lumees/github-code-2025-language-split · Datasets at Hugging Face

repo_id stringlengths 5 115	size int64 590 5.01M	file_path stringlengths 4 212	content stringlengths 590 5.01M
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	2,879	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_invalidate_icache_range.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * * microblaze_invalidate_icache_range(unsigned int cacheaddr, unsigned int len) * * Invalidate an ICache range * * Parameters: * 'cacheaddr' - address in the Icache where invalidation begins * 'len' - length (in bytes) worth of Icache to be invalidated * * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_ICACHE_ENABLE 0x00000020 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_ICACHE_LINE_LEN #define XPAR_MICROBLAZE_ICACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #endif .text .globl microblaze_invalidate_icache_range .ent microblaze_invalidate_icache_range .align 2 microblaze_invalidate_icache_range: #if (XPAR_MICROBLAZE_USE_ICACHE==1) && (XPAR_MICROBLAZE_ALLOW_ICACHE_WR==1) #ifdef MB_VERSION_LT_v720 / Disable Icache and interrupts before invalidating / mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_ICACHE_ENABLE \| MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif BEQI r6, L_done / Skip loop if size is zero / ADD r6, r5, r6 / Compute end address / ADDIK r6, r6, -1 ANDI r6, r6, -(4 XPAR_MICROBLAZE_ICACHE_LINE_LEN) /* Align end down to cache line / ANDI r5, r5, -(4 XPAR_MICROBLAZE_ICACHE_LINE_LEN) /* Align start down to cache line / L_start: CMPU r18, r5, r6 / Are we at the end? / BLTI r18, L_done wic r5, r0 / Invalidate the cache line / #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN 4) /* Increment the address by 4 / breai L_start / Branch to the beginning of the loop / #else brid L_start / Branch to the beginning of the loop / addik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN 4) /* Increment the address by 4 (delay slot) / #endif L_done: rtsd r15, 8 / Return / #ifdef MB_VERSION_LT_v720 / restore MSR only for MB version < v7.20 / mts rmsr, r9 #else nop #endif #else rtsd r15, 8 / Return */ nop #endif .end microblaze_invalidate_icache_range
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,482	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_flush_cache_ext_range.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * microblaze_flush_cache_ext_range (unsigned int cacheaddr, unsigned int len) * Flush a L2 Cache range Parameters: 'cacheaddr' - address in the L2 cache where the flush begins * 'len ' - length (in bytes) worth of L2 cache to be flushed * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN 16 .text .globl microblaze_flush_cache_ext_range .ent microblaze_flush_cache_ext_range .align 2 microblaze_flush_cache_ext_range: #if ((XPAR_MICROBLAZE_INTERCONNECT==3) && (XPAR_MICROBLAZE_USE_DCACHE==1)) beqi r6, Loop_done ADDIK r6, r6, -1 ADD r6, r5, r6 ANDI r6, r6, -(4 XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) ANDI r5, r5, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) RSUBK r6, r5, r6 Loop_start: wdc.ext.flush r5, r6 #if defined (__arch64__ ) addlik r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) beagei r6, Loop_start #else bneid r6, Loop_start addik r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) #endif Loop_done: #endif rtsd r15, 8 nop .end microblaze_flush_cache_ext_range
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,815	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_flush_dcache.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * * microblaze_flush_dcache() * * Flush the L1 DCache * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif .text .globl microblaze_flush_dcache .ent microblaze_flush_dcache .align 2 microblaze_flush_dcache: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) ADDIK r5, r0, XPAR_MICROBLAZE_DCACHE_BASEADDR & (-(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN)) /* Align to cache line / ADDIK r6, r5, XPAR_MICROBLAZE_DCACHE_BYTE_SIZE & (-(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN)) /* Compute end / L_start: wdc.flush r5, r0 / Flush the Cache / CMPU r18, r5, r6 / Are we at the end? / BLEI r18, L_done #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* Increment the address by 4 / BRI L_start #else brid L_start / Branch to the beginning of the loop / addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* Increment the address by 4 (delay slot) / #endif L_done: #endif rtsd r15, 8 / Return */ nop .end microblaze_flush_dcache
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	32,372	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_selftest.S	/****************************************************************************** * Copyright (c) 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * * @file microblaze_selftest.S * * @addtogroup microblaze_pseudo_asm_macro * @{ * <h2> microblaze_selftest.S </h2> * * This routine provides an internal self test of the MicroBlaze processor. The * register file and all integer execution units are tested. Long instructions * are also included if 64-bit mode is enabled. Currently FPU, MMU, BTC, data * and instruction caches, and GET/PUT instructions are not covered. * * The routine is not reentrant, and disables interrupts and exceptions during * execution. This can result in increased interrupt latency. * * Call this routine regularly from a timer interrupt. * * When called from C code the routine should be declared as: * extern int microblaze_selftest(); * * @param None. * * @return * - 0 if self test was successful * - Error code if self test failed: * Bit 0: Register file test failed * Bit 1: ALU test failed * Bit 2: Shift unit test failed * Bit 3: Load-store test failed * Bit 4: Branch instruction test failed * Bit 5: Barrel shifter test failed * Bit 6: Multiplier test failed * Bit 7: Integer divide test failed * Bit 8: Pattern compare test failed * Bit 9: MSR instruction test failed * Bit 10: Reorder instruction test failed * * @note * This routine assumes that the processor is in privileged mode when it is * called, if the MMU is enabled. * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- -------- ----------------------------------------------- * 1.0 sa 09/07/20 First release * * *****************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" / Define if execution units are used / #ifdef XPAR_MICROBLAZE_USE_BARREL #if XPAR_MICROBLAZE_USE_BARREL > 0 #define USE_BARREL #endif #endif #ifdef XPAR_MICROBLAZE_USE_HW_MUL #if XPAR_MICROBLAZE_USE_HW_MUL > 0 #define USE_HW_MUL #endif #if XPAR_MICROBLAZE_USE_HW_MUL == 2 #define USE_HW_MUL_2 #endif #endif #ifdef XPAR_MICROBLAZE_USE_DIV #if XPAR_MICROBLAZE_USE_DIV > 0 #define USE_DIV #endif #endif #ifdef XPAR_MICROBLAZE_USE_PCMP_INSTR #if XPAR_MICROBLAZE_USE_PCMP_INSTR > 0 #define USE_PCMP_INSTR #endif #endif #ifdef XPAR_MICROBLAZE_USE_MSR_INSTR #if XPAR_MICROBLAZE_USE_MSR_INSTR > 0 #define USE_MSR_INSTR #endif #endif #ifdef XPAR_MICROBLAZE_USE_REORDER_INSTR #if XPAR_MICROBLAZE_USE_REORDER_INSTR > 0 #define USE_REORDER_INSTR #endif #endif #if defined (__arch64__) #define OFFSET(index) ((index) 8) #define INCR(index) addlik r1, (index) * 8 #define DATA .quad #else #define OFFSET(index) ((index) * 4) #define INCR(index) addik r1, r1, (index) * 4 #define DATA .long #endif /***************************************************************************** * Machine Status Register masks ****************************************************************************/ #define MSR_CARRY_MASK 0x80000004 #define MSR_EE_IE_MASK 0x00000102 #define MSR_PVR_BIT_MASK 0x00000000 #ifdef XPAR_MICROBLAZE_PVR #if XPAR_MICROBLAZE_PVR > 0 #undef MSR_PVR_BIT_MASK #define MSR_PVR_BIT_MASK 0x00000400 #endif #endif #define MSR_BIT_MASK (0x8000000E \| MSR_PVR_BIT_MASK) /*************************************************************************** * Test macros ****************************************************************************/ #define TEST_ALU_ARITH(instr, load, offset) \ instr r5, r2, r4; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_aluerr; \ lwi r8, r1, OFFSET(offset + 1); \ mfs r9, rmsr; \ andi r9, r9, MSR_CARRY_MASK; \ cmpu r9, r9, r8; \ BNEID r9, L_microblaze_selftest_aluerr #define TEST_ALU_LOGIC(instr, load, offset) \ instr r5, r2, r4; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_aluerr #define TEST_SHIFT(instr, load, offset) \ instr r5, r2; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_shifterr #define TEST_SHIFTC(instr, load, offset) \ instr r5, r2; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_shifterr; \ lwi r8, r1, OFFSET(offset + 1); \ mfs r9, rmsr; \ andi r9, r9, MSR_CARRY_MASK; \ cmpu r9, r9, r8; \ BNEID r9, L_microblaze_selftest_shifterr #define TEST_BARREL(instr, load, offset) \ instr r5, r2, r4; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_barrelerr #define TEST_BARREL_IMM(instr, immw, imms, load, offset) \ ori r5, r2, 0; \ instr r5, r4, immw, imms; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_barrelerr #define TEST_MUL(instr, load, byteoffset) \ instr r5, r2, r4; \ load r6, r1, byteoffset; \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_mulerr #define TEST_DIV(instr, load, byteoffset) \ instr r5, r2, r4; \ load r6, r1, byteoffset; \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_diverr #define TEST_PCMP(instr, load, offset) \ instr r5, r2, r4; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_pcmperr .text .globl microblaze_selftest .ent microblaze_selftest .align 2 microblaze_selftest: /*************************************************************************** * Preamble *****************************************************************************/ / Disable interrupts and exceptions, save MSR / #ifdef USE_MSR_INSTR msrclr r3, MSR_EE_IE_MASK #else mfs r3, rmsr andi r3, r3, ~MSR_EE_IE_MASK mts rmsr, r3 #endif swi r3, r0, L_microblaze_selftest_regs / Save registers, except r3 temporary register and return value / ADDIK r3, r0, L_microblaze_selftest_regs SI r1, r3, OFFSET(1) SI r2, r3, OFFSET(2) SI r4, r3, OFFSET(4) SI r5, r3, OFFSET(5) SI r6, r3, OFFSET(6) SI r7, r3, OFFSET(7) SI r8, r3, OFFSET(8) SI r9, r3, OFFSET(9) SI r10, r3, OFFSET(10) SI r11, r3, OFFSET(11) SI r12, r3, OFFSET(12) SI r13, r3, OFFSET(13) SI r14, r3, OFFSET(14) SI r15, r3, OFFSET(15) SI r16, r3, OFFSET(16) SI r17, r3, OFFSET(17) SI r18, r3, OFFSET(18) SI r19, r3, OFFSET(19) SI r20, r3, OFFSET(20) SI r21, r3, OFFSET(21) SI r22, r3, OFFSET(22) SI r23, r3, OFFSET(23) SI r24, r3, OFFSET(24) SI r25, r3, OFFSET(25) SI r26, r3, OFFSET(26) SI r27, r3, OFFSET(27) SI r28, r3, OFFSET(28) SI r29, r3, OFFSET(29) SI r30, r3, OFFSET(30) SI r31, r3, OFFSET(31) / Set r3 to test pass = 0 / ADDIK r3, r0, 0 /**************************************************************************** * 1. Test register file *****************************************************************************/ L_microblaze_selftest_reg: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_regdata L_microblaze_selftest_regloop: / Load test pattern into r2, r4 - r31 / LI r2, r1, 0 LI r4, r1, 0 LI r5, r1, 0 LI r6, r1, 0 LI r7, r1, 0 LI r8, r1, 0 LI r9, r1, 0 LI r10, r1, 0 LI r11, r1, 0 LI r12, r1, 0 LI r13, r1, 0 LI r14, r1, 0 LI r15, r1, 0 LI r16, r1, 0 LI r17, r1, 0 LI r18, r1, 0 LI r19, r1, 0 LI r20, r1, 0 LI r21, r1, 0 LI r22, r1, 0 LI r23, r1, 0 LI r24, r1, 0 LI r25, r1, 0 LI r26, r1, 0 LI r27, r1, 0 LI r28, r1, 0 LI r29, r1, 0 LI r30, r1, 0 LI r31, r1, 0 / Compare registers pair by pair / CMPU r2, r2, r4 BNEID r2, L_microblaze_selftest_regerr CMPU r4, r4, r5 BNEID r4, L_microblaze_selftest_regerr CMPU r5, r5, r6 BNEID r5, L_microblaze_selftest_regerr CMPU r6, r6, r7 BNEID r6, L_microblaze_selftest_regerr CMPU r7, r7, r8 BNEID r7, L_microblaze_selftest_regerr CMPU r8, r8, r9 BNEID r8, L_microblaze_selftest_regerr CMPU r9, r9, r10 BNEID r9, L_microblaze_selftest_regerr CMPU r10, r10, r11 BNEID r10, L_microblaze_selftest_regerr CMPU r11, r11, r12 BNEID r11, L_microblaze_selftest_regerr CMPU r12, r12, r13 BNEID r12, L_microblaze_selftest_regerr CMPU r13, r13, r14 BNEID r13, L_microblaze_selftest_regerr CMPU r14, r14, r15 BNEID r14, L_microblaze_selftest_regerr CMPU r15, r15, r16 BNEID r15, L_microblaze_selftest_regerr CMPU r16, r16, r17 BNEID r16, L_microblaze_selftest_regerr CMPU r17, r17, r18 BNEID r17, L_microblaze_selftest_regerr CMPU r18, r18, r19 BNEID r18, L_microblaze_selftest_regerr CMPU r19, r19, r20 BNEID r19, L_microblaze_selftest_regerr CMPU r20, r20, r21 BNEID r20, L_microblaze_selftest_regerr CMPU r21, r21, r22 BNEID r21, L_microblaze_selftest_regerr CMPU r22, r22, r23 BNEID r22, L_microblaze_selftest_regerr CMPU r23, r23, r24 BNEID r23, L_microblaze_selftest_regerr CMPU r24, r24, r25 BNEID r24, L_microblaze_selftest_regerr CMPU r25, r25, r26 BNEID r25, L_microblaze_selftest_regerr CMPU r26, r26, r27 BNEID r26, L_microblaze_selftest_regerr CMPU r27, r27, r28 BNEID r27, L_microblaze_selftest_regerr CMPU r28, r28, r29 BNEID r28, L_microblaze_selftest_regerr CMPU r29, r29, r30 BNEID r29, L_microblaze_selftest_regerr CMPU r30, r30, r31 BEQI r30, L_microblaze_selftest_regnext L_microblaze_selftest_regerr: / Test error - set register file error (bit 0) / ori r3, r3, 1 L_microblaze_selftest_regnext: / Loop back with next test pattern - end after zero pattern / BNEID r31, L_microblaze_selftest_regloop INCR(1) /**************************************************************************** * 2. Test ALU *****************************************************************************/ L_microblaze_selftest_alu: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_aludata L_microblaze_selftest_aluloop: / Load operands into r2, r4 / LI r2, r1, OFFSET(0) LI r4, r1, OFFSET(1) / Execute all ALU arithmetic instructions / TEST_ALU_ARITH(add, lwi, 2) TEST_ALU_ARITH(addc, lwi, 4) TEST_ALU_ARITH(rsub, lwi, 6) TEST_ALU_ARITH(rsubc, lwi, 8) TEST_ALU_LOGIC(cmp, lwi, 10) / Execute all ALU logical instructions / TEST_ALU_LOGIC(and, lwi, 11) TEST_ALU_LOGIC(andn, lwi, 12) TEST_ALU_LOGIC(or, lwi, 13) TEST_ALU_LOGIC(xor, lwi, 14) nop bri L_microblaze_selftest_alunext L_microblaze_selftest_aluerr: / Test error - set ALU error (bit 1) / ori r3, r3, 2 L_microblaze_selftest_alunext: / Loop back with next test data - end after zero data / BNEID r2, L_microblaze_selftest_aluloop INCR(15) /**************************************************************************** * 3. Test shift unit *****************************************************************************/ L_microblaze_selftest_shift: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_shiftdata L_microblaze_selftest_shiftloop: / Load operand into r2 / LI r2, r1, OFFSET(0) / Test instructions clz, sext8, sext16, sra, src, srl / TEST_SHIFT(clz, lwi, 1) TEST_SHIFT(sext8, lwi, 2) TEST_SHIFT(sext16, lwi, 3) TEST_SHIFTC(sra, lwi, 4) TEST_SHIFTC(src, lwi, 6) TEST_SHIFTC(srl, lwi, 8) nop bri L_microblaze_selftest_shiftnext L_microblaze_selftest_shifterr: / Test error - set shift logic error (bit 2) / ori r3, r3, 4 L_microblaze_selftest_shiftnext: / Loop back with next test data - end after zero data / BNEID r2, L_microblaze_selftest_shiftloop INCR(10) /**************************************************************************** * 4. Test load-store *****************************************************************************/ L_microblaze_selftest_ldst: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_ldstdata / Set static address and offsets / ADDIK r4, r0, L_microblaze_selftest_ldstptr ADDIK r24, r0, 4 ADDIK r28, r0, 8 L_microblaze_selftest_ldstloop: / Load operand into r2 / LI r2, r1, OFFSET(0) / Test instructions lbu, lhu, lw, sb, sh, sw / sb r2, r4, r0 sh r2, r4, r24 sw r2, r4, r28 lbu r8, r4, r0 lhu r9, r4, r24 lw r10, r4, r28 / Compare load results / ANDI r11, r2, 0xFF ANDI r12, r2, 0xFFFF CMPU r16, r11, r8 BNEID r16, L_microblaze_selftest_ldsterr CMPU r17, r12, r9 BNEID r17, L_microblaze_selftest_ldsterr CMPU r18, r2, r10 BEQI r18, L_microblaze_selftest_ldstnext L_microblaze_selftest_ldsterr: / Test error - set load-store error (bit 3) / ori r3, r3, 8 L_microblaze_selftest_ldstnext: / Loop back with next test data - end after zero data / BNEID r2, L_microblaze_selftest_ldstloop INCR(1) /**************************************************************************** * 4. Test branch *****************************************************************************/ L_microblaze_selftest_branch: / Test instructions blt, ble, bge, bgt, br / / Untested instructions: rtbd, rtid, rted, brk / addik r2, r0, 0 / EQ / addik r4, r0, 1 / GT / addik r5, r0, -1 / LT / / Taken branches / BEQI r2, L_microblaze_selftest_brancheq ori r3, r3, 16 / Test error / L_microblaze_selftest_brancheq: BGEI r2, L_microblaze_selftest_branchge0 ori r3, r3, 16 / Test error / L_microblaze_selftest_branchge0: BGEI r4, L_microblaze_selftest_branchge1 ori r3, r3, 16 / Test error / L_microblaze_selftest_branchge1: BGTI r4, L_microblaze_selftest_branchgt ori r3, r3, 16 / Test error / L_microblaze_selftest_branchgt: BLEI r2, L_microblaze_selftest_branchle0 ori r3, r3, 16 / Test error / L_microblaze_selftest_branchle0: BLEI r5, L_microblaze_selftest_branchle1 ori r3, r3, 16 / Test error / L_microblaze_selftest_branchle1: BLTI r5, L_microblaze_selftest_branchlt ori r3, r3, 16 / Test error / L_microblaze_selftest_branchlt: BNEI r4, L_microblaze_selftest_branchne ori r3, r3, 16 / Test error / L_microblaze_selftest_branchne: / Not taken branches / BEQI r4, L_microblaze_selftest_brancherr BEQI r5, L_microblaze_selftest_brancherr BGEI r5, L_microblaze_selftest_brancherr BGTI r2, L_microblaze_selftest_brancherr BGTI r5, L_microblaze_selftest_brancherr BLEI r4, L_microblaze_selftest_brancherr BLTI r2, L_microblaze_selftest_brancherr BLTI r4, L_microblaze_selftest_brancherr BNEI r2, L_microblaze_selftest_brancherr BRI L_microblaze_selftest_branchnext L_microblaze_selftest_brancherr: / Test error - set branch error (bit 4) / ori r3, r3, 16 L_microblaze_selftest_branchnext: /**************************************************************************** * 6. Test barrel shifter *****************************************************************************/ #ifdef USE_BARREL L_microblaze_selftest_barrel: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_barreldata L_microblaze_selftest_barrelloop: / Load operands into r2, r4 / LI r2, r1, OFFSET(0) LI r4, r1, OFFSET(1) / Test instructions bsrl, bsra, bsll, bsifi, bsefi / TEST_BARREL(bsrl, lwi, 2) TEST_BARREL(bsra, lwi, 3) TEST_BARREL(bsll, lwi, 4) TEST_BARREL_IMM(bsifi, 11, 6, lwi, 5); TEST_BARREL_IMM(bsefi, 6, 1, lwi, 6); nop bri L_microblaze_selftest_barrelnext L_microblaze_selftest_barrelerr: / Test error - set barrel logic error (bit 5) / ori r3, r3, 32 L_microblaze_selftest_barrelnext: / Loop back with next test data - end after zero data / BNEID r2, L_microblaze_selftest_barrelloop INCR(7) #endif /**************************************************************************** * 7. Test multiplier *****************************************************************************/ #ifdef USE_HW_MUL L_microblaze_selftest_mul: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_muldata L_microblaze_selftest_mulloop: / Load operands into r2, r4 / lwi r2, r1, 0 lwi r4, r1, 4 / Test instruction mul / TEST_MUL(mul, lwi, 8) #ifdef USE_HW_MUL_2 / Test instructions mulh, mulhu, mulhsu / TEST_MUL(mulh, lwi, 12) TEST_MUL(mulhu, lwi, 16) TEST_MUL(mulhsu, lwi, 20) #endif nop bri L_microblaze_selftest_mulnext L_microblaze_selftest_mulerr: / Test error - set multiply error (bit 6) / ori r3, r3, 64 L_microblaze_selftest_mulnext: / Loop back with next test data - end after zero data / BNEID r2, L_microblaze_selftest_mulloop #ifdef USE_HW_MUL_2 addik r1, r1, 24 #else addik r1, r1, 12 #endif #endif /**************************************************************************** * 8. Test integer divide *****************************************************************************/ #ifdef USE_DIV L_microblaze_selftest_div: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_divdata L_microblaze_selftest_divloop: / Load operands into r2, r4 / lwi r2, r1, 0 lwi r4, r1, 4 / Test instructions idiv, idivu / TEST_DIV(idiv, lwi, 8) TEST_DIV(idivu, lwi, 12) nop bri L_microblaze_selftest_divnext L_microblaze_selftest_diverr: / Test error - set integer divide error (bit 7) / ori r3, r3, 128 L_microblaze_selftest_divnext: / Loop back with next test data - end after zero data / BNEID r4, L_microblaze_selftest_divloop addik r1, r1, 16 #endif /**************************************************************************** * 9. Test pattern compare *****************************************************************************/ #ifdef USE_PCMP_INSTR L_microblaze_selftest_pcmp: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_pcmpdata L_microblaze_selftest_pcmploop: / Load operands into r2, r4 / LI r2, r1, OFFSET(0) LI r4, r1, OFFSET(1) / Test instructions pcmpbf, pcmpeq, pcmpne / / 64-bit: add instructions pcmplbf, pcmpleq, pcmplne / TEST_PCMP(pcmpbf, lwi, 2) TEST_PCMP(pcmpeq, lwi, 3) TEST_PCMP(pcmpne, lwi, 4) nop bri L_microblaze_selftest_pcmpnext L_microblaze_selftest_pcmperr: / Test error - set pcmp logic error (bit 8) / ori r3, r3, 256 L_microblaze_selftest_pcmpnext: / Loop back with next test data - end after zero data / BNEID r2, L_microblaze_selftest_pcmploop INCR(5) #endif /**************************************************************************** * 10. Test MSR instructions *****************************************************************************/ L_microblaze_selftest_msr: #ifdef USE_MSR_INSTR / Test instructions msrclr, msrset, mfs msr / msrset r0, ~MSR_EE_IE_MASK & 0x7FFF nop mfs r6, rmsr nop msrclr r7, 0x7FF nop mfs r8, rmsr nop #endif / Test instructions mfs msr, mts msr / / Bits not included: ICE, DZO, DCE, EE, EIP, UMS, VMS / addik r9, r0, MSR_BIT_MASK & ~MSR_EE_IE_MASK mts rmsr, r9 nop mfs r10, rmsr / Compare instruction result / #ifdef USE_MSR_INSTR addik r11, r0, MSR_PVR_BIT_MASK cmpu r12, r6, r7 BNEID r12, L_microblaze_selftest_msrerr cmpu r13, r8, r11 BNEID r13, L_microblaze_selftest_msrerr #endif cmpu r14, r9, r10 BEQI r14, L_microblaze_selftest_msrnext L_microblaze_selftest_msrerr: / Test error - set MSR instruction error (bit 9) / ori r3, r3, 512 L_microblaze_selftest_msrnext: /**************************************************************************** * 11. Test reorder instructions *****************************************************************************/ #ifdef USE_REORDER_INSTR L_microblaze_selftest_reorder: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_reorderdata / Set static address and offsets / ADDIK r4, r0, L_microblaze_selftest_ldstptr ADDIK r24, r0, 4 ADDIK r28, r0, 8 L_microblaze_selftest_reorderloop: / Load operand into r2 / LI r2, r1, OFFSET(0) / Test instructions swapb, swaph, lbur, lhur, lwr, sbr, shr, swr / sbr r2, r4, r0 shr r2, r4, r24 swr r2, r4, r28 lbur r8, r4, r0 lhur r9, r4, r24 lwr r10, r4, r28 swapb r21, r2 swaph r22, r2 / Load swap results / LI r13, r1, OFFSET(1) LI r14, r1, OFFSET(2) / Compare load results / ANDI r11, r2, 0xFF ANDI r12, r2, 0xFFFF CMPU r16, r11, r8 BNEID r16, L_microblaze_selftest_reordererr CMPU r17, r12, r9 BNEID r17, L_microblaze_selftest_reordererr CMPU r18, r2, r10 BNEID r18, L_microblaze_selftest_reordererr CMPU r19, r21, r13 BNEID r19, L_microblaze_selftest_reordererr CMPU r20, r22, r14 BEQI r20, L_microblaze_selftest_reordernext L_microblaze_selftest_reordererr: / Test error - set reorder instruction error (bit 10) / ori r3, r3, 1024 L_microblaze_selftest_reordernext: / Loop back with next test data - end after zero data / BNEID r2, L_microblaze_selftest_reorderloop INCR(3) #endif /**************************************************************************** * Postamble *****************************************************************************/ / Restore all registers, except r3 return value and r4 temporary / ADDIK r31, r0, L_microblaze_selftest_regs LI r1, r31, OFFSET(1) LI r2, r31, OFFSET(2) LI r4, r31, OFFSET(4) LI r5, r31, OFFSET(5) LI r6, r31, OFFSET(6) LI r7, r31, OFFSET(7) LI r8, r31, OFFSET(8) LI r9, r31, OFFSET(9) LI r10, r31, OFFSET(10) LI r11, r31, OFFSET(11) LI r12, r31, OFFSET(12) LI r13, r31, OFFSET(13) LI r14, r31, OFFSET(14) LI r15, r31, OFFSET(15) LI r16, r31, OFFSET(16) LI r17, r31, OFFSET(17) LI r18, r31, OFFSET(18) LI r19, r31, OFFSET(19) LI r20, r31, OFFSET(20) LI r21, r31, OFFSET(21) LI r22, r31, OFFSET(22) LI r23, r31, OFFSET(23) LI r24, r31, OFFSET(24) LI r25, r31, OFFSET(25) LI r26, r31, OFFSET(26) LI r27, r31, OFFSET(27) LI r28, r31, OFFSET(28) LI r29, r31, OFFSET(29) LI r30, r31, OFFSET(30) LI r31, r31, OFFSET(31) / Restore MSR / lwi r4, r0, L_microblaze_selftest_regs mts rmsr, r4 / Return / rtsd r15, 8 nop L_microblaze_selftest_end: .end microblaze_selftest /**************************************************************************** * Temporary storage used by this routine * MSR followd by registers r1 - r31 ****************************************************************************/ .data .align 3 L_microblaze_selftest_regs: .rept 32 #if defined (__arch64__) .quad 0 #else .long 0 #endif .endr /*************************************************************************** * Test data used by this routine *****************************************************************************/ L_microblaze_selftest_regdata: #if defined (__arch64__) .quad 0x5555555555555555 .quad 0xAAAAAAAAAAAAAAAA .quad 0xFFFFFFFFFFFFFFFF .quad 0x0000000000000000 #else .long 0x55555555 .long 0xAAAAAAAA .long 0xFFFFFFFF .long 0x00000000 #endif L_microblaze_selftest_aludata: DATA 0x55555555 / rA operand / DATA 0x55555556 / rB operand / DATA 0xAAAAAAAB / rD result: add / DATA 0x00000000 / MSR.C: add / DATA 0xAAAAAAAB / rD result: addc / DATA 0x00000000 / MSR.C: addc / DATA 0x00000001 / rD result: rsub / DATA MSR_CARRY_MASK / MSR.C: rsub / DATA 0x00000001 / rD result: rsubc / DATA MSR_CARRY_MASK / MSR.C: rsubc / DATA 0x00000001 / rD result: cmp / DATA 0x55555554 / rD result: and / DATA 0x00000001 / rD result: andn / DATA 0x55555557 / rD result: or / DATA 0x00000003 / rD result: xor / DATA 0xAAAAAAAB / rA operand / DATA 0xAAAAAAAA / rB operand / DATA 0x55555555 / rD result: add / DATA MSR_CARRY_MASK / MSR.C: add / DATA 0x55555556 / rD result: addc / DATA MSR_CARRY_MASK / MSR.C: addc / DATA 0xFFFFFFFF / rD result: rsub / DATA 0x00000000 / MSR.C: rsub / DATA 0xFFFFFFFE / rD result: rsubc / DATA 0x00000000 / MSR.C: rsubc / DATA 0xFFFFFFFF / rD result: cmp / DATA 0xAAAAAAAA / rD result: and / DATA 0x00000001 / rD result: andn / DATA 0xAAAAAAAB / rD result: or / DATA 0x00000001 / rD result: xor / DATA 0xFFFFFFFF / rA operand / DATA 0xFFFFFFFF / rB operand / DATA 0xFFFFFFFE / rD result: add / DATA MSR_CARRY_MASK / MSR.C: add / DATA 0xFFFFFFFF / rD result: addc / DATA MSR_CARRY_MASK / MSR.C: addc / DATA 0x00000000 / rD result: rsub / DATA MSR_CARRY_MASK / MSR.C: rsub / DATA 0x00000000 / rD result: rsubc / DATA MSR_CARRY_MASK / MSR.C: rsubc / DATA 0x00000000 / rD result: cmp / DATA 0xFFFFFFFF / rD result: and / DATA 0x00000000 / rD result: andn / DATA 0xFFFFFFFF / rD result: or / DATA 0x00000000 / rD result: xor / DATA 0x00000000 / rA operand / DATA 0xFFFFFFFF / rB operand / DATA 0xFFFFFFFF / rD result: add / DATA 0x00000000 / MSR.C: add / DATA 0xFFFFFFFF / rD result: addc / DATA 0x00000000 / MSR.C: addc / DATA 0xFFFFFFFF / rD result: rsub / DATA MSR_CARRY_MASK / MSR.C: rsub / DATA 0xFFFFFFFF / rD result: rsubc / DATA MSR_CARRY_MASK / MSR.C: rsubc / DATA 0xFFFFFFFF / rD result: cmp / DATA 0x00000000 / rD result: and / DATA 0x00000000 / rD result: andn / DATA 0xFFFFFFFF / rD result: or / DATA 0xFFFFFFFF / rD result: xor / L_microblaze_selftest_shiftdata: DATA 0x55555555 / rA operand / DATA 0x00000001 / rD result: clz / DATA 0x00000055 / rD result: sext8 / DATA 0x00005555 / rD result: sext16 / DATA 0x2AAAAAAA / rD result: sra / DATA MSR_CARRY_MASK / MSR.C: sra / DATA 0xAAAAAAAA / rD result: src / DATA MSR_CARRY_MASK / MSR.C: src / DATA 0x2AAAAAAA / rD result: srl / DATA MSR_CARRY_MASK / MSR.C: src / DATA 0xAAAAAAAA / rA operand / DATA 0x00000000 / rD result: clz / DATA 0xFFFFFFAA / rD result: sext8 / DATA 0xFFFFAAAA / rD result: sext16 / DATA 0xD5555555 / rD result: sra / DATA 0x00000000 / MSR.C: sra / DATA 0x55555555 / rD result: src / DATA 0x00000000 / MSR.C: src / DATA 0x55555555 / rD result: srl / DATA 0x00000000 / MSR.C: srl / DATA 0xFFFFFFFF / rA operand / DATA 0x00000000 / rD result: clz / DATA 0xFFFFFFFF / rD result: sext8 / DATA 0xFFFFFFFF / rD result: sext16 / DATA 0xFFFFFFFF / rD result: sra / DATA MSR_CARRY_MASK / MSR.C: sra / DATA 0xFFFFFFFF / rD result: src / DATA MSR_CARRY_MASK / MSR.C: src / DATA 0x7FFFFFFF / rD result: srl / DATA MSR_CARRY_MASK / MSR.C: srl / DATA 0x00000000 / rA operand / DATA 0x00000020 / rD result: clz / DATA 0x00000000 / rD result: sext8 / DATA 0x00000000 / rD result: sext16 / DATA 0x00000000 / rD result: sra / DATA 0x00000000 / MSR.C: sra / DATA 0x00000000 / rD result: src / DATA 0x00000000 / MSR.C: src / DATA 0x00000000 / rD result: srl / DATA 0x00000000 / MSR.C: srl / L_microblaze_selftest_ldstdata: DATA 0xDEADBEEF / rD operand / DATA 0x12345678 / rD operand / DATA 0x00000000 / rD operand / L_microblaze_selftest_ldstptr: DATA 0 DATA 0 DATA 0 L_microblaze_selftest_barreldata: DATA 0x55555555 / rA operand / DATA 16 / rB operand / DATA 0x00005555 / rD result: bsrl / DATA 0x00005555 / rD result: bsra / DATA 0x55550000 / rD result: bsll / DATA 0x55540415 / rD result: bsifi / DATA 0x00000008 / rD result: bsefi / DATA 0xAAAAAAAA / rA operand / DATA 1 / rB operand / DATA 0x55555555 / rD result: bsrl / DATA 0xD5555555 / rD result: bsra / DATA 0x55555554 / rD result: bsll / DATA 0xAAAA006A / rD result: bsifi / DATA 0x00000000 / rD result: bsefi / DATA 0xFFFFFFFF / rA operand / DATA 25 / rB operand / DATA 0x0000007F / rD result: bsrl / DATA 0xFFFFFFFF / rD result: bsra / DATA 0xFE000000 / rD result: bsll / DATA 0xFFFE067F / rD result: bsifi / DATA 0x0000000C / rD result: bsefi / DATA 0x00000000 / rA operand / DATA 10 / rB operand / DATA 0x00000000 / rD result: bsrl / DATA 0x00000000 / rD result: bsra / DATA 0x00000000 / rD result: bsll / DATA 0x00000280 / rD result: bsifi / DATA 0x00000005 / rD result: bsefi / L_microblaze_selftest_muldata: .long 0x55555555 / rA operand / .long 0x55555555 / rB operand / .long 0x38E38E39 / rD result: mul / #ifdef USE_HW_MUL_2 .long 0x1C71C71C / rD result: mulh / .long 0x1C71C71C / rD result: mulhu / .long 0x1C71C71C / rD result: mulhsu / #endif .long 0xAAAAAAAA / rA operand / .long 0xAAAAAAAA / rB operand / .long 0xE38E38E4 / rD result: mul / #ifdef USE_HW_MUL_2 .long 0x1C71C71C / rD result: mulh / .long 0x71C71C70 / rD result: mulhu / .long 0xC71C71C6 / rD result: mulhsu / #endif .long 0xFFFFFFFF / rA operand / .long 0xFFFFFFFF / rB operand / .long 0x00000001 / rD result: mul / #ifdef USE_HW_MUL_2 .long 0x00000000 / rD result: mulh / .long 0xFFFFFFFE / rD result: mulhu / .long 0xFFFFFFFF / rD result: mulhsu / #endif .long 0x00000000 / rA operand / .long 0x00000000 / rB operand / .long 0x00000000 / rD result: mul / #ifdef USE_HW_MUL_2 .long 0x00000000 / rD result: mulh / .long 0x00000000 / rD result: mulhu / .long 0x00000000 / rD result: mulhsu / #endif L_microblaze_selftest_divdata: .long 0x55555555 / rA operand / .long 0x55555555 / rB operand / .long 0x00000001 / rD result: div / .long 0x00000001 / rD result: divu / .long 0xAAAAAAAA / rA operand / .long 0xAAAAAAAA / rB operand / .long 0x00000001 / rD result: div / .long 0x00000001 / rD result: divu / .long 0xFFFFFFFF / rA operand / .long 0xFFFFFFFF / rB operand / .long 0x00000001 / rD result: div / .long 0x00000001 / rD result: divu / .long 0x00000001 / rA operand / .long 0x00000000 / rB operand / .long 0x00000000 / rD result: div / .long 0x00000000 / rD result: divu / .align 3 L_microblaze_selftest_pcmpdata: DATA 0x55555555 / rA operand / DATA 0x44445555 / rB operand / DATA 0x00000003 / rD result: pcmpbf / DATA 0x00000000 / rD result: pcmpeq / DATA 0x00000001 / rD result: pcmpne / DATA 0xAAAAAAAA / rA operand / DATA 0xAAAAAAAA / rB operand / DATA 0x00000001 / rD result: pcmpbf / DATA 0x00000001 / rD result: pcmpeq / DATA 0x00000000 / rD result: pcmpne / DATA 0xFFFFFFFF / rA operand / DATA 0x000000FF / rB operand / DATA 0x00000004 / rD result: pcmpbf / DATA 0x00000000 / rD result: pcmpeq / DATA 0x00000001 / rD result: pcmpne / DATA 0x00000000 / rA operand / DATA 0xDEADBEEF / rB operand / DATA 0x00000000 / rD result: pcmpbf / DATA 0x00000000 / rD result: pcmpeq / DATA 0x00000001 / rD result: pcmpne / L_microblaze_selftest_reorderdata: DATA 0xDEADBEEF / rD operand / DATA 0xEFBEADDE / rD result: swapb / DATA 0xBEEFDEAD / rD result: swaph / DATA 0x00000000 / rD operand / DATA 0x00000000 / rD result: swapb / DATA 0x00000000 / rD result: swaph / /* * @} End of "addtogroup microblaze_pseudo_asm_macro". */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	3,488	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_invalidate_dcache_range.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * * microblaze_invalidate_dcache_range (unsigned int cacheaddr, unsigned int len) * * Invalidate a Dcache range * * Parameters: * 'cacheaddr' - address in the Dcache where invalidation begins * 'len ' - length (in bytes) worth of Dcache to be invalidated * * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #define MB_HAS_WRITEBACK_SET 0 #else #define MB_HAS_WRITEBACK_SET XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #endif .text .globl microblaze_invalidate_dcache_range .ent microblaze_invalidate_dcache_range .align 2 microblaze_invalidate_dcache_range: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) #ifdef MB_VERSION_LT_v720 / Disable Dcache and interrupts before invalidating / mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_DCACHE_ENABLE \| MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif BEQI r6, L_done / Skip loop if size is zero / ADD r6, r5, r6 / Compute end address / ADDIK r6, r6, -1 ANDI r6, r6, -(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align end down to cache line / ANDI r5, r5, -(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align start down to cache line / #if MB_HAS_WRITEBACK_SET == 0 / Use a different scheme for MB version < v7.20 or when caches are write-through / L_start: CMPU r18, r5, r6 / Are we at the end? / BLTI r18, L_done wdc r5, r0 #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* Increment the address by 4 / breai L_start / Branch to the beginning of the loop / #else brid L_start / Branch to the beginning of the loop / addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* Increment the address by 4 (delay slot) / #endif #else RSUBK r6, r5, r6 / r6 will now contain (count of bytes - (4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN)) / L_start: wdc.clear r5, r6 / Invalidate the cache line only if the address matches / #if defined (__arch64__ ) addlik r6, r6, -(XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) beagei r6, L_start #else bneid r6, L_start addik r6, r6, -(XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) #endif #endif L_done: rtsd r15, 8 #ifdef MB_VERSION_LT_v720 /* restore MSR only for MB version < v7.20 */ mts rmsr, r9 #else nop #endif #else rtsd r15, 8 nop #endif .end microblaze_invalidate_dcache_range
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,070	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_enable_icache.S	/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * File : microblaze_enable_icache.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Enable icache on the microblaze. * * *****************************************************************************/ #include "xparameters.h" .text .globl microblaze_enable_icache .ent microblaze_enable_icache .align 2 microblaze_enable_icache: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrset r0, 0x20 #else /XPAR_MICROBLAZE_USE_MSR_INSTR == 1/ #Read the MSR register mfs r8, rmsr #Set the interrupt enable bit ori r8, r8, 0x20 #Save the MSR register mts rmsr, r8 #Return rtsd r15, 8 nop #endif /XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ .end microblaze_enable_icache
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	2,198	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_init_dcache_range.S	/****************************************************************************** * Copyright (c) 2006 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * microblaze_init_dcache_range (unsigned int cache_start, unsigned int cache_len) * * Invalidate dcache on the microblaze * * Parameters: * 'cache_start' - address in the Dcache where invalidation begins * 'cache_len' - length (in bytes) worth of Dcache to be invalidated * * ******************************************************************************/ #include "xparameters.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif .text .globl microblaze_init_dcache_range .ent microblaze_init_dcache_range .align 2 microblaze_init_dcache_range: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) mfs r9, rmsr / Disable Dcache and interrupts before invalidating / andi r10, r9, (~(MICROBLAZE_MSR_DCACHE_ENABLE \| MICROBLAZE_MSR_INTR_ENABLE)) mts rmsr, r10 andi r5, r5, -(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align to cache line / add r6, r5, r6 / Compute end / andi r6, r6, -(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align to cache line / L_start: wdc r5, r0 / Invalidate the Cache (delay slot) / cmpu r18, r5, r6 / Are we at the end ? / blei r18, L_done brid L_start / Branch to the beginning of the loop / addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* Increment the address by 4 (delay slot) / L_done: rtsd r15, 8 / Return / mts rmsr, r9 #else rtsd r15, 8 / Return */ nop #endif .end microblaze_init_dcache_range
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	2,385	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_invalidate_icache.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * * microblaze_invalidate_icache() * * Invalidate the entire ICache * * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_ICACHE_ENABLE 0x00000020 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_ICACHE_LINE_LEN #define XPAR_MICROBLAZE_ICACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #endif .text .globl microblaze_invalidate_icache .ent microblaze_invalidate_icache .align 2 microblaze_invalidate_icache: #if (XPAR_MICROBLAZE_USE_ICACHE==1) && (XPAR_MICROBLAZE_ALLOW_ICACHE_WR==1) #ifdef MB_VERSION_LT_v720 / Disable Icache and interrupts before invalidating / mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_ICACHE_ENABLE \| MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif ADDIK r5, r0, XPAR_MICROBLAZE_ICACHE_BASEADDR & (-(4 XPAR_MICROBLAZE_ICACHE_LINE_LEN)) /* Align to cache line / ADDIK r6, r5, XPAR_MICROBLAZE_CACHE_BYTE_SIZE & (-(4 XPAR_MICROBLAZE_ICACHE_LINE_LEN)) /* Compute end / L_start: wic r5, r0 / Invalidate the Cache / CMPU r18, r5, r6 / Are we at the end? / BLEI r18, L_done #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN 4) /* Increment the address by 4 / breai L_start #else brid L_start / Branch to the beginning of the loop / addik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN 4) /* Increment the address by 4 (delay slot) / #endif L_done: rtsd r15, 8 / Return / #ifdef MB_VERSION_LT_v720 / restore MSR only for MB version < v7.20 / mts rmsr, r9 #else nop #endif #else rtsd r15, 8 / Return */ nop #endif .end microblaze_invalidate_icache
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,575	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_enable_interrupts.S	/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * @file microblaze_enable_interrupts.S * * @addtogroup microblaze_pseudo_asm_macro * @{ * <h2> microblaze_enable_interrupts.S </h2> * - API to Enable Interrupts: void microblaze_enable_interrupts(void) * * This API Enables interrupts on the MicroBlaze processor. When the MicroBlaze * processor starts up, interrupts are disabled. Interrupts must be explicitly * turned on using this function. * * <pre> * * File : microblaze_enable_interrupts.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Enable interrupts on the microblaze. * </pre> * *****************************************************************************/ #include "xparameters.h" .text .globl microblaze_enable_interrupts .ent microblaze_enable_interrupts .align 2 microblaze_enable_interrupts: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrset r0, 0x2 nop #else /XPAR_MICROBLAZE_USE_MSR_INSTR == 1/ #Read the MSR register mfs r12, rmsr #Set the interrupt enable bit ori r12, r12, 0x2 #Save the MSR register mts rmsr, r12 #Return rtsd r15, 8 nop #endif /XPAR_MICROBLAZE_USE_MSR_INSTR == 1/ .end microblaze_enable_interrupts /* * @} End of "addtogroup microblaze_pseudo_asm_macro". */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	3,540	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_flush_dcache_range.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * microblaze_flush_dcache_range (unsigned int cacheaddr, unsigned int len) * * Flush a L1 DCache range * * Parameters: * 'cacheaddr' - address in the Dcache where the flush begins * 'len ' - length (in bytes) worth of Dcache to be flushed * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #define MB_HAS_WRITEBACK_SET 0 #else #define MB_HAS_WRITEBACK_SET XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #endif .text .globl microblaze_flush_dcache_range .ent microblaze_flush_dcache_range .align 2 microblaze_flush_dcache_range: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) #ifdef MB_VERSION_LT_v720 / Disable Dcache and interrupts before invalidating / mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_DCACHE_ENABLE \| MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif beqi r6, L_done / Skip loop if size is zero / ADD r6, r5, r6 / Compute end address / ADDIK r6, r6, -1 ANDI r6, r6, -(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align end down to cache line / ANDI r5, r5, -(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align start down to cache line / #if MB_HAS_WRITEBACK_SET == 0 / Use a different scheme for MB version < v7.20 or when caches are write-through / L_start: CMPU r18, r5, r6 / Are we at the end? / BLTI r18, L_done wdc r5, r0 / Invalidate the cache line / #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* Increment the address by 4 / breai L_start / Branch to the beginning of the loop / #else brid L_start / Branch to the beginning of the loop / addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* Increment the address by 4 (delay slot) / #endif #else RSUBK r6, r5, r6 / r6 will now contain (count of bytes - (4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN)) / L_start: wdc.flush r5, r6 / Flush the cache line / #if defined (__arch64__ ) addlik r6, r6, -(XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) beagei r6, L_start #else bneid r6, L_start addik r6, r6, -(XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) #endif #endif L_done: rtsd r15, 8 #ifdef MB_VERSION_LT_v720 /* restore MSR only for MB version < v7.20 / mts rmsr, r9 #else nop #endif #else rtsd r15, 8 / Return */ nop #endif .end microblaze_flush_dcache_range
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,555	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_disable_interrupts.S	/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * @file microblaze_disable_interrupts.S * * @addtogroup microblaze_pseudo_asm_macro * @{ * <h2> microblaze_disable_interrupts.S </h2> * - API to disable Interrupts: void microblaze_disable_interrupts(void) * * This API Disables interrupts on the MicroBlaze processor. It can be * called when entering a critical section of code where a context switch is * undesirable. * * <pre> * File : microblaze_disable_interrupts.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Disable interrupts on the microblaze. * </pre> * *****************************************************************************/ #include "xparameters.h" .text .globl microblaze_disable_interrupts .ent microblaze_disable_interrupts .align 2 microblaze_disable_interrupts: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrclr r0, 0x2 #else /XPAR_MICROBLAZE_USE_MSR_INSTR == 1/ #Read the MSR register mfs r12, rmsr #Clear the interrupt enable bit andi r12, r12, ~(0x2) #Save the MSR register mts rmsr, r12 #Return rtsd r15, 8 nop #endif /XPAR_MICROBLAZE_USE_MSR_INSTR == 1/ .end microblaze_disable_interrupts /* * @} End of "addtogroup microblaze_pseudo_asm_macro". */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	26,672	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/hw_exception_handler.S	/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * Microblaze HW Exception Handler * - Non self-modifying exception handler for the following exception conditions * - Unalignment * - Instruction bus error * - Data bus error * - Illegal instruction opcode * - Divide-by-zero * - Stack protection violation ******************************************************************************/ #include "microblaze_exceptions_g.h" #include "xparameters.h" #include "microblaze_instructions.h" / 64-bit definitions / #if defined (__arch64__) #define INTPTR_DATAITEM .quad #define REGSIZE 8 #define DATAALIGN 4 #else #define INTPTR_DATAITEM .long #define REGSIZE 4 #define DATAALIGN 2 #endif / 64-bit definitions / / Helpful Macros / #define EX_HANDLER_STACK_SIZ (REGSIZE21) #define RMSR_OFFSET (20 * REGSIZE) #define R17_OFFSET (0) #define REG_OFFSET(regnum) (REGSIZE * (regnum + 1)) #define NUM_TO_REG(num) r ## num #define R3_TO_STACK(regnum) SI r3, r1, REG_OFFSET(regnum) #define R3_FROM_STACK(regnum) LI r3, r1, REG_OFFSET(regnum) #define PUSH_REG(regnum) SI NUM_TO_REG(regnum), r1, REG_OFFSET(regnum) #define POP_REG(regnum) LI NUM_TO_REG(regnum), r1, REG_OFFSET(regnum) /* Uses r5 / #define PUSH_MSR \ mfs r5, rmsr; \ swi r5, r1, RMSR_OFFSET; #define PUSH_MSR_AND_ENABLE_EXC \ mfs r5, rmsr; \ swi r5, r1, RMSR_OFFSET; \ ori r5, r5, 0x100; / Turn ON the EE bit/ \ mts rmsr, r5; / Uses r5 / #define POP_MSR \ lwi r5, r1, RMSR_OFFSET; \ mts rmsr, r5; / Push r17 / #define PUSH_R17 SI r17, r1, R17_OFFSET / Pop r17 / #define POP_R17 LI r17, r1, R17_OFFSET #define LWREG_NOP \ BRI ex_handler_unhandled; \ nop; #define SWREG_NOP \ BRI ex_handler_unhandled; \ nop; / r3 is the source / #define R3_TO_LWREG_V(regnum) \ R3_TO_STACK (regnum); \ BRI ex_handler_done; / r3 is the source / #define R3_TO_LWREG(regnum) \ OR NUM_TO_REG (regnum), r0, r3; \ BRI ex_handler_done; / r3 is the target / #define SWREG_TO_R3_V(regnum) \ R3_FROM_STACK (regnum); \ BRI ex_sw_tail; / r3 is the target / #define SWREG_TO_R3(regnum) \ OR r3, r0, NUM_TO_REG (regnum); \ BRI ex_sw_tail; / regnum is the source / #define FP_EX_OPB_SAVE(regnum) \ SI NUM_TO_REG (regnum), r0, mb_fpex_op_b; \ nop; \ BRI handle_fp_ex_opa; / regnum is the source / #define FP_EX_OPB_SAVE_V(regnum) \ R3_FROM_STACK (regnum); \ SI r3, r0, mb_fpex_op_b; \ BRI handle_fp_ex_opa; / regnum is the source / #define FP_EX_OPA_SAVE(regnum) \ SI NUM_TO_REG (regnum), r0, mb_fpex_op_a; \ nop; \ BRI handle_fp_ex_done; / regnum is the source / #define FP_EX_OPA_SAVE_V(regnum) \ R3_FROM_STACK (regnum); \ SI r3, r0, mb_fpex_op_a; \ BRI handle_fp_ex_done; #define FP_EX_UNHANDLED \ BRI fp_ex_unhandled; \ nop; \ nop; / ESR masks / #define ESR_EXC_MASK 0x0000001F #define ESR_REG_MASK 0x000003E0 #define ESR_LW_SW_MASK 0x00000400 #define ESR_WORD_MASK 0x00000800 #define ESR_DS_MASK 0x00001000 #define ESR_LONG_MASK 0x00002000 / Extern declarations / .extern XNullHandler #ifdef MICROBLAZE_EXCEPTIONS_ENABLED / If exceptions are enabled in the processor / / * hw_exception_handler - Handler for unaligned exceptions * Exception handler notes: * - Does not handle exceptions other than unaligned exceptions * - Does not handle exceptions during load into r17, r1, r0. * - Does not handle exceptions during store from r17 (cannot be done) and r1 (slows down common case) * * Relevant register structures * * EAR - \|----\|----\|----\|----\|----\|----\|----\|----\| * - < ## 32 or 64 bit faulting address ## > * * ESR - \|----\|----\|----\|----\|----\| - \| - \|-----\|-----\| * - W S REG EXC * * * STACK FRAME STRUCTURE * --------------------- * * +-------------+ + 0 * \| r17 \| * +-------------+ + 4 (32-bit) + 8 (64-bit) * \| Args for \| * \| next func \| * +-------------+ + 8 (32-bit) + 16 (64-bit) * \| r1 \| * \| . \| * \| . \| * \| . \| * \| . \| * \| r18 \| * +-------------+ + 80 (32-bit) + 160 (64-bit) * \| MSR \| * +-------------+ + 84 (32-bit) + 168 (64-bit) * \| . \| * \| . \| / .global _hw_exception_handler .section .text .align 2 .ent _hw_exception_handler .type _hw_exception_handler, @function _hw_exception_handler: #if defined(XPAR_MICROBLAZE_USE_STACK_PROTECTION) && (XPAR_MICROBLAZE_USE_STACK_PROTECTION == 1) / Immediately halt for stack protection violation exception without using any stack / SI r3, r0, mb_sp_save_r3; / Save temporary register / mfs r3, resr; / Extract ESR[DS] / andi r3, r3, ESR_EXC_MASK; xori r3, r3, 0x7; / Check for stack protection violation / BNEI r3, ex_handler_not_sp_violation; ex_handler_sp_violation: bri 0; / Halt here if stack protection violation / ex_handler_not_sp_violation: LI r3, r0, mb_sp_save_r3; / Restore temporary register / #endif / defined(XPAR_MICROBLAZE_USE_STACK_PROTECTION) && (XPAR_MICROBLAZE_USE_STACK_PROTECTION == 1) / ADDIK r1, r1, -(EX_HANDLER_STACK_SIZ); / Create stack frame / PUSH_REG(3); PUSH_REG(4); PUSH_REG(5); PUSH_REG(6); #ifdef MICROBLAZE_CAN_HANDLE_EXCEPTIONS_IN_DELAY_SLOTS mfs r6, resr; andi r6, r6, ESR_DS_MASK; BEQI r6, ex_handler_no_ds; mfs r17, rbtr; ex_handler_no_ds: #endif PUSH_R17; PUSH_MSR_AND_ENABLE_EXC; / Exceptions enabled here. This will allow nested exceptions / mfs r3, resr; andi r5, r3, ESR_EXC_MASK; / Extract ESR[EXC] / #ifndef NO_UNALIGNED_EXCEPTIONS xori r6, r5, 1; / 00001 = Unaligned Exception / BNEI r6, handle_ex_regular; ADDIK r4, r0, MB_ExceptionVectorTable; / Check if user has registered an unaligned exception handler / #if defined (__arch64__) LI r4, r4, 16; #else LI r4, r4, 8; #endif ADDIK r6, r0, XNullHandler; / If exceptionvectortable entry is still XNullHandler, use / XOR r6, r4, r6; / the default exception handler / BEQI r6, handle_unaligned_ex ; handle_ex_regular: #endif / ! NO_UNALIGNED_EXCEPTIONS / #if defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) xori r6, r5, 6; / 00110 = FPU exception / BEQI r6, handle_fp_ex; / Go and decode the FP exception / #endif / defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) / handle_other_ex: / Handle Other exceptions here / ori r6, r0, 20; cmp r6, r5, r6; / >= 20 are exceptions we do not handle. / BLEI r6, ex_handler_unhandled; ori r6, r0, 7; cmp r6, r5, r6; / Convert MMU exception indices into an ordinal of 7 / BGTI r6, handle_other_ex_tail; ori r5, r0, 0x7; handle_other_ex_tail: PUSH_REG(7); / Save other volatiles before we make procedure calls below / PUSH_REG(8); PUSH_REG(9); PUSH_REG(10); PUSH_REG(11); PUSH_REG(12); PUSH_REG(15); PUSH_REG(18); ADDIK r4, r0, MB_ExceptionVectorTable; / Load the Exception vector table base address / ADDK r7, r5, r5; / Calculate exception vector offset = r5 * 8 (32-bit) / ADDK r7, r7, r7; ADDK r7, r7, r7; #if defined (__arch64__) ADDK r7, r7, r7; / or r5 * 16 (64-bit) / #endif ADDK r7, r7, r4; / Get pointer to exception vector / LI r5, r7, REGSIZE; / Load argument to exception handler from table / LOAD r7, r7, r0; / Load vector itself here / brald r15, r7; / Branch to handler / nop; POP_REG(7); / Restore other volatiles / POP_REG(8); POP_REG(9); POP_REG(10); POP_REG(11); POP_REG(12); POP_REG(15); POP_REG(18); BRI ex_handler_done; / Complete exception handling / #ifndef NO_UNALIGNED_EXCEPTIONS handle_unaligned_ex: andi r6, r3, ESR_REG_MASK; / Mask and extract the register operand / srl r6, r6; / r6 >> 5 / srl r6, r6; srl r6, r6; srl r6, r6; srl r6, r6; sbi r6, r0, ex_reg_op; / Store the register operand in a temporary location / mfs r4, rear; andi r6, r3, ESR_LW_SW_MASK; / Extract ESR[S] / BNEI r6, ex_sw; #if defined (__arch64__) ex_ll: andi r6, r3, ESR_LONG_MASK; / Extract ESR[L] / BEQI r6, ex_lw; lbui r5, r4, 0; / Exception address in r4 / sbi r5, r0, ex_tmp_data_loc_0; / Load a long, byte-by-byte from destination address and save it in tmp space / lbui r5, r4, 1; sbi r5, r0, ex_tmp_data_loc_1; lbui r5, r4, 2; sbi r5, r0, ex_tmp_data_loc_2; lbui r5, r4, 3; sbi r5, r0, ex_tmp_data_loc_3; lbui r5, r4, 4; sbi r5, r0, ex_tmp_data_loc_4; lbui r5, r4, 5; sbi r5, r0, ex_tmp_data_loc_5; lbui r5, r4, 6; sbi r5, r0, ex_tmp_data_loc_6; lbui r5, r4, 7; sbi r5, r0, ex_tmp_data_loc_7; lli r3, r0, ex_tmp_data_loc_0; / Get the destination register value into r3 / BRI ex_lw_tail; #endif ex_lw: andi r6, r3, ESR_WORD_MASK; / Extract ESR[W] / BEQI r6, ex_lhw; lbui r5, r4, 0; / Exception address in r4 / sbi r5, r0, ex_tmp_data_loc_0; / Load a word, byte-by-byte from destination address and save it in tmp space / lbui r5, r4, 1; sbi r5, r0, ex_tmp_data_loc_1; lbui r5, r4, 2; sbi r5, r0, ex_tmp_data_loc_2; lbui r5, r4, 3; sbi r5, r0, ex_tmp_data_loc_3; lwi r3, r0, ex_tmp_data_loc_0; / Get the destination register value into r3 / BRI ex_lw_tail; ex_lhw: lbui r5, r4, 0; / Exception address in r4 / sbi r5, r0, ex_tmp_data_loc_0; / Load a half-word, byte-by-byte from destination address and save it in tmp space / lbui r5, r4, 1; sbi r5, r0, ex_tmp_data_loc_1; lhui r3, r0, ex_tmp_data_loc_0; / Get the destination register value into r3 / ex_lw_tail: lbui r5, r0, ex_reg_op; / Get the destination register number into r5 / ADDIK r6, r0, lw_table; / Form load_word jump table offset (lw_table + (8 * regnum)) / ADDK r5, r5, r5; ADDK r5, r5, r5; ADDK r5, r5, r5; ADDK r5, r5, r6; bra r5; ex_lw_end: / Exception handling of load word, ends / ex_sw: lbui r5, r0, ex_reg_op; / Get the destination register number into r5 / ADDIK r6, r0, sw_table; / Form store_word jump table offset (sw_table + (8 * regnum)) / ADDK r5, r5, r5; ADDK r5, r5, r5; ADDK r5, r5, r5; ADDK r5, r5, r6; bra r5; ex_sw_tail: #if defined (__arch64__) ex_sl: mfs r6, resr; andi r6, r6, ESR_LONG_MASK; / Extract ESR[L] / BEQI r6, ex_not_sl; sli r3, r0, ex_tmp_data_loc_0; lbui r3, r0, ex_tmp_data_loc_0; / Store the long, byte-by-byte into destination address / sbi r3, r4, 0; lbui r3, r0, ex_tmp_data_loc_1; sbi r3, r4, 1; lbui r3, r0, ex_tmp_data_loc_2; sbi r3, r4, 2; lbui r3, r0, ex_tmp_data_loc_3; sbi r3, r4, 3; lbui r3, r0, ex_tmp_data_loc_4; sbi r3, r4, 4; lbui r3, r0, ex_tmp_data_loc_5; sbi r3, r4, 5; lbui r3, r0, ex_tmp_data_loc_6; sbi r3, r4, 6; lbui r3, r0, ex_tmp_data_loc_7; sbi r3, r4, 7; BRI ex_handler_done; ex_not_sl: #endif mfs r6, resr; andi r6, r6, ESR_WORD_MASK; / Extract ESR[W] / BEQI r6, ex_shw; swi r3, r0, ex_tmp_data_loc_0; lbui r3, r0, ex_tmp_data_loc_0; / Store the word, byte-by-byte into destination address / sbi r3, r4, 0; lbui r3, r0, ex_tmp_data_loc_1; sbi r3, r4, 1; lbui r3, r0, ex_tmp_data_loc_2; sbi r3, r4, 2; lbui r3, r0, ex_tmp_data_loc_3; sbi r3, r4, 3; BRI ex_handler_done; ex_shw: swi r3, r0, ex_tmp_data_loc_0; / Store the lower half-word, byte-by-byte into destination address / #ifdef __LITTLE_ENDIAN__ lbui r3, r0, ex_tmp_data_loc_0; #else lbui r3, r0, ex_tmp_data_loc_2; #endif sbi r3, r4, 0; #ifdef __LITTLE_ENDIAN__ lbui r3, r0, ex_tmp_data_loc_1; #else lbui r3, r0, ex_tmp_data_loc_3; #endif sbi r3, r4, 1; ex_sw_end: / Exception handling of store word, ends. / BRI ex_handler_done; #endif / !NO_UNALIGNED_EXCEPTIONS / #if defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) handle_fp_ex: ADDIK r3, r17, -4; / r17 contains (addr of exception causing FP instruction + 4) / lw r4, r0, r3; / We might find ourselves in a spot here. Unguaranteed load / handle_fp_ex_opb: ADDIK r6, r0, fp_table_opb; / Decode opB and store its value in mb_fpex_op_b / srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; andi r3, r4, 0x1F; ADDK r3, r3, r3; / Calculate (fp_table_opb + (regno * 12)) in r5 / ADDK r3, r3, r3; ADDK r5, r3, r3; ADDK r5, r5, r3; ADDK r5, r5, r6; bra r5; handle_fp_ex_opa: ADDIK r6, r0, fp_table_opa; / Decode opA and store its value in mb_fpex_op_a / srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; andi r3, r4, 0x1F; ADDK r3, r3, r3; / Calculate (fp_table_opb + (regno * 12)) in r5 / ADDK r3, r3, r3; ADDK r5, r3, r3; ADDK r5, r5, r3; ADDK r5, r5, r6; bra r5; handle_fp_ex_done: ori r5, r0, 6; / Set exception number back to 6 / BRI handle_other_ex_tail; fp_ex_unhandled: bri 0; #endif / defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) / ex_handler_done: POP_R17; POP_MSR; POP_REG(3); POP_REG(4); POP_REG(5); POP_REG(6); ADDIK r1, r1, (EX_HANDLER_STACK_SIZ); / Restore stack frame / rted r17, 0 nop ex_handler_unhandled: bri 0 / UNHANDLED. TRAP HERE / .end _hw_exception_handler #ifndef NO_UNALIGNED_EXCEPTIONS / * hw_exception_handler Jump Table * - Contains code snippets for each register that caused the unaligned exception. * - Hence exception handler is NOT self-modifying * - Separate table for load exceptions and store exceptions. * - Each table is of size: (8 * 32) = 256 bytes / .section .text .align 4 lw_table: lw_r0: R3_TO_LWREG (0); lw_r1: LWREG_NOP; lw_r2: R3_TO_LWREG (2); lw_r3: R3_TO_LWREG_V (3); lw_r4: R3_TO_LWREG_V (4); lw_r5: R3_TO_LWREG_V (5); lw_r6: R3_TO_LWREG_V (6); lw_r7: R3_TO_LWREG (7); lw_r8: R3_TO_LWREG (8); lw_r9: R3_TO_LWREG (9); lw_r10: R3_TO_LWREG (10); lw_r11: R3_TO_LWREG (11); lw_r12: R3_TO_LWREG (12); lw_r13: R3_TO_LWREG (13); lw_r14: R3_TO_LWREG (14); lw_r15: R3_TO_LWREG (15); lw_r16: R3_TO_LWREG (16); lw_r17: LWREG_NOP; lw_r18: R3_TO_LWREG (18); lw_r19: R3_TO_LWREG (19); lw_r20: R3_TO_LWREG (20); lw_r21: R3_TO_LWREG (21); lw_r22: R3_TO_LWREG (22); lw_r23: R3_TO_LWREG (23); lw_r24: R3_TO_LWREG (24); lw_r25: R3_TO_LWREG (25); lw_r26: R3_TO_LWREG (26); lw_r27: R3_TO_LWREG (27); lw_r28: R3_TO_LWREG (28); lw_r29: R3_TO_LWREG (29); lw_r30: R3_TO_LWREG (30); lw_r31: R3_TO_LWREG (31); sw_table: sw_r0: SWREG_TO_R3 (0); sw_r1: SWREG_NOP; sw_r2: SWREG_TO_R3 (2); sw_r3: SWREG_TO_R3_V (3); sw_r4: SWREG_TO_R3_V (4); sw_r5: SWREG_TO_R3_V (5); sw_r6: SWREG_TO_R3_V (6); sw_r7: SWREG_TO_R3 (7); sw_r8: SWREG_TO_R3 (8); sw_r9: SWREG_TO_R3 (9); sw_r10: SWREG_TO_R3 (10); sw_r11: SWREG_TO_R3 (11); sw_r12: SWREG_TO_R3 (12); sw_r13: SWREG_TO_R3 (13); sw_r14: SWREG_TO_R3 (14); sw_r15: SWREG_TO_R3 (15); sw_r16: SWREG_TO_R3 (16); sw_r17: SWREG_NOP; sw_r18: SWREG_TO_R3 (18); sw_r19: SWREG_TO_R3 (19); sw_r20: SWREG_TO_R3 (20); sw_r21: SWREG_TO_R3 (21); sw_r22: SWREG_TO_R3 (22); sw_r23: SWREG_TO_R3 (23); sw_r24: SWREG_TO_R3 (24); sw_r25: SWREG_TO_R3 (25); sw_r26: SWREG_TO_R3 (26); sw_r27: SWREG_TO_R3 (27); sw_r28: SWREG_TO_R3 (28); sw_r29: SWREG_TO_R3 (29); sw_r30: SWREG_TO_R3 (30); sw_r31: SWREG_TO_R3 (31); / Temporary data structures used in the handler / .section .data .align DATAALIGN ex_tmp_data_loc_0: .byte 0 ex_tmp_data_loc_1: .byte 0 ex_tmp_data_loc_2: .byte 0 ex_tmp_data_loc_3: .byte 0 #if defined (__arch64__) ex_tmp_data_loc_4: .byte 0 ex_tmp_data_loc_5: .byte 0 ex_tmp_data_loc_6: .byte 0 ex_tmp_data_loc_7: .byte 0 #endif ex_reg_op: .byte 0 #endif / ! NO_UNALIGNED_EXCEPTIONS / #if defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) / * FP exception decode jump table. * - Contains code snippets for each register that could have been a source operand for an excepting FP instruction * - Hence exception handler is NOT self-modifying * - Separate table for opA and opB * - Each table is of size: (12 * 32) = 384 bytes / .section .text .align 4 fp_table_opa: opa_r0: FP_EX_OPA_SAVE (0); opa_r1: FP_EX_UNHANDLED; opa_r2: FP_EX_OPA_SAVE (2); opa_r3: FP_EX_OPA_SAVE_V (3); opa_r4: FP_EX_OPA_SAVE_V (4); opa_r5: FP_EX_OPA_SAVE_V (5); opa_r6: FP_EX_OPA_SAVE_V (6); opa_r7: FP_EX_OPA_SAVE (7); opa_r8: FP_EX_OPA_SAVE (8); opa_r9: FP_EX_OPA_SAVE (9); opa_r10: FP_EX_OPA_SAVE (10); opa_r11: FP_EX_OPA_SAVE (11); opa_r12: FP_EX_OPA_SAVE (12); opa_r13: FP_EX_OPA_SAVE (13); opa_r14: FP_EX_UNHANDLED; opa_r15: FP_EX_UNHANDLED; opa_r16: FP_EX_UNHANDLED; opa_r17: FP_EX_UNHANDLED; opa_r18: FP_EX_OPA_SAVE (18); opa_r19: FP_EX_OPA_SAVE (19); opa_r20: FP_EX_OPA_SAVE (20); opa_r21: FP_EX_OPA_SAVE (21); opa_r22: FP_EX_OPA_SAVE (22); opa_r23: FP_EX_OPA_SAVE (23); opa_r24: FP_EX_OPA_SAVE (24); opa_r25: FP_EX_OPA_SAVE (25); opa_r26: FP_EX_OPA_SAVE (26); opa_r27: FP_EX_OPA_SAVE (27); opa_r28: FP_EX_OPA_SAVE (28); opa_r29: FP_EX_OPA_SAVE (29); opa_r30: FP_EX_OPA_SAVE (30); opa_r31: FP_EX_OPA_SAVE (31); fp_table_opb: opb_r0: FP_EX_OPB_SAVE (0); opb_r1: FP_EX_UNHANDLED; opb_r2: FP_EX_OPB_SAVE (2); opb_r3: FP_EX_OPB_SAVE_V (3); opb_r4: FP_EX_OPB_SAVE_V (4); opb_r5: FP_EX_OPB_SAVE_V (5); opb_r6: FP_EX_OPB_SAVE_V (6); opb_r7: FP_EX_OPB_SAVE (7); opb_r8: FP_EX_OPB_SAVE (8); opb_r9: FP_EX_OPB_SAVE (9); opb_r10: FP_EX_OPB_SAVE (10); opb_r11: FP_EX_OPB_SAVE (11); opb_r12: FP_EX_OPB_SAVE (12); opb_r13: FP_EX_OPB_SAVE (13); opb_r14: FP_EX_UNHANDLED; opb_r15: FP_EX_UNHANDLED; opb_r16: FP_EX_UNHANDLED; opb_r17: FP_EX_UNHANDLED; opb_r18: FP_EX_OPB_SAVE (18); opb_r19: FP_EX_OPB_SAVE (19); opb_r20: FP_EX_OPB_SAVE (20); opb_r21: FP_EX_OPB_SAVE (21); opb_r22: FP_EX_OPB_SAVE (22); opb_r23: FP_EX_OPB_SAVE (23); opb_r24: FP_EX_OPB_SAVE (24); opb_r25: FP_EX_OPB_SAVE (25); opb_r26: FP_EX_OPB_SAVE (26); opb_r27: FP_EX_OPB_SAVE (27); opb_r28: FP_EX_OPB_SAVE (28); opb_r29: FP_EX_OPB_SAVE (29); opb_r30: FP_EX_OPB_SAVE (30); opb_r31: FP_EX_OPB_SAVE (31); #endif / defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) / #if defined(MICROBLAZE_FP_EXCEPTION_ENABLED) && defined(MICROBLAZE_FP_EXCEPTION_DECODE) / This is where we store the opA and opB of the last excepting FP instruction / .section .data .align DATAALIGN .global mb_fpex_op_a .global mb_fpex_op_b mb_fpex_op_a: INTPTR_DATAITEM 0 mb_fpex_op_b: INTPTR_DATAITEM 0 #endif / defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) / #if defined(XPAR_MICROBLAZE_USE_STACK_PROTECTION) && (XPAR_MICROBLAZE_USE_STACK_PROTECTION == 1) / This is where we store the register used to check which exception occurred / .section .data .align DATAALIGN mb_sp_save_r3: INTPTR_DATAITEM 0 #endif / defined(XPAR_MICROBLAZE_USE_STACK_PROTECTION) && (XPAR_MICROBLAZE_USE_STACK_PROTECTION == 1) / / The exception vector table / .section .data .align DATAALIGN .global MB_ExceptionVectorTable MB_ExceptionVectorTable: INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 0 / -- FSL Exception -- / INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 1 / -- Unaligned Access Exception -- / INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 2 / -- Illegal Opcode Exception -- / INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 3 / -- Instruction Bus Exception -- / INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 4 / -- Data Bus Exception -- / INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 5 / -- Div-by-0 Exception -- / INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 6 / -- FPU Exception -- / INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 7 / -- MMU Exceptions -- / #else / Dummy exception handler, in case exceptions are not present in the processor / .global _hw_exception_handler .section .text .align 2 .ent _hw_exception_handler _hw_exception_handler: bri 0; .end _hw_exception_handler #endif / MICROBLAZE_EXCEPTIONS_ENABLED */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	2,550	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_update_dcache.S	/****************************************************************************** * Copyright (c) 2006 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * * File : microblaze_update_dcache.s * Date : 2003, September 24 * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Update dcache on the microblaze. * Takes in three parameters * r5 : Cache Tag Line * r6 : Cache Data * r7 : Lock/Valid information * Bit 30 is Lock [ 1 indicates locked ] * Bit 31 is Valid [ 1 indicates valid ] * * -------------------------------------------------------------- * \| Lock \| Valid \| Effect * -------------------------------------------------------------- * \| 0 \| 0 \| Invalidate Cache * \| 0 \| 1 \| Valid, but unlocked cacheline * \| 1 \| 0 \| Invalidate Cache, No effect of lock * \| 1 \| 1 \| Valid cache. Locked to a * \| \| \| particular address * -------------------------------------------------------------- * * *********************************************************************************/ #include "xparameters.h" #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif .text .globl microblaze_update_dcache .ent microblaze_update_dcache .align 2 microblaze_update_dcache: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) #if XPAR_MICROBLAZE_DCACHE_LINE_LEN == 1 / Read the MSR register into a temp register / mfs r18, rmsr / Clear the dcache enable bit to disable the cache Register r10,r18 are volatile registers and hence do not need to be saved before use / andi r10, r18, ~128 mts rmsr, r10 / Update the lock and valid info / andi r5, r5, 0xfffffffc or r5, r5, r7 / Update dcache / wdc r5, r6 / Return / rtsd r15, 8 mts rmsr, r18 #else / The only valid usage of this routine for larger cache line lengths is to invalidate a data cache line So call microblaze_init_dcache_range appropriately to do the job / brid microblaze_init_dcache_range addik r6, r0, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* We don't have a return instruction here. This is tail call optimization :) / #endif / XPAR_MICROBLAZE_DCACHE_LINE_LEN == 1 */ #else rtsd r15, 8 nop #endif .end microblaze_update_dcache
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,044	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_disable_icache.S	/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * File : microblaze_disable_icache.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Disable L1 icache on the microblaze. * * *****************************************************************************/ #include "xparameters.h" .text .globl microblaze_disable_icache .ent microblaze_disable_icache .align 2 microblaze_disable_icache: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrclr r0, 0x20 #else /XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ #Read the MSR register mfs r8, rmsr #Clear the icache enable bit andi r8, r8, ~(0x20) #Save the MSR register mts rmsr, r8 #Return rtsd r15, 8 nop #endif .end microblaze_disable_icache
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,676	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_disable_dcache.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * File : microblaze_disable_dcache.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Disable the L1 dcache on the microblaze. * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" .text .globl microblaze_disable_dcache .ent microblaze_disable_dcache .align 2 microblaze_disable_dcache: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 #if XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 ADDIK r1, r1, -8 SI r15, r1, 0 BRLID r15, microblaze_flush_dcache / microblaze_flush_dcache does not use r1/ nop LI r15, r1, 0 ADDIK r1, r1, 8 #endif / XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 / rtsd r15, 8 msrclr r0, 0x80 #else / XPAR_MICROBLAZE_USE_MSR_INSTR == 1 / ADDIK r1, r1, -8 #if XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 SI r15, r1, 0 BRLID r15, microblaze_flush_dcache nop #endif / XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 / mfs r11, rmsr andi r11, r11, ~(0x80) mts rmsr, r11 #if XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 LI r15, r1, 0 #endif / XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 / ADDIK r1, r1, 8 rtsd r15, 8 nop #endif /XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ .end microblaze_disable_dcache
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,428	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_invalidate_cache_ext.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * microblaze_invalidate_cache_ext() * Invalidate the entire L2 Cache * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN 16 #define CACHEABLE_REGION_SIZE (XPAR_MICROBLAZE_DCACHE_HIGHADDR - XPAR_MICROBLAZE_DCACHE_BASEADDR) .text .globl microblaze_invalidate_cache_ext .ent microblaze_invalidate_cache_ext .align 2 microblaze_invalidate_cache_ext: #if ((XPAR_MICROBLAZE_INTERCONNECT==3) && (XPAR_MICROBLAZE_USE_DCACHE==1)) ADDIK r5, r0, XPAR_MICROBLAZE_DCACHE_BASEADDR & (-(4 XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN)) ADDIK r6, r0, CACHEABLE_REGION_SIZE-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) ANDI r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) Loop_start: wdc.ext.clear r5, r6 #if defined (__arch64__ ) addlik r6, r6,-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) beagei r6, Loop_start #else bgtid r6,Loop_start addik r6, r6,-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) #endif #endif rtsd r15, 8 nop .end microblaze_invalidate_cache_ext
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	5,784	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_scrub.S	/****************************************************************************** * Copyright (c) 2012 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * microblaze_scrub () * * Scrub LMB memory and all internal BRAMs (data cache, instruction cache, * MMU UTLB and branch target cache) in MicroBlaze to reduce the possibility * of an uncorrectable error when fault tolerance support is enabled. * * This routine assumes that the processor is in privileged mode when it is * called, if the MMU is enabled. * * Call this routine regularly from a timer interrupt. * * Parameters: * None * * ******************************************************************************/ #include "xparameters.h" / Define if fault tolerance is used / #ifdef XPAR_MICROBLAZE_FAULT_TOLERANT #if XPAR_MICROBLAZE_FAULT_TOLERANT > 0 #define FAULT_TOLERANT #endif #endif / Define if LMB is used and can be scrubbed / #if defined(XPAR_MICROBLAZE_D_LMB) && \ defined(XPAR_DLMB_CNTLR_BASEADDR) && \ defined(XPAR_DLMB_CNTLR_HIGHADDR) #if XPAR_MICROBLAZE_D_LMB == 1 #define HAS_SCRUBBABLE_LMB #define DLMB_MASK (XPAR_DLMB_CNTLR_HIGHADDR - XPAR_DLMB_CNTLR_BASEADDR) #endif #endif / Set default cache line lengths / #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 4 #endif #ifndef XPAR_MICROBLAZE_ICACHE_LINE_LEN #define XPAR_MICROBLAZE_ICACHE_LINE_LEN 4 #endif / Define if internal Data Cache BRAMs are used / #if defined(XPAR_MICROBLAZE_USE_DCACHE) && defined(XPAR_MICROBLAZE_DCACHE_BYTE_SIZE) #if XPAR_MICROBLAZE_USE_DCACHE == 1 && XPAR_MICROBLAZE_DCACHE_BYTE_SIZE > 1024 #define HAS_BRAM_DCACHE #define DCACHE_INCREMENT (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) #define DCACHE_MASK (XPAR_MICROBLAZE_DCACHE_BYTE_SIZE - 1) #endif #endif /* Define if internal Instruction Cache BRAMs are used / #if defined(XPAR_MICROBLAZE_USE_ICACHE) && defined(XPAR_MICROBLAZE_CACHE_BYTE_SIZE) #if XPAR_MICROBLAZE_USE_ICACHE == 1 && XPAR_MICROBLAZE_CACHE_BYTE_SIZE > 1024 #define HAS_BRAM_ICACHE #define ICACHE_INCREMENT (XPAR_MICROBLAZE_ICACHE_LINE_LEN 4) #define ICACHE_MASK (XPAR_MICROBLAZE_CACHE_BYTE_SIZE - 1) #endif #endif /* Define if internal MMU UTLB BRAM is used / #ifdef XPAR_MICROBLAZE_USE_MMU #if XPAR_MICROBLAZE_USE_MMU > 1 #define HAS_BRAM_MMU_UTLB #endif #endif / Define if internal BTC BRAM is used, and match BTC clear to a complete cache scrub / #if defined(XPAR_MICROBLAZE_USE_BRANCH_TARGET_CACHE) && \ defined(XPAR_MICROBLAZE_BRANCH_TARGET_CACHE_SIZE) #if XPAR_MICROBLAZE_USE_BRANCH_TARGET_CACHE == 1 #if XPAR_MICROBLAZE_BRANCH_TARGET_CACHE_SIZE == 0 \|\| \ XPAR_MICROBLAZE_BRANCH_TARGET_CACHE_SIZE > 4 #define HAS_BRAM_BRANCH_TARGET_CACHE #ifdef HAS_BRAM_DCACHE #define BTC_MASK_D (XPAR_MICROBLAZE_DCACHE_BYTE_SIZE/DCACHE_INCREMENT-1) #else #define BTC_MASK_D 256 #endif #ifdef HAS_BRAM_ICACHE #define BTC_MASK_I (XPAR_MICROBLAZE_CACHE_BYTE_SIZE/ICACHE_INCREMENT-1) #else #define BTC_MASK_I 256 #endif #if BTC_MASK_D > BTC_MASK_I #define BTC_MASK BTC_MASK_D #else #define BTC_MASK BTC_MASK_I #endif #endif #endif #endif / Define index offsets to persistent data used by this routine / #define DLMB_INDEX_OFFSET 0 #define DCACHE_INDEX_OFFSET 4 #define ICACHE_INDEX_OFFSET 8 #define MMU_INDEX_OFFSET 12 #define BTC_CALL_COUNT_OFFSET 16 .text .globl microblaze_scrub .ent microblaze_scrub .align 2 microblaze_scrub: #ifdef FAULT_TOLERANT la r6, r0, L_persistent_data / Get pointer to data / #ifdef HAS_SCRUBBABLE_LMB L_dlmb: lwi r5, r6, DLMB_INDEX_OFFSET / Get dlmb index / lw r7, r5, r0 / Load and store / sw r7, r5, r0 addik r5, r5, 4 / Increment and save dlmb index / andi r5, r5, DLMB_MASK swi r5, r6, DLMB_INDEX_OFFSET #endif / HAS_SCRUBBABLE_LMB / #ifdef HAS_BRAM_DCACHE L_dcache: lwi r5, r6, DCACHE_INDEX_OFFSET / Get dcache line index / wdc r5, r0 / Invalidate data cache line / addik r5, r5, DCACHE_INCREMENT / Increment and save entry index / andi r5, r5, DCACHE_MASK swi r5, r6, DCACHE_INDEX_OFFSET #endif / HAS_BRAM_DCACHE / #ifdef HAS_BRAM_ICACHE L_icache: lwi r5, r6, ICACHE_INDEX_OFFSET / Get icache line index / wic r5, r0 / Invalidate data cache line / addik r5, r5, ICACHE_INCREMENT / Increment and save entry index / andi r5, r5, ICACHE_MASK swi r5, r6, ICACHE_INDEX_OFFSET #endif / HAS_BRAM_ICACHE / #ifdef HAS_BRAM_MMU_UTLB L_mmu: lwi r5, r6, MMU_INDEX_OFFSET / Get UTLB entry index / mts rtlbx, r5 / Access next entry in UTLB / mts rtlbhi, r0 / Clear the UTLB entry / addik r5, r5, 1 / Increment and save entry index / andi r5, r5, 0x3F swi r5, r6, MMU_INDEX_OFFSET #endif / HAS_BRAM_MMU_UTLB / #ifdef HAS_BRAM_BRANCH_TARGET_CACHE L_btc: lwi r5, r6, BTC_CALL_COUNT_OFFSET / Get BTC call count offset / addik r5, r5, 1 / Increment and save call count / andi r5, r5, BTC_MASK swi r5, r6, BTC_CALL_COUNT_OFFSET bnei r5, L_skip_btc_scrub / Skip scrub unless count wrap / bri 4 / Clear branch target cache / L_skip_btc_scrub: #endif / HAS_BRAM_BRANCH_TARGET_CACHE / #endif / FAULT_TOLERANT / L_done: rtsd r15, 8 / Return / nop .end microblaze_scrub / Persistent data used by this routine / .data .align 2 L_persistent_data: .long 0 / dlmb index / .long 0 / dcache index / .long 0 / icache index / .long 0 / mmu entry index / .long 0 / btc call count */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,396	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_flush_cache_ext.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * microblaze_flush_cache_ext() * * Flush the entire L2 Cache * * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN 16 #define CACHEABLE_REGION_SIZE (XPAR_MICROBLAZE_DCACHE_HIGHADDR - XPAR_MICROBLAZE_DCACHE_BASEADDR) .text .globl microblaze_flush_cache_ext .ent microblaze_flush_cache_ext .align 2 microblaze_flush_cache_ext: #if ((XPAR_MICROBLAZE_INTERCONNECT==3) && (XPAR_MICROBLAZE_USE_DCACHE==1)) ADDIK r5, r0, XPAR_MICROBLAZE_DCACHE_BASEADDR & (-(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN)) ADDIK r6, r0, CACHEABLE_REGION_SIZE-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) ANDI r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) Loop_start: wdc.ext.flush r5, r6 #if defined (__arch64__) addlik r6, r6,-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) beagei r6, Loop_start #else bgtid r6,Loop_start addik r6, r6,-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) #endif #endif rtsd r15, 8 nop .end microblaze_flush_cache_ext
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,519	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_invalidate_cache_ext_range.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * microblaze_invalidate_cache_ext_range (unsigned int cacheaddr, unsigned int len) * Invalidate an L2 cache range Parameters: 'cacheaddr' - address in the L2 cache where invalidation begins * 'len ' - length (in bytes) worth of Dcache to be invalidated * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN 16 .text .globl microblaze_invalidate_cache_ext_range .ent microblaze_invalidate_cache_ext_range .align 2 microblaze_invalidate_cache_ext_range: #if ((XPAR_MICROBLAZE_INTERCONNECT==3) && (XPAR_MICROBLAZE_USE_DCACHE==1)) beqi r6, Loop_done ADD r6, r5, r6 ADDIK r6, r6, -1 ANDI r6, r6, -(4 XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) ANDI r5, r5, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) RSUBK r6, r5, r6 Loop_start: wdc.ext.clear r5, r6 #if defined (__arch64__ ) addlik r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) beagei r6, Loop_start #else bneid r6, Loop_start addik r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) #endif Loop_done: #endif rtsd r15, 8 nop .end microblaze_invalidate_cache_ext_range
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	2,555	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_update_icache.S	/****************************************************************************** * Copyright (c) 2006 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * File : microblaze_update_icache.s * Date : 2003, September 24 * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Update icache on the microblaze. * Takes in three parameters * r5 : Cache Tag Line * r6 : Cache Data * r7 : Lock/Valid information * Bit 30 is Lock [ 1 indicates locked ] * Bit 31 is Valid [ 1 indicates valid ] * * -------------------------------------------------------------- * \| Lock \| Valid \| Effect * -------------------------------------------------------------- * \| 0 \| 0 \| Invalidate Cache * \| 0 \| 1 \| Valid, but unlocked cacheline * \| 1 \| 0 \| Invalidate Cache, No effect of lock * \| 1 \| 1 \| Valid cache. Locked to a * \| \| \| particular address * -------------------------------------------------------------- * * *********************************************************************************/ #include "xparameters.h" #ifndef XPAR_MICROBLAZE_ICACHE_LINE_LEN #define XPAR_MICROBLAZE_ICACHE_LINE_LEN 1 #endif .text .globl microblaze_update_icache .ent microblaze_update_icache .align 2 microblaze_update_icache: #if (XPAR_MICROBLAZE_USE_ICACHE==1) && (XPAR_MICROBLAZE_ALLOW_ICACHE_WR==1) #if XPAR_MICROBLAZE_ICACHE_LINE_LEN == 1 / Read the MSR register into a temp register / mfs r18, rmsr / Clear the icache enable bit to disable the cache Register r10,r18 are volatile registers and hence do not need to be saved before use / andi r10, r18, ~32 mts rmsr, r10 / Update the lock and valid info / andi r5, r5, 0xfffffffc or r5, r5, r7 / Update icache / wic r5, r6 / Return / rtsd r15, 8 mts rmsr, r18 #else / The only valid usage of this routine for larger cache line lengths is to invalidate an instruction cache line So call microblaze_init_icache_range appropriately to do the job / brid microblaze_init_icache_range addik r6, r0, (XPAR_MICROBLAZE_ICACHE_LINE_LEN 4) /* We don't have a return instruction here. This is tail call optimization :) / #endif / XPAR_MICROBLAZE_ICACHE_LINE_LEN == 1 */ #else rtsd r15, 8 nop #endif .end microblaze_update_icache
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,075	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_enable_dcache.S	/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * File : microblaze_enable_dcache.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Enable L1 dcache on the microblaze. * * *****************************************************************************/ #include "xparameters.h" .text .globl microblaze_enable_dcache .ent microblaze_enable_dcache .align 2 microblaze_enable_dcache: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrset r0, 0x80 #else /XPAR_MICROBLAZE_USE_MSR_INSTR == 1/ #Read the MSR register mfs r8, rmsr #Set the interrupt enable bit ori r8, r8, 0x80 #Save the MSR register mts rmsr, r8 #Return rtsd r15, 8 nop #endif /XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ .end microblaze_enable_dcache
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	2,365	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_invalidate_dcache.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * microblaze_invalidate_dcache() * * Invalidate the entire L1 DCache * * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #endif .text .globl microblaze_invalidate_dcache .ent microblaze_invalidate_dcache .align 2 microblaze_invalidate_dcache: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) #ifdef MB_VERSION_LT_v720 / Disable Dcache and interrupts before invalidating / mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_DCACHE_ENABLE \| MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif ADDIK r5, r0, XPAR_MICROBLAZE_DCACHE_BASEADDR & (-(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN)) ADDIK r6, r5, XPAR_MICROBLAZE_DCACHE_BYTE_SIZE & (-(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN)) /* Compute end / L_start: wdc r5, r0 / Invalidate the Cache / CMPU r18, r5, r6 / Are we at the end? / BLEI r18, L_done #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* Increment the address by 4 / breai L_start #else brid L_start / Branch to the beginning of the loop / addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* Increment the address by 4 (delay slot) / #endif L_done: rtsd r15, 8 / Return / #ifdef MB_VERSION_LT_v720 / restore MSR only for MB version < v7.20 / mts rmsr, r9 #else nop #endif #else rtsd r15, 8 / Return */ nop #endif .end microblaze_invalidate_dcache
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	2,200	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_init_icache_range.S	/****************************************************************************** * Copyright (c) 2006 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * * microblaze_init_icache_range (unsigned int cache_start, unsigned int cache_len) * * Invalidate icache on the microblaze * * Parameters: * 'cache_start' - address in the Icache where invalidation begins * 'cache_len' - length (in bytes) worth of Icache to be invalidated * * ******************************************************************************/ #include "xparameters.h" #define MICROBLAZE_MSR_ICACHE_ENABLE 0x00000020 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_ICACHE_LINE_LEN #define XPAR_MICROBLAZE_ICACHE_LINE_LEN 1 #endif .text .globl microblaze_init_icache_range .ent microblaze_init_icache_range .align 2 microblaze_init_icache_range: #if (XPAR_MICROBLAZE_USE_ICACHE==1) && (XPAR_MICROBLAZE_ALLOW_ICACHE_WR==1) mfs r9, rmsr / Disable Icache and interrupts before invalidating / andi r10, r9, (~(MICROBLAZE_MSR_ICACHE_ENABLE \| MICROBLAZE_MSR_INTR_ENABLE)) mts rmsr, r10 andi r5, r5, -(4 XPAR_MICROBLAZE_ICACHE_LINE_LEN) /* Align to cache line / add r6, r5, r6 / Compute end / andi r6, r6, -(4 XPAR_MICROBLAZE_ICACHE_LINE_LEN) /* Align to cache line / L_start: wic r5, r0 / Invalidate the Cache (delay slot) / cmpu r18, r5, r6 / Are we at the end ? / blei r18, L_done brid L_start / Branch to the beginning of the loop / addik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN 4) /* Increment the address by 4 (delay slot) / L_done: rtsd r15, 8 / Return / mts rmsr, r9 #else rtsd r15, 8 / Return */ nop #endif .end microblaze_init_icache_range
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	2,879	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_invalidate_icache_range.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * * microblaze_invalidate_icache_range(unsigned int cacheaddr, unsigned int len) * * Invalidate an ICache range * * Parameters: * 'cacheaddr' - address in the Icache where invalidation begins * 'len' - length (in bytes) worth of Icache to be invalidated * * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_ICACHE_ENABLE 0x00000020 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_ICACHE_LINE_LEN #define XPAR_MICROBLAZE_ICACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #endif .text .globl microblaze_invalidate_icache_range .ent microblaze_invalidate_icache_range .align 2 microblaze_invalidate_icache_range: #if (XPAR_MICROBLAZE_USE_ICACHE==1) && (XPAR_MICROBLAZE_ALLOW_ICACHE_WR==1) #ifdef MB_VERSION_LT_v720 / Disable Icache and interrupts before invalidating / mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_ICACHE_ENABLE \| MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif BEQI r6, L_done / Skip loop if size is zero / ADD r6, r5, r6 / Compute end address / ADDIK r6, r6, -1 ANDI r6, r6, -(4 XPAR_MICROBLAZE_ICACHE_LINE_LEN) /* Align end down to cache line / ANDI r5, r5, -(4 XPAR_MICROBLAZE_ICACHE_LINE_LEN) /* Align start down to cache line / L_start: CMPU r18, r5, r6 / Are we at the end? / BLTI r18, L_done wic r5, r0 / Invalidate the cache line / #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN 4) /* Increment the address by 4 / breai L_start / Branch to the beginning of the loop / #else brid L_start / Branch to the beginning of the loop / addik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN 4) /* Increment the address by 4 (delay slot) / #endif L_done: rtsd r15, 8 / Return / #ifdef MB_VERSION_LT_v720 / restore MSR only for MB version < v7.20 / mts rmsr, r9 #else nop #endif #else rtsd r15, 8 / Return */ nop #endif .end microblaze_invalidate_icache_range
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,482	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_flush_cache_ext_range.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * microblaze_flush_cache_ext_range (unsigned int cacheaddr, unsigned int len) * Flush a L2 Cache range Parameters: 'cacheaddr' - address in the L2 cache where the flush begins * 'len ' - length (in bytes) worth of L2 cache to be flushed * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN 16 .text .globl microblaze_flush_cache_ext_range .ent microblaze_flush_cache_ext_range .align 2 microblaze_flush_cache_ext_range: #if ((XPAR_MICROBLAZE_INTERCONNECT==3) && (XPAR_MICROBLAZE_USE_DCACHE==1)) beqi r6, Loop_done ADDIK r6, r6, -1 ADD r6, r5, r6 ANDI r6, r6, -(4 XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) ANDI r5, r5, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) RSUBK r6, r5, r6 Loop_start: wdc.ext.flush r5, r6 #if defined (__arch64__ ) addlik r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) beagei r6, Loop_start #else bneid r6, Loop_start addik r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) #endif Loop_done: #endif rtsd r15, 8 nop .end microblaze_flush_cache_ext_range
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,815	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_flush_dcache.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * * microblaze_flush_dcache() * * Flush the L1 DCache * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif .text .globl microblaze_flush_dcache .ent microblaze_flush_dcache .align 2 microblaze_flush_dcache: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) ADDIK r5, r0, XPAR_MICROBLAZE_DCACHE_BASEADDR & (-(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN)) /* Align to cache line / ADDIK r6, r5, XPAR_MICROBLAZE_DCACHE_BYTE_SIZE & (-(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN)) /* Compute end / L_start: wdc.flush r5, r0 / Flush the Cache / CMPU r18, r5, r6 / Are we at the end? / BLEI r18, L_done #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* Increment the address by 4 / BRI L_start #else brid L_start / Branch to the beginning of the loop / addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* Increment the address by 4 (delay slot) / #endif L_done: #endif rtsd r15, 8 / Return */ nop .end microblaze_flush_dcache
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	32,372	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_selftest.S	/****************************************************************************** * Copyright (c) 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * * @file microblaze_selftest.S * * @addtogroup microblaze_pseudo_asm_macro * @{ * <h2> microblaze_selftest.S </h2> * * This routine provides an internal self test of the MicroBlaze processor. The * register file and all integer execution units are tested. Long instructions * are also included if 64-bit mode is enabled. Currently FPU, MMU, BTC, data * and instruction caches, and GET/PUT instructions are not covered. * * The routine is not reentrant, and disables interrupts and exceptions during * execution. This can result in increased interrupt latency. * * Call this routine regularly from a timer interrupt. * * When called from C code the routine should be declared as: * extern int microblaze_selftest(); * * @param None. * * @return * - 0 if self test was successful * - Error code if self test failed: * Bit 0: Register file test failed * Bit 1: ALU test failed * Bit 2: Shift unit test failed * Bit 3: Load-store test failed * Bit 4: Branch instruction test failed * Bit 5: Barrel shifter test failed * Bit 6: Multiplier test failed * Bit 7: Integer divide test failed * Bit 8: Pattern compare test failed * Bit 9: MSR instruction test failed * Bit 10: Reorder instruction test failed * * @note * This routine assumes that the processor is in privileged mode when it is * called, if the MMU is enabled. * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- -------- ----------------------------------------------- * 1.0 sa 09/07/20 First release * * *****************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" / Define if execution units are used / #ifdef XPAR_MICROBLAZE_USE_BARREL #if XPAR_MICROBLAZE_USE_BARREL > 0 #define USE_BARREL #endif #endif #ifdef XPAR_MICROBLAZE_USE_HW_MUL #if XPAR_MICROBLAZE_USE_HW_MUL > 0 #define USE_HW_MUL #endif #if XPAR_MICROBLAZE_USE_HW_MUL == 2 #define USE_HW_MUL_2 #endif #endif #ifdef XPAR_MICROBLAZE_USE_DIV #if XPAR_MICROBLAZE_USE_DIV > 0 #define USE_DIV #endif #endif #ifdef XPAR_MICROBLAZE_USE_PCMP_INSTR #if XPAR_MICROBLAZE_USE_PCMP_INSTR > 0 #define USE_PCMP_INSTR #endif #endif #ifdef XPAR_MICROBLAZE_USE_MSR_INSTR #if XPAR_MICROBLAZE_USE_MSR_INSTR > 0 #define USE_MSR_INSTR #endif #endif #ifdef XPAR_MICROBLAZE_USE_REORDER_INSTR #if XPAR_MICROBLAZE_USE_REORDER_INSTR > 0 #define USE_REORDER_INSTR #endif #endif #if defined (__arch64__) #define OFFSET(index) ((index) 8) #define INCR(index) addlik r1, (index) * 8 #define DATA .quad #else #define OFFSET(index) ((index) * 4) #define INCR(index) addik r1, r1, (index) * 4 #define DATA .long #endif /***************************************************************************** * Machine Status Register masks ****************************************************************************/ #define MSR_CARRY_MASK 0x80000004 #define MSR_EE_IE_MASK 0x00000102 #define MSR_PVR_BIT_MASK 0x00000000 #ifdef XPAR_MICROBLAZE_PVR #if XPAR_MICROBLAZE_PVR > 0 #undef MSR_PVR_BIT_MASK #define MSR_PVR_BIT_MASK 0x00000400 #endif #endif #define MSR_BIT_MASK (0x8000000E \| MSR_PVR_BIT_MASK) /*************************************************************************** * Test macros ****************************************************************************/ #define TEST_ALU_ARITH(instr, load, offset) \ instr r5, r2, r4; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_aluerr; \ lwi r8, r1, OFFSET(offset + 1); \ mfs r9, rmsr; \ andi r9, r9, MSR_CARRY_MASK; \ cmpu r9, r9, r8; \ BNEID r9, L_microblaze_selftest_aluerr #define TEST_ALU_LOGIC(instr, load, offset) \ instr r5, r2, r4; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_aluerr #define TEST_SHIFT(instr, load, offset) \ instr r5, r2; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_shifterr #define TEST_SHIFTC(instr, load, offset) \ instr r5, r2; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_shifterr; \ lwi r8, r1, OFFSET(offset + 1); \ mfs r9, rmsr; \ andi r9, r9, MSR_CARRY_MASK; \ cmpu r9, r9, r8; \ BNEID r9, L_microblaze_selftest_shifterr #define TEST_BARREL(instr, load, offset) \ instr r5, r2, r4; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_barrelerr #define TEST_BARREL_IMM(instr, immw, imms, load, offset) \ ori r5, r2, 0; \ instr r5, r4, immw, imms; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_barrelerr #define TEST_MUL(instr, load, byteoffset) \ instr r5, r2, r4; \ load r6, r1, byteoffset; \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_mulerr #define TEST_DIV(instr, load, byteoffset) \ instr r5, r2, r4; \ load r6, r1, byteoffset; \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_diverr #define TEST_PCMP(instr, load, offset) \ instr r5, r2, r4; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_pcmperr .text .globl microblaze_selftest .ent microblaze_selftest .align 2 microblaze_selftest: /*************************************************************************** * Preamble *****************************************************************************/ / Disable interrupts and exceptions, save MSR / #ifdef USE_MSR_INSTR msrclr r3, MSR_EE_IE_MASK #else mfs r3, rmsr andi r3, r3, ~MSR_EE_IE_MASK mts rmsr, r3 #endif swi r3, r0, L_microblaze_selftest_regs / Save registers, except r3 temporary register and return value / ADDIK r3, r0, L_microblaze_selftest_regs SI r1, r3, OFFSET(1) SI r2, r3, OFFSET(2) SI r4, r3, OFFSET(4) SI r5, r3, OFFSET(5) SI r6, r3, OFFSET(6) SI r7, r3, OFFSET(7) SI r8, r3, OFFSET(8) SI r9, r3, OFFSET(9) SI r10, r3, OFFSET(10) SI r11, r3, OFFSET(11) SI r12, r3, OFFSET(12) SI r13, r3, OFFSET(13) SI r14, r3, OFFSET(14) SI r15, r3, OFFSET(15) SI r16, r3, OFFSET(16) SI r17, r3, OFFSET(17) SI r18, r3, OFFSET(18) SI r19, r3, OFFSET(19) SI r20, r3, OFFSET(20) SI r21, r3, OFFSET(21) SI r22, r3, OFFSET(22) SI r23, r3, OFFSET(23) SI r24, r3, OFFSET(24) SI r25, r3, OFFSET(25) SI r26, r3, OFFSET(26) SI r27, r3, OFFSET(27) SI r28, r3, OFFSET(28) SI r29, r3, OFFSET(29) SI r30, r3, OFFSET(30) SI r31, r3, OFFSET(31) / Set r3 to test pass = 0 / ADDIK r3, r0, 0 /**************************************************************************** * 1. Test register file *****************************************************************************/ L_microblaze_selftest_reg: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_regdata L_microblaze_selftest_regloop: / Load test pattern into r2, r4 - r31 / LI r2, r1, 0 LI r4, r1, 0 LI r5, r1, 0 LI r6, r1, 0 LI r7, r1, 0 LI r8, r1, 0 LI r9, r1, 0 LI r10, r1, 0 LI r11, r1, 0 LI r12, r1, 0 LI r13, r1, 0 LI r14, r1, 0 LI r15, r1, 0 LI r16, r1, 0 LI r17, r1, 0 LI r18, r1, 0 LI r19, r1, 0 LI r20, r1, 0 LI r21, r1, 0 LI r22, r1, 0 LI r23, r1, 0 LI r24, r1, 0 LI r25, r1, 0 LI r26, r1, 0 LI r27, r1, 0 LI r28, r1, 0 LI r29, r1, 0 LI r30, r1, 0 LI r31, r1, 0 / Compare registers pair by pair / CMPU r2, r2, r4 BNEID r2, L_microblaze_selftest_regerr CMPU r4, r4, r5 BNEID r4, L_microblaze_selftest_regerr CMPU r5, r5, r6 BNEID r5, L_microblaze_selftest_regerr CMPU r6, r6, r7 BNEID r6, L_microblaze_selftest_regerr CMPU r7, r7, r8 BNEID r7, L_microblaze_selftest_regerr CMPU r8, r8, r9 BNEID r8, L_microblaze_selftest_regerr CMPU r9, r9, r10 BNEID r9, L_microblaze_selftest_regerr CMPU r10, r10, r11 BNEID r10, L_microblaze_selftest_regerr CMPU r11, r11, r12 BNEID r11, L_microblaze_selftest_regerr CMPU r12, r12, r13 BNEID r12, L_microblaze_selftest_regerr CMPU r13, r13, r14 BNEID r13, L_microblaze_selftest_regerr CMPU r14, r14, r15 BNEID r14, L_microblaze_selftest_regerr CMPU r15, r15, r16 BNEID r15, L_microblaze_selftest_regerr CMPU r16, r16, r17 BNEID r16, L_microblaze_selftest_regerr CMPU r17, r17, r18 BNEID r17, L_microblaze_selftest_regerr CMPU r18, r18, r19 BNEID r18, L_microblaze_selftest_regerr CMPU r19, r19, r20 BNEID r19, L_microblaze_selftest_regerr CMPU r20, r20, r21 BNEID r20, L_microblaze_selftest_regerr CMPU r21, r21, r22 BNEID r21, L_microblaze_selftest_regerr CMPU r22, r22, r23 BNEID r22, L_microblaze_selftest_regerr CMPU r23, r23, r24 BNEID r23, L_microblaze_selftest_regerr CMPU r24, r24, r25 BNEID r24, L_microblaze_selftest_regerr CMPU r25, r25, r26 BNEID r25, L_microblaze_selftest_regerr CMPU r26, r26, r27 BNEID r26, L_microblaze_selftest_regerr CMPU r27, r27, r28 BNEID r27, L_microblaze_selftest_regerr CMPU r28, r28, r29 BNEID r28, L_microblaze_selftest_regerr CMPU r29, r29, r30 BNEID r29, L_microblaze_selftest_regerr CMPU r30, r30, r31 BEQI r30, L_microblaze_selftest_regnext L_microblaze_selftest_regerr: / Test error - set register file error (bit 0) / ori r3, r3, 1 L_microblaze_selftest_regnext: / Loop back with next test pattern - end after zero pattern / BNEID r31, L_microblaze_selftest_regloop INCR(1) /**************************************************************************** * 2. Test ALU *****************************************************************************/ L_microblaze_selftest_alu: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_aludata L_microblaze_selftest_aluloop: / Load operands into r2, r4 / LI r2, r1, OFFSET(0) LI r4, r1, OFFSET(1) / Execute all ALU arithmetic instructions / TEST_ALU_ARITH(add, lwi, 2) TEST_ALU_ARITH(addc, lwi, 4) TEST_ALU_ARITH(rsub, lwi, 6) TEST_ALU_ARITH(rsubc, lwi, 8) TEST_ALU_LOGIC(cmp, lwi, 10) / Execute all ALU logical instructions / TEST_ALU_LOGIC(and, lwi, 11) TEST_ALU_LOGIC(andn, lwi, 12) TEST_ALU_LOGIC(or, lwi, 13) TEST_ALU_LOGIC(xor, lwi, 14) nop bri L_microblaze_selftest_alunext L_microblaze_selftest_aluerr: / Test error - set ALU error (bit 1) / ori r3, r3, 2 L_microblaze_selftest_alunext: / Loop back with next test data - end after zero data / BNEID r2, L_microblaze_selftest_aluloop INCR(15) /**************************************************************************** * 3. Test shift unit *****************************************************************************/ L_microblaze_selftest_shift: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_shiftdata L_microblaze_selftest_shiftloop: / Load operand into r2 / LI r2, r1, OFFSET(0) / Test instructions clz, sext8, sext16, sra, src, srl / TEST_SHIFT(clz, lwi, 1) TEST_SHIFT(sext8, lwi, 2) TEST_SHIFT(sext16, lwi, 3) TEST_SHIFTC(sra, lwi, 4) TEST_SHIFTC(src, lwi, 6) TEST_SHIFTC(srl, lwi, 8) nop bri L_microblaze_selftest_shiftnext L_microblaze_selftest_shifterr: / Test error - set shift logic error (bit 2) / ori r3, r3, 4 L_microblaze_selftest_shiftnext: / Loop back with next test data - end after zero data / BNEID r2, L_microblaze_selftest_shiftloop INCR(10) /**************************************************************************** * 4. Test load-store *****************************************************************************/ L_microblaze_selftest_ldst: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_ldstdata / Set static address and offsets / ADDIK r4, r0, L_microblaze_selftest_ldstptr ADDIK r24, r0, 4 ADDIK r28, r0, 8 L_microblaze_selftest_ldstloop: / Load operand into r2 / LI r2, r1, OFFSET(0) / Test instructions lbu, lhu, lw, sb, sh, sw / sb r2, r4, r0 sh r2, r4, r24 sw r2, r4, r28 lbu r8, r4, r0 lhu r9, r4, r24 lw r10, r4, r28 / Compare load results / ANDI r11, r2, 0xFF ANDI r12, r2, 0xFFFF CMPU r16, r11, r8 BNEID r16, L_microblaze_selftest_ldsterr CMPU r17, r12, r9 BNEID r17, L_microblaze_selftest_ldsterr CMPU r18, r2, r10 BEQI r18, L_microblaze_selftest_ldstnext L_microblaze_selftest_ldsterr: / Test error - set load-store error (bit 3) / ori r3, r3, 8 L_microblaze_selftest_ldstnext: / Loop back with next test data - end after zero data / BNEID r2, L_microblaze_selftest_ldstloop INCR(1) /**************************************************************************** * 4. Test branch *****************************************************************************/ L_microblaze_selftest_branch: / Test instructions blt, ble, bge, bgt, br / / Untested instructions: rtbd, rtid, rted, brk / addik r2, r0, 0 / EQ / addik r4, r0, 1 / GT / addik r5, r0, -1 / LT / / Taken branches / BEQI r2, L_microblaze_selftest_brancheq ori r3, r3, 16 / Test error / L_microblaze_selftest_brancheq: BGEI r2, L_microblaze_selftest_branchge0 ori r3, r3, 16 / Test error / L_microblaze_selftest_branchge0: BGEI r4, L_microblaze_selftest_branchge1 ori r3, r3, 16 / Test error / L_microblaze_selftest_branchge1: BGTI r4, L_microblaze_selftest_branchgt ori r3, r3, 16 / Test error / L_microblaze_selftest_branchgt: BLEI r2, L_microblaze_selftest_branchle0 ori r3, r3, 16 / Test error / L_microblaze_selftest_branchle0: BLEI r5, L_microblaze_selftest_branchle1 ori r3, r3, 16 / Test error / L_microblaze_selftest_branchle1: BLTI r5, L_microblaze_selftest_branchlt ori r3, r3, 16 / Test error / L_microblaze_selftest_branchlt: BNEI r4, L_microblaze_selftest_branchne ori r3, r3, 16 / Test error / L_microblaze_selftest_branchne: / Not taken branches / BEQI r4, L_microblaze_selftest_brancherr BEQI r5, L_microblaze_selftest_brancherr BGEI r5, L_microblaze_selftest_brancherr BGTI r2, L_microblaze_selftest_brancherr BGTI r5, L_microblaze_selftest_brancherr BLEI r4, L_microblaze_selftest_brancherr BLTI r2, L_microblaze_selftest_brancherr BLTI r4, L_microblaze_selftest_brancherr BNEI r2, L_microblaze_selftest_brancherr BRI L_microblaze_selftest_branchnext L_microblaze_selftest_brancherr: / Test error - set branch error (bit 4) / ori r3, r3, 16 L_microblaze_selftest_branchnext: /**************************************************************************** * 6. Test barrel shifter *****************************************************************************/ #ifdef USE_BARREL L_microblaze_selftest_barrel: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_barreldata L_microblaze_selftest_barrelloop: / Load operands into r2, r4 / LI r2, r1, OFFSET(0) LI r4, r1, OFFSET(1) / Test instructions bsrl, bsra, bsll, bsifi, bsefi / TEST_BARREL(bsrl, lwi, 2) TEST_BARREL(bsra, lwi, 3) TEST_BARREL(bsll, lwi, 4) TEST_BARREL_IMM(bsifi, 11, 6, lwi, 5); TEST_BARREL_IMM(bsefi, 6, 1, lwi, 6); nop bri L_microblaze_selftest_barrelnext L_microblaze_selftest_barrelerr: / Test error - set barrel logic error (bit 5) / ori r3, r3, 32 L_microblaze_selftest_barrelnext: / Loop back with next test data - end after zero data / BNEID r2, L_microblaze_selftest_barrelloop INCR(7) #endif /**************************************************************************** * 7. Test multiplier *****************************************************************************/ #ifdef USE_HW_MUL L_microblaze_selftest_mul: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_muldata L_microblaze_selftest_mulloop: / Load operands into r2, r4 / lwi r2, r1, 0 lwi r4, r1, 4 / Test instruction mul / TEST_MUL(mul, lwi, 8) #ifdef USE_HW_MUL_2 / Test instructions mulh, mulhu, mulhsu / TEST_MUL(mulh, lwi, 12) TEST_MUL(mulhu, lwi, 16) TEST_MUL(mulhsu, lwi, 20) #endif nop bri L_microblaze_selftest_mulnext L_microblaze_selftest_mulerr: / Test error - set multiply error (bit 6) / ori r3, r3, 64 L_microblaze_selftest_mulnext: / Loop back with next test data - end after zero data / BNEID r2, L_microblaze_selftest_mulloop #ifdef USE_HW_MUL_2 addik r1, r1, 24 #else addik r1, r1, 12 #endif #endif /**************************************************************************** * 8. Test integer divide *****************************************************************************/ #ifdef USE_DIV L_microblaze_selftest_div: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_divdata L_microblaze_selftest_divloop: / Load operands into r2, r4 / lwi r2, r1, 0 lwi r4, r1, 4 / Test instructions idiv, idivu / TEST_DIV(idiv, lwi, 8) TEST_DIV(idivu, lwi, 12) nop bri L_microblaze_selftest_divnext L_microblaze_selftest_diverr: / Test error - set integer divide error (bit 7) / ori r3, r3, 128 L_microblaze_selftest_divnext: / Loop back with next test data - end after zero data / BNEID r4, L_microblaze_selftest_divloop addik r1, r1, 16 #endif /**************************************************************************** * 9. Test pattern compare *****************************************************************************/ #ifdef USE_PCMP_INSTR L_microblaze_selftest_pcmp: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_pcmpdata L_microblaze_selftest_pcmploop: / Load operands into r2, r4 / LI r2, r1, OFFSET(0) LI r4, r1, OFFSET(1) / Test instructions pcmpbf, pcmpeq, pcmpne / / 64-bit: add instructions pcmplbf, pcmpleq, pcmplne / TEST_PCMP(pcmpbf, lwi, 2) TEST_PCMP(pcmpeq, lwi, 3) TEST_PCMP(pcmpne, lwi, 4) nop bri L_microblaze_selftest_pcmpnext L_microblaze_selftest_pcmperr: / Test error - set pcmp logic error (bit 8) / ori r3, r3, 256 L_microblaze_selftest_pcmpnext: / Loop back with next test data - end after zero data / BNEID r2, L_microblaze_selftest_pcmploop INCR(5) #endif /**************************************************************************** * 10. Test MSR instructions *****************************************************************************/ L_microblaze_selftest_msr: #ifdef USE_MSR_INSTR / Test instructions msrclr, msrset, mfs msr / msrset r0, ~MSR_EE_IE_MASK & 0x7FFF nop mfs r6, rmsr nop msrclr r7, 0x7FF nop mfs r8, rmsr nop #endif / Test instructions mfs msr, mts msr / / Bits not included: ICE, DZO, DCE, EE, EIP, UMS, VMS / addik r9, r0, MSR_BIT_MASK & ~MSR_EE_IE_MASK mts rmsr, r9 nop mfs r10, rmsr / Compare instruction result / #ifdef USE_MSR_INSTR addik r11, r0, MSR_PVR_BIT_MASK cmpu r12, r6, r7 BNEID r12, L_microblaze_selftest_msrerr cmpu r13, r8, r11 BNEID r13, L_microblaze_selftest_msrerr #endif cmpu r14, r9, r10 BEQI r14, L_microblaze_selftest_msrnext L_microblaze_selftest_msrerr: / Test error - set MSR instruction error (bit 9) / ori r3, r3, 512 L_microblaze_selftest_msrnext: /**************************************************************************** * 11. Test reorder instructions *****************************************************************************/ #ifdef USE_REORDER_INSTR L_microblaze_selftest_reorder: / Get pointer to test data / ADDIK r1, r0, L_microblaze_selftest_reorderdata / Set static address and offsets / ADDIK r4, r0, L_microblaze_selftest_ldstptr ADDIK r24, r0, 4 ADDIK r28, r0, 8 L_microblaze_selftest_reorderloop: / Load operand into r2 / LI r2, r1, OFFSET(0) / Test instructions swapb, swaph, lbur, lhur, lwr, sbr, shr, swr / sbr r2, r4, r0 shr r2, r4, r24 swr r2, r4, r28 lbur r8, r4, r0 lhur r9, r4, r24 lwr r10, r4, r28 swapb r21, r2 swaph r22, r2 / Load swap results / LI r13, r1, OFFSET(1) LI r14, r1, OFFSET(2) / Compare load results / ANDI r11, r2, 0xFF ANDI r12, r2, 0xFFFF CMPU r16, r11, r8 BNEID r16, L_microblaze_selftest_reordererr CMPU r17, r12, r9 BNEID r17, L_microblaze_selftest_reordererr CMPU r18, r2, r10 BNEID r18, L_microblaze_selftest_reordererr CMPU r19, r21, r13 BNEID r19, L_microblaze_selftest_reordererr CMPU r20, r22, r14 BEQI r20, L_microblaze_selftest_reordernext L_microblaze_selftest_reordererr: / Test error - set reorder instruction error (bit 10) / ori r3, r3, 1024 L_microblaze_selftest_reordernext: / Loop back with next test data - end after zero data / BNEID r2, L_microblaze_selftest_reorderloop INCR(3) #endif /**************************************************************************** * Postamble *****************************************************************************/ / Restore all registers, except r3 return value and r4 temporary / ADDIK r31, r0, L_microblaze_selftest_regs LI r1, r31, OFFSET(1) LI r2, r31, OFFSET(2) LI r4, r31, OFFSET(4) LI r5, r31, OFFSET(5) LI r6, r31, OFFSET(6) LI r7, r31, OFFSET(7) LI r8, r31, OFFSET(8) LI r9, r31, OFFSET(9) LI r10, r31, OFFSET(10) LI r11, r31, OFFSET(11) LI r12, r31, OFFSET(12) LI r13, r31, OFFSET(13) LI r14, r31, OFFSET(14) LI r15, r31, OFFSET(15) LI r16, r31, OFFSET(16) LI r17, r31, OFFSET(17) LI r18, r31, OFFSET(18) LI r19, r31, OFFSET(19) LI r20, r31, OFFSET(20) LI r21, r31, OFFSET(21) LI r22, r31, OFFSET(22) LI r23, r31, OFFSET(23) LI r24, r31, OFFSET(24) LI r25, r31, OFFSET(25) LI r26, r31, OFFSET(26) LI r27, r31, OFFSET(27) LI r28, r31, OFFSET(28) LI r29, r31, OFFSET(29) LI r30, r31, OFFSET(30) LI r31, r31, OFFSET(31) / Restore MSR / lwi r4, r0, L_microblaze_selftest_regs mts rmsr, r4 / Return / rtsd r15, 8 nop L_microblaze_selftest_end: .end microblaze_selftest /**************************************************************************** * Temporary storage used by this routine * MSR followd by registers r1 - r31 ****************************************************************************/ .data .align 3 L_microblaze_selftest_regs: .rept 32 #if defined (__arch64__) .quad 0 #else .long 0 #endif .endr /*************************************************************************** * Test data used by this routine *****************************************************************************/ L_microblaze_selftest_regdata: #if defined (__arch64__) .quad 0x5555555555555555 .quad 0xAAAAAAAAAAAAAAAA .quad 0xFFFFFFFFFFFFFFFF .quad 0x0000000000000000 #else .long 0x55555555 .long 0xAAAAAAAA .long 0xFFFFFFFF .long 0x00000000 #endif L_microblaze_selftest_aludata: DATA 0x55555555 / rA operand / DATA 0x55555556 / rB operand / DATA 0xAAAAAAAB / rD result: add / DATA 0x00000000 / MSR.C: add / DATA 0xAAAAAAAB / rD result: addc / DATA 0x00000000 / MSR.C: addc / DATA 0x00000001 / rD result: rsub / DATA MSR_CARRY_MASK / MSR.C: rsub / DATA 0x00000001 / rD result: rsubc / DATA MSR_CARRY_MASK / MSR.C: rsubc / DATA 0x00000001 / rD result: cmp / DATA 0x55555554 / rD result: and / DATA 0x00000001 / rD result: andn / DATA 0x55555557 / rD result: or / DATA 0x00000003 / rD result: xor / DATA 0xAAAAAAAB / rA operand / DATA 0xAAAAAAAA / rB operand / DATA 0x55555555 / rD result: add / DATA MSR_CARRY_MASK / MSR.C: add / DATA 0x55555556 / rD result: addc / DATA MSR_CARRY_MASK / MSR.C: addc / DATA 0xFFFFFFFF / rD result: rsub / DATA 0x00000000 / MSR.C: rsub / DATA 0xFFFFFFFE / rD result: rsubc / DATA 0x00000000 / MSR.C: rsubc / DATA 0xFFFFFFFF / rD result: cmp / DATA 0xAAAAAAAA / rD result: and / DATA 0x00000001 / rD result: andn / DATA 0xAAAAAAAB / rD result: or / DATA 0x00000001 / rD result: xor / DATA 0xFFFFFFFF / rA operand / DATA 0xFFFFFFFF / rB operand / DATA 0xFFFFFFFE / rD result: add / DATA MSR_CARRY_MASK / MSR.C: add / DATA 0xFFFFFFFF / rD result: addc / DATA MSR_CARRY_MASK / MSR.C: addc / DATA 0x00000000 / rD result: rsub / DATA MSR_CARRY_MASK / MSR.C: rsub / DATA 0x00000000 / rD result: rsubc / DATA MSR_CARRY_MASK / MSR.C: rsubc / DATA 0x00000000 / rD result: cmp / DATA 0xFFFFFFFF / rD result: and / DATA 0x00000000 / rD result: andn / DATA 0xFFFFFFFF / rD result: or / DATA 0x00000000 / rD result: xor / DATA 0x00000000 / rA operand / DATA 0xFFFFFFFF / rB operand / DATA 0xFFFFFFFF / rD result: add / DATA 0x00000000 / MSR.C: add / DATA 0xFFFFFFFF / rD result: addc / DATA 0x00000000 / MSR.C: addc / DATA 0xFFFFFFFF / rD result: rsub / DATA MSR_CARRY_MASK / MSR.C: rsub / DATA 0xFFFFFFFF / rD result: rsubc / DATA MSR_CARRY_MASK / MSR.C: rsubc / DATA 0xFFFFFFFF / rD result: cmp / DATA 0x00000000 / rD result: and / DATA 0x00000000 / rD result: andn / DATA 0xFFFFFFFF / rD result: or / DATA 0xFFFFFFFF / rD result: xor / L_microblaze_selftest_shiftdata: DATA 0x55555555 / rA operand / DATA 0x00000001 / rD result: clz / DATA 0x00000055 / rD result: sext8 / DATA 0x00005555 / rD result: sext16 / DATA 0x2AAAAAAA / rD result: sra / DATA MSR_CARRY_MASK / MSR.C: sra / DATA 0xAAAAAAAA / rD result: src / DATA MSR_CARRY_MASK / MSR.C: src / DATA 0x2AAAAAAA / rD result: srl / DATA MSR_CARRY_MASK / MSR.C: src / DATA 0xAAAAAAAA / rA operand / DATA 0x00000000 / rD result: clz / DATA 0xFFFFFFAA / rD result: sext8 / DATA 0xFFFFAAAA / rD result: sext16 / DATA 0xD5555555 / rD result: sra / DATA 0x00000000 / MSR.C: sra / DATA 0x55555555 / rD result: src / DATA 0x00000000 / MSR.C: src / DATA 0x55555555 / rD result: srl / DATA 0x00000000 / MSR.C: srl / DATA 0xFFFFFFFF / rA operand / DATA 0x00000000 / rD result: clz / DATA 0xFFFFFFFF / rD result: sext8 / DATA 0xFFFFFFFF / rD result: sext16 / DATA 0xFFFFFFFF / rD result: sra / DATA MSR_CARRY_MASK / MSR.C: sra / DATA 0xFFFFFFFF / rD result: src / DATA MSR_CARRY_MASK / MSR.C: src / DATA 0x7FFFFFFF / rD result: srl / DATA MSR_CARRY_MASK / MSR.C: srl / DATA 0x00000000 / rA operand / DATA 0x00000020 / rD result: clz / DATA 0x00000000 / rD result: sext8 / DATA 0x00000000 / rD result: sext16 / DATA 0x00000000 / rD result: sra / DATA 0x00000000 / MSR.C: sra / DATA 0x00000000 / rD result: src / DATA 0x00000000 / MSR.C: src / DATA 0x00000000 / rD result: srl / DATA 0x00000000 / MSR.C: srl / L_microblaze_selftest_ldstdata: DATA 0xDEADBEEF / rD operand / DATA 0x12345678 / rD operand / DATA 0x00000000 / rD operand / L_microblaze_selftest_ldstptr: DATA 0 DATA 0 DATA 0 L_microblaze_selftest_barreldata: DATA 0x55555555 / rA operand / DATA 16 / rB operand / DATA 0x00005555 / rD result: bsrl / DATA 0x00005555 / rD result: bsra / DATA 0x55550000 / rD result: bsll / DATA 0x55540415 / rD result: bsifi / DATA 0x00000008 / rD result: bsefi / DATA 0xAAAAAAAA / rA operand / DATA 1 / rB operand / DATA 0x55555555 / rD result: bsrl / DATA 0xD5555555 / rD result: bsra / DATA 0x55555554 / rD result: bsll / DATA 0xAAAA006A / rD result: bsifi / DATA 0x00000000 / rD result: bsefi / DATA 0xFFFFFFFF / rA operand / DATA 25 / rB operand / DATA 0x0000007F / rD result: bsrl / DATA 0xFFFFFFFF / rD result: bsra / DATA 0xFE000000 / rD result: bsll / DATA 0xFFFE067F / rD result: bsifi / DATA 0x0000000C / rD result: bsefi / DATA 0x00000000 / rA operand / DATA 10 / rB operand / DATA 0x00000000 / rD result: bsrl / DATA 0x00000000 / rD result: bsra / DATA 0x00000000 / rD result: bsll / DATA 0x00000280 / rD result: bsifi / DATA 0x00000005 / rD result: bsefi / L_microblaze_selftest_muldata: .long 0x55555555 / rA operand / .long 0x55555555 / rB operand / .long 0x38E38E39 / rD result: mul / #ifdef USE_HW_MUL_2 .long 0x1C71C71C / rD result: mulh / .long 0x1C71C71C / rD result: mulhu / .long 0x1C71C71C / rD result: mulhsu / #endif .long 0xAAAAAAAA / rA operand / .long 0xAAAAAAAA / rB operand / .long 0xE38E38E4 / rD result: mul / #ifdef USE_HW_MUL_2 .long 0x1C71C71C / rD result: mulh / .long 0x71C71C70 / rD result: mulhu / .long 0xC71C71C6 / rD result: mulhsu / #endif .long 0xFFFFFFFF / rA operand / .long 0xFFFFFFFF / rB operand / .long 0x00000001 / rD result: mul / #ifdef USE_HW_MUL_2 .long 0x00000000 / rD result: mulh / .long 0xFFFFFFFE / rD result: mulhu / .long 0xFFFFFFFF / rD result: mulhsu / #endif .long 0x00000000 / rA operand / .long 0x00000000 / rB operand / .long 0x00000000 / rD result: mul / #ifdef USE_HW_MUL_2 .long 0x00000000 / rD result: mulh / .long 0x00000000 / rD result: mulhu / .long 0x00000000 / rD result: mulhsu / #endif L_microblaze_selftest_divdata: .long 0x55555555 / rA operand / .long 0x55555555 / rB operand / .long 0x00000001 / rD result: div / .long 0x00000001 / rD result: divu / .long 0xAAAAAAAA / rA operand / .long 0xAAAAAAAA / rB operand / .long 0x00000001 / rD result: div / .long 0x00000001 / rD result: divu / .long 0xFFFFFFFF / rA operand / .long 0xFFFFFFFF / rB operand / .long 0x00000001 / rD result: div / .long 0x00000001 / rD result: divu / .long 0x00000001 / rA operand / .long 0x00000000 / rB operand / .long 0x00000000 / rD result: div / .long 0x00000000 / rD result: divu / .align 3 L_microblaze_selftest_pcmpdata: DATA 0x55555555 / rA operand / DATA 0x44445555 / rB operand / DATA 0x00000003 / rD result: pcmpbf / DATA 0x00000000 / rD result: pcmpeq / DATA 0x00000001 / rD result: pcmpne / DATA 0xAAAAAAAA / rA operand / DATA 0xAAAAAAAA / rB operand / DATA 0x00000001 / rD result: pcmpbf / DATA 0x00000001 / rD result: pcmpeq / DATA 0x00000000 / rD result: pcmpne / DATA 0xFFFFFFFF / rA operand / DATA 0x000000FF / rB operand / DATA 0x00000004 / rD result: pcmpbf / DATA 0x00000000 / rD result: pcmpeq / DATA 0x00000001 / rD result: pcmpne / DATA 0x00000000 / rA operand / DATA 0xDEADBEEF / rB operand / DATA 0x00000000 / rD result: pcmpbf / DATA 0x00000000 / rD result: pcmpeq / DATA 0x00000001 / rD result: pcmpne / L_microblaze_selftest_reorderdata: DATA 0xDEADBEEF / rD operand / DATA 0xEFBEADDE / rD result: swapb / DATA 0xBEEFDEAD / rD result: swaph / DATA 0x00000000 / rD operand / DATA 0x00000000 / rD result: swapb / DATA 0x00000000 / rD result: swaph / /* * @} End of "addtogroup microblaze_pseudo_asm_macro". */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	3,488	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_invalidate_dcache_range.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * * microblaze_invalidate_dcache_range (unsigned int cacheaddr, unsigned int len) * * Invalidate a Dcache range * * Parameters: * 'cacheaddr' - address in the Dcache where invalidation begins * 'len ' - length (in bytes) worth of Dcache to be invalidated * * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #define MB_HAS_WRITEBACK_SET 0 #else #define MB_HAS_WRITEBACK_SET XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #endif .text .globl microblaze_invalidate_dcache_range .ent microblaze_invalidate_dcache_range .align 2 microblaze_invalidate_dcache_range: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) #ifdef MB_VERSION_LT_v720 / Disable Dcache and interrupts before invalidating / mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_DCACHE_ENABLE \| MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif BEQI r6, L_done / Skip loop if size is zero / ADD r6, r5, r6 / Compute end address / ADDIK r6, r6, -1 ANDI r6, r6, -(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align end down to cache line / ANDI r5, r5, -(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align start down to cache line / #if MB_HAS_WRITEBACK_SET == 0 / Use a different scheme for MB version < v7.20 or when caches are write-through / L_start: CMPU r18, r5, r6 / Are we at the end? / BLTI r18, L_done wdc r5, r0 #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* Increment the address by 4 / breai L_start / Branch to the beginning of the loop / #else brid L_start / Branch to the beginning of the loop / addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* Increment the address by 4 (delay slot) / #endif #else RSUBK r6, r5, r6 / r6 will now contain (count of bytes - (4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN)) / L_start: wdc.clear r5, r6 / Invalidate the cache line only if the address matches / #if defined (__arch64__ ) addlik r6, r6, -(XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) beagei r6, L_start #else bneid r6, L_start addik r6, r6, -(XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) #endif #endif L_done: rtsd r15, 8 #ifdef MB_VERSION_LT_v720 /* restore MSR only for MB version < v7.20 */ mts rmsr, r9 #else nop #endif #else rtsd r15, 8 nop #endif .end microblaze_invalidate_dcache_range
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,070	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_enable_icache.S	/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * File : microblaze_enable_icache.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Enable icache on the microblaze. * * *****************************************************************************/ #include "xparameters.h" .text .globl microblaze_enable_icache .ent microblaze_enable_icache .align 2 microblaze_enable_icache: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrset r0, 0x20 #else /XPAR_MICROBLAZE_USE_MSR_INSTR == 1/ #Read the MSR register mfs r8, rmsr #Set the interrupt enable bit ori r8, r8, 0x20 #Save the MSR register mts rmsr, r8 #Return rtsd r15, 8 nop #endif /XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ .end microblaze_enable_icache
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	2,198	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_init_dcache_range.S	/****************************************************************************** * Copyright (c) 2006 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * microblaze_init_dcache_range (unsigned int cache_start, unsigned int cache_len) * * Invalidate dcache on the microblaze * * Parameters: * 'cache_start' - address in the Dcache where invalidation begins * 'cache_len' - length (in bytes) worth of Dcache to be invalidated * * ******************************************************************************/ #include "xparameters.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif .text .globl microblaze_init_dcache_range .ent microblaze_init_dcache_range .align 2 microblaze_init_dcache_range: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) mfs r9, rmsr / Disable Dcache and interrupts before invalidating / andi r10, r9, (~(MICROBLAZE_MSR_DCACHE_ENABLE \| MICROBLAZE_MSR_INTR_ENABLE)) mts rmsr, r10 andi r5, r5, -(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align to cache line / add r6, r5, r6 / Compute end / andi r6, r6, -(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align to cache line / L_start: wdc r5, r0 / Invalidate the Cache (delay slot) / cmpu r18, r5, r6 / Are we at the end ? / blei r18, L_done brid L_start / Branch to the beginning of the loop / addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* Increment the address by 4 (delay slot) / L_done: rtsd r15, 8 / Return / mts rmsr, r9 #else rtsd r15, 8 / Return */ nop #endif .end microblaze_init_dcache_range
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	2,385	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_invalidate_icache.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * * microblaze_invalidate_icache() * * Invalidate the entire ICache * * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_ICACHE_ENABLE 0x00000020 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_ICACHE_LINE_LEN #define XPAR_MICROBLAZE_ICACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #endif .text .globl microblaze_invalidate_icache .ent microblaze_invalidate_icache .align 2 microblaze_invalidate_icache: #if (XPAR_MICROBLAZE_USE_ICACHE==1) && (XPAR_MICROBLAZE_ALLOW_ICACHE_WR==1) #ifdef MB_VERSION_LT_v720 / Disable Icache and interrupts before invalidating / mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_ICACHE_ENABLE \| MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif ADDIK r5, r0, XPAR_MICROBLAZE_ICACHE_BASEADDR & (-(4 XPAR_MICROBLAZE_ICACHE_LINE_LEN)) /* Align to cache line / ADDIK r6, r5, XPAR_MICROBLAZE_CACHE_BYTE_SIZE & (-(4 XPAR_MICROBLAZE_ICACHE_LINE_LEN)) /* Compute end / L_start: wic r5, r0 / Invalidate the Cache / CMPU r18, r5, r6 / Are we at the end? / BLEI r18, L_done #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN 4) /* Increment the address by 4 / breai L_start #else brid L_start / Branch to the beginning of the loop / addik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN 4) /* Increment the address by 4 (delay slot) / #endif L_done: rtsd r15, 8 / Return / #ifdef MB_VERSION_LT_v720 / restore MSR only for MB version < v7.20 / mts rmsr, r9 #else nop #endif #else rtsd r15, 8 / Return */ nop #endif .end microblaze_invalidate_icache
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,575	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_enable_interrupts.S	/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * @file microblaze_enable_interrupts.S * * @addtogroup microblaze_pseudo_asm_macro * @{ * <h2> microblaze_enable_interrupts.S </h2> * - API to Enable Interrupts: void microblaze_enable_interrupts(void) * * This API Enables interrupts on the MicroBlaze processor. When the MicroBlaze * processor starts up, interrupts are disabled. Interrupts must be explicitly * turned on using this function. * * <pre> * * File : microblaze_enable_interrupts.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Enable interrupts on the microblaze. * </pre> * *****************************************************************************/ #include "xparameters.h" .text .globl microblaze_enable_interrupts .ent microblaze_enable_interrupts .align 2 microblaze_enable_interrupts: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrset r0, 0x2 nop #else /XPAR_MICROBLAZE_USE_MSR_INSTR == 1/ #Read the MSR register mfs r12, rmsr #Set the interrupt enable bit ori r12, r12, 0x2 #Save the MSR register mts rmsr, r12 #Return rtsd r15, 8 nop #endif /XPAR_MICROBLAZE_USE_MSR_INSTR == 1/ .end microblaze_enable_interrupts /* * @} End of "addtogroup microblaze_pseudo_asm_macro". */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	3,540	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_flush_dcache_range.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * microblaze_flush_dcache_range (unsigned int cacheaddr, unsigned int len) * * Flush a L1 DCache range * * Parameters: * 'cacheaddr' - address in the Dcache where the flush begins * 'len ' - length (in bytes) worth of Dcache to be flushed * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #define MB_HAS_WRITEBACK_SET 0 #else #define MB_HAS_WRITEBACK_SET XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #endif .text .globl microblaze_flush_dcache_range .ent microblaze_flush_dcache_range .align 2 microblaze_flush_dcache_range: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) #ifdef MB_VERSION_LT_v720 / Disable Dcache and interrupts before invalidating / mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_DCACHE_ENABLE \| MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif beqi r6, L_done / Skip loop if size is zero / ADD r6, r5, r6 / Compute end address / ADDIK r6, r6, -1 ANDI r6, r6, -(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align end down to cache line / ANDI r5, r5, -(4 XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align start down to cache line / #if MB_HAS_WRITEBACK_SET == 0 / Use a different scheme for MB version < v7.20 or when caches are write-through / L_start: CMPU r18, r5, r6 / Are we at the end? / BLTI r18, L_done wdc r5, r0 / Invalidate the cache line / #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* Increment the address by 4 / breai L_start / Branch to the beginning of the loop / #else brid L_start / Branch to the beginning of the loop / addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* Increment the address by 4 (delay slot) / #endif #else RSUBK r6, r5, r6 / r6 will now contain (count of bytes - (4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN)) / L_start: wdc.flush r5, r6 / Flush the cache line / #if defined (__arch64__ ) addlik r6, r6, -(XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) beagei r6, L_start #else bneid r6, L_start addik r6, r6, -(XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) #endif #endif L_done: rtsd r15, 8 #ifdef MB_VERSION_LT_v720 /* restore MSR only for MB version < v7.20 / mts rmsr, r9 #else nop #endif #else rtsd r15, 8 / Return */ nop #endif .end microblaze_flush_dcache_range
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,555	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_disable_interrupts.S	/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * @file microblaze_disable_interrupts.S * * @addtogroup microblaze_pseudo_asm_macro * @{ * <h2> microblaze_disable_interrupts.S </h2> * - API to disable Interrupts: void microblaze_disable_interrupts(void) * * This API Disables interrupts on the MicroBlaze processor. It can be * called when entering a critical section of code where a context switch is * undesirable. * * <pre> * File : microblaze_disable_interrupts.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Disable interrupts on the microblaze. * </pre> * *****************************************************************************/ #include "xparameters.h" .text .globl microblaze_disable_interrupts .ent microblaze_disable_interrupts .align 2 microblaze_disable_interrupts: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrclr r0, 0x2 #else /XPAR_MICROBLAZE_USE_MSR_INSTR == 1/ #Read the MSR register mfs r12, rmsr #Clear the interrupt enable bit andi r12, r12, ~(0x2) #Save the MSR register mts rmsr, r12 #Return rtsd r15, 8 nop #endif /XPAR_MICROBLAZE_USE_MSR_INSTR == 1/ .end microblaze_disable_interrupts /* * @} End of "addtogroup microblaze_pseudo_asm_macro". */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	26,672	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/hw_exception_handler.S	/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * Microblaze HW Exception Handler * - Non self-modifying exception handler for the following exception conditions * - Unalignment * - Instruction bus error * - Data bus error * - Illegal instruction opcode * - Divide-by-zero * - Stack protection violation ******************************************************************************/ #include "microblaze_exceptions_g.h" #include "xparameters.h" #include "microblaze_instructions.h" / 64-bit definitions / #if defined (__arch64__) #define INTPTR_DATAITEM .quad #define REGSIZE 8 #define DATAALIGN 4 #else #define INTPTR_DATAITEM .long #define REGSIZE 4 #define DATAALIGN 2 #endif / 64-bit definitions / / Helpful Macros / #define EX_HANDLER_STACK_SIZ (REGSIZE21) #define RMSR_OFFSET (20 * REGSIZE) #define R17_OFFSET (0) #define REG_OFFSET(regnum) (REGSIZE * (regnum + 1)) #define NUM_TO_REG(num) r ## num #define R3_TO_STACK(regnum) SI r3, r1, REG_OFFSET(regnum) #define R3_FROM_STACK(regnum) LI r3, r1, REG_OFFSET(regnum) #define PUSH_REG(regnum) SI NUM_TO_REG(regnum), r1, REG_OFFSET(regnum) #define POP_REG(regnum) LI NUM_TO_REG(regnum), r1, REG_OFFSET(regnum) /* Uses r5 / #define PUSH_MSR \ mfs r5, rmsr; \ swi r5, r1, RMSR_OFFSET; #define PUSH_MSR_AND_ENABLE_EXC \ mfs r5, rmsr; \ swi r5, r1, RMSR_OFFSET; \ ori r5, r5, 0x100; / Turn ON the EE bit/ \ mts rmsr, r5; / Uses r5 / #define POP_MSR \ lwi r5, r1, RMSR_OFFSET; \ mts rmsr, r5; / Push r17 / #define PUSH_R17 SI r17, r1, R17_OFFSET / Pop r17 / #define POP_R17 LI r17, r1, R17_OFFSET #define LWREG_NOP \ BRI ex_handler_unhandled; \ nop; #define SWREG_NOP \ BRI ex_handler_unhandled; \ nop; / r3 is the source / #define R3_TO_LWREG_V(regnum) \ R3_TO_STACK (regnum); \ BRI ex_handler_done; / r3 is the source / #define R3_TO_LWREG(regnum) \ OR NUM_TO_REG (regnum), r0, r3; \ BRI ex_handler_done; / r3 is the target / #define SWREG_TO_R3_V(regnum) \ R3_FROM_STACK (regnum); \ BRI ex_sw_tail; / r3 is the target / #define SWREG_TO_R3(regnum) \ OR r3, r0, NUM_TO_REG (regnum); \ BRI ex_sw_tail; / regnum is the source / #define FP_EX_OPB_SAVE(regnum) \ SI NUM_TO_REG (regnum), r0, mb_fpex_op_b; \ nop; \ BRI handle_fp_ex_opa; / regnum is the source / #define FP_EX_OPB_SAVE_V(regnum) \ R3_FROM_STACK (regnum); \ SI r3, r0, mb_fpex_op_b; \ BRI handle_fp_ex_opa; / regnum is the source / #define FP_EX_OPA_SAVE(regnum) \ SI NUM_TO_REG (regnum), r0, mb_fpex_op_a; \ nop; \ BRI handle_fp_ex_done; / regnum is the source / #define FP_EX_OPA_SAVE_V(regnum) \ R3_FROM_STACK (regnum); \ SI r3, r0, mb_fpex_op_a; \ BRI handle_fp_ex_done; #define FP_EX_UNHANDLED \ BRI fp_ex_unhandled; \ nop; \ nop; / ESR masks / #define ESR_EXC_MASK 0x0000001F #define ESR_REG_MASK 0x000003E0 #define ESR_LW_SW_MASK 0x00000400 #define ESR_WORD_MASK 0x00000800 #define ESR_DS_MASK 0x00001000 #define ESR_LONG_MASK 0x00002000 / Extern declarations / .extern XNullHandler #ifdef MICROBLAZE_EXCEPTIONS_ENABLED / If exceptions are enabled in the processor / / * hw_exception_handler - Handler for unaligned exceptions * Exception handler notes: * - Does not handle exceptions other than unaligned exceptions * - Does not handle exceptions during load into r17, r1, r0. * - Does not handle exceptions during store from r17 (cannot be done) and r1 (slows down common case) * * Relevant register structures * * EAR - \|----\|----\|----\|----\|----\|----\|----\|----\| * - < ## 32 or 64 bit faulting address ## > * * ESR - \|----\|----\|----\|----\|----\| - \| - \|-----\|-----\| * - W S REG EXC * * * STACK FRAME STRUCTURE * --------------------- * * +-------------+ + 0 * \| r17 \| * +-------------+ + 4 (32-bit) + 8 (64-bit) * \| Args for \| * \| next func \| * +-------------+ + 8 (32-bit) + 16 (64-bit) * \| r1 \| * \| . \| * \| . \| * \| . \| * \| . \| * \| r18 \| * +-------------+ + 80 (32-bit) + 160 (64-bit) * \| MSR \| * +-------------+ + 84 (32-bit) + 168 (64-bit) * \| . \| * \| . \| / .global _hw_exception_handler .section .text .align 2 .ent _hw_exception_handler .type _hw_exception_handler, @function _hw_exception_handler: #if defined(XPAR_MICROBLAZE_USE_STACK_PROTECTION) && (XPAR_MICROBLAZE_USE_STACK_PROTECTION == 1) / Immediately halt for stack protection violation exception without using any stack / SI r3, r0, mb_sp_save_r3; / Save temporary register / mfs r3, resr; / Extract ESR[DS] / andi r3, r3, ESR_EXC_MASK; xori r3, r3, 0x7; / Check for stack protection violation / BNEI r3, ex_handler_not_sp_violation; ex_handler_sp_violation: bri 0; / Halt here if stack protection violation / ex_handler_not_sp_violation: LI r3, r0, mb_sp_save_r3; / Restore temporary register / #endif / defined(XPAR_MICROBLAZE_USE_STACK_PROTECTION) && (XPAR_MICROBLAZE_USE_STACK_PROTECTION == 1) / ADDIK r1, r1, -(EX_HANDLER_STACK_SIZ); / Create stack frame / PUSH_REG(3); PUSH_REG(4); PUSH_REG(5); PUSH_REG(6); #ifdef MICROBLAZE_CAN_HANDLE_EXCEPTIONS_IN_DELAY_SLOTS mfs r6, resr; andi r6, r6, ESR_DS_MASK; BEQI r6, ex_handler_no_ds; mfs r17, rbtr; ex_handler_no_ds: #endif PUSH_R17; PUSH_MSR_AND_ENABLE_EXC; / Exceptions enabled here. This will allow nested exceptions / mfs r3, resr; andi r5, r3, ESR_EXC_MASK; / Extract ESR[EXC] / #ifndef NO_UNALIGNED_EXCEPTIONS xori r6, r5, 1; / 00001 = Unaligned Exception / BNEI r6, handle_ex_regular; ADDIK r4, r0, MB_ExceptionVectorTable; / Check if user has registered an unaligned exception handler / #if defined (__arch64__) LI r4, r4, 16; #else LI r4, r4, 8; #endif ADDIK r6, r0, XNullHandler; / If exceptionvectortable entry is still XNullHandler, use / XOR r6, r4, r6; / the default exception handler / BEQI r6, handle_unaligned_ex ; handle_ex_regular: #endif / ! NO_UNALIGNED_EXCEPTIONS / #if defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) xori r6, r5, 6; / 00110 = FPU exception / BEQI r6, handle_fp_ex; / Go and decode the FP exception / #endif / defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) / handle_other_ex: / Handle Other exceptions here / ori r6, r0, 20; cmp r6, r5, r6; / >= 20 are exceptions we do not handle. / BLEI r6, ex_handler_unhandled; ori r6, r0, 7; cmp r6, r5, r6; / Convert MMU exception indices into an ordinal of 7 / BGTI r6, handle_other_ex_tail; ori r5, r0, 0x7; handle_other_ex_tail: PUSH_REG(7); / Save other volatiles before we make procedure calls below / PUSH_REG(8); PUSH_REG(9); PUSH_REG(10); PUSH_REG(11); PUSH_REG(12); PUSH_REG(15); PUSH_REG(18); ADDIK r4, r0, MB_ExceptionVectorTable; / Load the Exception vector table base address / ADDK r7, r5, r5; / Calculate exception vector offset = r5 * 8 (32-bit) / ADDK r7, r7, r7; ADDK r7, r7, r7; #if defined (__arch64__) ADDK r7, r7, r7; / or r5 * 16 (64-bit) / #endif ADDK r7, r7, r4; / Get pointer to exception vector / LI r5, r7, REGSIZE; / Load argument to exception handler from table / LOAD r7, r7, r0; / Load vector itself here / brald r15, r7; / Branch to handler / nop; POP_REG(7); / Restore other volatiles / POP_REG(8); POP_REG(9); POP_REG(10); POP_REG(11); POP_REG(12); POP_REG(15); POP_REG(18); BRI ex_handler_done; / Complete exception handling / #ifndef NO_UNALIGNED_EXCEPTIONS handle_unaligned_ex: andi r6, r3, ESR_REG_MASK; / Mask and extract the register operand / srl r6, r6; / r6 >> 5 / srl r6, r6; srl r6, r6; srl r6, r6; srl r6, r6; sbi r6, r0, ex_reg_op; / Store the register operand in a temporary location / mfs r4, rear; andi r6, r3, ESR_LW_SW_MASK; / Extract ESR[S] / BNEI r6, ex_sw; #if defined (__arch64__) ex_ll: andi r6, r3, ESR_LONG_MASK; / Extract ESR[L] / BEQI r6, ex_lw; lbui r5, r4, 0; / Exception address in r4 / sbi r5, r0, ex_tmp_data_loc_0; / Load a long, byte-by-byte from destination address and save it in tmp space / lbui r5, r4, 1; sbi r5, r0, ex_tmp_data_loc_1; lbui r5, r4, 2; sbi r5, r0, ex_tmp_data_loc_2; lbui r5, r4, 3; sbi r5, r0, ex_tmp_data_loc_3; lbui r5, r4, 4; sbi r5, r0, ex_tmp_data_loc_4; lbui r5, r4, 5; sbi r5, r0, ex_tmp_data_loc_5; lbui r5, r4, 6; sbi r5, r0, ex_tmp_data_loc_6; lbui r5, r4, 7; sbi r5, r0, ex_tmp_data_loc_7; lli r3, r0, ex_tmp_data_loc_0; / Get the destination register value into r3 / BRI ex_lw_tail; #endif ex_lw: andi r6, r3, ESR_WORD_MASK; / Extract ESR[W] / BEQI r6, ex_lhw; lbui r5, r4, 0; / Exception address in r4 / sbi r5, r0, ex_tmp_data_loc_0; / Load a word, byte-by-byte from destination address and save it in tmp space / lbui r5, r4, 1; sbi r5, r0, ex_tmp_data_loc_1; lbui r5, r4, 2; sbi r5, r0, ex_tmp_data_loc_2; lbui r5, r4, 3; sbi r5, r0, ex_tmp_data_loc_3; lwi r3, r0, ex_tmp_data_loc_0; / Get the destination register value into r3 / BRI ex_lw_tail; ex_lhw: lbui r5, r4, 0; / Exception address in r4 / sbi r5, r0, ex_tmp_data_loc_0; / Load a half-word, byte-by-byte from destination address and save it in tmp space / lbui r5, r4, 1; sbi r5, r0, ex_tmp_data_loc_1; lhui r3, r0, ex_tmp_data_loc_0; / Get the destination register value into r3 / ex_lw_tail: lbui r5, r0, ex_reg_op; / Get the destination register number into r5 / ADDIK r6, r0, lw_table; / Form load_word jump table offset (lw_table + (8 * regnum)) / ADDK r5, r5, r5; ADDK r5, r5, r5; ADDK r5, r5, r5; ADDK r5, r5, r6; bra r5; ex_lw_end: / Exception handling of load word, ends / ex_sw: lbui r5, r0, ex_reg_op; / Get the destination register number into r5 / ADDIK r6, r0, sw_table; / Form store_word jump table offset (sw_table + (8 * regnum)) / ADDK r5, r5, r5; ADDK r5, r5, r5; ADDK r5, r5, r5; ADDK r5, r5, r6; bra r5; ex_sw_tail: #if defined (__arch64__) ex_sl: mfs r6, resr; andi r6, r6, ESR_LONG_MASK; / Extract ESR[L] / BEQI r6, ex_not_sl; sli r3, r0, ex_tmp_data_loc_0; lbui r3, r0, ex_tmp_data_loc_0; / Store the long, byte-by-byte into destination address / sbi r3, r4, 0; lbui r3, r0, ex_tmp_data_loc_1; sbi r3, r4, 1; lbui r3, r0, ex_tmp_data_loc_2; sbi r3, r4, 2; lbui r3, r0, ex_tmp_data_loc_3; sbi r3, r4, 3; lbui r3, r0, ex_tmp_data_loc_4; sbi r3, r4, 4; lbui r3, r0, ex_tmp_data_loc_5; sbi r3, r4, 5; lbui r3, r0, ex_tmp_data_loc_6; sbi r3, r4, 6; lbui r3, r0, ex_tmp_data_loc_7; sbi r3, r4, 7; BRI ex_handler_done; ex_not_sl: #endif mfs r6, resr; andi r6, r6, ESR_WORD_MASK; / Extract ESR[W] / BEQI r6, ex_shw; swi r3, r0, ex_tmp_data_loc_0; lbui r3, r0, ex_tmp_data_loc_0; / Store the word, byte-by-byte into destination address / sbi r3, r4, 0; lbui r3, r0, ex_tmp_data_loc_1; sbi r3, r4, 1; lbui r3, r0, ex_tmp_data_loc_2; sbi r3, r4, 2; lbui r3, r0, ex_tmp_data_loc_3; sbi r3, r4, 3; BRI ex_handler_done; ex_shw: swi r3, r0, ex_tmp_data_loc_0; / Store the lower half-word, byte-by-byte into destination address / #ifdef __LITTLE_ENDIAN__ lbui r3, r0, ex_tmp_data_loc_0; #else lbui r3, r0, ex_tmp_data_loc_2; #endif sbi r3, r4, 0; #ifdef __LITTLE_ENDIAN__ lbui r3, r0, ex_tmp_data_loc_1; #else lbui r3, r0, ex_tmp_data_loc_3; #endif sbi r3, r4, 1; ex_sw_end: / Exception handling of store word, ends. / BRI ex_handler_done; #endif / !NO_UNALIGNED_EXCEPTIONS / #if defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) handle_fp_ex: ADDIK r3, r17, -4; / r17 contains (addr of exception causing FP instruction + 4) / lw r4, r0, r3; / We might find ourselves in a spot here. Unguaranteed load / handle_fp_ex_opb: ADDIK r6, r0, fp_table_opb; / Decode opB and store its value in mb_fpex_op_b / srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; andi r3, r4, 0x1F; ADDK r3, r3, r3; / Calculate (fp_table_opb + (regno * 12)) in r5 / ADDK r3, r3, r3; ADDK r5, r3, r3; ADDK r5, r5, r3; ADDK r5, r5, r6; bra r5; handle_fp_ex_opa: ADDIK r6, r0, fp_table_opa; / Decode opA and store its value in mb_fpex_op_a / srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; andi r3, r4, 0x1F; ADDK r3, r3, r3; / Calculate (fp_table_opb + (regno * 12)) in r5 / ADDK r3, r3, r3; ADDK r5, r3, r3; ADDK r5, r5, r3; ADDK r5, r5, r6; bra r5; handle_fp_ex_done: ori r5, r0, 6; / Set exception number back to 6 / BRI handle_other_ex_tail; fp_ex_unhandled: bri 0; #endif / defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) / ex_handler_done: POP_R17; POP_MSR; POP_REG(3); POP_REG(4); POP_REG(5); POP_REG(6); ADDIK r1, r1, (EX_HANDLER_STACK_SIZ); / Restore stack frame / rted r17, 0 nop ex_handler_unhandled: bri 0 / UNHANDLED. TRAP HERE / .end _hw_exception_handler #ifndef NO_UNALIGNED_EXCEPTIONS / * hw_exception_handler Jump Table * - Contains code snippets for each register that caused the unaligned exception. * - Hence exception handler is NOT self-modifying * - Separate table for load exceptions and store exceptions. * - Each table is of size: (8 * 32) = 256 bytes / .section .text .align 4 lw_table: lw_r0: R3_TO_LWREG (0); lw_r1: LWREG_NOP; lw_r2: R3_TO_LWREG (2); lw_r3: R3_TO_LWREG_V (3); lw_r4: R3_TO_LWREG_V (4); lw_r5: R3_TO_LWREG_V (5); lw_r6: R3_TO_LWREG_V (6); lw_r7: R3_TO_LWREG (7); lw_r8: R3_TO_LWREG (8); lw_r9: R3_TO_LWREG (9); lw_r10: R3_TO_LWREG (10); lw_r11: R3_TO_LWREG (11); lw_r12: R3_TO_LWREG (12); lw_r13: R3_TO_LWREG (13); lw_r14: R3_TO_LWREG (14); lw_r15: R3_TO_LWREG (15); lw_r16: R3_TO_LWREG (16); lw_r17: LWREG_NOP; lw_r18: R3_TO_LWREG (18); lw_r19: R3_TO_LWREG (19); lw_r20: R3_TO_LWREG (20); lw_r21: R3_TO_LWREG (21); lw_r22: R3_TO_LWREG (22); lw_r23: R3_TO_LWREG (23); lw_r24: R3_TO_LWREG (24); lw_r25: R3_TO_LWREG (25); lw_r26: R3_TO_LWREG (26); lw_r27: R3_TO_LWREG (27); lw_r28: R3_TO_LWREG (28); lw_r29: R3_TO_LWREG (29); lw_r30: R3_TO_LWREG (30); lw_r31: R3_TO_LWREG (31); sw_table: sw_r0: SWREG_TO_R3 (0); sw_r1: SWREG_NOP; sw_r2: SWREG_TO_R3 (2); sw_r3: SWREG_TO_R3_V (3); sw_r4: SWREG_TO_R3_V (4); sw_r5: SWREG_TO_R3_V (5); sw_r6: SWREG_TO_R3_V (6); sw_r7: SWREG_TO_R3 (7); sw_r8: SWREG_TO_R3 (8); sw_r9: SWREG_TO_R3 (9); sw_r10: SWREG_TO_R3 (10); sw_r11: SWREG_TO_R3 (11); sw_r12: SWREG_TO_R3 (12); sw_r13: SWREG_TO_R3 (13); sw_r14: SWREG_TO_R3 (14); sw_r15: SWREG_TO_R3 (15); sw_r16: SWREG_TO_R3 (16); sw_r17: SWREG_NOP; sw_r18: SWREG_TO_R3 (18); sw_r19: SWREG_TO_R3 (19); sw_r20: SWREG_TO_R3 (20); sw_r21: SWREG_TO_R3 (21); sw_r22: SWREG_TO_R3 (22); sw_r23: SWREG_TO_R3 (23); sw_r24: SWREG_TO_R3 (24); sw_r25: SWREG_TO_R3 (25); sw_r26: SWREG_TO_R3 (26); sw_r27: SWREG_TO_R3 (27); sw_r28: SWREG_TO_R3 (28); sw_r29: SWREG_TO_R3 (29); sw_r30: SWREG_TO_R3 (30); sw_r31: SWREG_TO_R3 (31); / Temporary data structures used in the handler / .section .data .align DATAALIGN ex_tmp_data_loc_0: .byte 0 ex_tmp_data_loc_1: .byte 0 ex_tmp_data_loc_2: .byte 0 ex_tmp_data_loc_3: .byte 0 #if defined (__arch64__) ex_tmp_data_loc_4: .byte 0 ex_tmp_data_loc_5: .byte 0 ex_tmp_data_loc_6: .byte 0 ex_tmp_data_loc_7: .byte 0 #endif ex_reg_op: .byte 0 #endif / ! NO_UNALIGNED_EXCEPTIONS / #if defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) / * FP exception decode jump table. * - Contains code snippets for each register that could have been a source operand for an excepting FP instruction * - Hence exception handler is NOT self-modifying * - Separate table for opA and opB * - Each table is of size: (12 * 32) = 384 bytes / .section .text .align 4 fp_table_opa: opa_r0: FP_EX_OPA_SAVE (0); opa_r1: FP_EX_UNHANDLED; opa_r2: FP_EX_OPA_SAVE (2); opa_r3: FP_EX_OPA_SAVE_V (3); opa_r4: FP_EX_OPA_SAVE_V (4); opa_r5: FP_EX_OPA_SAVE_V (5); opa_r6: FP_EX_OPA_SAVE_V (6); opa_r7: FP_EX_OPA_SAVE (7); opa_r8: FP_EX_OPA_SAVE (8); opa_r9: FP_EX_OPA_SAVE (9); opa_r10: FP_EX_OPA_SAVE (10); opa_r11: FP_EX_OPA_SAVE (11); opa_r12: FP_EX_OPA_SAVE (12); opa_r13: FP_EX_OPA_SAVE (13); opa_r14: FP_EX_UNHANDLED; opa_r15: FP_EX_UNHANDLED; opa_r16: FP_EX_UNHANDLED; opa_r17: FP_EX_UNHANDLED; opa_r18: FP_EX_OPA_SAVE (18); opa_r19: FP_EX_OPA_SAVE (19); opa_r20: FP_EX_OPA_SAVE (20); opa_r21: FP_EX_OPA_SAVE (21); opa_r22: FP_EX_OPA_SAVE (22); opa_r23: FP_EX_OPA_SAVE (23); opa_r24: FP_EX_OPA_SAVE (24); opa_r25: FP_EX_OPA_SAVE (25); opa_r26: FP_EX_OPA_SAVE (26); opa_r27: FP_EX_OPA_SAVE (27); opa_r28: FP_EX_OPA_SAVE (28); opa_r29: FP_EX_OPA_SAVE (29); opa_r30: FP_EX_OPA_SAVE (30); opa_r31: FP_EX_OPA_SAVE (31); fp_table_opb: opb_r0: FP_EX_OPB_SAVE (0); opb_r1: FP_EX_UNHANDLED; opb_r2: FP_EX_OPB_SAVE (2); opb_r3: FP_EX_OPB_SAVE_V (3); opb_r4: FP_EX_OPB_SAVE_V (4); opb_r5: FP_EX_OPB_SAVE_V (5); opb_r6: FP_EX_OPB_SAVE_V (6); opb_r7: FP_EX_OPB_SAVE (7); opb_r8: FP_EX_OPB_SAVE (8); opb_r9: FP_EX_OPB_SAVE (9); opb_r10: FP_EX_OPB_SAVE (10); opb_r11: FP_EX_OPB_SAVE (11); opb_r12: FP_EX_OPB_SAVE (12); opb_r13: FP_EX_OPB_SAVE (13); opb_r14: FP_EX_UNHANDLED; opb_r15: FP_EX_UNHANDLED; opb_r16: FP_EX_UNHANDLED; opb_r17: FP_EX_UNHANDLED; opb_r18: FP_EX_OPB_SAVE (18); opb_r19: FP_EX_OPB_SAVE (19); opb_r20: FP_EX_OPB_SAVE (20); opb_r21: FP_EX_OPB_SAVE (21); opb_r22: FP_EX_OPB_SAVE (22); opb_r23: FP_EX_OPB_SAVE (23); opb_r24: FP_EX_OPB_SAVE (24); opb_r25: FP_EX_OPB_SAVE (25); opb_r26: FP_EX_OPB_SAVE (26); opb_r27: FP_EX_OPB_SAVE (27); opb_r28: FP_EX_OPB_SAVE (28); opb_r29: FP_EX_OPB_SAVE (29); opb_r30: FP_EX_OPB_SAVE (30); opb_r31: FP_EX_OPB_SAVE (31); #endif / defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) / #if defined(MICROBLAZE_FP_EXCEPTION_ENABLED) && defined(MICROBLAZE_FP_EXCEPTION_DECODE) / This is where we store the opA and opB of the last excepting FP instruction / .section .data .align DATAALIGN .global mb_fpex_op_a .global mb_fpex_op_b mb_fpex_op_a: INTPTR_DATAITEM 0 mb_fpex_op_b: INTPTR_DATAITEM 0 #endif / defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) / #if defined(XPAR_MICROBLAZE_USE_STACK_PROTECTION) && (XPAR_MICROBLAZE_USE_STACK_PROTECTION == 1) / This is where we store the register used to check which exception occurred / .section .data .align DATAALIGN mb_sp_save_r3: INTPTR_DATAITEM 0 #endif / defined(XPAR_MICROBLAZE_USE_STACK_PROTECTION) && (XPAR_MICROBLAZE_USE_STACK_PROTECTION == 1) / / The exception vector table / .section .data .align DATAALIGN .global MB_ExceptionVectorTable MB_ExceptionVectorTable: INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 0 / -- FSL Exception -- / INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 1 / -- Unaligned Access Exception -- / INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 2 / -- Illegal Opcode Exception -- / INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 3 / -- Instruction Bus Exception -- / INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 4 / -- Data Bus Exception -- / INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 5 / -- Div-by-0 Exception -- / INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 6 / -- FPU Exception -- / INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 7 / -- MMU Exceptions -- / #else / Dummy exception handler, in case exceptions are not present in the processor / .global _hw_exception_handler .section .text .align 2 .ent _hw_exception_handler _hw_exception_handler: bri 0; .end _hw_exception_handler #endif / MICROBLAZE_EXCEPTIONS_ENABLED */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	2,550	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_update_dcache.S	/****************************************************************************** * Copyright (c) 2006 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * * File : microblaze_update_dcache.s * Date : 2003, September 24 * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Update dcache on the microblaze. * Takes in three parameters * r5 : Cache Tag Line * r6 : Cache Data * r7 : Lock/Valid information * Bit 30 is Lock [ 1 indicates locked ] * Bit 31 is Valid [ 1 indicates valid ] * * -------------------------------------------------------------- * \| Lock \| Valid \| Effect * -------------------------------------------------------------- * \| 0 \| 0 \| Invalidate Cache * \| 0 \| 1 \| Valid, but unlocked cacheline * \| 1 \| 0 \| Invalidate Cache, No effect of lock * \| 1 \| 1 \| Valid cache. Locked to a * \| \| \| particular address * -------------------------------------------------------------- * * *********************************************************************************/ #include "xparameters.h" #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif .text .globl microblaze_update_dcache .ent microblaze_update_dcache .align 2 microblaze_update_dcache: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) #if XPAR_MICROBLAZE_DCACHE_LINE_LEN == 1 / Read the MSR register into a temp register / mfs r18, rmsr / Clear the dcache enable bit to disable the cache Register r10,r18 are volatile registers and hence do not need to be saved before use / andi r10, r18, ~128 mts rmsr, r10 / Update the lock and valid info / andi r5, r5, 0xfffffffc or r5, r5, r7 / Update dcache / wdc r5, r6 / Return / rtsd r15, 8 mts rmsr, r18 #else / The only valid usage of this routine for larger cache line lengths is to invalidate a data cache line So call microblaze_init_dcache_range appropriately to do the job / brid microblaze_init_dcache_range addik r6, r0, (XPAR_MICROBLAZE_DCACHE_LINE_LEN 4) /* We don't have a return instruction here. This is tail call optimization :) / #endif / XPAR_MICROBLAZE_DCACHE_LINE_LEN == 1 */ #else rtsd r15, 8 nop #endif .end microblaze_update_dcache
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,044	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_disable_icache.S	/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * File : microblaze_disable_icache.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Disable L1 icache on the microblaze. * * *****************************************************************************/ #include "xparameters.h" .text .globl microblaze_disable_icache .ent microblaze_disable_icache .align 2 microblaze_disable_icache: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrclr r0, 0x20 #else /XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ #Read the MSR register mfs r8, rmsr #Clear the icache enable bit andi r8, r8, ~(0x20) #Save the MSR register mts rmsr, r8 #Return rtsd r15, 8 nop #endif .end microblaze_disable_icache
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,676	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_disable_dcache.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * File : microblaze_disable_dcache.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Disable the L1 dcache on the microblaze. * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" .text .globl microblaze_disable_dcache .ent microblaze_disable_dcache .align 2 microblaze_disable_dcache: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 #if XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 ADDIK r1, r1, -8 SI r15, r1, 0 BRLID r15, microblaze_flush_dcache / microblaze_flush_dcache does not use r1/ nop LI r15, r1, 0 ADDIK r1, r1, 8 #endif / XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 / rtsd r15, 8 msrclr r0, 0x80 #else / XPAR_MICROBLAZE_USE_MSR_INSTR == 1 / ADDIK r1, r1, -8 #if XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 SI r15, r1, 0 BRLID r15, microblaze_flush_dcache nop #endif / XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 / mfs r11, rmsr andi r11, r11, ~(0x80) mts rmsr, r11 #if XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 LI r15, r1, 0 #endif / XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 / ADDIK r1, r1, 8 rtsd r15, 8 nop #endif /XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ .end microblaze_disable_dcache
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,428	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_invalidate_cache_ext.S	/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /**************************************************************************** * * microblaze_invalidate_cache_ext() * Invalidate the entire L2 Cache * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN 16 #define CACHEABLE_REGION_SIZE (XPAR_MICROBLAZE_DCACHE_HIGHADDR - XPAR_MICROBLAZE_DCACHE_BASEADDR) .text .globl microblaze_invalidate_cache_ext .ent microblaze_invalidate_cache_ext .align 2 microblaze_invalidate_cache_ext: #if ((XPAR_MICROBLAZE_INTERCONNECT==3) && (XPAR_MICROBLAZE_USE_DCACHE==1)) ADDIK r5, r0, XPAR_MICROBLAZE_DCACHE_BASEADDR & (-(4 XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN)) ADDIK r6, r0, CACHEABLE_REGION_SIZE-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) ANDI r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) Loop_start: wdc.ext.clear r5, r6 #if defined (__arch64__ ) addlik r6, r6,-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) beagei r6, Loop_start #else bgtid r6,Loop_start addik r6, r6,-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) #endif #endif rtsd r15, 8 nop .end microblaze_invalidate_cache_ext
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	8,201	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/armclang/asm_vectors.S	;/****************************************************************************** ;* Copyright (c) 2019 - 2021 Xilinx, Inc. All rights reserved. ;* SPDX-License-Identifier: MIT ;****************************************************************************/ ;/*************************************************************************/ ;/ ;* @file asm_vectors.S ;* ;* This file contains the initial vector table for the Cortex A53 processor ;* ;* <pre> ;* MODIFICATION HISTORY: ;* ;* Ver Who Date Changes ;* ----- ------- -------- --------------------------------------------------- ;* 7.0 cjp 02/26/19 First release ;* 7.7 asa 03/22/22 Updated FIQ handler to handle floating/SIMD context. ;* </pre> ;* ;* @note ;* ;* None. ;* ;******************************************************************************/ #include "bspconfig.h" EXPORT _vector_table EXPORT FPUStatus IMPORT _boot IMPORT FIQInterrupt IMPORT IRQInterrupt IMPORT SErrorInterrupt IMPORT SynchronousInterrupt ; ; FPUContextSize is the size of the array where floating point registers are ; stored when required. The default size corresponds to the case when there is ; no nested interrupt. If there are nested interrupts in application which are ; using floating point operation, the size of FPUContextSize need to be ; increased as per requirement ; FPUContextSize EQU 528 MACRO saveregister stp X0, X1, [sp,#-0x10]! stp X2, X3, [sp,#-0x10]! stp X4, X5, [sp,#-0x10]! stp X6, X7, [sp,#-0x10]! stp X8, X9, [sp,#-0x10]! stp X10, X11, [sp,#-0x10]! stp X12, X13, [sp,#-0x10]! stp X14, X15, [sp,#-0x10]! stp X16, X17, [sp,#-0x10]! stp X18, X19, [sp,#-0x10]! stp X29, X30, [sp,#-0x10]! MEND MACRO restoreregister ldp X29, X30, [sp], #0x10 ldp X18, X19, [sp], #0x10 ldp X16, X17, [sp], #0x10 ldp X14, X15, [sp], #0x10 ldp X12, X13, [sp], #0x10 ldp X10, X11, [sp], #0x10 ldp X8, X9, [sp], #0x10 ldp X6, X7, [sp], #0x10 ldp X4, X5, [sp], #0x10 ldp X2, X3, [sp], #0x10 ldp X0, X1, [sp], #0x10 MEND MACRO savefloatregister ldr x1, =FPUContextBase ; Load the floating point context array address from FPUContextBase ldr x0, [x1] stp q0, q1, [x0], #0x20 ; Save all the floating point register to the array stp q2, q3, [x0], #0x20 stp q4, q5, [x0], #0x20 stp q6, q7, [x0], #0x20 stp q8, q9, [x0], #0x20 stp q10, q11, [x0], #0x20 stp q12, q13, [x0], #0x20 stp q14, q15, [x0], #0x20 stp q16, q17, [x0], #0x20 stp q18, q19, [x0], #0x20 stp q20, q21, [x0], #0x20 stp q22, q23, [x0], #0x20 stp q24, q25, [x0], #0x20 stp q26, q27, [x0], #0x20 stp q28, q29, [x0], #0x20 stp q30, q31, [x0], #0x20 mrs x2, FPCR mrs x3, FPSR stp x2, x3, [x0], #0x10 str x0, [x1] ; Save current address of floating point context array to FPUContextBase MEND MACRO restorefloatregister ldr x1, =FPUContextBase ; Restore the address of floating point context array from FPUContextBase ldr x0, [x1] ldp x2, x3, [x0,#-0x10]! ; Restore all the floating point register from the array msr FPCR, x2 msr FPSR, x3 ldp q30, q31, [x0,#-0x20]! ldp q28, q29, [x0,#-0x20]! ldp q26, q27, [x0,#-0x20]! ldp q24, q25, [x0,#-0x20]! ldp q22, q23, [x0,#-0x20]! ldp q20, q21, [x0,#-0x20]! ldp q18, q19, [x0,#-0x20]! ldp q16, q17, [x0,#-0x20]! ldp q14, q15, [x0,#-0x20]! ldp q12, q13, [x0,#-0x20]! ldp q10, q11, [x0,#-0x20]! ldp q8, q9, [x0,#-0x20]! ldp q6, q7, [x0,#-0x20]! ldp q4, q5, [x0,#-0x20]! ldp q2, q3, [x0,#-0x20]! ldp q0, q1, [x0,#-0x20]! str x0, [x1] ; Save current address of floating point context array to FPUContextBase MEND AREA \|.vectors\|, CODE REQUIRE8 {TRUE} PRESERVE8 {TRUE} ENTRY ; Define this as an entry point _vector_table ; ; If application is built for XEN GUEST as EL1 Non-secure following image ; header is required by XEN. ; #if (HYP_GUEST == 1) ldr x16, =_boot ; Valid Image header br x16 ; HW reset vector DCD 0 ; Text offset DCD 0 ; Image size DCD 8 ; Flags DCD 0 ; RES0 DCD 0 DCD 0 DCD 0x644d5241 ; Magic DCD 0 ; RES0 #endif B _boot ALIGN 512 B SynchronousInterruptHandler ALIGN 128 B IRQInterruptHandler ALIGN 128 B FIQInterruptHandler ALIGN 128 B SErrorInterruptHandler SynchronousInterruptHandler saveregister ; Check if the Synchronous abort is occurred due to floating point access #if (EL3 == 1) mrs x0, ESR_EL3 #else mrs x0, ESR_EL1 #endif and x0, x0, #(0x3F << 26) mov x1, #(0x7 << 26) cmp x0, x1 ; ; If exception is not due to floating point access go to synchronous ; handler ; bne synchronoushandler ; ; If exception occurred due to floating point access, Enable the floating point ; access i.e. do not trap floating point instruction ; #if (EL3 == 1) mrs x1, CPTR_EL3 mov x2, #(0x1<<10) bic x1, x1, x2 msr CPTR_EL3, x1 #else mrs x1, CPACR_EL1 orr x1, x1, #(0x1<<20) msr CPACR_EL1, x1 #endif isb ; ; If the floating point access was previously enabled, store FPU context ; registers(storefloat) ; ldr x0, =FPUStatus ldrb w1, [x0] cbnz w1, storefloat ; ; If the floating point access was not enabled previously, save the status of ; floating point accessibility i.e. enabled and store floating point context ; array address(FPUContext) to FPUContextBase ; mov w1, #0x1 strb w1, [x0] ldr x0, =FPUContext ldr x1, =FPUContextBase str x0, [x1] b restorecontext storefloat savefloatregister b restorecontext synchronoushandler bl SynchronousInterrupt restorecontext restoreregister eret IRQInterruptHandler saveregister ; Save the status of SPSR, ELR and CPTR to stack #if (EL3 == 1) mrs x0, CPTR_EL3 mrs x1, ELR_EL3 mrs x2, SPSR_EL3 #else mrs x0, CPACR_EL1 mrs x1, ELR_EL1 mrs x2, SPSR_EL1 #endif stp x0, x1, [sp,#-0x10]! str x2, [sp,#-0x10]! ; Trap floating point access #if (EL3 == 1) mrs x1, CPTR_EL3 orr x1, x1, #(0x1<<10) msr CPTR_EL3, x1 #else mrs x1, CPACR_EL1 mov x2, #(0x1<<20) bic x1, x1, x2 msr CPACR_EL1, x1 #endif isb bl IRQInterrupt ; ; If floating point access is enabled during interrupt handling, restore ; floating point registers ; #if (EL3 == 1) mrs x0, CPTR_EL3 ands x0, x0, #(0x1<<10) bne RestorePrevState #else mrs x0, CPACR_EL1 ands x0, x0, #(0x1<<20) beq RestorePrevState #endif restorefloatregister ; Restore the status of SPSR, ELR and CPTR from stack RestorePrevState ldr x2, [sp], #0x10 ldp x0, x1, [sp],#0x10 #if (EL3 == 1) msr CPTR_EL3, x0 msr ELR_EL3, x1 msr SPSR_EL3, x2 #else msr CPACR_EL1, x0 msr ELR_EL1, x1 msr SPSR_EL1, x2 #endif restoreregister eret FIQInterruptHandler saveregister ; Save the status of SPSR, ELR and CPTR to stack #if (EL3 == 1) mrs x0, CPTR_EL3 mrs x1, ELR_EL3 mrs x2, SPSR_EL3 #else mrs x0, CPACR_EL1 mrs x1, ELR_EL1 mrs x2, SPSR_EL1 #endif stp x0, x1, [sp,#-0x10]! str x2, [sp,#-0x10]! ; Trap floating point access #if (EL3 == 1) mrs x1, CPTR_EL3 orr x1, x1, #(0x1<<10) msr CPTR_EL3, x1 #else mrs x1, CPACR_EL1 mov x2, #(0x1<<20) bic x1, x1, x2 msr CPACR_EL1, x1 #endif isb bl FIQInterrupt ; ; If floating point access is enabled during interrupt handling, restore ; floating point registers ; #if (EL3 == 1) mrs x0, CPTR_EL3 ands x0, x0, #(0x1<<10) bne RestorePrevStateFiq #else mrs x0, CPACR_EL1 ands x0, x0, #(0x1<<20) beq RestorePrevStateFiq #endif restorefloatregister ; Restore the status of SPSR, ELR and CPTR from stack RestorePrevStateFiq ldr x2, [sp], #0x10 ldp x0, x1, [sp],#0x10 #if (EL3 == 1) msr CPTR_EL3, x0 msr ELR_EL3, x1 msr SPSR_EL3, x2 #else msr CPACR_EL1, x0 msr ELR_EL1, x1 msr SPSR_EL1, x2 #endif restoreregister eret SErrorInterruptHandler saveregister bl SErrorInterrupt restoreregister eret ALIGN 8 ; Array to store floating point registers FPUContext SPACE FPUContextSize ; Stores address for floating point context array FPUContextBase SPACE 8 FPUStatus SPACE 4 END
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	11,341	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/armclang/boot.S	;/****************************************************************************** ;* Copyright (c) 2019 - 2021 Xilinx, Inc. All rights reserved. ;* SPDX-License-Identifier: MIT ;****************************************************************************/ ;/*************************************************************************/ ;/ ;* @file boot.S ;* ;* @addtogroup a53_64_boot_code Cortex A53 64bit Processor Boot Code ;* @{ ;* <h2> boot.S </h2> ;* ;* The boot code performs minimum configuration which is required for an ;* application. Cortex-A53 starts by checking current exception level. If the ;* current exception level is EL3 and BSP is built for EL3, it will do ;* initialization required for application execution at EL3. Below is a ;* sequence illustrating what all configuration is performed before control ;* reaches to main function for EL3 execution. ;* ;* 1. Program vector table base for exception handling ;* 2. Set reset vector table base address ;* 3. Program stack pointer for EL3 ;* 4. Routing of interrupts to EL3 ;* 5. Enable ECC protection ;* 6. Program generic counter frequency ;* 7. Invalidate instruction cache, data cache and TLBs ;* 8. Configure MMU registers and program base address of translation table ;* 9. Transfer control to _start which clears BSS sections and runs global ;* constructor before jumping to main application ;* ;* If current exception level is EL1 and BSP is also built for EL1_NONSECURE ;* it will perform initialization required for application execution at EL1 ;* non-secure. For all other combination, the execution will go into infinite ;* loop. Below is a sequence illustrating what all configuration is performed ;* before control reaches to main function for EL1 execution. ;* ;* 1. Program vector table base for exception handling ;* 2. Program stack pointer for EL1 ;* 3. Invalidate instruction cache, data cache and TLBs ;* 4. Configure MMU registers and program base address of translation table ;* 5. Transfer control to _start which clears BSS sections and runs global ;* constructor before jumping to main application ;* ;* <pre> ;* MODIFICATION HISTORY: ;* ;* Ver Who Date Changes ;* ----- ------- -------- --------------------------------------------------- ;* 7.0 mus 02/26/19 First release ;* 7.2 mus 01/08/19 Added support for versal ;* sd 02/23/20 Clock Init is called ;* sd 03/21/20 Added XCLOCKING flag ;* </pre> ;*****************************************************************************/ #include "xparameters.h" #include "bspconfig.h" #include "xil_errata.h" EXPORT _prestart EXPORT _boot IMPORT MMUTableL0 IMPORT \|Image$$ARM_LIB_STACK$$ZI$$Base\| IMPORT _vector_table IMPORT __main #ifdef XCLOCKING IMPORT Xil_ClockInit #endif #ifndef FREERTOS_BSP IMPORT FPUStatus #endif rvbar_base EQU 0xFD5C0040 MODE_EL1 EQU 0x5 DAIF_BIT EQU 0x1C0 TT_S1_FAULT EQU 0x0 TT_S1_TABLE EQU 0x3 AREA \|.boot\|, CODE ; This initializes the various processor modes _prestart _boot mov x0, #0 mov x1, #0 mov x2, #0 mov x3, #0 mov x4, #0 mov x5, #0 mov x6, #0 mov x7, #0 mov x8, #0 mov x9, #0 mov x10, #0 mov x11, #0 mov x12, #0 mov x13, #0 mov x14, #0 mov x15, #0 mov x16, #0 mov x17, #0 mov x18, #0 mov x19, #0 mov x20, #0 mov x21, #0 mov x22, #0 mov x23, #0 mov x24, #0 mov x25, #0 mov x26, #0 mov x27, #0 mov x28, #0 mov x29, #0 mov x30, #0 OKToRun mrs x0, currentEL cmp x0, #0xC beq InitEL3 cmp x0, #0x4 beq InitEL1 b error ; Go to error if current exception level is neither EL3 nor EL1 InitEL3 #if (EL3 == 1) ldr x1, =_vector_table ; Set vector table base address msr VBAR_EL3, x1 mrs x0, MPIDR_EL1 ; Get the CPU ID and x0, x0, #0xFF mov w0, w0 ldr w2, =rvbar_base ; Calculate the rvbar base address for particular CPU core mov w3, #0x8 mul w0, w0, w3 add w2, w2, w0 str x1, [x2] ; Store vector base address to rvbar ldr x2, =\|Image$$ARM_LIB_STACK$$ZI$$Base\| ; Define stack pointer for current exception level mov sp, x2 mov x0, #0 ; Enable Trapping of SIMD/FPU register for standalone BSP #ifndef FREERTOS_BSP orr x0, x0, #(0x1 << 10) #endif msr CPTR_EL3, x0 isb ; ; Clear FPUStatus variable to make sure that it contains current ; status of FPU i.e. disabled. In case of a warm restart execution ; when bss sections are not cleared, it may contain previously updated ; value which does not hold true now ; #ifndef FREERTOS_BSP ldr x0, =FPUStatus str xzr, [x0] #endif ; Configure SCR_EL3 mov w1, #0 ; Initial value of register is unknown orr w1, w1, #(1 << 11) ; Set ST bit (Secure EL1 can access CNTPS_TVAL_EL1, CNTPS_CTL_EL1 & CNTPS_CVAL_EL1) orr w1, w1, #(1 << 10) ; Set RW bit (EL1 is AArch64, as this is the Secure world) orr w1, w1, #(1 << 3) ; Set EA bit (SError routed to EL3) orr w1, w1, #(1 << 2) ; Set FIQ bit (FIQs routed to EL3) orr w1, w1, #(1 << 1) ; Set IRQ bit (IRQs routed to EL3) msr SCR_EL3, x1 ; Configure cpu auxiliary control register EL1 ldr x0, =0x80CA000 ; L1 Data prefetch control - 5, Enable device split throttle, 2 independent data prefetch streams #if (CONFIG_ARM_ERRATA_855873) ; ; Set ENDCCASCI bit in CPUACTLR_EL1 register, to execute data ; cache clean operations as data cache clean and invalidate ; orr x0, x0, #(1 << 44) ; Set ENDCCASCI bit #endif msr S3_1_C15_C2_0, x0 ; CPUACTLR_EL1 ; Program the counter frequency #if defined (versal) ldr x0, =XPAR_CPU_CORTEXA72_0_TIMESTAMP_CLK_FREQ #else ldr x0, =XPAR_CPU_CORTEXA53_0_TIMESTAMP_CLK_FREQ msr CNTFRQ_EL0, x0 #endif ; Enable hardware coherency between cores mrs x0, S3_1_c15_c2_1 ; Read EL1 CPU Extended Control Register orr x0, x0, #(1 << 6) ; Set the SMPEN bit msr S3_1_c15_c2_1, x0 ; Write EL1 CPU Extended Control Register isb tlbi ALLE3 ic IALLU ; Invalidate I cache to PoU bl invalidate_dcaches dsb sy isb ldr x1, =MMUTableL0 ; Get address of level 0 for TTBR0_EL3 msr TTBR0_EL3, x1 ; Set TTBR0_EL3 ; ; Set up memory attributes ; This equates to: ; 0 = b01000100 = Normal, Inner/Outer Non-Cacheable ; 1 = b11111111 = Normal, Inner/Outer WB/WA/RA ; 2 = b00000000 = Device-nGnRnE ; 3 = b00000100 = Device-nGnRE ; 4 = b10111011 = Normal, Inner/Outer WT/WA/RA ; ldr x1, =0x000000BB0400FF44 msr MAIR_EL3, x1 #if defined (versal) ; Set up TCR_EL3 ; Physical Address Size PS = 100 -> 44bits 16 TB ; Granual Size TG0 = 00 -> 4KB ; size offset of the memory region T0SZ = 20 -> (region size 2^(64-20) = 2^44) ldr x1,=0x80843514 #else ; ; Set up TCR_EL3 ; Physical Address Size PS = 010 -> 40bits 1TB ; Granule Size TG0 = 00 -> 4KB ; Size offset of the memory region T0SZ = 24 -> (region size 2^(64-24) = 2^40) ; ldr x1, =0x80823518 #endif msr TCR_EL3, x1 isb ; Enable SError Exception for asynchronous abort mrs x1, DAIF mov x2, #(0x1<<8) bic x1, x1, x2 msr DAIF, x1 ; Configure SCTLR_EL3 mov x1, #0 ; Most of the SCTLR_EL3 bits are unknown at reset orr x1, x1, #(1 << 12) ; Enable I cache orr x1, x1, #(1 << 3) ; Enable SP alignment check orr x1, x1, #(1 << 2) ; Enable caches orr x1, x1, #(1 << 0) ; Enable MMU msr SCTLR_EL3, x1 dsb sy isb #ifdef XCLOCKING b Xil_Clockinit #endif b __main ; Jump to start #else b error ; Present exception level and selected exception level mismatch #endif InitEL1 #if (EL1_NONSECURE == 1) ldr x1, =_vector_table ; Set vector table base address msr VBAR_EL1, x1 mrs x0, CPACR_EL1 mov x2, #(0x3 << 0x20) bic x0, x0, x2 msr CPACR_EL1, x0 isb ; ; Clear FPUStatus variable to make sure that it contains current ; status of FPU i.e. disabled. In case of a warm restart execution ; when bss sections are not cleared, it may contain previously updated ; value which does not hold true now ; #ifndef FREERTOS_BSP ldr x0, =FPUStatus str xzr, [x0] #endif ldr x2, =\|Image$$ARM_LIB_STACK$$ZI$$Base\| ; Define stack pointer for current exception level mov sp, x2 ; Disable MMU mov x1, #0x0 msr SCTLR_EL1, x1 isb TLBI VMALLE1 ic IALLU ; Invalidate I cache to PoU bl invalidate_dcaches dsb sy isb ldr x1, =MMUTableL0 ; Get address of level 0 for TTBR0_EL1 msr TTBR0_EL1, x1 ; Set TTBR0_EL1 ; ; Set up memory attributes ; This equates to: ; 0 = b01000100 = Normal, Inner/Outer Non-Cacheable ; 1 = b11111111 = Normal, Inner/Outer WB/WA/RA ; 2 = b00000000 = Device-nGnRnE ; 3 = b00000100 = Device-nGnRE ; 4 = b10111011 = Normal, Inner/Outer WT/WA/RA ; ldr x1, =0x000000BB0400FF44 msr MAIR_EL1, x1 #if defined (versal) ; ; Set up TCR_EL1 ; Physical Address Size PS = 100 -> 44bits 16TB ; Granual Size TG0 = 00 -> 4KB ; size offset of the memory region T0SZ = 20 -> (region size 2^(64-20) = 2^44) ; ldr x1,=0x485800514 #else ; ; Set up TCR_EL1 ; Physical Address Size PS = 010 -> 40bits 1TB ; Granule Size TG0 = 00 -> 4KB ; Size offset of the memory region T0SZ = 24 -> (region size 2^(64-24) = 2^40) ; ldr x1, =0x285800518 #endif msr TCR_EL1, x1 isb ; Enable SError Exception for asynchronous abort mrs x1,DAIF mov x2, #(0x1<<8) bic x1,x1,x2 msr DAIF,x1 ; Enable MMU mov x1,#0x0 orr x1, x1, #(1 << 18) ; Set WFE non trapping orr x1, x1, #(1 << 17) ; Set WFI non trapping orr x1, x1, #(1 << 5) ; Set CP15 barrier enabled orr x1, x1, #(1 << 12) ; Set I bit orr x1, x1, #(1 << 2) ; Set C bit orr x1, x1, #(1 << 0) ; Set M bit msr SCTLR_EL1, x1 isb bl __main ; Jump to start #else b error ; present exception level and selected exception level mismatch #endif error b error invalidate_dcaches dmb ISH mrs x0, CLIDR_EL1 ; x0 = CLIDR ubfx w2, w0, #24, #3 ; w2 = CLIDR>Loc cmp w2, #0 ; LoC is 0? b.eq invalidateCaches_end ; No cleaning required and enable MMU mov w1, #0 ; w1 = level iterator invalidateCaches_flush_level add w3, w1, w1, lsl #1 ; w3 = w1 3 (right-shift for cache type) lsr w3, w0, w3 ; w3 = w0 >> w3 ubfx w3, w3, #0, #3 ; w3 = cache type of this level cmp w3, #2 ; No cache at this level? b.lt invalidateCaches_next_level lsl w4, w1, #1 msr CSSELR_EL1, x4 ; Select current cache level in CSSELR isb ; ISB required to reflect new CSIDR mrs x4, CCSIDR_EL1 ; w4 = CSIDR ubfx w3, w4, #0, #3 add w3, w3, #2 ; w3 = log2(line size) ubfx w5, w4, #13, #15 ubfx w4, w4, #3, #10 ; w4 = Way number clz w6, w4 ; w6 = 32 - log2(number of ways) invalidateCaches_flush_set mov w8, w4 ; w8 = Way number invalidateCaches_flush_way lsl w7, w1, #1 ; Fill level field lsl w9, w5, w3 orr w7, w7, w9 ; Fill index field lsl w9, w8, w6 orr w7, w7, w9 ; Fill way field dc CISW, x7 ; Invalidate by set/way to point of coherency subs w8, w8, #1 ; Decrement way b.ge invalidateCaches_flush_way subs w5, w5, #1 ; Decrement set b.ge invalidateCaches_flush_set invalidateCaches_next_level add w1, w1, #1 ; Next level cmp w2, w1 b.gt invalidateCaches_flush_level invalidateCaches_end ret END ; ; @} End of "addtogroup a53_64_boot_code" ;
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,679	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/xpvxenconsole/hypercall.S	/* Copyright DornerWorks 2016 Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. THIS SOFTWARE IS PROVIDED BY DORNERWORKS FOR USE ON THE CONTRACTED PROJECT, AND ANY EXPRESS OR IMPLIED WARRANTY IS LIMITED TO THIS USE. FOR ALL OTHER USES THIS SOFTWARE IS PROVIDED ''AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL DORNERWORKS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "xen.h" .globl HYPERVISOR_console_io; .align 4; HYPERVISOR_console_io: mov x16, __HYPERVISOR_console_io; hvc 0xEA1; ret; .globl HYPERVISOR_hvm_op; .align 4; HYPERVISOR_hvm_op: mov x16, __HYPERVISOR_hvm_op; hvc 0xEA1; ret; .globl HYPERVISOR_memory_op; .align 4; HYPERVISOR_memory_op: mov x16, __HYPERVISOR_memory_op; hvc 0xEA1; ret; .globl HYPERVISOR_event_channel_op; .align 4; HYPERVISOR_event_channel_op: mov x16, __HYPERVISOR_event_channel_op hvc 0xEA1; ret;
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	4,386	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/gcc/xil-crt0.S	/****************************************************************************** * Copyright (C) 2014 - 2022 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file xil-crt0.S * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 5.00 pkp 05/21/14 Initial version * 5.04 pkp 12/18/15 Initialized global constructor for C++ applications * 5.04 pkp 01/05/16 Set the reset vector register RVBAR equivalent to * vector table base address * 6.02 pkp 01/22/17 Added support for EL1 non-secure * 6.6 srm 10/18/17 Added timer configuration using XTime_StartTTCTimer API. * Now the TTC instance as specified by the user will be * started. * 6.6 mus 01/29/18 Initialized the xen PV console for Cortexa53 64 bit * EL1 NS BSP. * 7.2 sd 02/23/20 Clock Init is called * 7.2 sd 02/23/20 Clock code added under XCLOCKING flag * 7.7 mus 01/06/22 Added call to Xil_SetTlbAttributes to set correct * attributes for GIC in case of Xen domU guest application. * It fixes CR#974078. * 8.0 mus 07/06/21 Added support for VERSAL NET * 8.0 mus 06/27/22 Enabled PMU counter. * </pre> * * @note * * None. * *****************************************************************************/ #include "xparameters.h" #include "bspconfig.h" .file "xil-crt0.S" .section ".got2","aw" .align 2 .text .Lsbss_start: .quad __sbss_start .Lsbss_end: .quad __sbss_end .Lbss_start: .quad __bss_start__ .Lbss_end: .quad __bss_end__ .set APU_PWRCTL, 0xFD5C0090 .globl _startup _startup: mov x0, #0 #if ! defined(VERSAL_NET) .if (EL3 == 1) / Check whether the clearing of bss sections shall be skipped / ldr x10, =APU_PWRCTL / Load PWRCTRL address / ldr w11, [x10] / Read PWRCTRL register / mrs x2, MPIDR_EL1 / Read MPIDR_EL1 / ubfx x2, x2, #0, #8 / Extract CPU ID (affinity level 0) / mov w1, #1 lsl w2, w1, w2 / Shift CPU ID to get one-hot ID / ands w11, w11, w2 / Get PWRCTRL bit for this core / bne .Lenclbss / Skip BSS and SBSS clearing / .endif #endif / clear sbss / ldr x1,.Lsbss_start / calculate beginning of the SBSS / ldr x2,.Lsbss_end / calculate end of the SBSS / .Lloop_sbss: cmp x1,x2 bge .Lenclsbss / If no SBSS, no clearing required / str x0, [x1], #8 b .Lloop_sbss .Lenclsbss: / clear bss / ldr x1,.Lbss_start / calculate beginning of the BSS / ldr x2,.Lbss_end / calculate end of the BSS / .Lloop_bss: cmp x1,x2 bge .Lenclbss / If no BSS, no clearing required / str x0, [x1], #8 b .Lloop_bss .Lenclbss: / run global constructors / bl __libc_init_array / Reset and start Triple Timer Counter / #if defined (SLEEP_TIMER_BASEADDR) bl XTime_StartTTCTimer #endif .if (EL1_NONSECURE == 1 && HYP_GUEST == 1) / * Xen domU guest memory map is not same as that of * native ZynqMP memory map. Currently GIC for Xen * domU guest is being mapped at < 2GB address, which * is configured as normal cacheable memory (DDR) in * default translation table. As GIC needs to be * configured as device memory, updating attributes * of GIC region as strongly ordered, RW, non executable * through Xil_SetTlbAttributes API. Below code snippet * in assemby is equivalent to, * Xil_SetTlbAttributes(XPAR_SCUGIC_0_DIST_BASEADDR, * STRONG_ORDERED \| EXECUTE_NEVER) / ldr x0, =XPAR_SCUGIC_0_DIST_BASEADDR mov x1, #0x409 orr x1, x1, #(0x1 << 53) orr x1, x1, #(0x1 << 54) bl Xil_SetTlbAttributes .endif .if (EL1_NONSECURE == 1 && HYP_GUEST == 1 && \ XEN_USE_PV_CONSOLE == 1) bl XPVXenConsole_Init .endif / Set E, C and D bits / mrs x1, PMCR_EL0 orr x1, x1, #(0x1 << 0) orr x1, x1, #(0x1 << 2) orr x1, x1, #(0x1 << 3) msr PMCR_EL0, x1 / make sure argc and argv are valid / mov x0, #0 mov x1, #0 #ifdef XCLOCKING bl Xil_ClockInit #endif bl main / Jump to main C code / / Cleanup global constructors / bl __libc_fini_array bl exit .Lexit: / should never get here */ b .Lexit .Lstart: .size _startup,.Lstart-_startup
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	8,881	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/gcc/asm_vectors.S	/****************************************************************************** * Copyright (c) 2014 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file asm_vectors.S * * This file contains the initial vector table for the Cortex A53 processor * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 5.00 pkp 05/21/14 Initial version * 6.02 pkp 12/21/16 Added support for floating point access * 6.02 pkp 01/22/17 Added support for EL1 non-secure and hypervisor * baremetal guest * 6.4 mus 06/14/17 Fixed bug in IRQInterruptHandler code snippet, * which checks for the FPEN bit of CPACR_EL1 * 6.6 mus 01/19/18 Added isb after writing to the cpacr_el1/cptr_el3, * to ensure enabling/disabling of floating-point unit * is completed, before any subsequent instruction. * 7.5 mus 05/20/21 Fixed speculative execution past ERET and BR instructions. * As per CVE-2020-13844, Cortex-A72 is affected with * vulnearability, hence changes are targeted only for Cortex-A72. * It fixes CR#1083649. * 7.7. asa 03/22/22 Updated FIQ handler to also handle floating/SIMD context. * * </pre> * * @note * * None. * *****************************************************************************/ #include "bspconfig.h" .org 0 .text .globl _boot .globl _vector_table .globl FIQInterrupt .globl IRQInterrupt .globl SErrorInterrupt .globl SynchronousInterrupt .globl FPUStatus / * FPUContextSize is the size of the array where floating point registers are * stored when required. The default size corresponds to the case when there is no * nested interrupt. If there are nested interrupts in application which are using * floating point operation, the size of FPUContextSize need to be increased as per * requirement / .set FPUContextSize, 528 .macro saveregister stp X0,X1, [sp,#-0x10]! stp X2,X3, [sp,#-0x10]! stp X4,X5, [sp,#-0x10]! stp X6,X7, [sp,#-0x10]! stp X8,X9, [sp,#-0x10]! stp X10,X11, [sp,#-0x10]! stp X12,X13, [sp,#-0x10]! stp X14,X15, [sp,#-0x10]! stp X16,X17, [sp,#-0x10]! stp X18,X19, [sp,#-0x10]! stp X29,X30, [sp,#-0x10]! .endm .macro restoreregister ldp X29,X30, [sp], #0x10 ldp X18,X19, [sp], #0x10 ldp X16,X17, [sp], #0x10 ldp X14,X15, [sp], #0x10 ldp X12,X13, [sp], #0x10 ldp X10,X11, [sp], #0x10 ldp X8,X9, [sp], #0x10 ldp X6,X7, [sp], #0x10 ldp X4,X5, [sp], #0x10 ldp X2,X3, [sp], #0x10 ldp X0,X1, [sp], #0x10 .endm .macro savefloatregister / Load the floating point context array address from FPUContextBase / ldr x1,=FPUContextBase ldr x0, [x1] / Save all the floating point register to the array / stp q0,q1, [x0], #0x20 stp q2,q3, [x0], #0x20 stp q4,q5, [x0], #0x20 stp q6,q7, [x0], #0x20 stp q8,q9, [x0], #0x20 stp q10,q11, [x0], #0x20 stp q12,q13, [x0], #0x20 stp q14,q15, [x0], #0x20 stp q16,q17, [x0], #0x20 stp q18,q19, [x0], #0x20 stp q20,q21, [x0], #0x20 stp q22,q23, [x0], #0x20 stp q24,q25, [x0], #0x20 stp q26,q27, [x0], #0x20 stp q28,q29, [x0], #0x20 stp q30,q31, [x0], #0x20 mrs x2, FPCR mrs x3, FPSR stp x2, x3, [x0], #0x10 / Save current address of floating point context array to FPUContextBase / str x0, [x1] .endm .macro restorefloatregister / Restore the address of floating point context array from FPUContextBase / ldr x1,=FPUContextBase ldr x0, [x1] / Restore all the floating point register from the array / ldp x2, x3, [x0,#-0x10]! msr FPCR, x2 msr FPSR, x3 ldp q30,q31, [x0,#-0x20]! ldp q28,q29, [x0,#-0x20]! ldp q26,q27, [x0,#-0x20]! ldp q24,q25, [x0,#-0x20]! ldp q22,q23, [x0,#-0x20]! ldp q20,q21, [x0,#-0x20]! ldp q18,q19, [x0,#-0x20]! ldp q16,q17, [x0,#-0x20]! ldp q14,q15, [x0,#-0x20]! ldp q12,q13, [x0,#-0x20]! ldp q10,q11, [x0,#-0x20]! ldp q8,q9, [x0,#-0x20]! ldp q6,q7, [x0,#-0x20]! ldp q4,q5, [x0,#-0x20]! ldp q2,q3, [x0,#-0x20]! ldp q0,q1, [x0,#-0x20]! / Save current address of floating point context array to FPUContextBase / str x0, [x1] .endm .macro exception_return eret #if defined (versal) dsb nsh isb #endif .endm .org 0 .section .vectors, "a" _vector_table: .set VBAR, _vector_table .org VBAR / * if application is built for XEN GUEST as EL1 Non-secure following image * header is required by XEN. / .if (HYP_GUEST == 1) / Valid Image header. / / HW reset vector. / ldr x16, =_boot br x16 #if defined (versal) dsb nsh isb #endif / text offset. / .dword 0 / image size. / .dword 0 / flags. / .dword 8 / RES0 / .dword 0 .dword 0 .dword 0 / magic / .dword 0x644d5241 / RES0 / .dword 0 / End of Image header. / .endif b _boot .org (VBAR + 0x200) b SynchronousInterruptHandler .org (VBAR + 0x280) b IRQInterruptHandler .org (VBAR + 0x300) b FIQInterruptHandler .org (VBAR + 0x380) b SErrorInterruptHandler SynchronousInterruptHandler: saveregister / Check if the Synchronous abort is occurred due to floating point access. / .if (EL3 == 1) mrs x0, ESR_EL3 .else mrs x0, ESR_EL1 .endif and x0, x0, #(0x3F << 26) mov x1, #(0x7 << 26) cmp x0, x1 / If exception is not due to floating point access go to synchronous handler / bne synchronoushandler / * If excpetion occurred due to floating point access, Enable the floating point * access i.e. do not trap floating point instruction / .if (EL3 == 1) mrs x1,CPTR_EL3 bic x1, x1, #(0x1<<10) msr CPTR_EL3, x1 .else mrs x1,CPACR_EL1 orr x1, x1, #(0x1<<20) msr CPACR_EL1, x1 .endif isb / If the floating point access was previously enabled, store FPU context * registers(storefloat). / ldr x0, =FPUStatus ldrb w1,[x0] cbnz w1, storefloat / * If the floating point access was not enabled previously, save the status of * floating point accessibility i.e. enabled and store floating point context * array address(FPUContext) to FPUContextBase. / mov w1, #0x1 strb w1, [x0] ldr x0, =FPUContext ldr x1, =FPUContextBase str x0,[x1] b restorecontext storefloat: savefloatregister b restorecontext synchronoushandler: bl SynchronousInterrupt restorecontext: restoreregister exception_return IRQInterruptHandler: saveregister / Save the status of SPSR, ELR and CPTR to stack / .if (EL3 == 1) mrs x0, CPTR_EL3 mrs x1, ELR_EL3 mrs x2, SPSR_EL3 .else mrs x0, CPACR_EL1 mrs x1, ELR_EL1 mrs x2, SPSR_EL1 .endif stp x0, x1, [sp,#-0x10]! str x2, [sp,#-0x10]! / Trap floating point access / .if (EL3 == 1) mrs x1,CPTR_EL3 orr x1, x1, #(0x1<<10) msr CPTR_EL3, x1 .else mrs x1,CPACR_EL1 bic x1, x1, #(0x1<<20) msr CPACR_EL1, x1 .endif isb bl IRQInterrupt / * If floating point access is enabled during interrupt handling, * restore floating point registers. / .if (EL3 == 1) mrs x0, CPTR_EL3 ands x0, x0, #(0x1<<10) bne RestorePrevState .else mrs x0,CPACR_EL1 ands x0, x0, #(0x1<<20) beq RestorePrevState .endif restorefloatregister / Restore the status of SPSR, ELR and CPTR from stack / RestorePrevState: ldr x2,[sp],0x10 ldp x0, x1, [sp],0x10 .if (EL3 == 1) msr CPTR_EL3, x0 msr ELR_EL3, x1 msr SPSR_EL3, x2 .else msr CPACR_EL1, x0 msr ELR_EL1, x1 msr SPSR_EL1, x2 .endif restoreregister exception_return FIQInterruptHandler: saveregister / Save the status of SPSR, ELR and CPTR to stack / .if (EL3 == 1) mrs x0, CPTR_EL3 mrs x1, ELR_EL3 mrs x2, SPSR_EL3 .else mrs x0, CPACR_EL1 mrs x1, ELR_EL1 mrs x2, SPSR_EL1 .endif stp x0, x1, [sp,#-0x10]! str x2, [sp,#-0x10]! / Trap floating point access / .if (EL3 == 1) mrs x1,CPTR_EL3 orr x1, x1, #(0x1<<10) msr CPTR_EL3, x1 .else mrs x1,CPACR_EL1 bic x1, x1, #(0x1<<20) msr CPACR_EL1, x1 .endif isb bl FIQInterrupt / * If floating point access is enabled during interrupt handling, * restore floating point registers. / .if (EL3 == 1) mrs x0, CPTR_EL3 ands x0, x0, #(0x1<<10) bne RestorePrevStatefiq .else mrs x0,CPACR_EL1 ands x0, x0, #(0x1<<20) beq RestorePrevStatefiq .endif restorefloatregister / Restore the status of SPSR, ELR and CPTR from stack / RestorePrevStatefiq: ldr x2,[sp],0x10 ldp x0, x1, [sp],0x10 .if (EL3 == 1) msr CPTR_EL3, x0 msr ELR_EL3, x1 msr SPSR_EL3, x2 .else msr CPACR_EL1, x0 msr ELR_EL1, x1 msr SPSR_EL1, x2 .endif restoreregister exception_return SErrorInterruptHandler: saveregister bl SErrorInterrupt restoreregister exception_return .align 8 / Array to store floating point registers / FPUContext: .skip FPUContextSize / Stores address for floating point context array */ FPUContextBase: .skip 8 FPUStatus: .skip 1 .end
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	15,990	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/gcc/boot.S	/****************************************************************************** * Copyright (c) 2014 - 2022 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file boot.S * * @addtogroup a53_64_boot_code Cortex A53 64bit Processor Boot Code * @{ * <h2> boot.S </h2> * * The boot code performs minimum configuration which is required for an * application. Cortex-A53 starts by checking current exception level. If the * current exception level is EL3 and BSP is built for EL3, it will do * initialization required for application execution at EL3. Below is a * sequence illustrating what all configuration is performed before control * reaches to main function for EL3 execution. * * 1. Program vector table base for exception handling * 2. Set reset vector table base address * 3. Program stack pointer for EL3 * 4. Routing of interrupts to EL3 * 5. Enable ECC protection * 6. Program generic counter frequency * 7. Invalidate instruction cache, data cache and TLBs * 8. Configure MMU registers and program base address of translation table * 9. Transfer control to _start which clears BSS sections and runs global * constructor before jumping to main application * * If the current exception level is EL1 and BSP is also built for EL1_NONSECURE * it will perform initialization required for application execution at EL1 * non-secure. For all other combination, the execution will go into infinite * loop. Below is a sequence illustrating what all configuration is performed * before control reaches to main function for EL1 execution. * * 1. Program vector table base for exception handling * 2. Program stack pointer for EL1 * 3. Invalidate instruction cache, data cache and TLBs * 4. Configure MMU registers and program base address of translation table * 5. Transfer control to _start which clears BSS sections and runs global * constructor before jumping to main application * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 5.00 pkp 05/21/14 Initial version * 6.00 pkp 07/25/16 Program the counter frequency * 6.02 pkp 01/22/17 Added support for EL1 non-secure * 6.02 pkp 01/24/17 Clearing status of FPUStatus variable to ensure it * holds correct value. * 6.3 mus 04/20/17 CPU Cache protection bit in the L2CTLR_EL1 will be in * set state on reset. So, setting that bit through boot * code is redundant, hence removed the code which sets * CPU cache protection bit. * 6.4 mus 08/11/17 Implemented ARM erratum 855873.It fixes * CR#982209. * 6.6 mus 01/19/18 Added isb after writing to the cpacr_el1/cptr_el3, * to ensure floating-point unit is disabled, before * any subsequent instruction. * 7.0 mus 03/26/18 Updated TCR_EL3/TCR_EL1 as per versal address map * 7.3 mus 04/24/20 Corrected CPACR_EL1 handling at EL1 NS * 8.0 mus 07/06/21 Added support for CortexA78 processor in VERSAL NET SoC * 8.0 mus 10/05/21 Default translation table for VERSAL NET has been configured * for 256 TB address space, due to this page tables size * exceeds OCM size, hence executable size is too large * to fit into OCM. This patch adds option to reduce * page table size, when OCM_ELF flag is defined in * compiler flags, translation table would be configured * for 1 TB address space. It would help to reduce * executable size. * * </pre> * *****************************************************************************/ #include "xparameters.h" #include "bspconfig.h" #include "xil_errata.h" .globl MMUTableL0 .globl MMUTableL1 .globl MMUTableL2 .global _prestart .global _boot .global __el3_stack .global __el2_stack .global __el1_stack .global __el0_stack .global _vector_table .set EL3_stack, __el3_stack .set EL2_stack, __el2_stack .set EL1_stack, __el1_stack .set EL0_stack, __el0_stack .set TT_S1_FAULT, 0x0 .set TT_S1_TABLE, 0x3 .set L0Table, MMUTableL0 .set L1Table, MMUTableL1 .set L2Table, MMUTableL2 .set vector_base, _vector_table .set rvbar_base, 0xFD5C0040 #if defined (VERSAL_NET) .set counterfreq, XPAR_CPU_CORTEXA78_0_TIMESTAMP_CLK_FREQ #elif defined (versal) .set counterfreq, XPAR_CPU_CORTEXA72_0_TIMESTAMP_CLK_FREQ #else .set counterfreq, XPAR_CPU_CORTEXA53_0_TIMESTAMP_CLK_FREQ #endif .set MODE_EL1, 0x5 .set DAIF_BIT, 0x1C0 .section .boot,"ax" / this initializes the various processor modes / _prestart: _boot: mov x0, #0 mov x1, #0 mov x2, #0 mov x3, #0 mov x4, #0 mov x5, #0 mov x6, #0 mov x7, #0 mov x8, #0 mov x9, #0 mov x10, #0 mov x11, #0 mov x12, #0 mov x13, #0 mov x14, #0 mov x15, #0 mov x16, #0 mov x17, #0 mov x18, #0 mov x19, #0 mov x20, #0 mov x21, #0 mov x22, #0 mov x23, #0 mov x24, #0 mov x25, #0 mov x26, #0 mov x27, #0 mov x28, #0 mov x29, #0 mov x30, #0 #if 0 //don't put other a53 cpus in wfi //Which core am I // ---------------- mrs x0, MPIDR_EL1 and x0, x0, #0xFF //Mask off to leave Aff0 cbz x0, OKToRun //If core 0, run the primary init code EndlessLoop0: wfi b EndlessLoop0 #endif OKToRun: mrs x0, currentEL cmp x0, #0xC beq InitEL3 cmp x0, #0x4 beq InitEL1 b error // go to error if current exception level is neither EL3 nor EL1 InitEL3: .if (EL3 == 1) /Set vector table base address/ ldr x1, =vector_base msr VBAR_EL3,x1 / Set reset vector address / / Get the cpu ID / mrs x0, MPIDR_EL1 and x0, x0, #0xFF mov w0, w0 #ifndef VERSAL_NET ldr w2, =rvbar_base / calculate the rvbar base address for particular CPU core / mov w3, #0x8 mul w0, w0, w3 add w2, w2, w0 / store vector base address to RVBAR / str x1, [x2] #endif /Define stack pointer for current exception level/ ldr x2,=EL3_stack mov sp,x2 / Enable Trapping of SIMD/FPU register for standalone BSP / mov x0, #0 #ifndef FREERTOS_BSP orr x0, x0, #(0x1 << 10) #endif msr CPTR_EL3, x0 isb / * Clear FPUStatus variable to make sure that it contains current * status of FPU i.e. disabled. In case of a warm restart execution * when bss sections are not cleared, it may contain previously updated * value which does not hold true now. / #ifndef FREERTOS_BSP ldr x0,=FPUStatus str xzr, [x0] #endif / Configure SCR_EL3 / mov w1, #0 //; Initial value of register is unknown orr w1, w1, #(1 << 11) //; Set ST bit (Secure EL1 can access CNTPS_TVAL_EL1, CNTPS_CTL_EL1 & CNTPS_CVAL_EL1) orr w1, w1, #(1 << 10) //; Set RW bit (EL1 is AArch64, as this is the Secure world) orr w1, w1, #(1 << 3) //; Set EA bit (SError routed to EL3) orr w1, w1, #(1 << 2) //; Set FIQ bit (FIQs routed to EL3) orr w1, w1, #(1 << 1) //; Set IRQ bit (IRQs routed to EL3) msr SCR_EL3, x1 / As per A78 TRM, CPUACTLR_EL1 is reserved for ARM internal use / #if !defined (VERSAL_NET) /configure cpu auxiliary control register EL1 / ldr x0,=0x80CA000 // L1 Data prefetch control - 5, Enable device split throttle, 2 independent data prefetch streams #if CONFIG_ARM_ERRATA_855873 / * Set ENDCCASCI bit in CPUACTLR_EL1 register, to execute data * cache clean operations as data cache clean and invalidate * / orr x0, x0, #(1 << 44) //; Set ENDCCASCI bit #endif msr S3_1_C15_C2_0, x0 //CPUACTLR_EL1 #endif / program the counter frequency / ldr x0,=counterfreq msr CNTFRQ_EL0, x0 / There is no SMPEN bit in A78, TODO: Check for equivalent bit / #if !defined (VERSAL_NET) /Enable hardware coherency between cores/ mrs x0, S3_1_c15_c2_1 //Read EL1 CPU Extended Control Register orr x0, x0, #(1 << 6) //Set the SMPEN bit msr S3_1_c15_c2_1, x0 //Write EL1 CPU Extended Control Register isb #endif tlbi ALLE3 ic IALLU //; Invalidate I cache to PoU bl invalidate_dcaches dsb sy isb ldr x1, =L0Table //; Get address of level 0 for TTBR0_EL3 msr TTBR0_EL3, x1 //; Set TTBR0_EL3 /********************************************* * Set up memory attributes * This equates to: * 0 = b01000100 = Normal, Inner/Outer Non-Cacheable * 1 = b11111111 = Normal, Inner/Outer WB/WA/RA * 2 = b00000000 = Device-nGnRnE * 3 = b00000100 = Device-nGnRE * 4 = b10111011 = Normal, Inner/Outer WT/WA/RA ********************************************/ ldr x1, =0x000000BB0400FF44 msr MAIR_EL3, x1 #if defined (VERSAL_NET) && defined (OCM_ELF) /******************************************** * Set up TCR_EL3 * Physical Address Size PS = 010 -> 40bits 1TB * Granual Size TG0 = 00 -> 4KB * Attributes for page table walks = 00 -> non cacheable * size offset of the memory region T0SZ = 24 -> (region size 2^(64-24) = 2^40) *************************************************/ ldr x1,=0x80823018 #elif defined (VERSAL_NET) /******************************************** * Set up TCR_EL3 * Physical Address Size PS = 101 -> 48bits 256 TB * Granual Size TG0 = 00 -> 4KB * size offset of the memory region T0SZ = 16 -> (region size 2^(64-16) = 2^48) **************************************************/ / ldr x1,=0x80853510 / ldr x1,=0x80853010 #elif defined (versal) /********************************************* * Set up TCR_EL3 * Physical Address Size PS = 100 -> 44bits 16 TB * Granual Size TG0 = 00 -> 4KB * size offset of the memory region T0SZ = 20 -> (region size 2^(64-20) = 2^44) *************************************************/ ldr x1,=0x80843514 #else /******************************************** * Set up TCR_EL3 * Physical Address Size PS = 010 -> 40bits 1TB * Granual Size TG0 = 00 -> 4KB * size offset of the memory region T0SZ = 24 -> (region size 2^(64-24) = 2^40) **************************************************/ ldr x1,=0x80823518 #endif msr TCR_EL3, x1 isb / Enable SError Exception for asynchronous abort / mrs x1,DAIF bic x1,x1,#(0x1<<8) msr DAIF,x1 / Configure SCTLR_EL3 / mov x1, #0 //Most of the SCTLR_EL3 bits are unknown at reset orr x1, x1, #(1 << 12) //Enable I cache orr x1, x1, #(1 << 3) //Enable SP alignment check orr x1, x1, #(1 << 2) //Enable caches orr x1, x1, #(1 << 0) //Enable MMU msr SCTLR_EL3, x1 dsb sy isb b _startup //jump to start .else b error // present exception level and selected exception level mismatch .endif InitEL1: .if (EL1_NONSECURE == 1) /Set vector table base address/ ldr x1, =vector_base msr VBAR_EL1,x1 / Trap floating point access only in case of standalone BSP / #ifdef FREERTOS_BSP mrs x0, CPACR_EL1 orr x0, x0, #(0x3 << 20) msr CPACR_EL1, x0 #else mrs x0, CPACR_EL1 bic x0, x0, #(0x3 << 20) msr CPACR_EL1, x0 #endif isb / * Clear FPUStatus variable to make sure that it contains current * status of FPU i.e. disabled. In case of a warm restart execution * when bss sections are not cleared, it may contain previously updated * value which does not hold true now. / #ifndef FREERTOS_BSP ldr x0,=FPUStatus str xzr, [x0] #endif /Define stack pointer for current exception level/ ldr x2,=EL1_stack mov sp,x2 / Disable MMU first / mov x1,#0x0 msr SCTLR_EL1, x1 isb TLBI VMALLE1 ic IALLU //; Invalidate I cache to PoU bl invalidate_dcaches dsb sy isb ldr x1, =L0Table //; Get address of level 0 for TTBR0_EL1 msr TTBR0_EL1, x1 //; Set TTBR0_EL1 /********************************************* * Set up memory attributes * This equates to: * 0 = b01000100 = Normal, Inner/Outer Non-Cacheable * 1 = b11111111 = Normal, Inner/Outer WB/WA/RA * 2 = b00000000 = Device-nGnRnE * 3 = b00000100 = Device-nGnRE * 4 = b10111011 = Normal, Inner/Outer WT/WA/RA ********************************************/ ldr x1, =0x000000BB0400FF44 msr MAIR_EL1, x1 #if defined (versal) /******************************************** * Set up TCR_EL1 * Physical Address Size PS = 100 -> 44bits 16TB * Granual Size TG0 = 00 -> 4KB * size offset of the memory region T0SZ = 20 -> (region size 2^(64-20) = 2^44) *************************************************/ ldr x1,=0x485800514 #else /******************************************** * Set up TCR_EL1 * Physical Address Size PS = 010 -> 44bits 16TB * Granual Size TG0 = 00 -> 4KB * size offset of the memory region T0SZ = 24 -> (region size 2^(64-24) = 2^40) **************************************************/ ldr x1,=0x285800518 #endif msr TCR_EL1, x1 isb / Enable SError Exception for asynchronous abort / mrs x1,DAIF bic x1,x1,#(0x1<<8) msr DAIF,x1 //; Enable MMU mov x1,#0x0 orr x1, x1, #(1 << 18) // ; Set WFE non trapping orr x1, x1, #(1 << 17) // ; Set WFI non trapping orr x1, x1, #(1 << 5) // ; Set CP15 barrier enabled orr x1, x1, #(1 << 12) // ; Set I bit orr x1, x1, #(1 << 2) // ; Set C bit orr x1, x1, #(1 << 0) // ; Set M bit msr SCTLR_EL1, x1 isb bl _startup //jump to start .else b error // present exception level and selected exception level mismatch .endif error: b error invalidate_dcaches: dmb ISH mrs x0, CLIDR_EL1 //; x0 = CLIDR ubfx w2, w0, #24, #3 //; w2 = CLIDR.LoC cmp w2, #0 //; LoC is 0? b.eq invalidateCaches_end //; No cleaning required and enable MMU mov w1, #0 //; w1 = level iterator invalidateCaches_flush_level: add w3, w1, w1, lsl #1 //; w3 = w1 3 (right-shift for cache type) lsr w3, w0, w3 //; w3 = w0 >> w3 ubfx w3, w3, #0, #3 //; w3 = cache type of this level cmp w3, #2 //; No cache at this level? b.lt invalidateCaches_next_level lsl w4, w1, #1 msr CSSELR_EL1, x4 //; Select current cache level in CSSELR isb //; ISB required to reflect new CSIDR mrs x4, CCSIDR_EL1 //; w4 = CSIDR ubfx w3, w4, #0, #3 add w3, w3, #2 //; w3 = log2(line size) ubfx w5, w4, #13, #15 ubfx w4, w4, #3, #10 //; w4 = Way number clz w6, w4 //; w6 = 32 - log2(number of ways) invalidateCaches_flush_set: mov w8, w4 //; w8 = Way number invalidateCaches_flush_way: lsl w7, w1, #1 //; Fill level field lsl w9, w5, w3 orr w7, w7, w9 //; Fill index field lsl w9, w8, w6 orr w7, w7, w9 //; Fill way field dc CISW, x7 //; Invalidate by set/way to point of coherency subs w8, w8, #1 //; Decrement way b.ge invalidateCaches_flush_way subs w5, w5, #1 //; Descrement set b.ge invalidateCaches_flush_set invalidateCaches_next_level: add w1, w1, #1 //; Next level cmp w2, w1 b.gt invalidateCaches_flush_level invalidateCaches_end: ret .end /** * @} End of "addtogroup a53_64_boot_code". */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	15,453	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/platform/versal/armclang/translation_table.S	/****************************************************************************** * Copyright (C) 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file translation_table.s * * @addtogroup a72_64_boot_code * @{ * <h2> translation_table.S </h2> * translation_table.S contains a static page table required by MMU for * cortex-A72. This translation table is flat mapped (input address = output * address) with default memory attributes defined for versal * architecture. It utilizes translation granual size of 4KB with 2MB section * size for initial 5GB memory and 1GB section size for memory after 5GB. * The overview of translation table memory attributes is described below. * \| Name \| Memory Range \| Def. in Translation Table \| \|-----------------------\|-----------------------------------\|-----------------------------\| \| DDR \| 0x000_0000_0000 - 0x000_7FFF_FFFF \| Normal WB Cacheable \| \| LPD_AFI_FS \| 0x000_8000_0000 - 0x000_9FFF_FFFF \| Strongly Ordered \| \| Reserved \| 0x000_A000_0000 - 0x000_A3FF_FFFF \| Unassigned \| \| FPD_AFI_0 \| 0x000_A400_0000 - 0x000_AFFF_FFFF \| Strongly Ordered \| \| FPD_AFI_1 \| 0x000_B000_0000 - 0x000_BFFF_FFFF \| Strongly Ordered \| \| QSPI \| 0x000_C000_0000 - 0x000_DFFF_FFFF \| Strongly Ordered \| \| PCIE region 0 \| 0x000_E000_0000 - 0x000_EFFF_FFFF \| Strongly Ordered \| \| PMC \| 0x000_F000_0000 - 0x000_F7FF_FFFF \| Strongly Ordered \| \| STM_CORESIGHT \| 0x000_F800_0000 - 0x000_F8FF_FFFF \| Strongly Ordered \| \| GIC \| 0x000_F900_0000 - 0x000_F90F_FFFF \| Strongly Ordered \| \| Reserved \| 0x000_F910_0000 - 0x000_FBFF_FFFF \| Unassigned \| \| CPM \| 0x000_FC00_0000 - 0x000_FCFF_FFFF \| Strongly Ordered \| \| FPD slaves \| 0x000_FD00_0000 - 0x000_FDFF_FFFF \| Strongly Ordered \| \| LPD slaves \| 0x000_FE00_0000 - 0x000_FFDF_FFFF \| Strongly Ordered \| \| OCM \| 0x000_FFE0_0000 - 0xFFF_FFFF_FFFF \| Normal WB Cacheable \| \| PMC region 0-3 \| 0x001_0000_0000 - 0x001_1FFF_FFFF \| Strongly Ordered \| \| Reserved \| 0x001_2000_0000 - 0x001_FFFF_FFFF \| Unassigned \| \| ME Array 0-3 \| 0x002_0000_0000 - 0x002_FFFF_FFFF \| Strongly Ordered \| \| Reserved \| 0x003_0000_0000 - 0x003_FFFF_FFFF \| Unassigned \| \| PL- via PS \| 0x004_0000_0000 - 0x005_FFFF_FFFF \| Strongly Ordered \| \| PCIe region 1 \| 0x006_0000_0000 - 0x007_FFFF_FFFF \| Strongly Ordered \| \| DDR \| 0x008_0000_0000 - 0x00F_FFFF_FFFF \| Normal WB Cacheable \| \| Reserved \| 0x010_0000_0000 - 0x03F_FFFF_FFFF \| Unassigned \| \| HBM 0-3 \| 0x040_0000_0000 - 0x07F_FFFF_FFFF \| Strongly Ordered \| \| PCIe region 2 \| 0x080_0000_0000 - 0x0BF_FFFF_FFFF \| Strongly Ordered \| \| DDR \| 0x0C0_0000_0000 - 0x1B7_7FFF_FFFF \| Normal WB Cacheable \| \| Reserved \| 0x1B7_8000_0000 - 0x1FF_FFFF_FFFF \| Unassigned \| \| PL- Via NoC \| 0x200_0000_0000 - 0x3FF_FFFF_FFFF \| Strongly Ordered \| \| PL- Via PS \| 0x400_0000_0000 - 0x4FF_FFFF_FFFF \| Strongly Ordered \| \| DDR CH1-CH3 \| 0x500_0000_0000 - 0x7FF_FFFF_FFFF \| Normal WB Cacheable \| \| PL- Via NoC \| 0x800_0000_0000 - 0xFFF_FFFF_FFFF \| Strongly Ordered \| * @note * * For DDR region 0x0000000000 - 0x007FFFFFFF, a system where DDR is less than * 2GB, region after DDR and before PL is marked as undefined/reserved in * translation table. Region 0xF9100000 - 0xF91FFFFF is reserved memory in * 0x00F9000000 - 0x00F91FFFFF range, but it is marked as strongly ordered * because minimum section size in translation table section is 2MB. * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 7.2 mus 01/09/20 Initial version * * *****************************************************************************/ #include "xparameters.h" #include "bspconfig.h" EXPORT MMUTableL0 EXPORT MMUTableL1 EXPORT MMUTableL2 GBLA abscnt GBLA count GBLA sect Reserved EQU 0x0 ; Fault #if EL1_NONSECURE Memory EQU 0x405:OR:(2:SHL:8):OR:0x0 ; normal writeback write allocate outer shared read write / #else Memory EQU 0x405:OR:(3:SHL:8):OR:0x0 ; normal writeback write allocate inner shared read write / #endif Device EQU 0x409:OR:(1:SHL:53):OR:(1:SHL:54):OR:0x0 ; strongly ordered read write non executable AREA \|.mmu_tbl0\|, CODE, ALIGN=12 MMUTableL0 count SETA 0 WHILE count<0x1f DCQU MMUTableL1+count0x1000+0x3 ; 0x0000_0000 - 0x7F_FFFF_FFFF count SETA count+1 WEND count SETA 1 WHILE count<0x20 DCQ MMUTableL1+count0x1000+0x3 ; 0x80_0000_0000 - 0xFFF_FFFF_FFFF count SETA count+1 WEND AREA \|.mmu_tbl1\|, CODE, ALIGN=12 MMUTableL1 DCQU MMUTableL2+0x3 ; 0x0000_0000 - 0x3FFF_FFFF count SETA 1 ; 0x4000_0000 - 0x1_3FFF_FFFF WHILE count<5 DCQ MMUTableL2+count0x1000+0x3 ; 1GB DDR, 512MB LPD_AFI_FS, 448MB FPD_AFI_0, 512MB QSPI, ; 256MB PCIe region 0, PMC 128MB, GIC 1 MB, reserved 47MB, ; 2GB other devices and memory, 512 MB PMC count SETA count+1 WEND Fixlocl1 EQU 0x140000000 abscnt SETA 0 count SETA 0 WHILE count<0x3 DCQU Fixlocl1+abscnt0x40000000+Reserved ; 0x1_4000_0000 - 0x1_FFFF_FFFF ; 3GB Reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x4 DCQU Fixlocl1+abscnt0x40000000+Device ; 0x2_0000_0000 - 0x2_FFFF_FFFF ; 4GB ME Array 0-3 count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x4 DCQU Fixlocl1+abscnt0x40000000+Reserved ; 0x3_0000_0000 - 0x3_FFFF_FFFF ; 4GB Reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x10 DCQU Fixlocl1+abscnt0x40000000+Device ; 0x4_0000_0000 - 0x7_FFFF_FFFF ; 8GB PL - via PS, 8GB PCIe region1 count SETA count+1 abscnt SETA abscnt+1 WEND #ifdef XPAR_AXI_NOC_DDR_LOW_1_BASEADDR DDR_1_START EQU XPAR_AXI_NOC_DDR_LOW_1_BASEADDR DDR_1_END EQU XPAR_AXI_NOC_DDR_LOW_1_HIGHADDR DDR_1_SIZE EQU (DDR_1_END - DDR_1_START+1) #if DDR_1_SIZE > 0x800000000 ; If DDR size is larger than 32GB, truncate to 32GB DDR_1_REG EQU 0x20 #else DDR_1_REG EQU DDR_1_SIZE/0x40000000 #endif #else DDR_1_REG EQU 0 #endif UNDEF_1_REG EQU (0x20 - DDR_1_REG) ; DDR based on size in hw design count SETA 0 WHILE count<DDR_1_REG DCQU Fixlocl1+abscnt0x40000000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_1_REG DCQU Fixlocl1+abscnt0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0xC0 DCQU Fixlocl1+abscnt0x40000000+Reserved ; 0x10_0000_0000 - 0x3F_FFFF_FFFF ; 192GB Reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x100 DCQU Fixlocl1+abscnt0x40000000+Device ; 0x40_0000_0000 - 0x7F_FFFF_FFFF ; 256GB HBM 0-3 count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x100 DCQU Fixlocl1+abscnt0x40000000+Device ; 0x80_0000_0000 - 0xBF_FFFF_FFFF ; 256GB PCIe 2 count SETA count+1 abscnt SETA abscnt+1 WEND #ifdef XPAR_AXI_NOC_DDR_LOW_2_BASEADDR DDR_2_START EQU XPAR_AXI_NOC_DDR_LOW_2_BASEADDR DDR_2_END EQU XPAR_AXI_NOC_DDR_LOW_2_HIGHADDR DDR_2_SIZE EQU (DDR_2_END - DDR_2_START+1) #if DDR_2_SIZE > 0x4000000000 ; If DDR size is larger than 256 GB, truncate to 256GB DDR_2_REG EQU 0x100 #else DDR_2_REG EQU DDR_2_SIZE/0x40000000 #endif #else DDR_2_REG EQU 0 #endif UNDEF_2_REG EQU (0x100 - DDR_2_REG) ; DDR based on size in hw design count SETA 0 WHILE count<DDR_2_REG DCQU Fixlocl1+abscnt0x40000000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_2_REG DCQU Fixlocl1+abscnt0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND #ifdef XPAR_AXI_NOC_DDR_LOW_3_BASEADDR DDR_3_START EQU XPAR_AXI_NOC_DDR_LOW_3_BASEADDR DDR_3_END EQU XPAR_AXI_NOC_DDR_LOW_3_HIGHADDR DDR_3_SIZE EQU (DDR_3_END - DDR_3_START+1) #if DDR_3_SIZE > 0xB780000000 ; If DDR size is larger than 734 GB, truncate to 734GB DDR_3_REG EQU 0x2de #else DDR_3_REG EQU DDR_3_SIZE/0x40000000 #endif #else DDR_3_REG EQU 0 #endif UNDEF_3_REG EQU (0x2de - DDR_3_REG) ; DDR based on size in hw design count SETA 0 WHILE count<DDR_3_REG DCQU Fixlocl1+abscnt0x40000000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_3_REG DCQU Fixlocl1+abscnt0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x122 DCQU Fixlocl1+abscnt0x40000000+Reserved ; 0x1B7_8000_0000 - 0x1FF_FFFF_FFFF ; 290GB reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x800 DCQU Fixlocl1+abscnt0x40000000+Device ; 0x200_0000_0000 - 0x3FF_FFFF_FFFF ; 2TB PL- via NoC count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x400 DCQU Fixlocl1+abscnt0x40000000+Device ; 0x400_0000_0000 - 0x4FF_FFFF_FFFF ; 1TB PL- via PS count SETA count+1 abscnt SETA abscnt+1 WEND #ifdef XPAR_AXI_NOC_DDR_CH_1_BASEADDR DDR_CH_1_START EQU XPAR_AXI_NOC_DDR_CH_1_BASEADDR DDR_CH_1_END EQU XPAR_AXI_NOC_DDR_CH_1_HIGHADDR DDR_CH_1_SIZE EQU (DDR_CH_1_END - DDR_CH_1_START + 1) #if DDR_CH_1_SIZE > 0x010000000000 ; If DDR size is larger than 1TB, truncate to 1 TB DDR_CH_1_REG EQU 0x400 ; 0x500_0000_0000 - 0x5FF_FFFF_FFFF #else DDR_CH_1_REG EQU DDR_CH_1_SIZE/0x40000000 #endif #else DDR_CH_1_REG EQU 0 #endif UNDEF_CH_1_REG EQU (0x400 - DDR_CH_1_REG) ; DDR based on size in hw design, Max size 1 TB count SETA 0 WHILE count<DDR_CH_1_REG DCQU Fixlocl1+abscnt0x40000000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_CH_1_REG DCQU Fixlocl1+abscnt0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND #ifdef XPAR_AXI_NOC_DDR_CH_2_BASEADDR DDR_CH_2_START EQU XPAR_AXI_NOC_DDR_CH_2_BASEADDR DDR_CH_2_END EQU XPAR_AXI_NOC_DDR_CH_2_HIGHADDR DDR_CH_2_SIZE EQU (DDR_CH_2_END - DDR_CH_2_START + 1) #if DDR_CH_2_SIZE > 0x010000000000 ; If DDR_CH_2 size is larger than 1TB, truncate to 1 TB DDR_CH_2_REG EQU 0x400 ; 0x600_0000_0000 - 0x6FF_FFFF_FFFF #else DDR_CH_2_REG EQU DDR_CH_2_SIZE/0x40000000 #endif #else DDR_CH_2_REG EQU 0 #endif UNDEF_CH_2_REG EQU (0x400 - DDR_CH_2_REG) ; DDR based on size in hw design, Max size 1 TB count SETA 0 WHILE count<DDR_CH_2_REG DCQU Fixlocl1+abscnt0x40000000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_CH_2_REG DCQU Fixlocl1+abscnt0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND #ifdef XPAR_AXI_NOC_DDR_CH_3_BASEADDR DDR_CH_3_START EQU XPAR_AXI_NOC_DDR_CH_3_BASEADDR DDR_CH_3_END EQU XPAR_AXI_NOC_DDR_CH_3_HIGHADDR DDR_CH_3_SIZE EQU (DDR_CH_3_END - DDR_CH_3_START+1) #if DDR_CH_3_SIZE > 0x010000000000 ; If DDR_CH_3 size is larger than 1TB, truncate to 1 TB / DDR_CH_3_REG EQU 0x400 ; 0x700_0000_0000 - 0x7FF_FFFF_FFFF #else DDR_CH_3_REG EQU DDR_CH_3_SIZE/0x40000000 #endif #else DDR_CH_3_REG EQU 0 #endif UNDEF_CH_3_REG EQU (0x400 - DDR_CH_3_REG) ; DDR based on size in hw design, Max size 1 TB count SETA 0 WHILE count<DDR_CH_3_REG DCQU Fixlocl1+abscnt0x40000000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_CH_3_REG DCQU Fixlocl1+abscnt0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x2000 DCQU Fixlocl1+abscnt0x40000000+Device count SETA count+1 abscnt SETA abscnt+1 WEND AREA \|.mmu_tbl2\|, CODE, ALIGN=12 MMUTableL2 abscnt SETA 0 #ifdef XPAR_AXI_NOC_DDR_LOW_0_BASEADDR DDR_0_START EQU XPAR_AXI_NOC_DDR_LOW_0_BASEADDR DDR_0_END EQU XPAR_AXI_NOC_DDR_LOW_0_HIGHADDR DDR_0_SIZE EQU (DDR_0_END - DDR_0_START+1) #if DDR_0_SIZE > 0x80000000 ; If DDR size is larger than 2GB, truncate to 2GB .set DDR_0_REG, 0x400 #else DDR_0_REG EQU DDR_0_SIZE/0x200000 #endif #else DDR_0_REG EQU 0 #endif UNDEF_0_REG EQU (0x400 - DDR_0_REG) ; DDR based on size in hw design count SETA 0 WHILE count<DDR_0_REG DCQU abscnt0x200000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_0_REG DCQU abscnt0x200000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x100 DCQU abscnt0x200000+Device count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x20 ; 0xA000_0000 - 0xA3FF_FFFF DCQU abscnt0x200000+Device ; 64MB reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x60 ; 0xA400_0000 - 0xAFFF_FFFF DCQU abscnt0x200000+Device ; 192MB FPD AFI 0 count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x80 ; 0xB000_0000 - 0xBFFF_FFFF DCQU abscnt0x200000+Device ; 192MB FPD AFI 1 count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x100 ; 0xC000_0000 - 0xDFFF_FFFF DCQU abscnt0x200000+Device ; 512MB QSPI count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x80 ; 0xE000_0000 - 0xEFFF_FFFF DCQU abscnt0x200000+Device ; 256MB lower PCIe count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x40 ; 0xF000_0000 - 0xF7FF_FFFF DCQU abscnt0x200000+Device ; 128MB PMC count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x8 ; 0xF800_0000 - 0xF8FF_FFFF DCQU abscnt0x200000+Device ; 16MB coresight count SETA count+1 abscnt SETA abscnt+1 WEND ; 1MB GIC is marked for 2MB region as the minimum block size in ; translation table is 2MB and adjacent 47MB reserved region is ; converted to 46MB DCQU abscnt0x200000+Device ; 0xF910_0000 - 0xF90F_FFFF abscnt SETA abscnt+1 ; Reserved 46MB 0xF91FFFFF - 0xFBFFFFFF count SETA 0 WHILE count<0x17 ; 0xF91F_FFFF - 0xFBFF_FFFF DCQU abscnt0x200000+Reserved ; 46MB reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x1F ; 0xFC00_0000 - 0xFFDF_FFFF DCQU abscnt0x200000+Device ; 16MB CPM,16MB FPS, 30MB LPS slaves count SETA count+1 abscnt SETA abscnt+1 WEND DCQU abscnt0x200000+Memory ; 0xFFE0_0000 - 0xFFFF_FFFF abscnt SETA abscnt+1 count SETA 0 WHILE count<0x100 ; 0x1_0000_0000 - 0x1_1FFF_FFFF DCQU abscnt0x200000+Device ; 512MB PMC 0-3 count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x100 ; 0x1_2000_0000 - 0x1_3FFF_FFFF DCQU abscnt0x200000+Device ; 512MB reserved count SETA count+1 abscnt SETA abscnt+1 WEND END /** * @} End of "addtogroup a53_64_boot_code". */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	26,891	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/platform/versal/gcc/translation_table.S	/****************************************************************************** * Copyright (C) 2018 - 2022 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file translation_table.s * * @addtogroup a53_64_boot_code * @{ * <h2> translation_table.S </h2> * The translation_table.S contains a static page table required by MMU for * cortex-A72. This translation table is flat mapped (input address = output * address) with default memory attributes defined for Versal * architecture. It utilizes translation granual size of 4KB with 2MB section * size for initial 5GB memory and 1GB section size for memory after 5GB. * The overview of translation table memory attributes is described below. * \| Name \| Memory Range \| Def. in Translation Table \| \|-----------------------\|-----------------------------------\|-----------------------------\| \| DDR \| 0x000_0000_0000 - 0x000_7FFF_FFFF \| Normal WB Cacheable \| \| LPD_AFI_FS \| 0x000_8000_0000 - 0x000_9FFF_FFFF \| Strongly Ordered \| \| Reserved \| 0x000_A000_0000 - 0x000_A3FF_FFFF \| Unassigned \| \| FPD_AFI_0 \| 0x000_A400_0000 - 0x000_AFFF_FFFF \| Strongly Ordered \| \| FPD_AFI_1 \| 0x000_B000_0000 - 0x000_BFFF_FFFF \| Strongly Ordered \| \| QSPI \| 0x000_C000_0000 - 0x000_DFFF_FFFF \| Strongly Ordered \| \| PCIE region 0 \| 0x000_E000_0000 - 0x000_EFFF_FFFF \| Strongly Ordered \| \| PMC \| 0x000_F000_0000 - 0x000_F7FF_FFFF \| Strongly Ordered \| \| STM_CORESIGHT \| 0x000_F800_0000 - 0x000_F8FF_FFFF \| Strongly Ordered \| \| GIC \| 0x000_F900_0000 - 0x000_F90F_FFFF \| Strongly Ordered \| \| Reserved \| 0x000_F910_0000 - 0x000_FBFF_FFFF \| Unassigned \| \| CPM \| 0x000_FC00_0000 - 0x000_FCFF_FFFF \| Strongly Ordered \| \| FPD slaves \| 0x000_FD00_0000 - 0x000_FDFF_FFFF \| Strongly Ordered \| \| LPD slaves \| 0x000_FE00_0000 - 0x000_FFDF_FFFF \| Strongly Ordered \| \| OCM \| 0x000_FFE0_0000 - 0xFFF_FFFF_FFFF \| Normal WB Cacheable \| \| PMC region 0-3 \| 0x001_0000_0000 - 0x001_1FFF_FFFF \| Strongly Ordered \| \| Reserved \| 0x001_2000_0000 - 0x001_FFFF_FFFF \| Unassigned \| \| ME Array 0-3 \| 0x002_0000_0000 - 0x002_FFFF_FFFF \| Strongly Ordered \| \| Reserved \| 0x003_0000_0000 - 0x003_FFFF_FFFF \| Unassigned \| \| PL- via PS \| 0x004_0000_0000 - 0x005_FFFF_FFFF \| Strongly Ordered \| \| PCIe region 1 \| 0x006_0000_0000 - 0x007_FFFF_FFFF \| Strongly Ordered \| \| DDR \| 0x008_0000_0000 - 0x00F_FFFF_FFFF \| Normal WB Cacheable \| \| Reserved \| 0x010_0000_0000 - 0x03F_FFFF_FFFF \| Unassigned \| \| HBM 0-3 \| 0x040_0000_0000 - 0x07F_FFFF_FFFF \| Strongly Ordered \| \| PCIe region 2 \| 0x080_0000_0000 - 0x0BF_FFFF_FFFF \| Strongly Ordered \| \| DDR \| 0x0C0_0000_0000 - 0x1B7_7FFF_FFFF \| Normal WB Cacheable \| \| Reserved \| 0x1B7_8000_0000 - 0x1FF_FFFF_FFFF \| Unassigned \| \| PL- Via NoC \| 0x200_0000_0000 - 0x3FF_FFFF_FFFF \| Strongly Ordered \| \| PL- Via PS \| 0x400_0000_0000 - 0x4FF_FFFF_FFFF \| Strongly Ordered \| \| DDR CH1-CH3 \| 0x500_0000_0000 - 0x7FF_FFFF_FFFF \| Normal WB Cacheable \| \| PL- Via NoC \| 0x800_0000_0000 - 0xFFF_FFFF_FFFF \| Strongly Ordered \| * @note * * For DDR region 0x0000000000 - 0x007FFFFFFF, a system where DDR is less than * 2GB, region after DDR and before PL is marked as undefined/reserved in * translation table. Region 0xF9100000 - 0xF91FFFFF is reserved memory in * 0x00F9000000 - 0x00F91FFFFF range, but it is marked as strongly ordered * because minimum section size in translation table section is 2MB. * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 7.00 mus 05/21/14 Initial version * 7.00 mus 03/16/19 Updated translation table to mark DDR regions as * memory, based on the DDR size in hdf * 7.1 mus 08/29/19 Updated translation table entries for DDR_CH_1, * DDR_CH_2 and DDR_CH_3 based on respective size in hdf * 7.3 mus 09/10/20 Updated translation table entries for DDR regions, to * support HW designs, where DDR memory is mapped at * address other than DDR region base address. It fixes * CR#1073099. * 8.0 mus 07/06/21 Added support for VERSAL NET * 8.0 mus 10/05/21 Updated VERSAL NET translation table to configure 1 TB address * space (default is 256 TB) when OCM_ELF flag is defined * in compiler flags. * * *****************************************************************************/ #include "xparameters.h" #include "bspconfig.h" .globl MMUTableL0 .globl MMUTableL1 .globl MMUTableL2 .set UNDEF_START, 0 / Base addresses for all DDR regions in Versal SoC / .set DDR_LOW_0_REGION_START_ADDR, 0x0000000000 / 0x0000_0000_0000 / .set DDR_LOW_1_REGION_START_ADDR, 0x800000000 / 0x0008_0000_0000 / .set DDR_LOW_2_REGION_START_ADDR, 0xC000000000 / 0x00C0_0000_0000 / .set DDR_LOW_3_REGION_START_ADDR, 0x10000000000 / 0x0100_0000_0000 / .set DDR_CH_1_REGION_START_ADDR, 0x50000000000 / 0x0500_0000_0000 / .set DDR_CH_2_REGION_START_ADDR, 0x60000000000 / 0x0600_0000_0000 / .set DDR_CH_3_REGION_START_ADDR, 0x70000000000 / 0x0700_0000_0000 / .set reserved, 0x0 / Fault/ .set Memory_NonCacheable, 0x401 / normal non-cacheable / #if EL1_NONSECURE .set Memory, 0x405 \| (2 << 8) \| (0x0) / normal writeback write allocate outer shared read write / #else .set Memory, 0x405 \| (3 << 8) \| (0x0) / normal writeback write allocate inner shared read write / #endif .set Device, 0x409 \| (1 << 53)\| (1 << 54) \|(0x0) / strongly ordered read write non executable/ #ifdef VERSAL_NET .section .mmu_tbl0,"a" MMUTableL0: / * 256 sections each with 512 GB size covers 0 - 128 TB. * 128TB - 256TB is reserved in VERSAL NET address map, * so not defining sections for that region. / .set SECT, MMUTableL1 / 0x0000_0000 - 0x7F_FFFF_FFFF / .8byte SECT + 0x3 #if ! defined (OCM_ELF) .rept 0xff .set SECT, SECT + 0x1000 / 0x80_0000_0000 - 0xFFF_FFFF_FFFF / .8byte SECT + 0x3 .endr #else .set SECT, SECT + 0x1000 / 0x80_0000_0000 - 0xFFF_FFFF_FFFF / .8byte SECT + 0x3 #endif .section .mmu_tbl1,"a" MMUTableL1: / * For first 4GB of address space provide granularity * of 2MB. / .set SECT, MMUTableL2 / 0x0000_0000 - 0x3FFF_FFFF / .8byte SECT + 0x3 / 1GB DDR / .rept 0x3 / 0x4000_0000 - 0x1_3FFF_FFFF / .set SECT, SECT + 0x1000 / DDR, PS_LPD_AFI_FS, PCIE_REGION0, PS_FPD_AFI_FS, OCM, xSPI, FPD_STM_CORESIGHT,/ .8byte SECT + 0x3 / FPD GIC, PS_FPD_CMN, PMC, CPM, FPD slaves, LPD slaves, PMC_ALIAS_REGION0-3, FPD_PKI / .endr / HNIC, Multimedia tiles / .set SECT,0x100000000 .rept 0x1C / 0x1_0000_0000 - 0x1_FFFF_FFFF / .8byte SECT + reserved / 28GB Reserved / .set SECT, SECT + 0x40000000 .endr / TODO: Mark DDR_CH0_MED as normal memory based on HW design / .rept 0x20 / 0x2_0000_0000 - 0x2_FFFF_FFFF / .8byte SECT + reserved / 32GB DDR_CH0_MED marked as reserved for now / .set SECT, SECT + 0x40000000 .endr .rept 0x40 / 0x3_0000_0000 - 0x3_FFFF_FFFF / .8byte SECT + reserved / 64GB Reserved / .set SECT, SECT + 0x40000000 .endr .rept 0x80 / 0x4_0000_0000 - 0x7_FFFF_FFFF / .8byte SECT + Device / 128GB C2C_MED / .set SECT, SECT + 0x40000000 .endr / TODO: Mark HBM regions as normal memory based on the HW design / .rept 0x100 / 0x10_0000_0000 - 0x3F_FFFF_FFFF / .8byte SECT + reserved / 256GB device / .set SECT, SECT + 0x40000000 .endr .rept 0x100 / 0x40_0000_0000 - 0x7F_FFFF_FFFF / .8byte SECT + reserved / 256GB reserved / .set SECT, SECT + 0x40000000 .endr / TODO: Mark this region as normal memory based on HW design / .rept 0x100 / 0x80_0000_0000 - 0xBF_FFFF_FFFF / .8byte SECT + reserved / 790GB DDR (DDR_CH0_HIGH_0: 256GB + DDR_CH0_HIGH_1: 734GB) / .set SECT, SECT + 0x40000000 .endr #if ! defined (OCM_ELF) .rept 0x234 / 0x80_0000_0000 - 0xBF_FFFF_FFFF / .8byte SECT + reserved / 790GB reserved / .set SECT, SECT + 0x40000000 .endr .rept 0x4 / 0x200_0000_0000 - 0x200_FFFF_FFFF / .8byte SECT + Device / 4GB ME Programming / .set SECT, SECT + 0x40000000 .endr .rept 0x4 / 0x201_0000_0000 - 0x201_FFFF_FFFF / .8byte SECT + reserved / 4GB reserved / .set SECT, SECT + 0x40000000 .endr .rept 0x7 / 0x202_0000_0000 - 0x203_BFFF_FFFF / .8byte SECT + Device / 2GB PS_FPD_AFI_FS_CONFIG + 2GB C2C_CONFIG + 2GB PL_VIA_NOC_CONFIG + 512MB PMC_ALIAS0-3 / .set SECT, SECT + 0x40000000 .endr .rept 0x1 / 0x203_C000_0000 - 0x203_FFFF_FFFF / .8byte SECT + reserved / 1GB reserved / .set SECT, SECT + 0x40000000 .endr .rept 0x1 / 0x204_0000_0000 - 0x204_3FFF_FFFF / .8byte SECT + Device / 8MB PKI, 1016MB reserved from next section / .set SECT, SECT + 0x40000000 .endr .rept 0x7EF / 0x204_4000_0000 - 0x3ffffffffff / .8byte SECT + Device / 2031GB reserved / .set SECT, SECT + 0x40000000 .endr .rept 0x400 / 0x400_0000_0000 - 0x4FF_FFFF_FFFF / .8byte SECT + Device / 1TB PS_FPD_AFI_FS_HIGH / .set SECT, SECT + 0x40000000 .endr / TODO: Mark this region as normal memory based on the HW design / .rept 0xc00 / 0x500_0000_0000 - 0x7FF_FFFF_FFFF / .8byte SECT + reserved / 3TB DDR: DDR_CH1, DDr_CH2 and DDR_CH3 each with 1TB / .set SECT, SECT + 0x40000000 .endr .rept 0x2000 / 0x800_0000_0000 - 0xFFF_FFFF_FFFF / .8byte SECT + Device / 8TB PL_VIA_NOC_HIGH/ .set SECT, SECT + 0x40000000 .endr .rept 0x2000 / 0x800_0000_0000 - 0xFFF_FFFF_FFFF / .8byte SECT + Device / 8TB CPM_CDX_DPU_HIGH / .set SECT, SECT + 0x40000000 .endr / TODO: Mark this region as normal memory based on the HW design / .rept 0x1800 / 0x400_0000_0000 - 0x4FF_FFFF_FFFF / .8byte SECT + reserved / 6TB DDR: 12 DDR regions (DDR_CH4 to DDR_CH15) each of size 512GB / .set SECT, SECT + 0x40000000 .endr .rept 0x800 / 0x800_0000_0000 - 0xFFF_FFFF_FFFF / .8byte SECT + reserved / 2TB reserved / .set SECT, SECT + 0x40000000 .endr .rept 0x4000 / 0x800_0000_0000 - 0xFFF_FFFF_FFFF / .8byte SECT + Device / 16TB C2C_HIGH / .set SECT, SECT + 0x40000000 .endr .rept 0x4000 / 0x800_0000_0000 - 0xFFF_FFFF_FFFF / .8byte SECT + reserved / 16TB reserved / .set SECT, SECT + 0x40000000 .endr .rept 0x10000 / 0x800_0000_0000 - 0xFFF_FFFF_FFFF / .8byte SECT + Device / 64TB PSX Socket 1 / .set SECT, SECT + 0x40000000 .endr #endif .section .mmu_tbl2,"a" MMUTableL2: .set SECT, 0 / TODO: Configure this region as normal memory/reserved based on HW design / .rept 0x400 / 2GB DDR 0x0 - 0x80000000 / .8byte SECT + Memory_NonCacheable .set SECT, SECT+0x200000 .endr .rept 0x0100 / 0x8000_0000 - 0x9FFF_FFFF / .8byte SECT + Device / 512MB PS_LPD_AFI_FS / .set SECT, SECT+0x200000 .endr .rept 0x080 / 0xA000_0000 - 0xAFFF_FFFF / .8byte SECT + reserved / 256MB PCIE_REGION / .set SECT, SECT+0x200000 .endr .rept 0x040 / 0xB00_0000 - 0xB7FF_FFFF / .8byte SECT + Device / 128MB PS_FPD_AFI_FS / .set SECT, SECT+0x200000 .endr .rept 0x01F / 0xB800_0000 - 0xBBDF_FFFF / .8byte SECT + reserved / 62MB reserved / .set SECT, SECT+0x200000 .endr / * Note: 1 MB OCM 0xBBF0_0000 - 0xBBFF_FFFF, * 0xBBE0_0000 - 0XBBEF_FFFF marked as normal * memory incorrectly due to 2 MB granularity limitation / .rept 0x01 / 0xBBE0_0000 - 0xBBFF_FFFF / .8byte SECT + Memory_NonCacheable / 1 MB OCM 0xBBF0_0000 - 0xBBFF_FFFF, 0xBBE0_0000 - 0XBBEF_FFFF marked as normal memory incorrectly / .set SECT, SECT+0x200000 .endr .rept 0x020 / 0xB000_0000 - 0xBFFF_FFFF / .8byte SECT + reserved / 64MB reserved / .set SECT, SECT+0x200000 .endr .rept 0x100 / 0xE000_0000 - 0xEFFF_FFFF / .8byte SECT + Device / 512MB xSPI / .set SECT, SECT+0x200000 .endr .rept 0x08 / 0xE000_0000 - 0xEFFF_FFFF / .8byte SECT + Device / 16MB FPD_STM_CORESIGHT / .set SECT, SECT+0x200000 .endr .rept 0x08 / 0xe1000000 - 0xE1FF_FFFF / .8byte SECT + reserved / 16MB reserved / .set SECT, SECT+0x200000 .endr .rept 0x02 / 0xE200_0000 - 0xE23F_FFFF / .8byte SECT + Device / 4MB GIC / .set SECT, SECT+0x200000 .endr .rept 0xE / 0xE240_0000 - 0xE3FF_FFFF / .8byte SECT + reserved / 28MB reserved / .set SECT, SECT+0x200000 .endr .rept 0x08 / 0xE400_0000 - 0xE4FF_FFFF_ / .8byte SECT + Device / 16MB CPM / .set SECT, SECT+0x200000 .endr .rept 0x8 / 0xE500_0000 - 0xE5FF_FFFF / .8byte SECT + reserved / 16MB reserved / .set SECT, SECT+0x200000 .endr .rept 0x4 / 0xE600_0000 - 0xE67F_FFFF / .8byte SECT + Device / 8MB HNIC / .set SECT, SECT+0x200000 .endr .rept 0xC / 0xE680_0000 - 0xE7FF_FFFF / .8byte SECT + reserved / 24MB reserved / .set SECT, SECT+0x200000 .endr .rept 0x4 / 0xE800_0000 - 0xE87F_FFFF / .8byte SECT + Device / 8MB Multimedia tiles / .set SECT, SECT+0x200000 .endr .rept 0xC / 0xE880_0000 - 0xE9FF_FFFF / .8byte SECT + reserved / 24MB reserved / .set SECT, SECT+0x200000 .endr .rept 0x18 / 0xEA00_0000 - 0xECFF_FFFF / .8byte SECT + Device / 32MB LPD_SLAVES 16MB FPD_SLAVES / .set SECT, SECT+0x200000 .endr .rept 0x18 / 0xED00_0000 - 0xEFFF_FFFF / .8byte SECT + reserved / 24MB reserved / .set SECT, SECT+0x200000 .endr .rept 0x40 / 0xF000_0000 - 0xF7FF_FFFF / .8byte SECT + Device / 128MB PMC / .set SECT, SECT+0x200000 .endr .rept 0x20 / 0xF800_0000 - 0xFBFF_FFFF / .8byte SECT + Device / 64MB PS_FPD_CMN / .set SECT, SECT+0x200000 .endr .rept 0x20 / 0xFC00_0000 - 0xFFFF_FFFF / .8byte SECT + reserved / 32MB reserved / .set SECT, SECT+0x200000 .endr .end #else .section .mmu_tbl0,"a" MMUTableL0: .set SECT, MMUTableL1 / 0x0000_0000 - 0x7F_FFFF_FFFF / .8byte SECT + 0x3 .rept 0x1f .set SECT, SECT + 0x1000 / 0x80_0000_0000 - 0xFFF_FFFF_FFFF / .8byte SECT + 0x3 .endr .section .mmu_tbl1,"a" MMUTableL1: .set SECT, MMUTableL2 / 0x0000_0000 - 0x3FFF_FFFF / .8byte SECT + 0x3 / 1GB DDR / .rept 0x4 / 0x4000_0000 - 0x1_3FFF_FFFF / .set SECT, SECT + 0x1000 /1GB DDR, 512MB LPD_AFI_FS, 448MB FPD_AFI_0, 512MB QSPI, 256MB PCIe region 0, PMC 128MB, GIC 1 MB, reserved 47MB, 2GB other devices and memory, 512 MB PMC / .8byte SECT + 0x3 .endr .set SECT,0x140000000 .rept 0x3 / 0x1_4000_0000 - 0x1_FFFF_FFFF / .8byte SECT + reserved / 3GB Reserved / .set SECT, SECT + 0x40000000 .endr .rept 0x4 / 0x2_0000_0000 - 0x2_FFFF_FFFF / .8byte SECT + Device / 4GB ME Array 0-3/ .set SECT, SECT + 0x40000000 .endr .rept 0x4 / 0x3_0000_0000 - 0x3_FFFF_FFFF / .8byte SECT + reserved / 4GB Reserved / .set SECT, SECT + 0x40000000 .endr .rept 0x10 / 0x4_0000_0000 - 0x7_FFFF_FFFF / .8byte SECT + Device / 8GB PL - via PS, 8GB PCIe region1 / .set SECT, SECT + 0x40000000 .endr .set UNDEF_START, 0 #ifdef XPAR_AXI_NOC_DDR_LOW_1_BASEADDR .set DDR_1_START, XPAR_AXI_NOC_DDR_LOW_1_BASEADDR .set DDR_1_END, XPAR_AXI_NOC_DDR_LOW_1_HIGHADDR .if DDR_1_START > DDR_LOW_1_REGION_START_ADDR .set UNDEF_START, (DDR_1_START - DDR_LOW_1_REGION_START_ADDR) .set UNDEF_START, (UNDEF_START)/0x40000000 .endif .set DDR_1_SIZE, (DDR_1_END - DDR_1_START)+1 .if DDR_1_SIZE > 0x800000000 / If DDR size is larger than 32GB, truncate to 32GB / .set DDR_1_REG, 0x20 .else .set DDR_1_REG, DDR_1_SIZE/0x40000000 .endif #else .set DDR_1_REG, 0 #warning "There's no DDR_1 in the HW design. MMU translation table marks 32 GB DDR address space as undefined" #endif .set UNDEF_1_REG, (0x20 - DDR_1_REG - UNDEF_START) .rept UNDEF_START / reserved for region where ddr is absent / .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept DDR_1_REG / DDR based on size in hdf/ .8byte SECT + Memory .set SECT, SECT+0x40000000 .endr .rept UNDEF_1_REG / reserved for region where ddr is absent / .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept 0xC0 / 0x10_0000_0000 - 0x3F_FFFF_FFFF / .8byte SECT + reserved / 192GB Reserved / .set SECT, SECT + 0x40000000 .endr .rept 0x100 / 0x40_0000_0000 - 0x7F_FFFF_FFFF / .8byte SECT + Device / 256GB HBM 0-3/ .set SECT, SECT + 0x40000000 .endr .rept 0x100 / 0x80_0000_0000 - 0xBF_FFFF_FFFF / .8byte SECT + Device / 256GB PCIe 2 / .set SECT, SECT + 0x40000000 .endr .set UNDEF_START, 0 #ifdef XPAR_AXI_NOC_DDR_LOW_2_BASEADDR .set DDR_2_START, XPAR_AXI_NOC_DDR_LOW_2_BASEADDR .set DDR_2_END, XPAR_AXI_NOC_DDR_LOW_2_HIGHADDR .if DDR_2_START > DDR_LOW_2_REGION_START_ADDR .set UNDEF_START, (DDR_2_START - DDR_LOW_2_REGION_START_ADDR) .set UNDEF_START, (UNDEF_START)/0x40000000 .endif .set DDR_2_SIZE, (DDR_2_END - DDR_2_START)+1 .if DDR_2_SIZE > 0x4000000000 / If DDR size is larger than 256 GB, truncate to 256GB / .set DDR_2_REG, 0x100 .else .set DDR_2_REG, DDR_2_SIZE/0x40000000 .endif #else .set DDR_2_REG, 0 #warning "There's no DDR_LOW_2 in the HW design. MMU translation table marks 256 GB DDR address space as undefined" #endif .set UNDEF_2_REG, (0x100 - DDR_2_REG - UNDEF_START) .rept UNDEF_START / reserved for region where ddr is absent / .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept DDR_2_REG / DDR based on size in hdf 0xC0_0000_0000 - 0xFF_FFFF_FFFF / .8byte SECT + Memory / Maximum DDR region size - 256GB / .set SECT, SECT + 0x40000000 .endr .rept UNDEF_2_REG / reserved for region where ddr is absent / .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .set UNDEF_START, 0 #ifdef XPAR_AXI_NOC_DDR_LOW_3_BASEADDR .set DDR_3_START, XPAR_AXI_NOC_DDR_LOW_3_BASEADDR .set DDR_3_END, XPAR_AXI_NOC_DDR_LOW_3_HIGHADDR .if DDR_3_START > DDR_LOW_3_REGION_START_ADDR .set UNDEF_START, (DDR_3_START - DDR_LOW_3_REGION_START_ADDR) .set UNDEF_START, (UNDEF_START)/0x40000000 .endif .set DDR_3_SIZE, (DDR_3_END - DDR_3_START)+1 .if DDR_3_SIZE > 0xB780000000 / If DDR size is larger than 734 GB, truncate to 734GB / .set DDR_3_REG, 0x2de .else .set DDR_3_REG, DDR_3_SIZE/0x40000000 .endif #else .set DDR_3_REG, 0 #warning "There's no DDR_LOW_3 in the HW design. MMU translation table marks 734 GB DDR address space as undefined" #endif .set UNDEF_3_REG, (0x2de - DDR_3_REG - UNDEF_START) .rept UNDEF_START / reserved for region where ddr is absent / .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept DDR_3_REG / DDR based on size in hdf 0x100_0000_0000 - 0x1B7_7FFF_FFFF / .8byte SECT + Memory / Maximum DDR region size - 734GB DDR / .set SECT, SECT + 0x40000000 .endr .rept UNDEF_3_REG / reserved for region where ddr is absent / .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept 0x122 / 0x1B7_8000_0000 - 0x1FF_FFFF_FFFF / .8byte SECT + reserved / 290GB reserved / .set SECT, SECT + 0x40000000 .endr .rept 0x800 / 0x200_0000_0000 - 0x3FF_FFFF_FFFF / .8byte SECT + Device / 2TB PL- via NoC / .set SECT, SECT + 0x40000000 .endr .rept 0x400 / 0x400_0000_0000 - 0x4FF_FFFF_FFFF / .8byte SECT + Device / 1TB PL- via PS / .set SECT, SECT + 0x40000000 .endr .set UNDEF_START, 0 #ifdef XPAR_AXI_NOC_DDR_CH_1_BASEADDR .set DDR_CH_1_START, XPAR_AXI_NOC_DDR_CH_1_BASEADDR .set DDR_CH_1_END, XPAR_AXI_NOC_DDR_CH_1_HIGHADDR .if DDR_CH_1_START > DDR_CH_1_REGION_START_ADDR .set UNDEF_START, (DDR_CH_1_START - DDR_CH_1_REGION_START_ADDR) .set UNDEF_START, (UNDEF_START)/0x40000000 .endif .set DDR_CH_1_SIZE, (DDR_CH_1_END - DDR_CH_1_START)+1 .if DDR_CH_1_SIZE > 0x010000000000 / If DDR size is larger than 1TB, truncate to 1 TB / .set DDR_CH_1_REG, 0x400 / 0x500_0000_0000 - 0x5FF_FFFF_FFFF / .else .set DDR_CH_1_REG, DDR_CH_1_SIZE/0x40000000 .endif #else .set DDR_CH_1_REG, 0 #warning "There's no DDR_CH_1 in the HW design. MMU translation table marks 1 TB DDR address space as undefined" #endif .set UNDEF_CH_1_REG, (0x400 - DDR_CH_1_REG - UNDEF_START) .rept UNDEF_START / reserved for region where ddr is absent / .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept DDR_CH_1_REG / DDR based on size in hdf, Max size 1 TB/ .8byte SECT + Memory .set SECT, SECT+0x40000000 .endr .rept UNDEF_CH_1_REG / reserved for region where ddr is absent / .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .set UNDEF_START, 0 #ifdef XPAR_AXI_NOC_DDR_CH_2_BASEADDR .set DDR_CH_2_START, XPAR_AXI_NOC_DDR_CH_2_BASEADDR .set DDR_CH_2_END, XPAR_AXI_NOC_DDR_CH_2_HIGHADDR .if DDR_CH_2_START > DDR_CH_2_REGION_START_ADDR .set UNDEF_START, (DDR_CH_2_START - DDR_CH_2_REGION_START_ADDR) .set UNDEF_START, (UNDEF_START)/0x40000000 .endif .set DDR_CH_2_SIZE, (DDR_CH_2_END - DDR_CH_2_START)+1 .if DDR_CH_2_SIZE > 0x010000000000 / If DDR_CH_2 size is larger than 1TB, truncate to 1 TB / .set DDR_CH_2_REG, 0x400 / 0x600_0000_0000 - 0x6FF_FFFF_FFFF / .else .set DDR_CH_2_REG, DDR_CH_2_SIZE/0x40000000 .endif #else .set DDR_CH_2_REG, 0 #warning "There's no DDR_CH_2 in the HW design. MMU translation table marks 1 TB DDR address space as undefined" #endif .set UNDEF_CH_2_REG, (0x400 - DDR_CH_2_REG - UNDEF_START) .rept UNDEF_START / reserved for region where ddr is absent / .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept DDR_CH_2_REG / DDR based on size in hdf, Max size 1 TB/ .8byte SECT + Memory .set SECT, SECT+0x40000000 .endr .rept UNDEF_CH_2_REG / reserved for region where ddr is absent / .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .set UNDEF_START, 0 #ifdef XPAR_AXI_NOC_DDR_CH_3_BASEADDR .set DDR_CH_3_START, XPAR_AXI_NOC_DDR_CH_3_BASEADDR .set DDR_CH_3_END, XPAR_AXI_NOC_DDR_CH_3_HIGHADDR .if DDR_CH_3_START > DDR_CH_3_REGION_START_ADDR .set UNDEF_START, (DDR_CH_3_START - DDR_CH_3_REGION_START_ADDR) .set UNDEF_START, (UNDEF_START)/0x40000000 .endif .set DDR_CH_3_SIZE, (DDR_CH_3_END - DDR_CH_3_START)+1 .if DDR_CH_3_SIZE > 0x010000000000 / If DDR_CH_3 size is larger than 1TB, truncate to 1 TB / .set DDR_CH_3_REG, 0x400 / 0x700_0000_0000 - 0x7FF_FFFF_FFFF / .else .set DDR_CH_3_REG, DDR_CH_3_SIZE/0x40000000 .endif #else .set DDR_CH_3_REG, 0 #warning "There's no DDR_CH_3 in the HW design. MMU translation table marks 1 TB DDR address space as undefined" #endif .set UNDEF_CH_3_REG, (0x400 - DDR_CH_3_REG - UNDEF_START) .rept UNDEF_START / reserved for region where ddr is absent / .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept DDR_CH_3_REG / DDR based on size in hdf, Max size 1 TB/ .8byte SECT + Memory .set SECT, SECT+0x40000000 .endr .rept UNDEF_CH_3_REG / reserved for region where ddr is absent / .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept 0x2000 / 0x800_0000_0000 - 0xFFF_FFFF_FFFF / .8byte SECT + Device / 8TB PL- via NoC/ .set SECT, SECT + 0x40000000 .endr .section .mmu_tbl2,"a" MMUTableL2: .set SECT, 0 .set UNDEF_START, 0 #ifdef XPAR_AXI_NOC_DDR_LOW_0_BASEADDR .set DDR_0_START, XPAR_AXI_NOC_DDR_LOW_0_BASEADDR .set DDR_0_END, XPAR_AXI_NOC_DDR_LOW_0_HIGHADDR .if DDR_0_START > DDR_LOW_0_REGION_START_ADDR .set UNDEF_START, (DDR_0_START - DDR_LOW_0_REGION_START_ADDR) .set UNDEF_START, (UNDEF_START)/0x200000 .endif .set DDR_0_SIZE, (DDR_0_END - DDR_0_START)+1 .if DDR_0_SIZE > 0x80000000 / If DDR size is larger than 2GB, truncate to 2GB / .set DDR_0_REG, 0x400 .else .set DDR_0_REG, DDR_0_SIZE/0x200000 .endif #else .set DDR_0_REG, 0 #warning "There's no DDR_0 in the HW design. MMU translation table marks 2 GB DDR address space as undefined" #endif .set UNDEF_0_REG, (0x400 - DDR_0_REG - UNDEF_START) .rept UNDEF_START / reserved for region where ddr is absent / .8byte SECT + reserved .set SECT, SECT+0x200000 .endr .rept DDR_0_REG / DDR based on size in hdf/ .8byte SECT + Memory .set SECT, SECT+0x200000 .endr .rept UNDEF_0_REG / reserved for region where ddr is absent / .8byte SECT + reserved .set SECT, SECT+0x200000 .endr .rept 0x0100 / 0x8000_0000 - 0xBFFF_FFFF / .8byte SECT + Device / 512MB LPD AFI / .set SECT, SECT+0x200000 .endr .rept 0x020 / 0xA000_0000 - 0xA3FF_FFFF / .8byte SECT + reserved / 64MB reserved/ .set SECT, SECT+0x200000 .endr .rept 0x60 / 0xA400_0000 - 0xAFFF_FFFF / .8byte SECT + Device / 192MB FPD AFI 0 / .set SECT, SECT+0x200000 .endr .rept 0x80 / 0xB000_0000 - 0xBFFF_FFFF / .8byte SECT + Device / 192MB FPD AFI 1 / .set SECT, SECT+0x200000 .endr .rept 0x100 / 0xC000_0000 - 0xDFFF_FFFF / .8byte SECT + Device / 512MB QSPI / .set SECT, SECT+0x200000 .endr .rept 0x080 / 0xE000_0000 - 0xEFFF_FFFF / .8byte SECT + Device / 256MB lower PCIe / .set SECT, SECT+0x200000 .endr .rept 0x040 / 0xF000_0000 - 0xF7FF_FFFF / .8byte SECT + Device / 128MB PMC / .set SECT, SECT+0x200000 .endr .rept 0x08 / 0xF800_0000 - 0xF8FF_FFFF / .8byte SECT + Device / 16MB coresight / .set SECT, SECT+0x200000 .endr / 1MB GIC is marked for 2MB region as the minimum block size in translation table is 2MB and adjacent 47MB reserved region is converted to 46MB / .8byte SECT + Device / 0xF910_0000 - 0xF90F_FFFF / / Reserved 46MB 0xF91FFFFF - 0xFBFFFFFF/ .rept 0x17 / 0xF91F_FFFF - 0xFBFF_FFFF / .set SECT, SECT+0x200000 .8byte SECT + reserved / 46MB reserved / .endr .rept 0x1F / 0xFC00_0000 - 0xFFDF_FFFF / .set SECT, SECT+0x200000 .8byte SECT + Device / 16MB CPM,16MB FPS, 30MB LPS slaves / .endr .set SECT, SECT+0x200000 / 0xFFE0_0000 - 0xFFFF_FFFF/ .8byte SECT + Memory /2MB OCM/TCM/ .rept 0x100 / 0x1_0000_0000 - 0x1_1FFF_FFFF / .set SECT, SECT+0x200000 .8byte SECT + Device / 512MB PMC 0-3 / .endr .rept 0x100 / 0x1_2000_0000 - 0x1_3FFF_FFFF / .set SECT, SECT+0x200000 .8byte SECT + reserved / 512MB reserved / .endr .end #endif /* * @} End of "addtogroup a53_64_boot_code". */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	8,548	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/platform/ZynqMP/armclang/translation_table.S	;/****************************************************************************** ;* Copyright (c) 2018 - 2020 Xilinx, Inc. All rights reserved. ;* SPDX-License-Identifier: MIT ;****************************************************************************/ ;/*************************************************************************/ ;/ ;* @file translation_table.s ;* ;* @addtogroup a53_64_boot_code ;* @{ ;* <h2> translation_table.S </h2> ;* translation_table.S contains a static page table required by MMU for ;* cortex-A53. This translation table is flat mapped (input address = output ;* address) with default memory attributes defined for zynq ultrascale+ ;* architecture. It utilizes translation granule size of 4KB with 2MB section ;* size for initial 4GB memory and 1GB section size for memory after 4GB. ;* The overview of translation table memory attributes is described below. ;* ;\| \| Memory Range \| Definition in Translation Table \| ;\|-----------------------\|-----------------------------\|-----------------------------------\| ;\| DDR \| 0x0000000000 - 0x007FFFFFFF \| Normal write-back Cacheable \| ;\| PL \| 0x0080000000 - 0x00BFFFFFFF \| Strongly Ordered \| ;\| QSPI, lower PCIe \| 0x00C0000000 - 0x00EFFFFFFF \| Strongly Ordered \| ;\| Reserved \| 0x00F0000000 - 0x00F7FFFFFF \| Unassigned \| ;\| STM Coresight \| 0x00F8000000 - 0x00F8FFFFFF \| Strongly Ordered \| ;\| GIC \| 0x00F9000000 - 0x00F91FFFFF \| Strongly Ordered \| ;\| Reserved \| 0x00F9200000 - 0x00FCFFFFFF \| Unassigned \| ;\| FPS, LPS slaves \| 0x00FD000000 - 0x00FFBFFFFF \| Strongly Ordered \| ;\| CSU, PMU \| 0x00FFC00000 - 0x00FFDFFFFF \| Strongly Ordered \| ;\| TCM, OCM \| 0x00FFE00000 - 0x00FFFFFFFF \| Normal inner write-back cacheable \| ;\| Reserved \| 0x0100000000 - 0x03FFFFFFFF \| Unassigned \| ;\| PL, PCIe \| 0x0400000000 - 0x07FFFFFFFF \| Strongly Ordered \| ;\| DDR \| 0x0800000000 - 0x0FFFFFFFFF \| Normal inner write-back cacheable \| ;\| PL, PCIe \| 0x1000000000 - 0xBFFFFFFFFF \| Strongly Ordered \| ;\| Reserved \| 0xC000000000 - 0xFFFFFFFFFF \| Unassigned \| ; ;* @note ;* ;* For DDR region 0x0000000000 - 0x007FFFFFFF, a system where DDR is less than ;* 2GB, region after DDR and before PL is marked as undefined/reserved in ;* translation table. Region 0xF9100000 - 0xF91FFFFF is reserved memory in ;* 0x00F9000000 - 0x00F91FFFFF range, but it is marked as strongly ordered ;* because minimum section size in translation table section is 2MB. Region ;* 0x00FFC00000 - 0x00FFDFFFFF contains CSU and PMU memory which are marked as ;* Device since it is less than 1MB and falls in a region with device memory. ;* ;* <pre> ;* MODIFICATION HISTORY: ;* ;* Ver Who Date Changes ;* ----- ---- -------- --------------------------------------------------- ;* 7.0 cjp 02/26/19 First release ;* ;*****************************************************************************/ #include "xparameters.h" #include "bspconfig.h" EXPORT MMUTableL0 EXPORT MMUTableL1 EXPORT MMUTableL2 GBLA abscnt GBLA count GBLA sect ; Fault Reserved EQU 0 #if (EL1_NONSECURE == 1) Memory EQU 0x405:OR:(2:SHL:8):OR:0x0 ; Normal writeback write allocate outer shared read write #else Memory EQU 0x405:OR:(3:SHL:8):OR:0x0 ; Normal writeback write allocate inner shared read write #endif Device EQU 0x409:OR:(1:SHL:53):OR:(1:SHL:54):OR:0x0 ; Strongly ordered read write non executable AREA \|.mmu_tbl0\|, CODE, ALIGN=12 MMUTableL0 DCQU MMUTableL1+0x3 ; 0x0000_0000 - 0x7F_FFFF_FFFF DCQU MMUTableL1+0x1000+0x3 ; 0x80_0000_0000 - 0xFF_FFFF_FFFF AREA \|.mmu_tbl1\|, CODE, ALIGN=12 MMUTableL1 ; ; 0x4000_0000 - 0xFFFF_FFFF ; 1GB DDR, 1GB PL, 2GB other devices n memory ; count SETA 0 WHILE count<0x4 DCQU MMUTableL2+count0x1000+0x3 count SETA count+1 WEND Fixlocl1 EQU 0x100000000 abscnt SETA 0 ; ; 0x0001_0000_0000 - 0x0003_FFFF_FFFF ; 12GB Reserved ; count SETA 0 WHILE count<0xc DCQU Fixlocl1+abscnt0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0x0004_0000_0000 - 0x0007_FFFF_FFFF ; 8GB PL, 8GB PCIe ; count SETA 0 WHILE count<0x10 DCQU Fixlocl1+abscnt0x40000000+Device count SETA count+1 abscnt SETA abscnt+1 WEND #ifdef XPAR_PSU_DDR_1_S_AXI_BASEADDR DDR_1_START EQU XPAR_PSU_DDR_1_S_AXI_BASEADDR DDR_1_END EQU XPAR_PSU_DDR_1_S_AXI_HIGHADDR DDR_1_SIZE EQU (DDR_1_END - DDR_1_START + 1) #if (DDR_1_SIZE > 0x800000000) DDR_1_REG EQU 0x20 ; If DDR size is larger than 32GB, truncate to 32GB #else DDR_1_REG EQU DDR_1_SIZE / 0x40000000 #endif #else DDR_1_REG EQU 0 #endif UNDEF_1_REG EQU (0x20 - DDR_1_REG) ; DDR based on size in hdf count SETA 0 WHILE count<DDR_1_REG DCQU Fixlocl1+abscnt0x40000000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_1_REG DCQU Fixlocl1+abscnt0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0x0010_0000_0000 - 0x007F_FFFF_FFFF ; 448 GB PL ; count SETA 0 WHILE count<0x1C0 DCQU Fixlocl1 + abscnt * 0x40000000 + Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0x0080_0000_0000 - 0x00BF_FFFF_FFFF ; 256GB PCIe ; count SETA 0 WHILE count<0x100 DCQU Fixlocl1+abscnt0x40000000+Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0x00C0_0000_0000 - 0x00FF_FFFF_FFFF ; 256GB Reserved ; count SETA 0 WHILE count<0x100 DCQU Fixlocl1+abscnt0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND AREA \|.mmu_tbl2\|, CODE, ALIGN=12 MMUTableL2 abscnt SETA 0 #ifdef XPAR_PSU_DDR_0_S_AXI_BASEADDR DDR_0_START EQU XPAR_PSU_DDR_0_S_AXI_BASEADDR DDR_0_END EQU XPAR_PSU_DDR_0_S_AXI_HIGHADDR DDR_0_SIZE EQU (DDR_0_END - DDR_0_START + 1) #if (DDR_0_SIZE > 0x80000000) DDR_0_REG EQU 0x400 ; If DDR size is larger than 2GB, truncate to 2GB #else DDR_0_REG EQU DDR_0_SIZE / 0x200000 #endif #else DDR_0_REG EQU 0 #endif UNDEF_0_REG EQU (0x400 - DDR_0_REG) ; DDR based on size in hdf count SETA 0 WHILE count<DDR_0_REG DCQU abscnt0x200000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_0_REG DCQU abscnt0x200000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0x8000_0000 - 0xBFFF_FFFF ; 1GB lower PL ; count SETA 0 WHILE count<0x0200 DCQU abscnt0x200000+Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0xC000_0000 - 0xDFFF_FFFF ; 512MB QSPI ; count SETA 0 WHILE count<0x0100 DCQU abscnt0x200000+Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0xE000_0000 - 0xEFFF_FFFF ; 256MB lower PCIe ; count SETA 0 WHILE count<0x080 DCQU abscnt0x200000+Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0xF000_0000 - 0xF7FF_FFFF ; 128MB Reserved ; count SETA 0 WHILE count<0x040 DCQU abscnt0x200000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0xF800_0000 - 0xF8FF_FFFF ; 16MB Coresight ; count SETA 0 WHILE count<0x8 DCQU abscnt0x200000+Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 1MB RPU LLP is marked for 2MB region as the minimum block size in translation ; table is 2MB and adjacent 63MB reserved region is converted to 62MB ; ; ; 0xF900_0000 - 0xF91F_FFFF ; 2MB RPU low latency port ; count SETA 0 WHILE count<0x1 DCQU abscnt0x200000+Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0xF920_0000 - 0xFCFF_FFFF ; 62MB Reserved ; count SETA 0 WHILE count<0x1f DCQU abscnt0x200000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0xFD00_0000 - 0xFDFF_FFFF ; 16MB FPS ; count SETA 0 WHILE count<0x8 DCQU abscnt0x200000+Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0xFE00_0000 - 0xFFBF_FFFF ; 28MB LPS ; count SETA 0 WHILE count<0xE DCQU abscnt0x200000+Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0xFFC0_0000 - 0xFFDF_FFFF ; 2MB PMU/CSU ; DCQU abscnt0x200000+Device abscnt SETA abscnt+1 ; ; 0xFFE0_0000 - 0xFFFF_FFFF ; 2MB OCM/TCM ; DCQU abscnt*0x200000+Memory END ; ; @} End of "addtogroup a53_64_boot_code" ;
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	8,360	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/platform/ZynqMP/gcc/translation_table.S	/****************************************************************************** * Copyright (c) 2014 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file translation_table.s * * @addtogroup a53_64_boot_code * @{ * <h2> translation_table.S </h2> * translation_table.S contains a static page table required by MMU for * cortex-A53. This translation table is flat mapped (input address = output * address) with default memory attributes defined for zynq ultrascale+ * architecture. It utilizes translation granual size of 4KB with 2MB section * size for initial 4GB memory and 1GB section size for memory after 4GB. * The overview of translation table memory attributes is described below. * \| \| Memory Range \| Definition in Translation Table \| \|-----------------------\|-----------------------------\|-----------------------------------\| \| DDR \| 0x0000000000 - 0x007FFFFFFF \| Normal write-back Cacheable \| \| PL \| 0x0080000000 - 0x00BFFFFFFF \| Strongly Ordered \| \| QSPI, lower PCIe \| 0x00C0000000 - 0x00EFFFFFFF \| Strongly Ordere \| \| Reserved \| 0x00F0000000 - 0x00F7FFFFFF \| Unassigned \| \| STM Coresight \| 0x00F8000000 - 0x00F8FFFFFF \| Strongly Ordered \| \| GIC \| 0x00F9000000 - 0x00F91FFFFF \| Strongly Ordered \| \| Reserved \| 0x00F9200000 - 0x00FCFFFFFF \| Unassigned \| \| FPS, LPS slaves \| 0x00FD000000 - 0x00FFBFFFFF \| Strongly Ordered \| \| CSU, PMU \| 0x00FFC00000 - 0x00FFDFFFFF \| Strongly Ordered \| \| TCM, OCM \| 0x00FFE00000 - 0x00FFFFFFFF \| Normal inner write-back cacheable \| \| Reserved \| 0x0100000000 - 0x03FFFFFFFF \| Unassigned \| \| PL, PCIe \| 0x0400000000 - 0x07FFFFFFFF \| Strongly Ordered \| \| DDR \| 0x0800000000 - 0x0FFFFFFFFF \| Normal inner write-back cacheable \| \| PL, PCIe \| 0x1000000000 - 0xBFFFFFFFFF \| Strongly Ordered \| \| Reserved \| 0xC000000000 - 0xFFFFFFFFFF \| Unassigned \| * @note * * For DDR region 0x0000000000 - 0x007FFFFFFF, a system where DDR is less than * 2GB, region after DDR and before PL is marked as undefined/reserved in * translation table. Region 0xF9100000 - 0xF91FFFFF is reserved memory in * 0x00F9000000 - 0x00F91FFFFF range, but it is marked as strongly ordered * because minimum section size in translation table section is 2MB. Region * 0x00FFC00000 - 0x00FFDFFFFF contains CSU and PMU memory which are marked as * Device since it is less than 1MB and falls in a region with device memory. * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 5.00 pkp 05/21/14 Initial version * 5.04 pkp 12/18/15 Updated the address map according to proper address map * 6.0 mus 07/20/16 Added warning for ddrless HW design CR-954977 * 6.2 pkp 12/14/16 DDR memory in 0x800000000 - 0xFFFFFFFFF range is marked * as normal writeback for the size defined in hdf and rest * of the memory in that 32GB range is marked as reserved. * 6.4 mus 08/10/17 Marked memory as a outer shareable for EL1 NS execution, * to support CCI enabled IP's. * * *****************************************************************************/ #include "xparameters.h" #include "bspconfig.h" .globl MMUTableL0 .globl MMUTableL1 .globl MMUTableL2 .set reserved, 0x0 / Fault/ #if EL1_NONSECURE .set Memory, 0x405 \| (2 << 8) \| (0x0) / normal writeback write allocate outer shared read write / #else .set Memory, 0x405 \| (3 << 8) \| (0x0) / normal writeback write allocate inner shared read write / #endif .set Device, 0x409 \| (1 << 53)\| (1 << 54) \|(0x0) / strongly ordered read write non executable/ .section .mmu_tbl0,"a" MMUTableL0: .set SECT, MMUTableL1 / 0x0000_0000 - 0x7F_FFFF_FFFF / .8byte SECT + 0x3 .set SECT, MMUTableL1+0x1000 / 0x80_0000_0000 - 0xFF_FFFF_FFFF / .8byte SECT + 0x3 .section .mmu_tbl1,"a" MMUTableL1: .set SECT, MMUTableL2 / 0x0000_0000 - 0x3FFF_FFFF / .8byte SECT + 0x3 / 1GB DDR / .rept 0x3 / 0x4000_0000 - 0xFFFF_FFFF / .set SECT, SECT + 0x1000 /1GB DDR, 1GB PL, 2GB other devices n memory / .8byte SECT + 0x3 .endr .set SECT,0x100000000 .rept 0xC / 0x0001_0000_0000 - 0x0003_FFFF_FFFF / .8byte SECT + reserved / 12GB Reserved / .set SECT, SECT + 0x40000000 .endr .rept 0x10 / 0x0004_0000_0000 - 0x0007_FFFF_FFFF / .8byte SECT + Device / 8GB PL, 8GB PCIe / .set SECT, SECT + 0x40000000 .endr #ifdef XPAR_PSU_DDR_1_S_AXI_BASEADDR .set DDR_1_START, XPAR_PSU_DDR_1_S_AXI_BASEADDR .set DDR_1_END, XPAR_PSU_DDR_1_S_AXI_HIGHADDR .set DDR_1_SIZE, (DDR_1_END - DDR_1_START)+1 .if DDR_1_SIZE > 0x800000000 / If DDR size is larger than 32GB, truncate to 32GB / .set DDR_1_REG, 0x20 .else .set DDR_1_REG, DDR_1_SIZE/0x40000000 .endif #else .set DDR_1_REG, 0 #warning "There's no DDR_1 in the HW design. MMU translation table marks 32 GB DDR address space as undefined" #endif .set UNDEF_1_REG, 0x20 - DDR_1_REG .rept DDR_1_REG / DDR based on size in hdf/ .8byte SECT + Memory .set SECT, SECT+0x40000000 .endr .rept UNDEF_1_REG / reserved for region where ddr is absent / .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept 0x1C0 / 0x0010_0000_0000 - 0x007F_FFFF_FFFF / .8byte SECT + Device / 448 GB PL / .set SECT, SECT + 0x40000000 .endr .rept 0x100 / 0x0080_0000_0000 - 0x00BF_FFFF_FFFF / .8byte SECT + Device / 256GB PCIe / .set SECT, SECT + 0x40000000 .endr .rept 0x100 / 0x00C0_0000_0000 - 0x00FF_FFFF_FFFF / .8byte SECT + reserved / 256GB reserved / .set SECT, SECT + 0x40000000 .endr .section .mmu_tbl2,"a" MMUTableL2: .set SECT, 0 #ifdef XPAR_PSU_DDR_0_S_AXI_BASEADDR .set DDR_0_START, XPAR_PSU_DDR_0_S_AXI_BASEADDR .set DDR_0_END, XPAR_PSU_DDR_0_S_AXI_HIGHADDR .set DDR_0_SIZE, (DDR_0_END - DDR_0_START)+1 .if DDR_0_SIZE > 0x80000000 / If DDR size is larger than 2GB, truncate to 2GB / .set DDR_0_REG, 0x400 .else .set DDR_0_REG, DDR_0_SIZE/0x200000 .endif #else .set DDR_0_REG, 0 #warning "There's no DDR_0 in the HW design. MMU translation table marks 2 GB DDR address space as undefined" #endif .set UNDEF_0_REG, 0x400 - DDR_0_REG .rept DDR_0_REG / DDR based on size in hdf/ .8byte SECT + Memory .set SECT, SECT+0x200000 .endr .rept UNDEF_0_REG / reserved for region where ddr is absent / .8byte SECT + reserved .set SECT, SECT+0x200000 .endr .rept 0x0200 / 0x8000_0000 - 0xBFFF_FFFF / .8byte SECT + Device / 1GB lower PL / .set SECT, SECT+0x200000 .endr .rept 0x0100 / 0xC000_0000 - 0xDFFF_FFFF / .8byte SECT + Device / 512MB QSPI / .set SECT, SECT+0x200000 .endr .rept 0x080 / 0xE000_0000 - 0xEFFF_FFFF / .8byte SECT + Device / 256MB lower PCIe / .set SECT, SECT+0x200000 .endr .rept 0x040 / 0xF000_0000 - 0xF7FF_FFFF / .8byte SECT + reserved / 128MB Reserved / .set SECT, SECT+0x200000 .endr .rept 0x8 / 0xF800_0000 - 0xF8FF_FFFF / .8byte SECT + Device / 16MB coresight / .set SECT, SECT+0x200000 .endr / 1MB RPU LLP is marked for 2MB region as the minimum block size in translation table is 2MB and adjacent 63MB reserved region is converted to 62MB / .rept 0x1 / 0xF900_0000 - 0xF91F_FFFF / .8byte SECT + Device / 2MB RPU low latency port / .set SECT, SECT+0x200000 .endr .rept 0x1F / 0xF920_0000 - 0xFCFF_FFFF / .8byte SECT + reserved / 62MB Reserved / .set SECT, SECT+0x200000 .endr .rept 0x8 / 0xFD00_0000 - 0xFDFF_FFFF / .8byte SECT + Device / 16MB FPS / .set SECT, SECT+0x200000 .endr .rept 0xE / 0xFE00_0000 - 0xFFBF_FFFF / .8byte SECT + Device / 28MB LPS / .set SECT, SECT+0x200000 .endr / 0xFFC0_0000 - 0xFFDF_FFFF / .8byte SECT + Device /2MB PMU/CSU / .set SECT, SECT+0x200000 / 0xFFE0_0000 - 0xFFFF_FFFF/ .8byte SECT + Memory /2MB OCM/TCM/ .end /* * @} End of "addtogroup a53_64_boot_code". */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	2,156	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/32bit/gcc/xil-crt0.S	/****************************************************************************** * Copyright (c) 2015 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file xil-crt0.S * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 5.2 pkp 28/05/15 First release * 5.4 pkp 18/12/15 Initialized global constructor for C++ applications * 6.6 srm 10/18/17 Added timer configuration using XTime_StartTTCTimer API. * Now the TTC instance as specified by the user will be * started. * </pre> * * @note * * None. * *****************************************************************************/ #include "xparameters.h" .file "xil-crt0.S" .section ".got2","aw" .align 2 .text .Lsbss_start: .long __sbss_start .Lsbss_end: .long __sbss_end .Lbss_start: .long __bss_start__ .Lbss_end: .long __bss_end__ .Lstack: .long __stack .globl _startup _startup: mov r0, #0 / clear sbss / ldr r1,.Lsbss_start / calculate beginning of the SBSS / ldr r2,.Lsbss_end / calculate end of the SBSS / .Lloop_sbss: cmp r1,r2 bge .Lenclsbss / If no SBSS, no clearing required / str r0, [r1], #4 b .Lloop_sbss .Lenclsbss: / clear bss / ldr r1,.Lbss_start / calculate beginning of the BSS / ldr r2,.Lbss_end / calculate end of the BSS / .Lloop_bss: cmp r1,r2 bge .Lenclbss / If no BSS, no clearing required / str r0, [r1], #4 b .Lloop_bss .Lenclbss: / set stack pointer / ldr r13,.Lstack / stack address / / run global constructors / bl __libc_init_array / Reset and start Triple Timer Counter / #if defined (SLEEP_TIMER_BASEADDR) bl XTime_StartTTCTimer #endif / make sure argc and argv are valid / mov r0, #0 mov r1, #0 bl main / Jump to main C code / / Cleanup global constructors / bl __libc_fini_array bl exit .Lexit: / should never get here */ b .Lexit .Lstart: .size _startup,.Lstart-_startup
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	4,011	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/32bit/gcc/asm_vectors.S	/****************************************************************************** * Copyright (c) 2015 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file asm_vectors.S * * This file contains the initial vector table for the Cortex A53 processor * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 5.2 pkp 28/05/15 First release * 6.0 mus 27/07/16 Added Undefined exception handler * 6.4 mus 25/07/17 Added support for hard floating point * </pre> * * @note * * None. * *****************************************************************************/ .org 0 .text .globl _boot .globl _vector_table .globl FIQInterrupt .globl IRQInterrupt .globl SWInterrupt .globl DataAbortInterrupt .globl PrefetchAbortInterrupt .globl IRQHandler .globl prof_pc .section .vectors, "a" _vector_table: B _boot B Undefined B SVCHandler B PrefetchAbortHandler B DataAbortHandler NOP / Placeholder for address exception vector/ B IRQHandler B FIQHandler IRQHandler: / IRQ vector handler / stmdb sp!,{r0-r3,r12,lr} / state save from compiled code/ vpush {d0-d7} vpush {d16-d31} vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} bl IRQInterrupt / IRQ vector / pop {r1} vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d16-d31} vpop {d0-d7} ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / subs pc, lr, #4 / adjust return / FIQHandler: / FIQ vector handler / stmdb sp!,{r0-r3,r12,lr} / state save from compiled code / vpush {d0-d7} vpush {d16-d31} vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} FIQLoop: bl FIQInterrupt / FIQ vector / pop {r1} vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d16-d31} vpop {d0-d7} ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / subs pc, lr, #4 / adjust return / Undefined: / Undefined handler / stmdb sp!,{r0-r3,r12,lr} / state save from compiled code / ldr r0, =UndefinedExceptionAddr sub r1, lr, #4 str r1, [r0] / Store address of instruction causing undefined exception / bl UndefinedException / UndefinedException: call C function here / ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / movs pc, lr SVCHandler: / SWI handler / stmdb sp!,{r0-r3,r12,lr} / state save from compiled code / tst r0, #0x20 / check the T bit / ldrneh r0, [lr,#-2] / Thumb mode / bicne r0, r0, #0xff00 / Thumb mode / ldreq r0, [lr,#-4] / ARM mode / biceq r0, r0, #0xff000000 / ARM mode / bl SWInterrupt / SWInterrupt: call C function here / ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / movs pc, lr /return to the next instruction after the SWI instruction / DataAbortHandler: / Data Abort handler / stmdb sp!,{r0-r3,r12,lr} / state save from compiled code / ldr r0, =DataAbortAddr sub r1, lr, #8 str r1, [r0] / Stores instruction causing data abort / bl DataAbortInterrupt /DataAbortInterrupt :call C function here / ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / subs pc, lr, #8 / points to the instruction that caused the Data Abort exception / PrefetchAbortHandler: / Prefetch Abort handler / stmdb sp!,{r0-r3,r12,lr} / state save from compiled code / ldr r0, =PrefetchAbortAddr sub r1, lr, #4 str r1, [r0] / Stores instruction causing prefetch abort / bl PrefetchAbortInterrupt / PrefetchAbortInterrupt: call C function here / ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / subs pc, lr, #4 / points to the instruction that caused the Prefetch Abort exception */ .end
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	9,225	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/32bit/gcc/boot.S	/****************************************************************************** * Copyright (c) 2015 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file boot.S * * @addtogroup a53_32_boot_code Cortex A53 32bit Processor Boot Code * @{ * <h2> boot.S </h2> * The boot.S file contains a minimal set of code for transferring control from the * processor reset location to the start of the application. The boot code performs * minimum configuration which is required for an application to run starting from * processor reset state of the processor. Below is a sequence illustrating what all * configuration is performed before control reaches to main function. * * 1. Program vector table base for exception handling * 2. Invalidate instruction cache, data cache and TLBs * 3. Program stack pointer for various modes (IRQ, FIQ, supervisor, undefine, * abort, system) * 4. Program counter frequency * 5. Configure MMU with short descriptor translation table format and program * base address of translation table * 6. Enable data cache, instruction cache and MMU * 7. Transfer control to _start which clears BSS sections and runs global * constructor before jumping to main application * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 5.2 pkp 28/05/15 First release * 5.4 pkp 09/11/15 Enable I-Cache and D-Cache in the initialization * 6.0 pkp 07/25/16 Program the counter frequency * 6.4 mus 07/25/17 Set VFP enable bit in FPEXC register, to support * hard floating point in BSP * </pre> * * *****************************************************************************/ #include "xparameters.h" .globl MMUTable .global _prestart .global _boot .global __stack .global __irq_stack .global __supervisor_stack .global __abort_stack .global __fiq_stack .global __undef_stack .global _vector_table .set PSS_L2CC_BASE_ADDR, 0xF8F02000 .set PSS_SLCR_BASE_ADDR, 0xF8000000 .set RESERVED, 0x0fffff00 .set TblBase , MMUTable .set LRemap, 0xFE00000F / set the base address of the peripheral block as not shared / .set CRValMmuCac, 0b01000000000001 / Enable IDC, and MMU / .set counterfreq, XPAR_CPU_CORTEXA53_0_TIMESTAMP_CLK_FREQ / Stack Pointer locations for boot code / .set Undef_stack, __undef_stack .set FIQ_stack, __fiq_stack .set Abort_stack, __abort_stack .set SPV_stack, __supervisor_stack .set IRQ_stack, __irq_stack .set SYS_stack, __stack .set vector_base, _vector_table .set FPEXC_EN, 0x40000000 / FPU enable bit, (1 << 30) / .section .boot,"ax" / this initializes the various processor modes / _prestart: _boot: OKToRun: mrc p15, 0, r0, c0, c0, 0 / Get the revision / and r5, r0, #0x00f00000 and r6, r0, #0x0000000f orr r6, r6, r5, lsr #20-4 / set VBAR to the _vector_table address in linker script / ldr r0, =vector_base mcr p15, 0, r0, c12, c0, 0 / Invalidate caches and TLBs / mov r0,#0 / r0 = 0 / mcr p15, 0, r0, c8, c7, 0 / invalidate TLBs / mcr p15, 0, r0, c7, c5, 0 / invalidate icache / mcr p15, 0, r0, c7, c5, 6 / Invalidate branch predictor array / bl invalidate_dcache / invalidate dcache / / Disable MMU, if enabled / mrc p15, 0, r0, c1, c0, 0 / read CP15 register 1 / bic r0, r0, #0x1 / clear bit 0 / mcr p15, 0, r0, c1, c0, 0 / write value back / mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the irq stack pointer / and r2, r1, r0 orr r2, r2, #0x12 / IRQ mode / msr cpsr, r2 ldr r13,=IRQ_stack / IRQ stack pointer / mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the supervisor stack pointer / and r2, r1, r0 orr r2, r2, #0x13 / supervisor mode / msr cpsr, r2 ldr r13,=SPV_stack / Supervisor stack pointer / mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the Abort stack pointer / and r2, r1, r0 orr r2, r2, #0x17 / Abort mode / msr cpsr, r2 ldr r13,=Abort_stack / Abort stack pointer / mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the FIQ stack pointer / and r2, r1, r0 orr r2, r2, #0x11 / FIQ mode / msr cpsr, r2 ldr r13,=FIQ_stack / FIQ stack pointer / mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the Undefine stack pointer / and r2, r1, r0 orr r2, r2, #0x1b / Undefine mode / msr cpsr, r2 ldr r13,=Undef_stack / Undefine stack pointer / mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the system stack pointer / and r2, r1, r0 orr r2, r2, #0x1F / SYS mode / msr cpsr, r2 ldr r13,=SYS_stack / SYS stack pointer / / program the timer counter frequency / ldr r0,=counterfreq mcr 15,0,r0,c14,c0,0 mov r0,#0 mcr 15,0,r0,c2,c0,2 / N = 0 to use ttbr0 / / Write to ACTLR / mrc p15, 0, r0, c1, c0, 1 / Read ACTLR / orr r0, r0, #(1 << 0) / Enable access to CPUECTLR / orr r0, r0, #(1 << 1) mcr p15, 0, r0, c1, c0, 1 / Write ACTLR / / Write to CPUECTLR / mrrc p15, 1, r0, r1, c15 / Read CPUECTLR / orr r0, r0, #(0x01 << 6) / Set SMPEN bit / mcrr p15, 1, r0, r1, c15 / Write CPUECTLR / / enable MMU and cache / ldr r0,=TblBase / Load MMU translation table base / orr r0, r0, #0x5B / Outer-cacheable, WB / mcr 15, 0, r0, c2, c0, 0 / TTB0 / mov r0,#0x5B mcr p15,0,r0,c2,c0,1 mvn r0,#0 / Load MMU domains -- all ones=manager / mcr p15,0,r0,c3,c0,0 / Enable mmu, icahce and dcache / mrc p15,0,r0,c1,c0,0 bic r0, r0, #(0x1 << 13) orr r0, r0, #(0x1 << 12) / enable I-cache / orr r0, r0, #(0x1 << 2) / enable D-Cache / orr r0, r0, #0x1 / enable MMU / dsb / dsb allow the MMU to start up / mcr p15,0,r0,c1,c0,0 / Enable cache and MMU / isb / isb flush prefetch buffer / mov r0, r0 mrc p15, 0, r1, c1, c0, 2 / read cp access control register (CACR) into r1 / orr r1, r1, #(0xf << 20) / enable full access for p10 & p11 / mcr p15, 0, r1, c1, c0, 2 / write back into CACR / / enable vfp / vmrs r1, FPEXC / read the exception register / orr r1,r1, #FPEXC_EN / set VFP enable bit, leave the others in orig state / vmsr FPEXC, r1 / write back the exception register / mrc p15,0,r0,c1,c0,0 / flow prediction enable / orr r0, r0, #(0x01 << 11) / #0x8000 / mcr p15,0,r0,c1,c0,0 mrc p15,0,r0,c1,c0,1 / read Auxiliary Control Register / orr r0, r0, #(0x1 << 2) / enable Dside prefetch / orr r0, r0, #(0x1 << 1) / enable L2 Prefetch hint / mcr p15,0,r0,c1,c0,1 / write Auxiliary Control Register / mrs r0, cpsr / get the current PSR / bic r0, r0, #0x100 / enable asynchronous abort exception / msr cpsr_xsf, r0 b _startup / jump to C startup code / and r0, r0, r0 / no op / .Ldone: b .Ldone / Paranoia: we should never get here / / ************************************************************************* * * invalidate_dcache - invalidate the entire d-cache by set/way * * Note: for Cortex-A53, there is no cp instruction for invalidating * the whole D-cache. Need to invalidate each line. * ************************************************************************* / invalidate_dcache: mrc p15, 1, r0, c0, c0, 1 / read CLIDR / ands r3, r0, #0x7000000 mov r3, r3, lsr #23 / cache level value (naturally aligned) / beq finished mov r10, #0 / start with level 0 / loop1: add r2, r10, r10, lsr #1 / work out 3xcachelevel / mov r1, r0, lsr r2 / bottom 3 bits are the Cache type for this level / and r1, r1, #7 / get those 3 bits alone / cmp r1, #2 blt skip / no cache or only instruction cache at this level / mcr p15, 2, r10, c0, c0, 0 / write the Cache Size selection register / isb / isb to sync the change to the CacheSizeID reg / mrc p15, 1, r1, c0, c0, 0 / reads current Cache Size ID register / and r2, r1, #7 / extract the line length field / add r2, r2, #4 / add 4 for the line length offset (log2 16 bytes) / ldr r4, =0x3ff ands r4, r4, r1, lsr #3 / r4 is the max number on the way size (right aligned) / clz r5, r4 / r5 is the bit position of the way size increment / ldr r7, =0x7fff ands r7, r7, r1, lsr #13 / r7 is the max number of the index size (right aligned) / loop2: mov r9, r4 / r9 working copy of the max way size (right aligned) / loop3: orr r11, r10, r9, lsl r5 / factor in the way number and cache number into r11 / orr r11, r11, r7, lsl r2 / factor in the index number / mcr p15, 0, r11, c7, c6, 2 / invalidate by set/way / subs r9, r9, #1 / decrement the way number / bge loop3 subs r7, r7, #1 / decrement the index / bge loop2 skip: add r10, r10, #2 / increment the cache number / cmp r3, r10 bgt loop1 finished: mov r10, #0 / switch back to cache level 0 / mcr p15, 2, r10, c0, c0, 0 / select current cache level in cssr / dsb isb bx lr .end /* * @} End of "addtogroup a53_32_boot_code". */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,374	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/32bit/gcc/cpu_init.S	/****************************************************************************** * Copyright (c) 2015 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file cpu_init.S * * This file contains CPU specific initialization. Invoked from main CRT * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 5.2 pkp 28/05/15 First release * </pre> * * @note * * None. * *****************************************************************************/ .text .global __cpu_init .align 2 __cpu_init: / Clear cp15 regs with unknown reset values / mov r0, #0x0 mcr p15, 0, r0, c5, c0, 0 / DFSR / mcr p15, 0, r0, c5, c0, 1 / IFSR / mcr p15, 0, r0, c6, c0, 0 / DFAR / mcr p15, 0, r0, c6, c0, 2 / IFAR / mcr p15, 0, r0, c9, c13, 2 / PMXEVCNTR / mcr p15, 0, r0, c13, c0, 2 / TPIDRURW / mcr p15, 0, r0, c13, c0, 3 / TPIDRURO / / Reset and start Cycle Counter / mov r2, #0x80000000 / clear overflow / mcr p15, 0, r2, c9, c12, 3 mov r2, #0xd / D, C, E / mcr p15, 0, r2, c9, c12, 0 mov r2, #0x80000000 / enable cycle counter */ mcr p15, 0, r2, c9, c12, 1 bx lr .end
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	5,658	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/32bit/platform/ZynqMP/translation_table.S	/****************************************************************************** * Copyright (c) 2015 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file translation_table.s * * @addtogroup a53_32_boot_code * @{ * <h2> translation_table.S </h2> * The translation_table.S contains a static page table required by MMU for * cortex-A53. This translation table is flat mapped (input address = output * address) with default memory attributes defined for zynq ultrascale+ * architecture. It utilizes short descriptor translation table format with each * section defining 1MB of memory. * * For DDR in region 0x00000000 - 0x7FFFFFFF, a system where DDR is less than * 2GB, region after DDR and before PL is marked as undefined/reserved in * translation table. In region 0xFFC00000 - 0xFFDFFFFF, it contains CSU * and PMU memory which are marked as Device since it is less than 1MB and * falls in a region with device memory. * * The overview of translation table memory attributes is described below. * \| \| Memory Range \| Definition in Translation Table \| \|-----------------\|-------------------------\|---------------------------------\| \| DDR \| 0x00000000 - 0x7FFFFFFF \| Normal write-back Cacheable \| \| PL \| 0x80000000 - 0xBFFFFFFF \| Strongly Ordered \| \| QSPI, lower PCIe\| 0xC0000000 - 0xEFFFFFFF \| Device Memory \| \| Reserved \| 0xF0000000 - 0xF7FFFFFF \| Unassigned \| \| STM Coresight \| 0xF8000000 - 0xF8FFFFFF \| Device Memory \| \| GIC \| 0xF9000000 - 0xF90FFFFF \| Device memory \| \| Reserved \| 0xF9100000 - 0xFCFFFFFF \| Unassigned \| \| FPS, LPS slaves \| 0xFD000000 - 0xFFBFFFFF \| Device memory \| \| CSU, PMU \| 0xFFC00000 - 0xFFDFFFFF \| Device Memory \| \| TCM, OCM \| 0xFFE00000 - 0xFFFFFFFF \| Normal write-back cacheable \| * * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 5.2 pkp 28/05/15 First release * 5.4 pkp 18/12/15 Updated the address map according to proper address map * 6.0 mus 20/07/16 Added warning for ddrless HW design CR-954977 * </pre> * * *****************************************************************************/ #include "xparameters.h" .globl MMUTable .section .mmu_tbl,"a" MMUTable: / Each table entry occupies one 32-bit word and there are * 4096 entries, so the entire table takes up 16KB. * Each entry covers a 1MB section. / .set SECT, 0 #ifdef XPAR_PSU_DDR_0_S_AXI_BASEADDR .set DDR_START, XPAR_PSU_DDR_0_S_AXI_BASEADDR .set DDR_END, XPAR_PSU_DDR_0_S_AXI_HIGHADDR .set DDR_SIZE, (DDR_END - DDR_START)+1 .if DDR_SIZE > 0x80000000 / If DDR size is larger than 2GB, truncate to 2GB / .set DDR_REG, 0x800 .else .set DDR_REG, DDR_SIZE/0x100000 .endif #else .set DDR_REG, 0 #warning "There's no DDR in the HW design. MMU translation table marks 2 GB DDR address space as undefined" #endif .set UNDEF_REG, 0x800 - DDR_REG .rept DDR_REG / DDR Cacheable / .word SECT + 0x15de6 / S=b1 TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 / .set SECT, SECT+0x100000 .endr .rept UNDEF_REG / unassigned/reserved / / Generates a translation fault if accessed / .word SECT + 0x0 / S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 / .set SECT, SECT+0x100000 .endr .rept 0x0200 / 0x80000000 - 0x9fffffff (FPGA slave0) / .word SECT + 0xc02 / S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 / .set SECT, SECT+0x100000 .endr .rept 0x0200 / 0xA0000000 - 0xbfffffff (FPGA slave1) / .word SECT + 0xc02 / S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 / .set SECT, SECT+0x100000 .endr .rept 0x0200 / 0xc0000000 - 0xdfffffff (OSPI IOU)/ .word SECT + 0xc06 / S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 / .set SECT, SECT+0x100000 .endr .rept 0x0100 / 0xe0000000 - 0xefffffff (Lower PCIe)/ .word SECT + 0xc06 / S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 / .set SECT, SECT+0x100000 .endr .rept 0x80 / 0xf0000000 - 0xf7ffffff (unassigned/reserved). * Generates a translation fault if accessed / .word SECT + 0x0 / S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 / .set SECT, SECT+0x100000 .endr .rept 0x10 / 0xf8000000 - 0xf8ffffff (STM Coresight) / .word SECT + 0xc06 / S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 / .set SECT, SECT+0x100000 .endr .rept 0x1 / 0xf9000000 - 0xf90fffff (RPU_A53_GIC) / .word SECT + 0xc06 / S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 / .set SECT, SECT+0x100000 .endr .rept 0x3f / 0xf9100000 - 0xfcffffff (reserved)./ .word SECT + 0x0 / S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 / .set SECT, SECT+0x100000 .endr .rept 0x10 / 0xfd000000 - 0xfdffffff (FPS Slaves) / .word SECT + 0xc06 / S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 / .set SECT, SECT+0x100000 .endr .rept 0x1C / 0xfe0000000 - 0xfeffffff (LPS Slaves) / .word SECT + 0xc06 / S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 / .set SECT, SECT+0x100000 .endr .rept 0x2 / 0xffc000000 - 0xffdfffff (CSU and PMU) / .word SECT + 0xc06 / S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 / .set SECT, SECT+0x100000 .endr .rept 0x02 / 0xffe00000 - 0xffffffff (TCM and OCM Cacheable) / .word SECT + 0x15de6 / S=b1 TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 / .set SECT, SECT+0x100000 .endr .end /* * @} End of "addtogroup a53_32_boot_code". */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	4,764	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/iccarm/translation_table.s	;**************************************************************************** ; Copyright (c) 2009 - 2020 Xilinx, Inc. All rights reserved. ; SPDX-License-Identifier: MIT ;************************************************************************* ;************************************************************************ ; ; @file translation_table.s ; ; This file contains the initialization for the MMU table in RAM ; needed by the Cortex A9 processor ; ; <pre> ; MODIFICATION HISTORY: ; ; Ver Who Date Changes ; ----- ---- -------- --------------------------------------------------- ; 1.00a ecm 10/20/09 Initial version ; 3.07a sgd 07/05/12 Configuring device address spaces as shareable device ; instead of strongly-ordered. ; 4.2 pkp 09/02/14 modified translation table entries according to address map ; 4.2 pkp 09/11/14 modified translation table entries to resolve compilation ; error for solving CR#822897 ; 6.1 pkp 07/11/16 Corrected comments for memory attributes ; 6.8 mus 07/12/2018 Mark DDR memory as inner cacheable, if BSP is built ; with the USE_AMP flag. ; </pre> ; ; @note ; ; None. ; ;**************************************************************************** EXPORT MMUTable ;ARMCC AREA \|.mmu_tbl\|,CODE,ALIGN=14 ; RSEG mmu_tbl:CODE:ROOT (14) SECTION .mmu_tbl:CODE:ROOT(14) MMUTable ; Each table entry occupies one 32-bit word and there are ; 4096 entries, so the entire table takes up 16KB. ; Each entry covers a 1MB section. ; 0x00000000 - 0x3ffffff (DDR Cacheable) count SETA 0 sect SETA 0 REPT 0x400 #ifndef USE_AMP DCD sect + 0x15de6 ; S=1, TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 #else DCD sect + 0x14de6 ; S=1, TEX=b100 AP=b11, Domain=b1111, C=b0, B=b1 #endif sect SETA sect+0x100000 count SETA count+1 ENDR ; 0x40000000 - 0x7fffffff (GpAxi0) count SETA 0 REPT 0x400 DCD sect + 0xc02 ; S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0x80000000 - 0xbfffffff (GpAxi1) count SETA 0 REPT 0x400 DCD sect + 0xc02 ; S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xc0000000 - 0xdfffffff (undef) count SETA 0 REPT 0x200 DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xe0000000 - 0xe02fffff (IOP dev) count SETA 0 REPT 0x3 DCD sect + 0xc06 ; S=0, TEX=b010 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xe0300000 - 0xe0ffffff (undef/reserved) count SETA 0 REPT 0xD DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xe1000000 - 0xe1ffffff (NAND) count SETA 0 REPT 0x10 DCD sect + 0xc06 ; S=0, TEX=b010 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xe2000000 - 0xe3ffffff (NOR) count SETA 0 REPT 0x20 DCD sect + 0xc06 ; S=0, TEX=b010 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xe4000000 - 0xe5ffffff (SRAM) count SETA 0 REPT 0x20 DCD sect + 0xc0e ; S=b0 TEX=b000 AP=b11, Domain=b0, C=b1, B=b1 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xe6000000 - 0xf7ffffff (reserved) count SETA 0 REPT 0x0120 DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xf8000c00 to 0xf8000fff, 0xf8010000 to 0xf88fffff and ; 0xf8f03000 to 0xf8ffffff are reserved but due to granual size of ; 1MB, it is not possible to define separate regions for them ; 0xf8000000 - 0xf8ffffff (APB device regs) count SETA 0 REPT 0x10 DCD sect + 0xc06 ; S=0, TEX=b010 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xf9000000 - 0xfbffffff (reserved) count SETA 0 REPT 0x30 DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xfc000000 - 0xfdffffff (QSPI) count SETA 0 REPT 0x20 DCD sect + 0xc0a ; S=b0 TEX=b000 AP=b11, Domain=b0, C=b1, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xfe000000 - 0xffefffff (reserved) count SETA 0 REPT 0x1F DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xfff00000 to 0xfffb0000 is reserved but due to granual size of ; 1MB, it is not possible to define separate region for it ; 0xfff00000 to 0xfffb0000 (OCM) count SETA 0 DCD sect + 0x4c0e ; S=b0 TEX=b100 AP=b11, Domain=b0, C=b1, B=b1 sect SETA sect+0x100000 END
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	14,970	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/iccarm/boot.s	;**************************************************************************** ; Copyright (c) 2009 - 2022 Xilinx, Inc. All rights reserved. ; SPDX-License-Identifier: MIT ;************************************************************************* ;************************************************************************ ; ; @file boot.s ; ; This file contains the initial vector table for the Cortex A9 processor ; ; <pre> ; MODIFICATION HISTORY: ; ; Ver Who Date Changes ; ----- ------- -------- --------------------------------------------------- ; 1.00a Initial version ; 4.2 pkp 08/04/14 Removed PEEP board related code which contained ; initialization of uart smc nor and sram ; 5.0 pkp 16/12/14 Modified initialization code to enable scu after ; MMU is enabled and removed incorrect initialization ; of TLB lockdown register to fix CR#830580 ; 5.1 pkp 05/13/15 Changed the initialization order so to first invalidate ; caches and TLB, enable MMU and caches, then enable SMP ; bit in ACTLR. L2Cache invalidation and enabling of L2Cache ; is done later. ; 6.0 mus 08/04/16 Added code to detect zynq-7000 base silicon configuration and ; attempt to enable dual core behavior on single cpu zynq-7000s devices ; is prevented from corrupting system behavior. ; 6.6 srm 10/25/17 Added timer configuration using XTime_StartTTCTimer API. ; Now the TTC instance as specified by the user will be ; started. ; 7.7 asa 01/06/22 Removed Cortex-A9 errata handling for errata ; 742230 and 743622. These do not apply to ; Cortex-A9 revision r3p0 being used in Zynq ; platforms. ; </pre> ; ; @note ; ; None. ; ;**************************************************************************** MODULE ?boot ;; Forward declaration of sections. SECTION IRQ_STACK:DATA:NOROOT(3) SECTION FIQ_STACK:DATA:NOROOT(3) SECTION SVC_STACK:DATA:NOROOT(3) SECTION ABT_STACK:DATA:NOROOT(3) SECTION UND_STACK:DATA:NOROOT(3) SECTION CSTACK:DATA:NOROOT(3) #include "xparameters.h" ;#include "xtime_l.h" #define UART_BAUDRATE 115200 PUBLIC _prestart PUBLIC __iar_program_start IMPORT _vector_table IMPORT MMUTable IMPORT __cmain IMPORT Xil_ExceptionInit IMPORT XTime_SetTime #if defined SLEEP_TIMER_BASEADDR IMPORT XTime_StartTTCTimer #endif PSS_L2CC_BASE_ADDR EQU 0xF8F02000 PSS_SLCR_BASE_ADDR EQU 0xF8000000 RESERVED EQU 0x0fffff00 TblBase EQU MMUTable LRemap EQU 0xFE00000F ; set the base address of the peripheral block as not shared L2CCWay EQU (PSS_L2CC_BASE_ADDR + 0x077C) ;(PSS_L2CC_BASE_ADDR + PSS_L2CC_CACHE_INVLD_WAY_OFFSET) L2CCSync EQU (PSS_L2CC_BASE_ADDR + 0x0730) ;(PSS_L2CC_BASE_ADDR + PSS_L2CC_CACHE_SYNC_OFFSET) L2CCCrtl EQU (PSS_L2CC_BASE_ADDR + 0x0100) ;(PSS_L2CC_BASE_ADDR + PSS_L2CC_CNTRL_OFFSET) L2CCAuxCrtl EQU (PSS_L2CC_BASE_ADDR + 0x0104) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_AUX_CNTRL_OFFSET) L2CCTAGLatReg EQU (PSS_L2CC_BASE_ADDR + 0x0108) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_TAG_RAM_CNTRL_OFFSET) L2CCDataLatReg EQU (PSS_L2CC_BASE_ADDR + 0x010C) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_DATA_RAM_CNTRL_OFFSET) L2CCIntClear EQU (PSS_L2CC_BASE_ADDR + 0x0220) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_IAR_OFFSET) L2CCIntRaw EQU (PSS_L2CC_BASE_ADDR + 0x021C) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_ISR_OFFSET) SLCRlockReg EQU (PSS_SLCR_BASE_ADDR + 0x04) ;(PSS_SLCR_BASE_ADDR + XPSS_SLCR_LOCK_OFFSET) SLCRUnlockReg EQU (PSS_SLCR_BASE_ADDR + 0x08) ;(PSS_SLCR_BASE_ADDR + XPSS_SLCR_UNLOCK_OFFSET) SLCRL2cRamReg EQU (PSS_SLCR_BASE_ADDR + 0xA1C) ;(PSS_SLCR_BASE_ADDR + XPSS_SLCR_L2C_RAM_OFFSET) SLCRCPURSTReg EQU (0xF8000000 + 0x244) ;(XPS_SYS_CTRL_BASEADDR + A9_CPU_RST_CTRL_OFFSET) EFUSEStaus EQU (0xF800D000 + 0x10) ;(XPS_EFUSE_BASEADDR + EFUSE_STATUS_OFFSET) /* workaround for simulation not working when L1 D and I caches,MMU and L2 cache enabled - DT568997 / #if SIM_MODE == 1 CRValMmuCac EQU 00000000000000b ; Disable IDC, and MMU #else CRValMmuCac EQU 01000000000101b ; Enable IDC, and MMU #endif CRValHiVectorAddr EQU 10000000000000b ; Set the Vector address to high, 0xFFFF0000 L2CCAuxControl EQU 0x72360000 ; Enable all prefetching, Way Size (16 KB) and High Priority for SO and Dev Reads Enable L2CCControl EQU 0x01 ; Enable L2CC L2CCTAGLatency EQU 0x0111 ; 7 Cycles of latency for TAG RAM L2CCDataLatency EQU 0x0121 ; 7 Cycles of latency for DATA RAM SLCRlockKey EQU 0x767B ; SLCR lock key SLCRUnlockKey EQU 0xDF0D ; SLCR unlock key SLCRL2cRamConfig EQU 0x00020202 ; SLCR L2C ram configuration vector_base EQU _vector_table FPEXC_EN EQU 0x40000000 ; FPU enable bit, (1 << 30) SECTION .intvec:CODE:NOROOT(2) ; this initializes the various processor modes _prestart __iar_program_start #if XPAR_CPU_ID==0 ; only allow cp0 through mrc p15,0,r1,c0,c0,5 and r1, r1, #0xf cmp r1, #0 beq OKToRun EndlessLoop0 wfe b EndlessLoop0 #elif XPAR_CPU_ID==1 ; only allow cp1 through mrc p15,0,r1,c0,c0,5 and r1, r1, #0xf cmp r1, #1 beq OKToRun EndlessLoop1 wfe b EndlessLoop1 #endif OKToRun ldr r0,=EFUSEStaus ldr r1,[r0] ; Read eFuse to detect zynq silicon configuration ands r1,r1,#0x80 ; Check whether cpu1 is disabled through eFuse beq DualCPU ; cpu1 is disabled through eFuse,reset cpu1 ldr r0,=SLCRUnlockReg ; Load SLCR base address base + unlock register ldr r1,=SLCRUnlockKey ; set unlock key str r1, [r0] ; Unlock SLCR ldr r0,=SLCRCPURSTReg ldr r1,[r0] ; Read CPU Software Reset Control register orr r1,r1,#0x22 str r1,[r0] ; Reset CPU1 ldr r0,=SLCRlockReg ; Load SLCR base address base + lock register ldr r1,=SLCRlockKey ; set lock key str r1, [r0] ; lock SLCR DualCPU mrc p15, 0, r0, c0, c0, 0 ; Get the revision and r5, r0, #0x00f00000 and r6, r0, #0x0000000f orr r6, r6, r5, lsr #20-4 ; set VBAR to the _vector_table address in linker script ldr r0, =vector_base mcr p15, 0, r0, c12, c0, 0 ;invalidate scu ldr r7, =0xf8f0000c ldr r6, =0xffff str r6, [r7] ;Invalidate caches and TLBs mov r0,#0 ; r0 = 0 mcr p15, 0, r0, c8, c7, 0 ; invalidate TLBs mcr p15, 0, r0, c7, c5, 0 ; invalidate icache mcr p15, 0, r0, c7, c5, 6 ; Invalidate branch predictor array bl invalidate_dcache ; invalidate dcache ; Disable MMU, if enabled mrc p15, 0, r0, c1, c0, 0 ; read CP15 register 1 bic r0, r0, #0x1 ; clear bit 0 mcr p15, 0, r0, c1, c0, 0 ; write value back #ifdef SHAREABLE_DDR ; Mark the entire DDR memory as shareable ldr r3, =0x3ff ; 1024 entries to cover 1G DDR ldr r0, =TblBase ; MMU Table address in memory ldr r2, =0x15de6 ; S=1, TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 shareable_loop str r2, [r0] ; write the entry to MMU table add r0, r0, #0x4 ; next entry in the table add r2, r2, #0x100000 ; next section subs r3, r3, #1 bge shareable_loop ; loop till 1G is covered #endif mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the irq stack pointer and r2, r1, r0 orr r2, r2, #0x12 ; IRQ mode msr cpsr, r2 ; was cpsr, apsr is considered synonym ldr r13,=SFE(IRQ_STACK) ; IRQ stack pointer mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the supervisor stack pointer and r2, r1, r0 orr r2, r2, #0x13 ; supervisor mode msr cpsr, r2 ; was cpsr, apsr is considered synonym ldr r13,=SFE(SVC_STACK) ; Supervisor stack pointer mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the Abort stack pointer and r2, r1, r0 orr r2, r2, #0x17 ; Abort mode msr cpsr, r2 ; was cpsr, apsr is considered synonym ldr r13,=SFE(ABT_STACK) ; Abort stack pointer mrs r0, cpsr ; was cpsr, get the current PSR mvn r1, #0x1f ; set up the FIQ stack pointer and r2, r1, r0 orr r2, r2, #0x11 ; FIQ mode msr cpsr, r2 ; was cpsr ldr r13,=SFE(FIQ_STACK) ; FIQ stack pointer mrs r0, cpsr ; was cpsr, get the current PSR mvn r1, #0x1f ; set up the Undefine stack pointer and r2, r1, r0 orr r2, r2, #0x1b ; Undefine mode msr cpsr, r2 ; was cpsr ldr r13,=SFE(UND_STACK) ; Undefine stack pointer mrs r0, cpsr ; was cpsr, get the current PSR mvn r1, #0x1f ; set up the system stack pointer and r2, r1, r0 orr r2, r2, #0x1f ; SYS mode msr cpsr, r2 ; was cpsr, apsr is considered synonym ldr r13,=SFE(CSTACK) ; SYS stack pointer ;set scu enable bit in scu ldr r7, =0xf8f00000 ldr r0, [r7] orr r0, r0, #0x1 str r0, [r7] ; enable MMU and cache ldr r0,=TblBase ; Load MMU translation table base orr r0, r0, #0x5B ; Outer-cacheable, WB mcr p15, 0, r0, c2, c0, 0 ; TTB0 mvn r0,#0 ; Load MMU domains -- all ones=manager mcr p15,0,r0,c3,c0,0 ; Enable mmu, icahce and dcache ldr r0,=CRValMmuCac mcr p15,0,r0,c1,c0,0 ; Enable cache and MMU dsb ; dsb allow the MMU to start up isb ; isb flush prefetch buffer ; Write to ACTLR mrc p15, 0,r0, c1, c0, 1 ; Read ACTLR orr r0, r0, #(0x01 << 6) ; SMP bit orr r0, r0, #(0x01 ) ; Cache/TLB maintenance broadcast mcr p15, 0,r0, c1, c0, 1 ; Write ACTLR ; Invalidate L2 Cache and initialize L2 Cache ; For AMP, assume running on CPU1. Don't initialize L2 Cache (up to Linux) #if USE_AMP!=1 ldr r0,=L2CCCrtl ; Load L2CC base address base + control register mov r1, #0 ; force the disable bit str r1, [r0] ; disable the L2 Caches ldr r0,=L2CCAuxCrtl ; Load L2CC base address base + Aux control register ldr r1,[r0] ; read the register ldr r2,=L2CCAuxControl ; set the default bits orr r1,r1,r2 str r1, [r0] ; store the Aux Control Register ldr r0,=L2CCTAGLatReg ; Load L2CC base address base + TAG Latency address ldr r1,=L2CCTAGLatency ; set the latencies for the TAG str r1, [r0] ; store the TAG Latency register Register ldr r0,=L2CCDataLatReg ; Load L2CC base address base + Data Latency address ldr r1,=L2CCDataLatency ; set the latencies for the Data str r1, [r0] ; store the Data Latency register Register ldr r0,=L2CCWay ; Load L2CC base address base + way register ldr r2, =0xFFFF str r2, [r0] ; force invalidate ldr r0,=L2CCSync ; need to poll 0x730, PSS_L2CC_CACHE_SYNC_OFFSET ; Load L2CC base address base + sync register ; poll for completion Sync ldr r1, [r0] cmp r1, #0 bne Sync ldr r0,=L2CCIntRaw ; clear pending interrupts ldr r1,[r0] ldr r0,=L2CCIntClear str r1,[r0] ldr r0,=SLCRUnlockReg ; Load SLCR base address base + unlock register ldr r1,=SLCRUnlockKey ; set unlock key str r1, [r0] ; Unlock SLCR ldr r0,=SLCRL2cRamReg ; Load SLCR base address base + l2c Ram Control register str r1, [r0] ; store the L2c Ram Control Register ldr r0,=SLCRlockReg ; Load SLCR base address base + lock register ldr r1,=SLCRlockKey ; set lock key str r1, [r0] ; lock SLCR ldr r0,=L2CCCrtl ; Load L2CC base address base + control register ldr r1,[r0] ; read the register mov r2, #L2CCControl ; set the enable bit orr r1,r1,r2 str r1, [r0] ; enable the L2 Caches #endif mov r0, r0 mrc p15, 0, r1, c1, c0, 2 ; read cp access control register (CACR) into r1 orr r1, r1, #(0xf << 20) ; enable full access for p10 & p11 mcr p15, 0, r1, c1, c0, 2 ; write back into CACR ; enable vfp fmrx r1, FPEXC ; read the exception register orr r1,r1, #FPEXC_EN ; set VFP enable bit, leave the others in orig state fmxr FPEXC, r1 ; write back the exception register mrc p15, 0, r0, c1, c0, 0 ; flow prediction enable orr r0, r0, #(0x01 << 11) ; #0x8000 mcr p15,0,r0,c1,c0,0 mrc p15, 0, r0, c1, c0, 1 ; read Auxiliary Control Register orr r0, r0, #(0x1 << 2) ; enable Dside prefetch orr r0, r0, #(0x1 << 1) ; enable L2 prefetch mcr p15, 0, r0, c1, c0, 1 ; write Auxiliary Control Register ; Initialize the vector table ;bl Xil_ExceptionInit ; Clear cp15 regs with unknown reset values mov r0, #0x0 mcr p15, 0, r0, c5, c0, 0 ; DFSR mcr p15, 0, r0, c5, c0, 1 ; IFSR mcr p15, 0, r0, c6, c0, 0 ; DFAR mcr p15, 0, r0, c6, c0, 2 ; IFAR mcr p15, 0, r0, c9, c13, 2 ; PMXEVCNTR mcr p15, 0, r0, c13, c0, 2 ; TPIDRURW mcr p15, 0, r0, c13, c0, 3 ; TPIDRURO ; Reset and start Cycle Counter mov r2, #0x80000000 ; clear overflow mcr p15, 0, r2, c9, c12, 3 mov r2, #0xd ; D, C, E mcr p15, 0, r2, c9, c12, 0 mov r2, #0x80000000 ; enable cycle counter mcr p15, 0, r2, c9, c12, 1 ; Reset and start Global Timer mov r0, #0x0 mov r1, #0x0 bl XTime_SetTime ; Reset and start Triple Timer counter #if defined SLEEP_TIMER_BASEADDR bl XTime_StartTTCTimer #endif ; make sure argc and argv are valid mov r0, #0 mov r1, #0 b __cmain ; jump to C startup code and r0, r0, r0 ; no op Ldone b Ldone ; Paranoia: we should never get here ; ************************************************************************ ; * ; * invalidate_dcache - invalidate the entire d-cache by set/way ; * ; * Note: for Cortex-A9, there is no cp instruction for invalidating ; * the whole D-cache. Need to invalidate each line. ; * ; ************************************************************************* invalidate_dcache mrc p15, 1, r0, c0, c0, 1 ; read CLIDR ands r3, r0, #0x7000000 mov r3, r3, lsr #23 ; cache level value (naturally aligned) beq finished mov r10, #0 ; start with level 0 loop1 add r2, r10, r10, lsr #1 ; work out 3xcachelevel mov r1, r0, lsr r2 ; bottom 3 bits are the Cache type for this level and r1, r1, #7 ; get those 3 bits alone cmp r1, #2 blt skip ; no cache or only instruction cache at this level mcr p15, 2, r10, c0, c0, 0 ; write the Cache Size selection register isb ; isb to sync the change to the CacheSizeID reg mrc p15, 1, r1, c0, c0, 0 ; reads current Cache Size ID register and r2, r1, #7 ; extract the line length field add r2, r2, #4 ; add 4 for the line length offset (log2 16 bytes) ldr r4, =0x3ff ands r4, r4, r1, lsr #3 ; r4 is the max number on the way size (right aligned) clz r5, r4 ; r5 is the bit position of the way size increment ldr r7, =0x7fff ands r7, r7, r1, lsr #13 ; r7 is the max number of the index size (right aligned) loop2 mov r9, r4 ; r9 working copy of the max way size (right aligned) loop3 orr r11, r10, r9, lsl r5 ; factor in the way number and cache number into r11 orr r11, r11, r7, lsl r2 ; factor in the index number mcr p15, 0, r11, c7, c6, 2 ; invalidate by set/way subs r9, r9, #1 ; decrement the way number bge loop3 subs r7, r7, #1 ; decrement the index bge loop2 skip add r10, r10, #2 ; increment the cache number cmp r3, r10 bgt loop1 finished mov r10, #0 ; switch back to cache level 0 mcr p15, 2, r10, c0, c0, 0 ; select current cache level in cssr dsb isb bx lr END
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	3,765	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/iccarm/asm_vectors.s	;**************************************************************************** ; Copyright (c) 2009 - 2020 Xilinx, Inc. All rights reserved. ; SPDX-License-Identifier: MIT ;************************************************************************* ;************************************************************************ ; ; @file asm_vectors.s ; ; This file contains the initial vector table for the Cortex A9 processor ; ; <pre> ; MODIFICATION HISTORY: ; ; Ver Who Date Changes ; ----- ------- -------- --------------------------------------------------- ; 1.00a Initial version ; 4.2 pkp 06/27/14 Modified return addresses for interrupt ; handlers ; 5.1 pkp 05/13/15 Saved the addresses of instruction causing data ; abort and prefetch abort into DataAbortAddr and ; PrefetchAbortAddr for further use to fix CR#854523 ; </pre> ; ; @note ; ; None. ; ;**************************************************************************** MODULE ?asm_vectors ;; Forward declaration of sections. SECTION IRQ_STACK:DATA:NOROOT(3) SECTION FIQ_STACK:DATA:NOROOT(3) SECTION SVC_STACK:DATA:NOROOT(3) SECTION ABT_STACK:DATA:NOROOT(3) SECTION UND_STACK:DATA:NOROOT(3) SECTION CSTACK:DATA:NOROOT(3) #include "xparameters.h" ;#include "xtime_l.h" #define UART_BAUDRATE 115200 IMPORT _prestart IMPORT __iar_program_start SECTION .intvec:CODE:NOROOT(2) PUBLIC _vector_table IMPORT IRQInterrupt IMPORT FIQInterrupt IMPORT SWInterrupt IMPORT DataAbortInterrupt IMPORT PrefetchAbortInterrupt IMPORT DataAbortAddr IMPORT PrefetchAbortAddr _vector_table ARM B __iar_program_start B Undefined B SVCHandler B PrefetchAbortHandler B DataAbortHandler NOP ; Placeholder for address exception vector B IRQHandler B FIQHandler SECTION .text:CODE:NOROOT(2) REQUIRE _vector_table ARM IRQHandler ; IRQ vector handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code bl IRQInterrupt ; IRQ vector ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #4 ; adjust return FIQHandler ; FIQ vector handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code FIQLoop bl FIQInterrupt ; FIQ vector ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #4 ; adjust return Undefined ; Undefined handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code b _prestart movs pc, lr SVCHandler ; SWI handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code tst r0, #0x20 ; check the T bit ldrneh r0, [lr,#-2] ; Thumb mode bicne r0, r0, #0xff00 ; Thumb mode ldreq r0, [lr,#-4] ; ARM mode biceq r0, r0, #0xff000000 ; ARM mode bl SWInterrupt ; SWInterrupt: call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code movs pc, lr ; adjust return DataAbortHandler ; Data Abort handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldr r0, =DataAbortAddr sub r1, lr,#8 str r1, [r0] ;Address of instruction causing data abort bl DataAbortInterrupt ;DataAbortInterrupt :call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #8 ; adjust return PrefetchAbortHandler ; Prefetch Abort handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldr r0, =PrefetchAbortAddr sub r1, lr,#4 str r1, [r0] ;Address of instruction causing prefetch abort bl PrefetchAbortInterrupt ; PrefetchAbortInterrupt: call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #4 ; adjust return END
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	4,612	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/armcc/translation_table.s	;**************************************************************************** ; Copyright (c) 2009 - 2020 Xilinx, Inc. All rights reserved. ; SPDX-License-Identifier: MIT ;************************************************************************* ;************************************************************************ ; ; @file translation_table.s ; ; This file contains the initialization for the MMU table in RAM ; needed by the Cortex A9 processor ; ; <pre> ; MODIFICATION HISTORY: ; ; Ver Who Date Changes ; ----- ---- -------- --------------------------------------------------- ; 1.00a ecm 10/20/09 Initial version ; 3.07a sgd 07/05/2012 Configuring device address spaces as shareable device ; instead of strongly-ordered. ; 4.2 pkp 09/02/14 modified translation table entries according to address map ; 4.2 pkp 09/11/14 modified translation table entries to resolve compilation ; error for solving CR#822897 ; 6.1 pkp 07/11/16 Corrected comments for memory attributes ; </pre> ; ; @note ; ; None. ; ;**************************************************************************** EXPORT MMUTable AREA \|.mmu_tbl\|,CODE,ALIGN=14 MMUTable ; Each table entry occupies one 32-bit word and there are ; 4096 entries, so the entire table takes up 16KB. ; Each entry covers a 1MB section. GBLA count GBLA sect ; 0x00000000 - 0x3ffffff (DDR Cacheable) count SETA 0 sect SETA 0 WHILE count<0x400 DCD sect + 0x15de6 ; S=1, TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 sect SETA sect+0x100000 count SETA count+1 WEND ; 0x40000000 - 0x7fffffff (GpAxi0) count SETA 0 WHILE count<0x400 DCD sect + 0xc02 ; S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0x80000000 - 0xbfffffff (GpAxi1) count SETA 0 WHILE count<0x400 DCD sect + 0xc02 ; S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xc0000000 - 0xdfffffff (undef) count SETA 0 WHILE count<0x200 DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xe0000000 - 0xe02fffff (IOP dev) count SETA 0 WHILE count<0x3 DCD sect + 0xc06 ; S=0, TEX=b010 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xe0300000 - 0xe0ffffff (undef/reserved) count SETA 0 WHILE count<0xD DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xe1000000 - 0xe1ffffff (NAND) count SETA 0 WHILE count<0x10 DCD sect + 0xc06 ; S=0, TEX=b010 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xe2000000 - 0xe3ffffff (NOR) count SETA 0 WHILE count<0x20 DCD sect + 0xc06 ; S=0, TEX=b010 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xe4000000 - 0xe5ffffff (SRAM) count SETA 0 WHILE count<0x20 DCD sect + 0xc0e ; S=b0 TEX=b000 AP=b11, Domain=b0, C=b1, B=b1 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xe6000000 - 0xf7ffffff (reserved) count SETA 0 WHILE count<0x120 DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xf8000c00 to 0xf8000fff, 0xf8010000 to 0xf88fffff and ; 0xf8f03000 to 0xf8ffffff are reserved but due to granual size of ; 1MB, it is not possible to define separate regions for them ; 0xf8000000 - 0xf8ffffff (APB device regs) count SETA 0 WHILE count<0x10 DCD sect + 0xc06 ; S=0, TEX=b010 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xf9000000 - 0xfbffffff (reserved) count SETA 0 WHILE count<0x30 DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xfc000000 - 0xfdffffff (QSPI) count SETA 0 WHILE count<0x20 DCD sect + 0xc0a ; S=b0 TEX=b000 AP=b11, Domain=b0, C=b1, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xfe000000 - 0xffefffff (reserved) count SETA 0 WHILE count<0x1F DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xfff00000 to 0xfffb0000 is reserved but due to granual size of ; 1MB, it is not possible to define separate region for it ; 0xfff00000 to 0xfffb0000 (OCM) count SETA 0 DCD sect + 0x4c0e ; S=b0 TEX=b100 AP=b11, Domain=b0, C=b1, B=b1 sect SETA sect+0x100000 END
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	15,378	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/armcc/boot.S	;**************************************************************************** ; Copyright (c) 2009 - 2022 Xilinx, Inc. All rights reserved. ; SPDX-License-Identifier: MIT ;************************************************************************* ;************************************************************************ ; ; @file boot.S ; ; This file contains the initial startup code for the Cortex A9 processor ; ; <pre> ; MODIFICATION HISTORY: ; ; Ver Who Date Changes ; ----- ------- -------- --------------------------------------------------- ; 1.00a ecm/sdm 10/20/09 Initial version ; 3.04a sdm 01/02/12 Updated to clear cp15 regs with unknown reset values ; 3.06a sgd 05/15/12 Updated L2CC Auxiliary and Tag RAM Latency control ; register settings. ; 3.06a asa 06/17/12 Modified the TTBR settings and L2 Cache auxiliary ; register settings. ; 3.07a sgd 07/05/12 Updated with reset and start Global Timer ; 3.07a sgd 10/19/12 SMC NOR and SRAM initialization with build option ; 4.2 pkp 06/19/14 Enabled asynchronous abort exception ; 4.2 pkp 08/04/14 Removed PEEP board related code which contained ; initialization of uart smc nor and sram ; 5.0 pkp 16/12/14 Modified initialization code to enable scu after ; MMU is enabled and removed incorrect initialization ; of TLB lockdown register to fix CR#830580 ; 5.1 pkp 05/13/15 Changed the initialization order so to first invalidate ; caches and TLB, enable MMU and caches, then enable SMP ; bit in ACTLR. L2Cache invalidation and enabling of L2Cache ; is done later. ; 5.4 asa 12/06/15 Added code to initialize SPSR for all relevant modes. ; 6.0 mus 04/08/16 Added code to detect zynq-7000 base silicon configuration and ; attempt to enable dual core behavior on single cpu zynq-7000s devices ; is prevented from corrupting system behavior. ; 6.0 mus 24/08/16 Check CPU core before putting cpu1 to reset for single core ; zynq-7000s devices ; 6.6 srm 10/25/17 Added timer configuration using XTime_StartTTCTimer API. ; Now the TTC instance as specified by the user will be ; started. ; 7.7 asa 01/06/22 Removed Cortex-A9 errata handling for errata ; 742230 and 743622. These do not apply to ; Cortex-A9 revision r3p0 being used in Zynq ; platforms. ; </pre> ; ; @note ; ; None. ; ;**************************************************************************** #include "xparameters.h" #include "xil_errata.h" #define UART_BAUDRATE 115200 EXPORT _prestart EXPORT _boot IMPORT \|Image$$ARM_LIB_STACK$$ZI$$Limit\| IMPORT \|Image$$IRQ_STACK$$ZI$$Limit\| IMPORT \|Image$$SPV_STACK$$ZI$$Limit\| IMPORT \|Image$$ABORT_STACK$$ZI$$Limit\| IMPORT MMUTable IMPORT _vector_table IMPORT __main IMPORT Xil_ExceptionInit IMPORT XTime_SetTime #if defined SLEEP_TIMER_BASEADDR IMPORT XTime_StartTTCTimer #endif PSS_L2CC_BASE_ADDR EQU 0xF8F02000 PSS_SLCR_BASE_ADDR EQU 0xF8000000 L2CCWay EQU (PSS_L2CC_BASE_ADDR + 0x077C) ;(PSS_L2CC_BASE_ADDR + PSS_L2CC_CACHE_INVLD_WAY_OFFSET) L2CCSync EQU (PSS_L2CC_BASE_ADDR + 0x0730) ;(PSS_L2CC_BASE_ADDR + PSS_L2CC_CACHE_SYNC_OFFSET) L2CCCrtl EQU (PSS_L2CC_BASE_ADDR + 0x0100) ;(PSS_L2CC_BASE_ADDR + PSS_L2CC_CNTRL_OFFSET) L2CCAuxCrtl EQU (PSS_L2CC_BASE_ADDR + 0x0104) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_AUX_CNTRL_OFFSET) L2CCTAGLatReg EQU (PSS_L2CC_BASE_ADDR + 0x0108) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_TAG_RAM_CNTRL_OFFSET) L2CCDataLatReg EQU (PSS_L2CC_BASE_ADDR + 0x010C) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_DATA_RAM_CNTRL_OFFSET) L2CCIntClear EQU (PSS_L2CC_BASE_ADDR + 0x0220) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_IAR_OFFSET) L2CCIntRaw EQU (PSS_L2CC_BASE_ADDR + 0x021C) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_ISR_OFFSET) SLCRlockReg EQU (PSS_SLCR_BASE_ADDR + 0x04) /(PSS_SLCR_BASE_ADDR + XPSS_SLCR_LOCK_OFFSET)/ SLCRUnlockReg EQU (PSS_SLCR_BASE_ADDR + 0x08) /(PSS_SLCR_BASE_ADDR + XPSS_SLCR_UNLOCK_OFFSET)/ SLCRL2cRamReg EQU (PSS_SLCR_BASE_ADDR + 0xA1C) /(PSS_SLCR_BASE_ADDR + XPSS_SLCR_L2C_RAM_OFFSET)/ SLCRCPURSTReg EQU (0xF8000000 + 0x244) ;(XPS_SYS_CTRL_BASEADDR + A9_CPU_RST_CTRL_OFFSET) EFUSEStaus EQU (0xF800D000 + 0x10) ;(XPS_EFUSE_BASEADDR + EFUSE_STATUS_OFFSET) SLCRlockKey EQU 0x767B /* SLCR lock key / SLCRUnlockKey EQU 0xDF0D / SLCR unlock key / SLCRL2cRamConfig EQU 0x00020202 / SLCR L2C ram configuration / CRValMmuCac EQU 2_01000000000101 ; Enable IDC, and MMU CRValHiVectorAddr EQU 2_10000000000000 ; Set the Vector address to high, 0xFFFF0000 L2CCAuxControl EQU 0x72360000 ; Enable all prefetching, Way Size (16 KB) and High Priority for SO and Dev Reads Enable L2CCControl EQU 0x01 ; Enable L2CC L2CCTAGLatency EQU 0x0111 ; 7 Cycles of latency for TAG RAM L2CCDataLatency EQU 0x0121 ; 7 Cycles of latency for DATA RAM FPEXC_EN EQU 0x40000000 ; FPU enable bit, (1 << 30) AREA \|.boot\|, CODE PRESERVE8 ; this initializes the various processor modes _prestart _boot #if XPAR_CPU_ID==0 ; only allow cp0 through mrc p15,0,r1,c0,c0,5 and r1, r1, #0xf cmp r1, #0 beq CheckEFUSE EndlessLoop0 wfe b EndlessLoop0 CheckEFUSE ldr r0,=EFUSEStaus ldr r1,[r0] ; Read eFuse setting ands r1,r1,#0x80 ; Check whether device is having single core beq OKToRun ; Single core device, reset CPU1 ldr r0,=SLCRUnlockReg ; Load SLCR base address base + unlock register ldr r1,=SLCRUnlockKey ; set unlock key str r1, [r0] ; Unlock SLCR ldr r0,=SLCRCPURSTReg ldr r1,[r0] ; Read CPU Software Reset Control register orr r1,r1,#0x22 str r1,[r0] ; Reset CPU1 ldr r0,=SLCRlockReg ; Load SLCR base address base + lock register ldr r1,=SLCRlockKey ; set lock key str r1, [r0] ; lock SLCR #elif XPAR_CPU_ID==1 ; only allow cpu1 through mrc p15,0,r1,c0,c0,5 and r1, r1, #0xf cmp r1, #1 beq CheckEFUSE1 b EndlessLoop1 CheckEFUSE1 ldr r0,=EFUSEStaus ldr r1,[r0] ; Read eFuse setting ands r1,r1,#0x80 ; Check whether device is having single core beq OKToRun EndlessLoop1 wfe b EndlessLoop1 #endif OKToRun mrc p15, 0, r0, c0, c0, 0 / Get the revision / and r5, r0, #0x00f00000 and r6, r0, #0x0000000f orr r6, r6, r5, lsr #20-4 / set VBAR to the _vector_table address in scatter file / ldr r0, =_vector_table mcr p15, 0, r0, c12, c0, 0 ;invalidate scu ldr r7, =0xf8f0000c ldr r6, =0xffff str r6, [r7] ;Invalidate caches and TLBs mov r0,#0 ; r0 = 0 mcr p15, 0, r0, c8, c7, 0 ; invalidate TLBs mcr p15, 0, r0, c7, c5, 0 ; invalidate icache mcr p15, 0, r0, c7, c5, 6 ; Invalidate branch predictor array bl invalidate_dcache ; invalidate dcache ; Disable MMU, if enabled mrc p15, 0, r0, c1, c0, 0 ; read CP15 register 1 bic r0, r0, #0x1 ; clear bit 0 mcr p15, 0, r0, c1, c0, 0 ; write value back #ifdef SHAREABLE_DDR ; Mark the entire DDR memory as shareable ldr r3, =0x3ff ; 1024 entries to cover 1G DDR ldr r0, =TblBase ; MMU Table address in memory ldr r2, =0x15de6 ; S=1, TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 shareable_loop: str r2, [r0] ; write the entry to MMU table add r0, r0, #0x4 ; next entry in the table add r2, r2, #0x100000 ; next section subs r3, r3, #1 bge shareable_loop ; loop till 1G is covered #endif mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the irq stack pointer and r2, r1, r0 orr r2, r2, #0x12 ; IRQ mode msr apsr, r2 ; was cpsr, apsr is considered synonym ldr r13,=\|Image$$IRQ_STACK$$ZI$$Limit\| ; IRQ stack pointer bic r2, r2, #(0x1 << 9) ; Set EE bit to little-endian msr spsr_fsxc,r2 mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the supervisor stack pointer and r2, r1, r0 orr r2, r2, #0x13 ; supervisor mode msr apsr, r2 ; was cpsr, apsr is considered synonym ldr r13,=\|Image$$SPV_STACK$$ZI$$Limit\| ; Supervisor stack pointer bic r2, r2, #(0x1 << 9) ; Set EE bit to little-endian msr spsr_fsxc,r2 mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the Abort stack pointer and r2, r1, r0 orr r2, r2, #0x17 ; Abort mode msr apsr, r2 ; was cpsr, apsr is considered synonym ldr r13,=\|Image$$ABORT_STACK$$ZI$$Limit\| ; Abort stack pointer bic r2, r2, #(0x1 << 9) ; Set EE bit to little-endian msr spsr_fsxc,r2 mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the system stack pointer and r2, r1, r0 orr r2, r2, #0x1f ; SYS mode msr apsr, r2 ; was cpsr, apsr is considered synonym ldr r13,=\|Image$$ARM_LIB_STACK$$ZI$$Limit\| ; SYS stack pointer ;set scu enable bit in scu ldr r7, =0xf8f00000 ldr r0, [r7] orr r0, r0, #0x1 str r0, [r7] ; enable MMU and cache ldr r0,=MMUTable ; Load MMU translation table base orr r0, r0, #0x5B ; Outer-cacheable, WB mcr p15, 0, r0, c2, c0, 0 ; TTB0 mvn r0,#0 mcr p15,0,r0,c3,c0,0 ; Enable mmu, icahce and dcache ldr r0,=CRValMmuCac mcr p15,0,r0,c1,c0,0 ; Enable cache and MMU dsb ; dsb allow the MMU to start up isb ; isb flush prefetch buffer ; Write to ACTLR mrc p15, 0,r0, c1, c0, 1 ; Read ACTLR orr r0, r0, #(0x01 << 6) ; SMP bit orr r0, r0, #(0x01 ) ; Cache/TLB maintenance broadcast mcr p15, 0,r0, c1, c0, 1 ; Write ACTLR ; Invalidate L2 Cache and initialize L2 Cache ; For AMP, assume running on CPU1. Don't initialize L2 Cache (up to Linux) #if USE_AMP!=1 ldr r0,=L2CCCrtl ; Load L2CC base address base + control register mov r1, #0 ; force the disable bit str r1, [r0] ; disable the L2 Caches ldr r0,=L2CCAuxCrtl ; Load L2CC base address base + Aux control register ldr r1,[r0] ; read the register ldr r2,=L2CCAuxControl ; set the default bits orr r1,r1,r2 str r1, [r0] ; store the Aux Control Register ldr r0,=L2CCTAGLatReg ; Load L2CC base address base + TAG Latency address ldr r1,=L2CCTAGLatency ; set the latencies for the TAG str r1, [r0] ; store the TAG Latency register Register ldr r0,=L2CCDataLatReg ; Load L2CC base address base + Data Latency address ldr r1,=L2CCDataLatency ; set the latencies for the Data str r1, [r0] ; store the Data Latency register Register ldr r0,=L2CCWay ; Load L2CC base address base + way register ldr r2, =0xFFFF str r2, [r0] ; force invalidate ldr r0,=L2CCSync ; need to poll 0x730, PSS_L2CC_CACHE_SYNC_OFFSET ; Load L2CC base address base + sync register ; poll for completion Sync ldr r1, [r0] cmp r1, #0 bne Sync ldr r0,=L2CCIntRaw ; clear pending interrupts ldr r1,[r0] ldr r0,=L2CCIntClear str r1,[r0] ldr r0,=SLCRUnlockReg ;Load SLCR base address base + unlock register ldr r1,=SLCRUnlockKey ;set unlock key str r1, [r0] ;Unlock SLCR ldr r0,=SLCRL2cRamReg ;Load SLCR base address base + l2c Ram Control register ldr r1,=SLCRL2cRamConfig ;set the configuration value str r1, [r0] ;store the L2c Ram Control Register ldr r0,=SLCRlockReg ;Load SLCR base address base + lock register ldr r1,=SLCRlockKey ;set lock key str r1, [r0] ;lock SLCR ldr r0,=L2CCCrtl ; Load L2CC base address base + control register ldr r1,[r0] ; read the register mov r2, #L2CCControl ; set the enable bit orr r1,r1,r2 str r1, [r0] ; enable the L2 Caches #endif mov r0, r0 mrc p15, 0, r1, c1, c0, 2 ; read cp access control register (CACR) into r1 orr r1, r1, #(0xf << 20) ; enable full access for p10 & p11 mcr p15, 0, r1, c1, c0, 2 ; write back into CACR ; enable vfp fmrx r1, FPEXC ; read the exception register orr r1,r1, #FPEXC_EN ; set VFP enable bit, leave the others in orig state fmxr FPEXC, r1 ; write back the exception register mrc p15, 0, r0, c1, c0, 0 ; flow prediction enable orr r0, r0, #(0x01 << 11) ; #0x8000 mcr p15,0,r0,c1,c0,0 mrc p15, 0, r0, c1, c0, 1 ; read Auxiliary Control Register orr r0, r0, #(0x1 << 2) ; enable Dside prefetch orr r0, r0, #(0x1 << 1) ; enable L2 prefetch mcr p15, 0, r0, c1, c0, 1 ; write Auxiliary Control Register mrs r0, cpsr / get the current PSR / bic r0, r0, #0x100 / enable asynchronous abort exception / msr cpsr_xsf, r0 ; Clear cp15 regs with unknown reset values mov r0, #0x0 mcr p15, 0, r0, c5, c0, 0 ; DFSR mcr p15, 0, r0, c5, c0, 1 ; IFSR mcr p15, 0, r0, c6, c0, 0 ; DFAR mcr p15, 0, r0, c6, c0, 2 ; IFAR mcr p15, 0, r0, c9, c13, 2 ; PMXEVCNTR mcr p15, 0, r0, c13, c0, 2 ; TPIDRURW mcr p15, 0, r0, c13, c0, 3 ; TPIDRURO ; Reset and start Cycle Counter mov r2, #0x80000000 ; clear overflow mcr p15, 0, r2, c9, c12, 3 mov r2, #0xd ; D, C, E mcr p15, 0, r2, c9, c12, 0 mov r2, #0x80000000 ; enable cycle counter mcr p15, 0, r2, c9, c12, 1 ; Reset and start Global Timer mov r0, #0x0 mov r1, #0x0 bl XTime_SetTime ; Reset and start Triple Timer counter #if defined SLEEP_TIMER_BASEADDR bl XTime_StartTTCTimer #endif #ifdef PROFILING / defined in Makefile / / Setup profiling stuff / bl _profile_init #endif / PROFILING / ; make sure argc and argv are valid mov r0, #0 mov r1, #0 b __main ; jump to C startup code and r0, r0, r0 ; no op Ldone b Ldone ; Paranoia: we should never get here ; ************************************************************************ ; * ; * invalidate_dcache - invalidate the entire d-cache by set/way ; * ; * Note: for Cortex-A9, there is no cp instruction for invalidating ; * the whole D-cache. Need to invalidate each line. ; * ; ************************************************************************* invalidate_dcache mrc p15, 1, r0, c0, c0, 1 ; read CLIDR ands r3, r0, #0x7000000 mov r3, r3, lsr #23 ; cache level value (naturally aligned) beq finished mov r10, #0 ; start with level 0 loop1 add r2, r10, r10, lsr #1 ; work out 3xcachelevel mov r1, r0, lsr r2 ; bottom 3 bits are the Cache type for this level and r1, r1, #7 ; get those 3 bits alone cmp r1, #2 blt skip ; no cache or only instruction cache at this level mcr p15, 2, r10, c0, c0, 0 ; write the Cache Size selection register isb ; isb to sync the change to the CacheSizeID reg mrc p15, 1, r1, c0, c0, 0 ; reads current Cache Size ID register and r2, r1, #7 ; extract the line length field add r2, r2, #4 ; add 4 for the line length offset (log2 16 bytes) ldr r4, =0x3ff ands r4, r4, r1, lsr #3 ; r4 is the max number on the way size (right aligned) clz r5, r4 ; r5 is the bit position of the way size increment ldr r7, =0x7fff ands r7, r7, r1, lsr #13 ; r7 is the max number of the index size (right aligned) loop2 mov r9, r4 ; r9 working copy of the max way size (right aligned) loop3 orr r11, r10, r9, lsl r5 ; factor in the way number and cache number into r11 orr r11, r11, r7, lsl r2 ; factor in the index number mcr p15, 0, r11, c7, c6, 2 ; invalidate by set/way subs r9, r9, #1 ; decrement the way number bge loop3 subs r7, r7, #1 ; decrement the index bge loop2 skip add r10, r10, #2 ; increment the cache number cmp r3, r10 bgt loop1 finished mov r10, #0 ; switch back to cache level 0 mcr p15, 2, r10, c0, c0, 0 ; select current cache level in cssr isb bx lr END
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	4,043	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/armcc/asm_vectors.s	;**************************************************************************** ; Copyright (c) 2009 - 2020 Xilinx, Inc. All rights reserved. ; SPDX-License-Identifier: MIT ;************************************************************************* ;************************************************************************ ; ; @file asm_vectors.s ; ; This file contains the initial vector table for the Cortex A9 processor ; ; <pre> ; MODIFICATION HISTORY: ; ; Ver Who Date Changes ; ----- ------- -------- --------------------------------------------------- ; 1.00a ecm/sdm 10/20/09 Initial version ; 3.11a asa 9/17/13 Added support for neon. ; 4.00 pkp 01/22/14 Modified return addresses for interrupt ; handlers ; 5.1 pkp 05/13/15 Saved the addresses of instruction causing data ; abort and prefetch abort into DataAbortAddr and ; PrefetchAbortAddr for further use to fix CR#854523 ; 5.4 pkp 12/03/15 Added handler for undefined exception ;</pre> ; ; @note ; ; None. ; ;**************************************************************************** EXPORT _vector_table EXPORT IRQHandler IMPORT _boot IMPORT _prestart IMPORT IRQInterrupt IMPORT FIQInterrupt IMPORT SWInterrupt IMPORT DataAbortInterrupt IMPORT PrefetchAbortInterrupt IMPORT UndefinedException IMPORT DataAbortAddr IMPORT PrefetchAbortAddr IMPORT UndefinedExceptionAddr AREA \|.vectors\|, CODE REQUIRE8 {TRUE} PRESERVE8 {TRUE} ENTRY ; define this as an entry point _vector_table B _boot B Undefined B SVCHandler B PrefetchAbortHandler B DataAbortHandler NOP ; Placeholder for address exception vector B IRQHandler B FIQHandler IRQHandler ; IRQ vector handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code vpush {d0-d7} vpush {d16-d31} vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} bl IRQInterrupt ; IRQ vector pop {r1} vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d16-d31} vpop {d0-d7} ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #4 ; adjust return FIQHandler ; FIQ vector handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code vpush {d0-d7} vpush {d16-d31} vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} FIQLoop bl FIQInterrupt ; FIQ vector pop {r1} vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d16-d31} vpop {d0-d7} ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #4 ; adjust return Undefined ; Undefined handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldr r0, =UndefinedExceptionAddr sub r1, lr,#4 str r1, [r0] ; Address of instruction causing undefined exception bl UndefinedException ; UndefinedException: call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code movs pc, lr SVCHandler ; SWI handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code tst r0, #0x20 ; check the T bit ldrneh r0, [lr,#-2] ; Thumb mode bicne r0, r0, #0xff00 ; Thumb mode ldreq r0, [lr,#-4] ; ARM mode biceq r0, r0, #0xff000000 ; ARM mode bl SWInterrupt ; SWInterrupt: call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code movs pc, lr ; adjust return DataAbortHandler ; Data Abort handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldr r0, =DataAbortAddr sub r1, lr,#8 str r1, [r0] ;Address of instruction causing data abort bl DataAbortInterrupt ;DataAbortInterrupt :call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #8 ; adjust return PrefetchAbortHandler ; Prefetch Abort handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldr r0, =PrefetchAbortAddr sub r1, lr,#4 str r1, [r0] ;Address of instruction causing prefetch abort bl PrefetchAbortInterrupt ; PrefetchAbortInterrupt: call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #4 ; adjust return END
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	8,023	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/gcc/translation_table.S	/****************************************************************************** * Copyright (c) 2009 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file translation_table.S * * @addtogroup a9_boot_code * @{ * <h2> translation_table.S </h2> * The translation_table.S contains a static page table required by MMU for * cortex-A9. This translation table is flat mapped (input address = output * address) with default memory attributes defined for zynq architecture. It * utilizes short descriptor translation table format with each section defining * 1 MB of memory. * * The overview of translation table memory attributes is described below. * \| \| Memory Range \| Definition in Translation Table \| \|-----------------------\|-------------------------\|-----------------------------------\| \| DDR \| 0x00000000 - 0x3FFFFFFF \| Normal write-back Cacheable \| \| PL \| 0x40000000 - 0xBFFFFFFF \| Strongly Ordered \| \| Reserved \| 0xC0000000 - 0xDFFFFFFF \| Unassigned \| \| Memory mapped devices \| 0xE0000000 - 0xE02FFFFF \| Device Memory \| \| Reserved \| 0xE0300000 - 0xE0FFFFFF \| Unassigned \| \| NAND, NOR \| 0xE1000000 - 0xE3FFFFFF \| Device memory \| \| SRAM \| 0xE4000000 - 0xE5FFFFFF \| Normal write-back Cacheable \| \| Reserved \| 0xE6000000 - 0xF7FFFFFF \| Unassigned \| \| AMBA APB Peripherals \| 0xF8000000 - 0xF8FFFFFF \| Device Memory \| \| Reserved \| 0xF9000000 - 0xFBFFFFFF \| Unassigned \| \| Linear QSPI - XIP \| 0xFC000000 - 0xFDFFFFFF \| Normal write-through cacheable \| \| Reserved \| 0xFE000000 - 0xFFEFFFFF \| Unassigned \| \| OCM \| 0xFFF00000 - 0xFFFFFFFF \| Normal inner write-back cacheable \| * For region 0x00000000 - 0x3FFFFFFF, a system where DDR is less than 1 GB, * region after DDR and before PL is marked as undefined/reserved in translation * table. In 0xF8000000 - 0xF8FFFFFF, 0xF8000C00 - 0xF8000FFF, 0xF8010000 - * 0xF88FFFFF and 0xF8F03000 to 0xF8FFFFFF are reserved but due to granual size * of 1 MB, it is not possible to define separate regions for them. For region * 0xFFF00000 - 0xFFFFFFFF, 0xFFF00000 to 0xFFFB0000 is reserved but due to 1MB * granual size, it is not possible to define separate region for it. * * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 1.00a ecm 10/20/09 Initial version * 3.04a sdm 01/13/12 Updated MMU table to mark DDR memory as Shareable * 3.07a sgd 07/05/2012 Configuring device address spaces as shareable device * instead of strongly-ordered. * 3.07a asa 07/17/2012 Changed the property of the ".mmu_tbl" section. * 4.2 pkp 09/02/2014 added entries for 0xfe000000 to 0xffefffff as reserved * and 0xe0000000 - 0xe1ffffff is broken down into * 0xe0000000 - 0xe02fffff (memory mapped divides) * 0xe0300000 - 0xe0ffffff (reserved) and * 0xe1000000 - 0xe1ffffff (NAND) * 5.2 pkp 06/08/2015 put a check for XPAR_PS7_DDR_0_S_AXI_BASEADDR to confirm * if DDR is present or not and accordingly generate the * translation table * 6.1 pkp 07/11/2016 Corrected comments for memory attributes * 6.8 mus 07/12/2018 Mark DDR memory as inner cacheable, if BSP is built * with the USE_AMP flag. * </pre> * * *****************************************************************************/ #include "xparameters.h" .globl MMUTable .section .mmu_tbl,"a" MMUTable: / Each table entry occupies one 32-bit word and there are * 4096 entries, so the entire table takes up 16KB. * Each entry covers a 1MB section. / .set SECT, 0 #ifdef XPAR_PS7_DDR_0_S_AXI_BASEADDR .set DDR_START, XPAR_PS7_DDR_0_S_AXI_BASEADDR .set DDR_END, XPAR_PS7_DDR_0_S_AXI_HIGHADDR .set DDR_SIZE, (DDR_END - DDR_START)+1 .set DDR_REG, DDR_SIZE/0x100000 #else .set DDR_REG, 0 #endif .set UNDEF_REG, 0x3FF - DDR_REG #ifndef USE_AMP /0x00000000 - 0x00100000 (inner and outer cacheable )/ .word SECT + 0x15de6 / S=b1 TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 / #else /0x00000000 - 0x00100000 (inner cacheable )/ .word SECT + 0x14de6 / S=b1 TEX=b100 AP=b11, Domain=b1111, C=b0, B=b1 / #endif .set SECT, SECT+0x100000 .rept DDR_REG / (DDR Cacheable) / .word SECT + 0x15de6 / S=b1 TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 / .set SECT, SECT+0x100000 .endr .rept UNDEF_REG / (unassigned/reserved). * Generates a translation fault if accessed / .word SECT + 0x0 / S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 / .set SECT, SECT+0x100000 .endr .rept 0x0400 / 0x40000000 - 0x7fffffff (FPGA slave0) / .word SECT + 0xc02 / S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b0 / .set SECT, SECT+0x100000 .endr .rept 0x0400 / 0x80000000 - 0xbfffffff (FPGA slave1) / .word SECT + 0xc02 / S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b0 / .set SECT, SECT+0x100000 .endr .rept 0x0200 / 0xc0000000 - 0xdfffffff (unassigned/reserved). * Generates a translation fault if accessed / .word SECT + 0x0 / S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 / .set SECT, SECT+0x100000 .endr .rept 0x003 / 0xe0000000 - 0xe02fffff (Memory mapped devices) * UART/USB/IIC/SPI/CAN/GEM/GPIO/QSPI/SD/NAND / .word SECT + 0xc06 / S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 / .set SECT, SECT+0x100000 .endr .rept 0x0D / 0xe0300000 - 0xe0ffffff (unassigned/reserved). * Generates a translation fault if accessed / .word SECT + 0x0 / S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 / .set SECT, SECT+0x100000 .endr .rept 0x0010 / 0xe1000000 - 0xe1ffffff (NAND) / .word SECT + 0xc06 / S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 / .set SECT, SECT+0x100000 .endr .rept 0x0020 / 0xe2000000 - 0xe3ffffff (NOR) / .word SECT + 0xc06 / S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 / .set SECT, SECT+0x100000 .endr .rept 0x0020 / 0xe4000000 - 0xe5ffffff (SRAM) / .word SECT + 0xc0e / S=b0 TEX=b000 AP=b11, Domain=b0, C=b1, B=b1 / .set SECT, SECT+0x100000 .endr .rept 0x0120 / 0xe6000000 - 0xf7ffffff (unassigned/reserved). * Generates a translation fault if accessed / .word SECT + 0x0 / S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 / .set SECT, SECT+0x100000 .endr / 0xf8000c00 to 0xf8000fff, 0xf8010000 to 0xf88fffff and 0xf8f03000 to 0xf8ffffff are reserved but due to granual size of 1MB, it is not possible to define separate regions for them / .rept 0x0010 / 0xf8000000 - 0xf8ffffff (AMBA APB Peripherals) / .word SECT + 0xc06 / S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 / .set SECT, SECT+0x100000 .endr .rept 0x0030 / 0xf9000000 - 0xfbffffff (unassigned/reserved). * Generates a translation fault if accessed / .word SECT + 0x0 / S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 / .set SECT, SECT+0x100000 .endr .rept 0x0020 / 0xfc000000 - 0xfdffffff (Linear QSPI - XIP) / .word SECT + 0xc0a / S=b0 TEX=b000 AP=b11, Domain=b0, C=b1, B=b0 / .set SECT, SECT+0x100000 .endr .rept 0x001F / 0xfe000000 - 0xffefffff (unassigned/reserved). * Generates a translation fault if accessed / .word SECT + 0x0 / S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 / .set SECT, SECT+0x100000 .endr / 0xfff00000 to 0xfffb0000 is reserved but due to granual size of 1MB, it is not possible to define separate region for it 0xfff00000 - 0xffffffff 256K OCM when mapped to high address space inner-cacheable / .word SECT + 0x4c0e / S=b0 TEX=b100 AP=b11, Domain=b0, C=b1, B=b1 / .set SECT, SECT+0x100000 .end /* * @} End of "addtogroup a9_boot_code". */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	3,153	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/gcc/xil-crt0.S	/****************************************************************************** * Copyright (c) 2009 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file xil-crt0.S * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 1.00a ecm 10/20/09 Initial version * 3.05a sdm 02/02/12 Added code for profiling * 3.06a sgd 05/16/12 Added global constructors and cleanup code * Uart initialization based on compiler flag * 3.07a sgd 07/05/12 Updated with reset and start Global Timer * 3.07a sgd 10/19/12 SMC NOR and SRAM initialization with build option * 4.2 pkp 08/04/14 Removed PEEP board related code which contained * initialization of uart smc nor and sram * 5.3 pkp 10/07/15 Added support for OpenAMP by not initializing global * timer when USE_AMP flag is defined * 6.6 srm 10/18/17 Added timer configuration using XTime_StartTTCTimer API. * Now the TTC instance as specified by the user will be * started. * 7.7 adk 11/30/21 Added support for xiltimer library. * </pre> * * @note * * None. * *****************************************************************************/ #include "bspconfig.h" #include "xparameters.h" .file "xil-crt0.S" .section ".got2","aw" .align 2 .text .Lsbss_start: .long __sbss_start .Lsbss_end: .long __sbss_end .Lbss_start: .long __bss_start .Lbss_end: .long __bss_end .Lstack: .long __stack .globl _start _start: bl __cpu_init / Initialize the CPU first (BSP provides this) / mov r0, #0 / clear sbss / ldr r1,.Lsbss_start / calculate beginning of the SBSS / ldr r2,.Lsbss_end / calculate end of the SBSS / .Lloop_sbss: cmp r1,r2 bge .Lenclsbss / If no SBSS, no clearing required / str r0, [r1], #4 b .Lloop_sbss .Lenclsbss: / clear bss / ldr r1,.Lbss_start / calculate beginning of the BSS / ldr r2,.Lbss_end / calculate end of the BSS / .Lloop_bss: cmp r1,r2 bge .Lenclbss / If no BSS, no clearing required / str r0, [r1], #4 b .Lloop_bss .Lenclbss: / set stack pointer / ldr r13,.Lstack / stack address / / Reset and start Global Timer / mov r0, #0x0 mov r1, #0x0 / Reset and start Triple Timer Counter / #if defined SLEEP_TIMER_BASEADDR bl XTime_StartTTCTimer #endif #ifndef XPAR_XILTIMER_ENABLED #if USE_AMP != 1 bl XTime_SetTime #endif #endif #ifdef PROFILING / defined in Makefile / / Setup profiling stuff / bl _profile_init #endif / PROFILING / / run global constructors / bl __libc_init_array / make sure argc and argv are valid / mov r0, #0 mov r1, #0 / Let her rip / bl main / Cleanup global constructors / bl __libc_fini_array #ifdef PROFILING / Cleanup profiling stuff / bl _profile_clean #endif / PROFILING / / All done / bl exit .Lexit: / should never get here */ b .Lexit .Lstart: .size _start,.Lstart-_start
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	4,892	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/gcc/asm_vectors.S	/****************************************************************************** * Copyright (c) 2009 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file asm_vectors.S * * This file contains the initial vector table for the Cortex A9 processor * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 1.00a ecm/sdm 10/20/09 Initial version * 3.05a sdm 02/02/12 Save lr when profiling is enabled * 3.10a srt 04/18/13 Implemented ARM Erratas. Please refer to file * 'xil_errata.h' for errata description * 4.00a pkp 22/01/14 Modified return addresses for interrupt * handlers (DataAbortHandler and SVCHandler) * to fix CR#767251 * 5.1 pkp 05/13/15 Saved the addresses of instruction causing data * abort and prefetch abort into DataAbortAddr and * PrefetchAbortAddr for further use to fix CR#854523 * 5.4 pkp 12/03/15 Added handler for undefined exception * 6.8 mus 04/27/18 Removed __ARM_NEON__ flag definition. Now, * saving/restoring of of HW floating point register * would be done through newly introduced flag * FPU_HARD_FLOAT_ABI_ENABLED. This new flag will be * configured based on the -mfpu-abi option in extra * compiler flags. * </pre> * * @note * * None. * *****************************************************************************/ #include "xil_errata.h" #include "bspconfig.h" .org 0 .text .globl _vector_table .section .vectors _vector_table: B _boot B Undefined B SVCHandler B PrefetchAbortHandler B DataAbortHandler NOP / Placeholder for address exception vector/ B IRQHandler B FIQHandler IRQHandler: / IRQ vector handler / stmdb sp!,{r0-r3,r12,lr} / state save from compiled code/ #if FPU_HARD_FLOAT_ABI_ENABLED vpush {d0-d7} vpush {d16-d31} vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} #endif #ifdef PROFILING ldr r2, =prof_pc subs r3, lr, #0 str r3, [r2] #endif bl IRQInterrupt / IRQ vector / #if FPU_HARD_FLOAT_ABI_ENABLED pop {r1} vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d16-d31} vpop {d0-d7} #endif ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / subs pc, lr, #4 / adjust return / FIQHandler: / FIQ vector handler / stmdb sp!,{r0-r3,r12,lr} / state save from compiled code / #if FPU_HARD_FLOAT_ABI_ENABLED vpush {d0-d7} vpush {d16-d31} vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} #endif FIQLoop: bl FIQInterrupt / FIQ vector / #if FPU_HARD_FLOAT_ABI_ENABLED pop {r1} vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d16-d31} vpop {d0-d7} #endif ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / subs pc, lr, #4 / adjust return / Undefined: / Undefined handler / stmdb sp!,{r0-r3,r12,lr} / state save from compiled code / ldr r0, =UndefinedExceptionAddr sub r1, lr, #4 str r1, [r0] / Store address of instruction causing undefined exception / bl UndefinedException / UndefinedException: call C function here / ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / movs pc, lr SVCHandler: / SWI handler / stmdb sp!,{r0-r3,r12,lr} / state save from compiled code / tst r0, #0x20 / check the T bit / ldrneh r0, [lr,#-2] / Thumb mode / bicne r0, r0, #0xff00 / Thumb mode / ldreq r0, [lr,#-4] / ARM mode / biceq r0, r0, #0xff000000 / ARM mode / bl SWInterrupt / SWInterrupt: call C function here / ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / movs pc, lr /return to the next instruction after the SWI instruction / DataAbortHandler: / Data Abort handler / #ifdef CONFIG_ARM_ERRATA_775420 dsb #endif stmdb sp!,{r0-r3,r12,lr} / state save from compiled code / ldr r0, =DataAbortAddr sub r1, lr, #8 str r1, [r0] / Stores instruction causing data abort / bl DataAbortInterrupt /DataAbortInterrupt :call C function here / ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / subs pc, lr, #8 / points to the instruction that caused the Data Abort exception / PrefetchAbortHandler: / Prefetch Abort handler / #ifdef CONFIG_ARM_ERRATA_775420 dsb #endif stmdb sp!,{r0-r3,r12,lr} / state save from compiled code / ldr r0, =PrefetchAbortAddr sub r1, lr, #4 str r1, [r0] / Stores instruction causing prefetch abort / bl PrefetchAbortInterrupt / PrefetchAbortInterrupt: call C function here / ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / subs pc, lr, #4 / points to the instruction that caused the Prefetch Abort exception */ .end
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	17,124	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/gcc/boot.S	/****************************************************************************** * Copyright (c) 2010 - 2022 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file boot.S * * @addtogroup a9_boot_code Cortex A9 Processor Boot Code * @{ * <h2> boot.S </h2> * The boot code performs minimum configuration which is required for an * application to run starting from processor reset state of the processor. Below is a * sequence illustrating what all configuration is performed before control * reaches to main function. * * 1. Program vector table base for exception handling * 2. Invalidate instruction cache, data cache and TLBs * 3. Program stack pointer for various modes (IRQ, FIQ, supervisor, undefine, * abort, system) * 4. Configure MMU with short descriptor translation table format and program * base address of translation table * 5. Enable data cache, instruction cache and MMU * 6. Enable Floating point unit * 7. Transfer control to _start which clears BSS sections, initializes * global timer and runs global constructor before jumping to main * application * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 1.00a ecm/sdm 10/20/09 Initial version * 3.06a sgd 05/15/12 Updated L2CC Auxiliary and Tag RAM Latency control * register settings. * 3.06a asa 06/17/12 Modified the TTBR settings and L2 Cache auxiliary * register settings. * 3.07a asa 07/16/12 Modified the L2 Cache controller settings to improve * performance. Changed the property of the ".boot" * section. * 3.07a sgd 08/21/12 Modified the L2 Cache controller and cp15 Aux Control * Register settings * 3.09a sgd 02/06/13 Updated SLCR l2c Ram Control register to a * value of 0x00020202. Fix for CR 697094 (SI#687034). * 3.10a srt 04/18/13 Implemented ARM Erratas. Please refer to file * 'xil_errata.h' for errata description * 4.2 pkp 06/19/14 Enabled asynchronous abort exception * 5.0 pkp 16/15/14 Modified initialization code to enable scu after * MMU is enabled * 5.1 pkp 05/13/15 Changed the initialization order so to first invalidate * caches and TLB, enable MMU and caches, then enable SMP * bit in ACTLR. L2Cache invalidation and enabling of L2Cache * is done later. * 5.4 asa 12/6/15 Added code to initialize SPSR for all relevant modes. * 6.0 mus 08/04/16 Added code to detect zynq-7000 base silicon configuration and * attempt to enable dual core behavior on single cpu zynq-7000s * devices is prevented from corrupting system behavior. * 6.0 mus 08/24/16 Check CPU core before putting cpu1 to reset for single core * zynq-7000s devices * 7.6 mus 09/02/21 SCU invalidation should be done only from primary CPU, so * skipping it when USE_AMP is set to 1. It fixes CR#1109723 * 7.7 asa 01/06/22 Removed Cortex-A9 errata handling for errata * 742230 and 743622. These do not apply to * Cortex-A9 revision r3p0 being used in Zynq * platforms. * * </pre> * * @note * * None. * *****************************************************************************/ #include "xparameters.h" #include "xil_errata.h" .globl MMUTable .global _prestart .global _boot .global __stack .global __irq_stack .global __supervisor_stack .global __abort_stack .global __fiq_stack .global __undef_stack .global _vector_table .set PSS_L2CC_BASE_ADDR, 0xF8F02000 .set PSS_SLCR_BASE_ADDR, 0xF8000000 .set RESERVED, 0x0fffff00 .set TblBase , MMUTable .set LRemap, 0xFE00000F / set the base address of the peripheral block as not shared / .set L2CCWay, (PSS_L2CC_BASE_ADDR + 0x077C) /(PSS_L2CC_BASE_ADDR + PSS_L2CC_CACHE_INVLD_WAY_OFFSET)/ .set L2CCSync, (PSS_L2CC_BASE_ADDR + 0x0730) /(PSS_L2CC_BASE_ADDR + PSS_L2CC_CACHE_SYNC_OFFSET)/ .set L2CCCrtl, (PSS_L2CC_BASE_ADDR + 0x0100) /(PSS_L2CC_BASE_ADDR + PSS_L2CC_CNTRL_OFFSET)/ .set L2CCAuxCrtl, (PSS_L2CC_BASE_ADDR + 0x0104) /(PSS_L2CC_BASE_ADDR + XPSS_L2CC_AUX_CNTRL_OFFSET)/ .set L2CCTAGLatReg, (PSS_L2CC_BASE_ADDR + 0x0108) /(PSS_L2CC_BASE_ADDR + XPSS_L2CC_TAG_RAM_CNTRL_OFFSET)/ .set L2CCDataLatReg, (PSS_L2CC_BASE_ADDR + 0x010C) /(PSS_L2CC_BASE_ADDR + XPSS_L2CC_DATA_RAM_CNTRL_OFFSET)/ .set L2CCIntClear, (PSS_L2CC_BASE_ADDR + 0x0220) /(PSS_L2CC_BASE_ADDR + XPSS_L2CC_IAR_OFFSET)/ .set L2CCIntRaw, (PSS_L2CC_BASE_ADDR + 0x021C) /(PSS_L2CC_BASE_ADDR + XPSS_L2CC_ISR_OFFSET)/ .set SLCRlockReg, (PSS_SLCR_BASE_ADDR + 0x04) /(PSS_SLCR_BASE_ADDR + XPSS_SLCR_LOCK_OFFSET)/ .set SLCRUnlockReg, (PSS_SLCR_BASE_ADDR + 0x08) /(PSS_SLCR_BASE_ADDR + XPSS_SLCR_UNLOCK_OFFSET)/ .set SLCRL2cRamReg, (PSS_SLCR_BASE_ADDR + 0xA1C) /(PSS_SLCR_BASE_ADDR + XPSS_SLCR_L2C_RAM_OFFSET)/ .set SLCRCPURSTReg, (0xF8000000 + 0x244) /(XPS_SYS_CTRL_BASEADDR + A9_CPU_RST_CTRL_OFFSET)/ .set EFUSEStaus, (0xF800D000 + 0x10) /(XPS_EFUSE_BASEADDR + EFUSE_STATUS_OFFSET)/ / workaround for simulation not working when L1 D and I caches,MMU and L2 cache enabled - DT568997 / .if SIM_MODE == 1 .set CRValMmuCac, 0b00000000000000 / Disable IDC, and MMU / .else .set CRValMmuCac, 0b01000000000101 / Enable IDC, and MMU / .endif .set CRValHiVectorAddr, 0b10000000000000 / Set the Vector address to high, 0xFFFF0000 / .set L2CCAuxControl, 0x72360000 / Enable all prefetching, Cache replacement policy, Parity enable, Event monitor bus enable and Way Size (64 KB) / .set L2CCControl, 0x01 / Enable L2CC / .set L2CCTAGLatency, 0x0111 / latency for TAG RAM / .set L2CCDataLatency, 0x0121 / latency for DATA RAM / .set SLCRlockKey, 0x767B / SLCR lock key / .set SLCRUnlockKey, 0xDF0D / SLCR unlock key / .set SLCRL2cRamConfig, 0x00020202 / SLCR L2C ram configuration / / Stack Pointer locations for boot code / .set Undef_stack, __undef_stack .set FIQ_stack, __fiq_stack .set Abort_stack, __abort_stack .set SPV_stack, __supervisor_stack .set IRQ_stack, __irq_stack .set SYS_stack, __stack .set vector_base, _vector_table .set FPEXC_EN, 0x40000000 / FPU enable bit, (1 << 30) / .section .boot,"ax" / this initializes the various processor modes / _prestart: _boot: #if XPAR_CPU_ID==0 / only allow cpu0 through / mrc p15,0,r1,c0,c0,5 and r1, r1, #0xf cmp r1, #0 beq CheckEFUSE EndlessLoop0: wfe b EndlessLoop0 CheckEFUSE: ldr r0,=EFUSEStaus ldr r1,[r0] / Read eFuse setting / ands r1,r1,#0x80 / Check whether device is having single core / beq OKToRun / single core device, reset cpu1 / ldr r0,=SLCRUnlockReg / Load SLCR base address base + unlock register / ldr r1,=SLCRUnlockKey / set unlock key / str r1, [r0] / Unlock SLCR / ldr r0,=SLCRCPURSTReg ldr r1,[r0] / Read CPU Software Reset Control register / orr r1,r1,#0x22 str r1,[r0] / Reset CPU1 / ldr r0,=SLCRlockReg / Load SLCR base address base + lock register / ldr r1,=SLCRlockKey / set lock key / str r1, [r0] / lock SLCR / #elif XPAR_CPU_ID==1 / only allow cpu1 through / mrc p15,0,r1,c0,c0,5 and r1, r1, #0xf cmp r1, #1 beq CheckEFUSE1 b EndlessLoop1 CheckEFUSE1: ldr r0,=EFUSEStaus ldr r1,[r0] / Read eFuse setting / ands r1,r1,#0x80 / Check whether device is having single core / beq OKToRun EndlessLoop1: wfe b EndlessLoop1 #endif OKToRun: mrc p15, 0, r0, c0, c0, 0 / Get the revision / and r5, r0, #0x00f00000 and r6, r0, #0x0000000f orr r6, r6, r5, lsr #20-4 / set VBAR to the _vector_table address in linker script / ldr r0, =vector_base mcr p15, 0, r0, c12, c0, 0 /invalidate scu/ #if USE_AMP!=1 ldr r7, =0xf8f0000c ldr r6, =0xffff str r6, [r7] #endif / Invalidate caches and TLBs / mov r0,#0 / r0 = 0 / mcr p15, 0, r0, c8, c7, 0 / invalidate TLBs / mcr p15, 0, r0, c7, c5, 0 / invalidate icache / mcr p15, 0, r0, c7, c5, 6 / Invalidate branch predictor array / bl invalidate_dcache / invalidate dcache / / Disable MMU, if enabled / mrc p15, 0, r0, c1, c0, 0 / read CP15 register 1 / bic r0, r0, #0x1 / clear bit 0 / mcr p15, 0, r0, c1, c0, 0 / write value back / #ifdef SHAREABLE_DDR / Mark the entire DDR memory as shareable / ldr r3, =0x3ff / 1024 entries to cover 1G DDR / ldr r0, =TblBase / MMU Table address in memory / ldr r2, =0x15de6 / S=b1 TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 / shareable_loop: str r2, [r0] / write the entry to MMU table / add r0, r0, #0x4 / next entry in the table / add r2, r2, #0x100000 / next section / subs r3, r3, #1 bge shareable_loop / loop till 1G is covered / #endif mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the irq stack pointer / and r2, r1, r0 orr r2, r2, #0x12 / IRQ mode / msr cpsr, r2 ldr r13,=IRQ_stack / IRQ stack pointer / bic r2, r2, #(0x1 << 9) / Set EE bit to little-endian / msr spsr_fsxc,r2 mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the supervisor stack pointer / and r2, r1, r0 orr r2, r2, #0x13 / supervisor mode / msr cpsr, r2 ldr r13,=SPV_stack / Supervisor stack pointer / bic r2, r2, #(0x1 << 9) / Set EE bit to little-endian / msr spsr_fsxc,r2 mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the Abort stack pointer / and r2, r1, r0 orr r2, r2, #0x17 / Abort mode / msr cpsr, r2 ldr r13,=Abort_stack / Abort stack pointer / bic r2, r2, #(0x1 << 9) / Set EE bit to little-endian / msr spsr_fsxc,r2 mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the FIQ stack pointer / and r2, r1, r0 orr r2, r2, #0x11 / FIQ mode / msr cpsr, r2 ldr r13,=FIQ_stack / FIQ stack pointer / bic r2, r2, #(0x1 << 9) / Set EE bit to little-endian / msr spsr_fsxc,r2 mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the Undefine stack pointer / and r2, r1, r0 orr r2, r2, #0x1b / Undefine mode / msr cpsr, r2 ldr r13,=Undef_stack / Undefine stack pointer / bic r2, r2, #(0x1 << 9) / Set EE bit to little-endian / msr spsr_fsxc,r2 mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the system stack pointer / and r2, r1, r0 orr r2, r2, #0x1F / SYS mode / msr cpsr, r2 ldr r13,=SYS_stack / SYS stack pointer / /set scu enable bit in scu/ ldr r7, =0xf8f00000 ldr r0, [r7] orr r0, r0, #0x1 str r0, [r7] / enable MMU and cache / ldr r0,=TblBase / Load MMU translation table base / orr r0, r0, #0x5B / Outer-cacheable, WB / mcr 15, 0, r0, c2, c0, 0 / TTB0 / mvn r0,#0 / Load MMU domains -- all ones=manager / mcr p15,0,r0,c3,c0,0 / Enable mmu, icahce and dcache / ldr r0,=CRValMmuCac mcr p15,0,r0,c1,c0,0 / Enable cache and MMU / dsb / dsb allow the MMU to start up / isb / isb flush prefetch buffer / / Write to ACTLR / mrc p15, 0, r0, c1, c0, 1 / Read ACTLR/ orr r0, r0, #(0x01 << 6) / set SMP bit / orr r0, r0, #(0x01 ) / Cache/TLB maintenance broadcast / mcr p15, 0, r0, c1, c0, 1 / Write ACTLR/ / Invalidate L2 Cache and enable L2 Cache/ / For AMP, assume running on CPU1. Don't initialize L2 Cache (up to Linux) / #if USE_AMP!=1 ldr r0,=L2CCCrtl / Load L2CC base address base + control register / mov r1, #0 / force the disable bit / str r1, [r0] / disable the L2 Caches / ldr r0,=L2CCAuxCrtl / Load L2CC base address base + Aux control register / ldr r1,[r0] / read the register / ldr r2,=L2CCAuxControl / set the default bits / orr r1,r1,r2 str r1, [r0] / store the Aux Control Register / ldr r0,=L2CCTAGLatReg / Load L2CC base address base + TAG Latency address / ldr r1,=L2CCTAGLatency / set the latencies for the TAG/ str r1, [r0] / store the TAG Latency register Register / ldr r0,=L2CCDataLatReg / Load L2CC base address base + Data Latency address / ldr r1,=L2CCDataLatency / set the latencies for the Data/ str r1, [r0] / store the Data Latency register Register / ldr r0,=L2CCWay / Load L2CC base address base + way register/ ldr r2, =0xFFFF str r2, [r0] / force invalidate / ldr r0,=L2CCSync / need to poll 0x730, PSS_L2CC_CACHE_SYNC_OFFSET / / Load L2CC base address base + sync register/ / poll for completion / Sync: ldr r1, [r0] cmp r1, #0 bne Sync ldr r0,=L2CCIntRaw / clear pending interrupts / ldr r1,[r0] ldr r0,=L2CCIntClear str r1,[r0] ldr r0,=SLCRUnlockReg / Load SLCR base address base + unlock register / ldr r1,=SLCRUnlockKey / set unlock key / str r1, [r0] / Unlock SLCR / ldr r0,=SLCRL2cRamReg / Load SLCR base address base + l2c Ram Control register / ldr r1,=SLCRL2cRamConfig / set the configuration value / str r1, [r0] / store the L2c Ram Control Register / ldr r0,=SLCRlockReg / Load SLCR base address base + lock register / ldr r1,=SLCRlockKey / set lock key / str r1, [r0] / lock SLCR / ldr r0,=L2CCCrtl / Load L2CC base address base + control register / ldr r1,[r0] / read the register / mov r2, #L2CCControl / set the enable bit / orr r1,r1,r2 str r1, [r0] / enable the L2 Caches / #endif mov r0, r0 mrc p15, 0, r1, c1, c0, 2 / read cp access control register (CACR) into r1 / orr r1, r1, #(0xf << 20) / enable full access for p10 & p11 / mcr p15, 0, r1, c1, c0, 2 / write back into CACR / / enable vfp / fmrx r1, FPEXC / read the exception register / orr r1,r1, #FPEXC_EN / set VFP enable bit, leave the others in orig state / fmxr FPEXC, r1 / write back the exception register / mrc p15,0,r0,c1,c0,0 / flow prediction enable / orr r0, r0, #(0x01 << 11) / #0x8000 / mcr p15,0,r0,c1,c0,0 mrc p15,0,r0,c1,c0,1 / read Auxiliary Control Register / orr r0, r0, #(0x1 << 2) / enable Dside prefetch / orr r0, r0, #(0x1 << 1) / enable L2 Prefetch hint / mcr p15,0,r0,c1,c0,1 / write Auxiliary Control Register / mrs r0, cpsr / get the current PSR / bic r0, r0, #0x100 / enable asynchronous abort exception / msr cpsr_xsf, r0 b _start / jump to C startup code / and r0, r0, r0 / no op / .Ldone: b .Ldone / Paranoia: we should never get here / / ************************************************************************* * * invalidate_dcache - invalidate the entire d-cache by set/way * * Note: for Cortex-A9, there is no cp instruction for invalidating * the whole D-cache. Need to invalidate each line. * ************************************************************************* / invalidate_dcache: mrc p15, 1, r0, c0, c0, 1 / read CLIDR / ands r3, r0, #0x7000000 mov r3, r3, lsr #23 / cache level value (naturally aligned) / beq finished mov r10, #0 / start with level 0 / loop1: add r2, r10, r10, lsr #1 / work out 3xcachelevel / mov r1, r0, lsr r2 / bottom 3 bits are the Cache type for this level / and r1, r1, #7 / get those 3 bits alone / cmp r1, #2 blt skip / no cache or only instruction cache at this level / mcr p15, 2, r10, c0, c0, 0 / write the Cache Size selection register / isb / isb to sync the change to the CacheSizeID reg / mrc p15, 1, r1, c0, c0, 0 / reads current Cache Size ID register / and r2, r1, #7 / extract the line length field / add r2, r2, #4 / add 4 for the line length offset (log2 16 bytes) / ldr r4, =0x3ff ands r4, r4, r1, lsr #3 / r4 is the max number on the way size (right aligned) / clz r5, r4 / r5 is the bit position of the way size increment / ldr r7, =0x7fff ands r7, r7, r1, lsr #13 / r7 is the max number of the index size (right aligned) / loop2: mov r9, r4 / r9 working copy of the max way size (right aligned) / loop3: orr r11, r10, r9, lsl r5 / factor in the way number and cache number into r11 / orr r11, r11, r7, lsl r2 / factor in the index number / mcr p15, 0, r11, c7, c6, 2 / invalidate by set/way / subs r9, r9, #1 / decrement the way number / bge loop3 subs r7, r7, #1 / decrement the index / bge loop2 skip: add r10, r10, #2 / increment the cache number / cmp r3, r10 bgt loop1 finished: mov r10, #0 / switch back to cache level 0 / mcr p15, 2, r10, c0, c0, 0 / select current cache level in cssr / dsb isb bx lr .end /* * @} End of "addtogroup a9_boot_code". */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,555	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/gcc/cpu_init.S	/****************************************************************************** * Copyright (c) 2009 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file cpu_init.S * * This file contains CPU specific initialization. Invoked from main CRT * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 1.00a ecm/sdm 10/20/09 Initial version * 3.04a sdm 01/02/12 Updated to clear cp15 regs with unknown reset values * 5.0 pkp 12/16/14 removed incorrect initialization of TLB lockdown * register to fix CR#830580 * </pre> * * @note * * None. * *****************************************************************************/ .text .global __cpu_init .align 2 __cpu_init: / Clear cp15 regs with unknown reset values / mov r0, #0x0 mcr p15, 0, r0, c5, c0, 0 / DFSR / mcr p15, 0, r0, c5, c0, 1 / IFSR / mcr p15, 0, r0, c6, c0, 0 / DFAR / mcr p15, 0, r0, c6, c0, 2 / IFAR / mcr p15, 0, r0, c9, c13, 2 / PMXEVCNTR / mcr p15, 0, r0, c13, c0, 2 / TPIDRURW / mcr p15, 0, r0, c13, c0, 3 / TPIDRURO / / Reset and start Cycle Counter / mov r2, #0x80000000 / clear overflow / mcr p15, 0, r2, c9, c12, 3 mov r2, #0xd / D, C, E / mcr p15, 0, r2, c9, c12, 0 mov r2, #0x80000000 / enable cycle counter */ mcr p15, 0, r2, c9, c12, 1 bx lr .end
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	8,976	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/iccarm/boot.s	;**************************************************************************** ; Copyright (c) 2014 - 2020 Xilinx, Inc. All rights reserved. ; SPDX-License-Identifier: MIT ; *************************************************************************/ ; ************************************************************************/ ; ; @file boot.S ; ; This file contains the initial startup code for the Cortex R5 processor ; ; <pre> ; MODIFICATION HISTORY: ; ; Ver Who Date Changes ; ----- ---- -------- --------------------------------------------------- ; 5.00 mus 01/27/17 Initial version ; 6.6 srm 10/18/17 Updated the timer configuration with XTime_StartTTCTimer. ; Now the timer instance as specified by the user will be ; started. ; 6.6 mus 02/23/17 Disable the debug logic in non-JTAG boot mode(when ; processor is in lockstep configuration), based ; on the mld parameter "lockstep_mode_debug". * 6.8 mus 09/20/18 Clear VINITHI field in RPU_0_CFG/RPU_1_CFG * registers to initialize CortexR5 core with LOVEC * on reset. It fixes CR#1010656. * 7.0 mus 03/19/19 Disable FPU only in case of softp, otherwise enable it by * default. CR#1021638 ; ; </pre> ; ; @note ; ; None. ; ; ****************************************************************************/ MODULE ?boot ;; Forward declaration of sections. SECTION IRQ_STACK:DATA:NOROOT(3) SECTION FIQ_STACK:DATA:NOROOT(3) SECTION SVC_STACK:DATA:NOROOT(3) SECTION ABT_STACK:DATA:NOROOT(3) SECTION UND_STACK:DATA:NOROOT(3) SECTION CSTACK:DATA:NOROOT(3) #include "xparameters.h" #define UART_BAUDRATE 115200 PUBLIC _prestart PUBLIC __iar_program_start IMPORT _vector_table IMPORT Init_MPU #ifdef SLEEP_TIMER_BASEADDR IMPORT XTime_StartTTCTimer #endif IMPORT __cmain vector_base EQU _vector_table RPU_GLBL_CNTL EQU 0xFF9A0000 RPU_ERR_INJ EQU 0xFF9A0020 RPU_0_CFG EQU 0xFF9A0100 RPU_1_CFG EQU 0xFF9A0200 RST_LPD_DBG EQU 0xFF5E0240 BOOT_MODE_USER EQU 0xFF5E0200 fault_log_enable EQU 0x101 SECTION .boot:CODE:NOROOT(2) / this initializes the various processor modes / _prestart __iar_program_start OKToRun REQUIRE _vector_table / Initialize processor registers to 0 / mov r0,#0 mov r1,#0 mov r2,#0 mov r3,#0 mov r4,#0 mov r5,#0 mov r6,#0 mov r7,#0 mov r8,#0 mov r9,#0 mov r10,#0 mov r11,#0 mov r12,#0 / Initialize stack pointer and banked registers for various mode / mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the irq stack pointer and r2, r1, r0 orr r2, r2, #0x12 ; IRQ mode msr cpsr, r2 ldr r13,=SFE(IRQ_STACK) ; IRQ stack pointer mov r14,#0 mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the supervisor stack pointer and r2, r1, r0 orr r2, r2, #0x13 ; supervisor mode msr cpsr, r2 ldr r13,=SFE(SVC_STACK) ; Supervisor stack pointer mov r14,#0 mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the Abort stack pointer and r2, r1, r0 orr r2, r2, #0x17 ; Abort mode msr cpsr, r2 ldr r13,=SFE(ABT_STACK) ; Abort stack pointer mov r14,#0 mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the FIQ stack pointer and r2, r1, r0 orr r2, r2, #0x11 ; FIQ mode msr cpsr, r2 mov r8, #0 mov r9, #0 mov r10, #0 mov r11, #0 mov r12, #0 ldr r13,=SFE(FIQ_STACK) ; FIQ stack pointer mov r14,#0 mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the Undefine stack pointer and r2, r1, r0 orr r2, r2, #0x1b ; Undefine mode msr cpsr, r2 ldr r13,=SFE(UND_STACK) ; Undefine stack pointer mov r14,#0 mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the system stack pointer and r2, r1, r0 orr r2, r2, #0x1F ; SYS mode msr cpsr, r2 ldr r13,=SFE(CSTACK) ; SYS stack pointer mov r14,#0 ; ; Enable access to VFP by enabling access to Coprocessors 10 and 11. ; Enables Full Access i.e. in both privileged and non privileged modes ; mrc p15, 0, r0, c1, c0, 2 ; Read Coprocessor Access Control Register (CPACR) orr r0, r0, #(0xF << 20) ; Enable access to CP 10 & 11 mcr p15, 0, r0, c1, c0, 2 ; Write Coprocessor Access Control Register (CPACR) isb ; enable fpu access vmrs r3, FPEXC orr r1, r3, #(1<<30) vmsr FPEXC, r1 ; clear the floating point register mov r1,#0 vmov d0,r1,r1 vmov d1,r1,r1 vmov d2,r1,r1 vmov d3,r1,r1 vmov d4,r1,r1 vmov d5,r1,r1 vmov d6,r1,r1 vmov d7,r1,r1 vmov d8,r1,r1 vmov d9,r1,r1 vmov d10,r1,r1 vmov d11,r1,r1 vmov d12,r1,r1 vmov d13,r1,r1 vmov d14,r1,r1 vmov d15,r1,r1 #ifdef __SOFTFP__ ; Disable FPU by restoring previous value for FPU access vmsr FPEXC,r3 #endif ; Disable MPU and caches mrc p15, 0, r0, c1, c0, 0 ; Read CP15 Control Register bic r0, r0, #0x05 ; Disable MPU (M bit) and data cache (C bit) bic r0, r0, #0x1000 ; Disable instruction cache (I bit) dsb ; Ensure all previous loads/stores have completed mcr p15, 0, r0, c1, c0, 0 ; Write CP15 Control Register isb ; Ensure subsequent insts execute wrt new MPU settings ; Disable Branch prediction, TCM ECC checks mrc p15, 0, r0, c1, c0, 1 ; Read ACTLR orr r0, r0, #(0x1 << 17) ; Enable RSDIS bit 17 to disable the return stack orr r0, r0, #(0x1 << 16) ; Clear BP bit 15 and set BP bit 16 bic r0, r0, #(0x1 << 15) ; Branch always not taken and history table updates disabled bic r0, r0, #(0x1 << 27) ; Disable B1TCM ECC check bic r0, r0, #(0x1 << 26) ; Disable B0TCM ECC check bic r0, r0, #(0x1 << 25) ; Disable ATCM ECC check orr r0, r0, #(0x1 << 5) ; Enable ECC with no forced write through with [5:3]=b'101 bic r0, r0, #(0x1 << 4) orr r0, r0, #(0x1 << 3) mcr p15, 0, r0, c1, c0, 1 ; Write ACTLR/ dsb ; Complete all outstanding explicit memory operations*/ ; Invalidate caches mov r0,#0 ; r0 = 0 dsb mcr p15, 0, r0, c7, c5, 0 ; invalidate icache mcr p15, 0, r0, c15, c5, 0 ; Invalidate entire data cache isb #if LOCKSTEP_MODE_DEBUG == 0 ; enable fault log for lock step ldr r0,=RPU_GLBL_CNTL ldr r1, [r0] ands r1, r1, #0x8 ; branch to initialization if split mode bne init ; check for boot mode if in lock step, branch to init if JTAG boot mode ldr r0,=BOOT_MODE_USER ldr r1, [r0] ands r1, r1, #0xF beq init ; reset the debug logic ldr r0,=RST_LPD_DBG ldr r1, [r0] orr r1, r1, #(0x1 << 1) orr r1, r1, #(0x1 << 4) orr r1, r1, #(0x1 << 5) str r1, [r0] ; enable fault log ldr r0,=RPU_ERR_INJ ldr r1,=fault_log_enable ldr r2, [r0] orr r2, r2, r1 str r2, [r0] nop nop #endif init bl Init_MPU ; Initialize MPU ; Enable Branch prediction mrc p15, 0, r0, c1, c0, 1 ; Read ACTLR bic r0, r0, #(0x1 << 17) ; Clear RSDIS bit 17 to enable return stack bic r0, r0, #(0x1 << 16) ; Clear BP bit 15 and BP bit 16: bic r0, r0, #(0x1 << 15) ; Normal operation, BP is taken from the global history table. orr r0, r0, #(0x1 << 14) ; Disable DBWR for errata 780125 mcr p15, 0, r0, c1, c0, 1 ; Write ACTLR ; Enable icahce and dcache mrc p15,0,r1,c1,c0,0 ldr r0, =0x1005 orr r1,r1,r0 dsb mcr p15,0,r1,c1,c0,0 ; Enable cache isb ; isb flush prefetch buffer ; Set vector table in TCM/LOVEC #ifndef VEC_TABLE_IN_OCM mrc p15, 0, r0, c1, c0, 0 mvn r1, #0x2000 and r0, r0, r1 mcr p15, 0, r0, c1, c0, 0 ; Clear VINITHI to enable LOVEC on reset #if XPAR_CPU_ID == 0 ldr r0, =RPU_0_CFG #else ldr r0, =RPU_1_CFG #endif ldr r1, [r0] bic r1, r1, #(0x1 << 2) str r1, [r0] #endif ; enable asynchronous abort exception mrs r0, cpsr bic r0, r0, #0x100 msr cpsr_xsf, r0 ; Clear cp15 regs with unknown reset values mov r0, #0x0 mcr p15, 0, r0, c5, c0, 0 ; DFSR mcr p15, 0, r0, c5, c0, 1 ; IFSR mcr p15, 0, r0, c6, c0, 0 ; DFAR mcr p15, 0, r0, c6, c0, 2 ; IFAR mcr p15, 0, r0, c9, c13, 2 ; PMXEVCNTR mcr p15, 0, r0, c13, c0, 2 ; TPIDRURW mcr p15, 0, r0, c13, c0, 3 ; TPIDRURO ; Reset and start Cycle Counter mov r2, #0x80000000 ; clear overflow mcr p15, 0, r2, c9, c12, 3 mov r2, #0xd ; D, C, E mcr p15, 0, r2, c9, c12, 0 mov r2, #0x80000000 ; enable cycle counter mcr p15, 0, r2, c9, c12, 1 ; configure the timer if TTC is present #ifdef SLEEP_TIMER_BASEADDR bl XTime_StartTTCTimer #endif ; make sure argc and argv are valid mov r0, #0 mov r1, #0 b __cmain ; jump to C startup code Ldone b Ldone ; Paranoia: we should never get here END
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	4,131	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/iccarm/asm_vectors.s	;**************************************************************************** ; Copyright (c) 2017 - 2020 Xilinx, Inc. All rights reserved. ; SPDX-License-Identifier: MIT ;*************************************************************************/ ;*************************************************************************/ ; ; @file asm_vectors.s ; ; This file contains the initial vector table for the Cortex R5 processor ; ; <pre> ; MODIFICATION HISTORY: ; ; Ver Who Date Changes ; ----- ------- -------- --------------------------------------------------- ; 6.2 mus 01/27/17 Initial version ; </pre> ; ; @note ; ; None. ; ;****************************************************************************/ MODULE ?asm_vectors ;; Forward declaration of sections. SECTION IRQ_STACK:DATA:NOROOT(3) SECTION FIQ_STACK:DATA:NOROOT(3) SECTION SVC_STACK:DATA:NOROOT(3) SECTION ABT_STACK:DATA:NOROOT(3) SECTION UND_STACK:DATA:NOROOT(3) SECTION CSTACK:DATA:NOROOT(3) #define UART_BAUDRATE 115200 IMPORT _prestart IMPORT __iar_program_start SECTION .intvec:CODE:NOROOT(2) PUBLIC _vector_table IMPORT FIQInterrupt IMPORT IRQInterrupt IMPORT SWInterrupt IMPORT DataAbortInterrupt IMPORT PrefetchAbortInterrupt IMPORT UndefinedException IMPORT UndefinedExceptionAddr IMPORT PrefetchAbortAddr IMPORT DataAbortAddr IMPORT prof_pc _vector_table ARM ldr pc,=__iar_program_start ldr pc,=Undefined ldr pc,=SVCHandler ldr pc,=PrefetchAbortHandler ldr pc,=DataAbortHandler NOP ; Placeholder for address exception vector ldr pc,=IRQHandler ldr pc,=FIQHandler SECTION .text:CODE:NOROOT(2) REQUIRE _vector_table ARM IRQHandler ; IRQ vector handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code #ifndef __SOFTFP__ vpush {d0-d7} / Store floating point registers / vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} #endif bl IRQInterrupt ; IRQ vector #ifndef __SOFTFP__ pop {r1} / Restore floating point registers / vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d0-d7} #endif ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #4 ; adjust return FIQHandler ; FIQ vector handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code FIQLoop bl FIQInterrupt ; FIQ vector ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #4 ; adjust return Undefined ; Undefined handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldr r0, =UndefinedExceptionAddr sub r1, lr, #4 str r1, [r0] ; Store address of instruction causing undefined exception bl UndefinedException ; UndefinedException: call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code movs pc, lr SVCHandler ; SWI handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code tst r0, #0x20 ; check the T bit ldrneh r0, [lr,#-2] ; Thumb mode bicne r0, r0, #0xff00 ; Thumb mode ldreq r0, [lr,#-4] ; ARM mode biceq r0, r0, #0xff000000 ; ARM mode bl SWInterrupt ; SWInterrupt: call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code movs pc, lr ; adjust return DataAbortHandler ; Data Abort handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldr r0, =DataAbortAddr sub r1, lr, #8 str r1, [r0] ; Stores instruction causing data abort bl DataAbortInterrupt ;DataAbortInterrupt :call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #8 ; adjust return PrefetchAbortHandler ; Prefetch Abort handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldr r0, =PrefetchAbortAddr sub r1, lr, #4 str r1, [r0] ; Stores instruction causing prefetch abort / bl PrefetchAbortInterrupt ; PrefetchAbortInterrupt: call C function here / ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code / subs pc, lr, #4 ; adjust return */ END
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,403	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/armclang/xil-crt0.S	;/****************************************************************************** ;* Copyright (c) 2020 Xilinx, Inc. All rights reserved. ;* SPDX-License-Identifier: MIT ;****************************************************************************/ ;/*************************************************************************/ ;/ ;* @file xil-crt0.S ;* ;* <pre> ;* MODIFICATION HISTORY: ;* ;* Ver Who Date Changes ;* ----- ---- -------- --------------------------------------------------- ;* 7.3 dp 06/25/20 Initial version for armclang ;* </pre> ;* ;* @note ;* ;* None. ;* ;*****************************************************************************/ #include "xparameters.h" #include "bspconfig.h" IMPORT \|Image$$BSS_SECTION$$Base\| IMPORT Xil_InitializeExistingMPURegConfig EXPORT _startup IMPORT __cpu_init IMPORT __main #ifdef SLEEP_TIMER_BASEADDR IMPORT XTime_StartTTCTimer #endif AREA \|.text\|, CODE REQUIRE8 {TRUE} PRESERVE8 {TRUE} ENTRY _startup bl __cpu_init ;Initialize the CPU first (BSP provides this) ;configure the timer if TTC is present #ifdef SLEEP_TIMER_BASEADDR bl XTime_StartTTCTimer #endif bl Xil_InitializeExistingMPURegConfig ;/ Initialize MPU config */ ;make sure argc and argv are valid mov r0, #0 mov r1, #0 #ifdef XCLOCKING bl Xil_ClockInit #endif bl __main ;Jump to main C code bl exit exit ;should never get here b exit END
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	3,689	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/armclang/asm_vectors.S	;/****************************************************************************** ;* Copyright (c) 2020 - 2021 Xilinx, Inc. All rights reserved. ;* ;* SPDX-License-Identifier: MIT ;* ;****************************************************************************/ ;/*************************************************************************/ ;/ ;* @file asm_vectors.S ;* ;* This file contains the initial vector table for the Cortex R5 processor ;* as per armclang compiler ;* ;* <pre> ;* MODIFICATION HISTORY: ;* ;* Ver Who Date Changes ;* ----- ------- -------- --------------------------------------------------- ;* 7.3 dp 06/25/20 Initial version for armclang ;* </pre> ;* ;* @note ;* ;* None. ;* ;******************************************************************************/ EXPORT _vector_table IMPORT _boot IMPORT FIQInterrupt IMPORT IRQInterrupt IMPORT SWInterrupt IMPORT DataAbortInterrupt IMPORT PrefetchAbortInterrupt IMPORT UndefinedExceptionAddr IMPORT UndefinedException IMPORT DataAbortAddr IMPORT PrefetchAbortAddr EXPORT IRQHandler AREA \|vectors\|, CODE REQUIRE8 {TRUE} PRESERVE8 {TRUE} ENTRY ; Define this an entry point _vector_table ldr pc, =_boot ldr pc, =Undefined ldr pc, =SVCHandler ldr pc, =PrefetchAbortHandler ldr pc, =DataAbortHandler NOP ;Placeholder for address exception vector ldr pc, =IRQHandler ldr pc, =FIQHandler IRQHandler ;IRQ vector handler stmdb sp!,{r0-r3,r12,lr} ;state save from compiled code #ifndef __SOFTFP__ vpush {d0-d7} ;Store floating point registers/ vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} #endif bl IRQInterrupt ;IRQ vector #ifndef __SOFTFP__ pop {r1} ;Restore floating point registers vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d0-d7} #endif ldmia sp!,{r0-r3,r12,lr} ;state restore from compiled code subs pc, lr, #4 ;adjust return FIQHandler ;FIQ vector handler stmdb sp!,{r0-r3,r12,lr} ;state save from compiled code FIQLoop bl FIQInterrupt ;FIQ vector ldmia sp!,{r0-r3,r12,lr} ;state restore from compiled code subs pc, lr, #4 ;adjust return Undefined ;Undefined handler stmdb sp!,{r0-r3,r12,lr} ;state save from compiled code ldr r0, =UndefinedExceptionAddr sub r1, lr, #4 str r1, [r0] ;Store address of instruction causing undefined exception bl UndefinedException ;UndefinedException: call C function here ldmia sp!,{r0-r3,r12,lr} ;state restore from compiled code movs pc, lr SVCHandler ;SWI handler stmdb sp!,{r0-r3,r12,lr} ;state save from compiled code tst r0, #0x20 ;check the T bit ldrneh r0, [lr,#-2] ;Thumb mode bicne r0, r0, #0xff00 ;Thumb mode ldreq r0, [lr,#-4] ;ARM mode biceq r0, r0, #0xff000000 ;ARM mode bl SWInterrupt ;SWInterrupt: call C function here ldmia sp!,{r0-r3,r12,lr} ;state restore from compiled code movs pc, lr ;adjust return DataAbortHandler ;Data Abort handler stmdb sp!,{r0-r3,r12,lr} ;state save from compiled code ldr r0, =DataAbortAddr sub r1, lr, #8 str r1, [r0] ;Stores instruction causing data abort bl DataAbortInterrupt ;ataAbortInterrupt :call C function here ldmia sp!,{r0-r3,r12,lr} ;state restore from compiled code subs pc, lr, #8 ;adjust return PrefetchAbortHandler ;Prefetch Abort handler stmdb sp!,{r0-r3,r12,lr} ;state save from compiled code ldr r0, =PrefetchAbortAddr sub r1, lr, #4 str r1, [r0] ;Stores instruction causing prefetch abort bl PrefetchAbortInterrupt ;PrefetchAbortInterrupt: call C function here ldmia sp!,{r0-r3,r12,lr} ;state restore from compiled code subs pc, lr, #4 ;adjust return END
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	8,033	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/armclang/boot.S	;/****************************************************************************** ;* Copyright (c) 2020 Xilinx, Inc. All rights reserved. ;* SPDX-License-Identifier: MIT ;****************************************************************************/ ;/*************************************************************************/ ;/ ;* @file boot.S ;* ;* @addtogroup r5_boot_code Cortex R5 Processor Boot Code ;* @{ ;* <h2> boot.S </h2> ;* The boot code performs minimum configuration which is required for an ;* application to run starting from processor's reset state. Below is a ;* sequence illustrating what all configuration is performed before control ;* reaches to main function. ;* ;* 1. Program vector table base for exception handling ;* 2. Program stack pointer for various modes (IRQ, FIQ, supervisor, undefine, ;* abort, system) ;* 3. Disable instruction cache, data cache and MPU ;* 4. Invalidate instruction and data cache ;* 5. Configure MPU with short descriptor translation table format and program ;* base address of translation table ;* 6. Enable data cache, instruction cache and MPU ;* 7. Enable Floating point unit ;* 8. Transfer control to _start which clears BSS sections and jumping to main ;* application ;* ;* ;* <pre> ;* MODIFICATION HISTORY: ;* ;* Ver Who Date Changes ;* ----- ---- -------- --------------------------------------------------- ;* 7.3 dp 06/25/20 Initial version for armclang ;* </pre> ;* ;******************************************************************************/ #include "xparameters.h" EXPORT _prestart EXPORT _boot IMPORT \|Image$$ARM_LIB_STACK$$Base\| IMPORT \|Image$$ARM_IRQ_STACK$$Base\| IMPORT \|Image$$ARM_SV_STACK$$Base\| IMPORT \|Image$$ARM_ABORT_STACK$$Base\| IMPORT \|Image$$ARM_FIQ_STACK$$Base\| IMPORT \|Image$$ARM_UNDEF_STACK$$Base\| IMPORT Init_MPU IMPORT _startup RPU_GLBL_CNTL EQU 0xFF9A0000 RPU_ERR_INJ EQU 0xFF9A0020 RPU_0_CFG EQU 0xFF9A0100 RPU_1_CFG EQU 0xFF9A0200 #if defined(versal) RST_LPD_DBG EQU 0xFF5E0338 BOOT_MODE_USER EQU 0xF1260200 #else RST_LPD_DBG EQU 0xFF5E0240 BOOT_MODE_USER EQU 0xFF5E0200 #endif fault_log_enable EQU 0x101 ;0th bit of PROCESSOR_ACCESS_VALUE macro signifies trustzone ;setting for RPU address space #define RPU_TZ_MASK 0x1 AREA \|.boot\|, CODE REQUIRE8 {TRUE} PRESERVE8 {TRUE} ENTRY ;this initializes the various processor modes _prestart _boot OKToRun ;Initialize processor registers to 0 mov r0,#0 mov r1,#0 mov r2,#0 mov r3,#0 mov r4,#0 mov r5,#0 mov r6,#0 mov r7,#0 mov r8,#0 mov r9,#0 mov r10,#0 mov r11,#0 mov r12,#0 ;Initialize stack pointer and banked registers for various mode mrs r0, cpsr ;get the current PSR mvn r1, #0x1f ;set up the irq stack pointer and r2, r1, r0 orr r2, r2, #0x12 ;IRQ mode msr cpsr_cxsf, r2 ldr r13,=\|Image$$ARM_IRQ_STACK$$Base\| ;IRQ stack pointer mov r14,#0 mrs r0, cpsr ;get the current PSR mvn r1, #0x1f ;set up the supervisor stack pointer and r2, r1, r0 orr r2, r2, #0x13 ;supervisor mode msr cpsr_cxsf, r2 ldr r13,=\|Image$$ARM_SV_STACK$$Base\| ;Supervisor stack pointer mov r14,#0 mrs r0, cpsr ;get the current PSR mvn r1, #0x1f ;set up the Abort stack pointer and r2, r1, r0 orr r2, r2, #0x17 ;Abort mode msr cpsr_cxsf, r2 ldr r13,=\|Image$$ARM_ABORT_STACK$$Base\| ;Abort stack pointer mov r14,#0 mrs r0, cpsr ;get the current PSR mvn r1, #0x1f ;set up the FIQ stack pointer and r2, r1, r0 orr r2, r2, #0x11 ;FIQ mode msr cpsr_cxsf, r2 mov r8, #0 mov r9, #0 mov r10, #0 mov r11, #0 mov r12, #0 ldr r13,=\|Image$$ARM_FIQ_STACK$$Base\| ;FIQ stack pointer mov r14,#0 mrs r0, cpsr ;get the current PSR mvn r1, #0x1f ;set up the Undefine stack pointer and r2, r1, r0 orr r2, r2, #0x1b ;Undefine mode msr cpsr_cxsf, r2 ldr r13,=\|Image$$ARM_UNDEF_STACK$$Base\| ;Undefine stack pointer mov r14,#0 mrs r0, cpsr ;get the current PSR mvn r1, #0x1f ;set up the system stack pointer and r2, r1, r0 orr r2, r2, #0x1F ;SYS mode msr cpsr_cxsf, r2 ldr r13,=\|Image$$ARM_LIB_STACK$$Base\| ;SYS stack pointer mov r14,#0 ;Enable access to VFP by enabling access to Coprocessors 10 and 11. ;Enables Full Access i.e. in both privileged and non privileged modes mrc p15, 0, r0, c1, c0, 2 ;Read Coprocessor Access Control Register (CPACR) orr r0, r0, #(0xF << 20) ;Enable access to CP 10 & 11 mcr p15, 0, r0, c1, c0, 2 ;Write Coprocessor Access Control Register (CPACR) isb ;enable fpu access vmrs r3, FPEXC orr r1, r3, #(1<<30) vmsr FPEXC, r1 ;clear the floating point register mov r1,#0 vmov d0,r1,r1 vmov d1,r1,r1 vmov d2,r1,r1 vmov d3,r1,r1 vmov d4,r1,r1 vmov d5,r1,r1 vmov d6,r1,r1 vmov d7,r1,r1 vmov d8,r1,r1 vmov d9,r1,r1 vmov d10,r1,r1 vmov d11,r1,r1 vmov d12,r1,r1 vmov d13,r1,r1 vmov d14,r1,r1 vmov d15,r1,r1 #ifdef __SOFTFP__ ;Disable the FPU if SOFTFP is defined vmsr FPEXC,r3 #endif ;Disable MPU and caches mrc p15, 0, r0, c1, c0, 0 ;Read CP15 Control Register bic r0, r0, #0x05 ;Disable MPU (M bit) and data cache (C bit) bic r0, r0, #0x1000 ;Disable instruction cache (I bit) dsb ;Ensure all previous loads/stores have completed mcr p15, 0, r0, c1, c0, 0 ;Write CP15 Control Register isb ;Ensure subsequent insts execute wrt new MPU settings ;Disable Branch prediction, TCM ECC checks mrc p15, 0, r0, c1, c0, 1 ;Read ACTLR orr r0, r0, #(0x1 << 17) ;Enable RSDIS bit 17 to disable the return stack orr r0, r0, #(0x1 << 16) ;Clear BP bit 15 and set BP bit 16: bic r0, r0, #(0x1 << 15) ;Branch always not taken and history table updates disabled orr r0, r0, #(0x1 << 27) ;Enable B1TCM ECC check orr r0, r0, #(0x1 << 26) ;Enable B0TCM ECC check orr r0, r0, #(0x1 << 25) ;Enable ATCM ECC check bic r0, r0, #(0x1 << 5) ;Generate abort on parity errors, with [5:3]=b 000 bic r0, r0, #(0x1 << 4) bic r0, r0, #(0x1 << 3) mcr p15, 0, r0, c1, c0, 1 ;Write ACTLR dsb ;Complete all outstanding explicit memory operations ;Invalidate caches mov r0,#0 ;r0 = 0 dsb mcr p15, 0, r0, c7, c5, 0 ;invalidate icache mcr p15, 0, r0, c15, c5, 0 ;Invalidate entire data cache isb #if LOCKSTEP_MODE_DEBUG == 0 && (PROCESSOR_ACCESS_VALUE & RPU_TZ_MASK) ;enable fault log for lock step ldr r0,=RPU_GLBL_CNTL ldr r1, [r0] ands r1, r1, #0x8 ;branch to initialization if split mode bne init ;check for boot mode if in lock step, branch to init if JTAG boot mode ldr r0,=BOOT_MODE_USER ldr r1, [r0] ands r1, r1, #0xF beq init ;reset the debug logic ldr r0,=RST_LPD_DBG ldr r1, [r0] orr r1, r1, #(0x1 << 4) orr r1, r1, #(0x1 << 5) str r1, [r0] ;enable fault log ldr r0,=RPU_ERR_INJ ldr r1,=fault_log_enable ldr r2, [r0] orr r2, r2, r1 str r2, [r0] nop nop #endif init bl Init_MPU;Initialize MPU ;Enable Branch prediction mrc p15, 0, r0, c1, c0, 1 ;Read ACTLR bic r0, r0, #(0x1 << 17) ;Clear RSDIS bit 17 to enable return stack bic r0, r0, #(0x1 << 16) ;Clear BP bit 15 and BP bit 16: bic r0, r0, #(0x1 << 15) ;Normal operation, BP is taken from the global history table. orr r0, r0, #(0x1 << 14) ;Disable DBWR for errata 780125 mcr p15, 0, r0, c1, c0, 1 ;Write ACTLR ;Enable icahce and dcache mrc p15,0,r1,c1,c0,0 ldr r0, =0x1005 orr r1,r1,r0 dsb mcr p15,0,r1,c1,c0,0 ;Enable cache isb ;isb flush prefetch buffer ;Set vector table in TCM/LOVEC #ifndef VEC_TABLE_IN_OCM mrc p15, 0, r0, c1, c0, 0 mvn r1, #0x2000 and r0, r0, r1 mcr p15, 0, r0, c1, c0, 0 ;Check if processor is having access to RPU address space #if (PROCESSOR_ACCESS_VALUE & RPU_TZ_MASK) ;Clear VINITHI to enable LOVEC on reset #if XPAR_CPU_ID == 0 ldr r0, =RPU_0_CFG #else ldr r0, =RPU_1_CFG #endif ldr r1, [r0] bic r1, r1, #(0x1 << 2) str r1, [r0] #endif #endif ;enable asynchronous abort exception mrs r0, cpsr bic r0, r0, #0x100 msr cpsr_xsf, r0 bl _startup Ldone b Ldone ;Paranoia: we should never get here END ;@} End of "addtogroup r5_boot_code".
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,401	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/armclang/cpu_init.S	;/****************************************************************************** ;* Copyright (c) 2020 - 2021 Xilinx, Inc. All rights reserved. ;* SPDX-License-Identifier: MIT ;****************************************************************************/ ;/*************************************************************************/ ;/ ;* @file cpu_init.S ;* ;* This file contains CPU specific initialization. Invoked from main CRT ;* ;* <pre> ;* MODIFICATION HISTORY: ;* ;* Ver Who Date Changes ;* ----- ------- -------- --------------------------------------------------- ;* 7.3 dp 06/25/20 Initial version for armclang ;* ;* </pre> ;* ;* @note ;* ;* None. ;* ******************************************************************************/ EXPORT __cpu_init AREA \|.text\|, CODE REQUIRE8 {TRUE} PRESERVE8 {TRUE} ENTRY __cpu_init ;Clear cp15 regs with unknown reset values mov r0, #0x0 mcr p15, 0, r0, c5, c0, 0 ;DFSR mcr p15, 0, r0, c5, c0, 1 ;IFSR mcr p15, 0, r0, c6, c0, 0 ;DFAR mcr p15, 0, r0, c6, c0, 2 ;IFAR mcr p15, 0, r0, c9, c13, 2 ;PMXEVCNTR mcr p15, 0, r0, c13, c0, 2 ;TPIDRURW mcr p15, 0, r0, c13, c0, 3 ;TPIDRURO ;Reset and start Cycle Counter mov r2, #0x80000000 ;clear overflow mcr p15, 0, r2, c9, c12, 3 mov r2, #0xd ;D, C, E mcr p15, 0, r2, c9, c12, 0 mov r2, #0x80000000 ;enable cycle counter mcr p15, 0, r2, c9, c12, 1 bx lr END
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	4,120	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/gcc/xil-crt0.S	/****************************************************************************** * Copyright (c) 2014 - 2022 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file xil-crt0.S * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 5.00 pkp 02/10/14 First release * 5.04 pkp 12/18/15 Initialized global constructor for C++ applications * 5.04 pkp 02/19/16 Added timer configuration using XTime_StartTimer API when * TTC3 is present * 6.4 asa 08/16/17 Added call to Xil_InitializeExistingMPURegConfig to * initialize the MPU configuration table with the MPU * configurations already set in Init_Mpu function. * 6.6 srm 10/18/17 Updated the timer configuration with XTime_StartTTCTimer. * Now the timer instance as specified by the user will be * started. * 7.2 mus 10/22/19 Defined RPU_TZ_MASK as #define instead of variable. * 7.2 sd 03/20/20 Add clocking support. * 7.7 adk 11/30/21 Added support for xiltimer library. * 8.0 mus 07/06/21 Added support for VERSAL NET * 8.0 mus 19/01/22 Existing bootcode is skipping call to __cpu_init for * R52, it's keeping PMU events disabled. Updated code * to fix it. * adk 09/08/22 When xiltimer is enabled don't call XTime_StartTimer() * API. * </pre> * *****************************************************************************/ #include "xparameters.h" #include "bspconfig.h" .file "xil-crt0.S" .section ".got2","aw" .align 2 / * 0th bit of PROCESSOR_ACCESS_VALUE macro signifies trustzone * setting for RPU address space / #define RPU_TZ_MASK 0x1 .text .Lsbss_start: .long __sbss_start .Lsbss_end: .long __sbss_end .Lbss_start: .long __bss_start__ .Lbss_end: .long __bss_end__ .Lstack: .long __stack .set RPU_0_PWRCTL, 0xFF9A0108 .set RPU_1_PWRCTL, 0xFF9A0208 .set MPIDR_AFF0, 0xFF .set PWRCTL_MASK, 0x1 .globl _startup _startup: bl __cpu_init / Initialize the CPU first (BSP provides this) / / TODO: This logic needs to be updated for Cortex-R52 / #ifndef XPAR_XILTIMER_ENABLED #if defined (ARMR52) bl XTime_StartTimer #else #if (PROCESSOR_ACCESS_VALUE & RPU_TZ_MASK) mrc p15, 0, r0, c0, c0, 5 / Read MPIDR register / ands r0, r0, #MPIDR_AFF0 / Get affinity level 0 / bne core1 ldr r10, =RPU_0_PWRCTL / Load PWRCTRL address for core 0 / b test_boot_status core1: ldr r10, =RPU_1_PWRCTL / Load PWRCTRL address for core 1 / test_boot_status: ldr r11, [r10] / Read PWRCTRL register / ands r11, r11, #PWRCTL_MASK / Extract and test core's PWRCTRL / / if warm reset, skip the clearing of BSS and SBSS / bne .Lenclbss #endif #endif #endif mov r0, #0 / clear sbss / ldr r1,.Lsbss_start / calculate beginning of the SBSS / ldr r2,.Lsbss_end / calculate end of the SBSS / .Lloop_sbss: cmp r1,r2 bge .Lenclsbss / If no SBSS, no clearing required / str r0, [r1], #4 b .Lloop_sbss .Lenclsbss: / clear bss / ldr r1,.Lbss_start / calculate beginning of the BSS / ldr r2,.Lbss_end / calculate end of the BSS / .Lloop_bss: cmp r1,r2 bge .Lenclbss / If no BSS, no clearing required / str r0, [r1], #4 b .Lloop_bss .Lenclbss: / set stack pointer / ldr r13,.Lstack / stack address / / configure the timer if TTC is present / #ifndef XPAR_XILTIMER_ENABLED #ifdef SLEEP_TIMER_BASEADDR bl XTime_StartTTCTimer #endif #endif bl Xil_InitializeExistingMPURegConfig / Initialize MPU config / / run global constructors / bl __libc_init_array / make sure argc and argv are valid / mov r0, #0 mov r1, #0 #ifdef XCLOCKING bl Xil_ClockInit #endif bl main / Jump to main C code / / Cleanup global constructors / bl __libc_fini_array bl exit .Lexit: / should never get here */ b .Lexit .Lstart: .size _startup,.Lstart-_startup
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	3,753	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/gcc/asm_vectors.S	/****************************************************************************** * Copyright (c) 2014 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file asm_vectors.S * * This file contains the initial vector table for the Cortex R5 processor * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 5.00 pkp 02/10/14 Initial version * 6.0 mus 27/07/16 Added UndefinedException handler * 6.3 pkp 02/13/17 Added support for hard float * </pre> * *****************************************************************************/ .org 0 .text .globl _boot .globl _vector_table .globl FIQInterrupt .globl IRQInterrupt .globl SWInterrupt .globl DataAbortInterrupt .globl PrefetchAbortInterrupt .globl IRQHandler .globl prof_pc .section .vectors, "a" _vector_table: ldr pc,=_boot ldr pc,=Undefined ldr pc,=SVCHandler ldr pc,=PrefetchAbortHandler ldr pc,=DataAbortHandler NOP / Placeholder for address exception vector/ ldr pc,=IRQHandler ldr pc,=FIQHandler .text IRQHandler: / IRQ vector handler / stmdb sp!,{r0-r3,r12,lr} / state save from compiled code/ #ifndef __SOFTFP__ vpush {d0-d7} / Store floating point registers / vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} #endif bl IRQInterrupt / IRQ vector / #ifndef __SOFTFP__ pop {r1} / Restore floating point registers / vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d0-d7} #endif ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / subs pc, lr, #4 / adjust return / FIQHandler: / FIQ vector handler / stmdb sp!,{r0-r3,r12,lr} / state save from compiled code / FIQLoop: bl FIQInterrupt / FIQ vector / ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / subs pc, lr, #4 / adjust return / Undefined: / Undefined handler / stmdb sp!,{r0-r3,r12,lr} / state save from compiled code / ldr r0, =UndefinedExceptionAddr sub r1, lr, #4 str r1, [r0] / Store address of instruction causing undefined exception / bl UndefinedException / UndefinedException: call C function here / ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / movs pc, lr SVCHandler: / SWI handler / stmdb sp!,{r0-r3,r12,lr} / state save from compiled code / tst r0, #0x20 / check the T bit / ldrneh r0, [lr,#-2] / Thumb mode / bicne r0, r0, #0xff00 / Thumb mode / ldreq r0, [lr,#-4] / ARM mode / biceq r0, r0, #0xff000000 / ARM mode / bl SWInterrupt / SWInterrupt: call C function here / ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / movs pc, lr / adjust return / DataAbortHandler: / Data Abort handler / stmdb sp!,{r0-r3,r12,lr} / state save from compiled code / ldr r0, =DataAbortAddr sub r1, lr, #8 str r1, [r0] / Stores instruction causing data abort / bl DataAbortInterrupt /DataAbortInterrupt :call C function here / ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / subs pc, lr, #8 / adjust return / PrefetchAbortHandler: / Prefetch Abort handler / stmdb sp!,{r0-r3,r12,lr} / state save from compiled code / ldr r0, =PrefetchAbortAddr sub r1, lr, #4 str r1, [r0] / Stores instruction causing prefetch abort / bl PrefetchAbortInterrupt / PrefetchAbortInterrupt: call C function here / ldmia sp!,{r0-r3,r12,lr} / state restore from compiled code / subs pc, lr, #4 / adjust return */ .end
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	13,665	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/gcc/boot.S	/****************************************************************************** * Copyright (c) 2014 - 2022 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file boot.S * * @addtogroup r5_boot_code Cortex R5 Processor Boot Code * @{ * <h2> boot.S </h2> * The boot.S file contains a minimal set of code for transferring control from the processor * reset location of the processor to the start of the application. * The boot code performs minimum configuration which is required for an * application to run starting from reset state of the processor. Below is a * sequence illustrating what all configuration is performed before control * reaches to main function. * * 1. Program vector table base for exception handling * 2. Program stack pointer for various modes (IRQ, FIQ, supervisor, undefine, * abort, system) * 3. Disable instruction cache, data cache and MPU * 4. Invalidate instruction and data cache * 5. Configure MPU with short descriptor translation table format and program * base address of translation table * 6. Enable data cache, instruction cache and MPU * 7. Enable Floating point unit * 8. Transfer control to _start which clears BSS sections and jumping to main * application * * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 5.00 pkp 02/10/14 Initial version * 5.04 pkp 09/11/15 Disabled ACTLR.DBWR bit to avoid potential R5 deadlock * for errata 780125 * 5.04 pkp 02/04/16 Enabled the fault log for lock-step mode * 5.04 pkp 02/25/16 Initialized the banked registers for various modes, * initialized floating point registers and enabled the * cache ECC check before enabling the fault log for * lock step mode * 5.04 pkp 03/24/16 Reset the dbg_lpd_reset before enabling the fault log * to avoid intervention for lock-step mode * 5.05 pkp 04/11/16 Enable the comparators for non-JTAG boot mode for * lock-step to avoid putting debug logic to reset * 6.02 pkp 02/13/17 Added support for hard float * 6.6 mus 02/23/17 Enable/Disable the debug logic in non-JTAG boot mode(when * processor is in lockstep configuration), based * on the mld parameter "lockstep_mode_debug". * 6.8 mus 09/20/18 Clear VINITHI field in RPU_0_CFG/RPU_1_CFG * registers to initialize CortexR5 core with LOVEC * on reset. It fixes CR#1010656. * 7.1 mus 03/27/19 Skip reading/writing to the RPU address space registers, * in case if processor is nonsecure and RPU * address space is secure. CR#1015725. * 7.2 mus 10/11/19 Resetting the r5_0 and r5_1 debug logic is sufficient * to avoid intervention for lock-step mode. So, removed * code which resets dbg_lpd_reset, to unblock debugger * access to LPD. Fix for CR#1027983. * 7.7 mus 11/26/21 Added call to Print_DDRSize_Warning after MPU enablement * to print warning related to DDR size if it is not in * power of 2. It fixes CR#1116431. * 8.0 mus 07/06/21 Added support for VERSAL NET * </pre> * *****************************************************************************/ #include "xparameters.h" .global _prestart .global _boot .global __stack .global __irq_stack .global __supervisor_stack .global __abort_stack .global __fiq_stack .global __undef_stack .global _vector_table / Stack Pointer locations for boot code / .set Undef_stack, __undef_stack .set FIQ_stack, __fiq_stack .set Abort_stack, __abort_stack .set SPV_stack, __supervisor_stack .set IRQ_stack, __irq_stack .set SYS_stack, __stack .set vector_base, _vector_table .set RPU_GLBL_CNTL, 0xFF9A0000 .set RPU_ERR_INJ, 0xFF9A0020 .set RPU_0_CFG, 0xFF9A0100 .set RPU_1_CFG, 0xFF9A0200 #if defined(versal) .set RST_LPD_DBG, 0xFF5E0338 .set BOOT_MODE_USER, 0xF1260200 #else .set RST_LPD_DBG, 0xFF5E0240 .set BOOT_MODE_USER, 0xFF5E0200 #endif .set fault_log_enable, 0x101 #if defined (ARMR52) .set counterfreq, XPAR_CPU_CORTEXR52_0_TIMESTAMP_CLK_FREQ #endif / * 0th bit of PROCESSOR_ACCESS_VALUE macro signifies trustzone * setting for RPU address space / #define RPU_TZ_MASK 0x1 .section .boot,"axS" / this initializes the various processor modes / _prestart: _boot: OKToRun: #if defined (ARMR52) mrs r0, cpsr bfi r1, r0, #0, #5 cmp r1, #0x1A / Check if it is HYP mode / bne InitEL1 ldr r0, =_vector_table mcr p15, 4, r0, c12, c0, 0 / Write HVBAR / #endif / Initialize processor registers to 0 / mov r0,#0 mov r1,#0 mov r2,#0 mov r3,#0 mov r4,#0 mov r5,#0 mov r6,#0 mov r7,#0 mov r8,#0 mov r9,#0 mov r10,#0 mov r11,#0 mov r12,#0 #if defined (ARMR52) / Set counter frequency, CNTFRQ: RW from EL2 RO from EL1 / ldr r0,=counterfreq / 800 KHZ TODO: change it based on HW design through XPARS / mcr 15,0,r0,c14,c0,0 / Write CNTFRQ / / Change EL1 exception base address / ldr r0, =_vector_table mcr p15, 0, r0, c12, c0, 0 / Write VBAR / / Switch to EL1 SVC mode / mrs r0, cpsr mov r1, #0x13 / Mode SVC / bfi r0, r1, #0, #5 msr spsr, r0 ldr r0, =InitEL1 msr elr_hyp, r0 dsb isb eret InitEL1: #endif / Initialize stack pointer and banked registers for various mode / mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the irq stack pointer / and r2, r1, r0 orr r2, r2, #0x12 / IRQ mode / msr cpsr, r2 ldr r13,=IRQ_stack / IRQ stack pointer / mov r14,#0 mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the supervisor stack pointer / and r2, r1, r0 orr r2, r2, #0x13 / supervisor mode / msr cpsr, r2 ldr r13,=SPV_stack / Supervisor stack pointer / mov r14,#0 mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the Abort stack pointer / and r2, r1, r0 orr r2, r2, #0x17 / Abort mode / msr cpsr, r2 ldr r13,=Abort_stack / Abort stack pointer / mov r14,#0 mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the FIQ stack pointer / and r2, r1, r0 orr r2, r2, #0x11 / FIQ mode / msr cpsr, r2 mov r8, #0 mov r9, #0 mov r10, #0 mov r11, #0 mov r12, #0 ldr r13,=FIQ_stack / FIQ stack pointer / mov r14,#0 mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the Undefine stack pointer / and r2, r1, r0 orr r2, r2, #0x1b / Undefine mode / msr cpsr, r2 ldr r13,=Undef_stack / Undefine stack pointer / mov r14,#0 mrs r0, cpsr / get the current PSR / mvn r1, #0x1f / set up the system stack pointer / and r2, r1, r0 orr r2, r2, #0x1F / SYS mode / msr cpsr, r2 ldr r13,=SYS_stack / SYS stack pointer / mov r14,#0 / * Enable access to VFP by enabling access to Coprocessors 10 and 11. * Enables Full Access i.e. in both privileged and non privileged modes / mrc p15, 0, r0, c1, c0, 2 / Read Coprocessor Access Control Register (CPACR) / orr r0, r0, #(0xF << 20) / Enable access to CP 10 & 11 / mcr p15, 0, r0, c1, c0, 2 / Write Coprocessor Access Control Register (CPACR) / isb / enable fpu access / vmrs r3, FPEXC orr r1, r3, #(1<<30) vmsr FPEXC, r1 / clear the floating point register/ mov r1,#0 vmov d0,r1,r1 vmov d1,r1,r1 vmov d2,r1,r1 vmov d3,r1,r1 vmov d4,r1,r1 vmov d5,r1,r1 vmov d6,r1,r1 vmov d7,r1,r1 vmov d8,r1,r1 vmov d9,r1,r1 vmov d10,r1,r1 vmov d11,r1,r1 vmov d12,r1,r1 vmov d13,r1,r1 vmov d14,r1,r1 vmov d15,r1,r1 #ifdef __SOFTFP__ / Disable the FPU if SOFTFP is defined/ vmsr FPEXC,r3 #endif / Disable MPU and caches / mrc p15, 0, r0, c1, c0, 0 / Read CP15 Control Register/ bic r0, r0, #0x05 / Disable MPU (M bit) and data cache (C bit) / bic r0, r0, #0x1000 / Disable instruction cache (I bit) / dsb / Ensure all previous loads/stores have completed / mcr p15, 0, r0, c1, c0, 0 / Write CP15 Control Register / isb / Ensure subsequent insts execute wrt new MPU settings / #if defined (ARMR52) / TODO: revisit to check whether fault log handling like Cortex-R5 is needed / / Enable ECC checks / mrc p15, 1, r0, c9, c1, 2 / Read IMP_MEMPROTCTLR / / disable TCM ECC / bic r0, r0, #(0x1 << 0) / disable TCM and L1 cache ECC / mcr p15, 1, r0, c9, c1, 2 / Write IMP_MEMPROTCTLR / / Disable branch prediction / mrc p15, 1, r0, c9, c1, 1 / Read IMP_BPCTLR / orr r0, r0, #(0x1 << 1) / Disable branch prediction / mcr p15, 1, r0, c9, c1, 1 / Write IMP_BPCTLR / / Set attributes index for normal and device memory in MAIR0 / MRC p15, 0, r0, c10, c2, 0 / Read MAIR0 / LDR r1, =0xBB / Attribute index0: Normal inner/outer RW cacheable, write-through / BFI r0, r1, #0, #8 / Update attribute index0 / LDR r1, =0x04 / Attribute index1: Device nGnRnE / BFI r0, r1, #8, #8 / Update Attribute index1 / LDR r1, =0x44 / Attribute index1: Normal non cacheable / BFI r0, r1, #16, #8 / Update Attribute index2 / MCR p15,0,r0,c10,c2,0 / Write MAIR0 / #else / Disable Branch prediction, TCM ECC checks / mrc p15, 0, r0, c1, c0, 1 / Read ACTLR / orr r0, r0, #(0x1 << 17) / Enable RSDIS bit 17 to disable the return stack / orr r0, r0, #(0x1 << 16) / Clear BP bit 15 and set BP bit 16:/ bic r0, r0, #(0x1 << 15) / Branch always not taken and history table updates disabled/ orr r0, r0, #(0x1 << 27) / Enable B1TCM ECC check / orr r0, r0, #(0x1 << 26) / Enable B0TCM ECC check / orr r0, r0, #(0x1 << 25) / Enable ATCM ECC check / bic r0, r0, #(0x1 << 5) / Generate abort on parity errors, with [5:3]=b 000/ bic r0, r0, #(0x1 << 4) bic r0, r0, #(0x1 << 3) mcr p15, 0, r0, c1, c0, 1 / Write ACTLR/ dsb / Complete all outstanding explicit memory operations/ / Invalidate caches / mov r0,#0 / r0 = 0 / dsb mcr p15, 0, r0, c7, c5, 0 / invalidate icache / mcr p15, 0, r0, c15, c5, 0 / Invalidate entire data cache/ isb #if LOCKSTEP_MODE_DEBUG == 0 && (PROCESSOR_ACCESS_VALUE & RPU_TZ_MASK) / enable fault log for lock step / ldr r0,=RPU_GLBL_CNTL ldr r1, [r0] ands r1, r1, #0x8 / branch to initialization if split mode/ bne init / check for boot mode if in lock step, branch to init if JTAG boot mode/ ldr r0,=BOOT_MODE_USER ldr r1, [r0] ands r1, r1, #0xF beq init / reset the debug logic / ldr r0,=RST_LPD_DBG ldr r1, [r0] orr r1, r1, #(0x1 << 4) orr r1, r1, #(0x1 << 5) str r1, [r0] / enable fault log / ldr r0,=RPU_ERR_INJ ldr r1,=fault_log_enable ldr r2, [r0] orr r2, r2, r1 str r2, [r0] nop nop #endif #endif init: bl Init_MPU / Initialize MPU / #if defined (ARMR52) / Enable Branch prediction / mrc p15, 1, r0, c9, c1, 1 / Read IMP_BPCTLR / bic r0, r0, #(0x1 << 1) / Enable branch prediction / mcr p15, 1, r0, c9, c1, 1 / Write IMP_BPCTLR / mrc p15, 0, r1, c1, c0, 0 / Read System Control Register / ldr r0, =0x1005 / Set M bit to enable MPU, C & I bit for data and instruction caches / orr r1,r1,r0 dsb / Ensure all previous loads/stores have completed / mcr p15, 0, r0, c1, c0, 0 / Write System Control Register / isb #else / Enable Branch prediction / mrc p15, 0, r0, c1, c0, 1 / Read ACTLR/ bic r0, r0, #(0x1 << 17) / Clear RSDIS bit 17 to enable return stack/ bic r0, r0, #(0x1 << 16) / Clear BP bit 15 and BP bit 16:/ bic r0, r0, #(0x1 << 15) / Normal operation, BP is taken from the global history table./ orr r0, r0, #(0x1 << 14) / Disable DBWR for errata 780125 / mcr p15, 0, r0, c1, c0, 1 / Write ACTLR/ / Enable icahce and dcache / mrc p15,0,r1,c1,c0,0 ldr r0, =0x1005 orr r1,r1,r0 dsb mcr p15,0,r1,c1,c0,0 / Enable cache / isb / isb flush prefetch buffer / #ifndef versal bl Print_DDRSize_Warning #endif / Warning message to be removed after 2016.1 / / USEAMP was introduced in 2015.4 with ZynqMP and caused confusion with USE_AMP / #ifdef USEAMP #warning "-DUSEAMP=1 is deprecated, use -DVEC_TABLE_IN_OCM instead to set vector table in OCM" #endif / Set vector table in TCM/LOVEC / #ifndef VEC_TABLE_IN_OCM mrc p15, 0, r0, c1, c0, 0 mvn r1, #0x2000 and r0, r0, r1 mcr p15, 0, r0, c1, c0, 0 / Check if processor is having access to RPU address space / #if (PROCESSOR_ACCESS_VALUE & RPU_TZ_MASK) / Clear VINITHI to enable LOVEC on reset / #if XPAR_CPU_ID == 0 ldr r0, =RPU_0_CFG #else ldr r0, =RPU_1_CFG #endif ldr r1, [r0] bic r1, r1, #(0x1 << 2) str r1, [r0] #endif #endif #endif / enable asynchronous abort exception / mrs r0, cpsr bic r0, r0, #0x100 msr cpsr_xsf, r0 b _startup / jump to C startup code / .Ldone: b .Ldone / Paranoia: we should never get here / .end /* * @} End of "addtogroup r5_boot_code". */
yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples	1,359	leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/gcc/cpu_init.S	/****************************************************************************** * Copyright (c) 2014 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ****************************************************************************/ /*************************************************************************/ / * @file cpu_init.S * * This file contains CPU specific initialization. Invoked from main CRT * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 5.00 pkp 02/10/14 Initial version * * </pre> * *****************************************************************************/ .text .global __cpu_init .align 2 __cpu_init: / Clear cp15 regs with unknown reset values / mov r0, #0x0 mcr p15, 0, r0, c5, c0, 0 / DFSR / mcr p15, 0, r0, c5, c0, 1 / IFSR / mcr p15, 0, r0, c6, c0, 0 / DFAR / mcr p15, 0, r0, c6, c0, 2 / IFAR / mcr p15, 0, r0, c9, c13, 2 / PMXEVCNTR / mcr p15, 0, r0, c13, c0, 2 / TPIDRURW / mcr p15, 0, r0, c13, c0, 3 / TPIDRURO / / Reset and start Cycle Counter / mov r2, #0x80000000 / clear overflow / mcr p15, 0, r2, c9, c12, 3 mov r2, #0xd / D, C, E / mcr p15, 0, r2, c9, c12, 0 mov r2, #0x80000000 / enable cycle counter */ mcr p15, 0, r2, c9, c12, 1 bx lr .end
yjymosheng/arceos-app-support	1,741	arceos/modules/axhal/linker.lds.S	OUTPUT_ARCH(%ARCH%) BASE_ADDRESS = %KERNEL_BASE%; ENTRY(_start) SECTIONS { . = BASE_ADDRESS; _skernel = .; .text : ALIGN(4K) { _stext = .; (.text.boot) (.text .text.) . = ALIGN(4K); _etext = .; } .rodata : ALIGN(4K) { _srodata = .; (.rodata .rodata.) (.srodata .srodata.) (.sdata2 .sdata2.) . = ALIGN(4K); _erodata = .; } .data : ALIGN(4K) { _sdata = .; (.data.boot_page_table) . = ALIGN(4K); (.data .data.) (.sdata .sdata.) (.got .got.) } .tdata : ALIGN(0x10) { _stdata = .; (.tdata .tdata.) _etdata = .; } .tbss : ALIGN(0x10) { _stbss = .; (.tbss .tbss.) (.tcommon) _etbss = .; } . = ALIGN(4K); _percpu_start = .; _percpu_end = _percpu_start + SIZEOF(.percpu); .percpu 0x0 : AT(_percpu_start) { _percpu_load_start = .; (.percpu .percpu.) _percpu_load_end = .; . = _percpu_load_start + ALIGN(64) %SMP%; } . = _percpu_end; . = ALIGN(4K); _edata = .; .bss : ALIGN(4K) { boot_stack = .; (.bss.stack) . = ALIGN(4K); boot_stack_top = .; _sbss = .; (.bss .bss.) (.sbss .sbss.) (COMMON) . = ALIGN(4K); _ebss = .; } _ekernel = .; /DISCARD/ : { (.comment) (.gnu) (.note) (.eh_frame) } } SECTIONS { linkme_IRQ : { (linkme_IRQ) } linkm2_IRQ : { (linkm2_IRQ) } linkme_PAGE_FAULT : { (linkme_PAGE_FAULT) } linkm2_PAGE_FAULT : { *(linkm2_PAGE_FAULT) } } INSERT AFTER .tbss;
yjymosheng/arceos-app-support	4,307	arceos/modules/axhal/src/platform/x86_pc/multiboot.S	# Bootstrapping from 32-bit with the Multiboot specification. # See https://www.gnu.org/software/grub/manual/multiboot/multiboot.html .section .text.boot .code32 .global _start _start: mov edi, eax # arg1: magic: 0x2BADB002 mov esi, ebx # arg2: multiboot info jmp bsp_entry32 .balign 4 .type multiboot_header, STT_OBJECT multiboot_header: .int {mb_hdr_magic} # magic: 0x1BADB002 .int {mb_hdr_flags} # flags .int -({mb_hdr_magic} + {mb_hdr_flags}) # checksum .int multiboot_header - {offset} # header_addr .int _skernel - {offset} # load_addr .int _edata - {offset} # load_end .int _ebss - {offset} # bss_end_addr .int _start - {offset} # entry_addr # Common code in 32-bit, prepare states to enter 64-bit. .macro ENTRY32_COMMON # set data segment selectors mov ax, 0x18 mov ss, ax mov ds, ax mov es, ax mov fs, ax mov gs, ax # set PAE, PGE bit in CR4 mov eax, {cr4} mov cr4, eax # load the temporary page table lea eax, [.Ltmp_pml4 - {offset}] mov cr3, eax # set LME, NXE bit in IA32_EFER mov ecx, {efer_msr} mov edx, 0 mov eax, {efer} wrmsr # set protected mode, write protect, paging bit in CR0 mov eax, {cr0} mov cr0, eax .endm # Common code in 64-bit .macro ENTRY64_COMMON # clear segment selectors xor ax, ax mov ss, ax mov ds, ax mov es, ax mov fs, ax mov gs, ax .endm .code32 bsp_entry32: lgdt [.Ltmp_gdt_desc - {offset}] # load the temporary GDT ENTRY32_COMMON ljmp 0x10, offset bsp_entry64 - {offset} # 0x10 is code64 segment .code32 .global ap_entry32 ap_entry32: ENTRY32_COMMON ljmp 0x10, offset ap_entry64 - {offset} # 0x10 is code64 segment .code64 bsp_entry64: ENTRY64_COMMON # set RSP to boot stack movabs rsp, offset {boot_stack} add rsp, {boot_stack_size} # call rust_entry(magic, mbi) movabs rax, offset {entry} call rax jmp .Lhlt .code64 ap_entry64: ENTRY64_COMMON # set RSP to high address (already set in ap_start.S) mov rax, {offset} add rsp, rax # call rust_entry_secondary(magic) mov rdi, {mb_magic} movabs rax, offset {entry_secondary} call rax jmp .Lhlt .Lhlt: hlt jmp .Lhlt .section .rodata .balign 8 .Ltmp_gdt_desc: .short .Ltmp_gdt_end - .Ltmp_gdt - 1 # limit .long .Ltmp_gdt - {offset} # base .section .data .balign 16 .Ltmp_gdt: .quad 0x0000000000000000 # 0x00: null .quad 0x00cf9b000000ffff # 0x08: code segment (base=0, limit=0xfffff, type=32bit code exec/read, DPL=0, 4k) .quad 0x00af9b000000ffff # 0x10: code segment (base=0, limit=0xfffff, type=64bit code exec/read, DPL=0, 4k) .quad 0x00cf93000000ffff # 0x18: data segment (base=0, limit=0xfffff, type=32bit data read/write, DPL=0, 4k) .Ltmp_gdt_end: .balign 4096 .Ltmp_pml4: # 0x0000_0000 ~ 0xffff_ffff .quad .Ltmp_pdpt_low - {offset} + 0x3 # PRESENT \| WRITABLE \| paddr(tmp_pdpt) .zero 8 * 510 # 0xffff_ff80_0000_0000 ~ 0xffff_ff80_ffff_ffff .quad .Ltmp_pdpt_high - {offset} + 0x3 # PRESENT \| WRITABLE \| paddr(tmp_pdpt) # FIXME: may not work on macOS using hvf as the CPU does not support 1GB page (pdpe1gb) .Ltmp_pdpt_low: .quad 0x0000 \| 0x83 # PRESENT \| WRITABLE \| HUGE_PAGE \| paddr(0x0) .quad 0x40000000 \| 0x83 # PRESENT \| WRITABLE \| HUGE_PAGE \| paddr(0x4000_0000) .quad 0x80000000 \| 0x83 # PRESENT \| WRITABLE \| HUGE_PAGE \| paddr(0x8000_0000) .quad 0xc0000000 \| 0x83 # PRESENT \| WRITABLE \| HUGE_PAGE \| paddr(0xc000_0000) .zero 8 * 508 .Ltmp_pdpt_high: .quad 0x0000 \| 0x83 # PRESENT \| WRITABLE \| HUGE_PAGE \| paddr(0x0) .quad 0x40000000 \| 0x83 # PRESENT \| WRITABLE \| HUGE_PAGE \| paddr(0x4000_0000) .quad 0x80000000 \| 0x83 # PRESENT \| WRITABLE \| HUGE_PAGE \| paddr(0x8000_0000) .quad 0xc0000000 \| 0x83 # PRESENT \| WRITABLE \| HUGE_PAGE \| paddr(0xc000_0000) .zero 8 * 508
yjymosheng/arceos-app-support	1,965	arceos/modules/axhal/src/platform/x86_pc/ap_start.S	# Boot application processors into the protected mode. # Each non-boot CPU ("AP") is started up in response to a STARTUP # IPI from the boot CPU. Section B.4.2 of the Multi-Processor # Specification says that the AP will start in real mode with CS:IP # set to XY00:0000, where XY is an 8-bit value sent with the # STARTUP. Thus this code must start at a 4096-byte boundary. # # Because this code sets DS to zero, it must sit # at an address in the low 2^16 bytes. .equ pa_ap_start32, ap_start32 - ap_start + {start_page_paddr} .equ pa_ap_gdt, .Lap_tmp_gdt - ap_start + {start_page_paddr} .equ pa_ap_gdt_desc, .Lap_tmp_gdt_desc - ap_start + {start_page_paddr} .equ stack_ptr, {start_page_paddr} + 0xff0 .equ entry_ptr, {start_page_paddr} + 0xff8 # 0x6000 .section .text .code16 .p2align 12 .global ap_start ap_start: cli wbinvd xor ax, ax mov ds, ax mov es, ax mov ss, ax mov fs, ax mov gs, ax # load the 64-bit GDT lgdt [pa_ap_gdt_desc] # switch to protected-mode mov eax, cr0 or eax, (1 << 0) mov cr0, eax # far jump to 32-bit code. 0x8 is code32 segment selector ljmp 0x8, offset pa_ap_start32 .code32 ap_start32: mov esp, [stack_ptr] mov eax, [entry_ptr] jmp eax .balign 8 # .type multiboot_header, STT_OBJECT .Lap_tmp_gdt_desc: .short .Lap_tmp_gdt_end - .Lap_tmp_gdt - 1 # limit .long pa_ap_gdt # base .balign 16 .Lap_tmp_gdt: .quad 0x0000000000000000 # 0x00: null .quad 0x00cf9b000000ffff # 0x08: code segment (base=0, limit=0xfffff, type=32bit code exec/read, DPL=0, 4k) .quad 0x00af9b000000ffff # 0x10: code segment (base=0, limit=0xfffff, type=64bit code exec/read, DPL=0, 4k) .quad 0x00cf93000000ffff # 0x18: data segment (base=0, limit=0xfffff, type=32bit data read/write, DPL=0, 4k) .Lap_tmp_gdt_end: # 0x7000 .p2align 12 .global ap_end ap_end:
yjymosheng/arceos-app-support	1,672	arceos/modules/axhal/src/arch/riscv/trap.S	.macro SAVE_REGS, from_user addi sp, sp, -{trapframe_size} PUSH_GENERAL_REGS csrr t0, sepc csrr t1, sstatus csrrw t2, sscratch, zero // save sscratch (sp) and zero it STR t0, sp, 31 // tf.sepc STR t1, sp, 32 // tf.sstatus STR t2, sp, 1 // tf.regs.sp .if \from_user == 1 LDR t0, sp, 3 // load supervisor tp STR gp, sp, 2 // save user gp and tp STR tp, sp, 3 mv tp, t0 .endif .endm .macro RESTORE_REGS, from_user .if \from_user == 1 LDR gp, sp, 2 // load user gp and tp LDR t0, sp, 3 STR tp, sp, 3 // save supervisor tp mv tp, t0 addi t0, sp, {trapframe_size} // put supervisor sp to scratch csrw sscratch, t0 .endif LDR t0, sp, 31 LDR t1, sp, 32 csrw sepc, t0 csrw sstatus, t1 POP_GENERAL_REGS LDR sp, sp, 1 // load sp from tf.regs.sp .endm .section .text .balign 4 .global trap_vector_base trap_vector_base: // sscratch == 0: trap from S mode // sscratch != 0: trap from U mode csrrw sp, sscratch, sp // switch sscratch and sp bnez sp, .Ltrap_entry_u csrr sp, sscratch // put supervisor sp back j .Ltrap_entry_s .Ltrap_entry_s: SAVE_REGS 0 mv a0, sp li a1, 0 call riscv_trap_handler RESTORE_REGS 0 sret .Ltrap_entry_u: SAVE_REGS 1 mv a0, sp li a1, 1 call riscv_trap_handler RESTORE_REGS 1 sret
yjymosheng/arceos-app-support	1,505	arceos/modules/axhal/src/arch/x86_64/trap.S	.equ NUM_INT, 256 .altmacro .macro DEF_HANDLER, i .Ltrap_handler_\i: .if \i == 8 \|\| (\i >= 10 && \i <= 14) \|\| \i == 17 # error code pushed by CPU push \i # interrupt vector jmp .Ltrap_common .else push 0 # fill in error code in TrapFrame push \i # interrupt vector jmp .Ltrap_common .endif .endm .macro DEF_TABLE_ENTRY, i .quad .Ltrap_handler_\i .endm .section .text .code64 _trap_handlers: .set i, 0 .rept NUM_INT DEF_HANDLER %i .set i, i + 1 .endr .Ltrap_common: test byte ptr [rsp + 3 * 8], 3 # swap GS if it comes from user space jz 1f swapgs 1: push r15 push r14 push r13 push r12 push r11 push r10 push r9 push r8 push rdi push rsi push rbp push rbx push rdx push rcx push rax mov rdi, rsp call x86_trap_handler pop rax pop rcx pop rdx pop rbx pop rbp pop rsi pop rdi pop r8 pop r9 pop r10 pop r11 pop r12 pop r13 pop r14 pop r15 test byte ptr [rsp + 3 * 8], 3 # swap GS back if return to user space jz 2f swapgs 2: add rsp, 16 # pop vector, error_code iretq .section .rodata .global trap_handler_table trap_handler_table: .set i, 0 .rept NUM_INT DEF_TABLE_ENTRY %i .set i, i + 1 .endr
yjymosheng/arceos-app-support	2,415	arceos/modules/axhal/src/arch/aarch64/trap.S	.macro SAVE_REGS sub sp, sp, 34 * 8 stp x0, x1, [sp] stp x2, x3, [sp, 2 * 8] stp x4, x5, [sp, 4 * 8] stp x6, x7, [sp, 6 * 8] stp x8, x9, [sp, 8 * 8] stp x10, x11, [sp, 10 * 8] stp x12, x13, [sp, 12 * 8] stp x14, x15, [sp, 14 * 8] stp x16, x17, [sp, 16 * 8] stp x18, x19, [sp, 18 * 8] stp x20, x21, [sp, 20 * 8] stp x22, x23, [sp, 22 * 8] stp x24, x25, [sp, 24 * 8] stp x26, x27, [sp, 26 * 8] stp x28, x29, [sp, 28 * 8] mrs x9, sp_el0 mrs x10, elr_el1 mrs x11, spsr_el1 stp x30, x9, [sp, 30 * 8] stp x10, x11, [sp, 32 * 8] .endm .macro RESTORE_REGS ldp x10, x11, [sp, 32 * 8] ldp x30, x9, [sp, 30 * 8] msr sp_el0, x9 msr elr_el1, x10 msr spsr_el1, x11 ldp x28, x29, [sp, 28 * 8] ldp x26, x27, [sp, 26 * 8] ldp x24, x25, [sp, 24 * 8] ldp x22, x23, [sp, 22 * 8] ldp x20, x21, [sp, 20 * 8] ldp x18, x19, [sp, 18 * 8] ldp x16, x17, [sp, 16 * 8] ldp x14, x15, [sp, 14 * 8] ldp x12, x13, [sp, 12 * 8] ldp x10, x11, [sp, 10 * 8] ldp x8, x9, [sp, 8 * 8] ldp x6, x7, [sp, 6 * 8] ldp x4, x5, [sp, 4 * 8] ldp x2, x3, [sp, 2 * 8] ldp x0, x1, [sp] add sp, sp, 34 * 8 .endm .macro INVALID_EXCP, kind, source .p2align 7 SAVE_REGS mov x0, sp mov x1, \kind mov x2, \source bl invalid_exception b .Lexception_return .endm .macro HANDLE_SYNC .p2align 7 SAVE_REGS mov x0, sp bl handle_sync_exception b .Lexception_return .endm .macro HANDLE_IRQ .p2align 7 SAVE_REGS mov x0, sp bl handle_irq_exception b .Lexception_return .endm .section .text .p2align 11 .global exception_vector_base exception_vector_base: // current EL, with SP_EL0 INVALID_EXCP 0 0 INVALID_EXCP 1 0 INVALID_EXCP 2 0 INVALID_EXCP 3 0 // current EL, with SP_ELx HANDLE_SYNC HANDLE_IRQ INVALID_EXCP 2 1 INVALID_EXCP 3 1 // lower EL, aarch64 HANDLE_SYNC HANDLE_IRQ INVALID_EXCP 2 2 INVALID_EXCP 3 2 // lower EL, aarch32 INVALID_EXCP 0 3 INVALID_EXCP 1 3 INVALID_EXCP 2 3 INVALID_EXCP 3 3 .Lexception_return: RESTORE_REGS eret
yjymosheng/arceos-app-support	2,544	arceos/tools/raspi4/chainloader/src/_arch/aarch64/cpu/boot.s	// SPDX-License-Identifier: MIT OR Apache-2.0 // // Copyright (c) 2021-2022 Andre Richter <andre.o.richter@gmail.com> //-------------------------------------------------------------------------------------------------- // Definitions //-------------------------------------------------------------------------------------------------- // Load the address of a symbol into a register, PC-relative. // // The symbol must lie within +/- 4 GiB of the Program Counter. // // # Resources // // - https://sourceware.org/binutils/docs-2.36/as/AArch64_002dRelocations.html .macro ADR_REL register, symbol adrp \register, \symbol add \register, \register, #:lo12:\symbol .endm // Load the address of a symbol into a register, absolute. // // # Resources // // - https://sourceware.org/binutils/docs-2.36/as/AArch64_002dRelocations.html .macro ADR_ABS register, symbol movz \register, #:abs_g2:\symbol movk \register, #:abs_g1_nc:\symbol movk \register, #:abs_g0_nc:\symbol .endm //-------------------------------------------------------------------------------------------------- // Public Code //-------------------------------------------------------------------------------------------------- .section .text._start //------------------------------------------------------------------------------ // fn _start() //------------------------------------------------------------------------------ _start: // Only proceed on the boot core. Park it otherwise. mrs x0, MPIDR_EL1 and x0, x0, {CONST_CORE_ID_MASK} ldr x1, BOOT_CORE_ID // provided by bsp/__board_name__/cpu.rs cmp x0, x1 b.ne .L_parking_loop // If execution reaches here, it is the boot core. // Initialize DRAM. ADR_ABS x0, __bss_start ADR_ABS x1, __bss_end_exclusive .L_bss_init_loop: cmp x0, x1 b.eq .L_relocate_binary stp xzr, xzr, [x0], #16 b .L_bss_init_loop // Next, relocate the binary. .L_relocate_binary: ADR_REL x0, __binary_nonzero_start // The address the binary got loaded to. ADR_ABS x1, __binary_nonzero_start // The address the binary was linked to. ADR_ABS x2, __binary_nonzero_end_exclusive .L_copy_loop: ldr x3, [x0], #8 str x3, [x1], #8 cmp x1, x2 b.lo .L_copy_loop // Prepare the jump to Rust code. // Set the stack pointer. ADR_ABS x0, __boot_core_stack_end_exclusive mov sp, x0 // Jump to the relocated Rust code. ADR_ABS x1, _start_rust br x1 // Infinitely wait for events (aka "park the core"). .L_parking_loop: wfe b .L_parking_loop .size _start, . - _start .type _start, function .global _start
ynutsgroup/coreflow	1,488	utils/sync_env.s	#!/bin/bash # /opt/coreflow/utils/sync_env.sh # 🔐 Sync .env & .env.key Linux → Windows via SCP (passwordless) # === KONFIGURATION === WIN_USER="${WIN_USER:-Administrator}" WIN_IP="${WIN_IP:-192.168.178.20}" WIN_PATH="${WIN_PATH:-/c:/CoreFlow/}" LINUX_ENV_PATH="${LINUX_ENV_PATH:-/opt/coreflow/}" SSH_KEY="${SSH_KEY:-/home/coreadmin/.ssh/id_rsa_sync}" # === LOGGING === log() { echo "$(date '+%Y-%m-%d %H:%M:%S') \| $1" } # === VORBEDINGUNGEN === check_prerequisites() { if [ ! -d "$LINUX_ENV_PATH" ]; then log "❌ Quellverzeichnis fehlt: $LINUX_ENV_PATH" exit 1 fi if [ ! -f "$SSH_KEY" ]; then log "❌ SSH Key fehlt: $SSH_KEY" exit 1 fi for file in .env .env.key; do if [ ! -f "$LINUX_ENV_PATH/$file" ]; then log "❌ Datei fehlt: $file" exit 1 fi done } # === BACKUP === create_backups() { cd "$LINUX_ENV_PATH" \|\| exit 1 for file in .env .env.key; do cp "$file" "$file.bak" && log "📦 Backup erstellt: $file.bak" done } # === SYNC === sync_files() { cd "$LINUX_ENV_PATH" \|\| exit 1 for file in .env .env.key; do log "🔄 Sync $file → $WIN_USER@$WIN_IP:$WIN_PATH" if scp -i "$SSH_KEY" "$file" "$WIN_USER@$WIN_IP:$WIN_PATH$file"; then log "✅ $file synchronisiert" else log "❌ Fehler beim Sync von $file" fi done } # === MAIN === main() { check_prerequisites create_backups sync_files } main
yongyia/OSKernel2024-SingleOs	2,218	os/src/trap/trap.S	.altmacro .macro SAVE_GP n sd x\n, \n8(sp) .endm .macro LOAD_GP n ld x\n, \n8(sp) .endm .section .text.trampoline .globl __alltraps .globl __restore .globl __alltraps_k .globl __restore_k .align 2 __alltraps: csrrw sp, sscratch, sp # now sp->TrapContext in user space, sscratch->user stack # save other general purpose registers sd x1, 18(sp) # skip sp(x2), we will save it later sd x3, 38(sp) # skip tp(x4), application does not use it # save x5~x31 .set n, 5 .rept 27 SAVE_GP %n .set n, n+1 .endr # we can use t0/t1/t2 freely, because they have been saved in TrapContext csrr t0, sstatus csrr t1, sepc sd t0, 328(sp) sd t1, 338(sp) # read user stack from sscratch and save it in TrapContext csrr t2, sscratch sd t2, 28(sp) # load kernel_satp into t0 ld t0, 348(sp) # load trap_handler into t1 ld t1, 368(sp) # move to kernel_sp ld sp, 358(sp) # switch to kernel space csrw satp, t0 sfence.vma # jump to trap_handler jr t1 __restore: # a0: TrapContext in user space(Constant); a1: user space token # switch to user space csrw satp, a1 sfence.vma csrw sscratch, a0 mv sp, a0 # now sp points to TrapContext in user space, start restoring based on it # restore sstatus/sepc ld t0, 328(sp) ld t1, 338(sp) csrw sstatus, t0 csrw sepc, t1 # restore general purpose registers except x0/sp/tp ld x1, 18(sp) ld x3, 38(sp) .set n, 5 .rept 27 LOAD_GP %n .set n, n+1 .endr # back to user stack ld sp, 28(sp) sret .align 2 __alltraps_k: addi sp, sp, -348 sd x1, 18(sp) sd x3, 38(sp) .set n, 5 .rept 27 SAVE_GP %n .set n, n+1 .endr csrr t0, sstatus csrr t1, sepc sd t0, 328(sp) sd t1, 338(sp) mv a0, sp csrr t2, sscratch jalr t2 __restore_k: ld t0, 328(sp) ld t1, 338(sp) csrw sstatus, t0 csrw sepc, t1 ld x1, 18(sp) ld x3, 38(sp) .set n, 5 .rept 27 LOAD_GP %n .set n, n+1 .endr addi sp, sp, 34*8 sret
Yooshikii/vecno-testnet	5,802	crypto/hashes/src/keccakf1600_x86-64-osx.s	# Source: https://github.com/dot-asm/cryptogams/blob/master/x86_64/keccak1600-x86_64.pl .text .p2align 5 __KeccakF1600: .cfi_startproc .byte 0xf3,0x0f,0x1e,0xfa movq 60(%rdi),%rax movq 68(%rdi),%rbx movq 76(%rdi),%rcx movq 84(%rdi),%rdx movq 92(%rdi),%rbp jmp L$oop .p2align 5 L$oop: movq -100(%rdi),%r8 movq -52(%rdi),%r9 movq -4(%rdi),%r10 movq 44(%rdi),%r11 xorq -84(%rdi),%rcx xorq -76(%rdi),%rdx xorq %r8,%rax xorq -92(%rdi),%rbx xorq -44(%rdi),%rcx xorq -60(%rdi),%rax movq %rbp,%r12 xorq -68(%rdi),%rbp xorq %r10,%rcx xorq -20(%rdi),%rax xorq -36(%rdi),%rdx xorq %r9,%rbx xorq -28(%rdi),%rbp xorq 36(%rdi),%rcx xorq 20(%rdi),%rax xorq 4(%rdi),%rdx xorq -12(%rdi),%rbx xorq 12(%rdi),%rbp movq %rcx,%r13 rolq $1,%rcx xorq %rax,%rcx xorq %r11,%rdx rolq $1,%rax xorq %rdx,%rax xorq 28(%rdi),%rbx rolq $1,%rdx xorq %rbx,%rdx xorq 52(%rdi),%rbp rolq $1,%rbx xorq %rbp,%rbx rolq $1,%rbp xorq %r13,%rbp xorq %rcx,%r9 xorq %rdx,%r10 rolq $44,%r9 xorq %rbp,%r11 xorq %rax,%r12 rolq $43,%r10 xorq %rbx,%r8 movq %r9,%r13 rolq $21,%r11 orq %r10,%r9 xorq %r8,%r9 rolq $14,%r12 xorq (%r15),%r9 leaq 8(%r15),%r15 movq %r12,%r14 andq %r11,%r12 movq %r9,-100(%rsi) xorq %r10,%r12 notq %r10 movq %r12,-84(%rsi) orq %r11,%r10 movq 76(%rdi),%r12 xorq %r13,%r10 movq %r10,-92(%rsi) andq %r8,%r13 movq -28(%rdi),%r9 xorq %r14,%r13 movq -20(%rdi),%r10 movq %r13,-68(%rsi) orq %r8,%r14 movq -76(%rdi),%r8 xorq %r11,%r14 movq 28(%rdi),%r11 movq %r14,-76(%rsi) xorq %rbp,%r8 xorq %rdx,%r12 rolq $28,%r8 xorq %rcx,%r11 xorq %rax,%r9 rolq $61,%r12 rolq $45,%r11 xorq %rbx,%r10 rolq $20,%r9 movq %r8,%r13 orq %r12,%r8 rolq $3,%r10 xorq %r11,%r8 movq %r8,-36(%rsi) movq %r9,%r14 andq %r13,%r9 movq -92(%rdi),%r8 xorq %r12,%r9 notq %r12 movq %r9,-28(%rsi) orq %r11,%r12 movq -44(%rdi),%r9 xorq %r10,%r12 movq %r12,-44(%rsi) andq %r10,%r11 movq 60(%rdi),%r12 xorq %r14,%r11 movq %r11,-52(%rsi) orq %r10,%r14 movq 4(%rdi),%r10 xorq %r13,%r14 movq 52(%rdi),%r11 movq %r14,-60(%rsi) xorq %rbp,%r10 xorq %rax,%r11 rolq $25,%r10 xorq %rdx,%r9 rolq $8,%r11 xorq %rbx,%r12 rolq $6,%r9 xorq %rcx,%r8 rolq $18,%r12 movq %r10,%r13 andq %r11,%r10 rolq $1,%r8 notq %r11 xorq %r9,%r10 movq %r10,-12(%rsi) movq %r12,%r14 andq %r11,%r12 movq -12(%rdi),%r10 xorq %r13,%r12 movq %r12,-4(%rsi) orq %r9,%r13 movq 84(%rdi),%r12 xorq %r8,%r13 movq %r13,-20(%rsi) andq %r8,%r9 xorq %r14,%r9 movq %r9,12(%rsi) orq %r8,%r14 movq -60(%rdi),%r9 xorq %r11,%r14 movq 36(%rdi),%r11 movq %r14,4(%rsi) movq -68(%rdi),%r8 xorq %rcx,%r10 xorq %rdx,%r11 rolq $10,%r10 xorq %rbx,%r9 rolq $15,%r11 xorq %rbp,%r12 rolq $36,%r9 xorq %rax,%r8 rolq $56,%r12 movq %r10,%r13 orq %r11,%r10 rolq $27,%r8 notq %r11 xorq %r9,%r10 movq %r10,28(%rsi) movq %r12,%r14 orq %r11,%r12 xorq %r13,%r12 movq %r12,36(%rsi) andq %r9,%r13 xorq %r8,%r13 movq %r13,20(%rsi) orq %r8,%r9 xorq %r14,%r9 movq %r9,52(%rsi) andq %r14,%r8 xorq %r11,%r8 movq %r8,44(%rsi) xorq -84(%rdi),%rdx xorq -36(%rdi),%rbp rolq $62,%rdx xorq 68(%rdi),%rcx rolq $55,%rbp xorq 12(%rdi),%rax rolq $2,%rcx xorq 20(%rdi),%rbx xchgq %rsi,%rdi rolq $39,%rax rolq $41,%rbx movq %rdx,%r13 andq %rbp,%rdx notq %rbp xorq %rcx,%rdx movq %rdx,92(%rdi) movq %rax,%r14 andq %rbp,%rax xorq %r13,%rax movq %rax,60(%rdi) orq %rcx,%r13 xorq %rbx,%r13 movq %r13,84(%rdi) andq %rbx,%rcx xorq %r14,%rcx movq %rcx,76(%rdi) orq %r14,%rbx xorq %rbp,%rbx movq %rbx,68(%rdi) movq %rdx,%rbp movq %r13,%rdx testq $255,%r15 jnz L$oop leaq -192(%r15),%r15 .byte 0xf3,0xc3 .cfi_endproc .globl _KeccakF1600 .p2align 5 _KeccakF1600: .cfi_startproc .byte 0xf3,0x0f,0x1e,0xfa pushq %rbx .cfi_adjust_cfa_offset 8 .cfi_offset %rbx,-16 pushq %rbp .cfi_adjust_cfa_offset 8 .cfi_offset %rbp,-24 pushq %r12 .cfi_adjust_cfa_offset 8 .cfi_offset %r12,-32 pushq %r13 .cfi_adjust_cfa_offset 8 .cfi_offset %r13,-40 pushq %r14 .cfi_adjust_cfa_offset 8 .cfi_offset %r14,-48 pushq %r15 .cfi_adjust_cfa_offset 8 .cfi_offset %r15,-56 leaq 100(%rdi),%rdi subq $200,%rsp .cfi_adjust_cfa_offset 200 notq -92(%rdi) notq -84(%rdi) notq -36(%rdi) notq -4(%rdi) notq 36(%rdi) notq 60(%rdi) leaq iotas(%rip),%r15 leaq 100(%rsp),%rsi call __KeccakF1600 notq -92(%rdi) notq -84(%rdi) notq -36(%rdi) notq -4(%rdi) notq 36(%rdi) notq 60(%rdi) leaq -100(%rdi),%rdi addq $200,%rsp .cfi_adjust_cfa_offset -200 popq %r15 .cfi_adjust_cfa_offset -8 .cfi_restore %r15 popq %r14 .cfi_adjust_cfa_offset -8 .cfi_restore %r14 popq %r13 .cfi_adjust_cfa_offset -8 .cfi_restore %r13 popq %r12 .cfi_adjust_cfa_offset -8 .cfi_restore %r12 popq %rbp .cfi_adjust_cfa_offset -8 .cfi_restore %rbp popq %rbx .cfi_adjust_cfa_offset -8 .cfi_restore %rbx .byte 0xf3,0xc3 .cfi_endproc .p2align 8 .quad 0,0,0,0,0,0,0,0 iotas: .quad 0x0000000000000001 .quad 0x0000000000008082 .quad 0x800000000000808a .quad 0x8000000080008000 .quad 0x000000000000808b .quad 0x0000000080000001 .quad 0x8000000080008081 .quad 0x8000000000008009 .quad 0x000000000000008a .quad 0x0000000000000088 .quad 0x0000000080008009 .quad 0x000000008000000a .quad 0x000000008000808b .quad 0x800000000000008b .quad 0x8000000000008089 .quad 0x8000000000008003 .quad 0x8000000000008002 .quad 0x8000000000000080 .quad 0x000000000000800a .quad 0x800000008000000a .quad 0x8000000080008081 .quad 0x8000000000008080 .quad 0x0000000080000001 .quad 0x8000000080008008 .byte 75,101,99,99,97,107,45,49,54,48,48,32,97,98,115,111,114,98,32,97,110,100,32,115,113,117,101,101,122,101,32,102,111,114,32,120,56,54,95,54,52,44,32,67,82,89,80,84,79,71,65,77,83,32,98,121,32,60,97,112,112,114,111,64,111,112,101,110,115,115,108,46,111,114,103,62,0
Yooshikii/vecno-testnet	6,073	crypto/hashes/src/keccakf1600_x86-64.s	# Source: https://github.com/dot-asm/cryptogams/blob/master/x86_64/keccak1600-x86_64.pl .text .type __KeccakF1600,@function .align 32 __KeccakF1600: .cfi_startproc .byte 0xf3,0x0f,0x1e,0xfa movq 60(%rdi),%rax movq 68(%rdi),%rbx movq 76(%rdi),%rcx movq 84(%rdi),%rdx movq 92(%rdi),%rbp jmp .Loop .align 32 .Loop: movq -100(%rdi),%r8 movq -52(%rdi),%r9 movq -4(%rdi),%r10 movq 44(%rdi),%r11 xorq -84(%rdi),%rcx xorq -76(%rdi),%rdx xorq %r8,%rax xorq -92(%rdi),%rbx xorq -44(%rdi),%rcx xorq -60(%rdi),%rax movq %rbp,%r12 xorq -68(%rdi),%rbp xorq %r10,%rcx xorq -20(%rdi),%rax xorq -36(%rdi),%rdx xorq %r9,%rbx xorq -28(%rdi),%rbp xorq 36(%rdi),%rcx xorq 20(%rdi),%rax xorq 4(%rdi),%rdx xorq -12(%rdi),%rbx xorq 12(%rdi),%rbp movq %rcx,%r13 rolq $1,%rcx xorq %rax,%rcx xorq %r11,%rdx rolq $1,%rax xorq %rdx,%rax xorq 28(%rdi),%rbx rolq $1,%rdx xorq %rbx,%rdx xorq 52(%rdi),%rbp rolq $1,%rbx xorq %rbp,%rbx rolq $1,%rbp xorq %r13,%rbp xorq %rcx,%r9 xorq %rdx,%r10 rolq $44,%r9 xorq %rbp,%r11 xorq %rax,%r12 rolq $43,%r10 xorq %rbx,%r8 movq %r9,%r13 rolq $21,%r11 orq %r10,%r9 xorq %r8,%r9 rolq $14,%r12 xorq (%r15),%r9 leaq 8(%r15),%r15 movq %r12,%r14 andq %r11,%r12 movq %r9,-100(%rsi) xorq %r10,%r12 notq %r10 movq %r12,-84(%rsi) orq %r11,%r10 movq 76(%rdi),%r12 xorq %r13,%r10 movq %r10,-92(%rsi) andq %r8,%r13 movq -28(%rdi),%r9 xorq %r14,%r13 movq -20(%rdi),%r10 movq %r13,-68(%rsi) orq %r8,%r14 movq -76(%rdi),%r8 xorq %r11,%r14 movq 28(%rdi),%r11 movq %r14,-76(%rsi) xorq %rbp,%r8 xorq %rdx,%r12 rolq $28,%r8 xorq %rcx,%r11 xorq %rax,%r9 rolq $61,%r12 rolq $45,%r11 xorq %rbx,%r10 rolq $20,%r9 movq %r8,%r13 orq %r12,%r8 rolq $3,%r10 xorq %r11,%r8 movq %r8,-36(%rsi) movq %r9,%r14 andq %r13,%r9 movq -92(%rdi),%r8 xorq %r12,%r9 notq %r12 movq %r9,-28(%rsi) orq %r11,%r12 movq -44(%rdi),%r9 xorq %r10,%r12 movq %r12,-44(%rsi) andq %r10,%r11 movq 60(%rdi),%r12 xorq %r14,%r11 movq %r11,-52(%rsi) orq %r10,%r14 movq 4(%rdi),%r10 xorq %r13,%r14 movq 52(%rdi),%r11 movq %r14,-60(%rsi) xorq %rbp,%r10 xorq %rax,%r11 rolq $25,%r10 xorq %rdx,%r9 rolq $8,%r11 xorq %rbx,%r12 rolq $6,%r9 xorq %rcx,%r8 rolq $18,%r12 movq %r10,%r13 andq %r11,%r10 rolq $1,%r8 notq %r11 xorq %r9,%r10 movq %r10,-12(%rsi) movq %r12,%r14 andq %r11,%r12 movq -12(%rdi),%r10 xorq %r13,%r12 movq %r12,-4(%rsi) orq %r9,%r13 movq 84(%rdi),%r12 xorq %r8,%r13 movq %r13,-20(%rsi) andq %r8,%r9 xorq %r14,%r9 movq %r9,12(%rsi) orq %r8,%r14 movq -60(%rdi),%r9 xorq %r11,%r14 movq 36(%rdi),%r11 movq %r14,4(%rsi) movq -68(%rdi),%r8 xorq %rcx,%r10 xorq %rdx,%r11 rolq $10,%r10 xorq %rbx,%r9 rolq $15,%r11 xorq %rbp,%r12 rolq $36,%r9 xorq %rax,%r8 rolq $56,%r12 movq %r10,%r13 orq %r11,%r10 rolq $27,%r8 notq %r11 xorq %r9,%r10 movq %r10,28(%rsi) movq %r12,%r14 orq %r11,%r12 xorq %r13,%r12 movq %r12,36(%rsi) andq %r9,%r13 xorq %r8,%r13 movq %r13,20(%rsi) orq %r8,%r9 xorq %r14,%r9 movq %r9,52(%rsi) andq %r14,%r8 xorq %r11,%r8 movq %r8,44(%rsi) xorq -84(%rdi),%rdx xorq -36(%rdi),%rbp rolq $62,%rdx xorq 68(%rdi),%rcx rolq $55,%rbp xorq 12(%rdi),%rax rolq $2,%rcx xorq 20(%rdi),%rbx xchgq %rsi,%rdi rolq $39,%rax rolq $41,%rbx movq %rdx,%r13 andq %rbp,%rdx notq %rbp xorq %rcx,%rdx movq %rdx,92(%rdi) movq %rax,%r14 andq %rbp,%rax xorq %r13,%rax movq %rax,60(%rdi) orq %rcx,%r13 xorq %rbx,%r13 movq %r13,84(%rdi) andq %rbx,%rcx xorq %r14,%rcx movq %rcx,76(%rdi) orq %r14,%rbx xorq %rbp,%rbx movq %rbx,68(%rdi) movq %rdx,%rbp movq %r13,%rdx testq $255,%r15 jnz .Loop leaq -192(%r15),%r15 .byte 0xf3,0xc3 .cfi_endproc .size __KeccakF1600,.-__KeccakF1600 .globl KeccakF1600 .type KeccakF1600,@function .align 32 KeccakF1600: .cfi_startproc .byte 0xf3,0x0f,0x1e,0xfa pushq %rbx .cfi_adjust_cfa_offset 8 .cfi_offset %rbx,-16 pushq %rbp .cfi_adjust_cfa_offset 8 .cfi_offset %rbp,-24 pushq %r12 .cfi_adjust_cfa_offset 8 .cfi_offset %r12,-32 pushq %r13 .cfi_adjust_cfa_offset 8 .cfi_offset %r13,-40 pushq %r14 .cfi_adjust_cfa_offset 8 .cfi_offset %r14,-48 pushq %r15 .cfi_adjust_cfa_offset 8 .cfi_offset %r15,-56 leaq 100(%rdi),%rdi subq $200,%rsp .cfi_adjust_cfa_offset 200 notq -92(%rdi) notq -84(%rdi) notq -36(%rdi) notq -4(%rdi) notq 36(%rdi) notq 60(%rdi) leaq iotas(%rip),%r15 leaq 100(%rsp),%rsi call __KeccakF1600 notq -92(%rdi) notq -84(%rdi) notq -36(%rdi) notq -4(%rdi) notq 36(%rdi) notq 60(%rdi) leaq -100(%rdi),%rdi addq $200,%rsp .cfi_adjust_cfa_offset -200 popq %r15 .cfi_adjust_cfa_offset -8 .cfi_restore %r15 popq %r14 .cfi_adjust_cfa_offset -8 .cfi_restore %r14 popq %r13 .cfi_adjust_cfa_offset -8 .cfi_restore %r13 popq %r12 .cfi_adjust_cfa_offset -8 .cfi_restore %r12 popq %rbp .cfi_adjust_cfa_offset -8 .cfi_restore %rbp popq %rbx .cfi_adjust_cfa_offset -8 .cfi_restore %rbx .byte 0xf3,0xc3 .cfi_endproc .size KeccakF1600,.-KeccakF1600 .align 256 .quad 0,0,0,0,0,0,0,0 .type iotas,@object iotas: .quad 0x0000000000000001 .quad 0x0000000000008082 .quad 0x800000000000808a .quad 0x8000000080008000 .quad 0x000000000000808b .quad 0x0000000080000001 .quad 0x8000000080008081 .quad 0x8000000000008009 .quad 0x000000000000008a .quad 0x0000000000000088 .quad 0x0000000080008009 .quad 0x000000008000000a .quad 0x000000008000808b .quad 0x800000000000008b .quad 0x8000000000008089 .quad 0x8000000000008003 .quad 0x8000000000008002 .quad 0x8000000000000080 .quad 0x000000000000800a .quad 0x800000008000000a .quad 0x8000000080008081 .quad 0x8000000000008080 .quad 0x0000000080000001 .quad 0x8000000080008008 .size iotas,.-iotas .byte 75,101,99,99,97,107,45,49,54,48,48,32,97,98,115,111,114,98,32,97,110,100,32,115,113,117,101,101,122,101,32,102,111,114,32,120,56,54,95,54,52,44,32,67,82,89,80,84,79,71,65,77,83,32,98,121,32,60,97,112,112,114,111,64,111,112,101,110,115,115,108,46,111,114,103,62,0 .section .note.gnu.property,"a",@note .long 4,2f-1f,5 .byte 0x47,0x4E,0x55,0 1: .long 0xc0000002,4,3 .align 8 2:
Yukash09/RustOS	1,344	src/asm/boot.s	.option norvc # No compressed instructions .section .data .section .text.init .global _start _start: csrr t0 , mhartid bnez t0 , wait csrw satp , zero # No virtual address translation .option push .option norelax # No relaxation optimizations la gp , _global_pointer .option pop # Rust requires .bss section to be zeroed out. la a0 , _bss_start la a1 , _bss_end bgeu a0 , a1 , bss2 # If there is no bss then continue, else zero it out. bss1: sd zero , (a0) # zero it out addi a0 , a0 , 8 bltu a0 , a1 , bss1 bss2: la sp , _stack # Setup stack li t0 , (0b11 << 11) \| (1 << 7) \| (1 << 3) # Set 12-th , 11-th bits csrw mstatus , t0 la t1 , kINIT csrw mepc , t1 la t2 , asm_trap_vector csrw mtvec , t2 li t3 , (1 << 3) \| (1 << 7) \| (1 << 11) csrw mie , t3 la ra , next1 mret next1: li t0 , (1 << 8) \| (1 << 5) # SPP = 1 , SPIE = 1 , SIE = 1 csrw sstatus , t0 la t1 , kmain csrw sepc , t1 # We need to delegate the interrupt , set Software,timer and external interrupts delegate to supervisor mode li t2 , (1 << 1) \| (1 << 5) \| (1 << 9) csrw mideleg , t2 csrw sie , t2 # set SSIE , STIE , SEIE la t3 , asm_trap_vector csrw stvec , t3 csrw satp , a0 sfence.vma sret wait: wfi # wait for interrupt j wait
yukineko/rust1000	5,611	0020-arc/src/main.s	.section __TEXT,__text,regular,pure_instructions .build_version macos, 11, 0 .private_extern __ZN3std2rt10lang_start17hc9ec6b6c1c21b466E .globl __ZN3std2rt10lang_start17hc9ec6b6c1c21b466E .p2align 2 __ZN3std2rt10lang_start17hc9ec6b6c1c21b466E: .cfi_startproc sub sp, sp, #48 stp x29, x30, [sp, #32] add x29, sp, #32 .cfi_def_cfa w29, 16 .cfi_offset w30, -8 .cfi_offset w29, -16 mov x8, x0 str x1, [sp, #8] mov x0, x2 ldr x2, [sp, #8] str x0, [sp, #16] mov x4, x3 ldr x3, [sp, #16] sub x0, x29, #8 stur x8, [x29, #-8] adrp x1, l___unnamed_1@PAGE add x1, x1, l___unnamed_1@PAGEOFF bl __ZN3std2rt19lang_start_internal17h95cf27b851151b9cE ldp x29, x30, [sp, #32] add sp, sp, #48 ret .cfi_endproc .p2align 2 __ZN3std2rt10lang_start28_$u7b$$u7b$closure$u7d$$u7d$17hfd1fe55ffac695a8E: .cfi_startproc stp x29, x30, [sp, #-16]! mov x29, sp .cfi_def_cfa w29, 16 .cfi_offset w30, -8 .cfi_offset w29, -16 ldr x0, [x0] bl __ZN3std3sys9backtrace28__rust_begin_short_backtrace17h44e3fcc15ba029bbE bl __ZN54_$LT$$LP$$RP$$u20$as$u20$std..process..Termination$GT$6report17hcc3ea3c6bcbd09d6E and w0, w0, #0xff ldp x29, x30, [sp], #16 ret .cfi_endproc .p2align 2 __ZN3std3sys9backtrace28__rust_begin_short_backtrace17h44e3fcc15ba029bbE: .cfi_startproc stp x29, x30, [sp, #-16]! mov x29, sp .cfi_def_cfa w29, 16 .cfi_offset w30, -8 .cfi_offset w29, -16 bl __ZN4core3ops8function6FnOnce9call_once17h7d3f893992e17b9aE ; InlineAsm Start ; InlineAsm End ldp x29, x30, [sp], #16 ret .cfi_endproc .p2align 2 __ZN4core3fmt9Arguments9new_const17h762cab0d31c0a37fE: .cfi_startproc str x0, [x8] mov w9, #1 str x9, [x8, #8] adrp x9, l___unnamed_2@PAGE adrp x10, l___unnamed_2@PAGE add x10, x10, l___unnamed_2@PAGEOFF ldr x11, [x9, l___unnamed_2@PAGEOFF] mov w9, #8 ldr x10, [x10, #8] str x11, [x8, #32] str x10, [x8, #40] str x9, [x8, #16] str xzr, [x8, #24] ret .cfi_endproc .p2align 2 __ZN4core3ops8function6FnOnce40call_once$u7b$$u7b$vtable.shim$u7d$$u7d$17hf0e802d55956103eE: .cfi_startproc sub sp, sp, #32 stp x29, x30, [sp, #16] add x29, sp, #16 .cfi_def_cfa w29, 16 .cfi_offset w30, -8 .cfi_offset w29, -16 ldr x0, [x0] bl __ZN4core3ops8function6FnOnce9call_once17h83e29275c978ee6eE ldp x29, x30, [sp, #16] add sp, sp, #32 ret .cfi_endproc .p2align 2 __ZN4core3ops8function6FnOnce9call_once17h7d3f893992e17b9aE: .cfi_startproc sub sp, sp, #32 stp x29, x30, [sp, #16] add x29, sp, #16 .cfi_def_cfa w29, 16 .cfi_offset w30, -8 .cfi_offset w29, -16 blr x0 ldp x29, x30, [sp, #16] add sp, sp, #32 ret .cfi_endproc .p2align 2 __ZN4core3ops8function6FnOnce9call_once17h83e29275c978ee6eE: Lfunc_begin0: .cfi_startproc .cfi_personality 155, _rust_eh_personality .cfi_lsda 16, Lexception0 sub sp, sp, #64 stp x29, x30, [sp, #48] add x29, sp, #48 .cfi_def_cfa w29, 16 .cfi_offset w30, -8 .cfi_offset w29, -16 mov x8, x0 add x0, sp, #16 str x8, [sp, #16] Ltmp0: bl __ZN3std2rt10lang_start28_$u7b$$u7b$closure$u7d$$u7d$17hfd1fe55ffac695a8E str w0, [sp, #12] Ltmp1: b LBB6_3 LBB6_1: ldur x0, [x29, #-16] bl __Unwind_Resume LBB6_2: Ltmp2: stur x0, [x29, #-16] mov x8, x1 stur w8, [x29, #-8] b LBB6_1 LBB6_3: ldr w0, [sp, #12] ldp x29, x30, [sp, #48] add sp, sp, #64 ret Lfunc_end0: .cfi_endproc .section __TEXT,__gcc_except_tab .p2align 2, 0x0 GCC_except_table6: Lexception0: .byte 255 .byte 255 .byte 1 .uleb128 Lcst_end0-Lcst_begin0 Lcst_begin0: .uleb128 Ltmp0-Lfunc_begin0 .uleb128 Ltmp1-Ltmp0 .uleb128 Ltmp2-Lfunc_begin0 .byte 0 .uleb128 Ltmp1-Lfunc_begin0 .uleb128 Lfunc_end0-Ltmp1 .byte 0 .byte 0 Lcst_end0: .p2align 2, 0x0 .section __TEXT,__text,regular,pure_instructions .p2align 2 __ZN4core3ptr85drop_in_place$LT$std..rt..lang_start$LT$$LP$$RP$$GT$..$u7b$$u7b$closure$u7d$$u7d$$GT$17h78975a253d878bd5E: .cfi_startproc ret .cfi_endproc .p2align 2 __ZN54_$LT$$LP$$RP$$u20$as$u20$std..process..Termination$GT$6report17hcc3ea3c6bcbd09d6E: .cfi_startproc mov w0, #0 ret .cfi_endproc .p2align 2 __ZN4main4main17h9b68587896d3bd06E: .cfi_startproc sub sp, sp, #80 stp x29, x30, [sp, #64] add x29, sp, #64 .cfi_def_cfa w29, 16 .cfi_offset w30, -8 .cfi_offset w29, -16 add x8, sp, #16 str x8, [sp, #8] adrp x0, l___unnamed_3@PAGE add x0, x0, l___unnamed_3@PAGEOFF bl __ZN4core3fmt9Arguments9new_const17h762cab0d31c0a37fE ldr x0, [sp, #8] bl __ZN3std2io5stdio6_print17h6200d46cef53dee1E ldp x29, x30, [sp, #64] add sp, sp, #80 ret .cfi_endproc .globl _main .p2align 2 _main: .cfi_startproc stp x29, x30, [sp, #-16]! mov x29, sp .cfi_def_cfa w29, 16 .cfi_offset w30, -8 .cfi_offset w29, -16 mov x2, x1 mov x8, x0 sxtw x1, w8 adrp x0, __ZN4main4main17h9b68587896d3bd06E@PAGE add x0, x0, __ZN4main4main17h9b68587896d3bd06E@PAGEOFF mov w3, #0 bl __ZN3std2rt10lang_start17hc9ec6b6c1c21b466E ldp x29, x30, [sp], #16 ret .cfi_endproc .section __DATA,__const .p2align 3, 0x0 l___unnamed_1: .asciz "\000\000\000\000\000\000\000\000\b\000\000\000\000\000\000\000\b\000\000\000\000\000\000" .quad __ZN4core3ops8function6FnOnce40call_once$u7b$$u7b$vtable.shim$u7d$$u7d$17hf0e802d55956103eE .quad __ZN3std2rt10lang_start28_$u7b$$u7b$closure$u7d$$u7d$17hfd1fe55ffac695a8E .quad __ZN3std2rt10lang_start28_$u7b$$u7b$closure$u7d$$u7d$17hfd1fe55ffac695a8E .section __TEXT,__literal16,16byte_literals .p2align 3, 0x0 l___unnamed_2: .space 8 .space 8 .section __TEXT,__const l___unnamed_4: .ascii "Hello, world!\n" .section __DATA,__const .p2align 3, 0x0 l___unnamed_3: .quad l___unnamed_4 .asciz "\016\000\000\000\000\000\000" .subsections_via_symbols
yusefkarim/firmware-playground	13,510	stm32l4/CMSIS/src/startup_stm32l476xx.s	/ **************************************************************************** * @file startup_stm32l476xx.s * @author MCD Application Team * @brief STM32L476xx devices vector table GCC toolchain. * This module performs: * - Set the initial SP * - Set the initial PC == Reset_Handler, * - Set the vector table entries with the exceptions ISR address, * - Configure the clock system * - Branches to main in the C library (which eventually * calls main()). * After Reset the Cortex-M4 processor is in Thread mode, * priority is Privileged, and the Stack is set to Main. ****************************************************************************** * @attention * * <h2><center>© Copyright (c) 2017 STMicroelectronics. * All rights reserved.</center></h2> * * This software component is licensed by ST under BSD 3-Clause license, * the "License"; You may not use this file except in compliance with the * License. You may obtain a copy of the License at: * opensource.org/licenses/BSD-3-Clause * ****************************************************************************** / .syntax unified .cpu cortex-m4 .fpu softvfp .thumb .global g_pfnVectors .global Default_Handler / start address for the initialization values of the .data section. defined in linker script / .word _sidata / start address for the .data section. defined in linker script / .word _sdata / end address for the .data section. defined in linker script / .word _edata / start address for the .bss section. defined in linker script / .word _sbss / end address for the .bss section. defined in linker script / .word _ebss .equ BootRAM, 0xF1E0F85F /* * @brief This is the code that gets called when the processor first * starts execution following a reset event. Only the absolutely * necessary set is performed, after which the application * supplied main() routine is called. * @param None * @retval : None / .section .text.Reset_Handler .weak Reset_Handler .type Reset_Handler, %function Reset_Handler: ldr sp, =_estack / Atollic update: set stack pointer / / Copy the data segment initializers from flash to SRAM / movs r1, #0 b LoopCopyDataInit CopyDataInit: ldr r3, =_sidata ldr r3, [r3, r1] str r3, [r0, r1] adds r1, r1, #4 LoopCopyDataInit: ldr r0, =_sdata ldr r3, =_edata adds r2, r0, r1 cmp r2, r3 bcc CopyDataInit ldr r2, =_sbss b LoopFillZerobss / Zero fill the bss segment. / FillZerobss: movs r3, #0 str r3, [r2], #4 LoopFillZerobss: ldr r3, = _ebss cmp r2, r3 bcc FillZerobss / Call the clock system intitialization function./ bl SystemInit / Call static constructors / bl __libc_init_array / Call the application's entry point./ bl main LoopForever: b LoopForever .size Reset_Handler, .-Reset_Handler /* * @brief This is the code that gets called when the processor receives an * unexpected interrupt. This simply enters an infinite loop, preserving * the system state for examination by a debugger. * * @param None * @retval : None / .section .text.Default_Handler,"ax",%progbits Default_Handler: Infinite_Loop: b Infinite_Loop .size Default_Handler, .-Default_Handler /***************************************************************************** * * The minimal vector table for a Cortex-M4. Note that the proper constructs * must be placed on this to ensure that it ends up at physical address * 0x0000.0000. * ****************************************************************************/ .section .isr_vector,"a",%progbits .type g_pfnVectors, %object .size g_pfnVectors, .-g_pfnVectors g_pfnVectors: .word _estack .word Reset_Handler .word NMI_Handler .word HardFault_Handler .word MemManage_Handler .word BusFault_Handler .word UsageFault_Handler .word 0 .word 0 .word 0 .word 0 .word SVC_Handler .word DebugMon_Handler .word 0 .word PendSV_Handler .word SysTick_Handler .word WWDG_IRQHandler .word PVD_PVM_IRQHandler .word TAMP_STAMP_IRQHandler .word RTC_WKUP_IRQHandler .word FLASH_IRQHandler .word RCC_IRQHandler .word EXTI0_IRQHandler .word EXTI1_IRQHandler .word EXTI2_IRQHandler .word EXTI3_IRQHandler .word EXTI4_IRQHandler .word DMA1_Channel1_IRQHandler .word DMA1_Channel2_IRQHandler .word DMA1_Channel3_IRQHandler .word DMA1_Channel4_IRQHandler .word DMA1_Channel5_IRQHandler .word DMA1_Channel6_IRQHandler .word DMA1_Channel7_IRQHandler .word ADC1_2_IRQHandler .word CAN1_TX_IRQHandler .word CAN1_RX0_IRQHandler .word CAN1_RX1_IRQHandler .word CAN1_SCE_IRQHandler .word EXTI9_5_IRQHandler .word TIM1_BRK_TIM15_IRQHandler .word TIM1_UP_TIM16_IRQHandler .word TIM1_TRG_COM_TIM17_IRQHandler .word TIM1_CC_IRQHandler .word TIM2_IRQHandler .word TIM3_IRQHandler .word TIM4_IRQHandler .word I2C1_EV_IRQHandler .word I2C1_ER_IRQHandler .word I2C2_EV_IRQHandler .word I2C2_ER_IRQHandler .word SPI1_IRQHandler .word SPI2_IRQHandler .word USART1_IRQHandler .word USART2_IRQHandler .word USART3_IRQHandler .word EXTI15_10_IRQHandler .word RTC_Alarm_IRQHandler .word DFSDM1_FLT3_IRQHandler .word TIM8_BRK_IRQHandler .word TIM8_UP_IRQHandler .word TIM8_TRG_COM_IRQHandler .word TIM8_CC_IRQHandler .word ADC3_IRQHandler .word FMC_IRQHandler .word SDMMC1_IRQHandler .word TIM5_IRQHandler .word SPI3_IRQHandler .word UART4_IRQHandler .word UART5_IRQHandler .word TIM6_DAC_IRQHandler .word TIM7_IRQHandler .word DMA2_Channel1_IRQHandler .word DMA2_Channel2_IRQHandler .word DMA2_Channel3_IRQHandler .word DMA2_Channel4_IRQHandler .word DMA2_Channel5_IRQHandler .word DFSDM1_FLT0_IRQHandler .word DFSDM1_FLT1_IRQHandler .word DFSDM1_FLT2_IRQHandler .word COMP_IRQHandler .word LPTIM1_IRQHandler .word LPTIM2_IRQHandler .word OTG_FS_IRQHandler .word DMA2_Channel6_IRQHandler .word DMA2_Channel7_IRQHandler .word LPUART1_IRQHandler .word QUADSPI_IRQHandler .word I2C3_EV_IRQHandler .word I2C3_ER_IRQHandler .word SAI1_IRQHandler .word SAI2_IRQHandler .word SWPMI1_IRQHandler .word TSC_IRQHandler .word LCD_IRQHandler .word 0 .word RNG_IRQHandler .word FPU_IRQHandler /***************************************************************************** * * Provide weak aliases for each Exception handler to the Default_Handler. * As they are weak aliases, any function with the same name will override * this definition. * *****************************************************************************/ .weak NMI_Handler .thumb_set NMI_Handler,Default_Handler .weak HardFault_Handler .thumb_set HardFault_Handler,Default_Handler .weak MemManage_Handler .thumb_set MemManage_Handler,Default_Handler .weak BusFault_Handler .thumb_set BusFault_Handler,Default_Handler .weak UsageFault_Handler .thumb_set UsageFault_Handler,Default_Handler .weak SVC_Handler .thumb_set SVC_Handler,Default_Handler .weak DebugMon_Handler .thumb_set DebugMon_Handler,Default_Handler .weak PendSV_Handler .thumb_set PendSV_Handler,Default_Handler .weak SysTick_Handler .thumb_set SysTick_Handler,Default_Handler .weak WWDG_IRQHandler .thumb_set WWDG_IRQHandler,Default_Handler .weak PVD_PVM_IRQHandler .thumb_set PVD_PVM_IRQHandler,Default_Handler .weak TAMP_STAMP_IRQHandler .thumb_set TAMP_STAMP_IRQHandler,Default_Handler .weak RTC_WKUP_IRQHandler .thumb_set RTC_WKUP_IRQHandler,Default_Handler .weak FLASH_IRQHandler .thumb_set FLASH_IRQHandler,Default_Handler .weak RCC_IRQHandler .thumb_set RCC_IRQHandler,Default_Handler .weak EXTI0_IRQHandler .thumb_set EXTI0_IRQHandler,Default_Handler .weak EXTI1_IRQHandler .thumb_set EXTI1_IRQHandler,Default_Handler .weak EXTI2_IRQHandler .thumb_set EXTI2_IRQHandler,Default_Handler .weak EXTI3_IRQHandler .thumb_set EXTI3_IRQHandler,Default_Handler .weak EXTI4_IRQHandler .thumb_set EXTI4_IRQHandler,Default_Handler .weak DMA1_Channel1_IRQHandler .thumb_set DMA1_Channel1_IRQHandler,Default_Handler .weak DMA1_Channel2_IRQHandler .thumb_set DMA1_Channel2_IRQHandler,Default_Handler .weak DMA1_Channel3_IRQHandler .thumb_set DMA1_Channel3_IRQHandler,Default_Handler .weak DMA1_Channel4_IRQHandler .thumb_set DMA1_Channel4_IRQHandler,Default_Handler .weak DMA1_Channel5_IRQHandler .thumb_set DMA1_Channel5_IRQHandler,Default_Handler .weak DMA1_Channel6_IRQHandler .thumb_set DMA1_Channel6_IRQHandler,Default_Handler .weak DMA1_Channel7_IRQHandler .thumb_set DMA1_Channel7_IRQHandler,Default_Handler .weak ADC1_2_IRQHandler .thumb_set ADC1_2_IRQHandler,Default_Handler .weak CAN1_TX_IRQHandler .thumb_set CAN1_TX_IRQHandler,Default_Handler .weak CAN1_RX0_IRQHandler .thumb_set CAN1_RX0_IRQHandler,Default_Handler .weak CAN1_RX1_IRQHandler .thumb_set CAN1_RX1_IRQHandler,Default_Handler .weak CAN1_SCE_IRQHandler .thumb_set CAN1_SCE_IRQHandler,Default_Handler .weak EXTI9_5_IRQHandler .thumb_set EXTI9_5_IRQHandler,Default_Handler .weak TIM1_BRK_TIM15_IRQHandler .thumb_set TIM1_BRK_TIM15_IRQHandler,Default_Handler .weak TIM1_UP_TIM16_IRQHandler .thumb_set TIM1_UP_TIM16_IRQHandler,Default_Handler .weak TIM1_TRG_COM_TIM17_IRQHandler .thumb_set TIM1_TRG_COM_TIM17_IRQHandler,Default_Handler .weak TIM1_CC_IRQHandler .thumb_set TIM1_CC_IRQHandler,Default_Handler .weak TIM2_IRQHandler .thumb_set TIM2_IRQHandler,Default_Handler .weak TIM3_IRQHandler .thumb_set TIM3_IRQHandler,Default_Handler .weak TIM4_IRQHandler .thumb_set TIM4_IRQHandler,Default_Handler .weak I2C1_EV_IRQHandler .thumb_set I2C1_EV_IRQHandler,Default_Handler .weak I2C1_ER_IRQHandler .thumb_set I2C1_ER_IRQHandler,Default_Handler .weak I2C2_EV_IRQHandler .thumb_set I2C2_EV_IRQHandler,Default_Handler .weak I2C2_ER_IRQHandler .thumb_set I2C2_ER_IRQHandler,Default_Handler .weak SPI1_IRQHandler .thumb_set SPI1_IRQHandler,Default_Handler .weak SPI2_IRQHandler .thumb_set SPI2_IRQHandler,Default_Handler .weak USART1_IRQHandler .thumb_set USART1_IRQHandler,Default_Handler .weak USART2_IRQHandler .thumb_set USART2_IRQHandler,Default_Handler .weak USART3_IRQHandler .thumb_set USART3_IRQHandler,Default_Handler .weak EXTI15_10_IRQHandler .thumb_set EXTI15_10_IRQHandler,Default_Handler .weak RTC_Alarm_IRQHandler .thumb_set RTC_Alarm_IRQHandler,Default_Handler .weak DFSDM1_FLT3_IRQHandler .thumb_set DFSDM1_FLT3_IRQHandler,Default_Handler .weak TIM8_BRK_IRQHandler .thumb_set TIM8_BRK_IRQHandler,Default_Handler .weak TIM8_UP_IRQHandler .thumb_set TIM8_UP_IRQHandler,Default_Handler .weak TIM8_TRG_COM_IRQHandler .thumb_set TIM8_TRG_COM_IRQHandler,Default_Handler .weak TIM8_CC_IRQHandler .thumb_set TIM8_CC_IRQHandler,Default_Handler .weak ADC3_IRQHandler .thumb_set ADC3_IRQHandler,Default_Handler .weak FMC_IRQHandler .thumb_set FMC_IRQHandler,Default_Handler .weak SDMMC1_IRQHandler .thumb_set SDMMC1_IRQHandler,Default_Handler .weak TIM5_IRQHandler .thumb_set TIM5_IRQHandler,Default_Handler .weak SPI3_IRQHandler .thumb_set SPI3_IRQHandler,Default_Handler .weak UART4_IRQHandler .thumb_set UART4_IRQHandler,Default_Handler .weak UART5_IRQHandler .thumb_set UART5_IRQHandler,Default_Handler .weak TIM6_DAC_IRQHandler .thumb_set TIM6_DAC_IRQHandler,Default_Handler .weak TIM7_IRQHandler .thumb_set TIM7_IRQHandler,Default_Handler .weak DMA2_Channel1_IRQHandler .thumb_set DMA2_Channel1_IRQHandler,Default_Handler .weak DMA2_Channel2_IRQHandler .thumb_set DMA2_Channel2_IRQHandler,Default_Handler .weak DMA2_Channel3_IRQHandler .thumb_set DMA2_Channel3_IRQHandler,Default_Handler .weak DMA2_Channel4_IRQHandler .thumb_set DMA2_Channel4_IRQHandler,Default_Handler .weak DMA2_Channel5_IRQHandler .thumb_set DMA2_Channel5_IRQHandler,Default_Handler .weak DFSDM1_FLT0_IRQHandler .thumb_set DFSDM1_FLT0_IRQHandler,Default_Handler .weak DFSDM1_FLT1_IRQHandler .thumb_set DFSDM1_FLT1_IRQHandler,Default_Handler .weak DFSDM1_FLT2_IRQHandler .thumb_set DFSDM1_FLT2_IRQHandler,Default_Handler .weak COMP_IRQHandler .thumb_set COMP_IRQHandler,Default_Handler .weak LPTIM1_IRQHandler .thumb_set LPTIM1_IRQHandler,Default_Handler .weak LPTIM2_IRQHandler .thumb_set LPTIM2_IRQHandler,Default_Handler .weak OTG_FS_IRQHandler .thumb_set OTG_FS_IRQHandler,Default_Handler .weak DMA2_Channel6_IRQHandler .thumb_set DMA2_Channel6_IRQHandler,Default_Handler .weak DMA2_Channel7_IRQHandler .thumb_set DMA2_Channel7_IRQHandler,Default_Handler .weak LPUART1_IRQHandler .thumb_set LPUART1_IRQHandler,Default_Handler .weak QUADSPI_IRQHandler .thumb_set QUADSPI_IRQHandler,Default_Handler .weak I2C3_EV_IRQHandler .thumb_set I2C3_EV_IRQHandler,Default_Handler .weak I2C3_ER_IRQHandler .thumb_set I2C3_ER_IRQHandler,Default_Handler .weak SAI1_IRQHandler .thumb_set SAI1_IRQHandler,Default_Handler .weak SAI2_IRQHandler .thumb_set SAI2_IRQHandler,Default_Handler .weak SWPMI1_IRQHandler .thumb_set SWPMI1_IRQHandler,Default_Handler .weak TSC_IRQHandler .thumb_set TSC_IRQHandler,Default_Handler .weak LCD_IRQHandler .thumb_set LCD_IRQHandler,Default_Handler .weak RNG_IRQHandler .thumb_set RNG_IRQHandler,Default_Handler .weak FPU_IRQHandler .thumb_set FPU_IRQHandler,Default_Handler /******************** (C) COPYRIGHT STMicroelectronics *END OF FILE**/
yusefkarim/firmware-playground	27,668	tm4c123/UTx_labs/Lab12_TuningFork/startup.s	; <<< Use Configuration Wizard in Context Menu >>> ;**************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Stack EQU 0x00000400 ;************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Heap EQU 0x00000000 ;************************************************************************** ; ; Allocate space for the stack. ; ;************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;************************************************************************** ; ; Allocate space for the heap. ; ;************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;************************************************************************** PRESERVE8 ;************************************************************************** ; ; Place code into the reset code section. ; ;************************************************************************** AREA RESET, CODE, READONLY THUMB ;************************************************************************** ; ; The vector table. ; ;************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;************************************************************************** AREA \|.text\|, CODE, READONLY ;************************************************************************** ; ; Useful functions. ; ;************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;******* DisableInterrupts *********** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;******* EnableInterrupts *********** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;******* StartCritical ******************** ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;******* EndCritical ******************** ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;******* WaitForInterrupt ******************** ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Tell the assembler that we're done. ; ;**************************************************************************** END
yusefkarim/firmware-playground	27,668	tm4c123/UTx_labs/Lab8_SwitchLEDinterface/Startup.s	; <<< Use Configuration Wizard in Context Menu >>> ;**************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Stack EQU 0x00000400 ;************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Heap EQU 0x00000000 ;************************************************************************** ; ; Allocate space for the stack. ; ;************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;************************************************************************** ; ; Allocate space for the heap. ; ;************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;************************************************************************** PRESERVE8 ;************************************************************************** ; ; Place code into the reset code section. ; ;************************************************************************** AREA RESET, CODE, READONLY THUMB ;************************************************************************** ; ; The vector table. ; ;************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;************************************************************************** AREA \|.text\|, CODE, READONLY ;************************************************************************** ; ; Useful functions. ; ;************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;******* DisableInterrupts *********** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;******* EnableInterrupts *********** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;******* StartCritical ******************** ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;******* EndCritical ******************** ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;******* WaitForInterrupt ******************** ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Tell the assembler that we're done. ; ;**************************************************************************** END
yusefkarim/firmware-playground	27,668	tm4c123/UTx_labs/Lab7_HeartBlock/Startup.s	; <<< Use Configuration Wizard in Context Menu >>> ;**************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Stack EQU 0x00000400 ;************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Heap EQU 0x00000000 ;************************************************************************** ; ; Allocate space for the stack. ; ;************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;************************************************************************** ; ; Allocate space for the heap. ; ;************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;************************************************************************** PRESERVE8 ;************************************************************************** ; ; Place code into the reset code section. ; ;************************************************************************** AREA RESET, CODE, READONLY THUMB ;************************************************************************** ; ; The vector table. ; ;************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;************************************************************************** AREA \|.text\|, CODE, READONLY ;************************************************************************** ; ; Useful functions. ; ;************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;******* DisableInterrupts *********** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;******* EnableInterrupts *********** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;******* StartCritical ******************** ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;******* EndCritical ******************** ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;******* WaitForInterrupt ******************** ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Tell the assembler that we're done. ; ;**************************************************************************** END
yusefkarim/firmware-playground	27,668	tm4c123/UTx_labs/Lab6_BranchingFunctionsDelays/Startup.s	; <<< Use Configuration Wizard in Context Menu >>> ;**************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Stack EQU 0x00000400 ;************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Heap EQU 0x00000000 ;************************************************************************** ; ; Allocate space for the stack. ; ;************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;************************************************************************** ; ; Allocate space for the heap. ; ;************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;************************************************************************** PRESERVE8 ;************************************************************************** ; ; Place code into the reset code section. ; ;************************************************************************** AREA RESET, CODE, READONLY THUMB ;************************************************************************** ; ; The vector table. ; ;************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;************************************************************************** AREA \|.text\|, CODE, READONLY ;************************************************************************** ; ; Useful functions. ; ;************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;******* DisableInterrupts *********** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;******* EnableInterrupts *********** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;******* StartCritical ******************** ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;******* EndCritical ******************** ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;******* WaitForInterrupt ******************** ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Tell the assembler that we're done. ; ;**************************************************************************** END
yusefkarim/firmware-playground	27,668	tm4c123/UTx_labs/Lab11_UART/startup.s	; <<< Use Configuration Wizard in Context Menu >>> ;**************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Stack EQU 0x00000400 ;************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Heap EQU 0x00000000 ;************************************************************************** ; ; Allocate space for the stack. ; ;************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;************************************************************************** ; ; Allocate space for the heap. ; ;************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;************************************************************************** PRESERVE8 ;************************************************************************** ; ; Place code into the reset code section. ; ;************************************************************************** AREA RESET, CODE, READONLY THUMB ;************************************************************************** ; ; The vector table. ; ;************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;************************************************************************** AREA \|.text\|, CODE, READONLY ;************************************************************************** ; ; Useful functions. ; ;************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;******* DisableInterrupts *********** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;******* EnableInterrupts *********** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;******* StartCritical ******************** ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;******* EndCritical ******************** ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;******* WaitForInterrupt ******************** ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Tell the assembler that we're done. ; ;**************************************************************************** END
yusefkarim/firmware-playground	27,668	tm4c123/UTx_labs/Lab14_MeasurementOfDistance/startup.s	; <<< Use Configuration Wizard in Context Menu >>> ;**************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Stack EQU 0x00000400 ;************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Heap EQU 0x00000000 ;************************************************************************** ; ; Allocate space for the stack. ; ;************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;************************************************************************** ; ; Allocate space for the heap. ; ;************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;************************************************************************** PRESERVE8 ;************************************************************************** ; ; Place code into the reset code section. ; ;************************************************************************** AREA RESET, CODE, READONLY THUMB ;************************************************************************** ; ; The vector table. ; ;************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;************************************************************************** AREA \|.text\|, CODE, READONLY ;************************************************************************** ; ; Useful functions. ; ;************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;******* DisableInterrupts *********** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;******* EnableInterrupts *********** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;******* StartCritical ******************** ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;******* EndCritical ******************** ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;******* WaitForInterrupt ******************** ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Tell the assembler that we're done. ; ;**************************************************************************** END
yusefkarim/firmware-playground	27,668	tm4c123/UTx_labs/Lab10_TrafficLight/startup.s	; <<< Use Configuration Wizard in Context Menu >>> ;**************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Stack EQU 0x00000400 ;************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Heap EQU 0x00000000 ;************************************************************************** ; ; Allocate space for the stack. ; ;************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;************************************************************************** ; ; Allocate space for the heap. ; ;************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;************************************************************************** PRESERVE8 ;************************************************************************** ; ; Place code into the reset code section. ; ;************************************************************************** AREA RESET, CODE, READONLY THUMB ;************************************************************************** ; ; The vector table. ; ;************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;************************************************************************** AREA \|.text\|, CODE, READONLY ;************************************************************************** ; ; Useful functions. ; ;************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;******* DisableInterrupts *********** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;******* EnableInterrupts *********** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;******* StartCritical ******************** ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;******* EndCritical ******************** ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;******* WaitForInterrupt ******************** ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Tell the assembler that we're done. ; ;**************************************************************************** END
yusefkarim/firmware-playground	27,668	tm4c123/UTx_labs/Lab13_DAC/startup.s	; <<< Use Configuration Wizard in Context Menu >>> ;**************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Stack EQU 0x00000400 ;************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Heap EQU 0x00000000 ;************************************************************************** ; ; Allocate space for the stack. ; ;************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;************************************************************************** ; ; Allocate space for the heap. ; ;************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;************************************************************************** PRESERVE8 ;************************************************************************** ; ; Place code into the reset code section. ; ;************************************************************************** AREA RESET, CODE, READONLY THUMB ;************************************************************************** ; ; The vector table. ; ;************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;************************************************************************** AREA \|.text\|, CODE, READONLY ;************************************************************************** ; ; Useful functions. ; ;************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;******* DisableInterrupts *********** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;******* EnableInterrupts *********** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;******* StartCritical ******************** ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;******* EndCritical ******************** ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;******* WaitForInterrupt ******************** ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Tell the assembler that we're done. ; ;**************************************************************************** END
yusefkarim/firmware-playground	27,668	tm4c123/UTx_labs/Lab9_FunctionalDebugging/Startup.s	; <<< Use Configuration Wizard in Context Menu >>> ;**************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Stack EQU 0x00000400 ;************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;************************************************************************** Heap EQU 0x00000000 ;************************************************************************** ; ; Allocate space for the stack. ; ;************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;************************************************************************** ; ; Allocate space for the heap. ; ;************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;************************************************************************** PRESERVE8 ;************************************************************************** ; ; Place code into the reset code section. ; ;************************************************************************** AREA RESET, CODE, READONLY THUMB ;************************************************************************** ; ; The vector table. ; ;************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;************************************************************************** AREA \|.text\|, CODE, READONLY ;************************************************************************** ; ; Useful functions. ; ;************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;******* DisableInterrupts *********** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;******* EnableInterrupts *********** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;******* StartCritical ******************** ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;******* EndCritical ******************** ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;******* WaitForInterrupt ******************** ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;************************************************************************** ; ; Make sure the end of this section is aligned. ; ;************************************************************************** ALIGN ;************************************************************************** ; ; Tell the assembler that we're done. ; ;**************************************************************************** END
yusefkarim/firmware-playground	9,878	stm32f1/CMSIS/src/startup_stm32f103xb.s	/ *********** (C) COPYRIGHT 2017 STMicroelectronics ********************** * @file startup_stm32f103xb.s * @author MCD Application Team * @brief STM32F103xB Devices vector table for Atollic toolchain. * This module performs: * - Set the initial SP * - Set the initial PC == Reset_Handler, * - Set the vector table entries with the exceptions ISR address * - Configure the clock system * - Branches to main in the C library (which eventually * calls main()). * After Reset the Cortex-M3 processor is in Thread mode, * priority is Privileged, and the Stack is set to Main. ****************************************************************************** * @attention * * <h2><center>© Copyright (c) 2017 STMicroelectronics. * All rights reserved.</center></h2> * * This software component is licensed by ST under BSD 3-Clause license, * the "License"; You may not use this file except in compliance with the * License. You may obtain a copy of the License at: * opensource.org/licenses/BSD-3-Clause * ****************************************************************************** / .syntax unified .cpu cortex-m3 .fpu softvfp .thumb .global g_pfnVectors .global Default_Handler / start address for the initialization values of the .data section. defined in linker script / .word _sidata / start address for the .data section. defined in linker script / .word _sdata / end address for the .data section. defined in linker script / .word _edata / start address for the .bss section. defined in linker script / .word _sbss / end address for the .bss section. defined in linker script / .word _ebss .equ BootRAM, 0xF108F85F /* * @brief This is the code that gets called when the processor first * starts execution following a reset event. Only the absolutely * necessary set is performed, after which the application * supplied main() routine is called. * @param None * @retval : None / .section .text.Reset_Handler .weak Reset_Handler .type Reset_Handler, %function Reset_Handler: / Copy the data segment initializers from flash to SRAM / movs r1, #0 b LoopCopyDataInit CopyDataInit: ldr r3, =_sidata ldr r3, [r3, r1] str r3, [r0, r1] adds r1, r1, #4 LoopCopyDataInit: ldr r0, =_sdata ldr r3, =_edata adds r2, r0, r1 cmp r2, r3 bcc CopyDataInit ldr r2, =_sbss b LoopFillZerobss / Zero fill the bss segment. / FillZerobss: movs r3, #0 str r3, [r2], #4 LoopFillZerobss: ldr r3, = _ebss cmp r2, r3 bcc FillZerobss / Call the clock system intitialization function./ bl SystemInit / Call static constructors / bl __libc_init_array / Call the application's entry point./ bl main bx lr .size Reset_Handler, .-Reset_Handler /* * @brief This is the code that gets called when the processor receives an * unexpected interrupt. This simply enters an infinite loop, preserving * the system state for examination by a debugger. * * @param None * @retval : None / .section .text.Default_Handler,"ax",%progbits Default_Handler: Infinite_Loop: b Infinite_Loop .size Default_Handler, .-Default_Handler /***************************************************************************** * * The minimal vector table for a Cortex M3. Note that the proper constructs * must be placed on this to ensure that it ends up at physical address * 0x0000.0000. * *****************************************************************************/ .section .isr_vector,"a",%progbits .type g_pfnVectors, %object .size g_pfnVectors, .-g_pfnVectors g_pfnVectors: .word _estack .word Reset_Handler .word NMI_Handler .word HardFault_Handler .word MemManage_Handler .word BusFault_Handler .word UsageFault_Handler .word 0 .word 0 .word 0 .word 0 .word SVC_Handler .word DebugMon_Handler .word 0 .word PendSV_Handler .word SysTick_Handler .word WWDG_IRQHandler .word PVD_IRQHandler .word TAMPER_IRQHandler .word RTC_IRQHandler .word FLASH_IRQHandler .word RCC_IRQHandler .word EXTI0_IRQHandler .word EXTI1_IRQHandler .word EXTI2_IRQHandler .word EXTI3_IRQHandler .word EXTI4_IRQHandler .word DMA1_Channel1_IRQHandler .word DMA1_Channel2_IRQHandler .word DMA1_Channel3_IRQHandler .word DMA1_Channel4_IRQHandler .word DMA1_Channel5_IRQHandler .word DMA1_Channel6_IRQHandler .word DMA1_Channel7_IRQHandler .word ADC1_2_IRQHandler .word USB_HP_CAN1_TX_IRQHandler .word USB_LP_CAN1_RX0_IRQHandler .word CAN1_RX1_IRQHandler .word CAN1_SCE_IRQHandler .word EXTI9_5_IRQHandler .word TIM1_BRK_IRQHandler .word TIM1_UP_IRQHandler .word TIM1_TRG_COM_IRQHandler .word TIM1_CC_IRQHandler .word TIM2_IRQHandler .word TIM3_IRQHandler .word TIM4_IRQHandler .word I2C1_EV_IRQHandler .word I2C1_ER_IRQHandler .word I2C2_EV_IRQHandler .word I2C2_ER_IRQHandler .word SPI1_IRQHandler .word SPI2_IRQHandler .word USART1_IRQHandler .word USART2_IRQHandler .word USART3_IRQHandler .word EXTI15_10_IRQHandler .word RTC_Alarm_IRQHandler .word USBWakeUp_IRQHandler .word 0 .word 0 .word 0 .word 0 .word 0 .word 0 .word 0 .word BootRAM / @0x108. This is for boot in RAM mode for STM32F10x Medium Density devices. / /****************************************************************************** * * Provide weak aliases for each Exception handler to the Default_Handler. * As they are weak aliases, any function with the same name will override * this definition. * *****************************************************************************/ .weak NMI_Handler .thumb_set NMI_Handler,Default_Handler .weak HardFault_Handler .thumb_set HardFault_Handler,Default_Handler .weak MemManage_Handler .thumb_set MemManage_Handler,Default_Handler .weak BusFault_Handler .thumb_set BusFault_Handler,Default_Handler .weak UsageFault_Handler .thumb_set UsageFault_Handler,Default_Handler .weak SVC_Handler .thumb_set SVC_Handler,Default_Handler .weak DebugMon_Handler .thumb_set DebugMon_Handler,Default_Handler .weak PendSV_Handler .thumb_set PendSV_Handler,Default_Handler .weak SysTick_Handler .thumb_set SysTick_Handler,Default_Handler .weak WWDG_IRQHandler .thumb_set WWDG_IRQHandler,Default_Handler .weak PVD_IRQHandler .thumb_set PVD_IRQHandler,Default_Handler .weak TAMPER_IRQHandler .thumb_set TAMPER_IRQHandler,Default_Handler .weak RTC_IRQHandler .thumb_set RTC_IRQHandler,Default_Handler .weak FLASH_IRQHandler .thumb_set FLASH_IRQHandler,Default_Handler .weak RCC_IRQHandler .thumb_set RCC_IRQHandler,Default_Handler .weak EXTI0_IRQHandler .thumb_set EXTI0_IRQHandler,Default_Handler .weak EXTI1_IRQHandler .thumb_set EXTI1_IRQHandler,Default_Handler .weak EXTI2_IRQHandler .thumb_set EXTI2_IRQHandler,Default_Handler .weak EXTI3_IRQHandler .thumb_set EXTI3_IRQHandler,Default_Handler .weak EXTI4_IRQHandler .thumb_set EXTI4_IRQHandler,Default_Handler .weak DMA1_Channel1_IRQHandler .thumb_set DMA1_Channel1_IRQHandler,Default_Handler .weak DMA1_Channel2_IRQHandler .thumb_set DMA1_Channel2_IRQHandler,Default_Handler .weak DMA1_Channel3_IRQHandler .thumb_set DMA1_Channel3_IRQHandler,Default_Handler .weak DMA1_Channel4_IRQHandler .thumb_set DMA1_Channel4_IRQHandler,Default_Handler .weak DMA1_Channel5_IRQHandler .thumb_set DMA1_Channel5_IRQHandler,Default_Handler .weak DMA1_Channel6_IRQHandler .thumb_set DMA1_Channel6_IRQHandler,Default_Handler .weak DMA1_Channel7_IRQHandler .thumb_set DMA1_Channel7_IRQHandler,Default_Handler .weak ADC1_2_IRQHandler .thumb_set ADC1_2_IRQHandler,Default_Handler .weak USB_HP_CAN1_TX_IRQHandler .thumb_set USB_HP_CAN1_TX_IRQHandler,Default_Handler .weak USB_LP_CAN1_RX0_IRQHandler .thumb_set USB_LP_CAN1_RX0_IRQHandler,Default_Handler .weak CAN1_RX1_IRQHandler .thumb_set CAN1_RX1_IRQHandler,Default_Handler .weak CAN1_SCE_IRQHandler .thumb_set CAN1_SCE_IRQHandler,Default_Handler .weak EXTI9_5_IRQHandler .thumb_set EXTI9_5_IRQHandler,Default_Handler .weak TIM1_BRK_IRQHandler .thumb_set TIM1_BRK_IRQHandler,Default_Handler .weak TIM1_UP_IRQHandler .thumb_set TIM1_UP_IRQHandler,Default_Handler .weak TIM1_TRG_COM_IRQHandler .thumb_set TIM1_TRG_COM_IRQHandler,Default_Handler .weak TIM1_CC_IRQHandler .thumb_set TIM1_CC_IRQHandler,Default_Handler .weak TIM2_IRQHandler .thumb_set TIM2_IRQHandler,Default_Handler .weak TIM3_IRQHandler .thumb_set TIM3_IRQHandler,Default_Handler .weak TIM4_IRQHandler .thumb_set TIM4_IRQHandler,Default_Handler .weak I2C1_EV_IRQHandler .thumb_set I2C1_EV_IRQHandler,Default_Handler .weak I2C1_ER_IRQHandler .thumb_set I2C1_ER_IRQHandler,Default_Handler .weak I2C2_EV_IRQHandler .thumb_set I2C2_EV_IRQHandler,Default_Handler .weak I2C2_ER_IRQHandler .thumb_set I2C2_ER_IRQHandler,Default_Handler .weak SPI1_IRQHandler .thumb_set SPI1_IRQHandler,Default_Handler .weak SPI2_IRQHandler .thumb_set SPI2_IRQHandler,Default_Handler .weak USART1_IRQHandler .thumb_set USART1_IRQHandler,Default_Handler .weak USART2_IRQHandler .thumb_set USART2_IRQHandler,Default_Handler .weak USART3_IRQHandler .thumb_set USART3_IRQHandler,Default_Handler .weak EXTI15_10_IRQHandler .thumb_set EXTI15_10_IRQHandler,Default_Handler .weak RTC_Alarm_IRQHandler .thumb_set RTC_Alarm_IRQHandler,Default_Handler .weak USBWakeUp_IRQHandler .thumb_set USBWakeUp_IRQHandler,Default_Handler /******************** (C) COPYRIGHT STMicroelectronics *END OF FILE**/
YuXuaann/Compile	1,028	task1/src/sample-32.s	.file "sample.c" .text .globl main .type main, @function main: .LFB0: .cfi_startproc endbr32 pushl %ebp .cfi_def_cfa_offset 8 .cfi_offset 5, -8 movl %esp, %ebp .cfi_def_cfa_register 5 subl $16, %esp call __x86.get_pc_thunk.ax addl $_GLOBAL_OFFSET_TABLE_, %eax movl $4, -4(%ebp) cmpl $0, -4(%ebp) je .L2 addl $4, -4(%ebp) jmp .L3 .L2: sall $2, -4(%ebp) .L3: movl $0, %eax leave .cfi_restore 5 .cfi_def_cfa 4, 4 ret .cfi_endproc .LFE0: .size main, .-main .section .text.__x86.get_pc_thunk.ax,"axG",@progbits,__x86.get_pc_thunk.ax,comdat .globl __x86.get_pc_thunk.ax .hidden __x86.get_pc_thunk.ax .type __x86.get_pc_thunk.ax, @function __x86.get_pc_thunk.ax: .LFB1: .cfi_startproc movl (%esp), %eax ret .cfi_endproc .LFE1: .ident "GCC: (Ubuntu 9.5.0-1ubuntu1~22.04) 9.5.0" .section .note.GNU-stack,"",@progbits .section .note.gnu.property,"a" .align 4 .long 1f - 0f .long 4f - 1f .long 5 0: .string "GNU" 1: .align 4 .long 0xc0000002 .long 3f - 2f 2: .long 0x3 3: .align 4 4:

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

2,879

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_invalidate_icache_range.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * * microblaze_invalidate_icache_range(unsigned int cacheaddr, unsigned int len) * * Invalidate an ICache range * * Parameters: * 'cacheaddr' - address in the Icache where invalidation begins * 'len' - length (in bytes) worth of Icache to be invalidated * * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_ICACHE_ENABLE 0x00000020 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_ICACHE_LINE_LEN #define XPAR_MICROBLAZE_ICACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #endif .text .globl microblaze_invalidate_icache_range .ent microblaze_invalidate_icache_range .align 2 microblaze_invalidate_icache_range: #if (XPAR_MICROBLAZE_USE_ICACHE==1) && (XPAR_MICROBLAZE_ALLOW_ICACHE_WR==1) #ifdef MB_VERSION_LT_v720 /* Disable Icache and interrupts before invalidating */ mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_ICACHE_ENABLE | MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif BEQI r6, L_done /* Skip loop if size is zero */ ADD r6, r5, r6 /* Compute end address */ ADDIK r6, r6, -1 ANDI r6, r6, -(4 * XPAR_MICROBLAZE_ICACHE_LINE_LEN) /* Align end down to cache line */ ANDI r5, r5, -(4 * XPAR_MICROBLAZE_ICACHE_LINE_LEN) /* Align start down to cache line */ L_start: CMPU r18, r5, r6 /* Are we at the end? */ BLTI r18, L_done wic r5, r0 /* Invalidate the cache line */ #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN * 4) /* Increment the address by 4 */ breai L_start /* Branch to the beginning of the loop */ #else brid L_start /* Branch to the beginning of the loop */ addik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN * 4) /* Increment the address by 4 (delay slot) */ #endif L_done: rtsd r15, 8 /* Return */ #ifdef MB_VERSION_LT_v720 /* restore MSR only for MB version < v7.20 */ mts rmsr, r9 #else nop #endif #else rtsd r15, 8 /* Return */ nop #endif .end microblaze_invalidate_icache_range

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,482

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_flush_cache_ext_range.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * microblaze_flush_cache_ext_range (unsigned int cacheaddr, unsigned int len) * *Flush a L2 Cache range * *Parameters: * 'cacheaddr' - address in the L2 cache where the flush begins * 'len ' - length (in bytes) worth of L2 cache to be flushed * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN 16 .text .globl microblaze_flush_cache_ext_range .ent microblaze_flush_cache_ext_range .align 2 microblaze_flush_cache_ext_range: #if ((XPAR_MICROBLAZE_INTERCONNECT==3) && (XPAR_MICROBLAZE_USE_DCACHE==1)) beqi r6, Loop_done ADDIK r6, r6, -1 ADD r6, r5, r6 ANDI r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) ANDI r5, r5, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) RSUBK r6, r5, r6 Loop_start: wdc.ext.flush r5, r6 #if defined (__arch64__ ) addlik r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) beagei r6, Loop_start #else bneid r6, Loop_start addik r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) #endif Loop_done: #endif rtsd r15, 8 nop .end microblaze_flush_cache_ext_range

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,815

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_flush_dcache.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * * microblaze_flush_dcache() * * Flush the L1 DCache * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif .text .globl microblaze_flush_dcache .ent microblaze_flush_dcache .align 2 microblaze_flush_dcache: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) ADDIK r5, r0, XPAR_MICROBLAZE_DCACHE_BASEADDR & (-(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN)) /* Align to cache line */ ADDIK r6, r5, XPAR_MICROBLAZE_DCACHE_BYTE_SIZE & (-(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN)) /* Compute end */ L_start: wdc.flush r5, r0 /* Flush the Cache */ CMPU r18, r5, r6 /* Are we at the end? */ BLEI r18, L_done #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* Increment the address by 4 */ BRI L_start #else brid L_start /* Branch to the beginning of the loop */ addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* Increment the address by 4 (delay slot) */ #endif L_done: #endif rtsd r15, 8 /* Return */ nop .end microblaze_flush_dcache

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

32,372

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_selftest.S

/****************************************************************************** * Copyright (c) 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * * @file microblaze_selftest.S * * @addtogroup microblaze_pseudo_asm_macro * @{ * <h2> microblaze_selftest.S </h2> * * This routine provides an internal self test of the MicroBlaze processor. The * register file and all integer execution units are tested. Long instructions * are also included if 64-bit mode is enabled. Currently FPU, MMU, BTC, data * and instruction caches, and GET/PUT instructions are not covered. * * The routine is not reentrant, and disables interrupts and exceptions during * execution. This can result in increased interrupt latency. * * Call this routine regularly from a timer interrupt. * * When called from C code the routine should be declared as: * extern int microblaze_selftest(); * * @param None. * * @return * - 0 if self test was successful * - Error code if self test failed: * Bit 0: Register file test failed * Bit 1: ALU test failed * Bit 2: Shift unit test failed * Bit 3: Load-store test failed * Bit 4: Branch instruction test failed * Bit 5: Barrel shifter test failed * Bit 6: Multiplier test failed * Bit 7: Integer divide test failed * Bit 8: Pattern compare test failed * Bit 9: MSR instruction test failed * Bit 10: Reorder instruction test failed * * @note * This routine assumes that the processor is in privileged mode when it is * called, if the MMU is enabled. * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- -------- ----------------------------------------------- * 1.0 sa 09/07/20 First release * * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" /* Define if execution units are used */ #ifdef XPAR_MICROBLAZE_USE_BARREL #if XPAR_MICROBLAZE_USE_BARREL > 0 #define USE_BARREL #endif #endif #ifdef XPAR_MICROBLAZE_USE_HW_MUL #if XPAR_MICROBLAZE_USE_HW_MUL > 0 #define USE_HW_MUL #endif #if XPAR_MICROBLAZE_USE_HW_MUL == 2 #define USE_HW_MUL_2 #endif #endif #ifdef XPAR_MICROBLAZE_USE_DIV #if XPAR_MICROBLAZE_USE_DIV > 0 #define USE_DIV #endif #endif #ifdef XPAR_MICROBLAZE_USE_PCMP_INSTR #if XPAR_MICROBLAZE_USE_PCMP_INSTR > 0 #define USE_PCMP_INSTR #endif #endif #ifdef XPAR_MICROBLAZE_USE_MSR_INSTR #if XPAR_MICROBLAZE_USE_MSR_INSTR > 0 #define USE_MSR_INSTR #endif #endif #ifdef XPAR_MICROBLAZE_USE_REORDER_INSTR #if XPAR_MICROBLAZE_USE_REORDER_INSTR > 0 #define USE_REORDER_INSTR #endif #endif #if defined (__arch64__) #define OFFSET(index) ((index) * 8) #define INCR(index) addlik r1, (index) * 8 #define DATA .quad #else #define OFFSET(index) ((index) * 4) #define INCR(index) addik r1, r1, (index) * 4 #define DATA .long #endif /***************************************************************************** * Machine Status Register masks ******************************************************************************/ #define MSR_CARRY_MASK 0x80000004 #define MSR_EE_IE_MASK 0x00000102 #define MSR_PVR_BIT_MASK 0x00000000 #ifdef XPAR_MICROBLAZE_PVR #if XPAR_MICROBLAZE_PVR > 0 #undef MSR_PVR_BIT_MASK #define MSR_PVR_BIT_MASK 0x00000400 #endif #endif #define MSR_BIT_MASK (0x8000000E | MSR_PVR_BIT_MASK) /***************************************************************************** * Test macros ******************************************************************************/ #define TEST_ALU_ARITH(instr, load, offset) \ instr r5, r2, r4; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_aluerr; \ lwi r8, r1, OFFSET(offset + 1); \ mfs r9, rmsr; \ andi r9, r9, MSR_CARRY_MASK; \ cmpu r9, r9, r8; \ BNEID r9, L_microblaze_selftest_aluerr #define TEST_ALU_LOGIC(instr, load, offset) \ instr r5, r2, r4; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_aluerr #define TEST_SHIFT(instr, load, offset) \ instr r5, r2; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_shifterr #define TEST_SHIFTC(instr, load, offset) \ instr r5, r2; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_shifterr; \ lwi r8, r1, OFFSET(offset + 1); \ mfs r9, rmsr; \ andi r9, r9, MSR_CARRY_MASK; \ cmpu r9, r9, r8; \ BNEID r9, L_microblaze_selftest_shifterr #define TEST_BARREL(instr, load, offset) \ instr r5, r2, r4; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_barrelerr #define TEST_BARREL_IMM(instr, immw, imms, load, offset) \ ori r5, r2, 0; \ instr r5, r4, immw, imms; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_barrelerr #define TEST_MUL(instr, load, byteoffset) \ instr r5, r2, r4; \ load r6, r1, byteoffset; \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_mulerr #define TEST_DIV(instr, load, byteoffset) \ instr r5, r2, r4; \ load r6, r1, byteoffset; \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_diverr #define TEST_PCMP(instr, load, offset) \ instr r5, r2, r4; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_pcmperr .text .globl microblaze_selftest .ent microblaze_selftest .align 2 microblaze_selftest: /***************************************************************************** * Preamble ******************************************************************************/ /* Disable interrupts and exceptions, save MSR */ #ifdef USE_MSR_INSTR msrclr r3, MSR_EE_IE_MASK #else mfs r3, rmsr andi r3, r3, ~MSR_EE_IE_MASK mts rmsr, r3 #endif swi r3, r0, L_microblaze_selftest_regs /* Save registers, except r3 temporary register and return value */ ADDIK r3, r0, L_microblaze_selftest_regs SI r1, r3, OFFSET(1) SI r2, r3, OFFSET(2) SI r4, r3, OFFSET(4) SI r5, r3, OFFSET(5) SI r6, r3, OFFSET(6) SI r7, r3, OFFSET(7) SI r8, r3, OFFSET(8) SI r9, r3, OFFSET(9) SI r10, r3, OFFSET(10) SI r11, r3, OFFSET(11) SI r12, r3, OFFSET(12) SI r13, r3, OFFSET(13) SI r14, r3, OFFSET(14) SI r15, r3, OFFSET(15) SI r16, r3, OFFSET(16) SI r17, r3, OFFSET(17) SI r18, r3, OFFSET(18) SI r19, r3, OFFSET(19) SI r20, r3, OFFSET(20) SI r21, r3, OFFSET(21) SI r22, r3, OFFSET(22) SI r23, r3, OFFSET(23) SI r24, r3, OFFSET(24) SI r25, r3, OFFSET(25) SI r26, r3, OFFSET(26) SI r27, r3, OFFSET(27) SI r28, r3, OFFSET(28) SI r29, r3, OFFSET(29) SI r30, r3, OFFSET(30) SI r31, r3, OFFSET(31) /* Set r3 to test pass = 0 */ ADDIK r3, r0, 0 /***************************************************************************** * 1. Test register file ******************************************************************************/ L_microblaze_selftest_reg: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_regdata L_microblaze_selftest_regloop: /* Load test pattern into r2, r4 - r31 */ LI r2, r1, 0 LI r4, r1, 0 LI r5, r1, 0 LI r6, r1, 0 LI r7, r1, 0 LI r8, r1, 0 LI r9, r1, 0 LI r10, r1, 0 LI r11, r1, 0 LI r12, r1, 0 LI r13, r1, 0 LI r14, r1, 0 LI r15, r1, 0 LI r16, r1, 0 LI r17, r1, 0 LI r18, r1, 0 LI r19, r1, 0 LI r20, r1, 0 LI r21, r1, 0 LI r22, r1, 0 LI r23, r1, 0 LI r24, r1, 0 LI r25, r1, 0 LI r26, r1, 0 LI r27, r1, 0 LI r28, r1, 0 LI r29, r1, 0 LI r30, r1, 0 LI r31, r1, 0 /* Compare registers pair by pair */ CMPU r2, r2, r4 BNEID r2, L_microblaze_selftest_regerr CMPU r4, r4, r5 BNEID r4, L_microblaze_selftest_regerr CMPU r5, r5, r6 BNEID r5, L_microblaze_selftest_regerr CMPU r6, r6, r7 BNEID r6, L_microblaze_selftest_regerr CMPU r7, r7, r8 BNEID r7, L_microblaze_selftest_regerr CMPU r8, r8, r9 BNEID r8, L_microblaze_selftest_regerr CMPU r9, r9, r10 BNEID r9, L_microblaze_selftest_regerr CMPU r10, r10, r11 BNEID r10, L_microblaze_selftest_regerr CMPU r11, r11, r12 BNEID r11, L_microblaze_selftest_regerr CMPU r12, r12, r13 BNEID r12, L_microblaze_selftest_regerr CMPU r13, r13, r14 BNEID r13, L_microblaze_selftest_regerr CMPU r14, r14, r15 BNEID r14, L_microblaze_selftest_regerr CMPU r15, r15, r16 BNEID r15, L_microblaze_selftest_regerr CMPU r16, r16, r17 BNEID r16, L_microblaze_selftest_regerr CMPU r17, r17, r18 BNEID r17, L_microblaze_selftest_regerr CMPU r18, r18, r19 BNEID r18, L_microblaze_selftest_regerr CMPU r19, r19, r20 BNEID r19, L_microblaze_selftest_regerr CMPU r20, r20, r21 BNEID r20, L_microblaze_selftest_regerr CMPU r21, r21, r22 BNEID r21, L_microblaze_selftest_regerr CMPU r22, r22, r23 BNEID r22, L_microblaze_selftest_regerr CMPU r23, r23, r24 BNEID r23, L_microblaze_selftest_regerr CMPU r24, r24, r25 BNEID r24, L_microblaze_selftest_regerr CMPU r25, r25, r26 BNEID r25, L_microblaze_selftest_regerr CMPU r26, r26, r27 BNEID r26, L_microblaze_selftest_regerr CMPU r27, r27, r28 BNEID r27, L_microblaze_selftest_regerr CMPU r28, r28, r29 BNEID r28, L_microblaze_selftest_regerr CMPU r29, r29, r30 BNEID r29, L_microblaze_selftest_regerr CMPU r30, r30, r31 BEQI r30, L_microblaze_selftest_regnext L_microblaze_selftest_regerr: /* Test error - set register file error (bit 0) */ ori r3, r3, 1 L_microblaze_selftest_regnext: /* Loop back with next test pattern - end after zero pattern */ BNEID r31, L_microblaze_selftest_regloop INCR(1) /***************************************************************************** * 2. Test ALU ******************************************************************************/ L_microblaze_selftest_alu: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_aludata L_microblaze_selftest_aluloop: /* Load operands into r2, r4 */ LI r2, r1, OFFSET(0) LI r4, r1, OFFSET(1) /* Execute all ALU arithmetic instructions */ TEST_ALU_ARITH(add, lwi, 2) TEST_ALU_ARITH(addc, lwi, 4) TEST_ALU_ARITH(rsub, lwi, 6) TEST_ALU_ARITH(rsubc, lwi, 8) TEST_ALU_LOGIC(cmp, lwi, 10) /* Execute all ALU logical instructions */ TEST_ALU_LOGIC(and, lwi, 11) TEST_ALU_LOGIC(andn, lwi, 12) TEST_ALU_LOGIC(or, lwi, 13) TEST_ALU_LOGIC(xor, lwi, 14) nop bri L_microblaze_selftest_alunext L_microblaze_selftest_aluerr: /* Test error - set ALU error (bit 1) */ ori r3, r3, 2 L_microblaze_selftest_alunext: /* Loop back with next test data - end after zero data */ BNEID r2, L_microblaze_selftest_aluloop INCR(15) /***************************************************************************** * 3. Test shift unit ******************************************************************************/ L_microblaze_selftest_shift: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_shiftdata L_microblaze_selftest_shiftloop: /* Load operand into r2 */ LI r2, r1, OFFSET(0) /* Test instructions clz, sext8, sext16, sra, src, srl */ TEST_SHIFT(clz, lwi, 1) TEST_SHIFT(sext8, lwi, 2) TEST_SHIFT(sext16, lwi, 3) TEST_SHIFTC(sra, lwi, 4) TEST_SHIFTC(src, lwi, 6) TEST_SHIFTC(srl, lwi, 8) nop bri L_microblaze_selftest_shiftnext L_microblaze_selftest_shifterr: /* Test error - set shift logic error (bit 2) */ ori r3, r3, 4 L_microblaze_selftest_shiftnext: /* Loop back with next test data - end after zero data */ BNEID r2, L_microblaze_selftest_shiftloop INCR(10) /***************************************************************************** * 4. Test load-store ******************************************************************************/ L_microblaze_selftest_ldst: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_ldstdata /* Set static address and offsets */ ADDIK r4, r0, L_microblaze_selftest_ldstptr ADDIK r24, r0, 4 ADDIK r28, r0, 8 L_microblaze_selftest_ldstloop: /* Load operand into r2 */ LI r2, r1, OFFSET(0) /* Test instructions lbu, lhu, lw, sb, sh, sw */ sb r2, r4, r0 sh r2, r4, r24 sw r2, r4, r28 lbu r8, r4, r0 lhu r9, r4, r24 lw r10, r4, r28 /* Compare load results */ ANDI r11, r2, 0xFF ANDI r12, r2, 0xFFFF CMPU r16, r11, r8 BNEID r16, L_microblaze_selftest_ldsterr CMPU r17, r12, r9 BNEID r17, L_microblaze_selftest_ldsterr CMPU r18, r2, r10 BEQI r18, L_microblaze_selftest_ldstnext L_microblaze_selftest_ldsterr: /* Test error - set load-store error (bit 3) */ ori r3, r3, 8 L_microblaze_selftest_ldstnext: /* Loop back with next test data - end after zero data */ BNEID r2, L_microblaze_selftest_ldstloop INCR(1) /***************************************************************************** * 4. Test branch ******************************************************************************/ L_microblaze_selftest_branch: /* Test instructions blt, ble, bge, bgt, br */ /* Untested instructions: rtbd, rtid, rted, brk */ addik r2, r0, 0 /* EQ */ addik r4, r0, 1 /* GT */ addik r5, r0, -1 /* LT */ /* Taken branches */ BEQI r2, L_microblaze_selftest_brancheq ori r3, r3, 16 /* Test error */ L_microblaze_selftest_brancheq: BGEI r2, L_microblaze_selftest_branchge0 ori r3, r3, 16 /* Test error */ L_microblaze_selftest_branchge0: BGEI r4, L_microblaze_selftest_branchge1 ori r3, r3, 16 /* Test error */ L_microblaze_selftest_branchge1: BGTI r4, L_microblaze_selftest_branchgt ori r3, r3, 16 /* Test error */ L_microblaze_selftest_branchgt: BLEI r2, L_microblaze_selftest_branchle0 ori r3, r3, 16 /* Test error */ L_microblaze_selftest_branchle0: BLEI r5, L_microblaze_selftest_branchle1 ori r3, r3, 16 /* Test error */ L_microblaze_selftest_branchle1: BLTI r5, L_microblaze_selftest_branchlt ori r3, r3, 16 /* Test error */ L_microblaze_selftest_branchlt: BNEI r4, L_microblaze_selftest_branchne ori r3, r3, 16 /* Test error */ L_microblaze_selftest_branchne: /* Not taken branches */ BEQI r4, L_microblaze_selftest_brancherr BEQI r5, L_microblaze_selftest_brancherr BGEI r5, L_microblaze_selftest_brancherr BGTI r2, L_microblaze_selftest_brancherr BGTI r5, L_microblaze_selftest_brancherr BLEI r4, L_microblaze_selftest_brancherr BLTI r2, L_microblaze_selftest_brancherr BLTI r4, L_microblaze_selftest_brancherr BNEI r2, L_microblaze_selftest_brancherr BRI L_microblaze_selftest_branchnext L_microblaze_selftest_brancherr: /* Test error - set branch error (bit 4) */ ori r3, r3, 16 L_microblaze_selftest_branchnext: /***************************************************************************** * 6. Test barrel shifter ******************************************************************************/ #ifdef USE_BARREL L_microblaze_selftest_barrel: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_barreldata L_microblaze_selftest_barrelloop: /* Load operands into r2, r4 */ LI r2, r1, OFFSET(0) LI r4, r1, OFFSET(1) /* Test instructions bsrl, bsra, bsll, bsifi, bsefi */ TEST_BARREL(bsrl, lwi, 2) TEST_BARREL(bsra, lwi, 3) TEST_BARREL(bsll, lwi, 4) TEST_BARREL_IMM(bsifi, 11, 6, lwi, 5); TEST_BARREL_IMM(bsefi, 6, 1, lwi, 6); nop bri L_microblaze_selftest_barrelnext L_microblaze_selftest_barrelerr: /* Test error - set barrel logic error (bit 5) */ ori r3, r3, 32 L_microblaze_selftest_barrelnext: /* Loop back with next test data - end after zero data */ BNEID r2, L_microblaze_selftest_barrelloop INCR(7) #endif /***************************************************************************** * 7. Test multiplier ******************************************************************************/ #ifdef USE_HW_MUL L_microblaze_selftest_mul: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_muldata L_microblaze_selftest_mulloop: /* Load operands into r2, r4 */ lwi r2, r1, 0 lwi r4, r1, 4 /* Test instruction mul */ TEST_MUL(mul, lwi, 8) #ifdef USE_HW_MUL_2 /* Test instructions mulh, mulhu, mulhsu */ TEST_MUL(mulh, lwi, 12) TEST_MUL(mulhu, lwi, 16) TEST_MUL(mulhsu, lwi, 20) #endif nop bri L_microblaze_selftest_mulnext L_microblaze_selftest_mulerr: /* Test error - set multiply error (bit 6) */ ori r3, r3, 64 L_microblaze_selftest_mulnext: /* Loop back with next test data - end after zero data */ BNEID r2, L_microblaze_selftest_mulloop #ifdef USE_HW_MUL_2 addik r1, r1, 24 #else addik r1, r1, 12 #endif #endif /***************************************************************************** * 8. Test integer divide ******************************************************************************/ #ifdef USE_DIV L_microblaze_selftest_div: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_divdata L_microblaze_selftest_divloop: /* Load operands into r2, r4 */ lwi r2, r1, 0 lwi r4, r1, 4 /* Test instructions idiv, idivu */ TEST_DIV(idiv, lwi, 8) TEST_DIV(idivu, lwi, 12) nop bri L_microblaze_selftest_divnext L_microblaze_selftest_diverr: /* Test error - set integer divide error (bit 7) */ ori r3, r3, 128 L_microblaze_selftest_divnext: /* Loop back with next test data - end after zero data */ BNEID r4, L_microblaze_selftest_divloop addik r1, r1, 16 #endif /***************************************************************************** * 9. Test pattern compare ******************************************************************************/ #ifdef USE_PCMP_INSTR L_microblaze_selftest_pcmp: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_pcmpdata L_microblaze_selftest_pcmploop: /* Load operands into r2, r4 */ LI r2, r1, OFFSET(0) LI r4, r1, OFFSET(1) /* Test instructions pcmpbf, pcmpeq, pcmpne */ /* 64-bit: add instructions pcmplbf, pcmpleq, pcmplne */ TEST_PCMP(pcmpbf, lwi, 2) TEST_PCMP(pcmpeq, lwi, 3) TEST_PCMP(pcmpne, lwi, 4) nop bri L_microblaze_selftest_pcmpnext L_microblaze_selftest_pcmperr: /* Test error - set pcmp logic error (bit 8) */ ori r3, r3, 256 L_microblaze_selftest_pcmpnext: /* Loop back with next test data - end after zero data */ BNEID r2, L_microblaze_selftest_pcmploop INCR(5) #endif /***************************************************************************** * 10. Test MSR instructions ******************************************************************************/ L_microblaze_selftest_msr: #ifdef USE_MSR_INSTR /* Test instructions msrclr, msrset, mfs msr */ msrset r0, ~MSR_EE_IE_MASK & 0x7FFF nop mfs r6, rmsr nop msrclr r7, 0x7FF nop mfs r8, rmsr nop #endif /* Test instructions mfs msr, mts msr */ /* Bits not included: ICE, DZO, DCE, EE, EIP, UMS, VMS */ addik r9, r0, MSR_BIT_MASK & ~MSR_EE_IE_MASK mts rmsr, r9 nop mfs r10, rmsr /* Compare instruction result */ #ifdef USE_MSR_INSTR addik r11, r0, MSR_PVR_BIT_MASK cmpu r12, r6, r7 BNEID r12, L_microblaze_selftest_msrerr cmpu r13, r8, r11 BNEID r13, L_microblaze_selftest_msrerr #endif cmpu r14, r9, r10 BEQI r14, L_microblaze_selftest_msrnext L_microblaze_selftest_msrerr: /* Test error - set MSR instruction error (bit 9) */ ori r3, r3, 512 L_microblaze_selftest_msrnext: /***************************************************************************** * 11. Test reorder instructions ******************************************************************************/ #ifdef USE_REORDER_INSTR L_microblaze_selftest_reorder: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_reorderdata /* Set static address and offsets */ ADDIK r4, r0, L_microblaze_selftest_ldstptr ADDIK r24, r0, 4 ADDIK r28, r0, 8 L_microblaze_selftest_reorderloop: /* Load operand into r2 */ LI r2, r1, OFFSET(0) /* Test instructions swapb, swaph, lbur, lhur, lwr, sbr, shr, swr */ sbr r2, r4, r0 shr r2, r4, r24 swr r2, r4, r28 lbur r8, r4, r0 lhur r9, r4, r24 lwr r10, r4, r28 swapb r21, r2 swaph r22, r2 /* Load swap results */ LI r13, r1, OFFSET(1) LI r14, r1, OFFSET(2) /* Compare load results */ ANDI r11, r2, 0xFF ANDI r12, r2, 0xFFFF CMPU r16, r11, r8 BNEID r16, L_microblaze_selftest_reordererr CMPU r17, r12, r9 BNEID r17, L_microblaze_selftest_reordererr CMPU r18, r2, r10 BNEID r18, L_microblaze_selftest_reordererr CMPU r19, r21, r13 BNEID r19, L_microblaze_selftest_reordererr CMPU r20, r22, r14 BEQI r20, L_microblaze_selftest_reordernext L_microblaze_selftest_reordererr: /* Test error - set reorder instruction error (bit 10) */ ori r3, r3, 1024 L_microblaze_selftest_reordernext: /* Loop back with next test data - end after zero data */ BNEID r2, L_microblaze_selftest_reorderloop INCR(3) #endif /***************************************************************************** * Postamble ******************************************************************************/ /* Restore all registers, except r3 return value and r4 temporary */ ADDIK r31, r0, L_microblaze_selftest_regs LI r1, r31, OFFSET(1) LI r2, r31, OFFSET(2) LI r4, r31, OFFSET(4) LI r5, r31, OFFSET(5) LI r6, r31, OFFSET(6) LI r7, r31, OFFSET(7) LI r8, r31, OFFSET(8) LI r9, r31, OFFSET(9) LI r10, r31, OFFSET(10) LI r11, r31, OFFSET(11) LI r12, r31, OFFSET(12) LI r13, r31, OFFSET(13) LI r14, r31, OFFSET(14) LI r15, r31, OFFSET(15) LI r16, r31, OFFSET(16) LI r17, r31, OFFSET(17) LI r18, r31, OFFSET(18) LI r19, r31, OFFSET(19) LI r20, r31, OFFSET(20) LI r21, r31, OFFSET(21) LI r22, r31, OFFSET(22) LI r23, r31, OFFSET(23) LI r24, r31, OFFSET(24) LI r25, r31, OFFSET(25) LI r26, r31, OFFSET(26) LI r27, r31, OFFSET(27) LI r28, r31, OFFSET(28) LI r29, r31, OFFSET(29) LI r30, r31, OFFSET(30) LI r31, r31, OFFSET(31) /* Restore MSR */ lwi r4, r0, L_microblaze_selftest_regs mts rmsr, r4 /* Return */ rtsd r15, 8 nop L_microblaze_selftest_end: .end microblaze_selftest /***************************************************************************** * Temporary storage used by this routine * MSR followd by registers r1 - r31 ******************************************************************************/ .data .align 3 L_microblaze_selftest_regs: .rept 32 #if defined (__arch64__) .quad 0 #else .long 0 #endif .endr /***************************************************************************** * Test data used by this routine ******************************************************************************/ L_microblaze_selftest_regdata: #if defined (__arch64__) .quad 0x5555555555555555 .quad 0xAAAAAAAAAAAAAAAA .quad 0xFFFFFFFFFFFFFFFF .quad 0x0000000000000000 #else .long 0x55555555 .long 0xAAAAAAAA .long 0xFFFFFFFF .long 0x00000000 #endif L_microblaze_selftest_aludata: DATA 0x55555555 /* rA operand */ DATA 0x55555556 /* rB operand */ DATA 0xAAAAAAAB /* rD result: add */ DATA 0x00000000 /* MSR.C: add */ DATA 0xAAAAAAAB /* rD result: addc */ DATA 0x00000000 /* MSR.C: addc */ DATA 0x00000001 /* rD result: rsub */ DATA MSR_CARRY_MASK /* MSR.C: rsub */ DATA 0x00000001 /* rD result: rsubc */ DATA MSR_CARRY_MASK /* MSR.C: rsubc */ DATA 0x00000001 /* rD result: cmp */ DATA 0x55555554 /* rD result: and */ DATA 0x00000001 /* rD result: andn */ DATA 0x55555557 /* rD result: or */ DATA 0x00000003 /* rD result: xor */ DATA 0xAAAAAAAB /* rA operand */ DATA 0xAAAAAAAA /* rB operand */ DATA 0x55555555 /* rD result: add */ DATA MSR_CARRY_MASK /* MSR.C: add */ DATA 0x55555556 /* rD result: addc */ DATA MSR_CARRY_MASK /* MSR.C: addc */ DATA 0xFFFFFFFF /* rD result: rsub */ DATA 0x00000000 /* MSR.C: rsub */ DATA 0xFFFFFFFE /* rD result: rsubc */ DATA 0x00000000 /* MSR.C: rsubc */ DATA 0xFFFFFFFF /* rD result: cmp */ DATA 0xAAAAAAAA /* rD result: and */ DATA 0x00000001 /* rD result: andn */ DATA 0xAAAAAAAB /* rD result: or */ DATA 0x00000001 /* rD result: xor */ DATA 0xFFFFFFFF /* rA operand */ DATA 0xFFFFFFFF /* rB operand */ DATA 0xFFFFFFFE /* rD result: add */ DATA MSR_CARRY_MASK /* MSR.C: add */ DATA 0xFFFFFFFF /* rD result: addc */ DATA MSR_CARRY_MASK /* MSR.C: addc */ DATA 0x00000000 /* rD result: rsub */ DATA MSR_CARRY_MASK /* MSR.C: rsub */ DATA 0x00000000 /* rD result: rsubc */ DATA MSR_CARRY_MASK /* MSR.C: rsubc */ DATA 0x00000000 /* rD result: cmp */ DATA 0xFFFFFFFF /* rD result: and */ DATA 0x00000000 /* rD result: andn */ DATA 0xFFFFFFFF /* rD result: or */ DATA 0x00000000 /* rD result: xor */ DATA 0x00000000 /* rA operand */ DATA 0xFFFFFFFF /* rB operand */ DATA 0xFFFFFFFF /* rD result: add */ DATA 0x00000000 /* MSR.C: add */ DATA 0xFFFFFFFF /* rD result: addc */ DATA 0x00000000 /* MSR.C: addc */ DATA 0xFFFFFFFF /* rD result: rsub */ DATA MSR_CARRY_MASK /* MSR.C: rsub */ DATA 0xFFFFFFFF /* rD result: rsubc */ DATA MSR_CARRY_MASK /* MSR.C: rsubc */ DATA 0xFFFFFFFF /* rD result: cmp */ DATA 0x00000000 /* rD result: and */ DATA 0x00000000 /* rD result: andn */ DATA 0xFFFFFFFF /* rD result: or */ DATA 0xFFFFFFFF /* rD result: xor */ L_microblaze_selftest_shiftdata: DATA 0x55555555 /* rA operand */ DATA 0x00000001 /* rD result: clz */ DATA 0x00000055 /* rD result: sext8 */ DATA 0x00005555 /* rD result: sext16 */ DATA 0x2AAAAAAA /* rD result: sra */ DATA MSR_CARRY_MASK /* MSR.C: sra */ DATA 0xAAAAAAAA /* rD result: src */ DATA MSR_CARRY_MASK /* MSR.C: src */ DATA 0x2AAAAAAA /* rD result: srl */ DATA MSR_CARRY_MASK /* MSR.C: src */ DATA 0xAAAAAAAA /* rA operand */ DATA 0x00000000 /* rD result: clz */ DATA 0xFFFFFFAA /* rD result: sext8 */ DATA 0xFFFFAAAA /* rD result: sext16 */ DATA 0xD5555555 /* rD result: sra */ DATA 0x00000000 /* MSR.C: sra */ DATA 0x55555555 /* rD result: src */ DATA 0x00000000 /* MSR.C: src */ DATA 0x55555555 /* rD result: srl */ DATA 0x00000000 /* MSR.C: srl */ DATA 0xFFFFFFFF /* rA operand */ DATA 0x00000000 /* rD result: clz */ DATA 0xFFFFFFFF /* rD result: sext8 */ DATA 0xFFFFFFFF /* rD result: sext16 */ DATA 0xFFFFFFFF /* rD result: sra */ DATA MSR_CARRY_MASK /* MSR.C: sra */ DATA 0xFFFFFFFF /* rD result: src */ DATA MSR_CARRY_MASK /* MSR.C: src */ DATA 0x7FFFFFFF /* rD result: srl */ DATA MSR_CARRY_MASK /* MSR.C: srl */ DATA 0x00000000 /* rA operand */ DATA 0x00000020 /* rD result: clz */ DATA 0x00000000 /* rD result: sext8 */ DATA 0x00000000 /* rD result: sext16 */ DATA 0x00000000 /* rD result: sra */ DATA 0x00000000 /* MSR.C: sra */ DATA 0x00000000 /* rD result: src */ DATA 0x00000000 /* MSR.C: src */ DATA 0x00000000 /* rD result: srl */ DATA 0x00000000 /* MSR.C: srl */ L_microblaze_selftest_ldstdata: DATA 0xDEADBEEF /* rD operand */ DATA 0x12345678 /* rD operand */ DATA 0x00000000 /* rD operand */ L_microblaze_selftest_ldstptr: DATA 0 DATA 0 DATA 0 L_microblaze_selftest_barreldata: DATA 0x55555555 /* rA operand */ DATA 16 /* rB operand */ DATA 0x00005555 /* rD result: bsrl */ DATA 0x00005555 /* rD result: bsra */ DATA 0x55550000 /* rD result: bsll */ DATA 0x55540415 /* rD result: bsifi */ DATA 0x00000008 /* rD result: bsefi */ DATA 0xAAAAAAAA /* rA operand */ DATA 1 /* rB operand */ DATA 0x55555555 /* rD result: bsrl */ DATA 0xD5555555 /* rD result: bsra */ DATA 0x55555554 /* rD result: bsll */ DATA 0xAAAA006A /* rD result: bsifi */ DATA 0x00000000 /* rD result: bsefi */ DATA 0xFFFFFFFF /* rA operand */ DATA 25 /* rB operand */ DATA 0x0000007F /* rD result: bsrl */ DATA 0xFFFFFFFF /* rD result: bsra */ DATA 0xFE000000 /* rD result: bsll */ DATA 0xFFFE067F /* rD result: bsifi */ DATA 0x0000000C /* rD result: bsefi */ DATA 0x00000000 /* rA operand */ DATA 10 /* rB operand */ DATA 0x00000000 /* rD result: bsrl */ DATA 0x00000000 /* rD result: bsra */ DATA 0x00000000 /* rD result: bsll */ DATA 0x00000280 /* rD result: bsifi */ DATA 0x00000005 /* rD result: bsefi */ L_microblaze_selftest_muldata: .long 0x55555555 /* rA operand */ .long 0x55555555 /* rB operand */ .long 0x38E38E39 /* rD result: mul */ #ifdef USE_HW_MUL_2 .long 0x1C71C71C /* rD result: mulh */ .long 0x1C71C71C /* rD result: mulhu */ .long 0x1C71C71C /* rD result: mulhsu */ #endif .long 0xAAAAAAAA /* rA operand */ .long 0xAAAAAAAA /* rB operand */ .long 0xE38E38E4 /* rD result: mul */ #ifdef USE_HW_MUL_2 .long 0x1C71C71C /* rD result: mulh */ .long 0x71C71C70 /* rD result: mulhu */ .long 0xC71C71C6 /* rD result: mulhsu */ #endif .long 0xFFFFFFFF /* rA operand */ .long 0xFFFFFFFF /* rB operand */ .long 0x00000001 /* rD result: mul */ #ifdef USE_HW_MUL_2 .long 0x00000000 /* rD result: mulh */ .long 0xFFFFFFFE /* rD result: mulhu */ .long 0xFFFFFFFF /* rD result: mulhsu */ #endif .long 0x00000000 /* rA operand */ .long 0x00000000 /* rB operand */ .long 0x00000000 /* rD result: mul */ #ifdef USE_HW_MUL_2 .long 0x00000000 /* rD result: mulh */ .long 0x00000000 /* rD result: mulhu */ .long 0x00000000 /* rD result: mulhsu */ #endif L_microblaze_selftest_divdata: .long 0x55555555 /* rA operand */ .long 0x55555555 /* rB operand */ .long 0x00000001 /* rD result: div */ .long 0x00000001 /* rD result: divu */ .long 0xAAAAAAAA /* rA operand */ .long 0xAAAAAAAA /* rB operand */ .long 0x00000001 /* rD result: div */ .long 0x00000001 /* rD result: divu */ .long 0xFFFFFFFF /* rA operand */ .long 0xFFFFFFFF /* rB operand */ .long 0x00000001 /* rD result: div */ .long 0x00000001 /* rD result: divu */ .long 0x00000001 /* rA operand */ .long 0x00000000 /* rB operand */ .long 0x00000000 /* rD result: div */ .long 0x00000000 /* rD result: divu */ .align 3 L_microblaze_selftest_pcmpdata: DATA 0x55555555 /* rA operand */ DATA 0x44445555 /* rB operand */ DATA 0x00000003 /* rD result: pcmpbf */ DATA 0x00000000 /* rD result: pcmpeq */ DATA 0x00000001 /* rD result: pcmpne */ DATA 0xAAAAAAAA /* rA operand */ DATA 0xAAAAAAAA /* rB operand */ DATA 0x00000001 /* rD result: pcmpbf */ DATA 0x00000001 /* rD result: pcmpeq */ DATA 0x00000000 /* rD result: pcmpne */ DATA 0xFFFFFFFF /* rA operand */ DATA 0x000000FF /* rB operand */ DATA 0x00000004 /* rD result: pcmpbf */ DATA 0x00000000 /* rD result: pcmpeq */ DATA 0x00000001 /* rD result: pcmpne */ DATA 0x00000000 /* rA operand */ DATA 0xDEADBEEF /* rB operand */ DATA 0x00000000 /* rD result: pcmpbf */ DATA 0x00000000 /* rD result: pcmpeq */ DATA 0x00000001 /* rD result: pcmpne */ L_microblaze_selftest_reorderdata: DATA 0xDEADBEEF /* rD operand */ DATA 0xEFBEADDE /* rD result: swapb */ DATA 0xBEEFDEAD /* rD result: swaph */ DATA 0x00000000 /* rD operand */ DATA 0x00000000 /* rD result: swapb */ DATA 0x00000000 /* rD result: swaph */ /** * @} End of "addtogroup microblaze_pseudo_asm_macro". */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

3,488

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_invalidate_dcache_range.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * * microblaze_invalidate_dcache_range (unsigned int cacheaddr, unsigned int len) * * Invalidate a Dcache range * * Parameters: * 'cacheaddr' - address in the Dcache where invalidation begins * 'len ' - length (in bytes) worth of Dcache to be invalidated * * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #define MB_HAS_WRITEBACK_SET 0 #else #define MB_HAS_WRITEBACK_SET XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #endif .text .globl microblaze_invalidate_dcache_range .ent microblaze_invalidate_dcache_range .align 2 microblaze_invalidate_dcache_range: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) #ifdef MB_VERSION_LT_v720 /* Disable Dcache and interrupts before invalidating */ mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_DCACHE_ENABLE | MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif BEQI r6, L_done /* Skip loop if size is zero */ ADD r6, r5, r6 /* Compute end address */ ADDIK r6, r6, -1 ANDI r6, r6, -(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align end down to cache line */ ANDI r5, r5, -(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align start down to cache line */ #if MB_HAS_WRITEBACK_SET == 0 /* Use a different scheme for MB version < v7.20 or when caches are write-through */ L_start: CMPU r18, r5, r6 /* Are we at the end? */ BLTI r18, L_done wdc r5, r0 #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* Increment the address by 4 */ breai L_start /* Branch to the beginning of the loop */ #else brid L_start /* Branch to the beginning of the loop */ addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* Increment the address by 4 (delay slot) */ #endif #else RSUBK r6, r5, r6 /* r6 will now contain (count of bytes - (4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN)) */ L_start: wdc.clear r5, r6 /* Invalidate the cache line only if the address matches */ #if defined (__arch64__ ) addlik r6, r6, -(XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) beagei r6, L_start #else bneid r6, L_start addik r6, r6, -(XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) #endif #endif L_done: rtsd r15, 8 #ifdef MB_VERSION_LT_v720 /* restore MSR only for MB version < v7.20 */ mts rmsr, r9 #else nop #endif #else rtsd r15, 8 nop #endif .end microblaze_invalidate_dcache_range

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,070

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_enable_icache.S

/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * File : microblaze_enable_icache.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Enable icache on the microblaze. * * ******************************************************************************/ #include "xparameters.h" .text .globl microblaze_enable_icache .ent microblaze_enable_icache .align 2 microblaze_enable_icache: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrset r0, 0x20 #else /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ #Read the MSR register mfs r8, rmsr #Set the interrupt enable bit ori r8, r8, 0x20 #Save the MSR register mts rmsr, r8 #Return rtsd r15, 8 nop #endif /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ .end microblaze_enable_icache

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

2,198

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_init_dcache_range.S

/****************************************************************************** * Copyright (c) 2006 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * microblaze_init_dcache_range (unsigned int cache_start, unsigned int cache_len) * * Invalidate dcache on the microblaze * * Parameters: * 'cache_start' - address in the Dcache where invalidation begins * 'cache_len' - length (in bytes) worth of Dcache to be invalidated * * *******************************************************************************/ #include "xparameters.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif .text .globl microblaze_init_dcache_range .ent microblaze_init_dcache_range .align 2 microblaze_init_dcache_range: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) mfs r9, rmsr /* Disable Dcache and interrupts before invalidating */ andi r10, r9, (~(MICROBLAZE_MSR_DCACHE_ENABLE | MICROBLAZE_MSR_INTR_ENABLE)) mts rmsr, r10 andi r5, r5, -(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align to cache line */ add r6, r5, r6 /* Compute end */ andi r6, r6, -(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align to cache line */ L_start: wdc r5, r0 /* Invalidate the Cache (delay slot) */ cmpu r18, r5, r6 /* Are we at the end ? */ blei r18, L_done brid L_start /* Branch to the beginning of the loop */ addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* Increment the address by 4 (delay slot) */ L_done: rtsd r15, 8 /* Return */ mts rmsr, r9 #else rtsd r15, 8 /* Return */ nop #endif .end microblaze_init_dcache_range

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

2,385

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_invalidate_icache.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * * microblaze_invalidate_icache() * * Invalidate the entire ICache * * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_ICACHE_ENABLE 0x00000020 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_ICACHE_LINE_LEN #define XPAR_MICROBLAZE_ICACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #endif .text .globl microblaze_invalidate_icache .ent microblaze_invalidate_icache .align 2 microblaze_invalidate_icache: #if (XPAR_MICROBLAZE_USE_ICACHE==1) && (XPAR_MICROBLAZE_ALLOW_ICACHE_WR==1) #ifdef MB_VERSION_LT_v720 /* Disable Icache and interrupts before invalidating */ mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_ICACHE_ENABLE | MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif ADDIK r5, r0, XPAR_MICROBLAZE_ICACHE_BASEADDR & (-(4 * XPAR_MICROBLAZE_ICACHE_LINE_LEN)) /* Align to cache line */ ADDIK r6, r5, XPAR_MICROBLAZE_CACHE_BYTE_SIZE & (-(4 * XPAR_MICROBLAZE_ICACHE_LINE_LEN)) /* Compute end */ L_start: wic r5, r0 /* Invalidate the Cache */ CMPU r18, r5, r6 /* Are we at the end? */ BLEI r18, L_done #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN * 4) /* Increment the address by 4 */ breai L_start #else brid L_start /* Branch to the beginning of the loop */ addik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN * 4) /* Increment the address by 4 (delay slot) */ #endif L_done: rtsd r15, 8 /* Return */ #ifdef MB_VERSION_LT_v720 /* restore MSR only for MB version < v7.20 */ mts rmsr, r9 #else nop #endif #else rtsd r15, 8 /* Return */ nop #endif .end microblaze_invalidate_icache

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,575

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_enable_interrupts.S

/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * @file microblaze_enable_interrupts.S * * @addtogroup microblaze_pseudo_asm_macro * @{ * <h2> microblaze_enable_interrupts.S </h2> * - API to Enable Interrupts: void microblaze_enable_interrupts(void) * * This API Enables interrupts on the MicroBlaze processor. When the MicroBlaze * processor starts up, interrupts are disabled. Interrupts must be explicitly * turned on using this function. * * <pre> * * File : microblaze_enable_interrupts.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Enable interrupts on the microblaze. * </pre> * ******************************************************************************/ #include "xparameters.h" .text .globl microblaze_enable_interrupts .ent microblaze_enable_interrupts .align 2 microblaze_enable_interrupts: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrset r0, 0x2 nop #else /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ #Read the MSR register mfs r12, rmsr #Set the interrupt enable bit ori r12, r12, 0x2 #Save the MSR register mts rmsr, r12 #Return rtsd r15, 8 nop #endif /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ .end microblaze_enable_interrupts /** * @} End of "addtogroup microblaze_pseudo_asm_macro". */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

3,540

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_flush_dcache_range.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * microblaze_flush_dcache_range (unsigned int cacheaddr, unsigned int len) * * Flush a L1 DCache range * * Parameters: * 'cacheaddr' - address in the Dcache where the flush begins * 'len ' - length (in bytes) worth of Dcache to be flushed * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #define MB_HAS_WRITEBACK_SET 0 #else #define MB_HAS_WRITEBACK_SET XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #endif .text .globl microblaze_flush_dcache_range .ent microblaze_flush_dcache_range .align 2 microblaze_flush_dcache_range: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) #ifdef MB_VERSION_LT_v720 /* Disable Dcache and interrupts before invalidating */ mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_DCACHE_ENABLE | MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif beqi r6, L_done /* Skip loop if size is zero */ ADD r6, r5, r6 /* Compute end address */ ADDIK r6, r6, -1 ANDI r6, r6, -(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align end down to cache line */ ANDI r5, r5, -(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align start down to cache line */ #if MB_HAS_WRITEBACK_SET == 0 /* Use a different scheme for MB version < v7.20 or when caches are write-through */ L_start: CMPU r18, r5, r6 /* Are we at the end? */ BLTI r18, L_done wdc r5, r0 /* Invalidate the cache line */ #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* Increment the address by 4 */ breai L_start /* Branch to the beginning of the loop */ #else brid L_start /* Branch to the beginning of the loop */ addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* Increment the address by 4 (delay slot) */ #endif #else RSUBK r6, r5, r6 /* r6 will now contain (count of bytes - (4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN)) */ L_start: wdc.flush r5, r6 /* Flush the cache line */ #if defined (__arch64__ ) addlik r6, r6, -(XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) beagei r6, L_start #else bneid r6, L_start addik r6, r6, -(XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) #endif #endif L_done: rtsd r15, 8 #ifdef MB_VERSION_LT_v720 /* restore MSR only for MB version < v7.20 */ mts rmsr, r9 #else nop #endif #else rtsd r15, 8 /* Return */ nop #endif .end microblaze_flush_dcache_range

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,555

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_disable_interrupts.S

/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * @file microblaze_disable_interrupts.S * * @addtogroup microblaze_pseudo_asm_macro * @{ * <h2> microblaze_disable_interrupts.S </h2> * - API to disable Interrupts: void microblaze_disable_interrupts(void) * * This API Disables interrupts on the MicroBlaze processor. It can be * called when entering a critical section of code where a context switch is * undesirable. * * <pre> * File : microblaze_disable_interrupts.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Disable interrupts on the microblaze. * </pre> * ******************************************************************************/ #include "xparameters.h" .text .globl microblaze_disable_interrupts .ent microblaze_disable_interrupts .align 2 microblaze_disable_interrupts: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrclr r0, 0x2 #else /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ #Read the MSR register mfs r12, rmsr #Clear the interrupt enable bit andi r12, r12, ~(0x2) #Save the MSR register mts rmsr, r12 #Return rtsd r15, 8 nop #endif /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ .end microblaze_disable_interrupts /** * @} End of "addtogroup microblaze_pseudo_asm_macro". */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

26,672

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/hw_exception_handler.S

/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * Microblaze HW Exception Handler * - Non self-modifying exception handler for the following exception conditions * - Unalignment * - Instruction bus error * - Data bus error * - Illegal instruction opcode * - Divide-by-zero * - Stack protection violation *******************************************************************************/ #include "microblaze_exceptions_g.h" #include "xparameters.h" #include "microblaze_instructions.h" /* 64-bit definitions */ #if defined (__arch64__) #define INTPTR_DATAITEM .quad #define REGSIZE 8 #define DATAALIGN 4 #else #define INTPTR_DATAITEM .long #define REGSIZE 4 #define DATAALIGN 2 #endif /* 64-bit definitions */ /* Helpful Macros */ #define EX_HANDLER_STACK_SIZ (REGSIZE*21) #define RMSR_OFFSET (20 * REGSIZE) #define R17_OFFSET (0) #define REG_OFFSET(regnum) (REGSIZE * (regnum + 1)) #define NUM_TO_REG(num) r ## num #define R3_TO_STACK(regnum) SI r3, r1, REG_OFFSET(regnum) #define R3_FROM_STACK(regnum) LI r3, r1, REG_OFFSET(regnum) #define PUSH_REG(regnum) SI NUM_TO_REG(regnum), r1, REG_OFFSET(regnum) #define POP_REG(regnum) LI NUM_TO_REG(regnum), r1, REG_OFFSET(regnum) /* Uses r5 */ #define PUSH_MSR \ mfs r5, rmsr; \ swi r5, r1, RMSR_OFFSET; #define PUSH_MSR_AND_ENABLE_EXC \ mfs r5, rmsr; \ swi r5, r1, RMSR_OFFSET; \ ori r5, r5, 0x100; /* Turn ON the EE bit*/ \ mts rmsr, r5; /* Uses r5 */ #define POP_MSR \ lwi r5, r1, RMSR_OFFSET; \ mts rmsr, r5; /* Push r17 */ #define PUSH_R17 SI r17, r1, R17_OFFSET /* Pop r17 */ #define POP_R17 LI r17, r1, R17_OFFSET #define LWREG_NOP \ BRI ex_handler_unhandled; \ nop; #define SWREG_NOP \ BRI ex_handler_unhandled; \ nop; /* r3 is the source */ #define R3_TO_LWREG_V(regnum) \ R3_TO_STACK (regnum); \ BRI ex_handler_done; /* r3 is the source */ #define R3_TO_LWREG(regnum) \ OR NUM_TO_REG (regnum), r0, r3; \ BRI ex_handler_done; /* r3 is the target */ #define SWREG_TO_R3_V(regnum) \ R3_FROM_STACK (regnum); \ BRI ex_sw_tail; /* r3 is the target */ #define SWREG_TO_R3(regnum) \ OR r3, r0, NUM_TO_REG (regnum); \ BRI ex_sw_tail; /* regnum is the source */ #define FP_EX_OPB_SAVE(regnum) \ SI NUM_TO_REG (regnum), r0, mb_fpex_op_b; \ nop; \ BRI handle_fp_ex_opa; /* regnum is the source */ #define FP_EX_OPB_SAVE_V(regnum) \ R3_FROM_STACK (regnum); \ SI r3, r0, mb_fpex_op_b; \ BRI handle_fp_ex_opa; /* regnum is the source */ #define FP_EX_OPA_SAVE(regnum) \ SI NUM_TO_REG (regnum), r0, mb_fpex_op_a; \ nop; \ BRI handle_fp_ex_done; /* regnum is the source */ #define FP_EX_OPA_SAVE_V(regnum) \ R3_FROM_STACK (regnum); \ SI r3, r0, mb_fpex_op_a; \ BRI handle_fp_ex_done; #define FP_EX_UNHANDLED \ BRI fp_ex_unhandled; \ nop; \ nop; /* ESR masks */ #define ESR_EXC_MASK 0x0000001F #define ESR_REG_MASK 0x000003E0 #define ESR_LW_SW_MASK 0x00000400 #define ESR_WORD_MASK 0x00000800 #define ESR_DS_MASK 0x00001000 #define ESR_LONG_MASK 0x00002000 /* Extern declarations */ .extern XNullHandler #ifdef MICROBLAZE_EXCEPTIONS_ENABLED /* If exceptions are enabled in the processor */ /* * hw_exception_handler - Handler for unaligned exceptions * Exception handler notes: * - Does not handle exceptions other than unaligned exceptions * - Does not handle exceptions during load into r17, r1, r0. * - Does not handle exceptions during store from r17 (cannot be done) and r1 (slows down common case) * * Relevant register structures * * EAR - |----|----|----|----|----|----|----|----| * - < ## 32 or 64 bit faulting address ## > * * ESR - |----|----|----|----|----| - | - |-----|-----| * - W S REG EXC * * * STACK FRAME STRUCTURE * --------------------- * * +-------------+ + 0 * | r17 | * +-------------+ + 4 (32-bit) + 8 (64-bit) * | Args for | * | next func | * +-------------+ + 8 (32-bit) + 16 (64-bit) * | r1 | * | . | * | . | * | . | * | . | * | r18 | * +-------------+ + 80 (32-bit) + 160 (64-bit) * | MSR | * +-------------+ + 84 (32-bit) + 168 (64-bit) * | . | * | . | */ .global _hw_exception_handler .section .text .align 2 .ent _hw_exception_handler .type _hw_exception_handler, @function _hw_exception_handler: #if defined(XPAR_MICROBLAZE_USE_STACK_PROTECTION) && (XPAR_MICROBLAZE_USE_STACK_PROTECTION == 1) /* Immediately halt for stack protection violation exception without using any stack */ SI r3, r0, mb_sp_save_r3; /* Save temporary register */ mfs r3, resr; /* Extract ESR[DS] */ andi r3, r3, ESR_EXC_MASK; xori r3, r3, 0x7; /* Check for stack protection violation */ BNEI r3, ex_handler_not_sp_violation; ex_handler_sp_violation: bri 0; /* Halt here if stack protection violation */ ex_handler_not_sp_violation: LI r3, r0, mb_sp_save_r3; /* Restore temporary register */ #endif /* defined(XPAR_MICROBLAZE_USE_STACK_PROTECTION) && (XPAR_MICROBLAZE_USE_STACK_PROTECTION == 1) */ ADDIK r1, r1, -(EX_HANDLER_STACK_SIZ); /* Create stack frame */ PUSH_REG(3); PUSH_REG(4); PUSH_REG(5); PUSH_REG(6); #ifdef MICROBLAZE_CAN_HANDLE_EXCEPTIONS_IN_DELAY_SLOTS mfs r6, resr; andi r6, r6, ESR_DS_MASK; BEQI r6, ex_handler_no_ds; mfs r17, rbtr; ex_handler_no_ds: #endif PUSH_R17; PUSH_MSR_AND_ENABLE_EXC; /* Exceptions enabled here. This will allow nested exceptions */ mfs r3, resr; andi r5, r3, ESR_EXC_MASK; /* Extract ESR[EXC] */ #ifndef NO_UNALIGNED_EXCEPTIONS xori r6, r5, 1; /* 00001 = Unaligned Exception */ BNEI r6, handle_ex_regular; ADDIK r4, r0, MB_ExceptionVectorTable; /* Check if user has registered an unaligned exception handler */ #if defined (__arch64__) LI r4, r4, 16; #else LI r4, r4, 8; #endif ADDIK r6, r0, XNullHandler; /* If exceptionvectortable entry is still XNullHandler, use */ XOR r6, r4, r6; /* the default exception handler */ BEQI r6, handle_unaligned_ex ; handle_ex_regular: #endif /* ! NO_UNALIGNED_EXCEPTIONS */ #if defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) xori r6, r5, 6; /* 00110 = FPU exception */ BEQI r6, handle_fp_ex; /* Go and decode the FP exception */ #endif /* defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) */ handle_other_ex: /* Handle Other exceptions here */ ori r6, r0, 20; cmp r6, r5, r6; /* >= 20 are exceptions we do not handle. */ BLEI r6, ex_handler_unhandled; ori r6, r0, 7; cmp r6, r5, r6; /* Convert MMU exception indices into an ordinal of 7 */ BGTI r6, handle_other_ex_tail; ori r5, r0, 0x7; handle_other_ex_tail: PUSH_REG(7); /* Save other volatiles before we make procedure calls below */ PUSH_REG(8); PUSH_REG(9); PUSH_REG(10); PUSH_REG(11); PUSH_REG(12); PUSH_REG(15); PUSH_REG(18); ADDIK r4, r0, MB_ExceptionVectorTable; /* Load the Exception vector table base address */ ADDK r7, r5, r5; /* Calculate exception vector offset = r5 * 8 (32-bit) */ ADDK r7, r7, r7; ADDK r7, r7, r7; #if defined (__arch64__) ADDK r7, r7, r7; /* or r5 * 16 (64-bit) */ #endif ADDK r7, r7, r4; /* Get pointer to exception vector */ LI r5, r7, REGSIZE; /* Load argument to exception handler from table */ LOAD r7, r7, r0; /* Load vector itself here */ brald r15, r7; /* Branch to handler */ nop; POP_REG(7); /* Restore other volatiles */ POP_REG(8); POP_REG(9); POP_REG(10); POP_REG(11); POP_REG(12); POP_REG(15); POP_REG(18); BRI ex_handler_done; /* Complete exception handling */ #ifndef NO_UNALIGNED_EXCEPTIONS handle_unaligned_ex: andi r6, r3, ESR_REG_MASK; /* Mask and extract the register operand */ srl r6, r6; /* r6 >> 5 */ srl r6, r6; srl r6, r6; srl r6, r6; srl r6, r6; sbi r6, r0, ex_reg_op; /* Store the register operand in a temporary location */ mfs r4, rear; andi r6, r3, ESR_LW_SW_MASK; /* Extract ESR[S] */ BNEI r6, ex_sw; #if defined (__arch64__) ex_ll: andi r6, r3, ESR_LONG_MASK; /* Extract ESR[L] */ BEQI r6, ex_lw; lbui r5, r4, 0; /* Exception address in r4 */ sbi r5, r0, ex_tmp_data_loc_0; /* Load a long, byte-by-byte from destination address and save it in tmp space */ lbui r5, r4, 1; sbi r5, r0, ex_tmp_data_loc_1; lbui r5, r4, 2; sbi r5, r0, ex_tmp_data_loc_2; lbui r5, r4, 3; sbi r5, r0, ex_tmp_data_loc_3; lbui r5, r4, 4; sbi r5, r0, ex_tmp_data_loc_4; lbui r5, r4, 5; sbi r5, r0, ex_tmp_data_loc_5; lbui r5, r4, 6; sbi r5, r0, ex_tmp_data_loc_6; lbui r5, r4, 7; sbi r5, r0, ex_tmp_data_loc_7; lli r3, r0, ex_tmp_data_loc_0; /* Get the destination register value into r3 */ BRI ex_lw_tail; #endif ex_lw: andi r6, r3, ESR_WORD_MASK; /* Extract ESR[W] */ BEQI r6, ex_lhw; lbui r5, r4, 0; /* Exception address in r4 */ sbi r5, r0, ex_tmp_data_loc_0; /* Load a word, byte-by-byte from destination address and save it in tmp space */ lbui r5, r4, 1; sbi r5, r0, ex_tmp_data_loc_1; lbui r5, r4, 2; sbi r5, r0, ex_tmp_data_loc_2; lbui r5, r4, 3; sbi r5, r0, ex_tmp_data_loc_3; lwi r3, r0, ex_tmp_data_loc_0; /* Get the destination register value into r3 */ BRI ex_lw_tail; ex_lhw: lbui r5, r4, 0; /* Exception address in r4 */ sbi r5, r0, ex_tmp_data_loc_0; /* Load a half-word, byte-by-byte from destination address and save it in tmp space */ lbui r5, r4, 1; sbi r5, r0, ex_tmp_data_loc_1; lhui r3, r0, ex_tmp_data_loc_0; /* Get the destination register value into r3 */ ex_lw_tail: lbui r5, r0, ex_reg_op; /* Get the destination register number into r5 */ ADDIK r6, r0, lw_table; /* Form load_word jump table offset (lw_table + (8 * regnum)) */ ADDK r5, r5, r5; ADDK r5, r5, r5; ADDK r5, r5, r5; ADDK r5, r5, r6; bra r5; ex_lw_end: /* Exception handling of load word, ends */ ex_sw: lbui r5, r0, ex_reg_op; /* Get the destination register number into r5 */ ADDIK r6, r0, sw_table; /* Form store_word jump table offset (sw_table + (8 * regnum)) */ ADDK r5, r5, r5; ADDK r5, r5, r5; ADDK r5, r5, r5; ADDK r5, r5, r6; bra r5; ex_sw_tail: #if defined (__arch64__) ex_sl: mfs r6, resr; andi r6, r6, ESR_LONG_MASK; /* Extract ESR[L] */ BEQI r6, ex_not_sl; sli r3, r0, ex_tmp_data_loc_0; lbui r3, r0, ex_tmp_data_loc_0; /* Store the long, byte-by-byte into destination address */ sbi r3, r4, 0; lbui r3, r0, ex_tmp_data_loc_1; sbi r3, r4, 1; lbui r3, r0, ex_tmp_data_loc_2; sbi r3, r4, 2; lbui r3, r0, ex_tmp_data_loc_3; sbi r3, r4, 3; lbui r3, r0, ex_tmp_data_loc_4; sbi r3, r4, 4; lbui r3, r0, ex_tmp_data_loc_5; sbi r3, r4, 5; lbui r3, r0, ex_tmp_data_loc_6; sbi r3, r4, 6; lbui r3, r0, ex_tmp_data_loc_7; sbi r3, r4, 7; BRI ex_handler_done; ex_not_sl: #endif mfs r6, resr; andi r6, r6, ESR_WORD_MASK; /* Extract ESR[W] */ BEQI r6, ex_shw; swi r3, r0, ex_tmp_data_loc_0; lbui r3, r0, ex_tmp_data_loc_0; /* Store the word, byte-by-byte into destination address */ sbi r3, r4, 0; lbui r3, r0, ex_tmp_data_loc_1; sbi r3, r4, 1; lbui r3, r0, ex_tmp_data_loc_2; sbi r3, r4, 2; lbui r3, r0, ex_tmp_data_loc_3; sbi r3, r4, 3; BRI ex_handler_done; ex_shw: swi r3, r0, ex_tmp_data_loc_0; /* Store the lower half-word, byte-by-byte into destination address */ #ifdef __LITTLE_ENDIAN__ lbui r3, r0, ex_tmp_data_loc_0; #else lbui r3, r0, ex_tmp_data_loc_2; #endif sbi r3, r4, 0; #ifdef __LITTLE_ENDIAN__ lbui r3, r0, ex_tmp_data_loc_1; #else lbui r3, r0, ex_tmp_data_loc_3; #endif sbi r3, r4, 1; ex_sw_end: /* Exception handling of store word, ends. */ BRI ex_handler_done; #endif /* !NO_UNALIGNED_EXCEPTIONS */ #if defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) handle_fp_ex: ADDIK r3, r17, -4; /* r17 contains (addr of exception causing FP instruction + 4) */ lw r4, r0, r3; /* We might find ourselves in a spot here. Unguaranteed load */ handle_fp_ex_opb: ADDIK r6, r0, fp_table_opb; /* Decode opB and store its value in mb_fpex_op_b */ srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; andi r3, r4, 0x1F; ADDK r3, r3, r3; /* Calculate (fp_table_opb + (regno * 12)) in r5 */ ADDK r3, r3, r3; ADDK r5, r3, r3; ADDK r5, r5, r3; ADDK r5, r5, r6; bra r5; handle_fp_ex_opa: ADDIK r6, r0, fp_table_opa; /* Decode opA and store its value in mb_fpex_op_a */ srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; andi r3, r4, 0x1F; ADDK r3, r3, r3; /* Calculate (fp_table_opb + (regno * 12)) in r5 */ ADDK r3, r3, r3; ADDK r5, r3, r3; ADDK r5, r5, r3; ADDK r5, r5, r6; bra r5; handle_fp_ex_done: ori r5, r0, 6; /* Set exception number back to 6 */ BRI handle_other_ex_tail; fp_ex_unhandled: bri 0; #endif /* defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) */ ex_handler_done: POP_R17; POP_MSR; POP_REG(3); POP_REG(4); POP_REG(5); POP_REG(6); ADDIK r1, r1, (EX_HANDLER_STACK_SIZ); /* Restore stack frame */ rted r17, 0 nop ex_handler_unhandled: bri 0 /* UNHANDLED. TRAP HERE */ .end _hw_exception_handler #ifndef NO_UNALIGNED_EXCEPTIONS /* * hw_exception_handler Jump Table * - Contains code snippets for each register that caused the unaligned exception. * - Hence exception handler is NOT self-modifying * - Separate table for load exceptions and store exceptions. * - Each table is of size: (8 * 32) = 256 bytes */ .section .text .align 4 lw_table: lw_r0: R3_TO_LWREG (0); lw_r1: LWREG_NOP; lw_r2: R3_TO_LWREG (2); lw_r3: R3_TO_LWREG_V (3); lw_r4: R3_TO_LWREG_V (4); lw_r5: R3_TO_LWREG_V (5); lw_r6: R3_TO_LWREG_V (6); lw_r7: R3_TO_LWREG (7); lw_r8: R3_TO_LWREG (8); lw_r9: R3_TO_LWREG (9); lw_r10: R3_TO_LWREG (10); lw_r11: R3_TO_LWREG (11); lw_r12: R3_TO_LWREG (12); lw_r13: R3_TO_LWREG (13); lw_r14: R3_TO_LWREG (14); lw_r15: R3_TO_LWREG (15); lw_r16: R3_TO_LWREG (16); lw_r17: LWREG_NOP; lw_r18: R3_TO_LWREG (18); lw_r19: R3_TO_LWREG (19); lw_r20: R3_TO_LWREG (20); lw_r21: R3_TO_LWREG (21); lw_r22: R3_TO_LWREG (22); lw_r23: R3_TO_LWREG (23); lw_r24: R3_TO_LWREG (24); lw_r25: R3_TO_LWREG (25); lw_r26: R3_TO_LWREG (26); lw_r27: R3_TO_LWREG (27); lw_r28: R3_TO_LWREG (28); lw_r29: R3_TO_LWREG (29); lw_r30: R3_TO_LWREG (30); lw_r31: R3_TO_LWREG (31); sw_table: sw_r0: SWREG_TO_R3 (0); sw_r1: SWREG_NOP; sw_r2: SWREG_TO_R3 (2); sw_r3: SWREG_TO_R3_V (3); sw_r4: SWREG_TO_R3_V (4); sw_r5: SWREG_TO_R3_V (5); sw_r6: SWREG_TO_R3_V (6); sw_r7: SWREG_TO_R3 (7); sw_r8: SWREG_TO_R3 (8); sw_r9: SWREG_TO_R3 (9); sw_r10: SWREG_TO_R3 (10); sw_r11: SWREG_TO_R3 (11); sw_r12: SWREG_TO_R3 (12); sw_r13: SWREG_TO_R3 (13); sw_r14: SWREG_TO_R3 (14); sw_r15: SWREG_TO_R3 (15); sw_r16: SWREG_TO_R3 (16); sw_r17: SWREG_NOP; sw_r18: SWREG_TO_R3 (18); sw_r19: SWREG_TO_R3 (19); sw_r20: SWREG_TO_R3 (20); sw_r21: SWREG_TO_R3 (21); sw_r22: SWREG_TO_R3 (22); sw_r23: SWREG_TO_R3 (23); sw_r24: SWREG_TO_R3 (24); sw_r25: SWREG_TO_R3 (25); sw_r26: SWREG_TO_R3 (26); sw_r27: SWREG_TO_R3 (27); sw_r28: SWREG_TO_R3 (28); sw_r29: SWREG_TO_R3 (29); sw_r30: SWREG_TO_R3 (30); sw_r31: SWREG_TO_R3 (31); /* Temporary data structures used in the handler */ .section .data .align DATAALIGN ex_tmp_data_loc_0: .byte 0 ex_tmp_data_loc_1: .byte 0 ex_tmp_data_loc_2: .byte 0 ex_tmp_data_loc_3: .byte 0 #if defined (__arch64__) ex_tmp_data_loc_4: .byte 0 ex_tmp_data_loc_5: .byte 0 ex_tmp_data_loc_6: .byte 0 ex_tmp_data_loc_7: .byte 0 #endif ex_reg_op: .byte 0 #endif /* ! NO_UNALIGNED_EXCEPTIONS */ #if defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) /* * FP exception decode jump table. * - Contains code snippets for each register that could have been a source operand for an excepting FP instruction * - Hence exception handler is NOT self-modifying * - Separate table for opA and opB * - Each table is of size: (12 * 32) = 384 bytes */ .section .text .align 4 fp_table_opa: opa_r0: FP_EX_OPA_SAVE (0); opa_r1: FP_EX_UNHANDLED; opa_r2: FP_EX_OPA_SAVE (2); opa_r3: FP_EX_OPA_SAVE_V (3); opa_r4: FP_EX_OPA_SAVE_V (4); opa_r5: FP_EX_OPA_SAVE_V (5); opa_r6: FP_EX_OPA_SAVE_V (6); opa_r7: FP_EX_OPA_SAVE (7); opa_r8: FP_EX_OPA_SAVE (8); opa_r9: FP_EX_OPA_SAVE (9); opa_r10: FP_EX_OPA_SAVE (10); opa_r11: FP_EX_OPA_SAVE (11); opa_r12: FP_EX_OPA_SAVE (12); opa_r13: FP_EX_OPA_SAVE (13); opa_r14: FP_EX_UNHANDLED; opa_r15: FP_EX_UNHANDLED; opa_r16: FP_EX_UNHANDLED; opa_r17: FP_EX_UNHANDLED; opa_r18: FP_EX_OPA_SAVE (18); opa_r19: FP_EX_OPA_SAVE (19); opa_r20: FP_EX_OPA_SAVE (20); opa_r21: FP_EX_OPA_SAVE (21); opa_r22: FP_EX_OPA_SAVE (22); opa_r23: FP_EX_OPA_SAVE (23); opa_r24: FP_EX_OPA_SAVE (24); opa_r25: FP_EX_OPA_SAVE (25); opa_r26: FP_EX_OPA_SAVE (26); opa_r27: FP_EX_OPA_SAVE (27); opa_r28: FP_EX_OPA_SAVE (28); opa_r29: FP_EX_OPA_SAVE (29); opa_r30: FP_EX_OPA_SAVE (30); opa_r31: FP_EX_OPA_SAVE (31); fp_table_opb: opb_r0: FP_EX_OPB_SAVE (0); opb_r1: FP_EX_UNHANDLED; opb_r2: FP_EX_OPB_SAVE (2); opb_r3: FP_EX_OPB_SAVE_V (3); opb_r4: FP_EX_OPB_SAVE_V (4); opb_r5: FP_EX_OPB_SAVE_V (5); opb_r6: FP_EX_OPB_SAVE_V (6); opb_r7: FP_EX_OPB_SAVE (7); opb_r8: FP_EX_OPB_SAVE (8); opb_r9: FP_EX_OPB_SAVE (9); opb_r10: FP_EX_OPB_SAVE (10); opb_r11: FP_EX_OPB_SAVE (11); opb_r12: FP_EX_OPB_SAVE (12); opb_r13: FP_EX_OPB_SAVE (13); opb_r14: FP_EX_UNHANDLED; opb_r15: FP_EX_UNHANDLED; opb_r16: FP_EX_UNHANDLED; opb_r17: FP_EX_UNHANDLED; opb_r18: FP_EX_OPB_SAVE (18); opb_r19: FP_EX_OPB_SAVE (19); opb_r20: FP_EX_OPB_SAVE (20); opb_r21: FP_EX_OPB_SAVE (21); opb_r22: FP_EX_OPB_SAVE (22); opb_r23: FP_EX_OPB_SAVE (23); opb_r24: FP_EX_OPB_SAVE (24); opb_r25: FP_EX_OPB_SAVE (25); opb_r26: FP_EX_OPB_SAVE (26); opb_r27: FP_EX_OPB_SAVE (27); opb_r28: FP_EX_OPB_SAVE (28); opb_r29: FP_EX_OPB_SAVE (29); opb_r30: FP_EX_OPB_SAVE (30); opb_r31: FP_EX_OPB_SAVE (31); #endif /* defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) */ #if defined(MICROBLAZE_FP_EXCEPTION_ENABLED) && defined(MICROBLAZE_FP_EXCEPTION_DECODE) /* This is where we store the opA and opB of the last excepting FP instruction */ .section .data .align DATAALIGN .global mb_fpex_op_a .global mb_fpex_op_b mb_fpex_op_a: INTPTR_DATAITEM 0 mb_fpex_op_b: INTPTR_DATAITEM 0 #endif /* defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) */ #if defined(XPAR_MICROBLAZE_USE_STACK_PROTECTION) && (XPAR_MICROBLAZE_USE_STACK_PROTECTION == 1) /* This is where we store the register used to check which exception occurred */ .section .data .align DATAALIGN mb_sp_save_r3: INTPTR_DATAITEM 0 #endif /* defined(XPAR_MICROBLAZE_USE_STACK_PROTECTION) && (XPAR_MICROBLAZE_USE_STACK_PROTECTION == 1) */ /* The exception vector table */ .section .data .align DATAALIGN .global MB_ExceptionVectorTable MB_ExceptionVectorTable: INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 0 /* -- FSL Exception -- */ INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 1 /* -- Unaligned Access Exception -- */ INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 2 /* -- Illegal Opcode Exception -- */ INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 3 /* -- Instruction Bus Exception -- */ INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 4 /* -- Data Bus Exception -- */ INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 5 /* -- Div-by-0 Exception -- */ INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 6 /* -- FPU Exception -- */ INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 7 /* -- MMU Exceptions -- */ #else /* Dummy exception handler, in case exceptions are not present in the processor */ .global _hw_exception_handler .section .text .align 2 .ent _hw_exception_handler _hw_exception_handler: bri 0; .end _hw_exception_handler #endif /* MICROBLAZE_EXCEPTIONS_ENABLED */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

2,550

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_update_dcache.S

/****************************************************************************** * Copyright (c) 2006 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * * File : microblaze_update_dcache.s * Date : 2003, September 24 * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Update dcache on the microblaze. * Takes in three parameters * r5 : Cache Tag Line * r6 : Cache Data * r7 : Lock/Valid information * Bit 30 is Lock [ 1 indicates locked ] * Bit 31 is Valid [ 1 indicates valid ] * * -------------------------------------------------------------- * | Lock | Valid | Effect * -------------------------------------------------------------- * | 0 | 0 | Invalidate Cache * | 0 | 1 | Valid, but unlocked cacheline * | 1 | 0 | Invalidate Cache, No effect of lock * | 1 | 1 | Valid cache. Locked to a * | | | particular address * -------------------------------------------------------------- * * **********************************************************************************/ #include "xparameters.h" #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif .text .globl microblaze_update_dcache .ent microblaze_update_dcache .align 2 microblaze_update_dcache: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) #if XPAR_MICROBLAZE_DCACHE_LINE_LEN == 1 /* Read the MSR register into a temp register */ mfs r18, rmsr /* Clear the dcache enable bit to disable the cache Register r10,r18 are volatile registers and hence do not need to be saved before use */ andi r10, r18, ~128 mts rmsr, r10 /* Update the lock and valid info */ andi r5, r5, 0xfffffffc or r5, r5, r7 /* Update dcache */ wdc r5, r6 /* Return */ rtsd r15, 8 mts rmsr, r18 #else /* The only valid usage of this routine for larger cache line lengths is to invalidate a data cache line So call microblaze_init_dcache_range appropriately to do the job */ brid microblaze_init_dcache_range addik r6, r0, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* We don't have a return instruction here. This is tail call optimization :) */ #endif /* XPAR_MICROBLAZE_DCACHE_LINE_LEN == 1 */ #else rtsd r15, 8 nop #endif .end microblaze_update_dcache

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,044

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_disable_icache.S

/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * File : microblaze_disable_icache.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Disable L1 icache on the microblaze. * * ******************************************************************************/ #include "xparameters.h" .text .globl microblaze_disable_icache .ent microblaze_disable_icache .align 2 microblaze_disable_icache: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrclr r0, 0x20 #else /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ #Read the MSR register mfs r8, rmsr #Clear the icache enable bit andi r8, r8, ~(0x20) #Save the MSR register mts rmsr, r8 #Return rtsd r15, 8 nop #endif .end microblaze_disable_icache

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,676

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_disable_dcache.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * File : microblaze_disable_dcache.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Disable the L1 dcache on the microblaze. * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" .text .globl microblaze_disable_dcache .ent microblaze_disable_dcache .align 2 microblaze_disable_dcache: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 #if XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 ADDIK r1, r1, -8 SI r15, r1, 0 BRLID r15, microblaze_flush_dcache /* microblaze_flush_dcache does not use r1*/ nop LI r15, r1, 0 ADDIK r1, r1, 8 #endif /* XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 */ rtsd r15, 8 msrclr r0, 0x80 #else /* XPAR_MICROBLAZE_USE_MSR_INSTR == 1 */ ADDIK r1, r1, -8 #if XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 SI r15, r1, 0 BRLID r15, microblaze_flush_dcache nop #endif /* XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 */ mfs r11, rmsr andi r11, r11, ~(0x80) mts rmsr, r11 #if XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 LI r15, r1, 0 #endif /* XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 */ ADDIK r1, r1, 8 rtsd r15, 8 nop #endif /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ .end microblaze_disable_dcache

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,428

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze_invalidate_cache_ext.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * microblaze_invalidate_cache_ext() * *Invalidate the entire L2 Cache * * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN 16 #define CACHEABLE_REGION_SIZE (XPAR_MICROBLAZE_DCACHE_HIGHADDR - XPAR_MICROBLAZE_DCACHE_BASEADDR) .text .globl microblaze_invalidate_cache_ext .ent microblaze_invalidate_cache_ext .align 2 microblaze_invalidate_cache_ext: #if ((XPAR_MICROBLAZE_INTERCONNECT==3) && (XPAR_MICROBLAZE_USE_DCACHE==1)) ADDIK r5, r0, XPAR_MICROBLAZE_DCACHE_BASEADDR & (-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN)) ADDIK r6, r0, CACHEABLE_REGION_SIZE-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) ANDI r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) Loop_start: wdc.ext.clear r5, r6 #if defined (__arch64__ ) addlik r6, r6,-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) beagei r6, Loop_start #else bgtid r6,Loop_start addik r6, r6,-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) #endif #endif rtsd r15, 8 nop .end microblaze_invalidate_cache_ext

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

5,784

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_scrub.S

/****************************************************************************** * Copyright (c) 2012 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * microblaze_scrub () * * Scrub LMB memory and all internal BRAMs (data cache, instruction cache, * MMU UTLB and branch target cache) in MicroBlaze to reduce the possibility * of an uncorrectable error when fault tolerance support is enabled. * * This routine assumes that the processor is in privileged mode when it is * called, if the MMU is enabled. * * Call this routine regularly from a timer interrupt. * * Parameters: * None * * *******************************************************************************/ #include "xparameters.h" /* Define if fault tolerance is used */ #ifdef XPAR_MICROBLAZE_FAULT_TOLERANT #if XPAR_MICROBLAZE_FAULT_TOLERANT > 0 #define FAULT_TOLERANT #endif #endif /* Define if LMB is used and can be scrubbed */ #if defined(XPAR_MICROBLAZE_D_LMB) && \ defined(XPAR_DLMB_CNTLR_BASEADDR) && \ defined(XPAR_DLMB_CNTLR_HIGHADDR) #if XPAR_MICROBLAZE_D_LMB == 1 #define HAS_SCRUBBABLE_LMB #define DLMB_MASK (XPAR_DLMB_CNTLR_HIGHADDR - XPAR_DLMB_CNTLR_BASEADDR) #endif #endif /* Set default cache line lengths */ #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 4 #endif #ifndef XPAR_MICROBLAZE_ICACHE_LINE_LEN #define XPAR_MICROBLAZE_ICACHE_LINE_LEN 4 #endif /* Define if internal Data Cache BRAMs are used */ #if defined(XPAR_MICROBLAZE_USE_DCACHE) && defined(XPAR_MICROBLAZE_DCACHE_BYTE_SIZE) #if XPAR_MICROBLAZE_USE_DCACHE == 1 && XPAR_MICROBLAZE_DCACHE_BYTE_SIZE > 1024 #define HAS_BRAM_DCACHE #define DCACHE_INCREMENT (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) #define DCACHE_MASK (XPAR_MICROBLAZE_DCACHE_BYTE_SIZE - 1) #endif #endif /* Define if internal Instruction Cache BRAMs are used */ #if defined(XPAR_MICROBLAZE_USE_ICACHE) && defined(XPAR_MICROBLAZE_CACHE_BYTE_SIZE) #if XPAR_MICROBLAZE_USE_ICACHE == 1 && XPAR_MICROBLAZE_CACHE_BYTE_SIZE > 1024 #define HAS_BRAM_ICACHE #define ICACHE_INCREMENT (XPAR_MICROBLAZE_ICACHE_LINE_LEN * 4) #define ICACHE_MASK (XPAR_MICROBLAZE_CACHE_BYTE_SIZE - 1) #endif #endif /* Define if internal MMU UTLB BRAM is used */ #ifdef XPAR_MICROBLAZE_USE_MMU #if XPAR_MICROBLAZE_USE_MMU > 1 #define HAS_BRAM_MMU_UTLB #endif #endif /* Define if internal BTC BRAM is used, and match BTC clear to a complete cache scrub */ #if defined(XPAR_MICROBLAZE_USE_BRANCH_TARGET_CACHE) && \ defined(XPAR_MICROBLAZE_BRANCH_TARGET_CACHE_SIZE) #if XPAR_MICROBLAZE_USE_BRANCH_TARGET_CACHE == 1 #if XPAR_MICROBLAZE_BRANCH_TARGET_CACHE_SIZE == 0 || \ XPAR_MICROBLAZE_BRANCH_TARGET_CACHE_SIZE > 4 #define HAS_BRAM_BRANCH_TARGET_CACHE #ifdef HAS_BRAM_DCACHE #define BTC_MASK_D (XPAR_MICROBLAZE_DCACHE_BYTE_SIZE/DCACHE_INCREMENT-1) #else #define BTC_MASK_D 256 #endif #ifdef HAS_BRAM_ICACHE #define BTC_MASK_I (XPAR_MICROBLAZE_CACHE_BYTE_SIZE/ICACHE_INCREMENT-1) #else #define BTC_MASK_I 256 #endif #if BTC_MASK_D > BTC_MASK_I #define BTC_MASK BTC_MASK_D #else #define BTC_MASK BTC_MASK_I #endif #endif #endif #endif /* Define index offsets to persistent data used by this routine */ #define DLMB_INDEX_OFFSET 0 #define DCACHE_INDEX_OFFSET 4 #define ICACHE_INDEX_OFFSET 8 #define MMU_INDEX_OFFSET 12 #define BTC_CALL_COUNT_OFFSET 16 .text .globl microblaze_scrub .ent microblaze_scrub .align 2 microblaze_scrub: #ifdef FAULT_TOLERANT la r6, r0, L_persistent_data /* Get pointer to data */ #ifdef HAS_SCRUBBABLE_LMB L_dlmb: lwi r5, r6, DLMB_INDEX_OFFSET /* Get dlmb index */ lw r7, r5, r0 /* Load and store */ sw r7, r5, r0 addik r5, r5, 4 /* Increment and save dlmb index */ andi r5, r5, DLMB_MASK swi r5, r6, DLMB_INDEX_OFFSET #endif /* HAS_SCRUBBABLE_LMB */ #ifdef HAS_BRAM_DCACHE L_dcache: lwi r5, r6, DCACHE_INDEX_OFFSET /* Get dcache line index */ wdc r5, r0 /* Invalidate data cache line */ addik r5, r5, DCACHE_INCREMENT /* Increment and save entry index */ andi r5, r5, DCACHE_MASK swi r5, r6, DCACHE_INDEX_OFFSET #endif /* HAS_BRAM_DCACHE */ #ifdef HAS_BRAM_ICACHE L_icache: lwi r5, r6, ICACHE_INDEX_OFFSET /* Get icache line index */ wic r5, r0 /* Invalidate data cache line */ addik r5, r5, ICACHE_INCREMENT /* Increment and save entry index */ andi r5, r5, ICACHE_MASK swi r5, r6, ICACHE_INDEX_OFFSET #endif /* HAS_BRAM_ICACHE */ #ifdef HAS_BRAM_MMU_UTLB L_mmu: lwi r5, r6, MMU_INDEX_OFFSET /* Get UTLB entry index */ mts rtlbx, r5 /* Access next entry in UTLB */ mts rtlbhi, r0 /* Clear the UTLB entry */ addik r5, r5, 1 /* Increment and save entry index */ andi r5, r5, 0x3F swi r5, r6, MMU_INDEX_OFFSET #endif /* HAS_BRAM_MMU_UTLB */ #ifdef HAS_BRAM_BRANCH_TARGET_CACHE L_btc: lwi r5, r6, BTC_CALL_COUNT_OFFSET /* Get BTC call count offset */ addik r5, r5, 1 /* Increment and save call count */ andi r5, r5, BTC_MASK swi r5, r6, BTC_CALL_COUNT_OFFSET bnei r5, L_skip_btc_scrub /* Skip scrub unless count wrap */ bri 4 /* Clear branch target cache */ L_skip_btc_scrub: #endif /* HAS_BRAM_BRANCH_TARGET_CACHE */ #endif /* FAULT_TOLERANT */ L_done: rtsd r15, 8 /* Return */ nop .end microblaze_scrub /* Persistent data used by this routine */ .data .align 2 L_persistent_data: .long 0 /* dlmb index */ .long 0 /* dcache index */ .long 0 /* icache index */ .long 0 /* mmu entry index */ .long 0 /* btc call count */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,396

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_flush_cache_ext.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * microblaze_flush_cache_ext() * * Flush the entire L2 Cache * * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN 16 #define CACHEABLE_REGION_SIZE (XPAR_MICROBLAZE_DCACHE_HIGHADDR - XPAR_MICROBLAZE_DCACHE_BASEADDR) .text .globl microblaze_flush_cache_ext .ent microblaze_flush_cache_ext .align 2 microblaze_flush_cache_ext: #if ((XPAR_MICROBLAZE_INTERCONNECT==3) && (XPAR_MICROBLAZE_USE_DCACHE==1)) ADDIK r5, r0, XPAR_MICROBLAZE_DCACHE_BASEADDR & (-(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN)) ADDIK r6, r0, CACHEABLE_REGION_SIZE-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) ANDI r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) Loop_start: wdc.ext.flush r5, r6 #if defined (__arch64__) addlik r6, r6,-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) beagei r6, Loop_start #else bgtid r6,Loop_start addik r6, r6,-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) #endif #endif rtsd r15, 8 nop .end microblaze_flush_cache_ext

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,519

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_invalidate_cache_ext_range.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * microblaze_invalidate_cache_ext_range (unsigned int cacheaddr, unsigned int len) * *Invalidate an L2 cache range * *Parameters: * 'cacheaddr' - address in the L2 cache where invalidation begins * 'len ' - length (in bytes) worth of Dcache to be invalidated * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN 16 .text .globl microblaze_invalidate_cache_ext_range .ent microblaze_invalidate_cache_ext_range .align 2 microblaze_invalidate_cache_ext_range: #if ((XPAR_MICROBLAZE_INTERCONNECT==3) && (XPAR_MICROBLAZE_USE_DCACHE==1)) beqi r6, Loop_done ADD r6, r5, r6 ADDIK r6, r6, -1 ANDI r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) ANDI r5, r5, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) RSUBK r6, r5, r6 Loop_start: wdc.ext.clear r5, r6 #if defined (__arch64__ ) addlik r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) beagei r6, Loop_start #else bneid r6, Loop_start addik r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) #endif Loop_done: #endif rtsd r15, 8 nop .end microblaze_invalidate_cache_ext_range

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

2,555

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_update_icache.S

/****************************************************************************** * Copyright (c) 2006 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * File : microblaze_update_icache.s * Date : 2003, September 24 * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Update icache on the microblaze. * Takes in three parameters * r5 : Cache Tag Line * r6 : Cache Data * r7 : Lock/Valid information * Bit 30 is Lock [ 1 indicates locked ] * Bit 31 is Valid [ 1 indicates valid ] * * -------------------------------------------------------------- * | Lock | Valid | Effect * -------------------------------------------------------------- * | 0 | 0 | Invalidate Cache * | 0 | 1 | Valid, but unlocked cacheline * | 1 | 0 | Invalidate Cache, No effect of lock * | 1 | 1 | Valid cache. Locked to a * | | | particular address * -------------------------------------------------------------- * * **********************************************************************************/ #include "xparameters.h" #ifndef XPAR_MICROBLAZE_ICACHE_LINE_LEN #define XPAR_MICROBLAZE_ICACHE_LINE_LEN 1 #endif .text .globl microblaze_update_icache .ent microblaze_update_icache .align 2 microblaze_update_icache: #if (XPAR_MICROBLAZE_USE_ICACHE==1) && (XPAR_MICROBLAZE_ALLOW_ICACHE_WR==1) #if XPAR_MICROBLAZE_ICACHE_LINE_LEN == 1 /* Read the MSR register into a temp register */ mfs r18, rmsr /* Clear the icache enable bit to disable the cache Register r10,r18 are volatile registers and hence do not need to be saved before use */ andi r10, r18, ~32 mts rmsr, r10 /* Update the lock and valid info */ andi r5, r5, 0xfffffffc or r5, r5, r7 /* Update icache */ wic r5, r6 /* Return */ rtsd r15, 8 mts rmsr, r18 #else /* The only valid usage of this routine for larger cache line lengths is to invalidate an instruction cache line So call microblaze_init_icache_range appropriately to do the job */ brid microblaze_init_icache_range addik r6, r0, (XPAR_MICROBLAZE_ICACHE_LINE_LEN * 4) /* We don't have a return instruction here. This is tail call optimization :) */ #endif /* XPAR_MICROBLAZE_ICACHE_LINE_LEN == 1 */ #else rtsd r15, 8 nop #endif .end microblaze_update_icache

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,075

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_enable_dcache.S

/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * File : microblaze_enable_dcache.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Enable L1 dcache on the microblaze. * * ******************************************************************************/ #include "xparameters.h" .text .globl microblaze_enable_dcache .ent microblaze_enable_dcache .align 2 microblaze_enable_dcache: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrset r0, 0x80 #else /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ #Read the MSR register mfs r8, rmsr #Set the interrupt enable bit ori r8, r8, 0x80 #Save the MSR register mts rmsr, r8 #Return rtsd r15, 8 nop #endif /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ .end microblaze_enable_dcache

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

2,365

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_invalidate_dcache.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * microblaze_invalidate_dcache() * * Invalidate the entire L1 DCache * * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #endif .text .globl microblaze_invalidate_dcache .ent microblaze_invalidate_dcache .align 2 microblaze_invalidate_dcache: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) #ifdef MB_VERSION_LT_v720 /* Disable Dcache and interrupts before invalidating */ mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_DCACHE_ENABLE | MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif ADDIK r5, r0, XPAR_MICROBLAZE_DCACHE_BASEADDR & (-(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN)) ADDIK r6, r5, XPAR_MICROBLAZE_DCACHE_BYTE_SIZE & (-(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN)) /* Compute end */ L_start: wdc r5, r0 /* Invalidate the Cache */ CMPU r18, r5, r6 /* Are we at the end? */ BLEI r18, L_done #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* Increment the address by 4 */ breai L_start #else brid L_start /* Branch to the beginning of the loop */ addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* Increment the address by 4 (delay slot) */ #endif L_done: rtsd r15, 8 /* Return */ #ifdef MB_VERSION_LT_v720 /* restore MSR only for MB version < v7.20 */ mts rmsr, r9 #else nop #endif #else rtsd r15, 8 /* Return */ nop #endif .end microblaze_invalidate_dcache

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

2,200

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_init_icache_range.S

/****************************************************************************** * Copyright (c) 2006 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * * microblaze_init_icache_range (unsigned int cache_start, unsigned int cache_len) * * Invalidate icache on the microblaze * * Parameters: * 'cache_start' - address in the Icache where invalidation begins * 'cache_len' - length (in bytes) worth of Icache to be invalidated * * *******************************************************************************/ #include "xparameters.h" #define MICROBLAZE_MSR_ICACHE_ENABLE 0x00000020 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_ICACHE_LINE_LEN #define XPAR_MICROBLAZE_ICACHE_LINE_LEN 1 #endif .text .globl microblaze_init_icache_range .ent microblaze_init_icache_range .align 2 microblaze_init_icache_range: #if (XPAR_MICROBLAZE_USE_ICACHE==1) && (XPAR_MICROBLAZE_ALLOW_ICACHE_WR==1) mfs r9, rmsr /* Disable Icache and interrupts before invalidating */ andi r10, r9, (~(MICROBLAZE_MSR_ICACHE_ENABLE | MICROBLAZE_MSR_INTR_ENABLE)) mts rmsr, r10 andi r5, r5, -(4 * XPAR_MICROBLAZE_ICACHE_LINE_LEN) /* Align to cache line */ add r6, r5, r6 /* Compute end */ andi r6, r6, -(4 * XPAR_MICROBLAZE_ICACHE_LINE_LEN) /* Align to cache line */ L_start: wic r5, r0 /* Invalidate the Cache (delay slot) */ cmpu r18, r5, r6 /* Are we at the end ? */ blei r18, L_done brid L_start /* Branch to the beginning of the loop */ addik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN * 4) /* Increment the address by 4 (delay slot) */ L_done: rtsd r15, 8 /* Return */ mts rmsr, r9 #else rtsd r15, 8 /* Return */ nop #endif .end microblaze_init_icache_range

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

2,879

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_invalidate_icache_range.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * * microblaze_invalidate_icache_range(unsigned int cacheaddr, unsigned int len) * * Invalidate an ICache range * * Parameters: * 'cacheaddr' - address in the Icache where invalidation begins * 'len' - length (in bytes) worth of Icache to be invalidated * * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_ICACHE_ENABLE 0x00000020 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_ICACHE_LINE_LEN #define XPAR_MICROBLAZE_ICACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #endif .text .globl microblaze_invalidate_icache_range .ent microblaze_invalidate_icache_range .align 2 microblaze_invalidate_icache_range: #if (XPAR_MICROBLAZE_USE_ICACHE==1) && (XPAR_MICROBLAZE_ALLOW_ICACHE_WR==1) #ifdef MB_VERSION_LT_v720 /* Disable Icache and interrupts before invalidating */ mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_ICACHE_ENABLE | MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif BEQI r6, L_done /* Skip loop if size is zero */ ADD r6, r5, r6 /* Compute end address */ ADDIK r6, r6, -1 ANDI r6, r6, -(4 * XPAR_MICROBLAZE_ICACHE_LINE_LEN) /* Align end down to cache line */ ANDI r5, r5, -(4 * XPAR_MICROBLAZE_ICACHE_LINE_LEN) /* Align start down to cache line */ L_start: CMPU r18, r5, r6 /* Are we at the end? */ BLTI r18, L_done wic r5, r0 /* Invalidate the cache line */ #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN * 4) /* Increment the address by 4 */ breai L_start /* Branch to the beginning of the loop */ #else brid L_start /* Branch to the beginning of the loop */ addik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN * 4) /* Increment the address by 4 (delay slot) */ #endif L_done: rtsd r15, 8 /* Return */ #ifdef MB_VERSION_LT_v720 /* restore MSR only for MB version < v7.20 */ mts rmsr, r9 #else nop #endif #else rtsd r15, 8 /* Return */ nop #endif .end microblaze_invalidate_icache_range

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,482

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_flush_cache_ext_range.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * microblaze_flush_cache_ext_range (unsigned int cacheaddr, unsigned int len) * *Flush a L2 Cache range * *Parameters: * 'cacheaddr' - address in the L2 cache where the flush begins * 'len ' - length (in bytes) worth of L2 cache to be flushed * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN 16 .text .globl microblaze_flush_cache_ext_range .ent microblaze_flush_cache_ext_range .align 2 microblaze_flush_cache_ext_range: #if ((XPAR_MICROBLAZE_INTERCONNECT==3) && (XPAR_MICROBLAZE_USE_DCACHE==1)) beqi r6, Loop_done ADDIK r6, r6, -1 ADD r6, r5, r6 ANDI r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) ANDI r5, r5, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) RSUBK r6, r5, r6 Loop_start: wdc.ext.flush r5, r6 #if defined (__arch64__ ) addlik r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) beagei r6, Loop_start #else bneid r6, Loop_start addik r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) #endif Loop_done: #endif rtsd r15, 8 nop .end microblaze_flush_cache_ext_range

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,815

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_flush_dcache.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * * microblaze_flush_dcache() * * Flush the L1 DCache * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif .text .globl microblaze_flush_dcache .ent microblaze_flush_dcache .align 2 microblaze_flush_dcache: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) ADDIK r5, r0, XPAR_MICROBLAZE_DCACHE_BASEADDR & (-(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN)) /* Align to cache line */ ADDIK r6, r5, XPAR_MICROBLAZE_DCACHE_BYTE_SIZE & (-(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN)) /* Compute end */ L_start: wdc.flush r5, r0 /* Flush the Cache */ CMPU r18, r5, r6 /* Are we at the end? */ BLEI r18, L_done #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* Increment the address by 4 */ BRI L_start #else brid L_start /* Branch to the beginning of the loop */ addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* Increment the address by 4 (delay slot) */ #endif L_done: #endif rtsd r15, 8 /* Return */ nop .end microblaze_flush_dcache

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

32,372

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_selftest.S

/****************************************************************************** * Copyright (c) 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * * @file microblaze_selftest.S * * @addtogroup microblaze_pseudo_asm_macro * @{ * <h2> microblaze_selftest.S </h2> * * This routine provides an internal self test of the MicroBlaze processor. The * register file and all integer execution units are tested. Long instructions * are also included if 64-bit mode is enabled. Currently FPU, MMU, BTC, data * and instruction caches, and GET/PUT instructions are not covered. * * The routine is not reentrant, and disables interrupts and exceptions during * execution. This can result in increased interrupt latency. * * Call this routine regularly from a timer interrupt. * * When called from C code the routine should be declared as: * extern int microblaze_selftest(); * * @param None. * * @return * - 0 if self test was successful * - Error code if self test failed: * Bit 0: Register file test failed * Bit 1: ALU test failed * Bit 2: Shift unit test failed * Bit 3: Load-store test failed * Bit 4: Branch instruction test failed * Bit 5: Barrel shifter test failed * Bit 6: Multiplier test failed * Bit 7: Integer divide test failed * Bit 8: Pattern compare test failed * Bit 9: MSR instruction test failed * Bit 10: Reorder instruction test failed * * @note * This routine assumes that the processor is in privileged mode when it is * called, if the MMU is enabled. * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- -------- ----------------------------------------------- * 1.0 sa 09/07/20 First release * * ******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" /* Define if execution units are used */ #ifdef XPAR_MICROBLAZE_USE_BARREL #if XPAR_MICROBLAZE_USE_BARREL > 0 #define USE_BARREL #endif #endif #ifdef XPAR_MICROBLAZE_USE_HW_MUL #if XPAR_MICROBLAZE_USE_HW_MUL > 0 #define USE_HW_MUL #endif #if XPAR_MICROBLAZE_USE_HW_MUL == 2 #define USE_HW_MUL_2 #endif #endif #ifdef XPAR_MICROBLAZE_USE_DIV #if XPAR_MICROBLAZE_USE_DIV > 0 #define USE_DIV #endif #endif #ifdef XPAR_MICROBLAZE_USE_PCMP_INSTR #if XPAR_MICROBLAZE_USE_PCMP_INSTR > 0 #define USE_PCMP_INSTR #endif #endif #ifdef XPAR_MICROBLAZE_USE_MSR_INSTR #if XPAR_MICROBLAZE_USE_MSR_INSTR > 0 #define USE_MSR_INSTR #endif #endif #ifdef XPAR_MICROBLAZE_USE_REORDER_INSTR #if XPAR_MICROBLAZE_USE_REORDER_INSTR > 0 #define USE_REORDER_INSTR #endif #endif #if defined (__arch64__) #define OFFSET(index) ((index) * 8) #define INCR(index) addlik r1, (index) * 8 #define DATA .quad #else #define OFFSET(index) ((index) * 4) #define INCR(index) addik r1, r1, (index) * 4 #define DATA .long #endif /***************************************************************************** * Machine Status Register masks ******************************************************************************/ #define MSR_CARRY_MASK 0x80000004 #define MSR_EE_IE_MASK 0x00000102 #define MSR_PVR_BIT_MASK 0x00000000 #ifdef XPAR_MICROBLAZE_PVR #if XPAR_MICROBLAZE_PVR > 0 #undef MSR_PVR_BIT_MASK #define MSR_PVR_BIT_MASK 0x00000400 #endif #endif #define MSR_BIT_MASK (0x8000000E | MSR_PVR_BIT_MASK) /***************************************************************************** * Test macros ******************************************************************************/ #define TEST_ALU_ARITH(instr, load, offset) \ instr r5, r2, r4; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_aluerr; \ lwi r8, r1, OFFSET(offset + 1); \ mfs r9, rmsr; \ andi r9, r9, MSR_CARRY_MASK; \ cmpu r9, r9, r8; \ BNEID r9, L_microblaze_selftest_aluerr #define TEST_ALU_LOGIC(instr, load, offset) \ instr r5, r2, r4; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_aluerr #define TEST_SHIFT(instr, load, offset) \ instr r5, r2; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_shifterr #define TEST_SHIFTC(instr, load, offset) \ instr r5, r2; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_shifterr; \ lwi r8, r1, OFFSET(offset + 1); \ mfs r9, rmsr; \ andi r9, r9, MSR_CARRY_MASK; \ cmpu r9, r9, r8; \ BNEID r9, L_microblaze_selftest_shifterr #define TEST_BARREL(instr, load, offset) \ instr r5, r2, r4; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_barrelerr #define TEST_BARREL_IMM(instr, immw, imms, load, offset) \ ori r5, r2, 0; \ instr r5, r4, immw, imms; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_barrelerr #define TEST_MUL(instr, load, byteoffset) \ instr r5, r2, r4; \ load r6, r1, byteoffset; \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_mulerr #define TEST_DIV(instr, load, byteoffset) \ instr r5, r2, r4; \ load r6, r1, byteoffset; \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_diverr #define TEST_PCMP(instr, load, offset) \ instr r5, r2, r4; \ load r6, r1, OFFSET(offset); \ CMPU r7, r5, r6; \ BNEID r7, L_microblaze_selftest_pcmperr .text .globl microblaze_selftest .ent microblaze_selftest .align 2 microblaze_selftest: /***************************************************************************** * Preamble ******************************************************************************/ /* Disable interrupts and exceptions, save MSR */ #ifdef USE_MSR_INSTR msrclr r3, MSR_EE_IE_MASK #else mfs r3, rmsr andi r3, r3, ~MSR_EE_IE_MASK mts rmsr, r3 #endif swi r3, r0, L_microblaze_selftest_regs /* Save registers, except r3 temporary register and return value */ ADDIK r3, r0, L_microblaze_selftest_regs SI r1, r3, OFFSET(1) SI r2, r3, OFFSET(2) SI r4, r3, OFFSET(4) SI r5, r3, OFFSET(5) SI r6, r3, OFFSET(6) SI r7, r3, OFFSET(7) SI r8, r3, OFFSET(8) SI r9, r3, OFFSET(9) SI r10, r3, OFFSET(10) SI r11, r3, OFFSET(11) SI r12, r3, OFFSET(12) SI r13, r3, OFFSET(13) SI r14, r3, OFFSET(14) SI r15, r3, OFFSET(15) SI r16, r3, OFFSET(16) SI r17, r3, OFFSET(17) SI r18, r3, OFFSET(18) SI r19, r3, OFFSET(19) SI r20, r3, OFFSET(20) SI r21, r3, OFFSET(21) SI r22, r3, OFFSET(22) SI r23, r3, OFFSET(23) SI r24, r3, OFFSET(24) SI r25, r3, OFFSET(25) SI r26, r3, OFFSET(26) SI r27, r3, OFFSET(27) SI r28, r3, OFFSET(28) SI r29, r3, OFFSET(29) SI r30, r3, OFFSET(30) SI r31, r3, OFFSET(31) /* Set r3 to test pass = 0 */ ADDIK r3, r0, 0 /***************************************************************************** * 1. Test register file ******************************************************************************/ L_microblaze_selftest_reg: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_regdata L_microblaze_selftest_regloop: /* Load test pattern into r2, r4 - r31 */ LI r2, r1, 0 LI r4, r1, 0 LI r5, r1, 0 LI r6, r1, 0 LI r7, r1, 0 LI r8, r1, 0 LI r9, r1, 0 LI r10, r1, 0 LI r11, r1, 0 LI r12, r1, 0 LI r13, r1, 0 LI r14, r1, 0 LI r15, r1, 0 LI r16, r1, 0 LI r17, r1, 0 LI r18, r1, 0 LI r19, r1, 0 LI r20, r1, 0 LI r21, r1, 0 LI r22, r1, 0 LI r23, r1, 0 LI r24, r1, 0 LI r25, r1, 0 LI r26, r1, 0 LI r27, r1, 0 LI r28, r1, 0 LI r29, r1, 0 LI r30, r1, 0 LI r31, r1, 0 /* Compare registers pair by pair */ CMPU r2, r2, r4 BNEID r2, L_microblaze_selftest_regerr CMPU r4, r4, r5 BNEID r4, L_microblaze_selftest_regerr CMPU r5, r5, r6 BNEID r5, L_microblaze_selftest_regerr CMPU r6, r6, r7 BNEID r6, L_microblaze_selftest_regerr CMPU r7, r7, r8 BNEID r7, L_microblaze_selftest_regerr CMPU r8, r8, r9 BNEID r8, L_microblaze_selftest_regerr CMPU r9, r9, r10 BNEID r9, L_microblaze_selftest_regerr CMPU r10, r10, r11 BNEID r10, L_microblaze_selftest_regerr CMPU r11, r11, r12 BNEID r11, L_microblaze_selftest_regerr CMPU r12, r12, r13 BNEID r12, L_microblaze_selftest_regerr CMPU r13, r13, r14 BNEID r13, L_microblaze_selftest_regerr CMPU r14, r14, r15 BNEID r14, L_microblaze_selftest_regerr CMPU r15, r15, r16 BNEID r15, L_microblaze_selftest_regerr CMPU r16, r16, r17 BNEID r16, L_microblaze_selftest_regerr CMPU r17, r17, r18 BNEID r17, L_microblaze_selftest_regerr CMPU r18, r18, r19 BNEID r18, L_microblaze_selftest_regerr CMPU r19, r19, r20 BNEID r19, L_microblaze_selftest_regerr CMPU r20, r20, r21 BNEID r20, L_microblaze_selftest_regerr CMPU r21, r21, r22 BNEID r21, L_microblaze_selftest_regerr CMPU r22, r22, r23 BNEID r22, L_microblaze_selftest_regerr CMPU r23, r23, r24 BNEID r23, L_microblaze_selftest_regerr CMPU r24, r24, r25 BNEID r24, L_microblaze_selftest_regerr CMPU r25, r25, r26 BNEID r25, L_microblaze_selftest_regerr CMPU r26, r26, r27 BNEID r26, L_microblaze_selftest_regerr CMPU r27, r27, r28 BNEID r27, L_microblaze_selftest_regerr CMPU r28, r28, r29 BNEID r28, L_microblaze_selftest_regerr CMPU r29, r29, r30 BNEID r29, L_microblaze_selftest_regerr CMPU r30, r30, r31 BEQI r30, L_microblaze_selftest_regnext L_microblaze_selftest_regerr: /* Test error - set register file error (bit 0) */ ori r3, r3, 1 L_microblaze_selftest_regnext: /* Loop back with next test pattern - end after zero pattern */ BNEID r31, L_microblaze_selftest_regloop INCR(1) /***************************************************************************** * 2. Test ALU ******************************************************************************/ L_microblaze_selftest_alu: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_aludata L_microblaze_selftest_aluloop: /* Load operands into r2, r4 */ LI r2, r1, OFFSET(0) LI r4, r1, OFFSET(1) /* Execute all ALU arithmetic instructions */ TEST_ALU_ARITH(add, lwi, 2) TEST_ALU_ARITH(addc, lwi, 4) TEST_ALU_ARITH(rsub, lwi, 6) TEST_ALU_ARITH(rsubc, lwi, 8) TEST_ALU_LOGIC(cmp, lwi, 10) /* Execute all ALU logical instructions */ TEST_ALU_LOGIC(and, lwi, 11) TEST_ALU_LOGIC(andn, lwi, 12) TEST_ALU_LOGIC(or, lwi, 13) TEST_ALU_LOGIC(xor, lwi, 14) nop bri L_microblaze_selftest_alunext L_microblaze_selftest_aluerr: /* Test error - set ALU error (bit 1) */ ori r3, r3, 2 L_microblaze_selftest_alunext: /* Loop back with next test data - end after zero data */ BNEID r2, L_microblaze_selftest_aluloop INCR(15) /***************************************************************************** * 3. Test shift unit ******************************************************************************/ L_microblaze_selftest_shift: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_shiftdata L_microblaze_selftest_shiftloop: /* Load operand into r2 */ LI r2, r1, OFFSET(0) /* Test instructions clz, sext8, sext16, sra, src, srl */ TEST_SHIFT(clz, lwi, 1) TEST_SHIFT(sext8, lwi, 2) TEST_SHIFT(sext16, lwi, 3) TEST_SHIFTC(sra, lwi, 4) TEST_SHIFTC(src, lwi, 6) TEST_SHIFTC(srl, lwi, 8) nop bri L_microblaze_selftest_shiftnext L_microblaze_selftest_shifterr: /* Test error - set shift logic error (bit 2) */ ori r3, r3, 4 L_microblaze_selftest_shiftnext: /* Loop back with next test data - end after zero data */ BNEID r2, L_microblaze_selftest_shiftloop INCR(10) /***************************************************************************** * 4. Test load-store ******************************************************************************/ L_microblaze_selftest_ldst: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_ldstdata /* Set static address and offsets */ ADDIK r4, r0, L_microblaze_selftest_ldstptr ADDIK r24, r0, 4 ADDIK r28, r0, 8 L_microblaze_selftest_ldstloop: /* Load operand into r2 */ LI r2, r1, OFFSET(0) /* Test instructions lbu, lhu, lw, sb, sh, sw */ sb r2, r4, r0 sh r2, r4, r24 sw r2, r4, r28 lbu r8, r4, r0 lhu r9, r4, r24 lw r10, r4, r28 /* Compare load results */ ANDI r11, r2, 0xFF ANDI r12, r2, 0xFFFF CMPU r16, r11, r8 BNEID r16, L_microblaze_selftest_ldsterr CMPU r17, r12, r9 BNEID r17, L_microblaze_selftest_ldsterr CMPU r18, r2, r10 BEQI r18, L_microblaze_selftest_ldstnext L_microblaze_selftest_ldsterr: /* Test error - set load-store error (bit 3) */ ori r3, r3, 8 L_microblaze_selftest_ldstnext: /* Loop back with next test data - end after zero data */ BNEID r2, L_microblaze_selftest_ldstloop INCR(1) /***************************************************************************** * 4. Test branch ******************************************************************************/ L_microblaze_selftest_branch: /* Test instructions blt, ble, bge, bgt, br */ /* Untested instructions: rtbd, rtid, rted, brk */ addik r2, r0, 0 /* EQ */ addik r4, r0, 1 /* GT */ addik r5, r0, -1 /* LT */ /* Taken branches */ BEQI r2, L_microblaze_selftest_brancheq ori r3, r3, 16 /* Test error */ L_microblaze_selftest_brancheq: BGEI r2, L_microblaze_selftest_branchge0 ori r3, r3, 16 /* Test error */ L_microblaze_selftest_branchge0: BGEI r4, L_microblaze_selftest_branchge1 ori r3, r3, 16 /* Test error */ L_microblaze_selftest_branchge1: BGTI r4, L_microblaze_selftest_branchgt ori r3, r3, 16 /* Test error */ L_microblaze_selftest_branchgt: BLEI r2, L_microblaze_selftest_branchle0 ori r3, r3, 16 /* Test error */ L_microblaze_selftest_branchle0: BLEI r5, L_microblaze_selftest_branchle1 ori r3, r3, 16 /* Test error */ L_microblaze_selftest_branchle1: BLTI r5, L_microblaze_selftest_branchlt ori r3, r3, 16 /* Test error */ L_microblaze_selftest_branchlt: BNEI r4, L_microblaze_selftest_branchne ori r3, r3, 16 /* Test error */ L_microblaze_selftest_branchne: /* Not taken branches */ BEQI r4, L_microblaze_selftest_brancherr BEQI r5, L_microblaze_selftest_brancherr BGEI r5, L_microblaze_selftest_brancherr BGTI r2, L_microblaze_selftest_brancherr BGTI r5, L_microblaze_selftest_brancherr BLEI r4, L_microblaze_selftest_brancherr BLTI r2, L_microblaze_selftest_brancherr BLTI r4, L_microblaze_selftest_brancherr BNEI r2, L_microblaze_selftest_brancherr BRI L_microblaze_selftest_branchnext L_microblaze_selftest_brancherr: /* Test error - set branch error (bit 4) */ ori r3, r3, 16 L_microblaze_selftest_branchnext: /***************************************************************************** * 6. Test barrel shifter ******************************************************************************/ #ifdef USE_BARREL L_microblaze_selftest_barrel: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_barreldata L_microblaze_selftest_barrelloop: /* Load operands into r2, r4 */ LI r2, r1, OFFSET(0) LI r4, r1, OFFSET(1) /* Test instructions bsrl, bsra, bsll, bsifi, bsefi */ TEST_BARREL(bsrl, lwi, 2) TEST_BARREL(bsra, lwi, 3) TEST_BARREL(bsll, lwi, 4) TEST_BARREL_IMM(bsifi, 11, 6, lwi, 5); TEST_BARREL_IMM(bsefi, 6, 1, lwi, 6); nop bri L_microblaze_selftest_barrelnext L_microblaze_selftest_barrelerr: /* Test error - set barrel logic error (bit 5) */ ori r3, r3, 32 L_microblaze_selftest_barrelnext: /* Loop back with next test data - end after zero data */ BNEID r2, L_microblaze_selftest_barrelloop INCR(7) #endif /***************************************************************************** * 7. Test multiplier ******************************************************************************/ #ifdef USE_HW_MUL L_microblaze_selftest_mul: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_muldata L_microblaze_selftest_mulloop: /* Load operands into r2, r4 */ lwi r2, r1, 0 lwi r4, r1, 4 /* Test instruction mul */ TEST_MUL(mul, lwi, 8) #ifdef USE_HW_MUL_2 /* Test instructions mulh, mulhu, mulhsu */ TEST_MUL(mulh, lwi, 12) TEST_MUL(mulhu, lwi, 16) TEST_MUL(mulhsu, lwi, 20) #endif nop bri L_microblaze_selftest_mulnext L_microblaze_selftest_mulerr: /* Test error - set multiply error (bit 6) */ ori r3, r3, 64 L_microblaze_selftest_mulnext: /* Loop back with next test data - end after zero data */ BNEID r2, L_microblaze_selftest_mulloop #ifdef USE_HW_MUL_2 addik r1, r1, 24 #else addik r1, r1, 12 #endif #endif /***************************************************************************** * 8. Test integer divide ******************************************************************************/ #ifdef USE_DIV L_microblaze_selftest_div: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_divdata L_microblaze_selftest_divloop: /* Load operands into r2, r4 */ lwi r2, r1, 0 lwi r4, r1, 4 /* Test instructions idiv, idivu */ TEST_DIV(idiv, lwi, 8) TEST_DIV(idivu, lwi, 12) nop bri L_microblaze_selftest_divnext L_microblaze_selftest_diverr: /* Test error - set integer divide error (bit 7) */ ori r3, r3, 128 L_microblaze_selftest_divnext: /* Loop back with next test data - end after zero data */ BNEID r4, L_microblaze_selftest_divloop addik r1, r1, 16 #endif /***************************************************************************** * 9. Test pattern compare ******************************************************************************/ #ifdef USE_PCMP_INSTR L_microblaze_selftest_pcmp: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_pcmpdata L_microblaze_selftest_pcmploop: /* Load operands into r2, r4 */ LI r2, r1, OFFSET(0) LI r4, r1, OFFSET(1) /* Test instructions pcmpbf, pcmpeq, pcmpne */ /* 64-bit: add instructions pcmplbf, pcmpleq, pcmplne */ TEST_PCMP(pcmpbf, lwi, 2) TEST_PCMP(pcmpeq, lwi, 3) TEST_PCMP(pcmpne, lwi, 4) nop bri L_microblaze_selftest_pcmpnext L_microblaze_selftest_pcmperr: /* Test error - set pcmp logic error (bit 8) */ ori r3, r3, 256 L_microblaze_selftest_pcmpnext: /* Loop back with next test data - end after zero data */ BNEID r2, L_microblaze_selftest_pcmploop INCR(5) #endif /***************************************************************************** * 10. Test MSR instructions ******************************************************************************/ L_microblaze_selftest_msr: #ifdef USE_MSR_INSTR /* Test instructions msrclr, msrset, mfs msr */ msrset r0, ~MSR_EE_IE_MASK & 0x7FFF nop mfs r6, rmsr nop msrclr r7, 0x7FF nop mfs r8, rmsr nop #endif /* Test instructions mfs msr, mts msr */ /* Bits not included: ICE, DZO, DCE, EE, EIP, UMS, VMS */ addik r9, r0, MSR_BIT_MASK & ~MSR_EE_IE_MASK mts rmsr, r9 nop mfs r10, rmsr /* Compare instruction result */ #ifdef USE_MSR_INSTR addik r11, r0, MSR_PVR_BIT_MASK cmpu r12, r6, r7 BNEID r12, L_microblaze_selftest_msrerr cmpu r13, r8, r11 BNEID r13, L_microblaze_selftest_msrerr #endif cmpu r14, r9, r10 BEQI r14, L_microblaze_selftest_msrnext L_microblaze_selftest_msrerr: /* Test error - set MSR instruction error (bit 9) */ ori r3, r3, 512 L_microblaze_selftest_msrnext: /***************************************************************************** * 11. Test reorder instructions ******************************************************************************/ #ifdef USE_REORDER_INSTR L_microblaze_selftest_reorder: /* Get pointer to test data */ ADDIK r1, r0, L_microblaze_selftest_reorderdata /* Set static address and offsets */ ADDIK r4, r0, L_microblaze_selftest_ldstptr ADDIK r24, r0, 4 ADDIK r28, r0, 8 L_microblaze_selftest_reorderloop: /* Load operand into r2 */ LI r2, r1, OFFSET(0) /* Test instructions swapb, swaph, lbur, lhur, lwr, sbr, shr, swr */ sbr r2, r4, r0 shr r2, r4, r24 swr r2, r4, r28 lbur r8, r4, r0 lhur r9, r4, r24 lwr r10, r4, r28 swapb r21, r2 swaph r22, r2 /* Load swap results */ LI r13, r1, OFFSET(1) LI r14, r1, OFFSET(2) /* Compare load results */ ANDI r11, r2, 0xFF ANDI r12, r2, 0xFFFF CMPU r16, r11, r8 BNEID r16, L_microblaze_selftest_reordererr CMPU r17, r12, r9 BNEID r17, L_microblaze_selftest_reordererr CMPU r18, r2, r10 BNEID r18, L_microblaze_selftest_reordererr CMPU r19, r21, r13 BNEID r19, L_microblaze_selftest_reordererr CMPU r20, r22, r14 BEQI r20, L_microblaze_selftest_reordernext L_microblaze_selftest_reordererr: /* Test error - set reorder instruction error (bit 10) */ ori r3, r3, 1024 L_microblaze_selftest_reordernext: /* Loop back with next test data - end after zero data */ BNEID r2, L_microblaze_selftest_reorderloop INCR(3) #endif /***************************************************************************** * Postamble ******************************************************************************/ /* Restore all registers, except r3 return value and r4 temporary */ ADDIK r31, r0, L_microblaze_selftest_regs LI r1, r31, OFFSET(1) LI r2, r31, OFFSET(2) LI r4, r31, OFFSET(4) LI r5, r31, OFFSET(5) LI r6, r31, OFFSET(6) LI r7, r31, OFFSET(7) LI r8, r31, OFFSET(8) LI r9, r31, OFFSET(9) LI r10, r31, OFFSET(10) LI r11, r31, OFFSET(11) LI r12, r31, OFFSET(12) LI r13, r31, OFFSET(13) LI r14, r31, OFFSET(14) LI r15, r31, OFFSET(15) LI r16, r31, OFFSET(16) LI r17, r31, OFFSET(17) LI r18, r31, OFFSET(18) LI r19, r31, OFFSET(19) LI r20, r31, OFFSET(20) LI r21, r31, OFFSET(21) LI r22, r31, OFFSET(22) LI r23, r31, OFFSET(23) LI r24, r31, OFFSET(24) LI r25, r31, OFFSET(25) LI r26, r31, OFFSET(26) LI r27, r31, OFFSET(27) LI r28, r31, OFFSET(28) LI r29, r31, OFFSET(29) LI r30, r31, OFFSET(30) LI r31, r31, OFFSET(31) /* Restore MSR */ lwi r4, r0, L_microblaze_selftest_regs mts rmsr, r4 /* Return */ rtsd r15, 8 nop L_microblaze_selftest_end: .end microblaze_selftest /***************************************************************************** * Temporary storage used by this routine * MSR followd by registers r1 - r31 ******************************************************************************/ .data .align 3 L_microblaze_selftest_regs: .rept 32 #if defined (__arch64__) .quad 0 #else .long 0 #endif .endr /***************************************************************************** * Test data used by this routine ******************************************************************************/ L_microblaze_selftest_regdata: #if defined (__arch64__) .quad 0x5555555555555555 .quad 0xAAAAAAAAAAAAAAAA .quad 0xFFFFFFFFFFFFFFFF .quad 0x0000000000000000 #else .long 0x55555555 .long 0xAAAAAAAA .long 0xFFFFFFFF .long 0x00000000 #endif L_microblaze_selftest_aludata: DATA 0x55555555 /* rA operand */ DATA 0x55555556 /* rB operand */ DATA 0xAAAAAAAB /* rD result: add */ DATA 0x00000000 /* MSR.C: add */ DATA 0xAAAAAAAB /* rD result: addc */ DATA 0x00000000 /* MSR.C: addc */ DATA 0x00000001 /* rD result: rsub */ DATA MSR_CARRY_MASK /* MSR.C: rsub */ DATA 0x00000001 /* rD result: rsubc */ DATA MSR_CARRY_MASK /* MSR.C: rsubc */ DATA 0x00000001 /* rD result: cmp */ DATA 0x55555554 /* rD result: and */ DATA 0x00000001 /* rD result: andn */ DATA 0x55555557 /* rD result: or */ DATA 0x00000003 /* rD result: xor */ DATA 0xAAAAAAAB /* rA operand */ DATA 0xAAAAAAAA /* rB operand */ DATA 0x55555555 /* rD result: add */ DATA MSR_CARRY_MASK /* MSR.C: add */ DATA 0x55555556 /* rD result: addc */ DATA MSR_CARRY_MASK /* MSR.C: addc */ DATA 0xFFFFFFFF /* rD result: rsub */ DATA 0x00000000 /* MSR.C: rsub */ DATA 0xFFFFFFFE /* rD result: rsubc */ DATA 0x00000000 /* MSR.C: rsubc */ DATA 0xFFFFFFFF /* rD result: cmp */ DATA 0xAAAAAAAA /* rD result: and */ DATA 0x00000001 /* rD result: andn */ DATA 0xAAAAAAAB /* rD result: or */ DATA 0x00000001 /* rD result: xor */ DATA 0xFFFFFFFF /* rA operand */ DATA 0xFFFFFFFF /* rB operand */ DATA 0xFFFFFFFE /* rD result: add */ DATA MSR_CARRY_MASK /* MSR.C: add */ DATA 0xFFFFFFFF /* rD result: addc */ DATA MSR_CARRY_MASK /* MSR.C: addc */ DATA 0x00000000 /* rD result: rsub */ DATA MSR_CARRY_MASK /* MSR.C: rsub */ DATA 0x00000000 /* rD result: rsubc */ DATA MSR_CARRY_MASK /* MSR.C: rsubc */ DATA 0x00000000 /* rD result: cmp */ DATA 0xFFFFFFFF /* rD result: and */ DATA 0x00000000 /* rD result: andn */ DATA 0xFFFFFFFF /* rD result: or */ DATA 0x00000000 /* rD result: xor */ DATA 0x00000000 /* rA operand */ DATA 0xFFFFFFFF /* rB operand */ DATA 0xFFFFFFFF /* rD result: add */ DATA 0x00000000 /* MSR.C: add */ DATA 0xFFFFFFFF /* rD result: addc */ DATA 0x00000000 /* MSR.C: addc */ DATA 0xFFFFFFFF /* rD result: rsub */ DATA MSR_CARRY_MASK /* MSR.C: rsub */ DATA 0xFFFFFFFF /* rD result: rsubc */ DATA MSR_CARRY_MASK /* MSR.C: rsubc */ DATA 0xFFFFFFFF /* rD result: cmp */ DATA 0x00000000 /* rD result: and */ DATA 0x00000000 /* rD result: andn */ DATA 0xFFFFFFFF /* rD result: or */ DATA 0xFFFFFFFF /* rD result: xor */ L_microblaze_selftest_shiftdata: DATA 0x55555555 /* rA operand */ DATA 0x00000001 /* rD result: clz */ DATA 0x00000055 /* rD result: sext8 */ DATA 0x00005555 /* rD result: sext16 */ DATA 0x2AAAAAAA /* rD result: sra */ DATA MSR_CARRY_MASK /* MSR.C: sra */ DATA 0xAAAAAAAA /* rD result: src */ DATA MSR_CARRY_MASK /* MSR.C: src */ DATA 0x2AAAAAAA /* rD result: srl */ DATA MSR_CARRY_MASK /* MSR.C: src */ DATA 0xAAAAAAAA /* rA operand */ DATA 0x00000000 /* rD result: clz */ DATA 0xFFFFFFAA /* rD result: sext8 */ DATA 0xFFFFAAAA /* rD result: sext16 */ DATA 0xD5555555 /* rD result: sra */ DATA 0x00000000 /* MSR.C: sra */ DATA 0x55555555 /* rD result: src */ DATA 0x00000000 /* MSR.C: src */ DATA 0x55555555 /* rD result: srl */ DATA 0x00000000 /* MSR.C: srl */ DATA 0xFFFFFFFF /* rA operand */ DATA 0x00000000 /* rD result: clz */ DATA 0xFFFFFFFF /* rD result: sext8 */ DATA 0xFFFFFFFF /* rD result: sext16 */ DATA 0xFFFFFFFF /* rD result: sra */ DATA MSR_CARRY_MASK /* MSR.C: sra */ DATA 0xFFFFFFFF /* rD result: src */ DATA MSR_CARRY_MASK /* MSR.C: src */ DATA 0x7FFFFFFF /* rD result: srl */ DATA MSR_CARRY_MASK /* MSR.C: srl */ DATA 0x00000000 /* rA operand */ DATA 0x00000020 /* rD result: clz */ DATA 0x00000000 /* rD result: sext8 */ DATA 0x00000000 /* rD result: sext16 */ DATA 0x00000000 /* rD result: sra */ DATA 0x00000000 /* MSR.C: sra */ DATA 0x00000000 /* rD result: src */ DATA 0x00000000 /* MSR.C: src */ DATA 0x00000000 /* rD result: srl */ DATA 0x00000000 /* MSR.C: srl */ L_microblaze_selftest_ldstdata: DATA 0xDEADBEEF /* rD operand */ DATA 0x12345678 /* rD operand */ DATA 0x00000000 /* rD operand */ L_microblaze_selftest_ldstptr: DATA 0 DATA 0 DATA 0 L_microblaze_selftest_barreldata: DATA 0x55555555 /* rA operand */ DATA 16 /* rB operand */ DATA 0x00005555 /* rD result: bsrl */ DATA 0x00005555 /* rD result: bsra */ DATA 0x55550000 /* rD result: bsll */ DATA 0x55540415 /* rD result: bsifi */ DATA 0x00000008 /* rD result: bsefi */ DATA 0xAAAAAAAA /* rA operand */ DATA 1 /* rB operand */ DATA 0x55555555 /* rD result: bsrl */ DATA 0xD5555555 /* rD result: bsra */ DATA 0x55555554 /* rD result: bsll */ DATA 0xAAAA006A /* rD result: bsifi */ DATA 0x00000000 /* rD result: bsefi */ DATA 0xFFFFFFFF /* rA operand */ DATA 25 /* rB operand */ DATA 0x0000007F /* rD result: bsrl */ DATA 0xFFFFFFFF /* rD result: bsra */ DATA 0xFE000000 /* rD result: bsll */ DATA 0xFFFE067F /* rD result: bsifi */ DATA 0x0000000C /* rD result: bsefi */ DATA 0x00000000 /* rA operand */ DATA 10 /* rB operand */ DATA 0x00000000 /* rD result: bsrl */ DATA 0x00000000 /* rD result: bsra */ DATA 0x00000000 /* rD result: bsll */ DATA 0x00000280 /* rD result: bsifi */ DATA 0x00000005 /* rD result: bsefi */ L_microblaze_selftest_muldata: .long 0x55555555 /* rA operand */ .long 0x55555555 /* rB operand */ .long 0x38E38E39 /* rD result: mul */ #ifdef USE_HW_MUL_2 .long 0x1C71C71C /* rD result: mulh */ .long 0x1C71C71C /* rD result: mulhu */ .long 0x1C71C71C /* rD result: mulhsu */ #endif .long 0xAAAAAAAA /* rA operand */ .long 0xAAAAAAAA /* rB operand */ .long 0xE38E38E4 /* rD result: mul */ #ifdef USE_HW_MUL_2 .long 0x1C71C71C /* rD result: mulh */ .long 0x71C71C70 /* rD result: mulhu */ .long 0xC71C71C6 /* rD result: mulhsu */ #endif .long 0xFFFFFFFF /* rA operand */ .long 0xFFFFFFFF /* rB operand */ .long 0x00000001 /* rD result: mul */ #ifdef USE_HW_MUL_2 .long 0x00000000 /* rD result: mulh */ .long 0xFFFFFFFE /* rD result: mulhu */ .long 0xFFFFFFFF /* rD result: mulhsu */ #endif .long 0x00000000 /* rA operand */ .long 0x00000000 /* rB operand */ .long 0x00000000 /* rD result: mul */ #ifdef USE_HW_MUL_2 .long 0x00000000 /* rD result: mulh */ .long 0x00000000 /* rD result: mulhu */ .long 0x00000000 /* rD result: mulhsu */ #endif L_microblaze_selftest_divdata: .long 0x55555555 /* rA operand */ .long 0x55555555 /* rB operand */ .long 0x00000001 /* rD result: div */ .long 0x00000001 /* rD result: divu */ .long 0xAAAAAAAA /* rA operand */ .long 0xAAAAAAAA /* rB operand */ .long 0x00000001 /* rD result: div */ .long 0x00000001 /* rD result: divu */ .long 0xFFFFFFFF /* rA operand */ .long 0xFFFFFFFF /* rB operand */ .long 0x00000001 /* rD result: div */ .long 0x00000001 /* rD result: divu */ .long 0x00000001 /* rA operand */ .long 0x00000000 /* rB operand */ .long 0x00000000 /* rD result: div */ .long 0x00000000 /* rD result: divu */ .align 3 L_microblaze_selftest_pcmpdata: DATA 0x55555555 /* rA operand */ DATA 0x44445555 /* rB operand */ DATA 0x00000003 /* rD result: pcmpbf */ DATA 0x00000000 /* rD result: pcmpeq */ DATA 0x00000001 /* rD result: pcmpne */ DATA 0xAAAAAAAA /* rA operand */ DATA 0xAAAAAAAA /* rB operand */ DATA 0x00000001 /* rD result: pcmpbf */ DATA 0x00000001 /* rD result: pcmpeq */ DATA 0x00000000 /* rD result: pcmpne */ DATA 0xFFFFFFFF /* rA operand */ DATA 0x000000FF /* rB operand */ DATA 0x00000004 /* rD result: pcmpbf */ DATA 0x00000000 /* rD result: pcmpeq */ DATA 0x00000001 /* rD result: pcmpne */ DATA 0x00000000 /* rA operand */ DATA 0xDEADBEEF /* rB operand */ DATA 0x00000000 /* rD result: pcmpbf */ DATA 0x00000000 /* rD result: pcmpeq */ DATA 0x00000001 /* rD result: pcmpne */ L_microblaze_selftest_reorderdata: DATA 0xDEADBEEF /* rD operand */ DATA 0xEFBEADDE /* rD result: swapb */ DATA 0xBEEFDEAD /* rD result: swaph */ DATA 0x00000000 /* rD operand */ DATA 0x00000000 /* rD result: swapb */ DATA 0x00000000 /* rD result: swaph */ /** * @} End of "addtogroup microblaze_pseudo_asm_macro". */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

3,488

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_invalidate_dcache_range.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * * microblaze_invalidate_dcache_range (unsigned int cacheaddr, unsigned int len) * * Invalidate a Dcache range * * Parameters: * 'cacheaddr' - address in the Dcache where invalidation begins * 'len ' - length (in bytes) worth of Dcache to be invalidated * * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #define MB_HAS_WRITEBACK_SET 0 #else #define MB_HAS_WRITEBACK_SET XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #endif .text .globl microblaze_invalidate_dcache_range .ent microblaze_invalidate_dcache_range .align 2 microblaze_invalidate_dcache_range: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) #ifdef MB_VERSION_LT_v720 /* Disable Dcache and interrupts before invalidating */ mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_DCACHE_ENABLE | MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif BEQI r6, L_done /* Skip loop if size is zero */ ADD r6, r5, r6 /* Compute end address */ ADDIK r6, r6, -1 ANDI r6, r6, -(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align end down to cache line */ ANDI r5, r5, -(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align start down to cache line */ #if MB_HAS_WRITEBACK_SET == 0 /* Use a different scheme for MB version < v7.20 or when caches are write-through */ L_start: CMPU r18, r5, r6 /* Are we at the end? */ BLTI r18, L_done wdc r5, r0 #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* Increment the address by 4 */ breai L_start /* Branch to the beginning of the loop */ #else brid L_start /* Branch to the beginning of the loop */ addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* Increment the address by 4 (delay slot) */ #endif #else RSUBK r6, r5, r6 /* r6 will now contain (count of bytes - (4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN)) */ L_start: wdc.clear r5, r6 /* Invalidate the cache line only if the address matches */ #if defined (__arch64__ ) addlik r6, r6, -(XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) beagei r6, L_start #else bneid r6, L_start addik r6, r6, -(XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) #endif #endif L_done: rtsd r15, 8 #ifdef MB_VERSION_LT_v720 /* restore MSR only for MB version < v7.20 */ mts rmsr, r9 #else nop #endif #else rtsd r15, 8 nop #endif .end microblaze_invalidate_dcache_range

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,070

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_enable_icache.S

/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * File : microblaze_enable_icache.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Enable icache on the microblaze. * * ******************************************************************************/ #include "xparameters.h" .text .globl microblaze_enable_icache .ent microblaze_enable_icache .align 2 microblaze_enable_icache: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrset r0, 0x20 #else /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ #Read the MSR register mfs r8, rmsr #Set the interrupt enable bit ori r8, r8, 0x20 #Save the MSR register mts rmsr, r8 #Return rtsd r15, 8 nop #endif /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ .end microblaze_enable_icache

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

2,198

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_init_dcache_range.S

/****************************************************************************** * Copyright (c) 2006 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * microblaze_init_dcache_range (unsigned int cache_start, unsigned int cache_len) * * Invalidate dcache on the microblaze * * Parameters: * 'cache_start' - address in the Dcache where invalidation begins * 'cache_len' - length (in bytes) worth of Dcache to be invalidated * * *******************************************************************************/ #include "xparameters.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif .text .globl microblaze_init_dcache_range .ent microblaze_init_dcache_range .align 2 microblaze_init_dcache_range: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) mfs r9, rmsr /* Disable Dcache and interrupts before invalidating */ andi r10, r9, (~(MICROBLAZE_MSR_DCACHE_ENABLE | MICROBLAZE_MSR_INTR_ENABLE)) mts rmsr, r10 andi r5, r5, -(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align to cache line */ add r6, r5, r6 /* Compute end */ andi r6, r6, -(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align to cache line */ L_start: wdc r5, r0 /* Invalidate the Cache (delay slot) */ cmpu r18, r5, r6 /* Are we at the end ? */ blei r18, L_done brid L_start /* Branch to the beginning of the loop */ addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* Increment the address by 4 (delay slot) */ L_done: rtsd r15, 8 /* Return */ mts rmsr, r9 #else rtsd r15, 8 /* Return */ nop #endif .end microblaze_init_dcache_range

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

2,385

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_invalidate_icache.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * * microblaze_invalidate_icache() * * Invalidate the entire ICache * * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_ICACHE_ENABLE 0x00000020 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_ICACHE_LINE_LEN #define XPAR_MICROBLAZE_ICACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #endif .text .globl microblaze_invalidate_icache .ent microblaze_invalidate_icache .align 2 microblaze_invalidate_icache: #if (XPAR_MICROBLAZE_USE_ICACHE==1) && (XPAR_MICROBLAZE_ALLOW_ICACHE_WR==1) #ifdef MB_VERSION_LT_v720 /* Disable Icache and interrupts before invalidating */ mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_ICACHE_ENABLE | MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif ADDIK r5, r0, XPAR_MICROBLAZE_ICACHE_BASEADDR & (-(4 * XPAR_MICROBLAZE_ICACHE_LINE_LEN)) /* Align to cache line */ ADDIK r6, r5, XPAR_MICROBLAZE_CACHE_BYTE_SIZE & (-(4 * XPAR_MICROBLAZE_ICACHE_LINE_LEN)) /* Compute end */ L_start: wic r5, r0 /* Invalidate the Cache */ CMPU r18, r5, r6 /* Are we at the end? */ BLEI r18, L_done #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN * 4) /* Increment the address by 4 */ breai L_start #else brid L_start /* Branch to the beginning of the loop */ addik r5, r5, (XPAR_MICROBLAZE_ICACHE_LINE_LEN * 4) /* Increment the address by 4 (delay slot) */ #endif L_done: rtsd r15, 8 /* Return */ #ifdef MB_VERSION_LT_v720 /* restore MSR only for MB version < v7.20 */ mts rmsr, r9 #else nop #endif #else rtsd r15, 8 /* Return */ nop #endif .end microblaze_invalidate_icache

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,575

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_enable_interrupts.S

/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * @file microblaze_enable_interrupts.S * * @addtogroup microblaze_pseudo_asm_macro * @{ * <h2> microblaze_enable_interrupts.S </h2> * - API to Enable Interrupts: void microblaze_enable_interrupts(void) * * This API Enables interrupts on the MicroBlaze processor. When the MicroBlaze * processor starts up, interrupts are disabled. Interrupts must be explicitly * turned on using this function. * * <pre> * * File : microblaze_enable_interrupts.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Enable interrupts on the microblaze. * </pre> * ******************************************************************************/ #include "xparameters.h" .text .globl microblaze_enable_interrupts .ent microblaze_enable_interrupts .align 2 microblaze_enable_interrupts: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrset r0, 0x2 nop #else /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ #Read the MSR register mfs r12, rmsr #Set the interrupt enable bit ori r12, r12, 0x2 #Save the MSR register mts rmsr, r12 #Return rtsd r15, 8 nop #endif /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ .end microblaze_enable_interrupts /** * @} End of "addtogroup microblaze_pseudo_asm_macro". */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

3,540

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_flush_dcache_range.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * microblaze_flush_dcache_range (unsigned int cacheaddr, unsigned int len) * * Flush a L1 DCache range * * Parameters: * 'cacheaddr' - address in the Dcache where the flush begins * 'len ' - length (in bytes) worth of Dcache to be flushed * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define MICROBLAZE_MSR_DCACHE_ENABLE 0x00000080 #define MICROBLAZE_MSR_INTR_ENABLE 0x00000002 #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif #ifndef XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #define MB_VERSION_LT_v720 #define MB_HAS_WRITEBACK_SET 0 #else #define MB_HAS_WRITEBACK_SET XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK #endif .text .globl microblaze_flush_dcache_range .ent microblaze_flush_dcache_range .align 2 microblaze_flush_dcache_range: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) #ifdef MB_VERSION_LT_v720 /* Disable Dcache and interrupts before invalidating */ mfs r9, rmsr andi r10, r9, ~(MICROBLAZE_MSR_DCACHE_ENABLE | MICROBLAZE_MSR_INTR_ENABLE) mts rmsr, r10 #endif beqi r6, L_done /* Skip loop if size is zero */ ADD r6, r5, r6 /* Compute end address */ ADDIK r6, r6, -1 ANDI r6, r6, -(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align end down to cache line */ ANDI r5, r5, -(4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN) /* Align start down to cache line */ #if MB_HAS_WRITEBACK_SET == 0 /* Use a different scheme for MB version < v7.20 or when caches are write-through */ L_start: CMPU r18, r5, r6 /* Are we at the end? */ BLTI r18, L_done wdc r5, r0 /* Invalidate the cache line */ #if defined (__arch64__ ) addlik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* Increment the address by 4 */ breai L_start /* Branch to the beginning of the loop */ #else brid L_start /* Branch to the beginning of the loop */ addik r5, r5, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* Increment the address by 4 (delay slot) */ #endif #else RSUBK r6, r5, r6 /* r6 will now contain (count of bytes - (4 * XPAR_MICROBLAZE_DCACHE_LINE_LEN)) */ L_start: wdc.flush r5, r6 /* Flush the cache line */ #if defined (__arch64__ ) addlik r6, r6, -(XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) beagei r6, L_start #else bneid r6, L_start addik r6, r6, -(XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) #endif #endif L_done: rtsd r15, 8 #ifdef MB_VERSION_LT_v720 /* restore MSR only for MB version < v7.20 */ mts rmsr, r9 #else nop #endif #else rtsd r15, 8 /* Return */ nop #endif .end microblaze_flush_dcache_range

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,555

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_disable_interrupts.S

/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * @file microblaze_disable_interrupts.S * * @addtogroup microblaze_pseudo_asm_macro * @{ * <h2> microblaze_disable_interrupts.S </h2> * - API to disable Interrupts: void microblaze_disable_interrupts(void) * * This API Disables interrupts on the MicroBlaze processor. It can be * called when entering a critical section of code where a context switch is * undesirable. * * <pre> * File : microblaze_disable_interrupts.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Disable interrupts on the microblaze. * </pre> * ******************************************************************************/ #include "xparameters.h" .text .globl microblaze_disable_interrupts .ent microblaze_disable_interrupts .align 2 microblaze_disable_interrupts: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrclr r0, 0x2 #else /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ #Read the MSR register mfs r12, rmsr #Clear the interrupt enable bit andi r12, r12, ~(0x2) #Save the MSR register mts rmsr, r12 #Return rtsd r15, 8 nop #endif /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ .end microblaze_disable_interrupts /** * @} End of "addtogroup microblaze_pseudo_asm_macro". */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

26,672

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/hw_exception_handler.S

/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * Microblaze HW Exception Handler * - Non self-modifying exception handler for the following exception conditions * - Unalignment * - Instruction bus error * - Data bus error * - Illegal instruction opcode * - Divide-by-zero * - Stack protection violation *******************************************************************************/ #include "microblaze_exceptions_g.h" #include "xparameters.h" #include "microblaze_instructions.h" /* 64-bit definitions */ #if defined (__arch64__) #define INTPTR_DATAITEM .quad #define REGSIZE 8 #define DATAALIGN 4 #else #define INTPTR_DATAITEM .long #define REGSIZE 4 #define DATAALIGN 2 #endif /* 64-bit definitions */ /* Helpful Macros */ #define EX_HANDLER_STACK_SIZ (REGSIZE*21) #define RMSR_OFFSET (20 * REGSIZE) #define R17_OFFSET (0) #define REG_OFFSET(regnum) (REGSIZE * (regnum + 1)) #define NUM_TO_REG(num) r ## num #define R3_TO_STACK(regnum) SI r3, r1, REG_OFFSET(regnum) #define R3_FROM_STACK(regnum) LI r3, r1, REG_OFFSET(regnum) #define PUSH_REG(regnum) SI NUM_TO_REG(regnum), r1, REG_OFFSET(regnum) #define POP_REG(regnum) LI NUM_TO_REG(regnum), r1, REG_OFFSET(regnum) /* Uses r5 */ #define PUSH_MSR \ mfs r5, rmsr; \ swi r5, r1, RMSR_OFFSET; #define PUSH_MSR_AND_ENABLE_EXC \ mfs r5, rmsr; \ swi r5, r1, RMSR_OFFSET; \ ori r5, r5, 0x100; /* Turn ON the EE bit*/ \ mts rmsr, r5; /* Uses r5 */ #define POP_MSR \ lwi r5, r1, RMSR_OFFSET; \ mts rmsr, r5; /* Push r17 */ #define PUSH_R17 SI r17, r1, R17_OFFSET /* Pop r17 */ #define POP_R17 LI r17, r1, R17_OFFSET #define LWREG_NOP \ BRI ex_handler_unhandled; \ nop; #define SWREG_NOP \ BRI ex_handler_unhandled; \ nop; /* r3 is the source */ #define R3_TO_LWREG_V(regnum) \ R3_TO_STACK (regnum); \ BRI ex_handler_done; /* r3 is the source */ #define R3_TO_LWREG(regnum) \ OR NUM_TO_REG (regnum), r0, r3; \ BRI ex_handler_done; /* r3 is the target */ #define SWREG_TO_R3_V(regnum) \ R3_FROM_STACK (regnum); \ BRI ex_sw_tail; /* r3 is the target */ #define SWREG_TO_R3(regnum) \ OR r3, r0, NUM_TO_REG (regnum); \ BRI ex_sw_tail; /* regnum is the source */ #define FP_EX_OPB_SAVE(regnum) \ SI NUM_TO_REG (regnum), r0, mb_fpex_op_b; \ nop; \ BRI handle_fp_ex_opa; /* regnum is the source */ #define FP_EX_OPB_SAVE_V(regnum) \ R3_FROM_STACK (regnum); \ SI r3, r0, mb_fpex_op_b; \ BRI handle_fp_ex_opa; /* regnum is the source */ #define FP_EX_OPA_SAVE(regnum) \ SI NUM_TO_REG (regnum), r0, mb_fpex_op_a; \ nop; \ BRI handle_fp_ex_done; /* regnum is the source */ #define FP_EX_OPA_SAVE_V(regnum) \ R3_FROM_STACK (regnum); \ SI r3, r0, mb_fpex_op_a; \ BRI handle_fp_ex_done; #define FP_EX_UNHANDLED \ BRI fp_ex_unhandled; \ nop; \ nop; /* ESR masks */ #define ESR_EXC_MASK 0x0000001F #define ESR_REG_MASK 0x000003E0 #define ESR_LW_SW_MASK 0x00000400 #define ESR_WORD_MASK 0x00000800 #define ESR_DS_MASK 0x00001000 #define ESR_LONG_MASK 0x00002000 /* Extern declarations */ .extern XNullHandler #ifdef MICROBLAZE_EXCEPTIONS_ENABLED /* If exceptions are enabled in the processor */ /* * hw_exception_handler - Handler for unaligned exceptions * Exception handler notes: * - Does not handle exceptions other than unaligned exceptions * - Does not handle exceptions during load into r17, r1, r0. * - Does not handle exceptions during store from r17 (cannot be done) and r1 (slows down common case) * * Relevant register structures * * EAR - |----|----|----|----|----|----|----|----| * - < ## 32 or 64 bit faulting address ## > * * ESR - |----|----|----|----|----| - | - |-----|-----| * - W S REG EXC * * * STACK FRAME STRUCTURE * --------------------- * * +-------------+ + 0 * | r17 | * +-------------+ + 4 (32-bit) + 8 (64-bit) * | Args for | * | next func | * +-------------+ + 8 (32-bit) + 16 (64-bit) * | r1 | * | . | * | . | * | . | * | . | * | r18 | * +-------------+ + 80 (32-bit) + 160 (64-bit) * | MSR | * +-------------+ + 84 (32-bit) + 168 (64-bit) * | . | * | . | */ .global _hw_exception_handler .section .text .align 2 .ent _hw_exception_handler .type _hw_exception_handler, @function _hw_exception_handler: #if defined(XPAR_MICROBLAZE_USE_STACK_PROTECTION) && (XPAR_MICROBLAZE_USE_STACK_PROTECTION == 1) /* Immediately halt for stack protection violation exception without using any stack */ SI r3, r0, mb_sp_save_r3; /* Save temporary register */ mfs r3, resr; /* Extract ESR[DS] */ andi r3, r3, ESR_EXC_MASK; xori r3, r3, 0x7; /* Check for stack protection violation */ BNEI r3, ex_handler_not_sp_violation; ex_handler_sp_violation: bri 0; /* Halt here if stack protection violation */ ex_handler_not_sp_violation: LI r3, r0, mb_sp_save_r3; /* Restore temporary register */ #endif /* defined(XPAR_MICROBLAZE_USE_STACK_PROTECTION) && (XPAR_MICROBLAZE_USE_STACK_PROTECTION == 1) */ ADDIK r1, r1, -(EX_HANDLER_STACK_SIZ); /* Create stack frame */ PUSH_REG(3); PUSH_REG(4); PUSH_REG(5); PUSH_REG(6); #ifdef MICROBLAZE_CAN_HANDLE_EXCEPTIONS_IN_DELAY_SLOTS mfs r6, resr; andi r6, r6, ESR_DS_MASK; BEQI r6, ex_handler_no_ds; mfs r17, rbtr; ex_handler_no_ds: #endif PUSH_R17; PUSH_MSR_AND_ENABLE_EXC; /* Exceptions enabled here. This will allow nested exceptions */ mfs r3, resr; andi r5, r3, ESR_EXC_MASK; /* Extract ESR[EXC] */ #ifndef NO_UNALIGNED_EXCEPTIONS xori r6, r5, 1; /* 00001 = Unaligned Exception */ BNEI r6, handle_ex_regular; ADDIK r4, r0, MB_ExceptionVectorTable; /* Check if user has registered an unaligned exception handler */ #if defined (__arch64__) LI r4, r4, 16; #else LI r4, r4, 8; #endif ADDIK r6, r0, XNullHandler; /* If exceptionvectortable entry is still XNullHandler, use */ XOR r6, r4, r6; /* the default exception handler */ BEQI r6, handle_unaligned_ex ; handle_ex_regular: #endif /* ! NO_UNALIGNED_EXCEPTIONS */ #if defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) xori r6, r5, 6; /* 00110 = FPU exception */ BEQI r6, handle_fp_ex; /* Go and decode the FP exception */ #endif /* defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) */ handle_other_ex: /* Handle Other exceptions here */ ori r6, r0, 20; cmp r6, r5, r6; /* >= 20 are exceptions we do not handle. */ BLEI r6, ex_handler_unhandled; ori r6, r0, 7; cmp r6, r5, r6; /* Convert MMU exception indices into an ordinal of 7 */ BGTI r6, handle_other_ex_tail; ori r5, r0, 0x7; handle_other_ex_tail: PUSH_REG(7); /* Save other volatiles before we make procedure calls below */ PUSH_REG(8); PUSH_REG(9); PUSH_REG(10); PUSH_REG(11); PUSH_REG(12); PUSH_REG(15); PUSH_REG(18); ADDIK r4, r0, MB_ExceptionVectorTable; /* Load the Exception vector table base address */ ADDK r7, r5, r5; /* Calculate exception vector offset = r5 * 8 (32-bit) */ ADDK r7, r7, r7; ADDK r7, r7, r7; #if defined (__arch64__) ADDK r7, r7, r7; /* or r5 * 16 (64-bit) */ #endif ADDK r7, r7, r4; /* Get pointer to exception vector */ LI r5, r7, REGSIZE; /* Load argument to exception handler from table */ LOAD r7, r7, r0; /* Load vector itself here */ brald r15, r7; /* Branch to handler */ nop; POP_REG(7); /* Restore other volatiles */ POP_REG(8); POP_REG(9); POP_REG(10); POP_REG(11); POP_REG(12); POP_REG(15); POP_REG(18); BRI ex_handler_done; /* Complete exception handling */ #ifndef NO_UNALIGNED_EXCEPTIONS handle_unaligned_ex: andi r6, r3, ESR_REG_MASK; /* Mask and extract the register operand */ srl r6, r6; /* r6 >> 5 */ srl r6, r6; srl r6, r6; srl r6, r6; srl r6, r6; sbi r6, r0, ex_reg_op; /* Store the register operand in a temporary location */ mfs r4, rear; andi r6, r3, ESR_LW_SW_MASK; /* Extract ESR[S] */ BNEI r6, ex_sw; #if defined (__arch64__) ex_ll: andi r6, r3, ESR_LONG_MASK; /* Extract ESR[L] */ BEQI r6, ex_lw; lbui r5, r4, 0; /* Exception address in r4 */ sbi r5, r0, ex_tmp_data_loc_0; /* Load a long, byte-by-byte from destination address and save it in tmp space */ lbui r5, r4, 1; sbi r5, r0, ex_tmp_data_loc_1; lbui r5, r4, 2; sbi r5, r0, ex_tmp_data_loc_2; lbui r5, r4, 3; sbi r5, r0, ex_tmp_data_loc_3; lbui r5, r4, 4; sbi r5, r0, ex_tmp_data_loc_4; lbui r5, r4, 5; sbi r5, r0, ex_tmp_data_loc_5; lbui r5, r4, 6; sbi r5, r0, ex_tmp_data_loc_6; lbui r5, r4, 7; sbi r5, r0, ex_tmp_data_loc_7; lli r3, r0, ex_tmp_data_loc_0; /* Get the destination register value into r3 */ BRI ex_lw_tail; #endif ex_lw: andi r6, r3, ESR_WORD_MASK; /* Extract ESR[W] */ BEQI r6, ex_lhw; lbui r5, r4, 0; /* Exception address in r4 */ sbi r5, r0, ex_tmp_data_loc_0; /* Load a word, byte-by-byte from destination address and save it in tmp space */ lbui r5, r4, 1; sbi r5, r0, ex_tmp_data_loc_1; lbui r5, r4, 2; sbi r5, r0, ex_tmp_data_loc_2; lbui r5, r4, 3; sbi r5, r0, ex_tmp_data_loc_3; lwi r3, r0, ex_tmp_data_loc_0; /* Get the destination register value into r3 */ BRI ex_lw_tail; ex_lhw: lbui r5, r4, 0; /* Exception address in r4 */ sbi r5, r0, ex_tmp_data_loc_0; /* Load a half-word, byte-by-byte from destination address and save it in tmp space */ lbui r5, r4, 1; sbi r5, r0, ex_tmp_data_loc_1; lhui r3, r0, ex_tmp_data_loc_0; /* Get the destination register value into r3 */ ex_lw_tail: lbui r5, r0, ex_reg_op; /* Get the destination register number into r5 */ ADDIK r6, r0, lw_table; /* Form load_word jump table offset (lw_table + (8 * regnum)) */ ADDK r5, r5, r5; ADDK r5, r5, r5; ADDK r5, r5, r5; ADDK r5, r5, r6; bra r5; ex_lw_end: /* Exception handling of load word, ends */ ex_sw: lbui r5, r0, ex_reg_op; /* Get the destination register number into r5 */ ADDIK r6, r0, sw_table; /* Form store_word jump table offset (sw_table + (8 * regnum)) */ ADDK r5, r5, r5; ADDK r5, r5, r5; ADDK r5, r5, r5; ADDK r5, r5, r6; bra r5; ex_sw_tail: #if defined (__arch64__) ex_sl: mfs r6, resr; andi r6, r6, ESR_LONG_MASK; /* Extract ESR[L] */ BEQI r6, ex_not_sl; sli r3, r0, ex_tmp_data_loc_0; lbui r3, r0, ex_tmp_data_loc_0; /* Store the long, byte-by-byte into destination address */ sbi r3, r4, 0; lbui r3, r0, ex_tmp_data_loc_1; sbi r3, r4, 1; lbui r3, r0, ex_tmp_data_loc_2; sbi r3, r4, 2; lbui r3, r0, ex_tmp_data_loc_3; sbi r3, r4, 3; lbui r3, r0, ex_tmp_data_loc_4; sbi r3, r4, 4; lbui r3, r0, ex_tmp_data_loc_5; sbi r3, r4, 5; lbui r3, r0, ex_tmp_data_loc_6; sbi r3, r4, 6; lbui r3, r0, ex_tmp_data_loc_7; sbi r3, r4, 7; BRI ex_handler_done; ex_not_sl: #endif mfs r6, resr; andi r6, r6, ESR_WORD_MASK; /* Extract ESR[W] */ BEQI r6, ex_shw; swi r3, r0, ex_tmp_data_loc_0; lbui r3, r0, ex_tmp_data_loc_0; /* Store the word, byte-by-byte into destination address */ sbi r3, r4, 0; lbui r3, r0, ex_tmp_data_loc_1; sbi r3, r4, 1; lbui r3, r0, ex_tmp_data_loc_2; sbi r3, r4, 2; lbui r3, r0, ex_tmp_data_loc_3; sbi r3, r4, 3; BRI ex_handler_done; ex_shw: swi r3, r0, ex_tmp_data_loc_0; /* Store the lower half-word, byte-by-byte into destination address */ #ifdef __LITTLE_ENDIAN__ lbui r3, r0, ex_tmp_data_loc_0; #else lbui r3, r0, ex_tmp_data_loc_2; #endif sbi r3, r4, 0; #ifdef __LITTLE_ENDIAN__ lbui r3, r0, ex_tmp_data_loc_1; #else lbui r3, r0, ex_tmp_data_loc_3; #endif sbi r3, r4, 1; ex_sw_end: /* Exception handling of store word, ends. */ BRI ex_handler_done; #endif /* !NO_UNALIGNED_EXCEPTIONS */ #if defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) handle_fp_ex: ADDIK r3, r17, -4; /* r17 contains (addr of exception causing FP instruction + 4) */ lw r4, r0, r3; /* We might find ourselves in a spot here. Unguaranteed load */ handle_fp_ex_opb: ADDIK r6, r0, fp_table_opb; /* Decode opB and store its value in mb_fpex_op_b */ srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; andi r3, r4, 0x1F; ADDK r3, r3, r3; /* Calculate (fp_table_opb + (regno * 12)) in r5 */ ADDK r3, r3, r3; ADDK r5, r3, r3; ADDK r5, r5, r3; ADDK r5, r5, r6; bra r5; handle_fp_ex_opa: ADDIK r6, r0, fp_table_opa; /* Decode opA and store its value in mb_fpex_op_a */ srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; srl r4, r4; andi r3, r4, 0x1F; ADDK r3, r3, r3; /* Calculate (fp_table_opb + (regno * 12)) in r5 */ ADDK r3, r3, r3; ADDK r5, r3, r3; ADDK r5, r5, r3; ADDK r5, r5, r6; bra r5; handle_fp_ex_done: ori r5, r0, 6; /* Set exception number back to 6 */ BRI handle_other_ex_tail; fp_ex_unhandled: bri 0; #endif /* defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) */ ex_handler_done: POP_R17; POP_MSR; POP_REG(3); POP_REG(4); POP_REG(5); POP_REG(6); ADDIK r1, r1, (EX_HANDLER_STACK_SIZ); /* Restore stack frame */ rted r17, 0 nop ex_handler_unhandled: bri 0 /* UNHANDLED. TRAP HERE */ .end _hw_exception_handler #ifndef NO_UNALIGNED_EXCEPTIONS /* * hw_exception_handler Jump Table * - Contains code snippets for each register that caused the unaligned exception. * - Hence exception handler is NOT self-modifying * - Separate table for load exceptions and store exceptions. * - Each table is of size: (8 * 32) = 256 bytes */ .section .text .align 4 lw_table: lw_r0: R3_TO_LWREG (0); lw_r1: LWREG_NOP; lw_r2: R3_TO_LWREG (2); lw_r3: R3_TO_LWREG_V (3); lw_r4: R3_TO_LWREG_V (4); lw_r5: R3_TO_LWREG_V (5); lw_r6: R3_TO_LWREG_V (6); lw_r7: R3_TO_LWREG (7); lw_r8: R3_TO_LWREG (8); lw_r9: R3_TO_LWREG (9); lw_r10: R3_TO_LWREG (10); lw_r11: R3_TO_LWREG (11); lw_r12: R3_TO_LWREG (12); lw_r13: R3_TO_LWREG (13); lw_r14: R3_TO_LWREG (14); lw_r15: R3_TO_LWREG (15); lw_r16: R3_TO_LWREG (16); lw_r17: LWREG_NOP; lw_r18: R3_TO_LWREG (18); lw_r19: R3_TO_LWREG (19); lw_r20: R3_TO_LWREG (20); lw_r21: R3_TO_LWREG (21); lw_r22: R3_TO_LWREG (22); lw_r23: R3_TO_LWREG (23); lw_r24: R3_TO_LWREG (24); lw_r25: R3_TO_LWREG (25); lw_r26: R3_TO_LWREG (26); lw_r27: R3_TO_LWREG (27); lw_r28: R3_TO_LWREG (28); lw_r29: R3_TO_LWREG (29); lw_r30: R3_TO_LWREG (30); lw_r31: R3_TO_LWREG (31); sw_table: sw_r0: SWREG_TO_R3 (0); sw_r1: SWREG_NOP; sw_r2: SWREG_TO_R3 (2); sw_r3: SWREG_TO_R3_V (3); sw_r4: SWREG_TO_R3_V (4); sw_r5: SWREG_TO_R3_V (5); sw_r6: SWREG_TO_R3_V (6); sw_r7: SWREG_TO_R3 (7); sw_r8: SWREG_TO_R3 (8); sw_r9: SWREG_TO_R3 (9); sw_r10: SWREG_TO_R3 (10); sw_r11: SWREG_TO_R3 (11); sw_r12: SWREG_TO_R3 (12); sw_r13: SWREG_TO_R3 (13); sw_r14: SWREG_TO_R3 (14); sw_r15: SWREG_TO_R3 (15); sw_r16: SWREG_TO_R3 (16); sw_r17: SWREG_NOP; sw_r18: SWREG_TO_R3 (18); sw_r19: SWREG_TO_R3 (19); sw_r20: SWREG_TO_R3 (20); sw_r21: SWREG_TO_R3 (21); sw_r22: SWREG_TO_R3 (22); sw_r23: SWREG_TO_R3 (23); sw_r24: SWREG_TO_R3 (24); sw_r25: SWREG_TO_R3 (25); sw_r26: SWREG_TO_R3 (26); sw_r27: SWREG_TO_R3 (27); sw_r28: SWREG_TO_R3 (28); sw_r29: SWREG_TO_R3 (29); sw_r30: SWREG_TO_R3 (30); sw_r31: SWREG_TO_R3 (31); /* Temporary data structures used in the handler */ .section .data .align DATAALIGN ex_tmp_data_loc_0: .byte 0 ex_tmp_data_loc_1: .byte 0 ex_tmp_data_loc_2: .byte 0 ex_tmp_data_loc_3: .byte 0 #if defined (__arch64__) ex_tmp_data_loc_4: .byte 0 ex_tmp_data_loc_5: .byte 0 ex_tmp_data_loc_6: .byte 0 ex_tmp_data_loc_7: .byte 0 #endif ex_reg_op: .byte 0 #endif /* ! NO_UNALIGNED_EXCEPTIONS */ #if defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) /* * FP exception decode jump table. * - Contains code snippets for each register that could have been a source operand for an excepting FP instruction * - Hence exception handler is NOT self-modifying * - Separate table for opA and opB * - Each table is of size: (12 * 32) = 384 bytes */ .section .text .align 4 fp_table_opa: opa_r0: FP_EX_OPA_SAVE (0); opa_r1: FP_EX_UNHANDLED; opa_r2: FP_EX_OPA_SAVE (2); opa_r3: FP_EX_OPA_SAVE_V (3); opa_r4: FP_EX_OPA_SAVE_V (4); opa_r5: FP_EX_OPA_SAVE_V (5); opa_r6: FP_EX_OPA_SAVE_V (6); opa_r7: FP_EX_OPA_SAVE (7); opa_r8: FP_EX_OPA_SAVE (8); opa_r9: FP_EX_OPA_SAVE (9); opa_r10: FP_EX_OPA_SAVE (10); opa_r11: FP_EX_OPA_SAVE (11); opa_r12: FP_EX_OPA_SAVE (12); opa_r13: FP_EX_OPA_SAVE (13); opa_r14: FP_EX_UNHANDLED; opa_r15: FP_EX_UNHANDLED; opa_r16: FP_EX_UNHANDLED; opa_r17: FP_EX_UNHANDLED; opa_r18: FP_EX_OPA_SAVE (18); opa_r19: FP_EX_OPA_SAVE (19); opa_r20: FP_EX_OPA_SAVE (20); opa_r21: FP_EX_OPA_SAVE (21); opa_r22: FP_EX_OPA_SAVE (22); opa_r23: FP_EX_OPA_SAVE (23); opa_r24: FP_EX_OPA_SAVE (24); opa_r25: FP_EX_OPA_SAVE (25); opa_r26: FP_EX_OPA_SAVE (26); opa_r27: FP_EX_OPA_SAVE (27); opa_r28: FP_EX_OPA_SAVE (28); opa_r29: FP_EX_OPA_SAVE (29); opa_r30: FP_EX_OPA_SAVE (30); opa_r31: FP_EX_OPA_SAVE (31); fp_table_opb: opb_r0: FP_EX_OPB_SAVE (0); opb_r1: FP_EX_UNHANDLED; opb_r2: FP_EX_OPB_SAVE (2); opb_r3: FP_EX_OPB_SAVE_V (3); opb_r4: FP_EX_OPB_SAVE_V (4); opb_r5: FP_EX_OPB_SAVE_V (5); opb_r6: FP_EX_OPB_SAVE_V (6); opb_r7: FP_EX_OPB_SAVE (7); opb_r8: FP_EX_OPB_SAVE (8); opb_r9: FP_EX_OPB_SAVE (9); opb_r10: FP_EX_OPB_SAVE (10); opb_r11: FP_EX_OPB_SAVE (11); opb_r12: FP_EX_OPB_SAVE (12); opb_r13: FP_EX_OPB_SAVE (13); opb_r14: FP_EX_UNHANDLED; opb_r15: FP_EX_UNHANDLED; opb_r16: FP_EX_UNHANDLED; opb_r17: FP_EX_UNHANDLED; opb_r18: FP_EX_OPB_SAVE (18); opb_r19: FP_EX_OPB_SAVE (19); opb_r20: FP_EX_OPB_SAVE (20); opb_r21: FP_EX_OPB_SAVE (21); opb_r22: FP_EX_OPB_SAVE (22); opb_r23: FP_EX_OPB_SAVE (23); opb_r24: FP_EX_OPB_SAVE (24); opb_r25: FP_EX_OPB_SAVE (25); opb_r26: FP_EX_OPB_SAVE (26); opb_r27: FP_EX_OPB_SAVE (27); opb_r28: FP_EX_OPB_SAVE (28); opb_r29: FP_EX_OPB_SAVE (29); opb_r30: FP_EX_OPB_SAVE (30); opb_r31: FP_EX_OPB_SAVE (31); #endif /* defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) */ #if defined(MICROBLAZE_FP_EXCEPTION_ENABLED) && defined(MICROBLAZE_FP_EXCEPTION_DECODE) /* This is where we store the opA and opB of the last excepting FP instruction */ .section .data .align DATAALIGN .global mb_fpex_op_a .global mb_fpex_op_b mb_fpex_op_a: INTPTR_DATAITEM 0 mb_fpex_op_b: INTPTR_DATAITEM 0 #endif /* defined (MICROBLAZE_FP_EXCEPTION_ENABLED) && defined (MICROBLAZE_FP_EXCEPTION_DECODE) */ #if defined(XPAR_MICROBLAZE_USE_STACK_PROTECTION) && (XPAR_MICROBLAZE_USE_STACK_PROTECTION == 1) /* This is where we store the register used to check which exception occurred */ .section .data .align DATAALIGN mb_sp_save_r3: INTPTR_DATAITEM 0 #endif /* defined(XPAR_MICROBLAZE_USE_STACK_PROTECTION) && (XPAR_MICROBLAZE_USE_STACK_PROTECTION == 1) */ /* The exception vector table */ .section .data .align DATAALIGN .global MB_ExceptionVectorTable MB_ExceptionVectorTable: INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 0 /* -- FSL Exception -- */ INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 1 /* -- Unaligned Access Exception -- */ INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 2 /* -- Illegal Opcode Exception -- */ INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 3 /* -- Instruction Bus Exception -- */ INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 4 /* -- Data Bus Exception -- */ INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 5 /* -- Div-by-0 Exception -- */ INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 6 /* -- FPU Exception -- */ INTPTR_DATAITEM XNullHandler INTPTR_DATAITEM 7 /* -- MMU Exceptions -- */ #else /* Dummy exception handler, in case exceptions are not present in the processor */ .global _hw_exception_handler .section .text .align 2 .ent _hw_exception_handler _hw_exception_handler: bri 0; .end _hw_exception_handler #endif /* MICROBLAZE_EXCEPTIONS_ENABLED */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

2,550

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_update_dcache.S

/****************************************************************************** * Copyright (c) 2006 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * * File : microblaze_update_dcache.s * Date : 2003, September 24 * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Update dcache on the microblaze. * Takes in three parameters * r5 : Cache Tag Line * r6 : Cache Data * r7 : Lock/Valid information * Bit 30 is Lock [ 1 indicates locked ] * Bit 31 is Valid [ 1 indicates valid ] * * -------------------------------------------------------------- * | Lock | Valid | Effect * -------------------------------------------------------------- * | 0 | 0 | Invalidate Cache * | 0 | 1 | Valid, but unlocked cacheline * | 1 | 0 | Invalidate Cache, No effect of lock * | 1 | 1 | Valid cache. Locked to a * | | | particular address * -------------------------------------------------------------- * * **********************************************************************************/ #include "xparameters.h" #ifndef XPAR_MICROBLAZE_DCACHE_LINE_LEN #define XPAR_MICROBLAZE_DCACHE_LINE_LEN 1 #endif .text .globl microblaze_update_dcache .ent microblaze_update_dcache .align 2 microblaze_update_dcache: #if (XPAR_MICROBLAZE_USE_DCACHE==1) && (XPAR_MICROBLAZE_ALLOW_DCACHE_WR==1) #if XPAR_MICROBLAZE_DCACHE_LINE_LEN == 1 /* Read the MSR register into a temp register */ mfs r18, rmsr /* Clear the dcache enable bit to disable the cache Register r10,r18 are volatile registers and hence do not need to be saved before use */ andi r10, r18, ~128 mts rmsr, r10 /* Update the lock and valid info */ andi r5, r5, 0xfffffffc or r5, r5, r7 /* Update dcache */ wdc r5, r6 /* Return */ rtsd r15, 8 mts rmsr, r18 #else /* The only valid usage of this routine for larger cache line lengths is to invalidate a data cache line So call microblaze_init_dcache_range appropriately to do the job */ brid microblaze_init_dcache_range addik r6, r0, (XPAR_MICROBLAZE_DCACHE_LINE_LEN * 4) /* We don't have a return instruction here. This is tail call optimization :) */ #endif /* XPAR_MICROBLAZE_DCACHE_LINE_LEN == 1 */ #else rtsd r15, 8 nop #endif .end microblaze_update_dcache

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,044

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_disable_icache.S

/****************************************************************************** * Copyright (c) 2004 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * File : microblaze_disable_icache.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Disable L1 icache on the microblaze. * * ******************************************************************************/ #include "xparameters.h" .text .globl microblaze_disable_icache .ent microblaze_disable_icache .align 2 microblaze_disable_icache: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 rtsd r15, 8 msrclr r0, 0x20 #else /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ #Read the MSR register mfs r8, rmsr #Clear the icache enable bit andi r8, r8, ~(0x20) #Save the MSR register mts rmsr, r8 #Return rtsd r15, 8 nop #endif .end microblaze_disable_icache

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,676

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_disable_dcache.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * File : microblaze_disable_dcache.s * Date : 2002, March 20. * Company: Xilinx * Group : Emerging Software Technologies * * Summary: * Disable the L1 dcache on the microblaze. * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" .text .globl microblaze_disable_dcache .ent microblaze_disable_dcache .align 2 microblaze_disable_dcache: #if XPAR_MICROBLAZE_USE_MSR_INSTR == 1 #if XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 ADDIK r1, r1, -8 SI r15, r1, 0 BRLID r15, microblaze_flush_dcache /* microblaze_flush_dcache does not use r1*/ nop LI r15, r1, 0 ADDIK r1, r1, 8 #endif /* XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 */ rtsd r15, 8 msrclr r0, 0x80 #else /* XPAR_MICROBLAZE_USE_MSR_INSTR == 1 */ ADDIK r1, r1, -8 #if XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 SI r15, r1, 0 BRLID r15, microblaze_flush_dcache nop #endif /* XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 */ mfs r11, rmsr andi r11, r11, ~(0x80) mts rmsr, r11 #if XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 LI r15, r1, 0 #endif /* XPAR_MICROBLAZE_DCACHE_USE_WRITEBACK != 0 */ ADDIK r1, r1, 8 rtsd r15, 8 nop #endif /*XPAR_MICROBLAZE_USE_MSR_INSTR == 1*/ .end microblaze_disable_dcache

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,428

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/microblaze/microblaze_invalidate_cache_ext.S

/****************************************************************************** * Copyright (c) 2008 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /****************************************************************************** * * microblaze_invalidate_cache_ext() * *Invalidate the entire L2 Cache * * *******************************************************************************/ #include "xparameters.h" #include "microblaze_instructions.h" #define XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN 16 #define CACHEABLE_REGION_SIZE (XPAR_MICROBLAZE_DCACHE_HIGHADDR - XPAR_MICROBLAZE_DCACHE_BASEADDR) .text .globl microblaze_invalidate_cache_ext .ent microblaze_invalidate_cache_ext .align 2 microblaze_invalidate_cache_ext: #if ((XPAR_MICROBLAZE_INTERCONNECT==3) && (XPAR_MICROBLAZE_USE_DCACHE==1)) ADDIK r5, r0, XPAR_MICROBLAZE_DCACHE_BASEADDR & (-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN)) ADDIK r6, r0, CACHEABLE_REGION_SIZE-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) ANDI r6, r6, -(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) Loop_start: wdc.ext.clear r5, r6 #if defined (__arch64__ ) addlik r6, r6,-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) beagei r6, Loop_start #else bgtid r6,Loop_start addik r6, r6,-(4 * XPAR_MICROBLAZE_EXT_CACHE_LINE_LEN) #endif #endif rtsd r15, 8 nop .end microblaze_invalidate_cache_ext

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

8,201

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/armclang/asm_vectors.S

;/****************************************************************************** ;* Copyright (c) 2019 - 2021 Xilinx, Inc. All rights reserved. ;* SPDX-License-Identifier: MIT ;******************************************************************************/ ;/*****************************************************************************/ ;/** ;* @file asm_vectors.S ;* ;* This file contains the initial vector table for the Cortex A53 processor ;* ;* <pre> ;* MODIFICATION HISTORY: ;* ;* Ver Who Date Changes ;* ----- ------- -------- --------------------------------------------------- ;* 7.0 cjp 02/26/19 First release ;* 7.7 asa 03/22/22 Updated FIQ handler to handle floating/SIMD context. ;* </pre> ;* ;* @note ;* ;* None. ;* ;******************************************************************************/ #include "bspconfig.h" EXPORT _vector_table EXPORT FPUStatus IMPORT _boot IMPORT FIQInterrupt IMPORT IRQInterrupt IMPORT SErrorInterrupt IMPORT SynchronousInterrupt ; ; FPUContextSize is the size of the array where floating point registers are ; stored when required. The default size corresponds to the case when there is ; no nested interrupt. If there are nested interrupts in application which are ; using floating point operation, the size of FPUContextSize need to be ; increased as per requirement ; FPUContextSize EQU 528 MACRO saveregister stp X0, X1, [sp,#-0x10]! stp X2, X3, [sp,#-0x10]! stp X4, X5, [sp,#-0x10]! stp X6, X7, [sp,#-0x10]! stp X8, X9, [sp,#-0x10]! stp X10, X11, [sp,#-0x10]! stp X12, X13, [sp,#-0x10]! stp X14, X15, [sp,#-0x10]! stp X16, X17, [sp,#-0x10]! stp X18, X19, [sp,#-0x10]! stp X29, X30, [sp,#-0x10]! MEND MACRO restoreregister ldp X29, X30, [sp], #0x10 ldp X18, X19, [sp], #0x10 ldp X16, X17, [sp], #0x10 ldp X14, X15, [sp], #0x10 ldp X12, X13, [sp], #0x10 ldp X10, X11, [sp], #0x10 ldp X8, X9, [sp], #0x10 ldp X6, X7, [sp], #0x10 ldp X4, X5, [sp], #0x10 ldp X2, X3, [sp], #0x10 ldp X0, X1, [sp], #0x10 MEND MACRO savefloatregister ldr x1, =FPUContextBase ; Load the floating point context array address from FPUContextBase ldr x0, [x1] stp q0, q1, [x0], #0x20 ; Save all the floating point register to the array stp q2, q3, [x0], #0x20 stp q4, q5, [x0], #0x20 stp q6, q7, [x0], #0x20 stp q8, q9, [x0], #0x20 stp q10, q11, [x0], #0x20 stp q12, q13, [x0], #0x20 stp q14, q15, [x0], #0x20 stp q16, q17, [x0], #0x20 stp q18, q19, [x0], #0x20 stp q20, q21, [x0], #0x20 stp q22, q23, [x0], #0x20 stp q24, q25, [x0], #0x20 stp q26, q27, [x0], #0x20 stp q28, q29, [x0], #0x20 stp q30, q31, [x0], #0x20 mrs x2, FPCR mrs x3, FPSR stp x2, x3, [x0], #0x10 str x0, [x1] ; Save current address of floating point context array to FPUContextBase MEND MACRO restorefloatregister ldr x1, =FPUContextBase ; Restore the address of floating point context array from FPUContextBase ldr x0, [x1] ldp x2, x3, [x0,#-0x10]! ; Restore all the floating point register from the array msr FPCR, x2 msr FPSR, x3 ldp q30, q31, [x0,#-0x20]! ldp q28, q29, [x0,#-0x20]! ldp q26, q27, [x0,#-0x20]! ldp q24, q25, [x0,#-0x20]! ldp q22, q23, [x0,#-0x20]! ldp q20, q21, [x0,#-0x20]! ldp q18, q19, [x0,#-0x20]! ldp q16, q17, [x0,#-0x20]! ldp q14, q15, [x0,#-0x20]! ldp q12, q13, [x0,#-0x20]! ldp q10, q11, [x0,#-0x20]! ldp q8, q9, [x0,#-0x20]! ldp q6, q7, [x0,#-0x20]! ldp q4, q5, [x0,#-0x20]! ldp q2, q3, [x0,#-0x20]! ldp q0, q1, [x0,#-0x20]! str x0, [x1] ; Save current address of floating point context array to FPUContextBase MEND AREA |.vectors|, CODE REQUIRE8 {TRUE} PRESERVE8 {TRUE} ENTRY ; Define this as an entry point _vector_table ; ; If application is built for XEN GUEST as EL1 Non-secure following image ; header is required by XEN. ; #if (HYP_GUEST == 1) ldr x16, =_boot ; Valid Image header br x16 ; HW reset vector DCD 0 ; Text offset DCD 0 ; Image size DCD 8 ; Flags DCD 0 ; RES0 DCD 0 DCD 0 DCD 0x644d5241 ; Magic DCD 0 ; RES0 #endif B _boot ALIGN 512 B SynchronousInterruptHandler ALIGN 128 B IRQInterruptHandler ALIGN 128 B FIQInterruptHandler ALIGN 128 B SErrorInterruptHandler SynchronousInterruptHandler saveregister ; Check if the Synchronous abort is occurred due to floating point access #if (EL3 == 1) mrs x0, ESR_EL3 #else mrs x0, ESR_EL1 #endif and x0, x0, #(0x3F << 26) mov x1, #(0x7 << 26) cmp x0, x1 ; ; If exception is not due to floating point access go to synchronous ; handler ; bne synchronoushandler ; ; If exception occurred due to floating point access, Enable the floating point ; access i.e. do not trap floating point instruction ; #if (EL3 == 1) mrs x1, CPTR_EL3 mov x2, #(0x1<<10) bic x1, x1, x2 msr CPTR_EL3, x1 #else mrs x1, CPACR_EL1 orr x1, x1, #(0x1<<20) msr CPACR_EL1, x1 #endif isb ; ; If the floating point access was previously enabled, store FPU context ; registers(storefloat) ; ldr x0, =FPUStatus ldrb w1, [x0] cbnz w1, storefloat ; ; If the floating point access was not enabled previously, save the status of ; floating point accessibility i.e. enabled and store floating point context ; array address(FPUContext) to FPUContextBase ; mov w1, #0x1 strb w1, [x0] ldr x0, =FPUContext ldr x1, =FPUContextBase str x0, [x1] b restorecontext storefloat savefloatregister b restorecontext synchronoushandler bl SynchronousInterrupt restorecontext restoreregister eret IRQInterruptHandler saveregister ; Save the status of SPSR, ELR and CPTR to stack #if (EL3 == 1) mrs x0, CPTR_EL3 mrs x1, ELR_EL3 mrs x2, SPSR_EL3 #else mrs x0, CPACR_EL1 mrs x1, ELR_EL1 mrs x2, SPSR_EL1 #endif stp x0, x1, [sp,#-0x10]! str x2, [sp,#-0x10]! ; Trap floating point access #if (EL3 == 1) mrs x1, CPTR_EL3 orr x1, x1, #(0x1<<10) msr CPTR_EL3, x1 #else mrs x1, CPACR_EL1 mov x2, #(0x1<<20) bic x1, x1, x2 msr CPACR_EL1, x1 #endif isb bl IRQInterrupt ; ; If floating point access is enabled during interrupt handling, restore ; floating point registers ; #if (EL3 == 1) mrs x0, CPTR_EL3 ands x0, x0, #(0x1<<10) bne RestorePrevState #else mrs x0, CPACR_EL1 ands x0, x0, #(0x1<<20) beq RestorePrevState #endif restorefloatregister ; Restore the status of SPSR, ELR and CPTR from stack RestorePrevState ldr x2, [sp], #0x10 ldp x0, x1, [sp],#0x10 #if (EL3 == 1) msr CPTR_EL3, x0 msr ELR_EL3, x1 msr SPSR_EL3, x2 #else msr CPACR_EL1, x0 msr ELR_EL1, x1 msr SPSR_EL1, x2 #endif restoreregister eret FIQInterruptHandler saveregister ; Save the status of SPSR, ELR and CPTR to stack #if (EL3 == 1) mrs x0, CPTR_EL3 mrs x1, ELR_EL3 mrs x2, SPSR_EL3 #else mrs x0, CPACR_EL1 mrs x1, ELR_EL1 mrs x2, SPSR_EL1 #endif stp x0, x1, [sp,#-0x10]! str x2, [sp,#-0x10]! ; Trap floating point access #if (EL3 == 1) mrs x1, CPTR_EL3 orr x1, x1, #(0x1<<10) msr CPTR_EL3, x1 #else mrs x1, CPACR_EL1 mov x2, #(0x1<<20) bic x1, x1, x2 msr CPACR_EL1, x1 #endif isb bl FIQInterrupt ; ; If floating point access is enabled during interrupt handling, restore ; floating point registers ; #if (EL3 == 1) mrs x0, CPTR_EL3 ands x0, x0, #(0x1<<10) bne RestorePrevStateFiq #else mrs x0, CPACR_EL1 ands x0, x0, #(0x1<<20) beq RestorePrevStateFiq #endif restorefloatregister ; Restore the status of SPSR, ELR and CPTR from stack RestorePrevStateFiq ldr x2, [sp], #0x10 ldp x0, x1, [sp],#0x10 #if (EL3 == 1) msr CPTR_EL3, x0 msr ELR_EL3, x1 msr SPSR_EL3, x2 #else msr CPACR_EL1, x0 msr ELR_EL1, x1 msr SPSR_EL1, x2 #endif restoreregister eret SErrorInterruptHandler saveregister bl SErrorInterrupt restoreregister eret ALIGN 8 ; Array to store floating point registers FPUContext SPACE FPUContextSize ; Stores address for floating point context array FPUContextBase SPACE 8 FPUStatus SPACE 4 END

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

11,341

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/armclang/boot.S

;/****************************************************************************** ;* Copyright (c) 2019 - 2021 Xilinx, Inc. All rights reserved. ;* SPDX-License-Identifier: MIT ;******************************************************************************/ ;/*****************************************************************************/ ;/** ;* @file boot.S ;* ;* @addtogroup a53_64_boot_code Cortex A53 64bit Processor Boot Code ;* @{ ;* <h2> boot.S </h2> ;* ;* The boot code performs minimum configuration which is required for an ;* application. Cortex-A53 starts by checking current exception level. If the ;* current exception level is EL3 and BSP is built for EL3, it will do ;* initialization required for application execution at EL3. Below is a ;* sequence illustrating what all configuration is performed before control ;* reaches to main function for EL3 execution. ;* ;* 1. Program vector table base for exception handling ;* 2. Set reset vector table base address ;* 3. Program stack pointer for EL3 ;* 4. Routing of interrupts to EL3 ;* 5. Enable ECC protection ;* 6. Program generic counter frequency ;* 7. Invalidate instruction cache, data cache and TLBs ;* 8. Configure MMU registers and program base address of translation table ;* 9. Transfer control to _start which clears BSS sections and runs global ;* constructor before jumping to main application ;* ;* If current exception level is EL1 and BSP is also built for EL1_NONSECURE ;* it will perform initialization required for application execution at EL1 ;* non-secure. For all other combination, the execution will go into infinite ;* loop. Below is a sequence illustrating what all configuration is performed ;* before control reaches to main function for EL1 execution. ;* ;* 1. Program vector table base for exception handling ;* 2. Program stack pointer for EL1 ;* 3. Invalidate instruction cache, data cache and TLBs ;* 4. Configure MMU registers and program base address of translation table ;* 5. Transfer control to _start which clears BSS sections and runs global ;* constructor before jumping to main application ;* ;* <pre> ;* MODIFICATION HISTORY: ;* ;* Ver Who Date Changes ;* ----- ------- -------- --------------------------------------------------- ;* 7.0 mus 02/26/19 First release ;* 7.2 mus 01/08/19 Added support for versal ;* sd 02/23/20 Clock Init is called ;* sd 03/21/20 Added XCLOCKING flag ;* </pre> ;******************************************************************************/ #include "xparameters.h" #include "bspconfig.h" #include "xil_errata.h" EXPORT _prestart EXPORT _boot IMPORT MMUTableL0 IMPORT |Image$$ARM_LIB_STACK$$ZI$$Base| IMPORT _vector_table IMPORT __main #ifdef XCLOCKING IMPORT Xil_ClockInit #endif #ifndef FREERTOS_BSP IMPORT FPUStatus #endif rvbar_base EQU 0xFD5C0040 MODE_EL1 EQU 0x5 DAIF_BIT EQU 0x1C0 TT_S1_FAULT EQU 0x0 TT_S1_TABLE EQU 0x3 AREA |.boot|, CODE ; This initializes the various processor modes _prestart _boot mov x0, #0 mov x1, #0 mov x2, #0 mov x3, #0 mov x4, #0 mov x5, #0 mov x6, #0 mov x7, #0 mov x8, #0 mov x9, #0 mov x10, #0 mov x11, #0 mov x12, #0 mov x13, #0 mov x14, #0 mov x15, #0 mov x16, #0 mov x17, #0 mov x18, #0 mov x19, #0 mov x20, #0 mov x21, #0 mov x22, #0 mov x23, #0 mov x24, #0 mov x25, #0 mov x26, #0 mov x27, #0 mov x28, #0 mov x29, #0 mov x30, #0 OKToRun mrs x0, currentEL cmp x0, #0xC beq InitEL3 cmp x0, #0x4 beq InitEL1 b error ; Go to error if current exception level is neither EL3 nor EL1 InitEL3 #if (EL3 == 1) ldr x1, =_vector_table ; Set vector table base address msr VBAR_EL3, x1 mrs x0, MPIDR_EL1 ; Get the CPU ID and x0, x0, #0xFF mov w0, w0 ldr w2, =rvbar_base ; Calculate the rvbar base address for particular CPU core mov w3, #0x8 mul w0, w0, w3 add w2, w2, w0 str x1, [x2] ; Store vector base address to rvbar ldr x2, =|Image$$ARM_LIB_STACK$$ZI$$Base| ; Define stack pointer for current exception level mov sp, x2 mov x0, #0 ; Enable Trapping of SIMD/FPU register for standalone BSP #ifndef FREERTOS_BSP orr x0, x0, #(0x1 << 10) #endif msr CPTR_EL3, x0 isb ; ; Clear FPUStatus variable to make sure that it contains current ; status of FPU i.e. disabled. In case of a warm restart execution ; when bss sections are not cleared, it may contain previously updated ; value which does not hold true now ; #ifndef FREERTOS_BSP ldr x0, =FPUStatus str xzr, [x0] #endif ; Configure SCR_EL3 mov w1, #0 ; Initial value of register is unknown orr w1, w1, #(1 << 11) ; Set ST bit (Secure EL1 can access CNTPS_TVAL_EL1, CNTPS_CTL_EL1 & CNTPS_CVAL_EL1) orr w1, w1, #(1 << 10) ; Set RW bit (EL1 is AArch64, as this is the Secure world) orr w1, w1, #(1 << 3) ; Set EA bit (SError routed to EL3) orr w1, w1, #(1 << 2) ; Set FIQ bit (FIQs routed to EL3) orr w1, w1, #(1 << 1) ; Set IRQ bit (IRQs routed to EL3) msr SCR_EL3, x1 ; Configure cpu auxiliary control register EL1 ldr x0, =0x80CA000 ; L1 Data prefetch control - 5, Enable device split throttle, 2 independent data prefetch streams #if (CONFIG_ARM_ERRATA_855873) ; ; Set ENDCCASCI bit in CPUACTLR_EL1 register, to execute data ; cache clean operations as data cache clean and invalidate ; orr x0, x0, #(1 << 44) ; Set ENDCCASCI bit #endif msr S3_1_C15_C2_0, x0 ; CPUACTLR_EL1 ; Program the counter frequency #if defined (versal) ldr x0, =XPAR_CPU_CORTEXA72_0_TIMESTAMP_CLK_FREQ #else ldr x0, =XPAR_CPU_CORTEXA53_0_TIMESTAMP_CLK_FREQ msr CNTFRQ_EL0, x0 #endif ; Enable hardware coherency between cores mrs x0, S3_1_c15_c2_1 ; Read EL1 CPU Extended Control Register orr x0, x0, #(1 << 6) ; Set the SMPEN bit msr S3_1_c15_c2_1, x0 ; Write EL1 CPU Extended Control Register isb tlbi ALLE3 ic IALLU ; Invalidate I cache to PoU bl invalidate_dcaches dsb sy isb ldr x1, =MMUTableL0 ; Get address of level 0 for TTBR0_EL3 msr TTBR0_EL3, x1 ; Set TTBR0_EL3 ; ; Set up memory attributes ; This equates to: ; 0 = b01000100 = Normal, Inner/Outer Non-Cacheable ; 1 = b11111111 = Normal, Inner/Outer WB/WA/RA ; 2 = b00000000 = Device-nGnRnE ; 3 = b00000100 = Device-nGnRE ; 4 = b10111011 = Normal, Inner/Outer WT/WA/RA ; ldr x1, =0x000000BB0400FF44 msr MAIR_EL3, x1 #if defined (versal) ; Set up TCR_EL3 ; Physical Address Size PS = 100 -> 44bits 16 TB ; Granual Size TG0 = 00 -> 4KB ; size offset of the memory region T0SZ = 20 -> (region size 2^(64-20) = 2^44) ldr x1,=0x80843514 #else ; ; Set up TCR_EL3 ; Physical Address Size PS = 010 -> 40bits 1TB ; Granule Size TG0 = 00 -> 4KB ; Size offset of the memory region T0SZ = 24 -> (region size 2^(64-24) = 2^40) ; ldr x1, =0x80823518 #endif msr TCR_EL3, x1 isb ; Enable SError Exception for asynchronous abort mrs x1, DAIF mov x2, #(0x1<<8) bic x1, x1, x2 msr DAIF, x1 ; Configure SCTLR_EL3 mov x1, #0 ; Most of the SCTLR_EL3 bits are unknown at reset orr x1, x1, #(1 << 12) ; Enable I cache orr x1, x1, #(1 << 3) ; Enable SP alignment check orr x1, x1, #(1 << 2) ; Enable caches orr x1, x1, #(1 << 0) ; Enable MMU msr SCTLR_EL3, x1 dsb sy isb #ifdef XCLOCKING b Xil_Clockinit #endif b __main ; Jump to start #else b error ; Present exception level and selected exception level mismatch #endif InitEL1 #if (EL1_NONSECURE == 1) ldr x1, =_vector_table ; Set vector table base address msr VBAR_EL1, x1 mrs x0, CPACR_EL1 mov x2, #(0x3 << 0x20) bic x0, x0, x2 msr CPACR_EL1, x0 isb ; ; Clear FPUStatus variable to make sure that it contains current ; status of FPU i.e. disabled. In case of a warm restart execution ; when bss sections are not cleared, it may contain previously updated ; value which does not hold true now ; #ifndef FREERTOS_BSP ldr x0, =FPUStatus str xzr, [x0] #endif ldr x2, =|Image$$ARM_LIB_STACK$$ZI$$Base| ; Define stack pointer for current exception level mov sp, x2 ; Disable MMU mov x1, #0x0 msr SCTLR_EL1, x1 isb TLBI VMALLE1 ic IALLU ; Invalidate I cache to PoU bl invalidate_dcaches dsb sy isb ldr x1, =MMUTableL0 ; Get address of level 0 for TTBR0_EL1 msr TTBR0_EL1, x1 ; Set TTBR0_EL1 ; ; Set up memory attributes ; This equates to: ; 0 = b01000100 = Normal, Inner/Outer Non-Cacheable ; 1 = b11111111 = Normal, Inner/Outer WB/WA/RA ; 2 = b00000000 = Device-nGnRnE ; 3 = b00000100 = Device-nGnRE ; 4 = b10111011 = Normal, Inner/Outer WT/WA/RA ; ldr x1, =0x000000BB0400FF44 msr MAIR_EL1, x1 #if defined (versal) ; ; Set up TCR_EL1 ; Physical Address Size PS = 100 -> 44bits 16TB ; Granual Size TG0 = 00 -> 4KB ; size offset of the memory region T0SZ = 20 -> (region size 2^(64-20) = 2^44) ; ldr x1,=0x485800514 #else ; ; Set up TCR_EL1 ; Physical Address Size PS = 010 -> 40bits 1TB ; Granule Size TG0 = 00 -> 4KB ; Size offset of the memory region T0SZ = 24 -> (region size 2^(64-24) = 2^40) ; ldr x1, =0x285800518 #endif msr TCR_EL1, x1 isb ; Enable SError Exception for asynchronous abort mrs x1,DAIF mov x2, #(0x1<<8) bic x1,x1,x2 msr DAIF,x1 ; Enable MMU mov x1,#0x0 orr x1, x1, #(1 << 18) ; Set WFE non trapping orr x1, x1, #(1 << 17) ; Set WFI non trapping orr x1, x1, #(1 << 5) ; Set CP15 barrier enabled orr x1, x1, #(1 << 12) ; Set I bit orr x1, x1, #(1 << 2) ; Set C bit orr x1, x1, #(1 << 0) ; Set M bit msr SCTLR_EL1, x1 isb bl __main ; Jump to start #else b error ; present exception level and selected exception level mismatch #endif error b error invalidate_dcaches dmb ISH mrs x0, CLIDR_EL1 ; x0 = CLIDR ubfx w2, w0, #24, #3 ; w2 = CLIDR>Loc cmp w2, #0 ; LoC is 0? b.eq invalidateCaches_end ; No cleaning required and enable MMU mov w1, #0 ; w1 = level iterator invalidateCaches_flush_level add w3, w1, w1, lsl #1 ; w3 = w1 * 3 (right-shift for cache type) lsr w3, w0, w3 ; w3 = w0 >> w3 ubfx w3, w3, #0, #3 ; w3 = cache type of this level cmp w3, #2 ; No cache at this level? b.lt invalidateCaches_next_level lsl w4, w1, #1 msr CSSELR_EL1, x4 ; Select current cache level in CSSELR isb ; ISB required to reflect new CSIDR mrs x4, CCSIDR_EL1 ; w4 = CSIDR ubfx w3, w4, #0, #3 add w3, w3, #2 ; w3 = log2(line size) ubfx w5, w4, #13, #15 ubfx w4, w4, #3, #10 ; w4 = Way number clz w6, w4 ; w6 = 32 - log2(number of ways) invalidateCaches_flush_set mov w8, w4 ; w8 = Way number invalidateCaches_flush_way lsl w7, w1, #1 ; Fill level field lsl w9, w5, w3 orr w7, w7, w9 ; Fill index field lsl w9, w8, w6 orr w7, w7, w9 ; Fill way field dc CISW, x7 ; Invalidate by set/way to point of coherency subs w8, w8, #1 ; Decrement way b.ge invalidateCaches_flush_way subs w5, w5, #1 ; Decrement set b.ge invalidateCaches_flush_set invalidateCaches_next_level add w1, w1, #1 ; Next level cmp w2, w1 b.gt invalidateCaches_flush_level invalidateCaches_end ret END ; ; @} End of "addtogroup a53_64_boot_code" ;

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,679

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/xpvxenconsole/hypercall.S

/* Copyright DornerWorks 2016 Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: 1. Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. THIS SOFTWARE IS PROVIDED BY DORNERWORKS FOR USE ON THE CONTRACTED PROJECT, AND ANY EXPRESS OR IMPLIED WARRANTY IS LIMITED TO THIS USE. FOR ALL OTHER USES THIS SOFTWARE IS PROVIDED ''AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL DORNERWORKS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include "xen.h" .globl HYPERVISOR_console_io; .align 4; HYPERVISOR_console_io: mov x16, __HYPERVISOR_console_io; hvc 0xEA1; ret; .globl HYPERVISOR_hvm_op; .align 4; HYPERVISOR_hvm_op: mov x16, __HYPERVISOR_hvm_op; hvc 0xEA1; ret; .globl HYPERVISOR_memory_op; .align 4; HYPERVISOR_memory_op: mov x16, __HYPERVISOR_memory_op; hvc 0xEA1; ret; .globl HYPERVISOR_event_channel_op; .align 4; HYPERVISOR_event_channel_op: mov x16, __HYPERVISOR_event_channel_op hvc 0xEA1; ret;

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

4,386

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/gcc/xil-crt0.S

/****************************************************************************** * Copyright (C) 2014 - 2022 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file xil-crt0.S * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 5.00 pkp 05/21/14 Initial version * 5.04 pkp 12/18/15 Initialized global constructor for C++ applications * 5.04 pkp 01/05/16 Set the reset vector register RVBAR equivalent to * vector table base address * 6.02 pkp 01/22/17 Added support for EL1 non-secure * 6.6 srm 10/18/17 Added timer configuration using XTime_StartTTCTimer API. * Now the TTC instance as specified by the user will be * started. * 6.6 mus 01/29/18 Initialized the xen PV console for Cortexa53 64 bit * EL1 NS BSP. * 7.2 sd 02/23/20 Clock Init is called * 7.2 sd 02/23/20 Clock code added under XCLOCKING flag * 7.7 mus 01/06/22 Added call to Xil_SetTlbAttributes to set correct * attributes for GIC in case of Xen domU guest application. * It fixes CR#974078. * 8.0 mus 07/06/21 Added support for VERSAL NET * 8.0 mus 06/27/22 Enabled PMU counter. * </pre> * * @note * * None. * ******************************************************************************/ #include "xparameters.h" #include "bspconfig.h" .file "xil-crt0.S" .section ".got2","aw" .align 2 .text .Lsbss_start: .quad __sbss_start .Lsbss_end: .quad __sbss_end .Lbss_start: .quad __bss_start__ .Lbss_end: .quad __bss_end__ .set APU_PWRCTL, 0xFD5C0090 .globl _startup _startup: mov x0, #0 #if ! defined(VERSAL_NET) .if (EL3 == 1) /* Check whether the clearing of bss sections shall be skipped */ ldr x10, =APU_PWRCTL /* Load PWRCTRL address */ ldr w11, [x10] /* Read PWRCTRL register */ mrs x2, MPIDR_EL1 /* Read MPIDR_EL1 */ ubfx x2, x2, #0, #8 /* Extract CPU ID (affinity level 0) */ mov w1, #1 lsl w2, w1, w2 /* Shift CPU ID to get one-hot ID */ ands w11, w11, w2 /* Get PWRCTRL bit for this core */ bne .Lenclbss /* Skip BSS and SBSS clearing */ .endif #endif /* clear sbss */ ldr x1,.Lsbss_start /* calculate beginning of the SBSS */ ldr x2,.Lsbss_end /* calculate end of the SBSS */ .Lloop_sbss: cmp x1,x2 bge .Lenclsbss /* If no SBSS, no clearing required */ str x0, [x1], #8 b .Lloop_sbss .Lenclsbss: /* clear bss */ ldr x1,.Lbss_start /* calculate beginning of the BSS */ ldr x2,.Lbss_end /* calculate end of the BSS */ .Lloop_bss: cmp x1,x2 bge .Lenclbss /* If no BSS, no clearing required */ str x0, [x1], #8 b .Lloop_bss .Lenclbss: /* run global constructors */ bl __libc_init_array /* Reset and start Triple Timer Counter */ #if defined (SLEEP_TIMER_BASEADDR) bl XTime_StartTTCTimer #endif .if (EL1_NONSECURE == 1 && HYP_GUEST == 1) /* * Xen domU guest memory map is not same as that of * native ZynqMP memory map. Currently GIC for Xen * domU guest is being mapped at < 2GB address, which * is configured as normal cacheable memory (DDR) in * default translation table. As GIC needs to be * configured as device memory, updating attributes * of GIC region as strongly ordered, RW, non executable * through Xil_SetTlbAttributes API. Below code snippet * in assemby is equivalent to, * Xil_SetTlbAttributes(XPAR_SCUGIC_0_DIST_BASEADDR, * STRONG_ORDERED | EXECUTE_NEVER) */ ldr x0, =XPAR_SCUGIC_0_DIST_BASEADDR mov x1, #0x409 orr x1, x1, #(0x1 << 53) orr x1, x1, #(0x1 << 54) bl Xil_SetTlbAttributes .endif .if (EL1_NONSECURE == 1 && HYP_GUEST == 1 && \ XEN_USE_PV_CONSOLE == 1) bl XPVXenConsole_Init .endif /* Set E, C and D bits */ mrs x1, PMCR_EL0 orr x1, x1, #(0x1 << 0) orr x1, x1, #(0x1 << 2) orr x1, x1, #(0x1 << 3) msr PMCR_EL0, x1 /* make sure argc and argv are valid */ mov x0, #0 mov x1, #0 #ifdef XCLOCKING bl Xil_ClockInit #endif bl main /* Jump to main C code */ /* Cleanup global constructors */ bl __libc_fini_array bl exit .Lexit: /* should never get here */ b .Lexit .Lstart: .size _startup,.Lstart-_startup

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

8,881

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/gcc/asm_vectors.S

/****************************************************************************** * Copyright (c) 2014 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file asm_vectors.S * * This file contains the initial vector table for the Cortex A53 processor * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 5.00 pkp 05/21/14 Initial version * 6.02 pkp 12/21/16 Added support for floating point access * 6.02 pkp 01/22/17 Added support for EL1 non-secure and hypervisor * baremetal guest * 6.4 mus 06/14/17 Fixed bug in IRQInterruptHandler code snippet, * which checks for the FPEN bit of CPACR_EL1 * 6.6 mus 01/19/18 Added isb after writing to the cpacr_el1/cptr_el3, * to ensure enabling/disabling of floating-point unit * is completed, before any subsequent instruction. * 7.5 mus 05/20/21 Fixed speculative execution past ERET and BR instructions. * As per CVE-2020-13844, Cortex-A72 is affected with * vulnearability, hence changes are targeted only for Cortex-A72. * It fixes CR#1083649. * 7.7. asa 03/22/22 Updated FIQ handler to also handle floating/SIMD context. * * </pre> * * @note * * None. * ******************************************************************************/ #include "bspconfig.h" .org 0 .text .globl _boot .globl _vector_table .globl FIQInterrupt .globl IRQInterrupt .globl SErrorInterrupt .globl SynchronousInterrupt .globl FPUStatus /* * FPUContextSize is the size of the array where floating point registers are * stored when required. The default size corresponds to the case when there is no * nested interrupt. If there are nested interrupts in application which are using * floating point operation, the size of FPUContextSize need to be increased as per * requirement */ .set FPUContextSize, 528 .macro saveregister stp X0,X1, [sp,#-0x10]! stp X2,X3, [sp,#-0x10]! stp X4,X5, [sp,#-0x10]! stp X6,X7, [sp,#-0x10]! stp X8,X9, [sp,#-0x10]! stp X10,X11, [sp,#-0x10]! stp X12,X13, [sp,#-0x10]! stp X14,X15, [sp,#-0x10]! stp X16,X17, [sp,#-0x10]! stp X18,X19, [sp,#-0x10]! stp X29,X30, [sp,#-0x10]! .endm .macro restoreregister ldp X29,X30, [sp], #0x10 ldp X18,X19, [sp], #0x10 ldp X16,X17, [sp], #0x10 ldp X14,X15, [sp], #0x10 ldp X12,X13, [sp], #0x10 ldp X10,X11, [sp], #0x10 ldp X8,X9, [sp], #0x10 ldp X6,X7, [sp], #0x10 ldp X4,X5, [sp], #0x10 ldp X2,X3, [sp], #0x10 ldp X0,X1, [sp], #0x10 .endm .macro savefloatregister /* Load the floating point context array address from FPUContextBase */ ldr x1,=FPUContextBase ldr x0, [x1] /* Save all the floating point register to the array */ stp q0,q1, [x0], #0x20 stp q2,q3, [x0], #0x20 stp q4,q5, [x0], #0x20 stp q6,q7, [x0], #0x20 stp q8,q9, [x0], #0x20 stp q10,q11, [x0], #0x20 stp q12,q13, [x0], #0x20 stp q14,q15, [x0], #0x20 stp q16,q17, [x0], #0x20 stp q18,q19, [x0], #0x20 stp q20,q21, [x0], #0x20 stp q22,q23, [x0], #0x20 stp q24,q25, [x0], #0x20 stp q26,q27, [x0], #0x20 stp q28,q29, [x0], #0x20 stp q30,q31, [x0], #0x20 mrs x2, FPCR mrs x3, FPSR stp x2, x3, [x0], #0x10 /* Save current address of floating point context array to FPUContextBase */ str x0, [x1] .endm .macro restorefloatregister /* Restore the address of floating point context array from FPUContextBase */ ldr x1,=FPUContextBase ldr x0, [x1] /* Restore all the floating point register from the array */ ldp x2, x3, [x0,#-0x10]! msr FPCR, x2 msr FPSR, x3 ldp q30,q31, [x0,#-0x20]! ldp q28,q29, [x0,#-0x20]! ldp q26,q27, [x0,#-0x20]! ldp q24,q25, [x0,#-0x20]! ldp q22,q23, [x0,#-0x20]! ldp q20,q21, [x0,#-0x20]! ldp q18,q19, [x0,#-0x20]! ldp q16,q17, [x0,#-0x20]! ldp q14,q15, [x0,#-0x20]! ldp q12,q13, [x0,#-0x20]! ldp q10,q11, [x0,#-0x20]! ldp q8,q9, [x0,#-0x20]! ldp q6,q7, [x0,#-0x20]! ldp q4,q5, [x0,#-0x20]! ldp q2,q3, [x0,#-0x20]! ldp q0,q1, [x0,#-0x20]! /* Save current address of floating point context array to FPUContextBase */ str x0, [x1] .endm .macro exception_return eret #if defined (versal) dsb nsh isb #endif .endm .org 0 .section .vectors, "a" _vector_table: .set VBAR, _vector_table .org VBAR /* * if application is built for XEN GUEST as EL1 Non-secure following image * header is required by XEN. */ .if (HYP_GUEST == 1) /* Valid Image header. */ /* HW reset vector. */ ldr x16, =_boot br x16 #if defined (versal) dsb nsh isb #endif /* text offset. */ .dword 0 /* image size. */ .dword 0 /* flags. */ .dword 8 /* RES0 */ .dword 0 .dword 0 .dword 0 /* magic */ .dword 0x644d5241 /* RES0 */ .dword 0 /* End of Image header. */ .endif b _boot .org (VBAR + 0x200) b SynchronousInterruptHandler .org (VBAR + 0x280) b IRQInterruptHandler .org (VBAR + 0x300) b FIQInterruptHandler .org (VBAR + 0x380) b SErrorInterruptHandler SynchronousInterruptHandler: saveregister /* Check if the Synchronous abort is occurred due to floating point access. */ .if (EL3 == 1) mrs x0, ESR_EL3 .else mrs x0, ESR_EL1 .endif and x0, x0, #(0x3F << 26) mov x1, #(0x7 << 26) cmp x0, x1 /* If exception is not due to floating point access go to synchronous handler */ bne synchronoushandler /* * If excpetion occurred due to floating point access, Enable the floating point * access i.e. do not trap floating point instruction */ .if (EL3 == 1) mrs x1,CPTR_EL3 bic x1, x1, #(0x1<<10) msr CPTR_EL3, x1 .else mrs x1,CPACR_EL1 orr x1, x1, #(0x1<<20) msr CPACR_EL1, x1 .endif isb /* If the floating point access was previously enabled, store FPU context * registers(storefloat). */ ldr x0, =FPUStatus ldrb w1,[x0] cbnz w1, storefloat /* * If the floating point access was not enabled previously, save the status of * floating point accessibility i.e. enabled and store floating point context * array address(FPUContext) to FPUContextBase. */ mov w1, #0x1 strb w1, [x0] ldr x0, =FPUContext ldr x1, =FPUContextBase str x0,[x1] b restorecontext storefloat: savefloatregister b restorecontext synchronoushandler: bl SynchronousInterrupt restorecontext: restoreregister exception_return IRQInterruptHandler: saveregister /* Save the status of SPSR, ELR and CPTR to stack */ .if (EL3 == 1) mrs x0, CPTR_EL3 mrs x1, ELR_EL3 mrs x2, SPSR_EL3 .else mrs x0, CPACR_EL1 mrs x1, ELR_EL1 mrs x2, SPSR_EL1 .endif stp x0, x1, [sp,#-0x10]! str x2, [sp,#-0x10]! /* Trap floating point access */ .if (EL3 == 1) mrs x1,CPTR_EL3 orr x1, x1, #(0x1<<10) msr CPTR_EL3, x1 .else mrs x1,CPACR_EL1 bic x1, x1, #(0x1<<20) msr CPACR_EL1, x1 .endif isb bl IRQInterrupt /* * If floating point access is enabled during interrupt handling, * restore floating point registers. */ .if (EL3 == 1) mrs x0, CPTR_EL3 ands x0, x0, #(0x1<<10) bne RestorePrevState .else mrs x0,CPACR_EL1 ands x0, x0, #(0x1<<20) beq RestorePrevState .endif restorefloatregister /* Restore the status of SPSR, ELR and CPTR from stack */ RestorePrevState: ldr x2,[sp],0x10 ldp x0, x1, [sp],0x10 .if (EL3 == 1) msr CPTR_EL3, x0 msr ELR_EL3, x1 msr SPSR_EL3, x2 .else msr CPACR_EL1, x0 msr ELR_EL1, x1 msr SPSR_EL1, x2 .endif restoreregister exception_return FIQInterruptHandler: saveregister /* Save the status of SPSR, ELR and CPTR to stack */ .if (EL3 == 1) mrs x0, CPTR_EL3 mrs x1, ELR_EL3 mrs x2, SPSR_EL3 .else mrs x0, CPACR_EL1 mrs x1, ELR_EL1 mrs x2, SPSR_EL1 .endif stp x0, x1, [sp,#-0x10]! str x2, [sp,#-0x10]! /* Trap floating point access */ .if (EL3 == 1) mrs x1,CPTR_EL3 orr x1, x1, #(0x1<<10) msr CPTR_EL3, x1 .else mrs x1,CPACR_EL1 bic x1, x1, #(0x1<<20) msr CPACR_EL1, x1 .endif isb bl FIQInterrupt /* * If floating point access is enabled during interrupt handling, * restore floating point registers. */ .if (EL3 == 1) mrs x0, CPTR_EL3 ands x0, x0, #(0x1<<10) bne RestorePrevStatefiq .else mrs x0,CPACR_EL1 ands x0, x0, #(0x1<<20) beq RestorePrevStatefiq .endif restorefloatregister /* Restore the status of SPSR, ELR and CPTR from stack */ RestorePrevStatefiq: ldr x2,[sp],0x10 ldp x0, x1, [sp],0x10 .if (EL3 == 1) msr CPTR_EL3, x0 msr ELR_EL3, x1 msr SPSR_EL3, x2 .else msr CPACR_EL1, x0 msr ELR_EL1, x1 msr SPSR_EL1, x2 .endif restoreregister exception_return SErrorInterruptHandler: saveregister bl SErrorInterrupt restoreregister exception_return .align 8 /* Array to store floating point registers */ FPUContext: .skip FPUContextSize /* Stores address for floating point context array */ FPUContextBase: .skip 8 FPUStatus: .skip 1 .end

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

15,990

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/gcc/boot.S

/****************************************************************************** * Copyright (c) 2014 - 2022 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file boot.S * * @addtogroup a53_64_boot_code Cortex A53 64bit Processor Boot Code * @{ * <h2> boot.S </h2> * * The boot code performs minimum configuration which is required for an * application. Cortex-A53 starts by checking current exception level. If the * current exception level is EL3 and BSP is built for EL3, it will do * initialization required for application execution at EL3. Below is a * sequence illustrating what all configuration is performed before control * reaches to main function for EL3 execution. * * 1. Program vector table base for exception handling * 2. Set reset vector table base address * 3. Program stack pointer for EL3 * 4. Routing of interrupts to EL3 * 5. Enable ECC protection * 6. Program generic counter frequency * 7. Invalidate instruction cache, data cache and TLBs * 8. Configure MMU registers and program base address of translation table * 9. Transfer control to _start which clears BSS sections and runs global * constructor before jumping to main application * * If the current exception level is EL1 and BSP is also built for EL1_NONSECURE * it will perform initialization required for application execution at EL1 * non-secure. For all other combination, the execution will go into infinite * loop. Below is a sequence illustrating what all configuration is performed * before control reaches to main function for EL1 execution. * * 1. Program vector table base for exception handling * 2. Program stack pointer for EL1 * 3. Invalidate instruction cache, data cache and TLBs * 4. Configure MMU registers and program base address of translation table * 5. Transfer control to _start which clears BSS sections and runs global * constructor before jumping to main application * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 5.00 pkp 05/21/14 Initial version * 6.00 pkp 07/25/16 Program the counter frequency * 6.02 pkp 01/22/17 Added support for EL1 non-secure * 6.02 pkp 01/24/17 Clearing status of FPUStatus variable to ensure it * holds correct value. * 6.3 mus 04/20/17 CPU Cache protection bit in the L2CTLR_EL1 will be in * set state on reset. So, setting that bit through boot * code is redundant, hence removed the code which sets * CPU cache protection bit. * 6.4 mus 08/11/17 Implemented ARM erratum 855873.It fixes * CR#982209. * 6.6 mus 01/19/18 Added isb after writing to the cpacr_el1/cptr_el3, * to ensure floating-point unit is disabled, before * any subsequent instruction. * 7.0 mus 03/26/18 Updated TCR_EL3/TCR_EL1 as per versal address map * 7.3 mus 04/24/20 Corrected CPACR_EL1 handling at EL1 NS * 8.0 mus 07/06/21 Added support for CortexA78 processor in VERSAL NET SoC * 8.0 mus 10/05/21 Default translation table for VERSAL NET has been configured * for 256 TB address space, due to this page tables size * exceeds OCM size, hence executable size is too large * to fit into OCM. This patch adds option to reduce * page table size, when OCM_ELF flag is defined in * compiler flags, translation table would be configured * for 1 TB address space. It would help to reduce * executable size. * * </pre> * ******************************************************************************/ #include "xparameters.h" #include "bspconfig.h" #include "xil_errata.h" .globl MMUTableL0 .globl MMUTableL1 .globl MMUTableL2 .global _prestart .global _boot .global __el3_stack .global __el2_stack .global __el1_stack .global __el0_stack .global _vector_table .set EL3_stack, __el3_stack .set EL2_stack, __el2_stack .set EL1_stack, __el1_stack .set EL0_stack, __el0_stack .set TT_S1_FAULT, 0x0 .set TT_S1_TABLE, 0x3 .set L0Table, MMUTableL0 .set L1Table, MMUTableL1 .set L2Table, MMUTableL2 .set vector_base, _vector_table .set rvbar_base, 0xFD5C0040 #if defined (VERSAL_NET) .set counterfreq, XPAR_CPU_CORTEXA78_0_TIMESTAMP_CLK_FREQ #elif defined (versal) .set counterfreq, XPAR_CPU_CORTEXA72_0_TIMESTAMP_CLK_FREQ #else .set counterfreq, XPAR_CPU_CORTEXA53_0_TIMESTAMP_CLK_FREQ #endif .set MODE_EL1, 0x5 .set DAIF_BIT, 0x1C0 .section .boot,"ax" /* this initializes the various processor modes */ _prestart: _boot: mov x0, #0 mov x1, #0 mov x2, #0 mov x3, #0 mov x4, #0 mov x5, #0 mov x6, #0 mov x7, #0 mov x8, #0 mov x9, #0 mov x10, #0 mov x11, #0 mov x12, #0 mov x13, #0 mov x14, #0 mov x15, #0 mov x16, #0 mov x17, #0 mov x18, #0 mov x19, #0 mov x20, #0 mov x21, #0 mov x22, #0 mov x23, #0 mov x24, #0 mov x25, #0 mov x26, #0 mov x27, #0 mov x28, #0 mov x29, #0 mov x30, #0 #if 0 //don't put other a53 cpus in wfi //Which core am I // ---------------- mrs x0, MPIDR_EL1 and x0, x0, #0xFF //Mask off to leave Aff0 cbz x0, OKToRun //If core 0, run the primary init code EndlessLoop0: wfi b EndlessLoop0 #endif OKToRun: mrs x0, currentEL cmp x0, #0xC beq InitEL3 cmp x0, #0x4 beq InitEL1 b error // go to error if current exception level is neither EL3 nor EL1 InitEL3: .if (EL3 == 1) /*Set vector table base address*/ ldr x1, =vector_base msr VBAR_EL3,x1 /* Set reset vector address */ /* Get the cpu ID */ mrs x0, MPIDR_EL1 and x0, x0, #0xFF mov w0, w0 #ifndef VERSAL_NET ldr w2, =rvbar_base /* calculate the rvbar base address for particular CPU core */ mov w3, #0x8 mul w0, w0, w3 add w2, w2, w0 /* store vector base address to RVBAR */ str x1, [x2] #endif /*Define stack pointer for current exception level*/ ldr x2,=EL3_stack mov sp,x2 /* Enable Trapping of SIMD/FPU register for standalone BSP */ mov x0, #0 #ifndef FREERTOS_BSP orr x0, x0, #(0x1 << 10) #endif msr CPTR_EL3, x0 isb /* * Clear FPUStatus variable to make sure that it contains current * status of FPU i.e. disabled. In case of a warm restart execution * when bss sections are not cleared, it may contain previously updated * value which does not hold true now. */ #ifndef FREERTOS_BSP ldr x0,=FPUStatus str xzr, [x0] #endif /* Configure SCR_EL3 */ mov w1, #0 //; Initial value of register is unknown orr w1, w1, #(1 << 11) //; Set ST bit (Secure EL1 can access CNTPS_TVAL_EL1, CNTPS_CTL_EL1 & CNTPS_CVAL_EL1) orr w1, w1, #(1 << 10) //; Set RW bit (EL1 is AArch64, as this is the Secure world) orr w1, w1, #(1 << 3) //; Set EA bit (SError routed to EL3) orr w1, w1, #(1 << 2) //; Set FIQ bit (FIQs routed to EL3) orr w1, w1, #(1 << 1) //; Set IRQ bit (IRQs routed to EL3) msr SCR_EL3, x1 /* As per A78 TRM, CPUACTLR_EL1 is reserved for ARM internal use */ #if !defined (VERSAL_NET) /*configure cpu auxiliary control register EL1 */ ldr x0,=0x80CA000 // L1 Data prefetch control - 5, Enable device split throttle, 2 independent data prefetch streams #if CONFIG_ARM_ERRATA_855873 /* * Set ENDCCASCI bit in CPUACTLR_EL1 register, to execute data * cache clean operations as data cache clean and invalidate * */ orr x0, x0, #(1 << 44) //; Set ENDCCASCI bit #endif msr S3_1_C15_C2_0, x0 //CPUACTLR_EL1 #endif /* program the counter frequency */ ldr x0,=counterfreq msr CNTFRQ_EL0, x0 /* There is no SMPEN bit in A78, TODO: Check for equivalent bit */ #if !defined (VERSAL_NET) /*Enable hardware coherency between cores*/ mrs x0, S3_1_c15_c2_1 //Read EL1 CPU Extended Control Register orr x0, x0, #(1 << 6) //Set the SMPEN bit msr S3_1_c15_c2_1, x0 //Write EL1 CPU Extended Control Register isb #endif tlbi ALLE3 ic IALLU //; Invalidate I cache to PoU bl invalidate_dcaches dsb sy isb ldr x1, =L0Table //; Get address of level 0 for TTBR0_EL3 msr TTBR0_EL3, x1 //; Set TTBR0_EL3 /********************************************** * Set up memory attributes * This equates to: * 0 = b01000100 = Normal, Inner/Outer Non-Cacheable * 1 = b11111111 = Normal, Inner/Outer WB/WA/RA * 2 = b00000000 = Device-nGnRnE * 3 = b00000100 = Device-nGnRE * 4 = b10111011 = Normal, Inner/Outer WT/WA/RA **********************************************/ ldr x1, =0x000000BB0400FF44 msr MAIR_EL3, x1 #if defined (VERSAL_NET) && defined (OCM_ELF) /********************************************** * Set up TCR_EL3 * Physical Address Size PS = 010 -> 40bits 1TB * Granual Size TG0 = 00 -> 4KB * Attributes for page table walks = 00 -> non cacheable * size offset of the memory region T0SZ = 24 -> (region size 2^(64-24) = 2^40) ***************************************************/ ldr x1,=0x80823018 #elif defined (VERSAL_NET) /********************************************** * Set up TCR_EL3 * Physical Address Size PS = 101 -> 48bits 256 TB * Granual Size TG0 = 00 -> 4KB * size offset of the memory region T0SZ = 16 -> (region size 2^(64-16) = 2^48) ***************************************************/ /* ldr x1,=0x80853510 */ ldr x1,=0x80853010 #elif defined (versal) /********************************************** * Set up TCR_EL3 * Physical Address Size PS = 100 -> 44bits 16 TB * Granual Size TG0 = 00 -> 4KB * size offset of the memory region T0SZ = 20 -> (region size 2^(64-20) = 2^44) ***************************************************/ ldr x1,=0x80843514 #else /********************************************** * Set up TCR_EL3 * Physical Address Size PS = 010 -> 40bits 1TB * Granual Size TG0 = 00 -> 4KB * size offset of the memory region T0SZ = 24 -> (region size 2^(64-24) = 2^40) ***************************************************/ ldr x1,=0x80823518 #endif msr TCR_EL3, x1 isb /* Enable SError Exception for asynchronous abort */ mrs x1,DAIF bic x1,x1,#(0x1<<8) msr DAIF,x1 /* Configure SCTLR_EL3 */ mov x1, #0 //Most of the SCTLR_EL3 bits are unknown at reset orr x1, x1, #(1 << 12) //Enable I cache orr x1, x1, #(1 << 3) //Enable SP alignment check orr x1, x1, #(1 << 2) //Enable caches orr x1, x1, #(1 << 0) //Enable MMU msr SCTLR_EL3, x1 dsb sy isb b _startup //jump to start .else b error // present exception level and selected exception level mismatch .endif InitEL1: .if (EL1_NONSECURE == 1) /*Set vector table base address*/ ldr x1, =vector_base msr VBAR_EL1,x1 /* Trap floating point access only in case of standalone BSP */ #ifdef FREERTOS_BSP mrs x0, CPACR_EL1 orr x0, x0, #(0x3 << 20) msr CPACR_EL1, x0 #else mrs x0, CPACR_EL1 bic x0, x0, #(0x3 << 20) msr CPACR_EL1, x0 #endif isb /* * Clear FPUStatus variable to make sure that it contains current * status of FPU i.e. disabled. In case of a warm restart execution * when bss sections are not cleared, it may contain previously updated * value which does not hold true now. */ #ifndef FREERTOS_BSP ldr x0,=FPUStatus str xzr, [x0] #endif /*Define stack pointer for current exception level*/ ldr x2,=EL1_stack mov sp,x2 /* Disable MMU first */ mov x1,#0x0 msr SCTLR_EL1, x1 isb TLBI VMALLE1 ic IALLU //; Invalidate I cache to PoU bl invalidate_dcaches dsb sy isb ldr x1, =L0Table //; Get address of level 0 for TTBR0_EL1 msr TTBR0_EL1, x1 //; Set TTBR0_EL1 /********************************************** * Set up memory attributes * This equates to: * 0 = b01000100 = Normal, Inner/Outer Non-Cacheable * 1 = b11111111 = Normal, Inner/Outer WB/WA/RA * 2 = b00000000 = Device-nGnRnE * 3 = b00000100 = Device-nGnRE * 4 = b10111011 = Normal, Inner/Outer WT/WA/RA **********************************************/ ldr x1, =0x000000BB0400FF44 msr MAIR_EL1, x1 #if defined (versal) /********************************************** * Set up TCR_EL1 * Physical Address Size PS = 100 -> 44bits 16TB * Granual Size TG0 = 00 -> 4KB * size offset of the memory region T0SZ = 20 -> (region size 2^(64-20) = 2^44) ***************************************************/ ldr x1,=0x485800514 #else /********************************************** * Set up TCR_EL1 * Physical Address Size PS = 010 -> 44bits 16TB * Granual Size TG0 = 00 -> 4KB * size offset of the memory region T0SZ = 24 -> (region size 2^(64-24) = 2^40) ***************************************************/ ldr x1,=0x285800518 #endif msr TCR_EL1, x1 isb /* Enable SError Exception for asynchronous abort */ mrs x1,DAIF bic x1,x1,#(0x1<<8) msr DAIF,x1 //; Enable MMU mov x1,#0x0 orr x1, x1, #(1 << 18) // ; Set WFE non trapping orr x1, x1, #(1 << 17) // ; Set WFI non trapping orr x1, x1, #(1 << 5) // ; Set CP15 barrier enabled orr x1, x1, #(1 << 12) // ; Set I bit orr x1, x1, #(1 << 2) // ; Set C bit orr x1, x1, #(1 << 0) // ; Set M bit msr SCTLR_EL1, x1 isb bl _startup //jump to start .else b error // present exception level and selected exception level mismatch .endif error: b error invalidate_dcaches: dmb ISH mrs x0, CLIDR_EL1 //; x0 = CLIDR ubfx w2, w0, #24, #3 //; w2 = CLIDR.LoC cmp w2, #0 //; LoC is 0? b.eq invalidateCaches_end //; No cleaning required and enable MMU mov w1, #0 //; w1 = level iterator invalidateCaches_flush_level: add w3, w1, w1, lsl #1 //; w3 = w1 * 3 (right-shift for cache type) lsr w3, w0, w3 //; w3 = w0 >> w3 ubfx w3, w3, #0, #3 //; w3 = cache type of this level cmp w3, #2 //; No cache at this level? b.lt invalidateCaches_next_level lsl w4, w1, #1 msr CSSELR_EL1, x4 //; Select current cache level in CSSELR isb //; ISB required to reflect new CSIDR mrs x4, CCSIDR_EL1 //; w4 = CSIDR ubfx w3, w4, #0, #3 add w3, w3, #2 //; w3 = log2(line size) ubfx w5, w4, #13, #15 ubfx w4, w4, #3, #10 //; w4 = Way number clz w6, w4 //; w6 = 32 - log2(number of ways) invalidateCaches_flush_set: mov w8, w4 //; w8 = Way number invalidateCaches_flush_way: lsl w7, w1, #1 //; Fill level field lsl w9, w5, w3 orr w7, w7, w9 //; Fill index field lsl w9, w8, w6 orr w7, w7, w9 //; Fill way field dc CISW, x7 //; Invalidate by set/way to point of coherency subs w8, w8, #1 //; Decrement way b.ge invalidateCaches_flush_way subs w5, w5, #1 //; Descrement set b.ge invalidateCaches_flush_set invalidateCaches_next_level: add w1, w1, #1 //; Next level cmp w2, w1 b.gt invalidateCaches_flush_level invalidateCaches_end: ret .end /** * @} End of "addtogroup a53_64_boot_code". */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

15,453

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/platform/versal/armclang/translation_table.S

/****************************************************************************** * Copyright (C) 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file translation_table.s * * @addtogroup a72_64_boot_code * @{ * <h2> translation_table.S </h2> * translation_table.S contains a static page table required by MMU for * cortex-A72. This translation table is flat mapped (input address = output * address) with default memory attributes defined for versal * architecture. It utilizes translation granual size of 4KB with 2MB section * size for initial 5GB memory and 1GB section size for memory after 5GB. * The overview of translation table memory attributes is described below. * *| Name | Memory Range | Def. in Translation Table | *|-----------------------|-----------------------------------|-----------------------------| *| DDR | 0x000_0000_0000 - 0x000_7FFF_FFFF | Normal WB Cacheable | *| LPD_AFI_FS | 0x000_8000_0000 - 0x000_9FFF_FFFF | Strongly Ordered | *| Reserved | 0x000_A000_0000 - 0x000_A3FF_FFFF | Unassigned | *| FPD_AFI_0 | 0x000_A400_0000 - 0x000_AFFF_FFFF | Strongly Ordered | *| FPD_AFI_1 | 0x000_B000_0000 - 0x000_BFFF_FFFF | Strongly Ordered | *| QSPI | 0x000_C000_0000 - 0x000_DFFF_FFFF | Strongly Ordered | *| PCIE region 0 | 0x000_E000_0000 - 0x000_EFFF_FFFF | Strongly Ordered | *| PMC | 0x000_F000_0000 - 0x000_F7FF_FFFF | Strongly Ordered | *| STM_CORESIGHT | 0x000_F800_0000 - 0x000_F8FF_FFFF | Strongly Ordered | *| GIC | 0x000_F900_0000 - 0x000_F90F_FFFF | Strongly Ordered | *| Reserved | 0x000_F910_0000 - 0x000_FBFF_FFFF | Unassigned | *| CPM | 0x000_FC00_0000 - 0x000_FCFF_FFFF | Strongly Ordered | *| FPD slaves | 0x000_FD00_0000 - 0x000_FDFF_FFFF | Strongly Ordered | *| LPD slaves | 0x000_FE00_0000 - 0x000_FFDF_FFFF | Strongly Ordered | *| OCM | 0x000_FFE0_0000 - 0xFFF_FFFF_FFFF | Normal WB Cacheable | *| PMC region 0-3 | 0x001_0000_0000 - 0x001_1FFF_FFFF | Strongly Ordered | *| Reserved | 0x001_2000_0000 - 0x001_FFFF_FFFF | Unassigned | *| ME Array 0-3 | 0x002_0000_0000 - 0x002_FFFF_FFFF | Strongly Ordered | *| Reserved | 0x003_0000_0000 - 0x003_FFFF_FFFF | Unassigned | *| PL- via PS | 0x004_0000_0000 - 0x005_FFFF_FFFF | Strongly Ordered | *| PCIe region 1 | 0x006_0000_0000 - 0x007_FFFF_FFFF | Strongly Ordered | *| DDR | 0x008_0000_0000 - 0x00F_FFFF_FFFF | Normal WB Cacheable | *| Reserved | 0x010_0000_0000 - 0x03F_FFFF_FFFF | Unassigned | *| HBM 0-3 | 0x040_0000_0000 - 0x07F_FFFF_FFFF | Strongly Ordered | *| PCIe region 2 | 0x080_0000_0000 - 0x0BF_FFFF_FFFF | Strongly Ordered | *| DDR | 0x0C0_0000_0000 - 0x1B7_7FFF_FFFF | Normal WB Cacheable | *| Reserved | 0x1B7_8000_0000 - 0x1FF_FFFF_FFFF | Unassigned | *| PL- Via NoC | 0x200_0000_0000 - 0x3FF_FFFF_FFFF | Strongly Ordered | *| PL- Via PS | 0x400_0000_0000 - 0x4FF_FFFF_FFFF | Strongly Ordered | *| DDR CH1-CH3 | 0x500_0000_0000 - 0x7FF_FFFF_FFFF | Normal WB Cacheable | *| PL- Via NoC | 0x800_0000_0000 - 0xFFF_FFFF_FFFF | Strongly Ordered | * * @note * * For DDR region 0x0000000000 - 0x007FFFFFFF, a system where DDR is less than * 2GB, region after DDR and before PL is marked as undefined/reserved in * translation table. Region 0xF9100000 - 0xF91FFFFF is reserved memory in * 0x00F9000000 - 0x00F91FFFFF range, but it is marked as strongly ordered * because minimum section size in translation table section is 2MB. * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 7.2 mus 01/09/20 Initial version * * ******************************************************************************/ #include "xparameters.h" #include "bspconfig.h" EXPORT MMUTableL0 EXPORT MMUTableL1 EXPORT MMUTableL2 GBLA abscnt GBLA count GBLA sect Reserved EQU 0x0 ; Fault #if EL1_NONSECURE Memory EQU 0x405:OR:(2:SHL:8):OR:0x0 ; normal writeback write allocate outer shared read write */ #else Memory EQU 0x405:OR:(3:SHL:8):OR:0x0 ; normal writeback write allocate inner shared read write */ #endif Device EQU 0x409:OR:(1:SHL:53):OR:(1:SHL:54):OR:0x0 ; strongly ordered read write non executable AREA |.mmu_tbl0|, CODE, ALIGN=12 MMUTableL0 count SETA 0 WHILE count<0x1f DCQU MMUTableL1+count*0x1000+0x3 ; 0x0000_0000 - 0x7F_FFFF_FFFF count SETA count+1 WEND count SETA 1 WHILE count<0x20 DCQ MMUTableL1+count*0x1000+0x3 ; 0x80_0000_0000 - 0xFFF_FFFF_FFFF count SETA count+1 WEND AREA |.mmu_tbl1|, CODE, ALIGN=12 MMUTableL1 DCQU MMUTableL2+0x3 ; 0x0000_0000 - 0x3FFF_FFFF count SETA 1 ; 0x4000_0000 - 0x1_3FFF_FFFF WHILE count<5 DCQ MMUTableL2+count*0x1000+0x3 ; 1GB DDR, 512MB LPD_AFI_FS, 448MB FPD_AFI_0, 512MB QSPI, ; 256MB PCIe region 0, PMC 128MB, GIC 1 MB, reserved 47MB, ; 2GB other devices and memory, 512 MB PMC count SETA count+1 WEND Fixlocl1 EQU 0x140000000 abscnt SETA 0 count SETA 0 WHILE count<0x3 DCQU Fixlocl1+abscnt*0x40000000+Reserved ; 0x1_4000_0000 - 0x1_FFFF_FFFF ; 3GB Reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x4 DCQU Fixlocl1+abscnt*0x40000000+Device ; 0x2_0000_0000 - 0x2_FFFF_FFFF ; 4GB ME Array 0-3 count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x4 DCQU Fixlocl1+abscnt*0x40000000+Reserved ; 0x3_0000_0000 - 0x3_FFFF_FFFF ; 4GB Reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x10 DCQU Fixlocl1+abscnt*0x40000000+Device ; 0x4_0000_0000 - 0x7_FFFF_FFFF ; 8GB PL - via PS, 8GB PCIe region1 count SETA count+1 abscnt SETA abscnt+1 WEND #ifdef XPAR_AXI_NOC_DDR_LOW_1_BASEADDR DDR_1_START EQU XPAR_AXI_NOC_DDR_LOW_1_BASEADDR DDR_1_END EQU XPAR_AXI_NOC_DDR_LOW_1_HIGHADDR DDR_1_SIZE EQU (DDR_1_END - DDR_1_START+1) #if DDR_1_SIZE > 0x800000000 ; If DDR size is larger than 32GB, truncate to 32GB DDR_1_REG EQU 0x20 #else DDR_1_REG EQU DDR_1_SIZE/0x40000000 #endif #else DDR_1_REG EQU 0 #endif UNDEF_1_REG EQU (0x20 - DDR_1_REG) ; DDR based on size in hw design count SETA 0 WHILE count<DDR_1_REG DCQU Fixlocl1+abscnt*0x40000000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_1_REG DCQU Fixlocl1+abscnt*0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0xC0 DCQU Fixlocl1+abscnt*0x40000000+Reserved ; 0x10_0000_0000 - 0x3F_FFFF_FFFF ; 192GB Reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x100 DCQU Fixlocl1+abscnt*0x40000000+Device ; 0x40_0000_0000 - 0x7F_FFFF_FFFF ; 256GB HBM 0-3 count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x100 DCQU Fixlocl1+abscnt*0x40000000+Device ; 0x80_0000_0000 - 0xBF_FFFF_FFFF ; 256GB PCIe 2 count SETA count+1 abscnt SETA abscnt+1 WEND #ifdef XPAR_AXI_NOC_DDR_LOW_2_BASEADDR DDR_2_START EQU XPAR_AXI_NOC_DDR_LOW_2_BASEADDR DDR_2_END EQU XPAR_AXI_NOC_DDR_LOW_2_HIGHADDR DDR_2_SIZE EQU (DDR_2_END - DDR_2_START+1) #if DDR_2_SIZE > 0x4000000000 ; If DDR size is larger than 256 GB, truncate to 256GB DDR_2_REG EQU 0x100 #else DDR_2_REG EQU DDR_2_SIZE/0x40000000 #endif #else DDR_2_REG EQU 0 #endif UNDEF_2_REG EQU (0x100 - DDR_2_REG) ; DDR based on size in hw design count SETA 0 WHILE count<DDR_2_REG DCQU Fixlocl1+abscnt*0x40000000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_2_REG DCQU Fixlocl1+abscnt*0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND #ifdef XPAR_AXI_NOC_DDR_LOW_3_BASEADDR DDR_3_START EQU XPAR_AXI_NOC_DDR_LOW_3_BASEADDR DDR_3_END EQU XPAR_AXI_NOC_DDR_LOW_3_HIGHADDR DDR_3_SIZE EQU (DDR_3_END - DDR_3_START+1) #if DDR_3_SIZE > 0xB780000000 ; If DDR size is larger than 734 GB, truncate to 734GB DDR_3_REG EQU 0x2de #else DDR_3_REG EQU DDR_3_SIZE/0x40000000 #endif #else DDR_3_REG EQU 0 #endif UNDEF_3_REG EQU (0x2de - DDR_3_REG) ; DDR based on size in hw design count SETA 0 WHILE count<DDR_3_REG DCQU Fixlocl1+abscnt*0x40000000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_3_REG DCQU Fixlocl1+abscnt*0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x122 DCQU Fixlocl1+abscnt*0x40000000+Reserved ; 0x1B7_8000_0000 - 0x1FF_FFFF_FFFF ; 290GB reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x800 DCQU Fixlocl1+abscnt*0x40000000+Device ; 0x200_0000_0000 - 0x3FF_FFFF_FFFF ; 2TB PL- via NoC count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x400 DCQU Fixlocl1+abscnt*0x40000000+Device ; 0x400_0000_0000 - 0x4FF_FFFF_FFFF ; 1TB PL- via PS count SETA count+1 abscnt SETA abscnt+1 WEND #ifdef XPAR_AXI_NOC_DDR_CH_1_BASEADDR DDR_CH_1_START EQU XPAR_AXI_NOC_DDR_CH_1_BASEADDR DDR_CH_1_END EQU XPAR_AXI_NOC_DDR_CH_1_HIGHADDR DDR_CH_1_SIZE EQU (DDR_CH_1_END - DDR_CH_1_START + 1) #if DDR_CH_1_SIZE > 0x010000000000 ; If DDR size is larger than 1TB, truncate to 1 TB DDR_CH_1_REG EQU 0x400 ; 0x500_0000_0000 - 0x5FF_FFFF_FFFF #else DDR_CH_1_REG EQU DDR_CH_1_SIZE/0x40000000 #endif #else DDR_CH_1_REG EQU 0 #endif UNDEF_CH_1_REG EQU (0x400 - DDR_CH_1_REG) ; DDR based on size in hw design, Max size 1 TB count SETA 0 WHILE count<DDR_CH_1_REG DCQU Fixlocl1+abscnt*0x40000000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_CH_1_REG DCQU Fixlocl1+abscnt*0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND #ifdef XPAR_AXI_NOC_DDR_CH_2_BASEADDR DDR_CH_2_START EQU XPAR_AXI_NOC_DDR_CH_2_BASEADDR DDR_CH_2_END EQU XPAR_AXI_NOC_DDR_CH_2_HIGHADDR DDR_CH_2_SIZE EQU (DDR_CH_2_END - DDR_CH_2_START + 1) #if DDR_CH_2_SIZE > 0x010000000000 ; If DDR_CH_2 size is larger than 1TB, truncate to 1 TB DDR_CH_2_REG EQU 0x400 ; 0x600_0000_0000 - 0x6FF_FFFF_FFFF #else DDR_CH_2_REG EQU DDR_CH_2_SIZE/0x40000000 #endif #else DDR_CH_2_REG EQU 0 #endif UNDEF_CH_2_REG EQU (0x400 - DDR_CH_2_REG) ; DDR based on size in hw design, Max size 1 TB count SETA 0 WHILE count<DDR_CH_2_REG DCQU Fixlocl1+abscnt*0x40000000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_CH_2_REG DCQU Fixlocl1+abscnt*0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND #ifdef XPAR_AXI_NOC_DDR_CH_3_BASEADDR DDR_CH_3_START EQU XPAR_AXI_NOC_DDR_CH_3_BASEADDR DDR_CH_3_END EQU XPAR_AXI_NOC_DDR_CH_3_HIGHADDR DDR_CH_3_SIZE EQU (DDR_CH_3_END - DDR_CH_3_START+1) #if DDR_CH_3_SIZE > 0x010000000000 ; If DDR_CH_3 size is larger than 1TB, truncate to 1 TB */ DDR_CH_3_REG EQU 0x400 ; 0x700_0000_0000 - 0x7FF_FFFF_FFFF #else DDR_CH_3_REG EQU DDR_CH_3_SIZE/0x40000000 #endif #else DDR_CH_3_REG EQU 0 #endif UNDEF_CH_3_REG EQU (0x400 - DDR_CH_3_REG) ; DDR based on size in hw design, Max size 1 TB count SETA 0 WHILE count<DDR_CH_3_REG DCQU Fixlocl1+abscnt*0x40000000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_CH_3_REG DCQU Fixlocl1+abscnt*0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x2000 DCQU Fixlocl1+abscnt*0x40000000+Device count SETA count+1 abscnt SETA abscnt+1 WEND AREA |.mmu_tbl2|, CODE, ALIGN=12 MMUTableL2 abscnt SETA 0 #ifdef XPAR_AXI_NOC_DDR_LOW_0_BASEADDR DDR_0_START EQU XPAR_AXI_NOC_DDR_LOW_0_BASEADDR DDR_0_END EQU XPAR_AXI_NOC_DDR_LOW_0_HIGHADDR DDR_0_SIZE EQU (DDR_0_END - DDR_0_START+1) #if DDR_0_SIZE > 0x80000000 ; If DDR size is larger than 2GB, truncate to 2GB .set DDR_0_REG, 0x400 #else DDR_0_REG EQU DDR_0_SIZE/0x200000 #endif #else DDR_0_REG EQU 0 #endif UNDEF_0_REG EQU (0x400 - DDR_0_REG) ; DDR based on size in hw design count SETA 0 WHILE count<DDR_0_REG DCQU abscnt*0x200000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_0_REG DCQU abscnt*0x200000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x100 DCQU abscnt*0x200000+Device count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x20 ; 0xA000_0000 - 0xA3FF_FFFF DCQU abscnt*0x200000+Device ; 64MB reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x60 ; 0xA400_0000 - 0xAFFF_FFFF DCQU abscnt*0x200000+Device ; 192MB FPD AFI 0 count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x80 ; 0xB000_0000 - 0xBFFF_FFFF DCQU abscnt*0x200000+Device ; 192MB FPD AFI 1 count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x100 ; 0xC000_0000 - 0xDFFF_FFFF DCQU abscnt*0x200000+Device ; 512MB QSPI count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x80 ; 0xE000_0000 - 0xEFFF_FFFF DCQU abscnt*0x200000+Device ; 256MB lower PCIe count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x40 ; 0xF000_0000 - 0xF7FF_FFFF DCQU abscnt*0x200000+Device ; 128MB PMC count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x8 ; 0xF800_0000 - 0xF8FF_FFFF DCQU abscnt*0x200000+Device ; 16MB coresight count SETA count+1 abscnt SETA abscnt+1 WEND ; 1MB GIC is marked for 2MB region as the minimum block size in ; translation table is 2MB and adjacent 47MB reserved region is ; converted to 46MB DCQU abscnt*0x200000+Device ; 0xF910_0000 - 0xF90F_FFFF abscnt SETA abscnt+1 ; Reserved 46MB 0xF91FFFFF - 0xFBFFFFFF count SETA 0 WHILE count<0x17 ; 0xF91F_FFFF - 0xFBFF_FFFF DCQU abscnt*0x200000+Reserved ; 46MB reserved count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x1F ; 0xFC00_0000 - 0xFFDF_FFFF DCQU abscnt*0x200000+Device ; 16MB CPM,16MB FPS, 30MB LPS slaves count SETA count+1 abscnt SETA abscnt+1 WEND DCQU abscnt*0x200000+Memory ; 0xFFE0_0000 - 0xFFFF_FFFF abscnt SETA abscnt+1 count SETA 0 WHILE count<0x100 ; 0x1_0000_0000 - 0x1_1FFF_FFFF DCQU abscnt*0x200000+Device ; 512MB PMC 0-3 count SETA count+1 abscnt SETA abscnt+1 WEND count SETA 0 WHILE count<0x100 ; 0x1_2000_0000 - 0x1_3FFF_FFFF DCQU abscnt*0x200000+Device ; 512MB reserved count SETA count+1 abscnt SETA abscnt+1 WEND END /** * @} End of "addtogroup a53_64_boot_code". */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

26,891

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/platform/versal/gcc/translation_table.S

/****************************************************************************** * Copyright (C) 2018 - 2022 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file translation_table.s * * @addtogroup a53_64_boot_code * @{ * <h2> translation_table.S </h2> * The translation_table.S contains a static page table required by MMU for * cortex-A72. This translation table is flat mapped (input address = output * address) with default memory attributes defined for Versal * architecture. It utilizes translation granual size of 4KB with 2MB section * size for initial 5GB memory and 1GB section size for memory after 5GB. * The overview of translation table memory attributes is described below. * *| Name | Memory Range | Def. in Translation Table | *|-----------------------|-----------------------------------|-----------------------------| *| DDR | 0x000_0000_0000 - 0x000_7FFF_FFFF | Normal WB Cacheable | *| LPD_AFI_FS | 0x000_8000_0000 - 0x000_9FFF_FFFF | Strongly Ordered | *| Reserved | 0x000_A000_0000 - 0x000_A3FF_FFFF | Unassigned | *| FPD_AFI_0 | 0x000_A400_0000 - 0x000_AFFF_FFFF | Strongly Ordered | *| FPD_AFI_1 | 0x000_B000_0000 - 0x000_BFFF_FFFF | Strongly Ordered | *| QSPI | 0x000_C000_0000 - 0x000_DFFF_FFFF | Strongly Ordered | *| PCIE region 0 | 0x000_E000_0000 - 0x000_EFFF_FFFF | Strongly Ordered | *| PMC | 0x000_F000_0000 - 0x000_F7FF_FFFF | Strongly Ordered | *| STM_CORESIGHT | 0x000_F800_0000 - 0x000_F8FF_FFFF | Strongly Ordered | *| GIC | 0x000_F900_0000 - 0x000_F90F_FFFF | Strongly Ordered | *| Reserved | 0x000_F910_0000 - 0x000_FBFF_FFFF | Unassigned | *| CPM | 0x000_FC00_0000 - 0x000_FCFF_FFFF | Strongly Ordered | *| FPD slaves | 0x000_FD00_0000 - 0x000_FDFF_FFFF | Strongly Ordered | *| LPD slaves | 0x000_FE00_0000 - 0x000_FFDF_FFFF | Strongly Ordered | *| OCM | 0x000_FFE0_0000 - 0xFFF_FFFF_FFFF | Normal WB Cacheable | *| PMC region 0-3 | 0x001_0000_0000 - 0x001_1FFF_FFFF | Strongly Ordered | *| Reserved | 0x001_2000_0000 - 0x001_FFFF_FFFF | Unassigned | *| ME Array 0-3 | 0x002_0000_0000 - 0x002_FFFF_FFFF | Strongly Ordered | *| Reserved | 0x003_0000_0000 - 0x003_FFFF_FFFF | Unassigned | *| PL- via PS | 0x004_0000_0000 - 0x005_FFFF_FFFF | Strongly Ordered | *| PCIe region 1 | 0x006_0000_0000 - 0x007_FFFF_FFFF | Strongly Ordered | *| DDR | 0x008_0000_0000 - 0x00F_FFFF_FFFF | Normal WB Cacheable | *| Reserved | 0x010_0000_0000 - 0x03F_FFFF_FFFF | Unassigned | *| HBM 0-3 | 0x040_0000_0000 - 0x07F_FFFF_FFFF | Strongly Ordered | *| PCIe region 2 | 0x080_0000_0000 - 0x0BF_FFFF_FFFF | Strongly Ordered | *| DDR | 0x0C0_0000_0000 - 0x1B7_7FFF_FFFF | Normal WB Cacheable | *| Reserved | 0x1B7_8000_0000 - 0x1FF_FFFF_FFFF | Unassigned | *| PL- Via NoC | 0x200_0000_0000 - 0x3FF_FFFF_FFFF | Strongly Ordered | *| PL- Via PS | 0x400_0000_0000 - 0x4FF_FFFF_FFFF | Strongly Ordered | *| DDR CH1-CH3 | 0x500_0000_0000 - 0x7FF_FFFF_FFFF | Normal WB Cacheable | *| PL- Via NoC | 0x800_0000_0000 - 0xFFF_FFFF_FFFF | Strongly Ordered | * * @note * * For DDR region 0x0000000000 - 0x007FFFFFFF, a system where DDR is less than * 2GB, region after DDR and before PL is marked as undefined/reserved in * translation table. Region 0xF9100000 - 0xF91FFFFF is reserved memory in * 0x00F9000000 - 0x00F91FFFFF range, but it is marked as strongly ordered * because minimum section size in translation table section is 2MB. * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 7.00 mus 05/21/14 Initial version * 7.00 mus 03/16/19 Updated translation table to mark DDR regions as * memory, based on the DDR size in hdf * 7.1 mus 08/29/19 Updated translation table entries for DDR_CH_1, * DDR_CH_2 and DDR_CH_3 based on respective size in hdf * 7.3 mus 09/10/20 Updated translation table entries for DDR regions, to * support HW designs, where DDR memory is mapped at * address other than DDR region base address. It fixes * CR#1073099. * 8.0 mus 07/06/21 Added support for VERSAL NET * 8.0 mus 10/05/21 Updated VERSAL NET translation table to configure 1 TB address * space (default is 256 TB) when OCM_ELF flag is defined * in compiler flags. * * ******************************************************************************/ #include "xparameters.h" #include "bspconfig.h" .globl MMUTableL0 .globl MMUTableL1 .globl MMUTableL2 .set UNDEF_START, 0 /* Base addresses for all DDR regions in Versal SoC */ .set DDR_LOW_0_REGION_START_ADDR, 0x0000000000 /* 0x0000_0000_0000 */ .set DDR_LOW_1_REGION_START_ADDR, 0x800000000 /* 0x0008_0000_0000 */ .set DDR_LOW_2_REGION_START_ADDR, 0xC000000000 /* 0x00C0_0000_0000 */ .set DDR_LOW_3_REGION_START_ADDR, 0x10000000000 /* 0x0100_0000_0000 */ .set DDR_CH_1_REGION_START_ADDR, 0x50000000000 /* 0x0500_0000_0000 */ .set DDR_CH_2_REGION_START_ADDR, 0x60000000000 /* 0x0600_0000_0000 */ .set DDR_CH_3_REGION_START_ADDR, 0x70000000000 /* 0x0700_0000_0000 */ .set reserved, 0x0 /* Fault*/ .set Memory_NonCacheable, 0x401 /* normal non-cacheable */ #if EL1_NONSECURE .set Memory, 0x405 | (2 << 8) | (0x0) /* normal writeback write allocate outer shared read write */ #else .set Memory, 0x405 | (3 << 8) | (0x0) /* normal writeback write allocate inner shared read write */ #endif .set Device, 0x409 | (1 << 53)| (1 << 54) |(0x0) /* strongly ordered read write non executable*/ #ifdef VERSAL_NET .section .mmu_tbl0,"a" MMUTableL0: /* * 256 sections each with 512 GB size covers 0 - 128 TB. * 128TB - 256TB is reserved in VERSAL NET address map, * so not defining sections for that region. */ .set SECT, MMUTableL1 /* 0x0000_0000 - 0x7F_FFFF_FFFF */ .8byte SECT + 0x3 #if ! defined (OCM_ELF) .rept 0xff .set SECT, SECT + 0x1000 /* 0x80_0000_0000 - 0xFFF_FFFF_FFFF */ .8byte SECT + 0x3 .endr #else .set SECT, SECT + 0x1000 /* 0x80_0000_0000 - 0xFFF_FFFF_FFFF */ .8byte SECT + 0x3 #endif .section .mmu_tbl1,"a" MMUTableL1: /* * For first 4GB of address space provide granularity * of 2MB. */ .set SECT, MMUTableL2 /* 0x0000_0000 - 0x3FFF_FFFF */ .8byte SECT + 0x3 /* 1GB DDR */ .rept 0x3 /* 0x4000_0000 - 0x1_3FFF_FFFF */ .set SECT, SECT + 0x1000 /* DDR, PS_LPD_AFI_FS, PCIE_REGION0, PS_FPD_AFI_FS, OCM, xSPI, FPD_STM_CORESIGHT,*/ .8byte SECT + 0x3 /* FPD GIC, PS_FPD_CMN, PMC, CPM, FPD slaves, LPD slaves, PMC_ALIAS_REGION0-3, FPD_PKI */ .endr /* HNIC, Multimedia tiles */ .set SECT,0x100000000 .rept 0x1C /* 0x1_0000_0000 - 0x1_FFFF_FFFF */ .8byte SECT + reserved /* 28GB Reserved */ .set SECT, SECT + 0x40000000 .endr /* TODO: Mark DDR_CH0_MED as normal memory based on HW design */ .rept 0x20 /* 0x2_0000_0000 - 0x2_FFFF_FFFF */ .8byte SECT + reserved /* 32GB DDR_CH0_MED marked as reserved for now */ .set SECT, SECT + 0x40000000 .endr .rept 0x40 /* 0x3_0000_0000 - 0x3_FFFF_FFFF */ .8byte SECT + reserved /* 64GB Reserved */ .set SECT, SECT + 0x40000000 .endr .rept 0x80 /* 0x4_0000_0000 - 0x7_FFFF_FFFF */ .8byte SECT + Device /* 128GB C2C_MED */ .set SECT, SECT + 0x40000000 .endr /* TODO: Mark HBM regions as normal memory based on the HW design */ .rept 0x100 /* 0x10_0000_0000 - 0x3F_FFFF_FFFF */ .8byte SECT + reserved /* 256GB device */ .set SECT, SECT + 0x40000000 .endr .rept 0x100 /* 0x40_0000_0000 - 0x7F_FFFF_FFFF */ .8byte SECT + reserved /* 256GB reserved */ .set SECT, SECT + 0x40000000 .endr /* TODO: Mark this region as normal memory based on HW design */ .rept 0x100 /* 0x80_0000_0000 - 0xBF_FFFF_FFFF */ .8byte SECT + reserved /* 790GB DDR (DDR_CH0_HIGH_0: 256GB + DDR_CH0_HIGH_1: 734GB) */ .set SECT, SECT + 0x40000000 .endr #if ! defined (OCM_ELF) .rept 0x234 /* 0x80_0000_0000 - 0xBF_FFFF_FFFF */ .8byte SECT + reserved /* 790GB reserved */ .set SECT, SECT + 0x40000000 .endr .rept 0x4 /* 0x200_0000_0000 - 0x200_FFFF_FFFF */ .8byte SECT + Device /* 4GB ME Programming */ .set SECT, SECT + 0x40000000 .endr .rept 0x4 /* 0x201_0000_0000 - 0x201_FFFF_FFFF */ .8byte SECT + reserved /* 4GB reserved */ .set SECT, SECT + 0x40000000 .endr .rept 0x7 /* 0x202_0000_0000 - 0x203_BFFF_FFFF */ .8byte SECT + Device /* 2GB PS_FPD_AFI_FS_CONFIG + 2GB C2C_CONFIG + 2GB PL_VIA_NOC_CONFIG + 512MB PMC_ALIAS0-3 */ .set SECT, SECT + 0x40000000 .endr .rept 0x1 /* 0x203_C000_0000 - 0x203_FFFF_FFFF */ .8byte SECT + reserved /* 1GB reserved */ .set SECT, SECT + 0x40000000 .endr .rept 0x1 /* 0x204_0000_0000 - 0x204_3FFF_FFFF */ .8byte SECT + Device /* 8MB PKI, 1016MB reserved from next section */ .set SECT, SECT + 0x40000000 .endr .rept 0x7EF /* 0x204_4000_0000 - 0x3ffffffffff */ .8byte SECT + Device /* 2031GB reserved */ .set SECT, SECT + 0x40000000 .endr .rept 0x400 /* 0x400_0000_0000 - 0x4FF_FFFF_FFFF */ .8byte SECT + Device /* 1TB PS_FPD_AFI_FS_HIGH */ .set SECT, SECT + 0x40000000 .endr /* TODO: Mark this region as normal memory based on the HW design */ .rept 0xc00 /* 0x500_0000_0000 - 0x7FF_FFFF_FFFF */ .8byte SECT + reserved /* 3TB DDR: DDR_CH1, DDr_CH2 and DDR_CH3 each with 1TB */ .set SECT, SECT + 0x40000000 .endr .rept 0x2000 /* 0x800_0000_0000 - 0xFFF_FFFF_FFFF */ .8byte SECT + Device /* 8TB PL_VIA_NOC_HIGH*/ .set SECT, SECT + 0x40000000 .endr .rept 0x2000 /* 0x800_0000_0000 - 0xFFF_FFFF_FFFF */ .8byte SECT + Device /* 8TB CPM_CDX_DPU_HIGH */ .set SECT, SECT + 0x40000000 .endr /* TODO: Mark this region as normal memory based on the HW design */ .rept 0x1800 /* 0x400_0000_0000 - 0x4FF_FFFF_FFFF */ .8byte SECT + reserved /* 6TB DDR: 12 DDR regions (DDR_CH4 to DDR_CH15) each of size 512GB */ .set SECT, SECT + 0x40000000 .endr .rept 0x800 /* 0x800_0000_0000 - 0xFFF_FFFF_FFFF */ .8byte SECT + reserved /* 2TB reserved */ .set SECT, SECT + 0x40000000 .endr .rept 0x4000 /* 0x800_0000_0000 - 0xFFF_FFFF_FFFF */ .8byte SECT + Device /* 16TB C2C_HIGH */ .set SECT, SECT + 0x40000000 .endr .rept 0x4000 /* 0x800_0000_0000 - 0xFFF_FFFF_FFFF */ .8byte SECT + reserved /* 16TB reserved */ .set SECT, SECT + 0x40000000 .endr .rept 0x10000 /* 0x800_0000_0000 - 0xFFF_FFFF_FFFF */ .8byte SECT + Device /* 64TB PSX Socket 1 */ .set SECT, SECT + 0x40000000 .endr #endif .section .mmu_tbl2,"a" MMUTableL2: .set SECT, 0 /* TODO: Configure this region as normal memory/reserved based on HW design */ .rept 0x400 /* 2GB DDR 0x0 - 0x80000000 */ .8byte SECT + Memory_NonCacheable .set SECT, SECT+0x200000 .endr .rept 0x0100 /* 0x8000_0000 - 0x9FFF_FFFF */ .8byte SECT + Device /* 512MB PS_LPD_AFI_FS */ .set SECT, SECT+0x200000 .endr .rept 0x080 /* 0xA000_0000 - 0xAFFF_FFFF */ .8byte SECT + reserved /* 256MB PCIE_REGION */ .set SECT, SECT+0x200000 .endr .rept 0x040 /* 0xB00_0000 - 0xB7FF_FFFF */ .8byte SECT + Device /* 128MB PS_FPD_AFI_FS */ .set SECT, SECT+0x200000 .endr .rept 0x01F /* 0xB800_0000 - 0xBBDF_FFFF */ .8byte SECT + reserved /* 62MB reserved */ .set SECT, SECT+0x200000 .endr /* * Note: 1 MB OCM 0xBBF0_0000 - 0xBBFF_FFFF, * 0xBBE0_0000 - 0XBBEF_FFFF marked as normal * memory incorrectly due to 2 MB granularity limitation */ .rept 0x01 /* 0xBBE0_0000 - 0xBBFF_FFFF */ .8byte SECT + Memory_NonCacheable /* 1 MB OCM 0xBBF0_0000 - 0xBBFF_FFFF, 0xBBE0_0000 - 0XBBEF_FFFF marked as normal memory incorrectly */ .set SECT, SECT+0x200000 .endr .rept 0x020 /* 0xB000_0000 - 0xBFFF_FFFF */ .8byte SECT + reserved /* 64MB reserved */ .set SECT, SECT+0x200000 .endr .rept 0x100 /* 0xE000_0000 - 0xEFFF_FFFF */ .8byte SECT + Device /* 512MB xSPI */ .set SECT, SECT+0x200000 .endr .rept 0x08 /* 0xE000_0000 - 0xEFFF_FFFF */ .8byte SECT + Device /* 16MB FPD_STM_CORESIGHT */ .set SECT, SECT+0x200000 .endr .rept 0x08 /* 0xe1000000 - 0xE1FF_FFFF */ .8byte SECT + reserved /* 16MB reserved */ .set SECT, SECT+0x200000 .endr .rept 0x02 /* 0xE200_0000 - 0xE23F_FFFF */ .8byte SECT + Device /* 4MB GIC */ .set SECT, SECT+0x200000 .endr .rept 0xE /* 0xE240_0000 - 0xE3FF_FFFF */ .8byte SECT + reserved /* 28MB reserved */ .set SECT, SECT+0x200000 .endr .rept 0x08 /* 0xE400_0000 - 0xE4FF_FFFF_ */ .8byte SECT + Device /* 16MB CPM */ .set SECT, SECT+0x200000 .endr .rept 0x8 /* 0xE500_0000 - 0xE5FF_FFFF */ .8byte SECT + reserved /* 16MB reserved */ .set SECT, SECT+0x200000 .endr .rept 0x4 /* 0xE600_0000 - 0xE67F_FFFF */ .8byte SECT + Device /* 8MB HNIC */ .set SECT, SECT+0x200000 .endr .rept 0xC /* 0xE680_0000 - 0xE7FF_FFFF */ .8byte SECT + reserved /* 24MB reserved */ .set SECT, SECT+0x200000 .endr .rept 0x4 /* 0xE800_0000 - 0xE87F_FFFF */ .8byte SECT + Device /* 8MB Multimedia tiles */ .set SECT, SECT+0x200000 .endr .rept 0xC /* 0xE880_0000 - 0xE9FF_FFFF */ .8byte SECT + reserved /* 24MB reserved */ .set SECT, SECT+0x200000 .endr .rept 0x18 /* 0xEA00_0000 - 0xECFF_FFFF */ .8byte SECT + Device /* 32MB LPD_SLAVES 16MB FPD_SLAVES */ .set SECT, SECT+0x200000 .endr .rept 0x18 /* 0xED00_0000 - 0xEFFF_FFFF */ .8byte SECT + reserved /* 24MB reserved */ .set SECT, SECT+0x200000 .endr .rept 0x40 /* 0xF000_0000 - 0xF7FF_FFFF */ .8byte SECT + Device /* 128MB PMC */ .set SECT, SECT+0x200000 .endr .rept 0x20 /* 0xF800_0000 - 0xFBFF_FFFF */ .8byte SECT + Device /* 64MB PS_FPD_CMN */ .set SECT, SECT+0x200000 .endr .rept 0x20 /* 0xFC00_0000 - 0xFFFF_FFFF */ .8byte SECT + reserved /* 32MB reserved */ .set SECT, SECT+0x200000 .endr .end #else .section .mmu_tbl0,"a" MMUTableL0: .set SECT, MMUTableL1 /* 0x0000_0000 - 0x7F_FFFF_FFFF */ .8byte SECT + 0x3 .rept 0x1f .set SECT, SECT + 0x1000 /* 0x80_0000_0000 - 0xFFF_FFFF_FFFF */ .8byte SECT + 0x3 .endr .section .mmu_tbl1,"a" MMUTableL1: .set SECT, MMUTableL2 /* 0x0000_0000 - 0x3FFF_FFFF */ .8byte SECT + 0x3 /* 1GB DDR */ .rept 0x4 /* 0x4000_0000 - 0x1_3FFF_FFFF */ .set SECT, SECT + 0x1000 /*1GB DDR, 512MB LPD_AFI_FS, 448MB FPD_AFI_0, 512MB QSPI, 256MB PCIe region 0, PMC 128MB, GIC 1 MB, reserved 47MB, 2GB other devices and memory, 512 MB PMC */ .8byte SECT + 0x3 .endr .set SECT,0x140000000 .rept 0x3 /* 0x1_4000_0000 - 0x1_FFFF_FFFF */ .8byte SECT + reserved /* 3GB Reserved */ .set SECT, SECT + 0x40000000 .endr .rept 0x4 /* 0x2_0000_0000 - 0x2_FFFF_FFFF */ .8byte SECT + Device /* 4GB ME Array 0-3*/ .set SECT, SECT + 0x40000000 .endr .rept 0x4 /* 0x3_0000_0000 - 0x3_FFFF_FFFF */ .8byte SECT + reserved /* 4GB Reserved */ .set SECT, SECT + 0x40000000 .endr .rept 0x10 /* 0x4_0000_0000 - 0x7_FFFF_FFFF */ .8byte SECT + Device /* 8GB PL - via PS, 8GB PCIe region1 */ .set SECT, SECT + 0x40000000 .endr .set UNDEF_START, 0 #ifdef XPAR_AXI_NOC_DDR_LOW_1_BASEADDR .set DDR_1_START, XPAR_AXI_NOC_DDR_LOW_1_BASEADDR .set DDR_1_END, XPAR_AXI_NOC_DDR_LOW_1_HIGHADDR .if DDR_1_START > DDR_LOW_1_REGION_START_ADDR .set UNDEF_START, (DDR_1_START - DDR_LOW_1_REGION_START_ADDR) .set UNDEF_START, (UNDEF_START)/0x40000000 .endif .set DDR_1_SIZE, (DDR_1_END - DDR_1_START)+1 .if DDR_1_SIZE > 0x800000000 /* If DDR size is larger than 32GB, truncate to 32GB */ .set DDR_1_REG, 0x20 .else .set DDR_1_REG, DDR_1_SIZE/0x40000000 .endif #else .set DDR_1_REG, 0 #warning "There's no DDR_1 in the HW design. MMU translation table marks 32 GB DDR address space as undefined" #endif .set UNDEF_1_REG, (0x20 - DDR_1_REG - UNDEF_START) .rept UNDEF_START /* reserved for region where ddr is absent */ .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept DDR_1_REG /* DDR based on size in hdf*/ .8byte SECT + Memory .set SECT, SECT+0x40000000 .endr .rept UNDEF_1_REG /* reserved for region where ddr is absent */ .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept 0xC0 /* 0x10_0000_0000 - 0x3F_FFFF_FFFF */ .8byte SECT + reserved /* 192GB Reserved */ .set SECT, SECT + 0x40000000 .endr .rept 0x100 /* 0x40_0000_0000 - 0x7F_FFFF_FFFF */ .8byte SECT + Device /* 256GB HBM 0-3*/ .set SECT, SECT + 0x40000000 .endr .rept 0x100 /* 0x80_0000_0000 - 0xBF_FFFF_FFFF */ .8byte SECT + Device /* 256GB PCIe 2 */ .set SECT, SECT + 0x40000000 .endr .set UNDEF_START, 0 #ifdef XPAR_AXI_NOC_DDR_LOW_2_BASEADDR .set DDR_2_START, XPAR_AXI_NOC_DDR_LOW_2_BASEADDR .set DDR_2_END, XPAR_AXI_NOC_DDR_LOW_2_HIGHADDR .if DDR_2_START > DDR_LOW_2_REGION_START_ADDR .set UNDEF_START, (DDR_2_START - DDR_LOW_2_REGION_START_ADDR) .set UNDEF_START, (UNDEF_START)/0x40000000 .endif .set DDR_2_SIZE, (DDR_2_END - DDR_2_START)+1 .if DDR_2_SIZE > 0x4000000000 /* If DDR size is larger than 256 GB, truncate to 256GB */ .set DDR_2_REG, 0x100 .else .set DDR_2_REG, DDR_2_SIZE/0x40000000 .endif #else .set DDR_2_REG, 0 #warning "There's no DDR_LOW_2 in the HW design. MMU translation table marks 256 GB DDR address space as undefined" #endif .set UNDEF_2_REG, (0x100 - DDR_2_REG - UNDEF_START) .rept UNDEF_START /* reserved for region where ddr is absent */ .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept DDR_2_REG /* DDR based on size in hdf 0xC0_0000_0000 - 0xFF_FFFF_FFFF */ .8byte SECT + Memory /* Maximum DDR region size - 256GB */ .set SECT, SECT + 0x40000000 .endr .rept UNDEF_2_REG /* reserved for region where ddr is absent */ .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .set UNDEF_START, 0 #ifdef XPAR_AXI_NOC_DDR_LOW_3_BASEADDR .set DDR_3_START, XPAR_AXI_NOC_DDR_LOW_3_BASEADDR .set DDR_3_END, XPAR_AXI_NOC_DDR_LOW_3_HIGHADDR .if DDR_3_START > DDR_LOW_3_REGION_START_ADDR .set UNDEF_START, (DDR_3_START - DDR_LOW_3_REGION_START_ADDR) .set UNDEF_START, (UNDEF_START)/0x40000000 .endif .set DDR_3_SIZE, (DDR_3_END - DDR_3_START)+1 .if DDR_3_SIZE > 0xB780000000 /* If DDR size is larger than 734 GB, truncate to 734GB */ .set DDR_3_REG, 0x2de .else .set DDR_3_REG, DDR_3_SIZE/0x40000000 .endif #else .set DDR_3_REG, 0 #warning "There's no DDR_LOW_3 in the HW design. MMU translation table marks 734 GB DDR address space as undefined" #endif .set UNDEF_3_REG, (0x2de - DDR_3_REG - UNDEF_START) .rept UNDEF_START /* reserved for region where ddr is absent */ .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept DDR_3_REG /* DDR based on size in hdf 0x100_0000_0000 - 0x1B7_7FFF_FFFF */ .8byte SECT + Memory /* Maximum DDR region size - 734GB DDR */ .set SECT, SECT + 0x40000000 .endr .rept UNDEF_3_REG /* reserved for region where ddr is absent */ .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept 0x122 /* 0x1B7_8000_0000 - 0x1FF_FFFF_FFFF */ .8byte SECT + reserved /* 290GB reserved */ .set SECT, SECT + 0x40000000 .endr .rept 0x800 /* 0x200_0000_0000 - 0x3FF_FFFF_FFFF */ .8byte SECT + Device /* 2TB PL- via NoC */ .set SECT, SECT + 0x40000000 .endr .rept 0x400 /* 0x400_0000_0000 - 0x4FF_FFFF_FFFF */ .8byte SECT + Device /* 1TB PL- via PS */ .set SECT, SECT + 0x40000000 .endr .set UNDEF_START, 0 #ifdef XPAR_AXI_NOC_DDR_CH_1_BASEADDR .set DDR_CH_1_START, XPAR_AXI_NOC_DDR_CH_1_BASEADDR .set DDR_CH_1_END, XPAR_AXI_NOC_DDR_CH_1_HIGHADDR .if DDR_CH_1_START > DDR_CH_1_REGION_START_ADDR .set UNDEF_START, (DDR_CH_1_START - DDR_CH_1_REGION_START_ADDR) .set UNDEF_START, (UNDEF_START)/0x40000000 .endif .set DDR_CH_1_SIZE, (DDR_CH_1_END - DDR_CH_1_START)+1 .if DDR_CH_1_SIZE > 0x010000000000 /* If DDR size is larger than 1TB, truncate to 1 TB */ .set DDR_CH_1_REG, 0x400 /* 0x500_0000_0000 - 0x5FF_FFFF_FFFF */ .else .set DDR_CH_1_REG, DDR_CH_1_SIZE/0x40000000 .endif #else .set DDR_CH_1_REG, 0 #warning "There's no DDR_CH_1 in the HW design. MMU translation table marks 1 TB DDR address space as undefined" #endif .set UNDEF_CH_1_REG, (0x400 - DDR_CH_1_REG - UNDEF_START) .rept UNDEF_START /* reserved for region where ddr is absent */ .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept DDR_CH_1_REG /* DDR based on size in hdf, Max size 1 TB*/ .8byte SECT + Memory .set SECT, SECT+0x40000000 .endr .rept UNDEF_CH_1_REG /* reserved for region where ddr is absent */ .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .set UNDEF_START, 0 #ifdef XPAR_AXI_NOC_DDR_CH_2_BASEADDR .set DDR_CH_2_START, XPAR_AXI_NOC_DDR_CH_2_BASEADDR .set DDR_CH_2_END, XPAR_AXI_NOC_DDR_CH_2_HIGHADDR .if DDR_CH_2_START > DDR_CH_2_REGION_START_ADDR .set UNDEF_START, (DDR_CH_2_START - DDR_CH_2_REGION_START_ADDR) .set UNDEF_START, (UNDEF_START)/0x40000000 .endif .set DDR_CH_2_SIZE, (DDR_CH_2_END - DDR_CH_2_START)+1 .if DDR_CH_2_SIZE > 0x010000000000 /* If DDR_CH_2 size is larger than 1TB, truncate to 1 TB */ .set DDR_CH_2_REG, 0x400 /* 0x600_0000_0000 - 0x6FF_FFFF_FFFF */ .else .set DDR_CH_2_REG, DDR_CH_2_SIZE/0x40000000 .endif #else .set DDR_CH_2_REG, 0 #warning "There's no DDR_CH_2 in the HW design. MMU translation table marks 1 TB DDR address space as undefined" #endif .set UNDEF_CH_2_REG, (0x400 - DDR_CH_2_REG - UNDEF_START) .rept UNDEF_START /* reserved for region where ddr is absent */ .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept DDR_CH_2_REG /* DDR based on size in hdf, Max size 1 TB*/ .8byte SECT + Memory .set SECT, SECT+0x40000000 .endr .rept UNDEF_CH_2_REG /* reserved for region where ddr is absent */ .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .set UNDEF_START, 0 #ifdef XPAR_AXI_NOC_DDR_CH_3_BASEADDR .set DDR_CH_3_START, XPAR_AXI_NOC_DDR_CH_3_BASEADDR .set DDR_CH_3_END, XPAR_AXI_NOC_DDR_CH_3_HIGHADDR .if DDR_CH_3_START > DDR_CH_3_REGION_START_ADDR .set UNDEF_START, (DDR_CH_3_START - DDR_CH_3_REGION_START_ADDR) .set UNDEF_START, (UNDEF_START)/0x40000000 .endif .set DDR_CH_3_SIZE, (DDR_CH_3_END - DDR_CH_3_START)+1 .if DDR_CH_3_SIZE > 0x010000000000 /* If DDR_CH_3 size is larger than 1TB, truncate to 1 TB */ .set DDR_CH_3_REG, 0x400 /* 0x700_0000_0000 - 0x7FF_FFFF_FFFF */ .else .set DDR_CH_3_REG, DDR_CH_3_SIZE/0x40000000 .endif #else .set DDR_CH_3_REG, 0 #warning "There's no DDR_CH_3 in the HW design. MMU translation table marks 1 TB DDR address space as undefined" #endif .set UNDEF_CH_3_REG, (0x400 - DDR_CH_3_REG - UNDEF_START) .rept UNDEF_START /* reserved for region where ddr is absent */ .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept DDR_CH_3_REG /* DDR based on size in hdf, Max size 1 TB*/ .8byte SECT + Memory .set SECT, SECT+0x40000000 .endr .rept UNDEF_CH_3_REG /* reserved for region where ddr is absent */ .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept 0x2000 /* 0x800_0000_0000 - 0xFFF_FFFF_FFFF */ .8byte SECT + Device /* 8TB PL- via NoC*/ .set SECT, SECT + 0x40000000 .endr .section .mmu_tbl2,"a" MMUTableL2: .set SECT, 0 .set UNDEF_START, 0 #ifdef XPAR_AXI_NOC_DDR_LOW_0_BASEADDR .set DDR_0_START, XPAR_AXI_NOC_DDR_LOW_0_BASEADDR .set DDR_0_END, XPAR_AXI_NOC_DDR_LOW_0_HIGHADDR .if DDR_0_START > DDR_LOW_0_REGION_START_ADDR .set UNDEF_START, (DDR_0_START - DDR_LOW_0_REGION_START_ADDR) .set UNDEF_START, (UNDEF_START)/0x200000 .endif .set DDR_0_SIZE, (DDR_0_END - DDR_0_START)+1 .if DDR_0_SIZE > 0x80000000 /* If DDR size is larger than 2GB, truncate to 2GB */ .set DDR_0_REG, 0x400 .else .set DDR_0_REG, DDR_0_SIZE/0x200000 .endif #else .set DDR_0_REG, 0 #warning "There's no DDR_0 in the HW design. MMU translation table marks 2 GB DDR address space as undefined" #endif .set UNDEF_0_REG, (0x400 - DDR_0_REG - UNDEF_START) .rept UNDEF_START /* reserved for region where ddr is absent */ .8byte SECT + reserved .set SECT, SECT+0x200000 .endr .rept DDR_0_REG /* DDR based on size in hdf*/ .8byte SECT + Memory .set SECT, SECT+0x200000 .endr .rept UNDEF_0_REG /* reserved for region where ddr is absent */ .8byte SECT + reserved .set SECT, SECT+0x200000 .endr .rept 0x0100 /* 0x8000_0000 - 0xBFFF_FFFF */ .8byte SECT + Device /* 512MB LPD AFI */ .set SECT, SECT+0x200000 .endr .rept 0x020 /* 0xA000_0000 - 0xA3FF_FFFF */ .8byte SECT + reserved /* 64MB reserved*/ .set SECT, SECT+0x200000 .endr .rept 0x60 /* 0xA400_0000 - 0xAFFF_FFFF */ .8byte SECT + Device /* 192MB FPD AFI 0 */ .set SECT, SECT+0x200000 .endr .rept 0x80 /* 0xB000_0000 - 0xBFFF_FFFF */ .8byte SECT + Device /* 192MB FPD AFI 1 */ .set SECT, SECT+0x200000 .endr .rept 0x100 /* 0xC000_0000 - 0xDFFF_FFFF */ .8byte SECT + Device /* 512MB QSPI */ .set SECT, SECT+0x200000 .endr .rept 0x080 /* 0xE000_0000 - 0xEFFF_FFFF */ .8byte SECT + Device /* 256MB lower PCIe */ .set SECT, SECT+0x200000 .endr .rept 0x040 /* 0xF000_0000 - 0xF7FF_FFFF */ .8byte SECT + Device /* 128MB PMC */ .set SECT, SECT+0x200000 .endr .rept 0x08 /* 0xF800_0000 - 0xF8FF_FFFF */ .8byte SECT + Device /* 16MB coresight */ .set SECT, SECT+0x200000 .endr /* 1MB GIC is marked for 2MB region as the minimum block size in translation table is 2MB and adjacent 47MB reserved region is converted to 46MB */ .8byte SECT + Device /* 0xF910_0000 - 0xF90F_FFFF */ /* Reserved 46MB 0xF91FFFFF - 0xFBFFFFFF*/ .rept 0x17 /* 0xF91F_FFFF - 0xFBFF_FFFF */ .set SECT, SECT+0x200000 .8byte SECT + reserved /* 46MB reserved */ .endr .rept 0x1F /* 0xFC00_0000 - 0xFFDF_FFFF */ .set SECT, SECT+0x200000 .8byte SECT + Device /* 16MB CPM,16MB FPS, 30MB LPS slaves */ .endr .set SECT, SECT+0x200000 /* 0xFFE0_0000 - 0xFFFF_FFFF*/ .8byte SECT + Memory /*2MB OCM/TCM*/ .rept 0x100 /* 0x1_0000_0000 - 0x1_1FFF_FFFF */ .set SECT, SECT+0x200000 .8byte SECT + Device /* 512MB PMC 0-3 */ .endr .rept 0x100 /* 0x1_2000_0000 - 0x1_3FFF_FFFF */ .set SECT, SECT+0x200000 .8byte SECT + reserved /* 512MB reserved */ .endr .end #endif /** * @} End of "addtogroup a53_64_boot_code". */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

8,548

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/platform/ZynqMP/armclang/translation_table.S

;/****************************************************************************** ;* Copyright (c) 2018 - 2020 Xilinx, Inc. All rights reserved. ;* SPDX-License-Identifier: MIT ;******************************************************************************/ ;/*****************************************************************************/ ;/** ;* @file translation_table.s ;* ;* @addtogroup a53_64_boot_code ;* @{ ;* <h2> translation_table.S </h2> ;* translation_table.S contains a static page table required by MMU for ;* cortex-A53. This translation table is flat mapped (input address = output ;* address) with default memory attributes defined for zynq ultrascale+ ;* architecture. It utilizes translation granule size of 4KB with 2MB section ;* size for initial 4GB memory and 1GB section size for memory after 4GB. ;* The overview of translation table memory attributes is described below. ;* ;*| | Memory Range | Definition in Translation Table | ;*|-----------------------|-----------------------------|-----------------------------------| ;*| DDR | 0x0000000000 - 0x007FFFFFFF | Normal write-back Cacheable | ;*| PL | 0x0080000000 - 0x00BFFFFFFF | Strongly Ordered | ;*| QSPI, lower PCIe | 0x00C0000000 - 0x00EFFFFFFF | Strongly Ordered | ;*| Reserved | 0x00F0000000 - 0x00F7FFFFFF | Unassigned | ;*| STM Coresight | 0x00F8000000 - 0x00F8FFFFFF | Strongly Ordered | ;*| GIC | 0x00F9000000 - 0x00F91FFFFF | Strongly Ordered | ;*| Reserved | 0x00F9200000 - 0x00FCFFFFFF | Unassigned | ;*| FPS, LPS slaves | 0x00FD000000 - 0x00FFBFFFFF | Strongly Ordered | ;*| CSU, PMU | 0x00FFC00000 - 0x00FFDFFFFF | Strongly Ordered | ;*| TCM, OCM | 0x00FFE00000 - 0x00FFFFFFFF | Normal inner write-back cacheable | ;*| Reserved | 0x0100000000 - 0x03FFFFFFFF | Unassigned | ;*| PL, PCIe | 0x0400000000 - 0x07FFFFFFFF | Strongly Ordered | ;*| DDR | 0x0800000000 - 0x0FFFFFFFFF | Normal inner write-back cacheable | ;*| PL, PCIe | 0x1000000000 - 0xBFFFFFFFFF | Strongly Ordered | ;*| Reserved | 0xC000000000 - 0xFFFFFFFFFF | Unassigned | ;* ;* @note ;* ;* For DDR region 0x0000000000 - 0x007FFFFFFF, a system where DDR is less than ;* 2GB, region after DDR and before PL is marked as undefined/reserved in ;* translation table. Region 0xF9100000 - 0xF91FFFFF is reserved memory in ;* 0x00F9000000 - 0x00F91FFFFF range, but it is marked as strongly ordered ;* because minimum section size in translation table section is 2MB. Region ;* 0x00FFC00000 - 0x00FFDFFFFF contains CSU and PMU memory which are marked as ;* Device since it is less than 1MB and falls in a region with device memory. ;* ;* <pre> ;* MODIFICATION HISTORY: ;* ;* Ver Who Date Changes ;* ----- ---- -------- --------------------------------------------------- ;* 7.0 cjp 02/26/19 First release ;* ;******************************************************************************/ #include "xparameters.h" #include "bspconfig.h" EXPORT MMUTableL0 EXPORT MMUTableL1 EXPORT MMUTableL2 GBLA abscnt GBLA count GBLA sect ; Fault Reserved EQU 0 #if (EL1_NONSECURE == 1) Memory EQU 0x405:OR:(2:SHL:8):OR:0x0 ; Normal writeback write allocate outer shared read write #else Memory EQU 0x405:OR:(3:SHL:8):OR:0x0 ; Normal writeback write allocate inner shared read write #endif Device EQU 0x409:OR:(1:SHL:53):OR:(1:SHL:54):OR:0x0 ; Strongly ordered read write non executable AREA |.mmu_tbl0|, CODE, ALIGN=12 MMUTableL0 DCQU MMUTableL1+0x3 ; 0x0000_0000 - 0x7F_FFFF_FFFF DCQU MMUTableL1+0x1000+0x3 ; 0x80_0000_0000 - 0xFF_FFFF_FFFF AREA |.mmu_tbl1|, CODE, ALIGN=12 MMUTableL1 ; ; 0x4000_0000 - 0xFFFF_FFFF ; 1GB DDR, 1GB PL, 2GB other devices n memory ; count SETA 0 WHILE count<0x4 DCQU MMUTableL2+count*0x1000+0x3 count SETA count+1 WEND Fixlocl1 EQU 0x100000000 abscnt SETA 0 ; ; 0x0001_0000_0000 - 0x0003_FFFF_FFFF ; 12GB Reserved ; count SETA 0 WHILE count<0xc DCQU Fixlocl1+abscnt*0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0x0004_0000_0000 - 0x0007_FFFF_FFFF ; 8GB PL, 8GB PCIe ; count SETA 0 WHILE count<0x10 DCQU Fixlocl1+abscnt*0x40000000+Device count SETA count+1 abscnt SETA abscnt+1 WEND #ifdef XPAR_PSU_DDR_1_S_AXI_BASEADDR DDR_1_START EQU XPAR_PSU_DDR_1_S_AXI_BASEADDR DDR_1_END EQU XPAR_PSU_DDR_1_S_AXI_HIGHADDR DDR_1_SIZE EQU (DDR_1_END - DDR_1_START + 1) #if (DDR_1_SIZE > 0x800000000) DDR_1_REG EQU 0x20 ; If DDR size is larger than 32GB, truncate to 32GB #else DDR_1_REG EQU DDR_1_SIZE / 0x40000000 #endif #else DDR_1_REG EQU 0 #endif UNDEF_1_REG EQU (0x20 - DDR_1_REG) ; DDR based on size in hdf count SETA 0 WHILE count<DDR_1_REG DCQU Fixlocl1+abscnt*0x40000000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_1_REG DCQU Fixlocl1+abscnt*0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0x0010_0000_0000 - 0x007F_FFFF_FFFF ; 448 GB PL ; count SETA 0 WHILE count<0x1C0 DCQU Fixlocl1 + abscnt * 0x40000000 + Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0x0080_0000_0000 - 0x00BF_FFFF_FFFF ; 256GB PCIe ; count SETA 0 WHILE count<0x100 DCQU Fixlocl1+abscnt*0x40000000+Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0x00C0_0000_0000 - 0x00FF_FFFF_FFFF ; 256GB Reserved ; count SETA 0 WHILE count<0x100 DCQU Fixlocl1+abscnt*0x40000000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND AREA |.mmu_tbl2|, CODE, ALIGN=12 MMUTableL2 abscnt SETA 0 #ifdef XPAR_PSU_DDR_0_S_AXI_BASEADDR DDR_0_START EQU XPAR_PSU_DDR_0_S_AXI_BASEADDR DDR_0_END EQU XPAR_PSU_DDR_0_S_AXI_HIGHADDR DDR_0_SIZE EQU (DDR_0_END - DDR_0_START + 1) #if (DDR_0_SIZE > 0x80000000) DDR_0_REG EQU 0x400 ; If DDR size is larger than 2GB, truncate to 2GB #else DDR_0_REG EQU DDR_0_SIZE / 0x200000 #endif #else DDR_0_REG EQU 0 #endif UNDEF_0_REG EQU (0x400 - DDR_0_REG) ; DDR based on size in hdf count SETA 0 WHILE count<DDR_0_REG DCQU abscnt*0x200000+Memory count SETA count+1 abscnt SETA abscnt+1 WEND ; Reserved for region where ddr is absent count SETA 0 WHILE count<UNDEF_0_REG DCQU abscnt*0x200000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0x8000_0000 - 0xBFFF_FFFF ; 1GB lower PL ; count SETA 0 WHILE count<0x0200 DCQU abscnt*0x200000+Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0xC000_0000 - 0xDFFF_FFFF ; 512MB QSPI ; count SETA 0 WHILE count<0x0100 DCQU abscnt*0x200000+Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0xE000_0000 - 0xEFFF_FFFF ; 256MB lower PCIe ; count SETA 0 WHILE count<0x080 DCQU abscnt*0x200000+Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0xF000_0000 - 0xF7FF_FFFF ; 128MB Reserved ; count SETA 0 WHILE count<0x040 DCQU abscnt*0x200000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0xF800_0000 - 0xF8FF_FFFF ; 16MB Coresight ; count SETA 0 WHILE count<0x8 DCQU abscnt*0x200000+Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 1MB RPU LLP is marked for 2MB region as the minimum block size in translation ; table is 2MB and adjacent 63MB reserved region is converted to 62MB ; ; ; 0xF900_0000 - 0xF91F_FFFF ; 2MB RPU low latency port ; count SETA 0 WHILE count<0x1 DCQU abscnt*0x200000+Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0xF920_0000 - 0xFCFF_FFFF ; 62MB Reserved ; count SETA 0 WHILE count<0x1f DCQU abscnt*0x200000+Reserved count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0xFD00_0000 - 0xFDFF_FFFF ; 16MB FPS ; count SETA 0 WHILE count<0x8 DCQU abscnt*0x200000+Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0xFE00_0000 - 0xFFBF_FFFF ; 28MB LPS ; count SETA 0 WHILE count<0xE DCQU abscnt*0x200000+Device count SETA count+1 abscnt SETA abscnt+1 WEND ; ; 0xFFC0_0000 - 0xFFDF_FFFF ; 2MB PMU/CSU ; DCQU abscnt*0x200000+Device abscnt SETA abscnt+1 ; ; 0xFFE0_0000 - 0xFFFF_FFFF ; 2MB OCM/TCM ; DCQU abscnt*0x200000+Memory END ; ; @} End of "addtogroup a53_64_boot_code" ;

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

8,360

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/64bit/platform/ZynqMP/gcc/translation_table.S

/****************************************************************************** * Copyright (c) 2014 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file translation_table.s * * @addtogroup a53_64_boot_code * @{ * <h2> translation_table.S </h2> * translation_table.S contains a static page table required by MMU for * cortex-A53. This translation table is flat mapped (input address = output * address) with default memory attributes defined for zynq ultrascale+ * architecture. It utilizes translation granual size of 4KB with 2MB section * size for initial 4GB memory and 1GB section size for memory after 4GB. * The overview of translation table memory attributes is described below. * *| | Memory Range | Definition in Translation Table | *|-----------------------|-----------------------------|-----------------------------------| *| DDR | 0x0000000000 - 0x007FFFFFFF | Normal write-back Cacheable | *| PL | 0x0080000000 - 0x00BFFFFFFF | Strongly Ordered | *| QSPI, lower PCIe | 0x00C0000000 - 0x00EFFFFFFF | Strongly Ordere | *| Reserved | 0x00F0000000 - 0x00F7FFFFFF | Unassigned | *| STM Coresight | 0x00F8000000 - 0x00F8FFFFFF | Strongly Ordered | *| GIC | 0x00F9000000 - 0x00F91FFFFF | Strongly Ordered | *| Reserved | 0x00F9200000 - 0x00FCFFFFFF | Unassigned | *| FPS, LPS slaves | 0x00FD000000 - 0x00FFBFFFFF | Strongly Ordered | *| CSU, PMU | 0x00FFC00000 - 0x00FFDFFFFF | Strongly Ordered | *| TCM, OCM | 0x00FFE00000 - 0x00FFFFFFFF | Normal inner write-back cacheable | *| Reserved | 0x0100000000 - 0x03FFFFFFFF | Unassigned | *| PL, PCIe | 0x0400000000 - 0x07FFFFFFFF | Strongly Ordered | *| DDR | 0x0800000000 - 0x0FFFFFFFFF | Normal inner write-back cacheable | *| PL, PCIe | 0x1000000000 - 0xBFFFFFFFFF | Strongly Ordered | *| Reserved | 0xC000000000 - 0xFFFFFFFFFF | Unassigned | * * @note * * For DDR region 0x0000000000 - 0x007FFFFFFF, a system where DDR is less than * 2GB, region after DDR and before PL is marked as undefined/reserved in * translation table. Region 0xF9100000 - 0xF91FFFFF is reserved memory in * 0x00F9000000 - 0x00F91FFFFF range, but it is marked as strongly ordered * because minimum section size in translation table section is 2MB. Region * 0x00FFC00000 - 0x00FFDFFFFF contains CSU and PMU memory which are marked as * Device since it is less than 1MB and falls in a region with device memory. * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 5.00 pkp 05/21/14 Initial version * 5.04 pkp 12/18/15 Updated the address map according to proper address map * 6.0 mus 07/20/16 Added warning for ddrless HW design CR-954977 * 6.2 pkp 12/14/16 DDR memory in 0x800000000 - 0xFFFFFFFFF range is marked * as normal writeback for the size defined in hdf and rest * of the memory in that 32GB range is marked as reserved. * 6.4 mus 08/10/17 Marked memory as a outer shareable for EL1 NS execution, * to support CCI enabled IP's. * * ******************************************************************************/ #include "xparameters.h" #include "bspconfig.h" .globl MMUTableL0 .globl MMUTableL1 .globl MMUTableL2 .set reserved, 0x0 /* Fault*/ #if EL1_NONSECURE .set Memory, 0x405 | (2 << 8) | (0x0) /* normal writeback write allocate outer shared read write */ #else .set Memory, 0x405 | (3 << 8) | (0x0) /* normal writeback write allocate inner shared read write */ #endif .set Device, 0x409 | (1 << 53)| (1 << 54) |(0x0) /* strongly ordered read write non executable*/ .section .mmu_tbl0,"a" MMUTableL0: .set SECT, MMUTableL1 /* 0x0000_0000 - 0x7F_FFFF_FFFF */ .8byte SECT + 0x3 .set SECT, MMUTableL1+0x1000 /* 0x80_0000_0000 - 0xFF_FFFF_FFFF */ .8byte SECT + 0x3 .section .mmu_tbl1,"a" MMUTableL1: .set SECT, MMUTableL2 /* 0x0000_0000 - 0x3FFF_FFFF */ .8byte SECT + 0x3 /* 1GB DDR */ .rept 0x3 /* 0x4000_0000 - 0xFFFF_FFFF */ .set SECT, SECT + 0x1000 /*1GB DDR, 1GB PL, 2GB other devices n memory */ .8byte SECT + 0x3 .endr .set SECT,0x100000000 .rept 0xC /* 0x0001_0000_0000 - 0x0003_FFFF_FFFF */ .8byte SECT + reserved /* 12GB Reserved */ .set SECT, SECT + 0x40000000 .endr .rept 0x10 /* 0x0004_0000_0000 - 0x0007_FFFF_FFFF */ .8byte SECT + Device /* 8GB PL, 8GB PCIe */ .set SECT, SECT + 0x40000000 .endr #ifdef XPAR_PSU_DDR_1_S_AXI_BASEADDR .set DDR_1_START, XPAR_PSU_DDR_1_S_AXI_BASEADDR .set DDR_1_END, XPAR_PSU_DDR_1_S_AXI_HIGHADDR .set DDR_1_SIZE, (DDR_1_END - DDR_1_START)+1 .if DDR_1_SIZE > 0x800000000 /* If DDR size is larger than 32GB, truncate to 32GB */ .set DDR_1_REG, 0x20 .else .set DDR_1_REG, DDR_1_SIZE/0x40000000 .endif #else .set DDR_1_REG, 0 #warning "There's no DDR_1 in the HW design. MMU translation table marks 32 GB DDR address space as undefined" #endif .set UNDEF_1_REG, 0x20 - DDR_1_REG .rept DDR_1_REG /* DDR based on size in hdf*/ .8byte SECT + Memory .set SECT, SECT+0x40000000 .endr .rept UNDEF_1_REG /* reserved for region where ddr is absent */ .8byte SECT + reserved .set SECT, SECT+0x40000000 .endr .rept 0x1C0 /* 0x0010_0000_0000 - 0x007F_FFFF_FFFF */ .8byte SECT + Device /* 448 GB PL */ .set SECT, SECT + 0x40000000 .endr .rept 0x100 /* 0x0080_0000_0000 - 0x00BF_FFFF_FFFF */ .8byte SECT + Device /* 256GB PCIe */ .set SECT, SECT + 0x40000000 .endr .rept 0x100 /* 0x00C0_0000_0000 - 0x00FF_FFFF_FFFF */ .8byte SECT + reserved /* 256GB reserved */ .set SECT, SECT + 0x40000000 .endr .section .mmu_tbl2,"a" MMUTableL2: .set SECT, 0 #ifdef XPAR_PSU_DDR_0_S_AXI_BASEADDR .set DDR_0_START, XPAR_PSU_DDR_0_S_AXI_BASEADDR .set DDR_0_END, XPAR_PSU_DDR_0_S_AXI_HIGHADDR .set DDR_0_SIZE, (DDR_0_END - DDR_0_START)+1 .if DDR_0_SIZE > 0x80000000 /* If DDR size is larger than 2GB, truncate to 2GB */ .set DDR_0_REG, 0x400 .else .set DDR_0_REG, DDR_0_SIZE/0x200000 .endif #else .set DDR_0_REG, 0 #warning "There's no DDR_0 in the HW design. MMU translation table marks 2 GB DDR address space as undefined" #endif .set UNDEF_0_REG, 0x400 - DDR_0_REG .rept DDR_0_REG /* DDR based on size in hdf*/ .8byte SECT + Memory .set SECT, SECT+0x200000 .endr .rept UNDEF_0_REG /* reserved for region where ddr is absent */ .8byte SECT + reserved .set SECT, SECT+0x200000 .endr .rept 0x0200 /* 0x8000_0000 - 0xBFFF_FFFF */ .8byte SECT + Device /* 1GB lower PL */ .set SECT, SECT+0x200000 .endr .rept 0x0100 /* 0xC000_0000 - 0xDFFF_FFFF */ .8byte SECT + Device /* 512MB QSPI */ .set SECT, SECT+0x200000 .endr .rept 0x080 /* 0xE000_0000 - 0xEFFF_FFFF */ .8byte SECT + Device /* 256MB lower PCIe */ .set SECT, SECT+0x200000 .endr .rept 0x040 /* 0xF000_0000 - 0xF7FF_FFFF */ .8byte SECT + reserved /* 128MB Reserved */ .set SECT, SECT+0x200000 .endr .rept 0x8 /* 0xF800_0000 - 0xF8FF_FFFF */ .8byte SECT + Device /* 16MB coresight */ .set SECT, SECT+0x200000 .endr /* 1MB RPU LLP is marked for 2MB region as the minimum block size in translation table is 2MB and adjacent 63MB reserved region is converted to 62MB */ .rept 0x1 /* 0xF900_0000 - 0xF91F_FFFF */ .8byte SECT + Device /* 2MB RPU low latency port */ .set SECT, SECT+0x200000 .endr .rept 0x1F /* 0xF920_0000 - 0xFCFF_FFFF */ .8byte SECT + reserved /* 62MB Reserved */ .set SECT, SECT+0x200000 .endr .rept 0x8 /* 0xFD00_0000 - 0xFDFF_FFFF */ .8byte SECT + Device /* 16MB FPS */ .set SECT, SECT+0x200000 .endr .rept 0xE /* 0xFE00_0000 - 0xFFBF_FFFF */ .8byte SECT + Device /* 28MB LPS */ .set SECT, SECT+0x200000 .endr /* 0xFFC0_0000 - 0xFFDF_FFFF */ .8byte SECT + Device /*2MB PMU/CSU */ .set SECT, SECT+0x200000 /* 0xFFE0_0000 - 0xFFFF_FFFF*/ .8byte SECT + Memory /*2MB OCM/TCM*/ .end /** * @} End of "addtogroup a53_64_boot_code". */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

2,156

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/32bit/gcc/xil-crt0.S

/****************************************************************************** * Copyright (c) 2015 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file xil-crt0.S * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 5.2 pkp 28/05/15 First release * 5.4 pkp 18/12/15 Initialized global constructor for C++ applications * 6.6 srm 10/18/17 Added timer configuration using XTime_StartTTCTimer API. * Now the TTC instance as specified by the user will be * started. * </pre> * * @note * * None. * ******************************************************************************/ #include "xparameters.h" .file "xil-crt0.S" .section ".got2","aw" .align 2 .text .Lsbss_start: .long __sbss_start .Lsbss_end: .long __sbss_end .Lbss_start: .long __bss_start__ .Lbss_end: .long __bss_end__ .Lstack: .long __stack .globl _startup _startup: mov r0, #0 /* clear sbss */ ldr r1,.Lsbss_start /* calculate beginning of the SBSS */ ldr r2,.Lsbss_end /* calculate end of the SBSS */ .Lloop_sbss: cmp r1,r2 bge .Lenclsbss /* If no SBSS, no clearing required */ str r0, [r1], #4 b .Lloop_sbss .Lenclsbss: /* clear bss */ ldr r1,.Lbss_start /* calculate beginning of the BSS */ ldr r2,.Lbss_end /* calculate end of the BSS */ .Lloop_bss: cmp r1,r2 bge .Lenclbss /* If no BSS, no clearing required */ str r0, [r1], #4 b .Lloop_bss .Lenclbss: /* set stack pointer */ ldr r13,.Lstack /* stack address */ /* run global constructors */ bl __libc_init_array /* Reset and start Triple Timer Counter */ #if defined (SLEEP_TIMER_BASEADDR) bl XTime_StartTTCTimer #endif /* make sure argc and argv are valid */ mov r0, #0 mov r1, #0 bl main /* Jump to main C code */ /* Cleanup global constructors */ bl __libc_fini_array bl exit .Lexit: /* should never get here */ b .Lexit .Lstart: .size _startup,.Lstart-_startup

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

4,011

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/32bit/gcc/asm_vectors.S

/****************************************************************************** * Copyright (c) 2015 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file asm_vectors.S * * This file contains the initial vector table for the Cortex A53 processor * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 5.2 pkp 28/05/15 First release * 6.0 mus 27/07/16 Added Undefined exception handler * 6.4 mus 25/07/17 Added support for hard floating point * </pre> * * @note * * None. * ******************************************************************************/ .org 0 .text .globl _boot .globl _vector_table .globl FIQInterrupt .globl IRQInterrupt .globl SWInterrupt .globl DataAbortInterrupt .globl PrefetchAbortInterrupt .globl IRQHandler .globl prof_pc .section .vectors, "a" _vector_table: B _boot B Undefined B SVCHandler B PrefetchAbortHandler B DataAbortHandler NOP /* Placeholder for address exception vector*/ B IRQHandler B FIQHandler IRQHandler: /* IRQ vector handler */ stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code*/ vpush {d0-d7} vpush {d16-d31} vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} bl IRQInterrupt /* IRQ vector */ pop {r1} vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d16-d31} vpop {d0-d7} ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ subs pc, lr, #4 /* adjust return */ FIQHandler: /* FIQ vector handler */ stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code */ vpush {d0-d7} vpush {d16-d31} vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} FIQLoop: bl FIQInterrupt /* FIQ vector */ pop {r1} vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d16-d31} vpop {d0-d7} ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ subs pc, lr, #4 /* adjust return */ Undefined: /* Undefined handler */ stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code */ ldr r0, =UndefinedExceptionAddr sub r1, lr, #4 str r1, [r0] /* Store address of instruction causing undefined exception */ bl UndefinedException /* UndefinedException: call C function here */ ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ movs pc, lr SVCHandler: /* SWI handler */ stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code */ tst r0, #0x20 /* check the T bit */ ldrneh r0, [lr,#-2] /* Thumb mode */ bicne r0, r0, #0xff00 /* Thumb mode */ ldreq r0, [lr,#-4] /* ARM mode */ biceq r0, r0, #0xff000000 /* ARM mode */ bl SWInterrupt /* SWInterrupt: call C function here */ ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ movs pc, lr /*return to the next instruction after the SWI instruction */ DataAbortHandler: /* Data Abort handler */ stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code */ ldr r0, =DataAbortAddr sub r1, lr, #8 str r1, [r0] /* Stores instruction causing data abort */ bl DataAbortInterrupt /*DataAbortInterrupt :call C function here */ ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ subs pc, lr, #8 /* points to the instruction that caused the Data Abort exception */ PrefetchAbortHandler: /* Prefetch Abort handler */ stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code */ ldr r0, =PrefetchAbortAddr sub r1, lr, #4 str r1, [r0] /* Stores instruction causing prefetch abort */ bl PrefetchAbortInterrupt /* PrefetchAbortInterrupt: call C function here */ ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ subs pc, lr, #4 /* points to the instruction that caused the Prefetch Abort exception */ .end

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

9,225

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/32bit/gcc/boot.S

/****************************************************************************** * Copyright (c) 2015 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file boot.S * * @addtogroup a53_32_boot_code Cortex A53 32bit Processor Boot Code * @{ * <h2> boot.S </h2> * The boot.S file contains a minimal set of code for transferring control from the * processor reset location to the start of the application. The boot code performs * minimum configuration which is required for an application to run starting from * processor reset state of the processor. Below is a sequence illustrating what all * configuration is performed before control reaches to main function. * * 1. Program vector table base for exception handling * 2. Invalidate instruction cache, data cache and TLBs * 3. Program stack pointer for various modes (IRQ, FIQ, supervisor, undefine, * abort, system) * 4. Program counter frequency * 5. Configure MMU with short descriptor translation table format and program * base address of translation table * 6. Enable data cache, instruction cache and MMU * 7. Transfer control to _start which clears BSS sections and runs global * constructor before jumping to main application * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 5.2 pkp 28/05/15 First release * 5.4 pkp 09/11/15 Enable I-Cache and D-Cache in the initialization * 6.0 pkp 07/25/16 Program the counter frequency * 6.4 mus 07/25/17 Set VFP enable bit in FPEXC register, to support * hard floating point in BSP * </pre> * * ******************************************************************************/ #include "xparameters.h" .globl MMUTable .global _prestart .global _boot .global __stack .global __irq_stack .global __supervisor_stack .global __abort_stack .global __fiq_stack .global __undef_stack .global _vector_table .set PSS_L2CC_BASE_ADDR, 0xF8F02000 .set PSS_SLCR_BASE_ADDR, 0xF8000000 .set RESERVED, 0x0fffff00 .set TblBase , MMUTable .set LRemap, 0xFE00000F /* set the base address of the peripheral block as not shared */ .set CRValMmuCac, 0b01000000000001 /* Enable IDC, and MMU */ .set counterfreq, XPAR_CPU_CORTEXA53_0_TIMESTAMP_CLK_FREQ /* Stack Pointer locations for boot code */ .set Undef_stack, __undef_stack .set FIQ_stack, __fiq_stack .set Abort_stack, __abort_stack .set SPV_stack, __supervisor_stack .set IRQ_stack, __irq_stack .set SYS_stack, __stack .set vector_base, _vector_table .set FPEXC_EN, 0x40000000 /* FPU enable bit, (1 << 30) */ .section .boot,"ax" /* this initializes the various processor modes */ _prestart: _boot: OKToRun: mrc p15, 0, r0, c0, c0, 0 /* Get the revision */ and r5, r0, #0x00f00000 and r6, r0, #0x0000000f orr r6, r6, r5, lsr #20-4 /* set VBAR to the _vector_table address in linker script */ ldr r0, =vector_base mcr p15, 0, r0, c12, c0, 0 /* Invalidate caches and TLBs */ mov r0,#0 /* r0 = 0 */ mcr p15, 0, r0, c8, c7, 0 /* invalidate TLBs */ mcr p15, 0, r0, c7, c5, 0 /* invalidate icache */ mcr p15, 0, r0, c7, c5, 6 /* Invalidate branch predictor array */ bl invalidate_dcache /* invalidate dcache */ /* Disable MMU, if enabled */ mrc p15, 0, r0, c1, c0, 0 /* read CP15 register 1 */ bic r0, r0, #0x1 /* clear bit 0 */ mcr p15, 0, r0, c1, c0, 0 /* write value back */ mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the irq stack pointer */ and r2, r1, r0 orr r2, r2, #0x12 /* IRQ mode */ msr cpsr, r2 ldr r13,=IRQ_stack /* IRQ stack pointer */ mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the supervisor stack pointer */ and r2, r1, r0 orr r2, r2, #0x13 /* supervisor mode */ msr cpsr, r2 ldr r13,=SPV_stack /* Supervisor stack pointer */ mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the Abort stack pointer */ and r2, r1, r0 orr r2, r2, #0x17 /* Abort mode */ msr cpsr, r2 ldr r13,=Abort_stack /* Abort stack pointer */ mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the FIQ stack pointer */ and r2, r1, r0 orr r2, r2, #0x11 /* FIQ mode */ msr cpsr, r2 ldr r13,=FIQ_stack /* FIQ stack pointer */ mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the Undefine stack pointer */ and r2, r1, r0 orr r2, r2, #0x1b /* Undefine mode */ msr cpsr, r2 ldr r13,=Undef_stack /* Undefine stack pointer */ mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the system stack pointer */ and r2, r1, r0 orr r2, r2, #0x1F /* SYS mode */ msr cpsr, r2 ldr r13,=SYS_stack /* SYS stack pointer */ /* program the timer counter frequency */ ldr r0,=counterfreq mcr 15,0,r0,c14,c0,0 mov r0,#0 mcr 15,0,r0,c2,c0,2 /* N = 0 to use ttbr0 */ /* Write to ACTLR */ mrc p15, 0, r0, c1, c0, 1 /* Read ACTLR */ orr r0, r0, #(1 << 0) /* Enable access to CPUECTLR */ orr r0, r0, #(1 << 1) mcr p15, 0, r0, c1, c0, 1 /* Write ACTLR */ /* Write to CPUECTLR */ mrrc p15, 1, r0, r1, c15 /* Read CPUECTLR */ orr r0, r0, #(0x01 << 6) /* Set SMPEN bit */ mcrr p15, 1, r0, r1, c15 /* Write CPUECTLR */ /* enable MMU and cache */ ldr r0,=TblBase /* Load MMU translation table base */ orr r0, r0, #0x5B /* Outer-cacheable, WB */ mcr 15, 0, r0, c2, c0, 0 /* TTB0 */ mov r0,#0x5B mcr p15,0,r0,c2,c0,1 mvn r0,#0 /* Load MMU domains -- all ones=manager */ mcr p15,0,r0,c3,c0,0 /* Enable mmu, icahce and dcache */ mrc p15,0,r0,c1,c0,0 bic r0, r0, #(0x1 << 13) orr r0, r0, #(0x1 << 12) /* enable I-cache */ orr r0, r0, #(0x1 << 2) /* enable D-Cache */ orr r0, r0, #0x1 /* enable MMU */ dsb /* dsb allow the MMU to start up */ mcr p15,0,r0,c1,c0,0 /* Enable cache and MMU */ isb /* isb flush prefetch buffer */ mov r0, r0 mrc p15, 0, r1, c1, c0, 2 /* read cp access control register (CACR) into r1 */ orr r1, r1, #(0xf << 20) /* enable full access for p10 & p11 */ mcr p15, 0, r1, c1, c0, 2 /* write back into CACR */ /* enable vfp */ vmrs r1, FPEXC /* read the exception register */ orr r1,r1, #FPEXC_EN /* set VFP enable bit, leave the others in orig state */ vmsr FPEXC, r1 /* write back the exception register */ mrc p15,0,r0,c1,c0,0 /* flow prediction enable */ orr r0, r0, #(0x01 << 11) /* #0x8000 */ mcr p15,0,r0,c1,c0,0 mrc p15,0,r0,c1,c0,1 /* read Auxiliary Control Register */ orr r0, r0, #(0x1 << 2) /* enable Dside prefetch */ orr r0, r0, #(0x1 << 1) /* enable L2 Prefetch hint */ mcr p15,0,r0,c1,c0,1 /* write Auxiliary Control Register */ mrs r0, cpsr /* get the current PSR */ bic r0, r0, #0x100 /* enable asynchronous abort exception */ msr cpsr_xsf, r0 b _startup /* jump to C startup code */ and r0, r0, r0 /* no op */ .Ldone: b .Ldone /* Paranoia: we should never get here */ /* ************************************************************************* * * invalidate_dcache - invalidate the entire d-cache by set/way * * Note: for Cortex-A53, there is no cp instruction for invalidating * the whole D-cache. Need to invalidate each line. * ************************************************************************* */ invalidate_dcache: mrc p15, 1, r0, c0, c0, 1 /* read CLIDR */ ands r3, r0, #0x7000000 mov r3, r3, lsr #23 /* cache level value (naturally aligned) */ beq finished mov r10, #0 /* start with level 0 */ loop1: add r2, r10, r10, lsr #1 /* work out 3xcachelevel */ mov r1, r0, lsr r2 /* bottom 3 bits are the Cache type for this level */ and r1, r1, #7 /* get those 3 bits alone */ cmp r1, #2 blt skip /* no cache or only instruction cache at this level */ mcr p15, 2, r10, c0, c0, 0 /* write the Cache Size selection register */ isb /* isb to sync the change to the CacheSizeID reg */ mrc p15, 1, r1, c0, c0, 0 /* reads current Cache Size ID register */ and r2, r1, #7 /* extract the line length field */ add r2, r2, #4 /* add 4 for the line length offset (log2 16 bytes) */ ldr r4, =0x3ff ands r4, r4, r1, lsr #3 /* r4 is the max number on the way size (right aligned) */ clz r5, r4 /* r5 is the bit position of the way size increment */ ldr r7, =0x7fff ands r7, r7, r1, lsr #13 /* r7 is the max number of the index size (right aligned) */ loop2: mov r9, r4 /* r9 working copy of the max way size (right aligned) */ loop3: orr r11, r10, r9, lsl r5 /* factor in the way number and cache number into r11 */ orr r11, r11, r7, lsl r2 /* factor in the index number */ mcr p15, 0, r11, c7, c6, 2 /* invalidate by set/way */ subs r9, r9, #1 /* decrement the way number */ bge loop3 subs r7, r7, #1 /* decrement the index */ bge loop2 skip: add r10, r10, #2 /* increment the cache number */ cmp r3, r10 bgt loop1 finished: mov r10, #0 /* switch back to cache level 0 */ mcr p15, 2, r10, c0, c0, 0 /* select current cache level in cssr */ dsb isb bx lr .end /** * @} End of "addtogroup a53_32_boot_code". */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,374

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/32bit/gcc/cpu_init.S

/****************************************************************************** * Copyright (c) 2015 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file cpu_init.S * * This file contains CPU specific initialization. Invoked from main CRT * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 5.2 pkp 28/05/15 First release * </pre> * * @note * * None. * ******************************************************************************/ .text .global __cpu_init .align 2 __cpu_init: /* Clear cp15 regs with unknown reset values */ mov r0, #0x0 mcr p15, 0, r0, c5, c0, 0 /* DFSR */ mcr p15, 0, r0, c5, c0, 1 /* IFSR */ mcr p15, 0, r0, c6, c0, 0 /* DFAR */ mcr p15, 0, r0, c6, c0, 2 /* IFAR */ mcr p15, 0, r0, c9, c13, 2 /* PMXEVCNTR */ mcr p15, 0, r0, c13, c0, 2 /* TPIDRURW */ mcr p15, 0, r0, c13, c0, 3 /* TPIDRURO */ /* Reset and start Cycle Counter */ mov r2, #0x80000000 /* clear overflow */ mcr p15, 0, r2, c9, c12, 3 mov r2, #0xd /* D, C, E */ mcr p15, 0, r2, c9, c12, 0 mov r2, #0x80000000 /* enable cycle counter */ mcr p15, 0, r2, c9, c12, 1 bx lr .end

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

5,658

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/ARMv8/32bit/platform/ZynqMP/translation_table.S

/****************************************************************************** * Copyright (c) 2015 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file translation_table.s * * @addtogroup a53_32_boot_code * @{ * <h2> translation_table.S </h2> * The translation_table.S contains a static page table required by MMU for * cortex-A53. This translation table is flat mapped (input address = output * address) with default memory attributes defined for zynq ultrascale+ * architecture. It utilizes short descriptor translation table format with each * section defining 1MB of memory. * * For DDR in region 0x00000000 - 0x7FFFFFFF, a system where DDR is less than * 2GB, region after DDR and before PL is marked as undefined/reserved in * translation table. In region 0xFFC00000 - 0xFFDFFFFF, it contains CSU * and PMU memory which are marked as Device since it is less than 1MB and * falls in a region with device memory. * * The overview of translation table memory attributes is described below. * *| | Memory Range | Definition in Translation Table | *|-----------------|-------------------------|---------------------------------| *| DDR | 0x00000000 - 0x7FFFFFFF | Normal write-back Cacheable | *| PL | 0x80000000 - 0xBFFFFFFF | Strongly Ordered | *| QSPI, lower PCIe| 0xC0000000 - 0xEFFFFFFF | Device Memory | *| Reserved | 0xF0000000 - 0xF7FFFFFF | Unassigned | *| STM Coresight | 0xF8000000 - 0xF8FFFFFF | Device Memory | *| GIC | 0xF9000000 - 0xF90FFFFF | Device memory | *| Reserved | 0xF9100000 - 0xFCFFFFFF | Unassigned | *| FPS, LPS slaves | 0xFD000000 - 0xFFBFFFFF | Device memory | *| CSU, PMU | 0xFFC00000 - 0xFFDFFFFF | Device Memory | *| TCM, OCM | 0xFFE00000 - 0xFFFFFFFF | Normal write-back cacheable | * * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 5.2 pkp 28/05/15 First release * 5.4 pkp 18/12/15 Updated the address map according to proper address map * 6.0 mus 20/07/16 Added warning for ddrless HW design CR-954977 * </pre> * * ******************************************************************************/ #include "xparameters.h" .globl MMUTable .section .mmu_tbl,"a" MMUTable: /* Each table entry occupies one 32-bit word and there are * 4096 entries, so the entire table takes up 16KB. * Each entry covers a 1MB section. */ .set SECT, 0 #ifdef XPAR_PSU_DDR_0_S_AXI_BASEADDR .set DDR_START, XPAR_PSU_DDR_0_S_AXI_BASEADDR .set DDR_END, XPAR_PSU_DDR_0_S_AXI_HIGHADDR .set DDR_SIZE, (DDR_END - DDR_START)+1 .if DDR_SIZE > 0x80000000 /* If DDR size is larger than 2GB, truncate to 2GB */ .set DDR_REG, 0x800 .else .set DDR_REG, DDR_SIZE/0x100000 .endif #else .set DDR_REG, 0 #warning "There's no DDR in the HW design. MMU translation table marks 2 GB DDR address space as undefined" #endif .set UNDEF_REG, 0x800 - DDR_REG .rept DDR_REG /* DDR Cacheable */ .word SECT + 0x15de6 /* S=b1 TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 */ .set SECT, SECT+0x100000 .endr .rept UNDEF_REG /* unassigned/reserved */ /* Generates a translation fault if accessed */ .word SECT + 0x0 /* S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 */ .set SECT, SECT+0x100000 .endr .rept 0x0200 /* 0x80000000 - 0x9fffffff (FPGA slave0) */ .word SECT + 0xc02 /* S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 */ .set SECT, SECT+0x100000 .endr .rept 0x0200 /* 0xA0000000 - 0xbfffffff (FPGA slave1) */ .word SECT + 0xc02 /* S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 */ .set SECT, SECT+0x100000 .endr .rept 0x0200 /* 0xc0000000 - 0xdfffffff (OSPI IOU)*/ .word SECT + 0xc06 /* S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 */ .set SECT, SECT+0x100000 .endr .rept 0x0100 /* 0xe0000000 - 0xefffffff (Lower PCIe)*/ .word SECT + 0xc06 /* S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 */ .set SECT, SECT+0x100000 .endr .rept 0x80 /* 0xf0000000 - 0xf7ffffff (unassigned/reserved). * Generates a translation fault if accessed */ .word SECT + 0x0 /* S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 */ .set SECT, SECT+0x100000 .endr .rept 0x10 /* 0xf8000000 - 0xf8ffffff (STM Coresight) */ .word SECT + 0xc06 /* S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 */ .set SECT, SECT+0x100000 .endr .rept 0x1 /* 0xf9000000 - 0xf90fffff (RPU_A53_GIC) */ .word SECT + 0xc06 /* S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 */ .set SECT, SECT+0x100000 .endr .rept 0x3f /* 0xf9100000 - 0xfcffffff (reserved).*/ .word SECT + 0x0 /* S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 */ .set SECT, SECT+0x100000 .endr .rept 0x10 /* 0xfd000000 - 0xfdffffff (FPS Slaves) */ .word SECT + 0xc06 /* S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 */ .set SECT, SECT+0x100000 .endr .rept 0x1C /* 0xfe0000000 - 0xfeffffff (LPS Slaves) */ .word SECT + 0xc06 /* S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 */ .set SECT, SECT+0x100000 .endr .rept 0x2 /* 0xffc000000 - 0xffdfffff (CSU and PMU) */ .word SECT + 0xc06 /* S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 */ .set SECT, SECT+0x100000 .endr .rept 0x02 /* 0xffe00000 - 0xffffffff (TCM and OCM Cacheable) */ .word SECT + 0x15de6 /* S=b1 TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 */ .set SECT, SECT+0x100000 .endr .end /** * @} End of "addtogroup a53_32_boot_code". */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

4,764

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/iccarm/translation_table.s

;****************************************************************************** ; Copyright (c) 2009 - 2020 Xilinx, Inc. All rights reserved. ; SPDX-License-Identifier: MIT ;***************************************************************************** ;**************************************************************************** ;** ; @file translation_table.s ; ; This file contains the initialization for the MMU table in RAM ; needed by the Cortex A9 processor ; ; <pre> ; MODIFICATION HISTORY: ; ; Ver Who Date Changes ; ----- ---- -------- --------------------------------------------------- ; 1.00a ecm 10/20/09 Initial version ; 3.07a sgd 07/05/12 Configuring device address spaces as shareable device ; instead of strongly-ordered. ; 4.2 pkp 09/02/14 modified translation table entries according to address map ; 4.2 pkp 09/11/14 modified translation table entries to resolve compilation ; error for solving CR#822897 ; 6.1 pkp 07/11/16 Corrected comments for memory attributes ; 6.8 mus 07/12/2018 Mark DDR memory as inner cacheable, if BSP is built ; with the USE_AMP flag. ; </pre> ; ; @note ; ; None. ; ;**************************************************************************** EXPORT MMUTable ;ARMCC AREA |.mmu_tbl|,CODE,ALIGN=14 ; RSEG mmu_tbl:CODE:ROOT (14) SECTION .mmu_tbl:CODE:ROOT(14) MMUTable ; Each table entry occupies one 32-bit word and there are ; 4096 entries, so the entire table takes up 16KB. ; Each entry covers a 1MB section. ; 0x00000000 - 0x3ffffff (DDR Cacheable) count SETA 0 sect SETA 0 REPT 0x400 #ifndef USE_AMP DCD sect + 0x15de6 ; S=1, TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 #else DCD sect + 0x14de6 ; S=1, TEX=b100 AP=b11, Domain=b1111, C=b0, B=b1 #endif sect SETA sect+0x100000 count SETA count+1 ENDR ; 0x40000000 - 0x7fffffff (GpAxi0) count SETA 0 REPT 0x400 DCD sect + 0xc02 ; S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0x80000000 - 0xbfffffff (GpAxi1) count SETA 0 REPT 0x400 DCD sect + 0xc02 ; S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xc0000000 - 0xdfffffff (undef) count SETA 0 REPT 0x200 DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xe0000000 - 0xe02fffff (IOP dev) count SETA 0 REPT 0x3 DCD sect + 0xc06 ; S=0, TEX=b010 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xe0300000 - 0xe0ffffff (undef/reserved) count SETA 0 REPT 0xD DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xe1000000 - 0xe1ffffff (NAND) count SETA 0 REPT 0x10 DCD sect + 0xc06 ; S=0, TEX=b010 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xe2000000 - 0xe3ffffff (NOR) count SETA 0 REPT 0x20 DCD sect + 0xc06 ; S=0, TEX=b010 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xe4000000 - 0xe5ffffff (SRAM) count SETA 0 REPT 0x20 DCD sect + 0xc0e ; S=b0 TEX=b000 AP=b11, Domain=b0, C=b1, B=b1 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xe6000000 - 0xf7ffffff (reserved) count SETA 0 REPT 0x0120 DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xf8000c00 to 0xf8000fff, 0xf8010000 to 0xf88fffff and ; 0xf8f03000 to 0xf8ffffff are reserved but due to granual size of ; 1MB, it is not possible to define separate regions for them ; 0xf8000000 - 0xf8ffffff (APB device regs) count SETA 0 REPT 0x10 DCD sect + 0xc06 ; S=0, TEX=b010 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xf9000000 - 0xfbffffff (reserved) count SETA 0 REPT 0x30 DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xfc000000 - 0xfdffffff (QSPI) count SETA 0 REPT 0x20 DCD sect + 0xc0a ; S=b0 TEX=b000 AP=b11, Domain=b0, C=b1, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xfe000000 - 0xffefffff (reserved) count SETA 0 REPT 0x1F DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 ENDR ; 0xfff00000 to 0xfffb0000 is reserved but due to granual size of ; 1MB, it is not possible to define separate region for it ; 0xfff00000 to 0xfffb0000 (OCM) count SETA 0 DCD sect + 0x4c0e ; S=b0 TEX=b100 AP=b11, Domain=b0, C=b1, B=b1 sect SETA sect+0x100000 END

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

14,970

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/iccarm/boot.s

;****************************************************************************** ; Copyright (c) 2009 - 2022 Xilinx, Inc. All rights reserved. ; SPDX-License-Identifier: MIT ;***************************************************************************** ;**************************************************************************** ;** ; @file boot.s ; ; This file contains the initial vector table for the Cortex A9 processor ; ; <pre> ; MODIFICATION HISTORY: ; ; Ver Who Date Changes ; ----- ------- -------- --------------------------------------------------- ; 1.00a Initial version ; 4.2 pkp 08/04/14 Removed PEEP board related code which contained ; initialization of uart smc nor and sram ; 5.0 pkp 16/12/14 Modified initialization code to enable scu after ; MMU is enabled and removed incorrect initialization ; of TLB lockdown register to fix CR#830580 ; 5.1 pkp 05/13/15 Changed the initialization order so to first invalidate ; caches and TLB, enable MMU and caches, then enable SMP ; bit in ACTLR. L2Cache invalidation and enabling of L2Cache ; is done later. ; 6.0 mus 08/04/16 Added code to detect zynq-7000 base silicon configuration and ; attempt to enable dual core behavior on single cpu zynq-7000s devices ; is prevented from corrupting system behavior. ; 6.6 srm 10/25/17 Added timer configuration using XTime_StartTTCTimer API. ; Now the TTC instance as specified by the user will be ; started. ; 7.7 asa 01/06/22 Removed Cortex-A9 errata handling for errata ; 742230 and 743622. These do not apply to ; Cortex-A9 revision r3p0 being used in Zynq ; platforms. ; </pre> ; ; @note ; ; None. ; ;**************************************************************************** MODULE ?boot ;; Forward declaration of sections. SECTION IRQ_STACK:DATA:NOROOT(3) SECTION FIQ_STACK:DATA:NOROOT(3) SECTION SVC_STACK:DATA:NOROOT(3) SECTION ABT_STACK:DATA:NOROOT(3) SECTION UND_STACK:DATA:NOROOT(3) SECTION CSTACK:DATA:NOROOT(3) #include "xparameters.h" ;#include "xtime_l.h" #define UART_BAUDRATE 115200 PUBLIC _prestart PUBLIC __iar_program_start IMPORT _vector_table IMPORT MMUTable IMPORT __cmain IMPORT Xil_ExceptionInit IMPORT XTime_SetTime #if defined SLEEP_TIMER_BASEADDR IMPORT XTime_StartTTCTimer #endif PSS_L2CC_BASE_ADDR EQU 0xF8F02000 PSS_SLCR_BASE_ADDR EQU 0xF8000000 RESERVED EQU 0x0fffff00 TblBase EQU MMUTable LRemap EQU 0xFE00000F ; set the base address of the peripheral block as not shared L2CCWay EQU (PSS_L2CC_BASE_ADDR + 0x077C) ;(PSS_L2CC_BASE_ADDR + PSS_L2CC_CACHE_INVLD_WAY_OFFSET) L2CCSync EQU (PSS_L2CC_BASE_ADDR + 0x0730) ;(PSS_L2CC_BASE_ADDR + PSS_L2CC_CACHE_SYNC_OFFSET) L2CCCrtl EQU (PSS_L2CC_BASE_ADDR + 0x0100) ;(PSS_L2CC_BASE_ADDR + PSS_L2CC_CNTRL_OFFSET) L2CCAuxCrtl EQU (PSS_L2CC_BASE_ADDR + 0x0104) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_AUX_CNTRL_OFFSET) L2CCTAGLatReg EQU (PSS_L2CC_BASE_ADDR + 0x0108) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_TAG_RAM_CNTRL_OFFSET) L2CCDataLatReg EQU (PSS_L2CC_BASE_ADDR + 0x010C) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_DATA_RAM_CNTRL_OFFSET) L2CCIntClear EQU (PSS_L2CC_BASE_ADDR + 0x0220) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_IAR_OFFSET) L2CCIntRaw EQU (PSS_L2CC_BASE_ADDR + 0x021C) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_ISR_OFFSET) SLCRlockReg EQU (PSS_SLCR_BASE_ADDR + 0x04) ;(PSS_SLCR_BASE_ADDR + XPSS_SLCR_LOCK_OFFSET) SLCRUnlockReg EQU (PSS_SLCR_BASE_ADDR + 0x08) ;(PSS_SLCR_BASE_ADDR + XPSS_SLCR_UNLOCK_OFFSET) SLCRL2cRamReg EQU (PSS_SLCR_BASE_ADDR + 0xA1C) ;(PSS_SLCR_BASE_ADDR + XPSS_SLCR_L2C_RAM_OFFSET) SLCRCPURSTReg EQU (0xF8000000 + 0x244) ;(XPS_SYS_CTRL_BASEADDR + A9_CPU_RST_CTRL_OFFSET) EFUSEStaus EQU (0xF800D000 + 0x10) ;(XPS_EFUSE_BASEADDR + EFUSE_STATUS_OFFSET) /* workaround for simulation not working when L1 D and I caches,MMU and L2 cache enabled - DT568997 */ #if SIM_MODE == 1 CRValMmuCac EQU 00000000000000b ; Disable IDC, and MMU #else CRValMmuCac EQU 01000000000101b ; Enable IDC, and MMU #endif CRValHiVectorAddr EQU 10000000000000b ; Set the Vector address to high, 0xFFFF0000 L2CCAuxControl EQU 0x72360000 ; Enable all prefetching, Way Size (16 KB) and High Priority for SO and Dev Reads Enable L2CCControl EQU 0x01 ; Enable L2CC L2CCTAGLatency EQU 0x0111 ; 7 Cycles of latency for TAG RAM L2CCDataLatency EQU 0x0121 ; 7 Cycles of latency for DATA RAM SLCRlockKey EQU 0x767B ; SLCR lock key SLCRUnlockKey EQU 0xDF0D ; SLCR unlock key SLCRL2cRamConfig EQU 0x00020202 ; SLCR L2C ram configuration vector_base EQU _vector_table FPEXC_EN EQU 0x40000000 ; FPU enable bit, (1 << 30) SECTION .intvec:CODE:NOROOT(2) ; this initializes the various processor modes _prestart __iar_program_start #if XPAR_CPU_ID==0 ; only allow cp0 through mrc p15,0,r1,c0,c0,5 and r1, r1, #0xf cmp r1, #0 beq OKToRun EndlessLoop0 wfe b EndlessLoop0 #elif XPAR_CPU_ID==1 ; only allow cp1 through mrc p15,0,r1,c0,c0,5 and r1, r1, #0xf cmp r1, #1 beq OKToRun EndlessLoop1 wfe b EndlessLoop1 #endif OKToRun ldr r0,=EFUSEStaus ldr r1,[r0] ; Read eFuse to detect zynq silicon configuration ands r1,r1,#0x80 ; Check whether cpu1 is disabled through eFuse beq DualCPU ; cpu1 is disabled through eFuse,reset cpu1 ldr r0,=SLCRUnlockReg ; Load SLCR base address base + unlock register ldr r1,=SLCRUnlockKey ; set unlock key str r1, [r0] ; Unlock SLCR ldr r0,=SLCRCPURSTReg ldr r1,[r0] ; Read CPU Software Reset Control register orr r1,r1,#0x22 str r1,[r0] ; Reset CPU1 ldr r0,=SLCRlockReg ; Load SLCR base address base + lock register ldr r1,=SLCRlockKey ; set lock key str r1, [r0] ; lock SLCR DualCPU mrc p15, 0, r0, c0, c0, 0 ; Get the revision and r5, r0, #0x00f00000 and r6, r0, #0x0000000f orr r6, r6, r5, lsr #20-4 ; set VBAR to the _vector_table address in linker script ldr r0, =vector_base mcr p15, 0, r0, c12, c0, 0 ;invalidate scu ldr r7, =0xf8f0000c ldr r6, =0xffff str r6, [r7] ;Invalidate caches and TLBs mov r0,#0 ; r0 = 0 mcr p15, 0, r0, c8, c7, 0 ; invalidate TLBs mcr p15, 0, r0, c7, c5, 0 ; invalidate icache mcr p15, 0, r0, c7, c5, 6 ; Invalidate branch predictor array bl invalidate_dcache ; invalidate dcache ; Disable MMU, if enabled mrc p15, 0, r0, c1, c0, 0 ; read CP15 register 1 bic r0, r0, #0x1 ; clear bit 0 mcr p15, 0, r0, c1, c0, 0 ; write value back #ifdef SHAREABLE_DDR ; Mark the entire DDR memory as shareable ldr r3, =0x3ff ; 1024 entries to cover 1G DDR ldr r0, =TblBase ; MMU Table address in memory ldr r2, =0x15de6 ; S=1, TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 shareable_loop str r2, [r0] ; write the entry to MMU table add r0, r0, #0x4 ; next entry in the table add r2, r2, #0x100000 ; next section subs r3, r3, #1 bge shareable_loop ; loop till 1G is covered #endif mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the irq stack pointer and r2, r1, r0 orr r2, r2, #0x12 ; IRQ mode msr cpsr, r2 ; was cpsr, apsr is considered synonym ldr r13,=SFE(IRQ_STACK) ; IRQ stack pointer mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the supervisor stack pointer and r2, r1, r0 orr r2, r2, #0x13 ; supervisor mode msr cpsr, r2 ; was cpsr, apsr is considered synonym ldr r13,=SFE(SVC_STACK) ; Supervisor stack pointer mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the Abort stack pointer and r2, r1, r0 orr r2, r2, #0x17 ; Abort mode msr cpsr, r2 ; was cpsr, apsr is considered synonym ldr r13,=SFE(ABT_STACK) ; Abort stack pointer mrs r0, cpsr ; was cpsr, get the current PSR mvn r1, #0x1f ; set up the FIQ stack pointer and r2, r1, r0 orr r2, r2, #0x11 ; FIQ mode msr cpsr, r2 ; was cpsr ldr r13,=SFE(FIQ_STACK) ; FIQ stack pointer mrs r0, cpsr ; was cpsr, get the current PSR mvn r1, #0x1f ; set up the Undefine stack pointer and r2, r1, r0 orr r2, r2, #0x1b ; Undefine mode msr cpsr, r2 ; was cpsr ldr r13,=SFE(UND_STACK) ; Undefine stack pointer mrs r0, cpsr ; was cpsr, get the current PSR mvn r1, #0x1f ; set up the system stack pointer and r2, r1, r0 orr r2, r2, #0x1f ; SYS mode msr cpsr, r2 ; was cpsr, apsr is considered synonym ldr r13,=SFE(CSTACK) ; SYS stack pointer ;set scu enable bit in scu ldr r7, =0xf8f00000 ldr r0, [r7] orr r0, r0, #0x1 str r0, [r7] ; enable MMU and cache ldr r0,=TblBase ; Load MMU translation table base orr r0, r0, #0x5B ; Outer-cacheable, WB mcr p15, 0, r0, c2, c0, 0 ; TTB0 mvn r0,#0 ; Load MMU domains -- all ones=manager mcr p15,0,r0,c3,c0,0 ; Enable mmu, icahce and dcache ldr r0,=CRValMmuCac mcr p15,0,r0,c1,c0,0 ; Enable cache and MMU dsb ; dsb allow the MMU to start up isb ; isb flush prefetch buffer ; Write to ACTLR mrc p15, 0,r0, c1, c0, 1 ; Read ACTLR orr r0, r0, #(0x01 << 6) ; SMP bit orr r0, r0, #(0x01 ) ; Cache/TLB maintenance broadcast mcr p15, 0,r0, c1, c0, 1 ; Write ACTLR ; Invalidate L2 Cache and initialize L2 Cache ; For AMP, assume running on CPU1. Don't initialize L2 Cache (up to Linux) #if USE_AMP!=1 ldr r0,=L2CCCrtl ; Load L2CC base address base + control register mov r1, #0 ; force the disable bit str r1, [r0] ; disable the L2 Caches ldr r0,=L2CCAuxCrtl ; Load L2CC base address base + Aux control register ldr r1,[r0] ; read the register ldr r2,=L2CCAuxControl ; set the default bits orr r1,r1,r2 str r1, [r0] ; store the Aux Control Register ldr r0,=L2CCTAGLatReg ; Load L2CC base address base + TAG Latency address ldr r1,=L2CCTAGLatency ; set the latencies for the TAG str r1, [r0] ; store the TAG Latency register Register ldr r0,=L2CCDataLatReg ; Load L2CC base address base + Data Latency address ldr r1,=L2CCDataLatency ; set the latencies for the Data str r1, [r0] ; store the Data Latency register Register ldr r0,=L2CCWay ; Load L2CC base address base + way register ldr r2, =0xFFFF str r2, [r0] ; force invalidate ldr r0,=L2CCSync ; need to poll 0x730, PSS_L2CC_CACHE_SYNC_OFFSET ; Load L2CC base address base + sync register ; poll for completion Sync ldr r1, [r0] cmp r1, #0 bne Sync ldr r0,=L2CCIntRaw ; clear pending interrupts ldr r1,[r0] ldr r0,=L2CCIntClear str r1,[r0] ldr r0,=SLCRUnlockReg ; Load SLCR base address base + unlock register ldr r1,=SLCRUnlockKey ; set unlock key str r1, [r0] ; Unlock SLCR ldr r0,=SLCRL2cRamReg ; Load SLCR base address base + l2c Ram Control register str r1, [r0] ; store the L2c Ram Control Register ldr r0,=SLCRlockReg ; Load SLCR base address base + lock register ldr r1,=SLCRlockKey ; set lock key str r1, [r0] ; lock SLCR ldr r0,=L2CCCrtl ; Load L2CC base address base + control register ldr r1,[r0] ; read the register mov r2, #L2CCControl ; set the enable bit orr r1,r1,r2 str r1, [r0] ; enable the L2 Caches #endif mov r0, r0 mrc p15, 0, r1, c1, c0, 2 ; read cp access control register (CACR) into r1 orr r1, r1, #(0xf << 20) ; enable full access for p10 & p11 mcr p15, 0, r1, c1, c0, 2 ; write back into CACR ; enable vfp fmrx r1, FPEXC ; read the exception register orr r1,r1, #FPEXC_EN ; set VFP enable bit, leave the others in orig state fmxr FPEXC, r1 ; write back the exception register mrc p15, 0, r0, c1, c0, 0 ; flow prediction enable orr r0, r0, #(0x01 << 11) ; #0x8000 mcr p15,0,r0,c1,c0,0 mrc p15, 0, r0, c1, c0, 1 ; read Auxiliary Control Register orr r0, r0, #(0x1 << 2) ; enable Dside prefetch orr r0, r0, #(0x1 << 1) ; enable L2 prefetch mcr p15, 0, r0, c1, c0, 1 ; write Auxiliary Control Register ; Initialize the vector table ;bl Xil_ExceptionInit ; Clear cp15 regs with unknown reset values mov r0, #0x0 mcr p15, 0, r0, c5, c0, 0 ; DFSR mcr p15, 0, r0, c5, c0, 1 ; IFSR mcr p15, 0, r0, c6, c0, 0 ; DFAR mcr p15, 0, r0, c6, c0, 2 ; IFAR mcr p15, 0, r0, c9, c13, 2 ; PMXEVCNTR mcr p15, 0, r0, c13, c0, 2 ; TPIDRURW mcr p15, 0, r0, c13, c0, 3 ; TPIDRURO ; Reset and start Cycle Counter mov r2, #0x80000000 ; clear overflow mcr p15, 0, r2, c9, c12, 3 mov r2, #0xd ; D, C, E mcr p15, 0, r2, c9, c12, 0 mov r2, #0x80000000 ; enable cycle counter mcr p15, 0, r2, c9, c12, 1 ; Reset and start Global Timer mov r0, #0x0 mov r1, #0x0 bl XTime_SetTime ; Reset and start Triple Timer counter #if defined SLEEP_TIMER_BASEADDR bl XTime_StartTTCTimer #endif ; make sure argc and argv are valid mov r0, #0 mov r1, #0 b __cmain ; jump to C startup code and r0, r0, r0 ; no op Ldone b Ldone ; Paranoia: we should never get here ; ************************************************************************* ; * ; * invalidate_dcache - invalidate the entire d-cache by set/way ; * ; * Note: for Cortex-A9, there is no cp instruction for invalidating ; * the whole D-cache. Need to invalidate each line. ; * ; ************************************************************************* invalidate_dcache mrc p15, 1, r0, c0, c0, 1 ; read CLIDR ands r3, r0, #0x7000000 mov r3, r3, lsr #23 ; cache level value (naturally aligned) beq finished mov r10, #0 ; start with level 0 loop1 add r2, r10, r10, lsr #1 ; work out 3xcachelevel mov r1, r0, lsr r2 ; bottom 3 bits are the Cache type for this level and r1, r1, #7 ; get those 3 bits alone cmp r1, #2 blt skip ; no cache or only instruction cache at this level mcr p15, 2, r10, c0, c0, 0 ; write the Cache Size selection register isb ; isb to sync the change to the CacheSizeID reg mrc p15, 1, r1, c0, c0, 0 ; reads current Cache Size ID register and r2, r1, #7 ; extract the line length field add r2, r2, #4 ; add 4 for the line length offset (log2 16 bytes) ldr r4, =0x3ff ands r4, r4, r1, lsr #3 ; r4 is the max number on the way size (right aligned) clz r5, r4 ; r5 is the bit position of the way size increment ldr r7, =0x7fff ands r7, r7, r1, lsr #13 ; r7 is the max number of the index size (right aligned) loop2 mov r9, r4 ; r9 working copy of the max way size (right aligned) loop3 orr r11, r10, r9, lsl r5 ; factor in the way number and cache number into r11 orr r11, r11, r7, lsl r2 ; factor in the index number mcr p15, 0, r11, c7, c6, 2 ; invalidate by set/way subs r9, r9, #1 ; decrement the way number bge loop3 subs r7, r7, #1 ; decrement the index bge loop2 skip add r10, r10, #2 ; increment the cache number cmp r3, r10 bgt loop1 finished mov r10, #0 ; switch back to cache level 0 mcr p15, 2, r10, c0, c0, 0 ; select current cache level in cssr dsb isb bx lr END

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

3,765

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/iccarm/asm_vectors.s

;****************************************************************************** ; Copyright (c) 2009 - 2020 Xilinx, Inc. All rights reserved. ; SPDX-License-Identifier: MIT ;***************************************************************************** ;**************************************************************************** ;** ; @file asm_vectors.s ; ; This file contains the initial vector table for the Cortex A9 processor ; ; <pre> ; MODIFICATION HISTORY: ; ; Ver Who Date Changes ; ----- ------- -------- --------------------------------------------------- ; 1.00a Initial version ; 4.2 pkp 06/27/14 Modified return addresses for interrupt ; handlers ; 5.1 pkp 05/13/15 Saved the addresses of instruction causing data ; abort and prefetch abort into DataAbortAddr and ; PrefetchAbortAddr for further use to fix CR#854523 ; </pre> ; ; @note ; ; None. ; ;**************************************************************************** MODULE ?asm_vectors ;; Forward declaration of sections. SECTION IRQ_STACK:DATA:NOROOT(3) SECTION FIQ_STACK:DATA:NOROOT(3) SECTION SVC_STACK:DATA:NOROOT(3) SECTION ABT_STACK:DATA:NOROOT(3) SECTION UND_STACK:DATA:NOROOT(3) SECTION CSTACK:DATA:NOROOT(3) #include "xparameters.h" ;#include "xtime_l.h" #define UART_BAUDRATE 115200 IMPORT _prestart IMPORT __iar_program_start SECTION .intvec:CODE:NOROOT(2) PUBLIC _vector_table IMPORT IRQInterrupt IMPORT FIQInterrupt IMPORT SWInterrupt IMPORT DataAbortInterrupt IMPORT PrefetchAbortInterrupt IMPORT DataAbortAddr IMPORT PrefetchAbortAddr _vector_table ARM B __iar_program_start B Undefined B SVCHandler B PrefetchAbortHandler B DataAbortHandler NOP ; Placeholder for address exception vector B IRQHandler B FIQHandler SECTION .text:CODE:NOROOT(2) REQUIRE _vector_table ARM IRQHandler ; IRQ vector handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code bl IRQInterrupt ; IRQ vector ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #4 ; adjust return FIQHandler ; FIQ vector handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code FIQLoop bl FIQInterrupt ; FIQ vector ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #4 ; adjust return Undefined ; Undefined handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code b _prestart movs pc, lr SVCHandler ; SWI handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code tst r0, #0x20 ; check the T bit ldrneh r0, [lr,#-2] ; Thumb mode bicne r0, r0, #0xff00 ; Thumb mode ldreq r0, [lr,#-4] ; ARM mode biceq r0, r0, #0xff000000 ; ARM mode bl SWInterrupt ; SWInterrupt: call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code movs pc, lr ; adjust return DataAbortHandler ; Data Abort handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldr r0, =DataAbortAddr sub r1, lr,#8 str r1, [r0] ;Address of instruction causing data abort bl DataAbortInterrupt ;DataAbortInterrupt :call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #8 ; adjust return PrefetchAbortHandler ; Prefetch Abort handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldr r0, =PrefetchAbortAddr sub r1, lr,#4 str r1, [r0] ;Address of instruction causing prefetch abort bl PrefetchAbortInterrupt ; PrefetchAbortInterrupt: call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #4 ; adjust return END

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

4,612

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/armcc/translation_table.s

;****************************************************************************** ; Copyright (c) 2009 - 2020 Xilinx, Inc. All rights reserved. ; SPDX-License-Identifier: MIT ;***************************************************************************** ;**************************************************************************** ;** ; @file translation_table.s ; ; This file contains the initialization for the MMU table in RAM ; needed by the Cortex A9 processor ; ; <pre> ; MODIFICATION HISTORY: ; ; Ver Who Date Changes ; ----- ---- -------- --------------------------------------------------- ; 1.00a ecm 10/20/09 Initial version ; 3.07a sgd 07/05/2012 Configuring device address spaces as shareable device ; instead of strongly-ordered. ; 4.2 pkp 09/02/14 modified translation table entries according to address map ; 4.2 pkp 09/11/14 modified translation table entries to resolve compilation ; error for solving CR#822897 ; 6.1 pkp 07/11/16 Corrected comments for memory attributes ; </pre> ; ; @note ; ; None. ; ;**************************************************************************** EXPORT MMUTable AREA |.mmu_tbl|,CODE,ALIGN=14 MMUTable ; Each table entry occupies one 32-bit word and there are ; 4096 entries, so the entire table takes up 16KB. ; Each entry covers a 1MB section. GBLA count GBLA sect ; 0x00000000 - 0x3ffffff (DDR Cacheable) count SETA 0 sect SETA 0 WHILE count<0x400 DCD sect + 0x15de6 ; S=1, TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 sect SETA sect+0x100000 count SETA count+1 WEND ; 0x40000000 - 0x7fffffff (GpAxi0) count SETA 0 WHILE count<0x400 DCD sect + 0xc02 ; S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0x80000000 - 0xbfffffff (GpAxi1) count SETA 0 WHILE count<0x400 DCD sect + 0xc02 ; S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xc0000000 - 0xdfffffff (undef) count SETA 0 WHILE count<0x200 DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xe0000000 - 0xe02fffff (IOP dev) count SETA 0 WHILE count<0x3 DCD sect + 0xc06 ; S=0, TEX=b010 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xe0300000 - 0xe0ffffff (undef/reserved) count SETA 0 WHILE count<0xD DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xe1000000 - 0xe1ffffff (NAND) count SETA 0 WHILE count<0x10 DCD sect + 0xc06 ; S=0, TEX=b010 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xe2000000 - 0xe3ffffff (NOR) count SETA 0 WHILE count<0x20 DCD sect + 0xc06 ; S=0, TEX=b010 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xe4000000 - 0xe5ffffff (SRAM) count SETA 0 WHILE count<0x20 DCD sect + 0xc0e ; S=b0 TEX=b000 AP=b11, Domain=b0, C=b1, B=b1 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xe6000000 - 0xf7ffffff (reserved) count SETA 0 WHILE count<0x120 DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xf8000c00 to 0xf8000fff, 0xf8010000 to 0xf88fffff and ; 0xf8f03000 to 0xf8ffffff are reserved but due to granual size of ; 1MB, it is not possible to define separate regions for them ; 0xf8000000 - 0xf8ffffff (APB device regs) count SETA 0 WHILE count<0x10 DCD sect + 0xc06 ; S=0, TEX=b010 AP=b11, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xf9000000 - 0xfbffffff (reserved) count SETA 0 WHILE count<0x30 DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xfc000000 - 0xfdffffff (QSPI) count SETA 0 WHILE count<0x20 DCD sect + 0xc0a ; S=b0 TEX=b000 AP=b11, Domain=b0, C=b1, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xfe000000 - 0xffefffff (reserved) count SETA 0 WHILE count<0x1F DCD sect ; S=0, TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 sect SETA sect+0x100000 count SETA count+1 WEND ; 0xfff00000 to 0xfffb0000 is reserved but due to granual size of ; 1MB, it is not possible to define separate region for it ; 0xfff00000 to 0xfffb0000 (OCM) count SETA 0 DCD sect + 0x4c0e ; S=b0 TEX=b100 AP=b11, Domain=b0, C=b1, B=b1 sect SETA sect+0x100000 END

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

15,378

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/armcc/boot.S

;****************************************************************************** ; Copyright (c) 2009 - 2022 Xilinx, Inc. All rights reserved. ; SPDX-License-Identifier: MIT ;***************************************************************************** ;**************************************************************************** ;** ; @file boot.S ; ; This file contains the initial startup code for the Cortex A9 processor ; ; <pre> ; MODIFICATION HISTORY: ; ; Ver Who Date Changes ; ----- ------- -------- --------------------------------------------------- ; 1.00a ecm/sdm 10/20/09 Initial version ; 3.04a sdm 01/02/12 Updated to clear cp15 regs with unknown reset values ; 3.06a sgd 05/15/12 Updated L2CC Auxiliary and Tag RAM Latency control ; register settings. ; 3.06a asa 06/17/12 Modified the TTBR settings and L2 Cache auxiliary ; register settings. ; 3.07a sgd 07/05/12 Updated with reset and start Global Timer ; 3.07a sgd 10/19/12 SMC NOR and SRAM initialization with build option ; 4.2 pkp 06/19/14 Enabled asynchronous abort exception ; 4.2 pkp 08/04/14 Removed PEEP board related code which contained ; initialization of uart smc nor and sram ; 5.0 pkp 16/12/14 Modified initialization code to enable scu after ; MMU is enabled and removed incorrect initialization ; of TLB lockdown register to fix CR#830580 ; 5.1 pkp 05/13/15 Changed the initialization order so to first invalidate ; caches and TLB, enable MMU and caches, then enable SMP ; bit in ACTLR. L2Cache invalidation and enabling of L2Cache ; is done later. ; 5.4 asa 12/06/15 Added code to initialize SPSR for all relevant modes. ; 6.0 mus 04/08/16 Added code to detect zynq-7000 base silicon configuration and ; attempt to enable dual core behavior on single cpu zynq-7000s devices ; is prevented from corrupting system behavior. ; 6.0 mus 24/08/16 Check CPU core before putting cpu1 to reset for single core ; zynq-7000s devices ; 6.6 srm 10/25/17 Added timer configuration using XTime_StartTTCTimer API. ; Now the TTC instance as specified by the user will be ; started. ; 7.7 asa 01/06/22 Removed Cortex-A9 errata handling for errata ; 742230 and 743622. These do not apply to ; Cortex-A9 revision r3p0 being used in Zynq ; platforms. ; </pre> ; ; @note ; ; None. ; ;**************************************************************************** #include "xparameters.h" #include "xil_errata.h" #define UART_BAUDRATE 115200 EXPORT _prestart EXPORT _boot IMPORT |Image$$ARM_LIB_STACK$$ZI$$Limit| IMPORT |Image$$IRQ_STACK$$ZI$$Limit| IMPORT |Image$$SPV_STACK$$ZI$$Limit| IMPORT |Image$$ABORT_STACK$$ZI$$Limit| IMPORT MMUTable IMPORT _vector_table IMPORT __main IMPORT Xil_ExceptionInit IMPORT XTime_SetTime #if defined SLEEP_TIMER_BASEADDR IMPORT XTime_StartTTCTimer #endif PSS_L2CC_BASE_ADDR EQU 0xF8F02000 PSS_SLCR_BASE_ADDR EQU 0xF8000000 L2CCWay EQU (PSS_L2CC_BASE_ADDR + 0x077C) ;(PSS_L2CC_BASE_ADDR + PSS_L2CC_CACHE_INVLD_WAY_OFFSET) L2CCSync EQU (PSS_L2CC_BASE_ADDR + 0x0730) ;(PSS_L2CC_BASE_ADDR + PSS_L2CC_CACHE_SYNC_OFFSET) L2CCCrtl EQU (PSS_L2CC_BASE_ADDR + 0x0100) ;(PSS_L2CC_BASE_ADDR + PSS_L2CC_CNTRL_OFFSET) L2CCAuxCrtl EQU (PSS_L2CC_BASE_ADDR + 0x0104) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_AUX_CNTRL_OFFSET) L2CCTAGLatReg EQU (PSS_L2CC_BASE_ADDR + 0x0108) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_TAG_RAM_CNTRL_OFFSET) L2CCDataLatReg EQU (PSS_L2CC_BASE_ADDR + 0x010C) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_DATA_RAM_CNTRL_OFFSET) L2CCIntClear EQU (PSS_L2CC_BASE_ADDR + 0x0220) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_IAR_OFFSET) L2CCIntRaw EQU (PSS_L2CC_BASE_ADDR + 0x021C) ;(PSS_L2CC_BASE_ADDR + XPSS_L2CC_ISR_OFFSET) SLCRlockReg EQU (PSS_SLCR_BASE_ADDR + 0x04) /*(PSS_SLCR_BASE_ADDR + XPSS_SLCR_LOCK_OFFSET)*/ SLCRUnlockReg EQU (PSS_SLCR_BASE_ADDR + 0x08) /*(PSS_SLCR_BASE_ADDR + XPSS_SLCR_UNLOCK_OFFSET)*/ SLCRL2cRamReg EQU (PSS_SLCR_BASE_ADDR + 0xA1C) /*(PSS_SLCR_BASE_ADDR + XPSS_SLCR_L2C_RAM_OFFSET)*/ SLCRCPURSTReg EQU (0xF8000000 + 0x244) ;(XPS_SYS_CTRL_BASEADDR + A9_CPU_RST_CTRL_OFFSET) EFUSEStaus EQU (0xF800D000 + 0x10) ;(XPS_EFUSE_BASEADDR + EFUSE_STATUS_OFFSET) SLCRlockKey EQU 0x767B /* SLCR lock key */ SLCRUnlockKey EQU 0xDF0D /* SLCR unlock key */ SLCRL2cRamConfig EQU 0x00020202 /* SLCR L2C ram configuration */ CRValMmuCac EQU 2_01000000000101 ; Enable IDC, and MMU CRValHiVectorAddr EQU 2_10000000000000 ; Set the Vector address to high, 0xFFFF0000 L2CCAuxControl EQU 0x72360000 ; Enable all prefetching, Way Size (16 KB) and High Priority for SO and Dev Reads Enable L2CCControl EQU 0x01 ; Enable L2CC L2CCTAGLatency EQU 0x0111 ; 7 Cycles of latency for TAG RAM L2CCDataLatency EQU 0x0121 ; 7 Cycles of latency for DATA RAM FPEXC_EN EQU 0x40000000 ; FPU enable bit, (1 << 30) AREA |.boot|, CODE PRESERVE8 ; this initializes the various processor modes _prestart _boot #if XPAR_CPU_ID==0 ; only allow cp0 through mrc p15,0,r1,c0,c0,5 and r1, r1, #0xf cmp r1, #0 beq CheckEFUSE EndlessLoop0 wfe b EndlessLoop0 CheckEFUSE ldr r0,=EFUSEStaus ldr r1,[r0] ; Read eFuse setting ands r1,r1,#0x80 ; Check whether device is having single core beq OKToRun ; Single core device, reset CPU1 ldr r0,=SLCRUnlockReg ; Load SLCR base address base + unlock register ldr r1,=SLCRUnlockKey ; set unlock key str r1, [r0] ; Unlock SLCR ldr r0,=SLCRCPURSTReg ldr r1,[r0] ; Read CPU Software Reset Control register orr r1,r1,#0x22 str r1,[r0] ; Reset CPU1 ldr r0,=SLCRlockReg ; Load SLCR base address base + lock register ldr r1,=SLCRlockKey ; set lock key str r1, [r0] ; lock SLCR #elif XPAR_CPU_ID==1 ; only allow cpu1 through mrc p15,0,r1,c0,c0,5 and r1, r1, #0xf cmp r1, #1 beq CheckEFUSE1 b EndlessLoop1 CheckEFUSE1 ldr r0,=EFUSEStaus ldr r1,[r0] ; Read eFuse setting ands r1,r1,#0x80 ; Check whether device is having single core beq OKToRun EndlessLoop1 wfe b EndlessLoop1 #endif OKToRun mrc p15, 0, r0, c0, c0, 0 /* Get the revision */ and r5, r0, #0x00f00000 and r6, r0, #0x0000000f orr r6, r6, r5, lsr #20-4 /* set VBAR to the _vector_table address in scatter file */ ldr r0, =_vector_table mcr p15, 0, r0, c12, c0, 0 ;invalidate scu ldr r7, =0xf8f0000c ldr r6, =0xffff str r6, [r7] ;Invalidate caches and TLBs mov r0,#0 ; r0 = 0 mcr p15, 0, r0, c8, c7, 0 ; invalidate TLBs mcr p15, 0, r0, c7, c5, 0 ; invalidate icache mcr p15, 0, r0, c7, c5, 6 ; Invalidate branch predictor array bl invalidate_dcache ; invalidate dcache ; Disable MMU, if enabled mrc p15, 0, r0, c1, c0, 0 ; read CP15 register 1 bic r0, r0, #0x1 ; clear bit 0 mcr p15, 0, r0, c1, c0, 0 ; write value back #ifdef SHAREABLE_DDR ; Mark the entire DDR memory as shareable ldr r3, =0x3ff ; 1024 entries to cover 1G DDR ldr r0, =TblBase ; MMU Table address in memory ldr r2, =0x15de6 ; S=1, TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 shareable_loop: str r2, [r0] ; write the entry to MMU table add r0, r0, #0x4 ; next entry in the table add r2, r2, #0x100000 ; next section subs r3, r3, #1 bge shareable_loop ; loop till 1G is covered #endif mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the irq stack pointer and r2, r1, r0 orr r2, r2, #0x12 ; IRQ mode msr apsr, r2 ; was cpsr, apsr is considered synonym ldr r13,=|Image$$IRQ_STACK$$ZI$$Limit| ; IRQ stack pointer bic r2, r2, #(0x1 << 9) ; Set EE bit to little-endian msr spsr_fsxc,r2 mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the supervisor stack pointer and r2, r1, r0 orr r2, r2, #0x13 ; supervisor mode msr apsr, r2 ; was cpsr, apsr is considered synonym ldr r13,=|Image$$SPV_STACK$$ZI$$Limit| ; Supervisor stack pointer bic r2, r2, #(0x1 << 9) ; Set EE bit to little-endian msr spsr_fsxc,r2 mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the Abort stack pointer and r2, r1, r0 orr r2, r2, #0x17 ; Abort mode msr apsr, r2 ; was cpsr, apsr is considered synonym ldr r13,=|Image$$ABORT_STACK$$ZI$$Limit| ; Abort stack pointer bic r2, r2, #(0x1 << 9) ; Set EE bit to little-endian msr spsr_fsxc,r2 mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the system stack pointer and r2, r1, r0 orr r2, r2, #0x1f ; SYS mode msr apsr, r2 ; was cpsr, apsr is considered synonym ldr r13,=|Image$$ARM_LIB_STACK$$ZI$$Limit| ; SYS stack pointer ;set scu enable bit in scu ldr r7, =0xf8f00000 ldr r0, [r7] orr r0, r0, #0x1 str r0, [r7] ; enable MMU and cache ldr r0,=MMUTable ; Load MMU translation table base orr r0, r0, #0x5B ; Outer-cacheable, WB mcr p15, 0, r0, c2, c0, 0 ; TTB0 mvn r0,#0 mcr p15,0,r0,c3,c0,0 ; Enable mmu, icahce and dcache ldr r0,=CRValMmuCac mcr p15,0,r0,c1,c0,0 ; Enable cache and MMU dsb ; dsb allow the MMU to start up isb ; isb flush prefetch buffer ; Write to ACTLR mrc p15, 0,r0, c1, c0, 1 ; Read ACTLR orr r0, r0, #(0x01 << 6) ; SMP bit orr r0, r0, #(0x01 ) ; Cache/TLB maintenance broadcast mcr p15, 0,r0, c1, c0, 1 ; Write ACTLR ; Invalidate L2 Cache and initialize L2 Cache ; For AMP, assume running on CPU1. Don't initialize L2 Cache (up to Linux) #if USE_AMP!=1 ldr r0,=L2CCCrtl ; Load L2CC base address base + control register mov r1, #0 ; force the disable bit str r1, [r0] ; disable the L2 Caches ldr r0,=L2CCAuxCrtl ; Load L2CC base address base + Aux control register ldr r1,[r0] ; read the register ldr r2,=L2CCAuxControl ; set the default bits orr r1,r1,r2 str r1, [r0] ; store the Aux Control Register ldr r0,=L2CCTAGLatReg ; Load L2CC base address base + TAG Latency address ldr r1,=L2CCTAGLatency ; set the latencies for the TAG str r1, [r0] ; store the TAG Latency register Register ldr r0,=L2CCDataLatReg ; Load L2CC base address base + Data Latency address ldr r1,=L2CCDataLatency ; set the latencies for the Data str r1, [r0] ; store the Data Latency register Register ldr r0,=L2CCWay ; Load L2CC base address base + way register ldr r2, =0xFFFF str r2, [r0] ; force invalidate ldr r0,=L2CCSync ; need to poll 0x730, PSS_L2CC_CACHE_SYNC_OFFSET ; Load L2CC base address base + sync register ; poll for completion Sync ldr r1, [r0] cmp r1, #0 bne Sync ldr r0,=L2CCIntRaw ; clear pending interrupts ldr r1,[r0] ldr r0,=L2CCIntClear str r1,[r0] ldr r0,=SLCRUnlockReg ;Load SLCR base address base + unlock register ldr r1,=SLCRUnlockKey ;set unlock key str r1, [r0] ;Unlock SLCR ldr r0,=SLCRL2cRamReg ;Load SLCR base address base + l2c Ram Control register ldr r1,=SLCRL2cRamConfig ;set the configuration value str r1, [r0] ;store the L2c Ram Control Register ldr r0,=SLCRlockReg ;Load SLCR base address base + lock register ldr r1,=SLCRlockKey ;set lock key str r1, [r0] ;lock SLCR ldr r0,=L2CCCrtl ; Load L2CC base address base + control register ldr r1,[r0] ; read the register mov r2, #L2CCControl ; set the enable bit orr r1,r1,r2 str r1, [r0] ; enable the L2 Caches #endif mov r0, r0 mrc p15, 0, r1, c1, c0, 2 ; read cp access control register (CACR) into r1 orr r1, r1, #(0xf << 20) ; enable full access for p10 & p11 mcr p15, 0, r1, c1, c0, 2 ; write back into CACR ; enable vfp fmrx r1, FPEXC ; read the exception register orr r1,r1, #FPEXC_EN ; set VFP enable bit, leave the others in orig state fmxr FPEXC, r1 ; write back the exception register mrc p15, 0, r0, c1, c0, 0 ; flow prediction enable orr r0, r0, #(0x01 << 11) ; #0x8000 mcr p15,0,r0,c1,c0,0 mrc p15, 0, r0, c1, c0, 1 ; read Auxiliary Control Register orr r0, r0, #(0x1 << 2) ; enable Dside prefetch orr r0, r0, #(0x1 << 1) ; enable L2 prefetch mcr p15, 0, r0, c1, c0, 1 ; write Auxiliary Control Register mrs r0, cpsr /* get the current PSR */ bic r0, r0, #0x100 /* enable asynchronous abort exception */ msr cpsr_xsf, r0 ; Clear cp15 regs with unknown reset values mov r0, #0x0 mcr p15, 0, r0, c5, c0, 0 ; DFSR mcr p15, 0, r0, c5, c0, 1 ; IFSR mcr p15, 0, r0, c6, c0, 0 ; DFAR mcr p15, 0, r0, c6, c0, 2 ; IFAR mcr p15, 0, r0, c9, c13, 2 ; PMXEVCNTR mcr p15, 0, r0, c13, c0, 2 ; TPIDRURW mcr p15, 0, r0, c13, c0, 3 ; TPIDRURO ; Reset and start Cycle Counter mov r2, #0x80000000 ; clear overflow mcr p15, 0, r2, c9, c12, 3 mov r2, #0xd ; D, C, E mcr p15, 0, r2, c9, c12, 0 mov r2, #0x80000000 ; enable cycle counter mcr p15, 0, r2, c9, c12, 1 ; Reset and start Global Timer mov r0, #0x0 mov r1, #0x0 bl XTime_SetTime ; Reset and start Triple Timer counter #if defined SLEEP_TIMER_BASEADDR bl XTime_StartTTCTimer #endif #ifdef PROFILING /* defined in Makefile */ /* Setup profiling stuff */ bl _profile_init #endif /* PROFILING */ ; make sure argc and argv are valid mov r0, #0 mov r1, #0 b __main ; jump to C startup code and r0, r0, r0 ; no op Ldone b Ldone ; Paranoia: we should never get here ; ************************************************************************* ; * ; * invalidate_dcache - invalidate the entire d-cache by set/way ; * ; * Note: for Cortex-A9, there is no cp instruction for invalidating ; * the whole D-cache. Need to invalidate each line. ; * ; ************************************************************************* invalidate_dcache mrc p15, 1, r0, c0, c0, 1 ; read CLIDR ands r3, r0, #0x7000000 mov r3, r3, lsr #23 ; cache level value (naturally aligned) beq finished mov r10, #0 ; start with level 0 loop1 add r2, r10, r10, lsr #1 ; work out 3xcachelevel mov r1, r0, lsr r2 ; bottom 3 bits are the Cache type for this level and r1, r1, #7 ; get those 3 bits alone cmp r1, #2 blt skip ; no cache or only instruction cache at this level mcr p15, 2, r10, c0, c0, 0 ; write the Cache Size selection register isb ; isb to sync the change to the CacheSizeID reg mrc p15, 1, r1, c0, c0, 0 ; reads current Cache Size ID register and r2, r1, #7 ; extract the line length field add r2, r2, #4 ; add 4 for the line length offset (log2 16 bytes) ldr r4, =0x3ff ands r4, r4, r1, lsr #3 ; r4 is the max number on the way size (right aligned) clz r5, r4 ; r5 is the bit position of the way size increment ldr r7, =0x7fff ands r7, r7, r1, lsr #13 ; r7 is the max number of the index size (right aligned) loop2 mov r9, r4 ; r9 working copy of the max way size (right aligned) loop3 orr r11, r10, r9, lsl r5 ; factor in the way number and cache number into r11 orr r11, r11, r7, lsl r2 ; factor in the index number mcr p15, 0, r11, c7, c6, 2 ; invalidate by set/way subs r9, r9, #1 ; decrement the way number bge loop3 subs r7, r7, #1 ; decrement the index bge loop2 skip add r10, r10, #2 ; increment the cache number cmp r3, r10 bgt loop1 finished mov r10, #0 ; switch back to cache level 0 mcr p15, 2, r10, c0, c0, 0 ; select current cache level in cssr isb bx lr END

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

4,043

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/armcc/asm_vectors.s

;****************************************************************************** ; Copyright (c) 2009 - 2020 Xilinx, Inc. All rights reserved. ; SPDX-License-Identifier: MIT ;***************************************************************************** ;**************************************************************************** ;** ; @file asm_vectors.s ; ; This file contains the initial vector table for the Cortex A9 processor ; ; <pre> ; MODIFICATION HISTORY: ; ; Ver Who Date Changes ; ----- ------- -------- --------------------------------------------------- ; 1.00a ecm/sdm 10/20/09 Initial version ; 3.11a asa 9/17/13 Added support for neon. ; 4.00 pkp 01/22/14 Modified return addresses for interrupt ; handlers ; 5.1 pkp 05/13/15 Saved the addresses of instruction causing data ; abort and prefetch abort into DataAbortAddr and ; PrefetchAbortAddr for further use to fix CR#854523 ; 5.4 pkp 12/03/15 Added handler for undefined exception ;</pre> ; ; @note ; ; None. ; ;**************************************************************************** EXPORT _vector_table EXPORT IRQHandler IMPORT _boot IMPORT _prestart IMPORT IRQInterrupt IMPORT FIQInterrupt IMPORT SWInterrupt IMPORT DataAbortInterrupt IMPORT PrefetchAbortInterrupt IMPORT UndefinedException IMPORT DataAbortAddr IMPORT PrefetchAbortAddr IMPORT UndefinedExceptionAddr AREA |.vectors|, CODE REQUIRE8 {TRUE} PRESERVE8 {TRUE} ENTRY ; define this as an entry point _vector_table B _boot B Undefined B SVCHandler B PrefetchAbortHandler B DataAbortHandler NOP ; Placeholder for address exception vector B IRQHandler B FIQHandler IRQHandler ; IRQ vector handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code vpush {d0-d7} vpush {d16-d31} vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} bl IRQInterrupt ; IRQ vector pop {r1} vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d16-d31} vpop {d0-d7} ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #4 ; adjust return FIQHandler ; FIQ vector handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code vpush {d0-d7} vpush {d16-d31} vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} FIQLoop bl FIQInterrupt ; FIQ vector pop {r1} vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d16-d31} vpop {d0-d7} ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #4 ; adjust return Undefined ; Undefined handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldr r0, =UndefinedExceptionAddr sub r1, lr,#4 str r1, [r0] ; Address of instruction causing undefined exception bl UndefinedException ; UndefinedException: call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code movs pc, lr SVCHandler ; SWI handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code tst r0, #0x20 ; check the T bit ldrneh r0, [lr,#-2] ; Thumb mode bicne r0, r0, #0xff00 ; Thumb mode ldreq r0, [lr,#-4] ; ARM mode biceq r0, r0, #0xff000000 ; ARM mode bl SWInterrupt ; SWInterrupt: call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code movs pc, lr ; adjust return DataAbortHandler ; Data Abort handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldr r0, =DataAbortAddr sub r1, lr,#8 str r1, [r0] ;Address of instruction causing data abort bl DataAbortInterrupt ;DataAbortInterrupt :call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #8 ; adjust return PrefetchAbortHandler ; Prefetch Abort handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldr r0, =PrefetchAbortAddr sub r1, lr,#4 str r1, [r0] ;Address of instruction causing prefetch abort bl PrefetchAbortInterrupt ; PrefetchAbortInterrupt: call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #4 ; adjust return END

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

8,023

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/gcc/translation_table.S

/****************************************************************************** * Copyright (c) 2009 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file translation_table.S * * @addtogroup a9_boot_code * @{ * <h2> translation_table.S </h2> * The translation_table.S contains a static page table required by MMU for * cortex-A9. This translation table is flat mapped (input address = output * address) with default memory attributes defined for zynq architecture. It * utilizes short descriptor translation table format with each section defining * 1 MB of memory. * * The overview of translation table memory attributes is described below. * *| | Memory Range | Definition in Translation Table | *|-----------------------|-------------------------|-----------------------------------| *| DDR | 0x00000000 - 0x3FFFFFFF | Normal write-back Cacheable | *| PL | 0x40000000 - 0xBFFFFFFF | Strongly Ordered | *| Reserved | 0xC0000000 - 0xDFFFFFFF | Unassigned | *| Memory mapped devices | 0xE0000000 - 0xE02FFFFF | Device Memory | *| Reserved | 0xE0300000 - 0xE0FFFFFF | Unassigned | *| NAND, NOR | 0xE1000000 - 0xE3FFFFFF | Device memory | *| SRAM | 0xE4000000 - 0xE5FFFFFF | Normal write-back Cacheable | *| Reserved | 0xE6000000 - 0xF7FFFFFF | Unassigned | *| AMBA APB Peripherals | 0xF8000000 - 0xF8FFFFFF | Device Memory | *| Reserved | 0xF9000000 - 0xFBFFFFFF | Unassigned | *| Linear QSPI - XIP | 0xFC000000 - 0xFDFFFFFF | Normal write-through cacheable | *| Reserved | 0xFE000000 - 0xFFEFFFFF | Unassigned | *| OCM | 0xFFF00000 - 0xFFFFFFFF | Normal inner write-back cacheable | * * For region 0x00000000 - 0x3FFFFFFF, a system where DDR is less than 1 GB, * region after DDR and before PL is marked as undefined/reserved in translation * table. In 0xF8000000 - 0xF8FFFFFF, 0xF8000C00 - 0xF8000FFF, 0xF8010000 - * 0xF88FFFFF and 0xF8F03000 to 0xF8FFFFFF are reserved but due to granual size * of 1 MB, it is not possible to define separate regions for them. For region * 0xFFF00000 - 0xFFFFFFFF, 0xFFF00000 to 0xFFFB0000 is reserved but due to 1MB * granual size, it is not possible to define separate region for it. * * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 1.00a ecm 10/20/09 Initial version * 3.04a sdm 01/13/12 Updated MMU table to mark DDR memory as Shareable * 3.07a sgd 07/05/2012 Configuring device address spaces as shareable device * instead of strongly-ordered. * 3.07a asa 07/17/2012 Changed the property of the ".mmu_tbl" section. * 4.2 pkp 09/02/2014 added entries for 0xfe000000 to 0xffefffff as reserved * and 0xe0000000 - 0xe1ffffff is broken down into * 0xe0000000 - 0xe02fffff (memory mapped divides) * 0xe0300000 - 0xe0ffffff (reserved) and * 0xe1000000 - 0xe1ffffff (NAND) * 5.2 pkp 06/08/2015 put a check for XPAR_PS7_DDR_0_S_AXI_BASEADDR to confirm * if DDR is present or not and accordingly generate the * translation table * 6.1 pkp 07/11/2016 Corrected comments for memory attributes * 6.8 mus 07/12/2018 Mark DDR memory as inner cacheable, if BSP is built * with the USE_AMP flag. * </pre> * * ******************************************************************************/ #include "xparameters.h" .globl MMUTable .section .mmu_tbl,"a" MMUTable: /* Each table entry occupies one 32-bit word and there are * 4096 entries, so the entire table takes up 16KB. * Each entry covers a 1MB section. */ .set SECT, 0 #ifdef XPAR_PS7_DDR_0_S_AXI_BASEADDR .set DDR_START, XPAR_PS7_DDR_0_S_AXI_BASEADDR .set DDR_END, XPAR_PS7_DDR_0_S_AXI_HIGHADDR .set DDR_SIZE, (DDR_END - DDR_START)+1 .set DDR_REG, DDR_SIZE/0x100000 #else .set DDR_REG, 0 #endif .set UNDEF_REG, 0x3FF - DDR_REG #ifndef USE_AMP /*0x00000000 - 0x00100000 (inner and outer cacheable )*/ .word SECT + 0x15de6 /* S=b1 TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 */ #else /*0x00000000 - 0x00100000 (inner cacheable )*/ .word SECT + 0x14de6 /* S=b1 TEX=b100 AP=b11, Domain=b1111, C=b0, B=b1 */ #endif .set SECT, SECT+0x100000 .rept DDR_REG /* (DDR Cacheable) */ .word SECT + 0x15de6 /* S=b1 TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 */ .set SECT, SECT+0x100000 .endr .rept UNDEF_REG /* (unassigned/reserved). * Generates a translation fault if accessed */ .word SECT + 0x0 /* S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 */ .set SECT, SECT+0x100000 .endr .rept 0x0400 /* 0x40000000 - 0x7fffffff (FPGA slave0) */ .word SECT + 0xc02 /* S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b0 */ .set SECT, SECT+0x100000 .endr .rept 0x0400 /* 0x80000000 - 0xbfffffff (FPGA slave1) */ .word SECT + 0xc02 /* S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b0 */ .set SECT, SECT+0x100000 .endr .rept 0x0200 /* 0xc0000000 - 0xdfffffff (unassigned/reserved). * Generates a translation fault if accessed */ .word SECT + 0x0 /* S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 */ .set SECT, SECT+0x100000 .endr .rept 0x003 /* 0xe0000000 - 0xe02fffff (Memory mapped devices) * UART/USB/IIC/SPI/CAN/GEM/GPIO/QSPI/SD/NAND */ .word SECT + 0xc06 /* S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 */ .set SECT, SECT+0x100000 .endr .rept 0x0D /* 0xe0300000 - 0xe0ffffff (unassigned/reserved). * Generates a translation fault if accessed */ .word SECT + 0x0 /* S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 */ .set SECT, SECT+0x100000 .endr .rept 0x0010 /* 0xe1000000 - 0xe1ffffff (NAND) */ .word SECT + 0xc06 /* S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 */ .set SECT, SECT+0x100000 .endr .rept 0x0020 /* 0xe2000000 - 0xe3ffffff (NOR) */ .word SECT + 0xc06 /* S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 */ .set SECT, SECT+0x100000 .endr .rept 0x0020 /* 0xe4000000 - 0xe5ffffff (SRAM) */ .word SECT + 0xc0e /* S=b0 TEX=b000 AP=b11, Domain=b0, C=b1, B=b1 */ .set SECT, SECT+0x100000 .endr .rept 0x0120 /* 0xe6000000 - 0xf7ffffff (unassigned/reserved). * Generates a translation fault if accessed */ .word SECT + 0x0 /* S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 */ .set SECT, SECT+0x100000 .endr /* 0xf8000c00 to 0xf8000fff, 0xf8010000 to 0xf88fffff and 0xf8f03000 to 0xf8ffffff are reserved but due to granual size of 1MB, it is not possible to define separate regions for them */ .rept 0x0010 /* 0xf8000000 - 0xf8ffffff (AMBA APB Peripherals) */ .word SECT + 0xc06 /* S=b0 TEX=b000 AP=b11, Domain=b0, C=b0, B=b1 */ .set SECT, SECT+0x100000 .endr .rept 0x0030 /* 0xf9000000 - 0xfbffffff (unassigned/reserved). * Generates a translation fault if accessed */ .word SECT + 0x0 /* S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 */ .set SECT, SECT+0x100000 .endr .rept 0x0020 /* 0xfc000000 - 0xfdffffff (Linear QSPI - XIP) */ .word SECT + 0xc0a /* S=b0 TEX=b000 AP=b11, Domain=b0, C=b1, B=b0 */ .set SECT, SECT+0x100000 .endr .rept 0x001F /* 0xfe000000 - 0xffefffff (unassigned/reserved). * Generates a translation fault if accessed */ .word SECT + 0x0 /* S=b0 TEX=b000 AP=b00, Domain=b0, C=b0, B=b0 */ .set SECT, SECT+0x100000 .endr /* 0xfff00000 to 0xfffb0000 is reserved but due to granual size of 1MB, it is not possible to define separate region for it 0xfff00000 - 0xffffffff 256K OCM when mapped to high address space inner-cacheable */ .word SECT + 0x4c0e /* S=b0 TEX=b100 AP=b11, Domain=b0, C=b1, B=b1 */ .set SECT, SECT+0x100000 .end /** * @} End of "addtogroup a9_boot_code". */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

3,153

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/gcc/xil-crt0.S

/****************************************************************************** * Copyright (c) 2009 - 2020 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file xil-crt0.S * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 1.00a ecm 10/20/09 Initial version * 3.05a sdm 02/02/12 Added code for profiling * 3.06a sgd 05/16/12 Added global constructors and cleanup code * Uart initialization based on compiler flag * 3.07a sgd 07/05/12 Updated with reset and start Global Timer * 3.07a sgd 10/19/12 SMC NOR and SRAM initialization with build option * 4.2 pkp 08/04/14 Removed PEEP board related code which contained * initialization of uart smc nor and sram * 5.3 pkp 10/07/15 Added support for OpenAMP by not initializing global * timer when USE_AMP flag is defined * 6.6 srm 10/18/17 Added timer configuration using XTime_StartTTCTimer API. * Now the TTC instance as specified by the user will be * started. * 7.7 adk 11/30/21 Added support for xiltimer library. * </pre> * * @note * * None. * ******************************************************************************/ #include "bspconfig.h" #include "xparameters.h" .file "xil-crt0.S" .section ".got2","aw" .align 2 .text .Lsbss_start: .long __sbss_start .Lsbss_end: .long __sbss_end .Lbss_start: .long __bss_start .Lbss_end: .long __bss_end .Lstack: .long __stack .globl _start _start: bl __cpu_init /* Initialize the CPU first (BSP provides this) */ mov r0, #0 /* clear sbss */ ldr r1,.Lsbss_start /* calculate beginning of the SBSS */ ldr r2,.Lsbss_end /* calculate end of the SBSS */ .Lloop_sbss: cmp r1,r2 bge .Lenclsbss /* If no SBSS, no clearing required */ str r0, [r1], #4 b .Lloop_sbss .Lenclsbss: /* clear bss */ ldr r1,.Lbss_start /* calculate beginning of the BSS */ ldr r2,.Lbss_end /* calculate end of the BSS */ .Lloop_bss: cmp r1,r2 bge .Lenclbss /* If no BSS, no clearing required */ str r0, [r1], #4 b .Lloop_bss .Lenclbss: /* set stack pointer */ ldr r13,.Lstack /* stack address */ /* Reset and start Global Timer */ mov r0, #0x0 mov r1, #0x0 /* Reset and start Triple Timer Counter */ #if defined SLEEP_TIMER_BASEADDR bl XTime_StartTTCTimer #endif #ifndef XPAR_XILTIMER_ENABLED #if USE_AMP != 1 bl XTime_SetTime #endif #endif #ifdef PROFILING /* defined in Makefile */ /* Setup profiling stuff */ bl _profile_init #endif /* PROFILING */ /* run global constructors */ bl __libc_init_array /* make sure argc and argv are valid */ mov r0, #0 mov r1, #0 /* Let her rip */ bl main /* Cleanup global constructors */ bl __libc_fini_array #ifdef PROFILING /* Cleanup profiling stuff */ bl _profile_clean #endif /* PROFILING */ /* All done */ bl exit .Lexit: /* should never get here */ b .Lexit .Lstart: .size _start,.Lstart-_start

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

4,892

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/gcc/asm_vectors.S

/****************************************************************************** * Copyright (c) 2009 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file asm_vectors.S * * This file contains the initial vector table for the Cortex A9 processor * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 1.00a ecm/sdm 10/20/09 Initial version * 3.05a sdm 02/02/12 Save lr when profiling is enabled * 3.10a srt 04/18/13 Implemented ARM Erratas. Please refer to file * 'xil_errata.h' for errata description * 4.00a pkp 22/01/14 Modified return addresses for interrupt * handlers (DataAbortHandler and SVCHandler) * to fix CR#767251 * 5.1 pkp 05/13/15 Saved the addresses of instruction causing data * abort and prefetch abort into DataAbortAddr and * PrefetchAbortAddr for further use to fix CR#854523 * 5.4 pkp 12/03/15 Added handler for undefined exception * 6.8 mus 04/27/18 Removed __ARM_NEON__ flag definition. Now, * saving/restoring of of HW floating point register * would be done through newly introduced flag * FPU_HARD_FLOAT_ABI_ENABLED. This new flag will be * configured based on the -mfpu-abi option in extra * compiler flags. * </pre> * * @note * * None. * ******************************************************************************/ #include "xil_errata.h" #include "bspconfig.h" .org 0 .text .globl _vector_table .section .vectors _vector_table: B _boot B Undefined B SVCHandler B PrefetchAbortHandler B DataAbortHandler NOP /* Placeholder for address exception vector*/ B IRQHandler B FIQHandler IRQHandler: /* IRQ vector handler */ stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code*/ #if FPU_HARD_FLOAT_ABI_ENABLED vpush {d0-d7} vpush {d16-d31} vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} #endif #ifdef PROFILING ldr r2, =prof_pc subs r3, lr, #0 str r3, [r2] #endif bl IRQInterrupt /* IRQ vector */ #if FPU_HARD_FLOAT_ABI_ENABLED pop {r1} vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d16-d31} vpop {d0-d7} #endif ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ subs pc, lr, #4 /* adjust return */ FIQHandler: /* FIQ vector handler */ stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code */ #if FPU_HARD_FLOAT_ABI_ENABLED vpush {d0-d7} vpush {d16-d31} vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} #endif FIQLoop: bl FIQInterrupt /* FIQ vector */ #if FPU_HARD_FLOAT_ABI_ENABLED pop {r1} vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d16-d31} vpop {d0-d7} #endif ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ subs pc, lr, #4 /* adjust return */ Undefined: /* Undefined handler */ stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code */ ldr r0, =UndefinedExceptionAddr sub r1, lr, #4 str r1, [r0] /* Store address of instruction causing undefined exception */ bl UndefinedException /* UndefinedException: call C function here */ ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ movs pc, lr SVCHandler: /* SWI handler */ stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code */ tst r0, #0x20 /* check the T bit */ ldrneh r0, [lr,#-2] /* Thumb mode */ bicne r0, r0, #0xff00 /* Thumb mode */ ldreq r0, [lr,#-4] /* ARM mode */ biceq r0, r0, #0xff000000 /* ARM mode */ bl SWInterrupt /* SWInterrupt: call C function here */ ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ movs pc, lr /*return to the next instruction after the SWI instruction */ DataAbortHandler: /* Data Abort handler */ #ifdef CONFIG_ARM_ERRATA_775420 dsb #endif stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code */ ldr r0, =DataAbortAddr sub r1, lr, #8 str r1, [r0] /* Stores instruction causing data abort */ bl DataAbortInterrupt /*DataAbortInterrupt :call C function here */ ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ subs pc, lr, #8 /* points to the instruction that caused the Data Abort exception */ PrefetchAbortHandler: /* Prefetch Abort handler */ #ifdef CONFIG_ARM_ERRATA_775420 dsb #endif stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code */ ldr r0, =PrefetchAbortAddr sub r1, lr, #4 str r1, [r0] /* Stores instruction causing prefetch abort */ bl PrefetchAbortInterrupt /* PrefetchAbortInterrupt: call C function here */ ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ subs pc, lr, #4 /* points to the instruction that caused the Prefetch Abort exception */ .end

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

17,124

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/gcc/boot.S

/****************************************************************************** * Copyright (c) 2010 - 2022 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file boot.S * * @addtogroup a9_boot_code Cortex A9 Processor Boot Code * @{ * <h2> boot.S </h2> * The boot code performs minimum configuration which is required for an * application to run starting from processor reset state of the processor. Below is a * sequence illustrating what all configuration is performed before control * reaches to main function. * * 1. Program vector table base for exception handling * 2. Invalidate instruction cache, data cache and TLBs * 3. Program stack pointer for various modes (IRQ, FIQ, supervisor, undefine, * abort, system) * 4. Configure MMU with short descriptor translation table format and program * base address of translation table * 5. Enable data cache, instruction cache and MMU * 6. Enable Floating point unit * 7. Transfer control to _start which clears BSS sections, initializes * global timer and runs global constructor before jumping to main * application * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 1.00a ecm/sdm 10/20/09 Initial version * 3.06a sgd 05/15/12 Updated L2CC Auxiliary and Tag RAM Latency control * register settings. * 3.06a asa 06/17/12 Modified the TTBR settings and L2 Cache auxiliary * register settings. * 3.07a asa 07/16/12 Modified the L2 Cache controller settings to improve * performance. Changed the property of the ".boot" * section. * 3.07a sgd 08/21/12 Modified the L2 Cache controller and cp15 Aux Control * Register settings * 3.09a sgd 02/06/13 Updated SLCR l2c Ram Control register to a * value of 0x00020202. Fix for CR 697094 (SI#687034). * 3.10a srt 04/18/13 Implemented ARM Erratas. Please refer to file * 'xil_errata.h' for errata description * 4.2 pkp 06/19/14 Enabled asynchronous abort exception * 5.0 pkp 16/15/14 Modified initialization code to enable scu after * MMU is enabled * 5.1 pkp 05/13/15 Changed the initialization order so to first invalidate * caches and TLB, enable MMU and caches, then enable SMP * bit in ACTLR. L2Cache invalidation and enabling of L2Cache * is done later. * 5.4 asa 12/6/15 Added code to initialize SPSR for all relevant modes. * 6.0 mus 08/04/16 Added code to detect zynq-7000 base silicon configuration and * attempt to enable dual core behavior on single cpu zynq-7000s * devices is prevented from corrupting system behavior. * 6.0 mus 08/24/16 Check CPU core before putting cpu1 to reset for single core * zynq-7000s devices * 7.6 mus 09/02/21 SCU invalidation should be done only from primary CPU, so * skipping it when USE_AMP is set to 1. It fixes CR#1109723 * 7.7 asa 01/06/22 Removed Cortex-A9 errata handling for errata * 742230 and 743622. These do not apply to * Cortex-A9 revision r3p0 being used in Zynq * platforms. * * </pre> * * @note * * None. * ******************************************************************************/ #include "xparameters.h" #include "xil_errata.h" .globl MMUTable .global _prestart .global _boot .global __stack .global __irq_stack .global __supervisor_stack .global __abort_stack .global __fiq_stack .global __undef_stack .global _vector_table .set PSS_L2CC_BASE_ADDR, 0xF8F02000 .set PSS_SLCR_BASE_ADDR, 0xF8000000 .set RESERVED, 0x0fffff00 .set TblBase , MMUTable .set LRemap, 0xFE00000F /* set the base address of the peripheral block as not shared */ .set L2CCWay, (PSS_L2CC_BASE_ADDR + 0x077C) /*(PSS_L2CC_BASE_ADDR + PSS_L2CC_CACHE_INVLD_WAY_OFFSET)*/ .set L2CCSync, (PSS_L2CC_BASE_ADDR + 0x0730) /*(PSS_L2CC_BASE_ADDR + PSS_L2CC_CACHE_SYNC_OFFSET)*/ .set L2CCCrtl, (PSS_L2CC_BASE_ADDR + 0x0100) /*(PSS_L2CC_BASE_ADDR + PSS_L2CC_CNTRL_OFFSET)*/ .set L2CCAuxCrtl, (PSS_L2CC_BASE_ADDR + 0x0104) /*(PSS_L2CC_BASE_ADDR + XPSS_L2CC_AUX_CNTRL_OFFSET)*/ .set L2CCTAGLatReg, (PSS_L2CC_BASE_ADDR + 0x0108) /*(PSS_L2CC_BASE_ADDR + XPSS_L2CC_TAG_RAM_CNTRL_OFFSET)*/ .set L2CCDataLatReg, (PSS_L2CC_BASE_ADDR + 0x010C) /*(PSS_L2CC_BASE_ADDR + XPSS_L2CC_DATA_RAM_CNTRL_OFFSET)*/ .set L2CCIntClear, (PSS_L2CC_BASE_ADDR + 0x0220) /*(PSS_L2CC_BASE_ADDR + XPSS_L2CC_IAR_OFFSET)*/ .set L2CCIntRaw, (PSS_L2CC_BASE_ADDR + 0x021C) /*(PSS_L2CC_BASE_ADDR + XPSS_L2CC_ISR_OFFSET)*/ .set SLCRlockReg, (PSS_SLCR_BASE_ADDR + 0x04) /*(PSS_SLCR_BASE_ADDR + XPSS_SLCR_LOCK_OFFSET)*/ .set SLCRUnlockReg, (PSS_SLCR_BASE_ADDR + 0x08) /*(PSS_SLCR_BASE_ADDR + XPSS_SLCR_UNLOCK_OFFSET)*/ .set SLCRL2cRamReg, (PSS_SLCR_BASE_ADDR + 0xA1C) /*(PSS_SLCR_BASE_ADDR + XPSS_SLCR_L2C_RAM_OFFSET)*/ .set SLCRCPURSTReg, (0xF8000000 + 0x244) /*(XPS_SYS_CTRL_BASEADDR + A9_CPU_RST_CTRL_OFFSET)*/ .set EFUSEStaus, (0xF800D000 + 0x10) /*(XPS_EFUSE_BASEADDR + EFUSE_STATUS_OFFSET)*/ /* workaround for simulation not working when L1 D and I caches,MMU and L2 cache enabled - DT568997 */ .if SIM_MODE == 1 .set CRValMmuCac, 0b00000000000000 /* Disable IDC, and MMU */ .else .set CRValMmuCac, 0b01000000000101 /* Enable IDC, and MMU */ .endif .set CRValHiVectorAddr, 0b10000000000000 /* Set the Vector address to high, 0xFFFF0000 */ .set L2CCAuxControl, 0x72360000 /* Enable all prefetching, Cache replacement policy, Parity enable, Event monitor bus enable and Way Size (64 KB) */ .set L2CCControl, 0x01 /* Enable L2CC */ .set L2CCTAGLatency, 0x0111 /* latency for TAG RAM */ .set L2CCDataLatency, 0x0121 /* latency for DATA RAM */ .set SLCRlockKey, 0x767B /* SLCR lock key */ .set SLCRUnlockKey, 0xDF0D /* SLCR unlock key */ .set SLCRL2cRamConfig, 0x00020202 /* SLCR L2C ram configuration */ /* Stack Pointer locations for boot code */ .set Undef_stack, __undef_stack .set FIQ_stack, __fiq_stack .set Abort_stack, __abort_stack .set SPV_stack, __supervisor_stack .set IRQ_stack, __irq_stack .set SYS_stack, __stack .set vector_base, _vector_table .set FPEXC_EN, 0x40000000 /* FPU enable bit, (1 << 30) */ .section .boot,"ax" /* this initializes the various processor modes */ _prestart: _boot: #if XPAR_CPU_ID==0 /* only allow cpu0 through */ mrc p15,0,r1,c0,c0,5 and r1, r1, #0xf cmp r1, #0 beq CheckEFUSE EndlessLoop0: wfe b EndlessLoop0 CheckEFUSE: ldr r0,=EFUSEStaus ldr r1,[r0] /* Read eFuse setting */ ands r1,r1,#0x80 /* Check whether device is having single core */ beq OKToRun /* single core device, reset cpu1 */ ldr r0,=SLCRUnlockReg /* Load SLCR base address base + unlock register */ ldr r1,=SLCRUnlockKey /* set unlock key */ str r1, [r0] /* Unlock SLCR */ ldr r0,=SLCRCPURSTReg ldr r1,[r0] /* Read CPU Software Reset Control register */ orr r1,r1,#0x22 str r1,[r0] /* Reset CPU1 */ ldr r0,=SLCRlockReg /* Load SLCR base address base + lock register */ ldr r1,=SLCRlockKey /* set lock key */ str r1, [r0] /* lock SLCR */ #elif XPAR_CPU_ID==1 /* only allow cpu1 through */ mrc p15,0,r1,c0,c0,5 and r1, r1, #0xf cmp r1, #1 beq CheckEFUSE1 b EndlessLoop1 CheckEFUSE1: ldr r0,=EFUSEStaus ldr r1,[r0] /* Read eFuse setting */ ands r1,r1,#0x80 /* Check whether device is having single core */ beq OKToRun EndlessLoop1: wfe b EndlessLoop1 #endif OKToRun: mrc p15, 0, r0, c0, c0, 0 /* Get the revision */ and r5, r0, #0x00f00000 and r6, r0, #0x0000000f orr r6, r6, r5, lsr #20-4 /* set VBAR to the _vector_table address in linker script */ ldr r0, =vector_base mcr p15, 0, r0, c12, c0, 0 /*invalidate scu*/ #if USE_AMP!=1 ldr r7, =0xf8f0000c ldr r6, =0xffff str r6, [r7] #endif /* Invalidate caches and TLBs */ mov r0,#0 /* r0 = 0 */ mcr p15, 0, r0, c8, c7, 0 /* invalidate TLBs */ mcr p15, 0, r0, c7, c5, 0 /* invalidate icache */ mcr p15, 0, r0, c7, c5, 6 /* Invalidate branch predictor array */ bl invalidate_dcache /* invalidate dcache */ /* Disable MMU, if enabled */ mrc p15, 0, r0, c1, c0, 0 /* read CP15 register 1 */ bic r0, r0, #0x1 /* clear bit 0 */ mcr p15, 0, r0, c1, c0, 0 /* write value back */ #ifdef SHAREABLE_DDR /* Mark the entire DDR memory as shareable */ ldr r3, =0x3ff /* 1024 entries to cover 1G DDR */ ldr r0, =TblBase /* MMU Table address in memory */ ldr r2, =0x15de6 /* S=b1 TEX=b101 AP=b11, Domain=b1111, C=b0, B=b1 */ shareable_loop: str r2, [r0] /* write the entry to MMU table */ add r0, r0, #0x4 /* next entry in the table */ add r2, r2, #0x100000 /* next section */ subs r3, r3, #1 bge shareable_loop /* loop till 1G is covered */ #endif mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the irq stack pointer */ and r2, r1, r0 orr r2, r2, #0x12 /* IRQ mode */ msr cpsr, r2 ldr r13,=IRQ_stack /* IRQ stack pointer */ bic r2, r2, #(0x1 << 9) /* Set EE bit to little-endian */ msr spsr_fsxc,r2 mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the supervisor stack pointer */ and r2, r1, r0 orr r2, r2, #0x13 /* supervisor mode */ msr cpsr, r2 ldr r13,=SPV_stack /* Supervisor stack pointer */ bic r2, r2, #(0x1 << 9) /* Set EE bit to little-endian */ msr spsr_fsxc,r2 mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the Abort stack pointer */ and r2, r1, r0 orr r2, r2, #0x17 /* Abort mode */ msr cpsr, r2 ldr r13,=Abort_stack /* Abort stack pointer */ bic r2, r2, #(0x1 << 9) /* Set EE bit to little-endian */ msr spsr_fsxc,r2 mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the FIQ stack pointer */ and r2, r1, r0 orr r2, r2, #0x11 /* FIQ mode */ msr cpsr, r2 ldr r13,=FIQ_stack /* FIQ stack pointer */ bic r2, r2, #(0x1 << 9) /* Set EE bit to little-endian */ msr spsr_fsxc,r2 mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the Undefine stack pointer */ and r2, r1, r0 orr r2, r2, #0x1b /* Undefine mode */ msr cpsr, r2 ldr r13,=Undef_stack /* Undefine stack pointer */ bic r2, r2, #(0x1 << 9) /* Set EE bit to little-endian */ msr spsr_fsxc,r2 mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the system stack pointer */ and r2, r1, r0 orr r2, r2, #0x1F /* SYS mode */ msr cpsr, r2 ldr r13,=SYS_stack /* SYS stack pointer */ /*set scu enable bit in scu*/ ldr r7, =0xf8f00000 ldr r0, [r7] orr r0, r0, #0x1 str r0, [r7] /* enable MMU and cache */ ldr r0,=TblBase /* Load MMU translation table base */ orr r0, r0, #0x5B /* Outer-cacheable, WB */ mcr 15, 0, r0, c2, c0, 0 /* TTB0 */ mvn r0,#0 /* Load MMU domains -- all ones=manager */ mcr p15,0,r0,c3,c0,0 /* Enable mmu, icahce and dcache */ ldr r0,=CRValMmuCac mcr p15,0,r0,c1,c0,0 /* Enable cache and MMU */ dsb /* dsb allow the MMU to start up */ isb /* isb flush prefetch buffer */ /* Write to ACTLR */ mrc p15, 0, r0, c1, c0, 1 /* Read ACTLR*/ orr r0, r0, #(0x01 << 6) /* set SMP bit */ orr r0, r0, #(0x01 ) /* Cache/TLB maintenance broadcast */ mcr p15, 0, r0, c1, c0, 1 /* Write ACTLR*/ /* Invalidate L2 Cache and enable L2 Cache*/ /* For AMP, assume running on CPU1. Don't initialize L2 Cache (up to Linux) */ #if USE_AMP!=1 ldr r0,=L2CCCrtl /* Load L2CC base address base + control register */ mov r1, #0 /* force the disable bit */ str r1, [r0] /* disable the L2 Caches */ ldr r0,=L2CCAuxCrtl /* Load L2CC base address base + Aux control register */ ldr r1,[r0] /* read the register */ ldr r2,=L2CCAuxControl /* set the default bits */ orr r1,r1,r2 str r1, [r0] /* store the Aux Control Register */ ldr r0,=L2CCTAGLatReg /* Load L2CC base address base + TAG Latency address */ ldr r1,=L2CCTAGLatency /* set the latencies for the TAG*/ str r1, [r0] /* store the TAG Latency register Register */ ldr r0,=L2CCDataLatReg /* Load L2CC base address base + Data Latency address */ ldr r1,=L2CCDataLatency /* set the latencies for the Data*/ str r1, [r0] /* store the Data Latency register Register */ ldr r0,=L2CCWay /* Load L2CC base address base + way register*/ ldr r2, =0xFFFF str r2, [r0] /* force invalidate */ ldr r0,=L2CCSync /* need to poll 0x730, PSS_L2CC_CACHE_SYNC_OFFSET */ /* Load L2CC base address base + sync register*/ /* poll for completion */ Sync: ldr r1, [r0] cmp r1, #0 bne Sync ldr r0,=L2CCIntRaw /* clear pending interrupts */ ldr r1,[r0] ldr r0,=L2CCIntClear str r1,[r0] ldr r0,=SLCRUnlockReg /* Load SLCR base address base + unlock register */ ldr r1,=SLCRUnlockKey /* set unlock key */ str r1, [r0] /* Unlock SLCR */ ldr r0,=SLCRL2cRamReg /* Load SLCR base address base + l2c Ram Control register */ ldr r1,=SLCRL2cRamConfig /* set the configuration value */ str r1, [r0] /* store the L2c Ram Control Register */ ldr r0,=SLCRlockReg /* Load SLCR base address base + lock register */ ldr r1,=SLCRlockKey /* set lock key */ str r1, [r0] /* lock SLCR */ ldr r0,=L2CCCrtl /* Load L2CC base address base + control register */ ldr r1,[r0] /* read the register */ mov r2, #L2CCControl /* set the enable bit */ orr r1,r1,r2 str r1, [r0] /* enable the L2 Caches */ #endif mov r0, r0 mrc p15, 0, r1, c1, c0, 2 /* read cp access control register (CACR) into r1 */ orr r1, r1, #(0xf << 20) /* enable full access for p10 & p11 */ mcr p15, 0, r1, c1, c0, 2 /* write back into CACR */ /* enable vfp */ fmrx r1, FPEXC /* read the exception register */ orr r1,r1, #FPEXC_EN /* set VFP enable bit, leave the others in orig state */ fmxr FPEXC, r1 /* write back the exception register */ mrc p15,0,r0,c1,c0,0 /* flow prediction enable */ orr r0, r0, #(0x01 << 11) /* #0x8000 */ mcr p15,0,r0,c1,c0,0 mrc p15,0,r0,c1,c0,1 /* read Auxiliary Control Register */ orr r0, r0, #(0x1 << 2) /* enable Dside prefetch */ orr r0, r0, #(0x1 << 1) /* enable L2 Prefetch hint */ mcr p15,0,r0,c1,c0,1 /* write Auxiliary Control Register */ mrs r0, cpsr /* get the current PSR */ bic r0, r0, #0x100 /* enable asynchronous abort exception */ msr cpsr_xsf, r0 b _start /* jump to C startup code */ and r0, r0, r0 /* no op */ .Ldone: b .Ldone /* Paranoia: we should never get here */ /* ************************************************************************* * * invalidate_dcache - invalidate the entire d-cache by set/way * * Note: for Cortex-A9, there is no cp instruction for invalidating * the whole D-cache. Need to invalidate each line. * ************************************************************************* */ invalidate_dcache: mrc p15, 1, r0, c0, c0, 1 /* read CLIDR */ ands r3, r0, #0x7000000 mov r3, r3, lsr #23 /* cache level value (naturally aligned) */ beq finished mov r10, #0 /* start with level 0 */ loop1: add r2, r10, r10, lsr #1 /* work out 3xcachelevel */ mov r1, r0, lsr r2 /* bottom 3 bits are the Cache type for this level */ and r1, r1, #7 /* get those 3 bits alone */ cmp r1, #2 blt skip /* no cache or only instruction cache at this level */ mcr p15, 2, r10, c0, c0, 0 /* write the Cache Size selection register */ isb /* isb to sync the change to the CacheSizeID reg */ mrc p15, 1, r1, c0, c0, 0 /* reads current Cache Size ID register */ and r2, r1, #7 /* extract the line length field */ add r2, r2, #4 /* add 4 for the line length offset (log2 16 bytes) */ ldr r4, =0x3ff ands r4, r4, r1, lsr #3 /* r4 is the max number on the way size (right aligned) */ clz r5, r4 /* r5 is the bit position of the way size increment */ ldr r7, =0x7fff ands r7, r7, r1, lsr #13 /* r7 is the max number of the index size (right aligned) */ loop2: mov r9, r4 /* r9 working copy of the max way size (right aligned) */ loop3: orr r11, r10, r9, lsl r5 /* factor in the way number and cache number into r11 */ orr r11, r11, r7, lsl r2 /* factor in the index number */ mcr p15, 0, r11, c7, c6, 2 /* invalidate by set/way */ subs r9, r9, #1 /* decrement the way number */ bge loop3 subs r7, r7, #1 /* decrement the index */ bge loop2 skip: add r10, r10, #2 /* increment the cache number */ cmp r3, r10 bgt loop1 finished: mov r10, #0 /* switch back to cache level 0 */ mcr p15, 2, r10, c0, c0, 0 /* select current cache level in cssr */ dsb isb bx lr .end /** * @} End of "addtogroup a9_boot_code". */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,555

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexa9/gcc/cpu_init.S

/****************************************************************************** * Copyright (c) 2009 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file cpu_init.S * * This file contains CPU specific initialization. Invoked from main CRT * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 1.00a ecm/sdm 10/20/09 Initial version * 3.04a sdm 01/02/12 Updated to clear cp15 regs with unknown reset values * 5.0 pkp 12/16/14 removed incorrect initialization of TLB lockdown * register to fix CR#830580 * </pre> * * @note * * None. * ******************************************************************************/ .text .global __cpu_init .align 2 __cpu_init: /* Clear cp15 regs with unknown reset values */ mov r0, #0x0 mcr p15, 0, r0, c5, c0, 0 /* DFSR */ mcr p15, 0, r0, c5, c0, 1 /* IFSR */ mcr p15, 0, r0, c6, c0, 0 /* DFAR */ mcr p15, 0, r0, c6, c0, 2 /* IFAR */ mcr p15, 0, r0, c9, c13, 2 /* PMXEVCNTR */ mcr p15, 0, r0, c13, c0, 2 /* TPIDRURW */ mcr p15, 0, r0, c13, c0, 3 /* TPIDRURO */ /* Reset and start Cycle Counter */ mov r2, #0x80000000 /* clear overflow */ mcr p15, 0, r2, c9, c12, 3 mov r2, #0xd /* D, C, E */ mcr p15, 0, r2, c9, c12, 0 mov r2, #0x80000000 /* enable cycle counter */ mcr p15, 0, r2, c9, c12, 1 bx lr .end

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

8,976

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/iccarm/boot.s

;****************************************************************************** ; Copyright (c) 2014 - 2020 Xilinx, Inc. All rights reserved. ; SPDX-License-Identifier: MIT ; *****************************************************************************/ ; ****************************************************************************/ ; ** ; @file boot.S ; ; This file contains the initial startup code for the Cortex R5 processor ; ; <pre> ; MODIFICATION HISTORY: ; ; Ver Who Date Changes ; ----- ---- -------- --------------------------------------------------- ; 5.00 mus 01/27/17 Initial version ; 6.6 srm 10/18/17 Updated the timer configuration with XTime_StartTTCTimer. ; Now the timer instance as specified by the user will be ; started. ; 6.6 mus 02/23/17 Disable the debug logic in non-JTAG boot mode(when ; processor is in lockstep configuration), based ; on the mld parameter "lockstep_mode_debug". * 6.8 mus 09/20/18 Clear VINITHI field in RPU_0_CFG/RPU_1_CFG * registers to initialize CortexR5 core with LOVEC * on reset. It fixes CR#1010656. * 7.0 mus 03/19/19 Disable FPU only in case of softp, otherwise enable it by * default. CR#1021638 ; ; </pre> ; ; @note ; ; None. ; ; *****************************************************************************/ MODULE ?boot ;; Forward declaration of sections. SECTION IRQ_STACK:DATA:NOROOT(3) SECTION FIQ_STACK:DATA:NOROOT(3) SECTION SVC_STACK:DATA:NOROOT(3) SECTION ABT_STACK:DATA:NOROOT(3) SECTION UND_STACK:DATA:NOROOT(3) SECTION CSTACK:DATA:NOROOT(3) #include "xparameters.h" #define UART_BAUDRATE 115200 PUBLIC _prestart PUBLIC __iar_program_start IMPORT _vector_table IMPORT Init_MPU #ifdef SLEEP_TIMER_BASEADDR IMPORT XTime_StartTTCTimer #endif IMPORT __cmain vector_base EQU _vector_table RPU_GLBL_CNTL EQU 0xFF9A0000 RPU_ERR_INJ EQU 0xFF9A0020 RPU_0_CFG EQU 0xFF9A0100 RPU_1_CFG EQU 0xFF9A0200 RST_LPD_DBG EQU 0xFF5E0240 BOOT_MODE_USER EQU 0xFF5E0200 fault_log_enable EQU 0x101 SECTION .boot:CODE:NOROOT(2) /* this initializes the various processor modes */ _prestart __iar_program_start OKToRun REQUIRE _vector_table /* Initialize processor registers to 0 */ mov r0,#0 mov r1,#0 mov r2,#0 mov r3,#0 mov r4,#0 mov r5,#0 mov r6,#0 mov r7,#0 mov r8,#0 mov r9,#0 mov r10,#0 mov r11,#0 mov r12,#0 /* Initialize stack pointer and banked registers for various mode */ mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the irq stack pointer and r2, r1, r0 orr r2, r2, #0x12 ; IRQ mode msr cpsr, r2 ldr r13,=SFE(IRQ_STACK) ; IRQ stack pointer mov r14,#0 mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the supervisor stack pointer and r2, r1, r0 orr r2, r2, #0x13 ; supervisor mode msr cpsr, r2 ldr r13,=SFE(SVC_STACK) ; Supervisor stack pointer mov r14,#0 mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the Abort stack pointer and r2, r1, r0 orr r2, r2, #0x17 ; Abort mode msr cpsr, r2 ldr r13,=SFE(ABT_STACK) ; Abort stack pointer mov r14,#0 mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the FIQ stack pointer and r2, r1, r0 orr r2, r2, #0x11 ; FIQ mode msr cpsr, r2 mov r8, #0 mov r9, #0 mov r10, #0 mov r11, #0 mov r12, #0 ldr r13,=SFE(FIQ_STACK) ; FIQ stack pointer mov r14,#0 mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the Undefine stack pointer and r2, r1, r0 orr r2, r2, #0x1b ; Undefine mode msr cpsr, r2 ldr r13,=SFE(UND_STACK) ; Undefine stack pointer mov r14,#0 mrs r0, cpsr ; get the current PSR mvn r1, #0x1f ; set up the system stack pointer and r2, r1, r0 orr r2, r2, #0x1F ; SYS mode msr cpsr, r2 ldr r13,=SFE(CSTACK) ; SYS stack pointer mov r14,#0 ; ; Enable access to VFP by enabling access to Coprocessors 10 and 11. ; Enables Full Access i.e. in both privileged and non privileged modes ; mrc p15, 0, r0, c1, c0, 2 ; Read Coprocessor Access Control Register (CPACR) orr r0, r0, #(0xF << 20) ; Enable access to CP 10 & 11 mcr p15, 0, r0, c1, c0, 2 ; Write Coprocessor Access Control Register (CPACR) isb ; enable fpu access vmrs r3, FPEXC orr r1, r3, #(1<<30) vmsr FPEXC, r1 ; clear the floating point register mov r1,#0 vmov d0,r1,r1 vmov d1,r1,r1 vmov d2,r1,r1 vmov d3,r1,r1 vmov d4,r1,r1 vmov d5,r1,r1 vmov d6,r1,r1 vmov d7,r1,r1 vmov d8,r1,r1 vmov d9,r1,r1 vmov d10,r1,r1 vmov d11,r1,r1 vmov d12,r1,r1 vmov d13,r1,r1 vmov d14,r1,r1 vmov d15,r1,r1 #ifdef __SOFTFP__ ; Disable FPU by restoring previous value for FPU access vmsr FPEXC,r3 #endif ; Disable MPU and caches mrc p15, 0, r0, c1, c0, 0 ; Read CP15 Control Register bic r0, r0, #0x05 ; Disable MPU (M bit) and data cache (C bit) bic r0, r0, #0x1000 ; Disable instruction cache (I bit) dsb ; Ensure all previous loads/stores have completed mcr p15, 0, r0, c1, c0, 0 ; Write CP15 Control Register isb ; Ensure subsequent insts execute wrt new MPU settings ; Disable Branch prediction, TCM ECC checks mrc p15, 0, r0, c1, c0, 1 ; Read ACTLR orr r0, r0, #(0x1 << 17) ; Enable RSDIS bit 17 to disable the return stack orr r0, r0, #(0x1 << 16) ; Clear BP bit 15 and set BP bit 16 bic r0, r0, #(0x1 << 15) ; Branch always not taken and history table updates disabled bic r0, r0, #(0x1 << 27) ; Disable B1TCM ECC check bic r0, r0, #(0x1 << 26) ; Disable B0TCM ECC check bic r0, r0, #(0x1 << 25) ; Disable ATCM ECC check orr r0, r0, #(0x1 << 5) ; Enable ECC with no forced write through with [5:3]=b'101 bic r0, r0, #(0x1 << 4) orr r0, r0, #(0x1 << 3) mcr p15, 0, r0, c1, c0, 1 ; Write ACTLR*/ dsb ; Complete all outstanding explicit memory operations*/ ; Invalidate caches mov r0,#0 ; r0 = 0 dsb mcr p15, 0, r0, c7, c5, 0 ; invalidate icache mcr p15, 0, r0, c15, c5, 0 ; Invalidate entire data cache isb #if LOCKSTEP_MODE_DEBUG == 0 ; enable fault log for lock step ldr r0,=RPU_GLBL_CNTL ldr r1, [r0] ands r1, r1, #0x8 ; branch to initialization if split mode bne init ; check for boot mode if in lock step, branch to init if JTAG boot mode ldr r0,=BOOT_MODE_USER ldr r1, [r0] ands r1, r1, #0xF beq init ; reset the debug logic ldr r0,=RST_LPD_DBG ldr r1, [r0] orr r1, r1, #(0x1 << 1) orr r1, r1, #(0x1 << 4) orr r1, r1, #(0x1 << 5) str r1, [r0] ; enable fault log ldr r0,=RPU_ERR_INJ ldr r1,=fault_log_enable ldr r2, [r0] orr r2, r2, r1 str r2, [r0] nop nop #endif init bl Init_MPU ; Initialize MPU ; Enable Branch prediction mrc p15, 0, r0, c1, c0, 1 ; Read ACTLR bic r0, r0, #(0x1 << 17) ; Clear RSDIS bit 17 to enable return stack bic r0, r0, #(0x1 << 16) ; Clear BP bit 15 and BP bit 16: bic r0, r0, #(0x1 << 15) ; Normal operation, BP is taken from the global history table. orr r0, r0, #(0x1 << 14) ; Disable DBWR for errata 780125 mcr p15, 0, r0, c1, c0, 1 ; Write ACTLR ; Enable icahce and dcache mrc p15,0,r1,c1,c0,0 ldr r0, =0x1005 orr r1,r1,r0 dsb mcr p15,0,r1,c1,c0,0 ; Enable cache isb ; isb flush prefetch buffer ; Set vector table in TCM/LOVEC #ifndef VEC_TABLE_IN_OCM mrc p15, 0, r0, c1, c0, 0 mvn r1, #0x2000 and r0, r0, r1 mcr p15, 0, r0, c1, c0, 0 ; Clear VINITHI to enable LOVEC on reset #if XPAR_CPU_ID == 0 ldr r0, =RPU_0_CFG #else ldr r0, =RPU_1_CFG #endif ldr r1, [r0] bic r1, r1, #(0x1 << 2) str r1, [r0] #endif ; enable asynchronous abort exception mrs r0, cpsr bic r0, r0, #0x100 msr cpsr_xsf, r0 ; Clear cp15 regs with unknown reset values mov r0, #0x0 mcr p15, 0, r0, c5, c0, 0 ; DFSR mcr p15, 0, r0, c5, c0, 1 ; IFSR mcr p15, 0, r0, c6, c0, 0 ; DFAR mcr p15, 0, r0, c6, c0, 2 ; IFAR mcr p15, 0, r0, c9, c13, 2 ; PMXEVCNTR mcr p15, 0, r0, c13, c0, 2 ; TPIDRURW mcr p15, 0, r0, c13, c0, 3 ; TPIDRURO ; Reset and start Cycle Counter mov r2, #0x80000000 ; clear overflow mcr p15, 0, r2, c9, c12, 3 mov r2, #0xd ; D, C, E mcr p15, 0, r2, c9, c12, 0 mov r2, #0x80000000 ; enable cycle counter mcr p15, 0, r2, c9, c12, 1 ; configure the timer if TTC is present #ifdef SLEEP_TIMER_BASEADDR bl XTime_StartTTCTimer #endif ; make sure argc and argv are valid mov r0, #0 mov r1, #0 b __cmain ; jump to C startup code Ldone b Ldone ; Paranoia: we should never get here END

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

4,131

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/iccarm/asm_vectors.s

;****************************************************************************** ; Copyright (c) 2017 - 2020 Xilinx, Inc. All rights reserved. ; SPDX-License-Identifier: MIT ;*****************************************************************************/ ;*****************************************************************************/ ;** ; @file asm_vectors.s ; ; This file contains the initial vector table for the Cortex R5 processor ; ; <pre> ; MODIFICATION HISTORY: ; ; Ver Who Date Changes ; ----- ------- -------- --------------------------------------------------- ; 6.2 mus 01/27/17 Initial version ; </pre> ; ; @note ; ; None. ; ;*****************************************************************************/ MODULE ?asm_vectors ;; Forward declaration of sections. SECTION IRQ_STACK:DATA:NOROOT(3) SECTION FIQ_STACK:DATA:NOROOT(3) SECTION SVC_STACK:DATA:NOROOT(3) SECTION ABT_STACK:DATA:NOROOT(3) SECTION UND_STACK:DATA:NOROOT(3) SECTION CSTACK:DATA:NOROOT(3) #define UART_BAUDRATE 115200 IMPORT _prestart IMPORT __iar_program_start SECTION .intvec:CODE:NOROOT(2) PUBLIC _vector_table IMPORT FIQInterrupt IMPORT IRQInterrupt IMPORT SWInterrupt IMPORT DataAbortInterrupt IMPORT PrefetchAbortInterrupt IMPORT UndefinedException IMPORT UndefinedExceptionAddr IMPORT PrefetchAbortAddr IMPORT DataAbortAddr IMPORT prof_pc _vector_table ARM ldr pc,=__iar_program_start ldr pc,=Undefined ldr pc,=SVCHandler ldr pc,=PrefetchAbortHandler ldr pc,=DataAbortHandler NOP ; Placeholder for address exception vector ldr pc,=IRQHandler ldr pc,=FIQHandler SECTION .text:CODE:NOROOT(2) REQUIRE _vector_table ARM IRQHandler ; IRQ vector handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code #ifndef __SOFTFP__ vpush {d0-d7} /* Store floating point registers */ vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} #endif bl IRQInterrupt ; IRQ vector #ifndef __SOFTFP__ pop {r1} /* Restore floating point registers */ vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d0-d7} #endif ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #4 ; adjust return FIQHandler ; FIQ vector handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code FIQLoop bl FIQInterrupt ; FIQ vector ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #4 ; adjust return Undefined ; Undefined handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldr r0, =UndefinedExceptionAddr sub r1, lr, #4 str r1, [r0] ; Store address of instruction causing undefined exception bl UndefinedException ; UndefinedException: call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code movs pc, lr SVCHandler ; SWI handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code tst r0, #0x20 ; check the T bit ldrneh r0, [lr,#-2] ; Thumb mode bicne r0, r0, #0xff00 ; Thumb mode ldreq r0, [lr,#-4] ; ARM mode biceq r0, r0, #0xff000000 ; ARM mode bl SWInterrupt ; SWInterrupt: call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code movs pc, lr ; adjust return DataAbortHandler ; Data Abort handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldr r0, =DataAbortAddr sub r1, lr, #8 str r1, [r0] ; Stores instruction causing data abort bl DataAbortInterrupt ;DataAbortInterrupt :call C function here ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code subs pc, lr, #8 ; adjust return PrefetchAbortHandler ; Prefetch Abort handler stmdb sp!,{r0-r3,r12,lr} ; state save from compiled code ldr r0, =PrefetchAbortAddr sub r1, lr, #4 str r1, [r0] ; Stores instruction causing prefetch abort */ bl PrefetchAbortInterrupt ; PrefetchAbortInterrupt: call C function here */ ldmia sp!,{r0-r3,r12,lr} ; state restore from compiled code */ subs pc, lr, #4 ; adjust return */ END

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,403

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/armclang/xil-crt0.S

;/****************************************************************************** ;* Copyright (c) 2020 Xilinx, Inc. All rights reserved. ;* SPDX-License-Identifier: MIT ;******************************************************************************/ ;/*****************************************************************************/ ;/** ;* @file xil-crt0.S ;* ;* <pre> ;* MODIFICATION HISTORY: ;* ;* Ver Who Date Changes ;* ----- ---- -------- --------------------------------------------------- ;* 7.3 dp 06/25/20 Initial version for armclang ;* </pre> ;* ;* @note ;* ;* None. ;* ;******************************************************************************/ #include "xparameters.h" #include "bspconfig.h" IMPORT |Image$$BSS_SECTION$$Base| IMPORT Xil_InitializeExistingMPURegConfig EXPORT _startup IMPORT __cpu_init IMPORT __main #ifdef SLEEP_TIMER_BASEADDR IMPORT XTime_StartTTCTimer #endif AREA |.text|, CODE REQUIRE8 {TRUE} PRESERVE8 {TRUE} ENTRY _startup bl __cpu_init ;Initialize the CPU first (BSP provides this) ;configure the timer if TTC is present #ifdef SLEEP_TIMER_BASEADDR bl XTime_StartTTCTimer #endif bl Xil_InitializeExistingMPURegConfig ;/* Initialize MPU config */ ;make sure argc and argv are valid mov r0, #0 mov r1, #0 #ifdef XCLOCKING bl Xil_ClockInit #endif bl __main ;Jump to main C code bl exit exit ;should never get here b exit END

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

3,689

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/armclang/asm_vectors.S

;/****************************************************************************** ;* Copyright (c) 2020 - 2021 Xilinx, Inc. All rights reserved. ;* ;* SPDX-License-Identifier: MIT ;* ;******************************************************************************/ ;/*****************************************************************************/ ;/** ;* @file asm_vectors.S ;* ;* This file contains the initial vector table for the Cortex R5 processor ;* as per armclang compiler ;* ;* <pre> ;* MODIFICATION HISTORY: ;* ;* Ver Who Date Changes ;* ----- ------- -------- --------------------------------------------------- ;* 7.3 dp 06/25/20 Initial version for armclang ;* </pre> ;* ;* @note ;* ;* None. ;* ;******************************************************************************/ EXPORT _vector_table IMPORT _boot IMPORT FIQInterrupt IMPORT IRQInterrupt IMPORT SWInterrupt IMPORT DataAbortInterrupt IMPORT PrefetchAbortInterrupt IMPORT UndefinedExceptionAddr IMPORT UndefinedException IMPORT DataAbortAddr IMPORT PrefetchAbortAddr EXPORT IRQHandler AREA |vectors|, CODE REQUIRE8 {TRUE} PRESERVE8 {TRUE} ENTRY ; Define this an entry point _vector_table ldr pc, =_boot ldr pc, =Undefined ldr pc, =SVCHandler ldr pc, =PrefetchAbortHandler ldr pc, =DataAbortHandler NOP ;Placeholder for address exception vector ldr pc, =IRQHandler ldr pc, =FIQHandler IRQHandler ;IRQ vector handler stmdb sp!,{r0-r3,r12,lr} ;state save from compiled code #ifndef __SOFTFP__ vpush {d0-d7} ;Store floating point registers/ vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} #endif bl IRQInterrupt ;IRQ vector #ifndef __SOFTFP__ pop {r1} ;Restore floating point registers vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d0-d7} #endif ldmia sp!,{r0-r3,r12,lr} ;state restore from compiled code subs pc, lr, #4 ;adjust return FIQHandler ;FIQ vector handler stmdb sp!,{r0-r3,r12,lr} ;state save from compiled code FIQLoop bl FIQInterrupt ;FIQ vector ldmia sp!,{r0-r3,r12,lr} ;state restore from compiled code subs pc, lr, #4 ;adjust return Undefined ;Undefined handler stmdb sp!,{r0-r3,r12,lr} ;state save from compiled code ldr r0, =UndefinedExceptionAddr sub r1, lr, #4 str r1, [r0] ;Store address of instruction causing undefined exception bl UndefinedException ;UndefinedException: call C function here ldmia sp!,{r0-r3,r12,lr} ;state restore from compiled code movs pc, lr SVCHandler ;SWI handler stmdb sp!,{r0-r3,r12,lr} ;state save from compiled code tst r0, #0x20 ;check the T bit ldrneh r0, [lr,#-2] ;Thumb mode bicne r0, r0, #0xff00 ;Thumb mode ldreq r0, [lr,#-4] ;ARM mode biceq r0, r0, #0xff000000 ;ARM mode bl SWInterrupt ;SWInterrupt: call C function here ldmia sp!,{r0-r3,r12,lr} ;state restore from compiled code movs pc, lr ;adjust return DataAbortHandler ;Data Abort handler stmdb sp!,{r0-r3,r12,lr} ;state save from compiled code ldr r0, =DataAbortAddr sub r1, lr, #8 str r1, [r0] ;Stores instruction causing data abort bl DataAbortInterrupt ;ataAbortInterrupt :call C function here ldmia sp!,{r0-r3,r12,lr} ;state restore from compiled code subs pc, lr, #8 ;adjust return PrefetchAbortHandler ;Prefetch Abort handler stmdb sp!,{r0-r3,r12,lr} ;state save from compiled code ldr r0, =PrefetchAbortAddr sub r1, lr, #4 str r1, [r0] ;Stores instruction causing prefetch abort bl PrefetchAbortInterrupt ;PrefetchAbortInterrupt: call C function here ldmia sp!,{r0-r3,r12,lr} ;state restore from compiled code subs pc, lr, #4 ;adjust return END

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

8,033

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/armclang/boot.S

;/****************************************************************************** ;* Copyright (c) 2020 Xilinx, Inc. All rights reserved. ;* SPDX-License-Identifier: MIT ;******************************************************************************/ ;/*****************************************************************************/ ;/** ;* @file boot.S ;* ;* @addtogroup r5_boot_code Cortex R5 Processor Boot Code ;* @{ ;* <h2> boot.S </h2> ;* The boot code performs minimum configuration which is required for an ;* application to run starting from processor's reset state. Below is a ;* sequence illustrating what all configuration is performed before control ;* reaches to main function. ;* ;* 1. Program vector table base for exception handling ;* 2. Program stack pointer for various modes (IRQ, FIQ, supervisor, undefine, ;* abort, system) ;* 3. Disable instruction cache, data cache and MPU ;* 4. Invalidate instruction and data cache ;* 5. Configure MPU with short descriptor translation table format and program ;* base address of translation table ;* 6. Enable data cache, instruction cache and MPU ;* 7. Enable Floating point unit ;* 8. Transfer control to _start which clears BSS sections and jumping to main ;* application ;* ;* ;* <pre> ;* MODIFICATION HISTORY: ;* ;* Ver Who Date Changes ;* ----- ---- -------- --------------------------------------------------- ;* 7.3 dp 06/25/20 Initial version for armclang ;* </pre> ;* ;******************************************************************************/ #include "xparameters.h" EXPORT _prestart EXPORT _boot IMPORT |Image$$ARM_LIB_STACK$$Base| IMPORT |Image$$ARM_IRQ_STACK$$Base| IMPORT |Image$$ARM_SV_STACK$$Base| IMPORT |Image$$ARM_ABORT_STACK$$Base| IMPORT |Image$$ARM_FIQ_STACK$$Base| IMPORT |Image$$ARM_UNDEF_STACK$$Base| IMPORT Init_MPU IMPORT _startup RPU_GLBL_CNTL EQU 0xFF9A0000 RPU_ERR_INJ EQU 0xFF9A0020 RPU_0_CFG EQU 0xFF9A0100 RPU_1_CFG EQU 0xFF9A0200 #if defined(versal) RST_LPD_DBG EQU 0xFF5E0338 BOOT_MODE_USER EQU 0xF1260200 #else RST_LPD_DBG EQU 0xFF5E0240 BOOT_MODE_USER EQU 0xFF5E0200 #endif fault_log_enable EQU 0x101 ;0th bit of PROCESSOR_ACCESS_VALUE macro signifies trustzone ;setting for RPU address space #define RPU_TZ_MASK 0x1 AREA |.boot|, CODE REQUIRE8 {TRUE} PRESERVE8 {TRUE} ENTRY ;this initializes the various processor modes _prestart _boot OKToRun ;Initialize processor registers to 0 mov r0,#0 mov r1,#0 mov r2,#0 mov r3,#0 mov r4,#0 mov r5,#0 mov r6,#0 mov r7,#0 mov r8,#0 mov r9,#0 mov r10,#0 mov r11,#0 mov r12,#0 ;Initialize stack pointer and banked registers for various mode mrs r0, cpsr ;get the current PSR mvn r1, #0x1f ;set up the irq stack pointer and r2, r1, r0 orr r2, r2, #0x12 ;IRQ mode msr cpsr_cxsf, r2 ldr r13,=|Image$$ARM_IRQ_STACK$$Base| ;IRQ stack pointer mov r14,#0 mrs r0, cpsr ;get the current PSR mvn r1, #0x1f ;set up the supervisor stack pointer and r2, r1, r0 orr r2, r2, #0x13 ;supervisor mode msr cpsr_cxsf, r2 ldr r13,=|Image$$ARM_SV_STACK$$Base| ;Supervisor stack pointer mov r14,#0 mrs r0, cpsr ;get the current PSR mvn r1, #0x1f ;set up the Abort stack pointer and r2, r1, r0 orr r2, r2, #0x17 ;Abort mode msr cpsr_cxsf, r2 ldr r13,=|Image$$ARM_ABORT_STACK$$Base| ;Abort stack pointer mov r14,#0 mrs r0, cpsr ;get the current PSR mvn r1, #0x1f ;set up the FIQ stack pointer and r2, r1, r0 orr r2, r2, #0x11 ;FIQ mode msr cpsr_cxsf, r2 mov r8, #0 mov r9, #0 mov r10, #0 mov r11, #0 mov r12, #0 ldr r13,=|Image$$ARM_FIQ_STACK$$Base| ;FIQ stack pointer mov r14,#0 mrs r0, cpsr ;get the current PSR mvn r1, #0x1f ;set up the Undefine stack pointer and r2, r1, r0 orr r2, r2, #0x1b ;Undefine mode msr cpsr_cxsf, r2 ldr r13,=|Image$$ARM_UNDEF_STACK$$Base| ;Undefine stack pointer mov r14,#0 mrs r0, cpsr ;get the current PSR mvn r1, #0x1f ;set up the system stack pointer and r2, r1, r0 orr r2, r2, #0x1F ;SYS mode msr cpsr_cxsf, r2 ldr r13,=|Image$$ARM_LIB_STACK$$Base| ;SYS stack pointer mov r14,#0 ;Enable access to VFP by enabling access to Coprocessors 10 and 11. ;Enables Full Access i.e. in both privileged and non privileged modes mrc p15, 0, r0, c1, c0, 2 ;Read Coprocessor Access Control Register (CPACR) orr r0, r0, #(0xF << 20) ;Enable access to CP 10 & 11 mcr p15, 0, r0, c1, c0, 2 ;Write Coprocessor Access Control Register (CPACR) isb ;enable fpu access vmrs r3, FPEXC orr r1, r3, #(1<<30) vmsr FPEXC, r1 ;clear the floating point register mov r1,#0 vmov d0,r1,r1 vmov d1,r1,r1 vmov d2,r1,r1 vmov d3,r1,r1 vmov d4,r1,r1 vmov d5,r1,r1 vmov d6,r1,r1 vmov d7,r1,r1 vmov d8,r1,r1 vmov d9,r1,r1 vmov d10,r1,r1 vmov d11,r1,r1 vmov d12,r1,r1 vmov d13,r1,r1 vmov d14,r1,r1 vmov d15,r1,r1 #ifdef __SOFTFP__ ;Disable the FPU if SOFTFP is defined vmsr FPEXC,r3 #endif ;Disable MPU and caches mrc p15, 0, r0, c1, c0, 0 ;Read CP15 Control Register bic r0, r0, #0x05 ;Disable MPU (M bit) and data cache (C bit) bic r0, r0, #0x1000 ;Disable instruction cache (I bit) dsb ;Ensure all previous loads/stores have completed mcr p15, 0, r0, c1, c0, 0 ;Write CP15 Control Register isb ;Ensure subsequent insts execute wrt new MPU settings ;Disable Branch prediction, TCM ECC checks mrc p15, 0, r0, c1, c0, 1 ;Read ACTLR orr r0, r0, #(0x1 << 17) ;Enable RSDIS bit 17 to disable the return stack orr r0, r0, #(0x1 << 16) ;Clear BP bit 15 and set BP bit 16: bic r0, r0, #(0x1 << 15) ;Branch always not taken and history table updates disabled orr r0, r0, #(0x1 << 27) ;Enable B1TCM ECC check orr r0, r0, #(0x1 << 26) ;Enable B0TCM ECC check orr r0, r0, #(0x1 << 25) ;Enable ATCM ECC check bic r0, r0, #(0x1 << 5) ;Generate abort on parity errors, with [5:3]=b 000 bic r0, r0, #(0x1 << 4) bic r0, r0, #(0x1 << 3) mcr p15, 0, r0, c1, c0, 1 ;Write ACTLR dsb ;Complete all outstanding explicit memory operations ;Invalidate caches mov r0,#0 ;r0 = 0 dsb mcr p15, 0, r0, c7, c5, 0 ;invalidate icache mcr p15, 0, r0, c15, c5, 0 ;Invalidate entire data cache isb #if LOCKSTEP_MODE_DEBUG == 0 && (PROCESSOR_ACCESS_VALUE & RPU_TZ_MASK) ;enable fault log for lock step ldr r0,=RPU_GLBL_CNTL ldr r1, [r0] ands r1, r1, #0x8 ;branch to initialization if split mode bne init ;check for boot mode if in lock step, branch to init if JTAG boot mode ldr r0,=BOOT_MODE_USER ldr r1, [r0] ands r1, r1, #0xF beq init ;reset the debug logic ldr r0,=RST_LPD_DBG ldr r1, [r0] orr r1, r1, #(0x1 << 4) orr r1, r1, #(0x1 << 5) str r1, [r0] ;enable fault log ldr r0,=RPU_ERR_INJ ldr r1,=fault_log_enable ldr r2, [r0] orr r2, r2, r1 str r2, [r0] nop nop #endif init bl Init_MPU;Initialize MPU ;Enable Branch prediction mrc p15, 0, r0, c1, c0, 1 ;Read ACTLR bic r0, r0, #(0x1 << 17) ;Clear RSDIS bit 17 to enable return stack bic r0, r0, #(0x1 << 16) ;Clear BP bit 15 and BP bit 16: bic r0, r0, #(0x1 << 15) ;Normal operation, BP is taken from the global history table. orr r0, r0, #(0x1 << 14) ;Disable DBWR for errata 780125 mcr p15, 0, r0, c1, c0, 1 ;Write ACTLR ;Enable icahce and dcache mrc p15,0,r1,c1,c0,0 ldr r0, =0x1005 orr r1,r1,r0 dsb mcr p15,0,r1,c1,c0,0 ;Enable cache isb ;isb flush prefetch buffer ;Set vector table in TCM/LOVEC #ifndef VEC_TABLE_IN_OCM mrc p15, 0, r0, c1, c0, 0 mvn r1, #0x2000 and r0, r0, r1 mcr p15, 0, r0, c1, c0, 0 ;Check if processor is having access to RPU address space #if (PROCESSOR_ACCESS_VALUE & RPU_TZ_MASK) ;Clear VINITHI to enable LOVEC on reset #if XPAR_CPU_ID == 0 ldr r0, =RPU_0_CFG #else ldr r0, =RPU_1_CFG #endif ldr r1, [r0] bic r1, r1, #(0x1 << 2) str r1, [r0] #endif #endif ;enable asynchronous abort exception mrs r0, cpsr bic r0, r0, #0x100 msr cpsr_xsf, r0 bl _startup Ldone b Ldone ;Paranoia: we should never get here END ;@} End of "addtogroup r5_boot_code".

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,401

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/armclang/cpu_init.S

;/****************************************************************************** ;* Copyright (c) 2020 - 2021 Xilinx, Inc. All rights reserved. ;* SPDX-License-Identifier: MIT ;******************************************************************************/ ;/*****************************************************************************/ ;/** ;* @file cpu_init.S ;* ;* This file contains CPU specific initialization. Invoked from main CRT ;* ;* <pre> ;* MODIFICATION HISTORY: ;* ;* Ver Who Date Changes ;* ----- ------- -------- --------------------------------------------------- ;* 7.3 dp 06/25/20 Initial version for armclang ;* ;* </pre> ;* ;* @note ;* ;* None. ;* ******************************************************************************/ EXPORT __cpu_init AREA |.text|, CODE REQUIRE8 {TRUE} PRESERVE8 {TRUE} ENTRY __cpu_init ;Clear cp15 regs with unknown reset values mov r0, #0x0 mcr p15, 0, r0, c5, c0, 0 ;DFSR mcr p15, 0, r0, c5, c0, 1 ;IFSR mcr p15, 0, r0, c6, c0, 0 ;DFAR mcr p15, 0, r0, c6, c0, 2 ;IFAR mcr p15, 0, r0, c9, c13, 2 ;PMXEVCNTR mcr p15, 0, r0, c13, c0, 2 ;TPIDRURW mcr p15, 0, r0, c13, c0, 3 ;TPIDRURO ;Reset and start Cycle Counter mov r2, #0x80000000 ;clear overflow mcr p15, 0, r2, c9, c12, 3 mov r2, #0xd ;D, C, E mcr p15, 0, r2, c9, c12, 0 mov r2, #0x80000000 ;enable cycle counter mcr p15, 0, r2, c9, c12, 1 bx lr END

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

4,120

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/gcc/xil-crt0.S

/****************************************************************************** * Copyright (c) 2014 - 2022 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file xil-crt0.S * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 5.00 pkp 02/10/14 First release * 5.04 pkp 12/18/15 Initialized global constructor for C++ applications * 5.04 pkp 02/19/16 Added timer configuration using XTime_StartTimer API when * TTC3 is present * 6.4 asa 08/16/17 Added call to Xil_InitializeExistingMPURegConfig to * initialize the MPU configuration table with the MPU * configurations already set in Init_Mpu function. * 6.6 srm 10/18/17 Updated the timer configuration with XTime_StartTTCTimer. * Now the timer instance as specified by the user will be * started. * 7.2 mus 10/22/19 Defined RPU_TZ_MASK as #define instead of variable. * 7.2 sd 03/20/20 Add clocking support. * 7.7 adk 11/30/21 Added support for xiltimer library. * 8.0 mus 07/06/21 Added support for VERSAL NET * 8.0 mus 19/01/22 Existing bootcode is skipping call to __cpu_init for * R52, it's keeping PMU events disabled. Updated code * to fix it. * adk 09/08/22 When xiltimer is enabled don't call XTime_StartTimer() * API. * </pre> * ******************************************************************************/ #include "xparameters.h" #include "bspconfig.h" .file "xil-crt0.S" .section ".got2","aw" .align 2 /* * 0th bit of PROCESSOR_ACCESS_VALUE macro signifies trustzone * setting for RPU address space */ #define RPU_TZ_MASK 0x1 .text .Lsbss_start: .long __sbss_start .Lsbss_end: .long __sbss_end .Lbss_start: .long __bss_start__ .Lbss_end: .long __bss_end__ .Lstack: .long __stack .set RPU_0_PWRCTL, 0xFF9A0108 .set RPU_1_PWRCTL, 0xFF9A0208 .set MPIDR_AFF0, 0xFF .set PWRCTL_MASK, 0x1 .globl _startup _startup: bl __cpu_init /* Initialize the CPU first (BSP provides this) */ /* TODO: This logic needs to be updated for Cortex-R52 */ #ifndef XPAR_XILTIMER_ENABLED #if defined (ARMR52) bl XTime_StartTimer #else #if (PROCESSOR_ACCESS_VALUE & RPU_TZ_MASK) mrc p15, 0, r0, c0, c0, 5 /* Read MPIDR register */ ands r0, r0, #MPIDR_AFF0 /* Get affinity level 0 */ bne core1 ldr r10, =RPU_0_PWRCTL /* Load PWRCTRL address for core 0 */ b test_boot_status core1: ldr r10, =RPU_1_PWRCTL /* Load PWRCTRL address for core 1 */ test_boot_status: ldr r11, [r10] /* Read PWRCTRL register */ ands r11, r11, #PWRCTL_MASK /* Extract and test core's PWRCTRL */ /* if warm reset, skip the clearing of BSS and SBSS */ bne .Lenclbss #endif #endif #endif mov r0, #0 /* clear sbss */ ldr r1,.Lsbss_start /* calculate beginning of the SBSS */ ldr r2,.Lsbss_end /* calculate end of the SBSS */ .Lloop_sbss: cmp r1,r2 bge .Lenclsbss /* If no SBSS, no clearing required */ str r0, [r1], #4 b .Lloop_sbss .Lenclsbss: /* clear bss */ ldr r1,.Lbss_start /* calculate beginning of the BSS */ ldr r2,.Lbss_end /* calculate end of the BSS */ .Lloop_bss: cmp r1,r2 bge .Lenclbss /* If no BSS, no clearing required */ str r0, [r1], #4 b .Lloop_bss .Lenclbss: /* set stack pointer */ ldr r13,.Lstack /* stack address */ /* configure the timer if TTC is present */ #ifndef XPAR_XILTIMER_ENABLED #ifdef SLEEP_TIMER_BASEADDR bl XTime_StartTTCTimer #endif #endif bl Xil_InitializeExistingMPURegConfig /* Initialize MPU config */ /* run global constructors */ bl __libc_init_array /* make sure argc and argv are valid */ mov r0, #0 mov r1, #0 #ifdef XCLOCKING bl Xil_ClockInit #endif bl main /* Jump to main C code */ /* Cleanup global constructors */ bl __libc_fini_array bl exit .Lexit: /* should never get here */ b .Lexit .Lstart: .size _startup,.Lstart-_startup

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

3,753

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/gcc/asm_vectors.S

/****************************************************************************** * Copyright (c) 2014 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file asm_vectors.S * * This file contains the initial vector table for the Cortex R5 processor * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 5.00 pkp 02/10/14 Initial version * 6.0 mus 27/07/16 Added UndefinedException handler * 6.3 pkp 02/13/17 Added support for hard float * </pre> * ******************************************************************************/ .org 0 .text .globl _boot .globl _vector_table .globl FIQInterrupt .globl IRQInterrupt .globl SWInterrupt .globl DataAbortInterrupt .globl PrefetchAbortInterrupt .globl IRQHandler .globl prof_pc .section .vectors, "a" _vector_table: ldr pc,=_boot ldr pc,=Undefined ldr pc,=SVCHandler ldr pc,=PrefetchAbortHandler ldr pc,=DataAbortHandler NOP /* Placeholder for address exception vector*/ ldr pc,=IRQHandler ldr pc,=FIQHandler .text IRQHandler: /* IRQ vector handler */ stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code*/ #ifndef __SOFTFP__ vpush {d0-d7} /* Store floating point registers */ vmrs r1, FPSCR push {r1} vmrs r1, FPEXC push {r1} #endif bl IRQInterrupt /* IRQ vector */ #ifndef __SOFTFP__ pop {r1} /* Restore floating point registers */ vmsr FPEXC, r1 pop {r1} vmsr FPSCR, r1 vpop {d0-d7} #endif ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ subs pc, lr, #4 /* adjust return */ FIQHandler: /* FIQ vector handler */ stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code */ FIQLoop: bl FIQInterrupt /* FIQ vector */ ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ subs pc, lr, #4 /* adjust return */ Undefined: /* Undefined handler */ stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code */ ldr r0, =UndefinedExceptionAddr sub r1, lr, #4 str r1, [r0] /* Store address of instruction causing undefined exception */ bl UndefinedException /* UndefinedException: call C function here */ ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ movs pc, lr SVCHandler: /* SWI handler */ stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code */ tst r0, #0x20 /* check the T bit */ ldrneh r0, [lr,#-2] /* Thumb mode */ bicne r0, r0, #0xff00 /* Thumb mode */ ldreq r0, [lr,#-4] /* ARM mode */ biceq r0, r0, #0xff000000 /* ARM mode */ bl SWInterrupt /* SWInterrupt: call C function here */ ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ movs pc, lr /* adjust return */ DataAbortHandler: /* Data Abort handler */ stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code */ ldr r0, =DataAbortAddr sub r1, lr, #8 str r1, [r0] /* Stores instruction causing data abort */ bl DataAbortInterrupt /*DataAbortInterrupt :call C function here */ ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ subs pc, lr, #8 /* adjust return */ PrefetchAbortHandler: /* Prefetch Abort handler */ stmdb sp!,{r0-r3,r12,lr} /* state save from compiled code */ ldr r0, =PrefetchAbortAddr sub r1, lr, #4 str r1, [r0] /* Stores instruction causing prefetch abort */ bl PrefetchAbortInterrupt /* PrefetchAbortInterrupt: call C function here */ ldmia sp!,{r0-r3,r12,lr} /* state restore from compiled code */ subs pc, lr, #4 /* adjust return */ .end

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

13,665

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/gcc/boot.S

/****************************************************************************** * Copyright (c) 2014 - 2022 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file boot.S * * @addtogroup r5_boot_code Cortex R5 Processor Boot Code * @{ * <h2> boot.S </h2> * The boot.S file contains a minimal set of code for transferring control from the processor * reset location of the processor to the start of the application. * The boot code performs minimum configuration which is required for an * application to run starting from reset state of the processor. Below is a * sequence illustrating what all configuration is performed before control * reaches to main function. * * 1. Program vector table base for exception handling * 2. Program stack pointer for various modes (IRQ, FIQ, supervisor, undefine, * abort, system) * 3. Disable instruction cache, data cache and MPU * 4. Invalidate instruction and data cache * 5. Configure MPU with short descriptor translation table format and program * base address of translation table * 6. Enable data cache, instruction cache and MPU * 7. Enable Floating point unit * 8. Transfer control to _start which clears BSS sections and jumping to main * application * * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ---- -------- --------------------------------------------------- * 5.00 pkp 02/10/14 Initial version * 5.04 pkp 09/11/15 Disabled ACTLR.DBWR bit to avoid potential R5 deadlock * for errata 780125 * 5.04 pkp 02/04/16 Enabled the fault log for lock-step mode * 5.04 pkp 02/25/16 Initialized the banked registers for various modes, * initialized floating point registers and enabled the * cache ECC check before enabling the fault log for * lock step mode * 5.04 pkp 03/24/16 Reset the dbg_lpd_reset before enabling the fault log * to avoid intervention for lock-step mode * 5.05 pkp 04/11/16 Enable the comparators for non-JTAG boot mode for * lock-step to avoid putting debug logic to reset * 6.02 pkp 02/13/17 Added support for hard float * 6.6 mus 02/23/17 Enable/Disable the debug logic in non-JTAG boot mode(when * processor is in lockstep configuration), based * on the mld parameter "lockstep_mode_debug". * 6.8 mus 09/20/18 Clear VINITHI field in RPU_0_CFG/RPU_1_CFG * registers to initialize CortexR5 core with LOVEC * on reset. It fixes CR#1010656. * 7.1 mus 03/27/19 Skip reading/writing to the RPU address space registers, * in case if processor is nonsecure and RPU * address space is secure. CR#1015725. * 7.2 mus 10/11/19 Resetting the r5_0 and r5_1 debug logic is sufficient * to avoid intervention for lock-step mode. So, removed * code which resets dbg_lpd_reset, to unblock debugger * access to LPD. Fix for CR#1027983. * 7.7 mus 11/26/21 Added call to Print_DDRSize_Warning after MPU enablement * to print warning related to DDR size if it is not in * power of 2. It fixes CR#1116431. * 8.0 mus 07/06/21 Added support for VERSAL NET * </pre> * ******************************************************************************/ #include "xparameters.h" .global _prestart .global _boot .global __stack .global __irq_stack .global __supervisor_stack .global __abort_stack .global __fiq_stack .global __undef_stack .global _vector_table /* Stack Pointer locations for boot code */ .set Undef_stack, __undef_stack .set FIQ_stack, __fiq_stack .set Abort_stack, __abort_stack .set SPV_stack, __supervisor_stack .set IRQ_stack, __irq_stack .set SYS_stack, __stack .set vector_base, _vector_table .set RPU_GLBL_CNTL, 0xFF9A0000 .set RPU_ERR_INJ, 0xFF9A0020 .set RPU_0_CFG, 0xFF9A0100 .set RPU_1_CFG, 0xFF9A0200 #if defined(versal) .set RST_LPD_DBG, 0xFF5E0338 .set BOOT_MODE_USER, 0xF1260200 #else .set RST_LPD_DBG, 0xFF5E0240 .set BOOT_MODE_USER, 0xFF5E0200 #endif .set fault_log_enable, 0x101 #if defined (ARMR52) .set counterfreq, XPAR_CPU_CORTEXR52_0_TIMESTAMP_CLK_FREQ #endif /* * 0th bit of PROCESSOR_ACCESS_VALUE macro signifies trustzone * setting for RPU address space */ #define RPU_TZ_MASK 0x1 .section .boot,"axS" /* this initializes the various processor modes */ _prestart: _boot: OKToRun: #if defined (ARMR52) mrs r0, cpsr bfi r1, r0, #0, #5 cmp r1, #0x1A /* Check if it is HYP mode */ bne InitEL1 ldr r0, =_vector_table mcr p15, 4, r0, c12, c0, 0 /* Write HVBAR */ #endif /* Initialize processor registers to 0 */ mov r0,#0 mov r1,#0 mov r2,#0 mov r3,#0 mov r4,#0 mov r5,#0 mov r6,#0 mov r7,#0 mov r8,#0 mov r9,#0 mov r10,#0 mov r11,#0 mov r12,#0 #if defined (ARMR52) /* Set counter frequency, CNTFRQ: RW from EL2 RO from EL1 */ ldr r0,=counterfreq /* 800 KHZ TODO: change it based on HW design through XPARS */ mcr 15,0,r0,c14,c0,0 /* Write CNTFRQ */ /* Change EL1 exception base address */ ldr r0, =_vector_table mcr p15, 0, r0, c12, c0, 0 /* Write VBAR */ /* Switch to EL1 SVC mode */ mrs r0, cpsr mov r1, #0x13 /* Mode SVC */ bfi r0, r1, #0, #5 msr spsr, r0 ldr r0, =InitEL1 msr elr_hyp, r0 dsb isb eret InitEL1: #endif /* Initialize stack pointer and banked registers for various mode */ mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the irq stack pointer */ and r2, r1, r0 orr r2, r2, #0x12 /* IRQ mode */ msr cpsr, r2 ldr r13,=IRQ_stack /* IRQ stack pointer */ mov r14,#0 mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the supervisor stack pointer */ and r2, r1, r0 orr r2, r2, #0x13 /* supervisor mode */ msr cpsr, r2 ldr r13,=SPV_stack /* Supervisor stack pointer */ mov r14,#0 mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the Abort stack pointer */ and r2, r1, r0 orr r2, r2, #0x17 /* Abort mode */ msr cpsr, r2 ldr r13,=Abort_stack /* Abort stack pointer */ mov r14,#0 mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the FIQ stack pointer */ and r2, r1, r0 orr r2, r2, #0x11 /* FIQ mode */ msr cpsr, r2 mov r8, #0 mov r9, #0 mov r10, #0 mov r11, #0 mov r12, #0 ldr r13,=FIQ_stack /* FIQ stack pointer */ mov r14,#0 mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the Undefine stack pointer */ and r2, r1, r0 orr r2, r2, #0x1b /* Undefine mode */ msr cpsr, r2 ldr r13,=Undef_stack /* Undefine stack pointer */ mov r14,#0 mrs r0, cpsr /* get the current PSR */ mvn r1, #0x1f /* set up the system stack pointer */ and r2, r1, r0 orr r2, r2, #0x1F /* SYS mode */ msr cpsr, r2 ldr r13,=SYS_stack /* SYS stack pointer */ mov r14,#0 /* * Enable access to VFP by enabling access to Coprocessors 10 and 11. * Enables Full Access i.e. in both privileged and non privileged modes */ mrc p15, 0, r0, c1, c0, 2 /* Read Coprocessor Access Control Register (CPACR) */ orr r0, r0, #(0xF << 20) /* Enable access to CP 10 & 11 */ mcr p15, 0, r0, c1, c0, 2 /* Write Coprocessor Access Control Register (CPACR) */ isb /* enable fpu access */ vmrs r3, FPEXC orr r1, r3, #(1<<30) vmsr FPEXC, r1 /* clear the floating point register*/ mov r1,#0 vmov d0,r1,r1 vmov d1,r1,r1 vmov d2,r1,r1 vmov d3,r1,r1 vmov d4,r1,r1 vmov d5,r1,r1 vmov d6,r1,r1 vmov d7,r1,r1 vmov d8,r1,r1 vmov d9,r1,r1 vmov d10,r1,r1 vmov d11,r1,r1 vmov d12,r1,r1 vmov d13,r1,r1 vmov d14,r1,r1 vmov d15,r1,r1 #ifdef __SOFTFP__ /* Disable the FPU if SOFTFP is defined*/ vmsr FPEXC,r3 #endif /* Disable MPU and caches */ mrc p15, 0, r0, c1, c0, 0 /* Read CP15 Control Register*/ bic r0, r0, #0x05 /* Disable MPU (M bit) and data cache (C bit) */ bic r0, r0, #0x1000 /* Disable instruction cache (I bit) */ dsb /* Ensure all previous loads/stores have completed */ mcr p15, 0, r0, c1, c0, 0 /* Write CP15 Control Register */ isb /* Ensure subsequent insts execute wrt new MPU settings */ #if defined (ARMR52) /* TODO: revisit to check whether fault log handling like Cortex-R5 is needed */ /* Enable ECC checks */ mrc p15, 1, r0, c9, c1, 2 /* Read IMP_MEMPROTCTLR */ /* disable TCM ECC */ bic r0, r0, #(0x1 << 0) /* disable TCM and L1 cache ECC */ mcr p15, 1, r0, c9, c1, 2 /* Write IMP_MEMPROTCTLR */ /* Disable branch prediction */ mrc p15, 1, r0, c9, c1, 1 /* Read IMP_BPCTLR */ orr r0, r0, #(0x1 << 1) /* Disable branch prediction */ mcr p15, 1, r0, c9, c1, 1 /* Write IMP_BPCTLR */ /* Set attributes index for normal and device memory in MAIR0 */ MRC p15, 0, r0, c10, c2, 0 /* Read MAIR0 */ LDR r1, =0xBB /* Attribute index0: Normal inner/outer RW cacheable, write-through */ BFI r0, r1, #0, #8 /* Update attribute index0 */ LDR r1, =0x04 /* Attribute index1: Device nGnRnE */ BFI r0, r1, #8, #8 /* Update Attribute index1 */ LDR r1, =0x44 /* Attribute index1: Normal non cacheable */ BFI r0, r1, #16, #8 /* Update Attribute index2 */ MCR p15,0,r0,c10,c2,0 /* Write MAIR0 */ #else /* Disable Branch prediction, TCM ECC checks */ mrc p15, 0, r0, c1, c0, 1 /* Read ACTLR */ orr r0, r0, #(0x1 << 17) /* Enable RSDIS bit 17 to disable the return stack */ orr r0, r0, #(0x1 << 16) /* Clear BP bit 15 and set BP bit 16:*/ bic r0, r0, #(0x1 << 15) /* Branch always not taken and history table updates disabled*/ orr r0, r0, #(0x1 << 27) /* Enable B1TCM ECC check */ orr r0, r0, #(0x1 << 26) /* Enable B0TCM ECC check */ orr r0, r0, #(0x1 << 25) /* Enable ATCM ECC check */ bic r0, r0, #(0x1 << 5) /* Generate abort on parity errors, with [5:3]=b 000*/ bic r0, r0, #(0x1 << 4) bic r0, r0, #(0x1 << 3) mcr p15, 0, r0, c1, c0, 1 /* Write ACTLR*/ dsb /* Complete all outstanding explicit memory operations*/ /* Invalidate caches */ mov r0,#0 /* r0 = 0 */ dsb mcr p15, 0, r0, c7, c5, 0 /* invalidate icache */ mcr p15, 0, r0, c15, c5, 0 /* Invalidate entire data cache*/ isb #if LOCKSTEP_MODE_DEBUG == 0 && (PROCESSOR_ACCESS_VALUE & RPU_TZ_MASK) /* enable fault log for lock step */ ldr r0,=RPU_GLBL_CNTL ldr r1, [r0] ands r1, r1, #0x8 /* branch to initialization if split mode*/ bne init /* check for boot mode if in lock step, branch to init if JTAG boot mode*/ ldr r0,=BOOT_MODE_USER ldr r1, [r0] ands r1, r1, #0xF beq init /* reset the debug logic */ ldr r0,=RST_LPD_DBG ldr r1, [r0] orr r1, r1, #(0x1 << 4) orr r1, r1, #(0x1 << 5) str r1, [r0] /* enable fault log */ ldr r0,=RPU_ERR_INJ ldr r1,=fault_log_enable ldr r2, [r0] orr r2, r2, r1 str r2, [r0] nop nop #endif #endif init: bl Init_MPU /* Initialize MPU */ #if defined (ARMR52) /* Enable Branch prediction */ mrc p15, 1, r0, c9, c1, 1 /* Read IMP_BPCTLR */ bic r0, r0, #(0x1 << 1) /* Enable branch prediction */ mcr p15, 1, r0, c9, c1, 1 /* Write IMP_BPCTLR */ mrc p15, 0, r1, c1, c0, 0 /* Read System Control Register */ ldr r0, =0x1005 /* Set M bit to enable MPU, C & I bit for data and instruction caches */ orr r1,r1,r0 dsb /* Ensure all previous loads/stores have completed */ mcr p15, 0, r0, c1, c0, 0 /* Write System Control Register */ isb #else /* Enable Branch prediction */ mrc p15, 0, r0, c1, c0, 1 /* Read ACTLR*/ bic r0, r0, #(0x1 << 17) /* Clear RSDIS bit 17 to enable return stack*/ bic r0, r0, #(0x1 << 16) /* Clear BP bit 15 and BP bit 16:*/ bic r0, r0, #(0x1 << 15) /* Normal operation, BP is taken from the global history table.*/ orr r0, r0, #(0x1 << 14) /* Disable DBWR for errata 780125 */ mcr p15, 0, r0, c1, c0, 1 /* Write ACTLR*/ /* Enable icahce and dcache */ mrc p15,0,r1,c1,c0,0 ldr r0, =0x1005 orr r1,r1,r0 dsb mcr p15,0,r1,c1,c0,0 /* Enable cache */ isb /* isb flush prefetch buffer */ #ifndef versal bl Print_DDRSize_Warning #endif /* Warning message to be removed after 2016.1 */ /* USEAMP was introduced in 2015.4 with ZynqMP and caused confusion with USE_AMP */ #ifdef USEAMP #warning "-DUSEAMP=1 is deprecated, use -DVEC_TABLE_IN_OCM instead to set vector table in OCM" #endif /* Set vector table in TCM/LOVEC */ #ifndef VEC_TABLE_IN_OCM mrc p15, 0, r0, c1, c0, 0 mvn r1, #0x2000 and r0, r0, r1 mcr p15, 0, r0, c1, c0, 0 /* Check if processor is having access to RPU address space */ #if (PROCESSOR_ACCESS_VALUE & RPU_TZ_MASK) /* Clear VINITHI to enable LOVEC on reset */ #if XPAR_CPU_ID == 0 ldr r0, =RPU_0_CFG #else ldr r0, =RPU_1_CFG #endif ldr r1, [r0] bic r1, r1, #(0x1 << 2) str r1, [r0] #endif #endif #endif /* enable asynchronous abort exception */ mrs r0, cpsr bic r0, r0, #0x100 msr cpsr_xsf, r0 b _startup /* jump to C startup code */ .Ldone: b .Ldone /* Paranoia: we should never get here */ .end /** * @} End of "addtogroup r5_boot_code". */

yavuztackin/Zybo_Z20_Vitis_LEDBlink-HelloWorldUART-Examples

1,359

leddeneme/microblaze_0/standalone_domain/bsp/microblaze_0/libsrc/standalone_v8_0/src/arm/cortexr5/gcc/cpu_init.S

/****************************************************************************** * Copyright (c) 2014 - 2021 Xilinx, Inc. All rights reserved. * SPDX-License-Identifier: MIT ******************************************************************************/ /*****************************************************************************/ /** * @file cpu_init.S * * This file contains CPU specific initialization. Invoked from main CRT * * <pre> * MODIFICATION HISTORY: * * Ver Who Date Changes * ----- ------- -------- --------------------------------------------------- * 5.00 pkp 02/10/14 Initial version * * </pre> * ******************************************************************************/ .text .global __cpu_init .align 2 __cpu_init: /* Clear cp15 regs with unknown reset values */ mov r0, #0x0 mcr p15, 0, r0, c5, c0, 0 /* DFSR */ mcr p15, 0, r0, c5, c0, 1 /* IFSR */ mcr p15, 0, r0, c6, c0, 0 /* DFAR */ mcr p15, 0, r0, c6, c0, 2 /* IFAR */ mcr p15, 0, r0, c9, c13, 2 /* PMXEVCNTR */ mcr p15, 0, r0, c13, c0, 2 /* TPIDRURW */ mcr p15, 0, r0, c13, c0, 3 /* TPIDRURO */ /* Reset and start Cycle Counter */ mov r2, #0x80000000 /* clear overflow */ mcr p15, 0, r2, c9, c12, 3 mov r2, #0xd /* D, C, E */ mcr p15, 0, r2, c9, c12, 0 mov r2, #0x80000000 /* enable cycle counter */ mcr p15, 0, r2, c9, c12, 1 bx lr .end

yjymosheng/arceos-app-support

1,741

arceos/modules/axhal/linker.lds.S

OUTPUT_ARCH(%ARCH%) BASE_ADDRESS = %KERNEL_BASE%; ENTRY(_start) SECTIONS { . = BASE_ADDRESS; _skernel = .; .text : ALIGN(4K) { _stext = .; *(.text.boot) *(.text .text.*) . = ALIGN(4K); _etext = .; } .rodata : ALIGN(4K) { _srodata = .; *(.rodata .rodata.*) *(.srodata .srodata.*) *(.sdata2 .sdata2.*) . = ALIGN(4K); _erodata = .; } .data : ALIGN(4K) { _sdata = .; *(.data.boot_page_table) . = ALIGN(4K); *(.data .data.*) *(.sdata .sdata.*) *(.got .got.*) } .tdata : ALIGN(0x10) { _stdata = .; *(.tdata .tdata.*) _etdata = .; } .tbss : ALIGN(0x10) { _stbss = .; *(.tbss .tbss.*) *(.tcommon) _etbss = .; } . = ALIGN(4K); _percpu_start = .; _percpu_end = _percpu_start + SIZEOF(.percpu); .percpu 0x0 : AT(_percpu_start) { _percpu_load_start = .; *(.percpu .percpu.*) _percpu_load_end = .; . = _percpu_load_start + ALIGN(64) * %SMP%; } . = _percpu_end; . = ALIGN(4K); _edata = .; .bss : ALIGN(4K) { boot_stack = .; *(.bss.stack) . = ALIGN(4K); boot_stack_top = .; _sbss = .; *(.bss .bss.*) *(.sbss .sbss.*) *(COMMON) . = ALIGN(4K); _ebss = .; } _ekernel = .; /DISCARD/ : { *(.comment) *(.gnu*) *(.note*) *(.eh_frame*) } } SECTIONS { linkme_IRQ : { *(linkme_IRQ) } linkm2_IRQ : { *(linkm2_IRQ) } linkme_PAGE_FAULT : { *(linkme_PAGE_FAULT) } linkm2_PAGE_FAULT : { *(linkm2_PAGE_FAULT) } } INSERT AFTER .tbss;

yjymosheng/arceos-app-support

4,307

arceos/modules/axhal/src/platform/x86_pc/multiboot.S

# Bootstrapping from 32-bit with the Multiboot specification. # See https://www.gnu.org/software/grub/manual/multiboot/multiboot.html .section .text.boot .code32 .global _start _start: mov edi, eax # arg1: magic: 0x2BADB002 mov esi, ebx # arg2: multiboot info jmp bsp_entry32 .balign 4 .type multiboot_header, STT_OBJECT multiboot_header: .int {mb_hdr_magic} # magic: 0x1BADB002 .int {mb_hdr_flags} # flags .int -({mb_hdr_magic} + {mb_hdr_flags}) # checksum .int multiboot_header - {offset} # header_addr .int _skernel - {offset} # load_addr .int _edata - {offset} # load_end .int _ebss - {offset} # bss_end_addr .int _start - {offset} # entry_addr # Common code in 32-bit, prepare states to enter 64-bit. .macro ENTRY32_COMMON # set data segment selectors mov ax, 0x18 mov ss, ax mov ds, ax mov es, ax mov fs, ax mov gs, ax # set PAE, PGE bit in CR4 mov eax, {cr4} mov cr4, eax # load the temporary page table lea eax, [.Ltmp_pml4 - {offset}] mov cr3, eax # set LME, NXE bit in IA32_EFER mov ecx, {efer_msr} mov edx, 0 mov eax, {efer} wrmsr # set protected mode, write protect, paging bit in CR0 mov eax, {cr0} mov cr0, eax .endm # Common code in 64-bit .macro ENTRY64_COMMON # clear segment selectors xor ax, ax mov ss, ax mov ds, ax mov es, ax mov fs, ax mov gs, ax .endm .code32 bsp_entry32: lgdt [.Ltmp_gdt_desc - {offset}] # load the temporary GDT ENTRY32_COMMON ljmp 0x10, offset bsp_entry64 - {offset} # 0x10 is code64 segment .code32 .global ap_entry32 ap_entry32: ENTRY32_COMMON ljmp 0x10, offset ap_entry64 - {offset} # 0x10 is code64 segment .code64 bsp_entry64: ENTRY64_COMMON # set RSP to boot stack movabs rsp, offset {boot_stack} add rsp, {boot_stack_size} # call rust_entry(magic, mbi) movabs rax, offset {entry} call rax jmp .Lhlt .code64 ap_entry64: ENTRY64_COMMON # set RSP to high address (already set in ap_start.S) mov rax, {offset} add rsp, rax # call rust_entry_secondary(magic) mov rdi, {mb_magic} movabs rax, offset {entry_secondary} call rax jmp .Lhlt .Lhlt: hlt jmp .Lhlt .section .rodata .balign 8 .Ltmp_gdt_desc: .short .Ltmp_gdt_end - .Ltmp_gdt - 1 # limit .long .Ltmp_gdt - {offset} # base .section .data .balign 16 .Ltmp_gdt: .quad 0x0000000000000000 # 0x00: null .quad 0x00cf9b000000ffff # 0x08: code segment (base=0, limit=0xfffff, type=32bit code exec/read, DPL=0, 4k) .quad 0x00af9b000000ffff # 0x10: code segment (base=0, limit=0xfffff, type=64bit code exec/read, DPL=0, 4k) .quad 0x00cf93000000ffff # 0x18: data segment (base=0, limit=0xfffff, type=32bit data read/write, DPL=0, 4k) .Ltmp_gdt_end: .balign 4096 .Ltmp_pml4: # 0x0000_0000 ~ 0xffff_ffff .quad .Ltmp_pdpt_low - {offset} + 0x3 # PRESENT | WRITABLE | paddr(tmp_pdpt) .zero 8 * 510 # 0xffff_ff80_0000_0000 ~ 0xffff_ff80_ffff_ffff .quad .Ltmp_pdpt_high - {offset} + 0x3 # PRESENT | WRITABLE | paddr(tmp_pdpt) # FIXME: may not work on macOS using hvf as the CPU does not support 1GB page (pdpe1gb) .Ltmp_pdpt_low: .quad 0x0000 | 0x83 # PRESENT | WRITABLE | HUGE_PAGE | paddr(0x0) .quad 0x40000000 | 0x83 # PRESENT | WRITABLE | HUGE_PAGE | paddr(0x4000_0000) .quad 0x80000000 | 0x83 # PRESENT | WRITABLE | HUGE_PAGE | paddr(0x8000_0000) .quad 0xc0000000 | 0x83 # PRESENT | WRITABLE | HUGE_PAGE | paddr(0xc000_0000) .zero 8 * 508 .Ltmp_pdpt_high: .quad 0x0000 | 0x83 # PRESENT | WRITABLE | HUGE_PAGE | paddr(0x0) .quad 0x40000000 | 0x83 # PRESENT | WRITABLE | HUGE_PAGE | paddr(0x4000_0000) .quad 0x80000000 | 0x83 # PRESENT | WRITABLE | HUGE_PAGE | paddr(0x8000_0000) .quad 0xc0000000 | 0x83 # PRESENT | WRITABLE | HUGE_PAGE | paddr(0xc000_0000) .zero 8 * 508

yjymosheng/arceos-app-support

1,965

arceos/modules/axhal/src/platform/x86_pc/ap_start.S

# Boot application processors into the protected mode. # Each non-boot CPU ("AP") is started up in response to a STARTUP # IPI from the boot CPU. Section B.4.2 of the Multi-Processor # Specification says that the AP will start in real mode with CS:IP # set to XY00:0000, where XY is an 8-bit value sent with the # STARTUP. Thus this code must start at a 4096-byte boundary. # # Because this code sets DS to zero, it must sit # at an address in the low 2^16 bytes. .equ pa_ap_start32, ap_start32 - ap_start + {start_page_paddr} .equ pa_ap_gdt, .Lap_tmp_gdt - ap_start + {start_page_paddr} .equ pa_ap_gdt_desc, .Lap_tmp_gdt_desc - ap_start + {start_page_paddr} .equ stack_ptr, {start_page_paddr} + 0xff0 .equ entry_ptr, {start_page_paddr} + 0xff8 # 0x6000 .section .text .code16 .p2align 12 .global ap_start ap_start: cli wbinvd xor ax, ax mov ds, ax mov es, ax mov ss, ax mov fs, ax mov gs, ax # load the 64-bit GDT lgdt [pa_ap_gdt_desc] # switch to protected-mode mov eax, cr0 or eax, (1 << 0) mov cr0, eax # far jump to 32-bit code. 0x8 is code32 segment selector ljmp 0x8, offset pa_ap_start32 .code32 ap_start32: mov esp, [stack_ptr] mov eax, [entry_ptr] jmp eax .balign 8 # .type multiboot_header, STT_OBJECT .Lap_tmp_gdt_desc: .short .Lap_tmp_gdt_end - .Lap_tmp_gdt - 1 # limit .long pa_ap_gdt # base .balign 16 .Lap_tmp_gdt: .quad 0x0000000000000000 # 0x00: null .quad 0x00cf9b000000ffff # 0x08: code segment (base=0, limit=0xfffff, type=32bit code exec/read, DPL=0, 4k) .quad 0x00af9b000000ffff # 0x10: code segment (base=0, limit=0xfffff, type=64bit code exec/read, DPL=0, 4k) .quad 0x00cf93000000ffff # 0x18: data segment (base=0, limit=0xfffff, type=32bit data read/write, DPL=0, 4k) .Lap_tmp_gdt_end: # 0x7000 .p2align 12 .global ap_end ap_end:

yjymosheng/arceos-app-support

1,672

arceos/modules/axhal/src/arch/riscv/trap.S

.macro SAVE_REGS, from_user addi sp, sp, -{trapframe_size} PUSH_GENERAL_REGS csrr t0, sepc csrr t1, sstatus csrrw t2, sscratch, zero // save sscratch (sp) and zero it STR t0, sp, 31 // tf.sepc STR t1, sp, 32 // tf.sstatus STR t2, sp, 1 // tf.regs.sp .if \from_user == 1 LDR t0, sp, 3 // load supervisor tp STR gp, sp, 2 // save user gp and tp STR tp, sp, 3 mv tp, t0 .endif .endm .macro RESTORE_REGS, from_user .if \from_user == 1 LDR gp, sp, 2 // load user gp and tp LDR t0, sp, 3 STR tp, sp, 3 // save supervisor tp mv tp, t0 addi t0, sp, {trapframe_size} // put supervisor sp to scratch csrw sscratch, t0 .endif LDR t0, sp, 31 LDR t1, sp, 32 csrw sepc, t0 csrw sstatus, t1 POP_GENERAL_REGS LDR sp, sp, 1 // load sp from tf.regs.sp .endm .section .text .balign 4 .global trap_vector_base trap_vector_base: // sscratch == 0: trap from S mode // sscratch != 0: trap from U mode csrrw sp, sscratch, sp // switch sscratch and sp bnez sp, .Ltrap_entry_u csrr sp, sscratch // put supervisor sp back j .Ltrap_entry_s .Ltrap_entry_s: SAVE_REGS 0 mv a0, sp li a1, 0 call riscv_trap_handler RESTORE_REGS 0 sret .Ltrap_entry_u: SAVE_REGS 1 mv a0, sp li a1, 1 call riscv_trap_handler RESTORE_REGS 1 sret

yjymosheng/arceos-app-support

1,505

arceos/modules/axhal/src/arch/x86_64/trap.S

.equ NUM_INT, 256 .altmacro .macro DEF_HANDLER, i .Ltrap_handler_\i: .if \i == 8 || (\i >= 10 && \i <= 14) || \i == 17 # error code pushed by CPU push \i # interrupt vector jmp .Ltrap_common .else push 0 # fill in error code in TrapFrame push \i # interrupt vector jmp .Ltrap_common .endif .endm .macro DEF_TABLE_ENTRY, i .quad .Ltrap_handler_\i .endm .section .text .code64 _trap_handlers: .set i, 0 .rept NUM_INT DEF_HANDLER %i .set i, i + 1 .endr .Ltrap_common: test byte ptr [rsp + 3 * 8], 3 # swap GS if it comes from user space jz 1f swapgs 1: push r15 push r14 push r13 push r12 push r11 push r10 push r9 push r8 push rdi push rsi push rbp push rbx push rdx push rcx push rax mov rdi, rsp call x86_trap_handler pop rax pop rcx pop rdx pop rbx pop rbp pop rsi pop rdi pop r8 pop r9 pop r10 pop r11 pop r12 pop r13 pop r14 pop r15 test byte ptr [rsp + 3 * 8], 3 # swap GS back if return to user space jz 2f swapgs 2: add rsp, 16 # pop vector, error_code iretq .section .rodata .global trap_handler_table trap_handler_table: .set i, 0 .rept NUM_INT DEF_TABLE_ENTRY %i .set i, i + 1 .endr

yjymosheng/arceos-app-support

2,415

arceos/modules/axhal/src/arch/aarch64/trap.S

.macro SAVE_REGS sub sp, sp, 34 * 8 stp x0, x1, [sp] stp x2, x3, [sp, 2 * 8] stp x4, x5, [sp, 4 * 8] stp x6, x7, [sp, 6 * 8] stp x8, x9, [sp, 8 * 8] stp x10, x11, [sp, 10 * 8] stp x12, x13, [sp, 12 * 8] stp x14, x15, [sp, 14 * 8] stp x16, x17, [sp, 16 * 8] stp x18, x19, [sp, 18 * 8] stp x20, x21, [sp, 20 * 8] stp x22, x23, [sp, 22 * 8] stp x24, x25, [sp, 24 * 8] stp x26, x27, [sp, 26 * 8] stp x28, x29, [sp, 28 * 8] mrs x9, sp_el0 mrs x10, elr_el1 mrs x11, spsr_el1 stp x30, x9, [sp, 30 * 8] stp x10, x11, [sp, 32 * 8] .endm .macro RESTORE_REGS ldp x10, x11, [sp, 32 * 8] ldp x30, x9, [sp, 30 * 8] msr sp_el0, x9 msr elr_el1, x10 msr spsr_el1, x11 ldp x28, x29, [sp, 28 * 8] ldp x26, x27, [sp, 26 * 8] ldp x24, x25, [sp, 24 * 8] ldp x22, x23, [sp, 22 * 8] ldp x20, x21, [sp, 20 * 8] ldp x18, x19, [sp, 18 * 8] ldp x16, x17, [sp, 16 * 8] ldp x14, x15, [sp, 14 * 8] ldp x12, x13, [sp, 12 * 8] ldp x10, x11, [sp, 10 * 8] ldp x8, x9, [sp, 8 * 8] ldp x6, x7, [sp, 6 * 8] ldp x4, x5, [sp, 4 * 8] ldp x2, x3, [sp, 2 * 8] ldp x0, x1, [sp] add sp, sp, 34 * 8 .endm .macro INVALID_EXCP, kind, source .p2align 7 SAVE_REGS mov x0, sp mov x1, \kind mov x2, \source bl invalid_exception b .Lexception_return .endm .macro HANDLE_SYNC .p2align 7 SAVE_REGS mov x0, sp bl handle_sync_exception b .Lexception_return .endm .macro HANDLE_IRQ .p2align 7 SAVE_REGS mov x0, sp bl handle_irq_exception b .Lexception_return .endm .section .text .p2align 11 .global exception_vector_base exception_vector_base: // current EL, with SP_EL0 INVALID_EXCP 0 0 INVALID_EXCP 1 0 INVALID_EXCP 2 0 INVALID_EXCP 3 0 // current EL, with SP_ELx HANDLE_SYNC HANDLE_IRQ INVALID_EXCP 2 1 INVALID_EXCP 3 1 // lower EL, aarch64 HANDLE_SYNC HANDLE_IRQ INVALID_EXCP 2 2 INVALID_EXCP 3 2 // lower EL, aarch32 INVALID_EXCP 0 3 INVALID_EXCP 1 3 INVALID_EXCP 2 3 INVALID_EXCP 3 3 .Lexception_return: RESTORE_REGS eret

yjymosheng/arceos-app-support

2,544

arceos/tools/raspi4/chainloader/src/_arch/aarch64/cpu/boot.s

// SPDX-License-Identifier: MIT OR Apache-2.0 // // Copyright (c) 2021-2022 Andre Richter <andre.o.richter@gmail.com> //-------------------------------------------------------------------------------------------------- // Definitions //-------------------------------------------------------------------------------------------------- // Load the address of a symbol into a register, PC-relative. // // The symbol must lie within +/- 4 GiB of the Program Counter. // // # Resources // // - https://sourceware.org/binutils/docs-2.36/as/AArch64_002dRelocations.html .macro ADR_REL register, symbol adrp \register, \symbol add \register, \register, #:lo12:\symbol .endm // Load the address of a symbol into a register, absolute. // // # Resources // // - https://sourceware.org/binutils/docs-2.36/as/AArch64_002dRelocations.html .macro ADR_ABS register, symbol movz \register, #:abs_g2:\symbol movk \register, #:abs_g1_nc:\symbol movk \register, #:abs_g0_nc:\symbol .endm //-------------------------------------------------------------------------------------------------- // Public Code //-------------------------------------------------------------------------------------------------- .section .text._start //------------------------------------------------------------------------------ // fn _start() //------------------------------------------------------------------------------ _start: // Only proceed on the boot core. Park it otherwise. mrs x0, MPIDR_EL1 and x0, x0, {CONST_CORE_ID_MASK} ldr x1, BOOT_CORE_ID // provided by bsp/__board_name__/cpu.rs cmp x0, x1 b.ne .L_parking_loop // If execution reaches here, it is the boot core. // Initialize DRAM. ADR_ABS x0, __bss_start ADR_ABS x1, __bss_end_exclusive .L_bss_init_loop: cmp x0, x1 b.eq .L_relocate_binary stp xzr, xzr, [x0], #16 b .L_bss_init_loop // Next, relocate the binary. .L_relocate_binary: ADR_REL x0, __binary_nonzero_start // The address the binary got loaded to. ADR_ABS x1, __binary_nonzero_start // The address the binary was linked to. ADR_ABS x2, __binary_nonzero_end_exclusive .L_copy_loop: ldr x3, [x0], #8 str x3, [x1], #8 cmp x1, x2 b.lo .L_copy_loop // Prepare the jump to Rust code. // Set the stack pointer. ADR_ABS x0, __boot_core_stack_end_exclusive mov sp, x0 // Jump to the relocated Rust code. ADR_ABS x1, _start_rust br x1 // Infinitely wait for events (aka "park the core"). .L_parking_loop: wfe b .L_parking_loop .size _start, . - _start .type _start, function .global _start

ynutsgroup/coreflow

1,488

utils/sync_env.s

#!/bin/bash # /opt/coreflow/utils/sync_env.sh # 🔐 Sync .env & .env.key Linux → Windows via SCP (passwordless) # === KONFIGURATION === WIN_USER="${WIN_USER:-Administrator}" WIN_IP="${WIN_IP:-192.168.178.20}" WIN_PATH="${WIN_PATH:-/c:/CoreFlow/}" LINUX_ENV_PATH="${LINUX_ENV_PATH:-/opt/coreflow/}" SSH_KEY="${SSH_KEY:-/home/coreadmin/.ssh/id_rsa_sync}" # === LOGGING === log() { echo "$(date '+%Y-%m-%d %H:%M:%S') | $1" } # === VORBEDINGUNGEN === check_prerequisites() { if [ ! -d "$LINUX_ENV_PATH" ]; then log "❌ Quellverzeichnis fehlt: $LINUX_ENV_PATH" exit 1 fi if [ ! -f "$SSH_KEY" ]; then log "❌ SSH Key fehlt: $SSH_KEY" exit 1 fi for file in .env .env.key; do if [ ! -f "$LINUX_ENV_PATH/$file" ]; then log "❌ Datei fehlt: $file" exit 1 fi done } # === BACKUP === create_backups() { cd "$LINUX_ENV_PATH" || exit 1 for file in .env .env.key; do cp "$file" "$file.bak" && log "📦 Backup erstellt: $file.bak" done } # === SYNC === sync_files() { cd "$LINUX_ENV_PATH" || exit 1 for file in .env .env.key; do log "🔄 Sync $file → $WIN_USER@$WIN_IP:$WIN_PATH" if scp -i "$SSH_KEY" "$file" "$WIN_USER@$WIN_IP:$WIN_PATH$file"; then log "✅ $file synchronisiert" else log "❌ Fehler beim Sync von $file" fi done } # === MAIN === main() { check_prerequisites create_backups sync_files } main

yongyia/OSKernel2024-SingleOs

2,218

os/src/trap/trap.S

.altmacro .macro SAVE_GP n sd x\n, \n*8(sp) .endm .macro LOAD_GP n ld x\n, \n*8(sp) .endm .section .text.trampoline .globl __alltraps .globl __restore .globl __alltraps_k .globl __restore_k .align 2 __alltraps: csrrw sp, sscratch, sp # now sp->*TrapContext in user space, sscratch->user stack # save other general purpose registers sd x1, 1*8(sp) # skip sp(x2), we will save it later sd x3, 3*8(sp) # skip tp(x4), application does not use it # save x5~x31 .set n, 5 .rept 27 SAVE_GP %n .set n, n+1 .endr # we can use t0/t1/t2 freely, because they have been saved in TrapContext csrr t0, sstatus csrr t1, sepc sd t0, 32*8(sp) sd t1, 33*8(sp) # read user stack from sscratch and save it in TrapContext csrr t2, sscratch sd t2, 2*8(sp) # load kernel_satp into t0 ld t0, 34*8(sp) # load trap_handler into t1 ld t1, 36*8(sp) # move to kernel_sp ld sp, 35*8(sp) # switch to kernel space csrw satp, t0 sfence.vma # jump to trap_handler jr t1 __restore: # a0: *TrapContext in user space(Constant); a1: user space token # switch to user space csrw satp, a1 sfence.vma csrw sscratch, a0 mv sp, a0 # now sp points to TrapContext in user space, start restoring based on it # restore sstatus/sepc ld t0, 32*8(sp) ld t1, 33*8(sp) csrw sstatus, t0 csrw sepc, t1 # restore general purpose registers except x0/sp/tp ld x1, 1*8(sp) ld x3, 3*8(sp) .set n, 5 .rept 27 LOAD_GP %n .set n, n+1 .endr # back to user stack ld sp, 2*8(sp) sret .align 2 __alltraps_k: addi sp, sp, -34*8 sd x1, 1*8(sp) sd x3, 3*8(sp) .set n, 5 .rept 27 SAVE_GP %n .set n, n+1 .endr csrr t0, sstatus csrr t1, sepc sd t0, 32*8(sp) sd t1, 33*8(sp) mv a0, sp csrr t2, sscratch jalr t2 __restore_k: ld t0, 32*8(sp) ld t1, 33*8(sp) csrw sstatus, t0 csrw sepc, t1 ld x1, 1*8(sp) ld x3, 3*8(sp) .set n, 5 .rept 27 LOAD_GP %n .set n, n+1 .endr addi sp, sp, 34*8 sret

Yooshikii/vecno-testnet

5,802

crypto/hashes/src/keccakf1600_x86-64-osx.s

# Source: https://github.com/dot-asm/cryptogams/blob/master/x86_64/keccak1600-x86_64.pl .text .p2align 5 __KeccakF1600: .cfi_startproc .byte 0xf3,0x0f,0x1e,0xfa movq 60(%rdi),%rax movq 68(%rdi),%rbx movq 76(%rdi),%rcx movq 84(%rdi),%rdx movq 92(%rdi),%rbp jmp L$oop .p2align 5 L$oop: movq -100(%rdi),%r8 movq -52(%rdi),%r9 movq -4(%rdi),%r10 movq 44(%rdi),%r11 xorq -84(%rdi),%rcx xorq -76(%rdi),%rdx xorq %r8,%rax xorq -92(%rdi),%rbx xorq -44(%rdi),%rcx xorq -60(%rdi),%rax movq %rbp,%r12 xorq -68(%rdi),%rbp xorq %r10,%rcx xorq -20(%rdi),%rax xorq -36(%rdi),%rdx xorq %r9,%rbx xorq -28(%rdi),%rbp xorq 36(%rdi),%rcx xorq 20(%rdi),%rax xorq 4(%rdi),%rdx xorq -12(%rdi),%rbx xorq 12(%rdi),%rbp movq %rcx,%r13 rolq $1,%rcx xorq %rax,%rcx xorq %r11,%rdx rolq $1,%rax xorq %rdx,%rax xorq 28(%rdi),%rbx rolq $1,%rdx xorq %rbx,%rdx xorq 52(%rdi),%rbp rolq $1,%rbx xorq %rbp,%rbx rolq $1,%rbp xorq %r13,%rbp xorq %rcx,%r9 xorq %rdx,%r10 rolq $44,%r9 xorq %rbp,%r11 xorq %rax,%r12 rolq $43,%r10 xorq %rbx,%r8 movq %r9,%r13 rolq $21,%r11 orq %r10,%r9 xorq %r8,%r9 rolq $14,%r12 xorq (%r15),%r9 leaq 8(%r15),%r15 movq %r12,%r14 andq %r11,%r12 movq %r9,-100(%rsi) xorq %r10,%r12 notq %r10 movq %r12,-84(%rsi) orq %r11,%r10 movq 76(%rdi),%r12 xorq %r13,%r10 movq %r10,-92(%rsi) andq %r8,%r13 movq -28(%rdi),%r9 xorq %r14,%r13 movq -20(%rdi),%r10 movq %r13,-68(%rsi) orq %r8,%r14 movq -76(%rdi),%r8 xorq %r11,%r14 movq 28(%rdi),%r11 movq %r14,-76(%rsi) xorq %rbp,%r8 xorq %rdx,%r12 rolq $28,%r8 xorq %rcx,%r11 xorq %rax,%r9 rolq $61,%r12 rolq $45,%r11 xorq %rbx,%r10 rolq $20,%r9 movq %r8,%r13 orq %r12,%r8 rolq $3,%r10 xorq %r11,%r8 movq %r8,-36(%rsi) movq %r9,%r14 andq %r13,%r9 movq -92(%rdi),%r8 xorq %r12,%r9 notq %r12 movq %r9,-28(%rsi) orq %r11,%r12 movq -44(%rdi),%r9 xorq %r10,%r12 movq %r12,-44(%rsi) andq %r10,%r11 movq 60(%rdi),%r12 xorq %r14,%r11 movq %r11,-52(%rsi) orq %r10,%r14 movq 4(%rdi),%r10 xorq %r13,%r14 movq 52(%rdi),%r11 movq %r14,-60(%rsi) xorq %rbp,%r10 xorq %rax,%r11 rolq $25,%r10 xorq %rdx,%r9 rolq $8,%r11 xorq %rbx,%r12 rolq $6,%r9 xorq %rcx,%r8 rolq $18,%r12 movq %r10,%r13 andq %r11,%r10 rolq $1,%r8 notq %r11 xorq %r9,%r10 movq %r10,-12(%rsi) movq %r12,%r14 andq %r11,%r12 movq -12(%rdi),%r10 xorq %r13,%r12 movq %r12,-4(%rsi) orq %r9,%r13 movq 84(%rdi),%r12 xorq %r8,%r13 movq %r13,-20(%rsi) andq %r8,%r9 xorq %r14,%r9 movq %r9,12(%rsi) orq %r8,%r14 movq -60(%rdi),%r9 xorq %r11,%r14 movq 36(%rdi),%r11 movq %r14,4(%rsi) movq -68(%rdi),%r8 xorq %rcx,%r10 xorq %rdx,%r11 rolq $10,%r10 xorq %rbx,%r9 rolq $15,%r11 xorq %rbp,%r12 rolq $36,%r9 xorq %rax,%r8 rolq $56,%r12 movq %r10,%r13 orq %r11,%r10 rolq $27,%r8 notq %r11 xorq %r9,%r10 movq %r10,28(%rsi) movq %r12,%r14 orq %r11,%r12 xorq %r13,%r12 movq %r12,36(%rsi) andq %r9,%r13 xorq %r8,%r13 movq %r13,20(%rsi) orq %r8,%r9 xorq %r14,%r9 movq %r9,52(%rsi) andq %r14,%r8 xorq %r11,%r8 movq %r8,44(%rsi) xorq -84(%rdi),%rdx xorq -36(%rdi),%rbp rolq $62,%rdx xorq 68(%rdi),%rcx rolq $55,%rbp xorq 12(%rdi),%rax rolq $2,%rcx xorq 20(%rdi),%rbx xchgq %rsi,%rdi rolq $39,%rax rolq $41,%rbx movq %rdx,%r13 andq %rbp,%rdx notq %rbp xorq %rcx,%rdx movq %rdx,92(%rdi) movq %rax,%r14 andq %rbp,%rax xorq %r13,%rax movq %rax,60(%rdi) orq %rcx,%r13 xorq %rbx,%r13 movq %r13,84(%rdi) andq %rbx,%rcx xorq %r14,%rcx movq %rcx,76(%rdi) orq %r14,%rbx xorq %rbp,%rbx movq %rbx,68(%rdi) movq %rdx,%rbp movq %r13,%rdx testq $255,%r15 jnz L$oop leaq -192(%r15),%r15 .byte 0xf3,0xc3 .cfi_endproc .globl _KeccakF1600 .p2align 5 _KeccakF1600: .cfi_startproc .byte 0xf3,0x0f,0x1e,0xfa pushq %rbx .cfi_adjust_cfa_offset 8 .cfi_offset %rbx,-16 pushq %rbp .cfi_adjust_cfa_offset 8 .cfi_offset %rbp,-24 pushq %r12 .cfi_adjust_cfa_offset 8 .cfi_offset %r12,-32 pushq %r13 .cfi_adjust_cfa_offset 8 .cfi_offset %r13,-40 pushq %r14 .cfi_adjust_cfa_offset 8 .cfi_offset %r14,-48 pushq %r15 .cfi_adjust_cfa_offset 8 .cfi_offset %r15,-56 leaq 100(%rdi),%rdi subq $200,%rsp .cfi_adjust_cfa_offset 200 notq -92(%rdi) notq -84(%rdi) notq -36(%rdi) notq -4(%rdi) notq 36(%rdi) notq 60(%rdi) leaq iotas(%rip),%r15 leaq 100(%rsp),%rsi call __KeccakF1600 notq -92(%rdi) notq -84(%rdi) notq -36(%rdi) notq -4(%rdi) notq 36(%rdi) notq 60(%rdi) leaq -100(%rdi),%rdi addq $200,%rsp .cfi_adjust_cfa_offset -200 popq %r15 .cfi_adjust_cfa_offset -8 .cfi_restore %r15 popq %r14 .cfi_adjust_cfa_offset -8 .cfi_restore %r14 popq %r13 .cfi_adjust_cfa_offset -8 .cfi_restore %r13 popq %r12 .cfi_adjust_cfa_offset -8 .cfi_restore %r12 popq %rbp .cfi_adjust_cfa_offset -8 .cfi_restore %rbp popq %rbx .cfi_adjust_cfa_offset -8 .cfi_restore %rbx .byte 0xf3,0xc3 .cfi_endproc .p2align 8 .quad 0,0,0,0,0,0,0,0 iotas: .quad 0x0000000000000001 .quad 0x0000000000008082 .quad 0x800000000000808a .quad 0x8000000080008000 .quad 0x000000000000808b .quad 0x0000000080000001 .quad 0x8000000080008081 .quad 0x8000000000008009 .quad 0x000000000000008a .quad 0x0000000000000088 .quad 0x0000000080008009 .quad 0x000000008000000a .quad 0x000000008000808b .quad 0x800000000000008b .quad 0x8000000000008089 .quad 0x8000000000008003 .quad 0x8000000000008002 .quad 0x8000000000000080 .quad 0x000000000000800a .quad 0x800000008000000a .quad 0x8000000080008081 .quad 0x8000000000008080 .quad 0x0000000080000001 .quad 0x8000000080008008 .byte 75,101,99,99,97,107,45,49,54,48,48,32,97,98,115,111,114,98,32,97,110,100,32,115,113,117,101,101,122,101,32,102,111,114,32,120,56,54,95,54,52,44,32,67,82,89,80,84,79,71,65,77,83,32,98,121,32,60,97,112,112,114,111,64,111,112,101,110,115,115,108,46,111,114,103,62,0

Yooshikii/vecno-testnet

6,073

crypto/hashes/src/keccakf1600_x86-64.s

# Source: https://github.com/dot-asm/cryptogams/blob/master/x86_64/keccak1600-x86_64.pl .text .type __KeccakF1600,@function .align 32 __KeccakF1600: .cfi_startproc .byte 0xf3,0x0f,0x1e,0xfa movq 60(%rdi),%rax movq 68(%rdi),%rbx movq 76(%rdi),%rcx movq 84(%rdi),%rdx movq 92(%rdi),%rbp jmp .Loop .align 32 .Loop: movq -100(%rdi),%r8 movq -52(%rdi),%r9 movq -4(%rdi),%r10 movq 44(%rdi),%r11 xorq -84(%rdi),%rcx xorq -76(%rdi),%rdx xorq %r8,%rax xorq -92(%rdi),%rbx xorq -44(%rdi),%rcx xorq -60(%rdi),%rax movq %rbp,%r12 xorq -68(%rdi),%rbp xorq %r10,%rcx xorq -20(%rdi),%rax xorq -36(%rdi),%rdx xorq %r9,%rbx xorq -28(%rdi),%rbp xorq 36(%rdi),%rcx xorq 20(%rdi),%rax xorq 4(%rdi),%rdx xorq -12(%rdi),%rbx xorq 12(%rdi),%rbp movq %rcx,%r13 rolq $1,%rcx xorq %rax,%rcx xorq %r11,%rdx rolq $1,%rax xorq %rdx,%rax xorq 28(%rdi),%rbx rolq $1,%rdx xorq %rbx,%rdx xorq 52(%rdi),%rbp rolq $1,%rbx xorq %rbp,%rbx rolq $1,%rbp xorq %r13,%rbp xorq %rcx,%r9 xorq %rdx,%r10 rolq $44,%r9 xorq %rbp,%r11 xorq %rax,%r12 rolq $43,%r10 xorq %rbx,%r8 movq %r9,%r13 rolq $21,%r11 orq %r10,%r9 xorq %r8,%r9 rolq $14,%r12 xorq (%r15),%r9 leaq 8(%r15),%r15 movq %r12,%r14 andq %r11,%r12 movq %r9,-100(%rsi) xorq %r10,%r12 notq %r10 movq %r12,-84(%rsi) orq %r11,%r10 movq 76(%rdi),%r12 xorq %r13,%r10 movq %r10,-92(%rsi) andq %r8,%r13 movq -28(%rdi),%r9 xorq %r14,%r13 movq -20(%rdi),%r10 movq %r13,-68(%rsi) orq %r8,%r14 movq -76(%rdi),%r8 xorq %r11,%r14 movq 28(%rdi),%r11 movq %r14,-76(%rsi) xorq %rbp,%r8 xorq %rdx,%r12 rolq $28,%r8 xorq %rcx,%r11 xorq %rax,%r9 rolq $61,%r12 rolq $45,%r11 xorq %rbx,%r10 rolq $20,%r9 movq %r8,%r13 orq %r12,%r8 rolq $3,%r10 xorq %r11,%r8 movq %r8,-36(%rsi) movq %r9,%r14 andq %r13,%r9 movq -92(%rdi),%r8 xorq %r12,%r9 notq %r12 movq %r9,-28(%rsi) orq %r11,%r12 movq -44(%rdi),%r9 xorq %r10,%r12 movq %r12,-44(%rsi) andq %r10,%r11 movq 60(%rdi),%r12 xorq %r14,%r11 movq %r11,-52(%rsi) orq %r10,%r14 movq 4(%rdi),%r10 xorq %r13,%r14 movq 52(%rdi),%r11 movq %r14,-60(%rsi) xorq %rbp,%r10 xorq %rax,%r11 rolq $25,%r10 xorq %rdx,%r9 rolq $8,%r11 xorq %rbx,%r12 rolq $6,%r9 xorq %rcx,%r8 rolq $18,%r12 movq %r10,%r13 andq %r11,%r10 rolq $1,%r8 notq %r11 xorq %r9,%r10 movq %r10,-12(%rsi) movq %r12,%r14 andq %r11,%r12 movq -12(%rdi),%r10 xorq %r13,%r12 movq %r12,-4(%rsi) orq %r9,%r13 movq 84(%rdi),%r12 xorq %r8,%r13 movq %r13,-20(%rsi) andq %r8,%r9 xorq %r14,%r9 movq %r9,12(%rsi) orq %r8,%r14 movq -60(%rdi),%r9 xorq %r11,%r14 movq 36(%rdi),%r11 movq %r14,4(%rsi) movq -68(%rdi),%r8 xorq %rcx,%r10 xorq %rdx,%r11 rolq $10,%r10 xorq %rbx,%r9 rolq $15,%r11 xorq %rbp,%r12 rolq $36,%r9 xorq %rax,%r8 rolq $56,%r12 movq %r10,%r13 orq %r11,%r10 rolq $27,%r8 notq %r11 xorq %r9,%r10 movq %r10,28(%rsi) movq %r12,%r14 orq %r11,%r12 xorq %r13,%r12 movq %r12,36(%rsi) andq %r9,%r13 xorq %r8,%r13 movq %r13,20(%rsi) orq %r8,%r9 xorq %r14,%r9 movq %r9,52(%rsi) andq %r14,%r8 xorq %r11,%r8 movq %r8,44(%rsi) xorq -84(%rdi),%rdx xorq -36(%rdi),%rbp rolq $62,%rdx xorq 68(%rdi),%rcx rolq $55,%rbp xorq 12(%rdi),%rax rolq $2,%rcx xorq 20(%rdi),%rbx xchgq %rsi,%rdi rolq $39,%rax rolq $41,%rbx movq %rdx,%r13 andq %rbp,%rdx notq %rbp xorq %rcx,%rdx movq %rdx,92(%rdi) movq %rax,%r14 andq %rbp,%rax xorq %r13,%rax movq %rax,60(%rdi) orq %rcx,%r13 xorq %rbx,%r13 movq %r13,84(%rdi) andq %rbx,%rcx xorq %r14,%rcx movq %rcx,76(%rdi) orq %r14,%rbx xorq %rbp,%rbx movq %rbx,68(%rdi) movq %rdx,%rbp movq %r13,%rdx testq $255,%r15 jnz .Loop leaq -192(%r15),%r15 .byte 0xf3,0xc3 .cfi_endproc .size __KeccakF1600,.-__KeccakF1600 .globl KeccakF1600 .type KeccakF1600,@function .align 32 KeccakF1600: .cfi_startproc .byte 0xf3,0x0f,0x1e,0xfa pushq %rbx .cfi_adjust_cfa_offset 8 .cfi_offset %rbx,-16 pushq %rbp .cfi_adjust_cfa_offset 8 .cfi_offset %rbp,-24 pushq %r12 .cfi_adjust_cfa_offset 8 .cfi_offset %r12,-32 pushq %r13 .cfi_adjust_cfa_offset 8 .cfi_offset %r13,-40 pushq %r14 .cfi_adjust_cfa_offset 8 .cfi_offset %r14,-48 pushq %r15 .cfi_adjust_cfa_offset 8 .cfi_offset %r15,-56 leaq 100(%rdi),%rdi subq $200,%rsp .cfi_adjust_cfa_offset 200 notq -92(%rdi) notq -84(%rdi) notq -36(%rdi) notq -4(%rdi) notq 36(%rdi) notq 60(%rdi) leaq iotas(%rip),%r15 leaq 100(%rsp),%rsi call __KeccakF1600 notq -92(%rdi) notq -84(%rdi) notq -36(%rdi) notq -4(%rdi) notq 36(%rdi) notq 60(%rdi) leaq -100(%rdi),%rdi addq $200,%rsp .cfi_adjust_cfa_offset -200 popq %r15 .cfi_adjust_cfa_offset -8 .cfi_restore %r15 popq %r14 .cfi_adjust_cfa_offset -8 .cfi_restore %r14 popq %r13 .cfi_adjust_cfa_offset -8 .cfi_restore %r13 popq %r12 .cfi_adjust_cfa_offset -8 .cfi_restore %r12 popq %rbp .cfi_adjust_cfa_offset -8 .cfi_restore %rbp popq %rbx .cfi_adjust_cfa_offset -8 .cfi_restore %rbx .byte 0xf3,0xc3 .cfi_endproc .size KeccakF1600,.-KeccakF1600 .align 256 .quad 0,0,0,0,0,0,0,0 .type iotas,@object iotas: .quad 0x0000000000000001 .quad 0x0000000000008082 .quad 0x800000000000808a .quad 0x8000000080008000 .quad 0x000000000000808b .quad 0x0000000080000001 .quad 0x8000000080008081 .quad 0x8000000000008009 .quad 0x000000000000008a .quad 0x0000000000000088 .quad 0x0000000080008009 .quad 0x000000008000000a .quad 0x000000008000808b .quad 0x800000000000008b .quad 0x8000000000008089 .quad 0x8000000000008003 .quad 0x8000000000008002 .quad 0x8000000000000080 .quad 0x000000000000800a .quad 0x800000008000000a .quad 0x8000000080008081 .quad 0x8000000000008080 .quad 0x0000000080000001 .quad 0x8000000080008008 .size iotas,.-iotas .byte 75,101,99,99,97,107,45,49,54,48,48,32,97,98,115,111,114,98,32,97,110,100,32,115,113,117,101,101,122,101,32,102,111,114,32,120,56,54,95,54,52,44,32,67,82,89,80,84,79,71,65,77,83,32,98,121,32,60,97,112,112,114,111,64,111,112,101,110,115,115,108,46,111,114,103,62,0 .section .note.gnu.property,"a",@note .long 4,2f-1f,5 .byte 0x47,0x4E,0x55,0 1: .long 0xc0000002,4,3 .align 8 2:

Yukash09/RustOS

1,344

src/asm/boot.s

.option norvc # No compressed instructions .section .data .section .text.init .global _start _start: csrr t0 , mhartid bnez t0 , wait csrw satp , zero # No virtual address translation .option push .option norelax # No relaxation optimizations la gp , _global_pointer .option pop # Rust requires .bss section to be zeroed out. la a0 , _bss_start la a1 , _bss_end bgeu a0 , a1 , bss2 # If there is no bss then continue, else zero it out. bss1: sd zero , (a0) # zero it out addi a0 , a0 , 8 bltu a0 , a1 , bss1 bss2: la sp , _stack # Setup stack li t0 , (0b11 << 11) | (1 << 7) | (1 << 3) # Set 12-th , 11-th bits csrw mstatus , t0 la t1 , kINIT csrw mepc , t1 la t2 , asm_trap_vector csrw mtvec , t2 li t3 , (1 << 3) | (1 << 7) | (1 << 11) csrw mie , t3 la ra , next1 mret next1: li t0 , (1 << 8) | (1 << 5) # SPP = 1 , SPIE = 1 , SIE = 1 csrw sstatus , t0 la t1 , kmain csrw sepc , t1 # We need to delegate the interrupt , set Software,timer and external interrupts delegate to supervisor mode li t2 , (1 << 1) | (1 << 5) | (1 << 9) csrw mideleg , t2 csrw sie , t2 # set SSIE , STIE , SEIE la t3 , asm_trap_vector csrw stvec , t3 csrw satp , a0 sfence.vma sret wait: wfi # wait for interrupt j wait

yukineko/rust1000

5,611

0020-arc/src/main.s

.section __TEXT,__text,regular,pure_instructions .build_version macos, 11, 0 .private_extern __ZN3std2rt10lang_start17hc9ec6b6c1c21b466E .globl __ZN3std2rt10lang_start17hc9ec6b6c1c21b466E .p2align 2 __ZN3std2rt10lang_start17hc9ec6b6c1c21b466E: .cfi_startproc sub sp, sp, #48 stp x29, x30, [sp, #32] add x29, sp, #32 .cfi_def_cfa w29, 16 .cfi_offset w30, -8 .cfi_offset w29, -16 mov x8, x0 str x1, [sp, #8] mov x0, x2 ldr x2, [sp, #8] str x0, [sp, #16] mov x4, x3 ldr x3, [sp, #16] sub x0, x29, #8 stur x8, [x29, #-8] adrp x1, l___unnamed_1@PAGE add x1, x1, l___unnamed_1@PAGEOFF bl __ZN3std2rt19lang_start_internal17h95cf27b851151b9cE ldp x29, x30, [sp, #32] add sp, sp, #48 ret .cfi_endproc .p2align 2 __ZN3std2rt10lang_start28_$u7b$$u7b$closure$u7d$$u7d$17hfd1fe55ffac695a8E: .cfi_startproc stp x29, x30, [sp, #-16]! mov x29, sp .cfi_def_cfa w29, 16 .cfi_offset w30, -8 .cfi_offset w29, -16 ldr x0, [x0] bl __ZN3std3sys9backtrace28__rust_begin_short_backtrace17h44e3fcc15ba029bbE bl __ZN54_$LT$$LP$$RP$$u20$as$u20$std..process..Termination$GT$6report17hcc3ea3c6bcbd09d6E and w0, w0, #0xff ldp x29, x30, [sp], #16 ret .cfi_endproc .p2align 2 __ZN3std3sys9backtrace28__rust_begin_short_backtrace17h44e3fcc15ba029bbE: .cfi_startproc stp x29, x30, [sp, #-16]! mov x29, sp .cfi_def_cfa w29, 16 .cfi_offset w30, -8 .cfi_offset w29, -16 bl __ZN4core3ops8function6FnOnce9call_once17h7d3f893992e17b9aE ; InlineAsm Start ; InlineAsm End ldp x29, x30, [sp], #16 ret .cfi_endproc .p2align 2 __ZN4core3fmt9Arguments9new_const17h762cab0d31c0a37fE: .cfi_startproc str x0, [x8] mov w9, #1 str x9, [x8, #8] adrp x9, l___unnamed_2@PAGE adrp x10, l___unnamed_2@PAGE add x10, x10, l___unnamed_2@PAGEOFF ldr x11, [x9, l___unnamed_2@PAGEOFF] mov w9, #8 ldr x10, [x10, #8] str x11, [x8, #32] str x10, [x8, #40] str x9, [x8, #16] str xzr, [x8, #24] ret .cfi_endproc .p2align 2 __ZN4core3ops8function6FnOnce40call_once$u7b$$u7b$vtable.shim$u7d$$u7d$17hf0e802d55956103eE: .cfi_startproc sub sp, sp, #32 stp x29, x30, [sp, #16] add x29, sp, #16 .cfi_def_cfa w29, 16 .cfi_offset w30, -8 .cfi_offset w29, -16 ldr x0, [x0] bl __ZN4core3ops8function6FnOnce9call_once17h83e29275c978ee6eE ldp x29, x30, [sp, #16] add sp, sp, #32 ret .cfi_endproc .p2align 2 __ZN4core3ops8function6FnOnce9call_once17h7d3f893992e17b9aE: .cfi_startproc sub sp, sp, #32 stp x29, x30, [sp, #16] add x29, sp, #16 .cfi_def_cfa w29, 16 .cfi_offset w30, -8 .cfi_offset w29, -16 blr x0 ldp x29, x30, [sp, #16] add sp, sp, #32 ret .cfi_endproc .p2align 2 __ZN4core3ops8function6FnOnce9call_once17h83e29275c978ee6eE: Lfunc_begin0: .cfi_startproc .cfi_personality 155, _rust_eh_personality .cfi_lsda 16, Lexception0 sub sp, sp, #64 stp x29, x30, [sp, #48] add x29, sp, #48 .cfi_def_cfa w29, 16 .cfi_offset w30, -8 .cfi_offset w29, -16 mov x8, x0 add x0, sp, #16 str x8, [sp, #16] Ltmp0: bl __ZN3std2rt10lang_start28_$u7b$$u7b$closure$u7d$$u7d$17hfd1fe55ffac695a8E str w0, [sp, #12] Ltmp1: b LBB6_3 LBB6_1: ldur x0, [x29, #-16] bl __Unwind_Resume LBB6_2: Ltmp2: stur x0, [x29, #-16] mov x8, x1 stur w8, [x29, #-8] b LBB6_1 LBB6_3: ldr w0, [sp, #12] ldp x29, x30, [sp, #48] add sp, sp, #64 ret Lfunc_end0: .cfi_endproc .section __TEXT,__gcc_except_tab .p2align 2, 0x0 GCC_except_table6: Lexception0: .byte 255 .byte 255 .byte 1 .uleb128 Lcst_end0-Lcst_begin0 Lcst_begin0: .uleb128 Ltmp0-Lfunc_begin0 .uleb128 Ltmp1-Ltmp0 .uleb128 Ltmp2-Lfunc_begin0 .byte 0 .uleb128 Ltmp1-Lfunc_begin0 .uleb128 Lfunc_end0-Ltmp1 .byte 0 .byte 0 Lcst_end0: .p2align 2, 0x0 .section __TEXT,__text,regular,pure_instructions .p2align 2 __ZN4core3ptr85drop_in_place$LT$std..rt..lang_start$LT$$LP$$RP$$GT$..$u7b$$u7b$closure$u7d$$u7d$$GT$17h78975a253d878bd5E: .cfi_startproc ret .cfi_endproc .p2align 2 __ZN54_$LT$$LP$$RP$$u20$as$u20$std..process..Termination$GT$6report17hcc3ea3c6bcbd09d6E: .cfi_startproc mov w0, #0 ret .cfi_endproc .p2align 2 __ZN4main4main17h9b68587896d3bd06E: .cfi_startproc sub sp, sp, #80 stp x29, x30, [sp, #64] add x29, sp, #64 .cfi_def_cfa w29, 16 .cfi_offset w30, -8 .cfi_offset w29, -16 add x8, sp, #16 str x8, [sp, #8] adrp x0, l___unnamed_3@PAGE add x0, x0, l___unnamed_3@PAGEOFF bl __ZN4core3fmt9Arguments9new_const17h762cab0d31c0a37fE ldr x0, [sp, #8] bl __ZN3std2io5stdio6_print17h6200d46cef53dee1E ldp x29, x30, [sp, #64] add sp, sp, #80 ret .cfi_endproc .globl _main .p2align 2 _main: .cfi_startproc stp x29, x30, [sp, #-16]! mov x29, sp .cfi_def_cfa w29, 16 .cfi_offset w30, -8 .cfi_offset w29, -16 mov x2, x1 mov x8, x0 sxtw x1, w8 adrp x0, __ZN4main4main17h9b68587896d3bd06E@PAGE add x0, x0, __ZN4main4main17h9b68587896d3bd06E@PAGEOFF mov w3, #0 bl __ZN3std2rt10lang_start17hc9ec6b6c1c21b466E ldp x29, x30, [sp], #16 ret .cfi_endproc .section __DATA,__const .p2align 3, 0x0 l___unnamed_1: .asciz "\000\000\000\000\000\000\000\000\b\000\000\000\000\000\000\000\b\000\000\000\000\000\000" .quad __ZN4core3ops8function6FnOnce40call_once$u7b$$u7b$vtable.shim$u7d$$u7d$17hf0e802d55956103eE .quad __ZN3std2rt10lang_start28_$u7b$$u7b$closure$u7d$$u7d$17hfd1fe55ffac695a8E .quad __ZN3std2rt10lang_start28_$u7b$$u7b$closure$u7d$$u7d$17hfd1fe55ffac695a8E .section __TEXT,__literal16,16byte_literals .p2align 3, 0x0 l___unnamed_2: .space 8 .space 8 .section __TEXT,__const l___unnamed_4: .ascii "Hello, world!\n" .section __DATA,__const .p2align 3, 0x0 l___unnamed_3: .quad l___unnamed_4 .asciz "\016\000\000\000\000\000\000" .subsections_via_symbols

yusefkarim/firmware-playground

13,510

stm32l4/CMSIS/src/startup_stm32l476xx.s

/** ****************************************************************************** * @file startup_stm32l476xx.s * @author MCD Application Team * @brief STM32L476xx devices vector table GCC toolchain. * This module performs: * - Set the initial SP * - Set the initial PC == Reset_Handler, * - Set the vector table entries with the exceptions ISR address, * - Configure the clock system * - Branches to main in the C library (which eventually * calls main()). * After Reset the Cortex-M4 processor is in Thread mode, * priority is Privileged, and the Stack is set to Main. ****************************************************************************** * @attention * * <h2><center>© Copyright (c) 2017 STMicroelectronics. * All rights reserved.</center></h2> * * This software component is licensed by ST under BSD 3-Clause license, * the "License"; You may not use this file except in compliance with the * License. You may obtain a copy of the License at: * opensource.org/licenses/BSD-3-Clause * ****************************************************************************** */ .syntax unified .cpu cortex-m4 .fpu softvfp .thumb .global g_pfnVectors .global Default_Handler /* start address for the initialization values of the .data section. defined in linker script */ .word _sidata /* start address for the .data section. defined in linker script */ .word _sdata /* end address for the .data section. defined in linker script */ .word _edata /* start address for the .bss section. defined in linker script */ .word _sbss /* end address for the .bss section. defined in linker script */ .word _ebss .equ BootRAM, 0xF1E0F85F /** * @brief This is the code that gets called when the processor first * starts execution following a reset event. Only the absolutely * necessary set is performed, after which the application * supplied main() routine is called. * @param None * @retval : None */ .section .text.Reset_Handler .weak Reset_Handler .type Reset_Handler, %function Reset_Handler: ldr sp, =_estack /* Atollic update: set stack pointer */ /* Copy the data segment initializers from flash to SRAM */ movs r1, #0 b LoopCopyDataInit CopyDataInit: ldr r3, =_sidata ldr r3, [r3, r1] str r3, [r0, r1] adds r1, r1, #4 LoopCopyDataInit: ldr r0, =_sdata ldr r3, =_edata adds r2, r0, r1 cmp r2, r3 bcc CopyDataInit ldr r2, =_sbss b LoopFillZerobss /* Zero fill the bss segment. */ FillZerobss: movs r3, #0 str r3, [r2], #4 LoopFillZerobss: ldr r3, = _ebss cmp r2, r3 bcc FillZerobss /* Call the clock system intitialization function.*/ bl SystemInit /* Call static constructors */ bl __libc_init_array /* Call the application's entry point.*/ bl main LoopForever: b LoopForever .size Reset_Handler, .-Reset_Handler /** * @brief This is the code that gets called when the processor receives an * unexpected interrupt. This simply enters an infinite loop, preserving * the system state for examination by a debugger. * * @param None * @retval : None */ .section .text.Default_Handler,"ax",%progbits Default_Handler: Infinite_Loop: b Infinite_Loop .size Default_Handler, .-Default_Handler /****************************************************************************** * * The minimal vector table for a Cortex-M4. Note that the proper constructs * must be placed on this to ensure that it ends up at physical address * 0x0000.0000. * ******************************************************************************/ .section .isr_vector,"a",%progbits .type g_pfnVectors, %object .size g_pfnVectors, .-g_pfnVectors g_pfnVectors: .word _estack .word Reset_Handler .word NMI_Handler .word HardFault_Handler .word MemManage_Handler .word BusFault_Handler .word UsageFault_Handler .word 0 .word 0 .word 0 .word 0 .word SVC_Handler .word DebugMon_Handler .word 0 .word PendSV_Handler .word SysTick_Handler .word WWDG_IRQHandler .word PVD_PVM_IRQHandler .word TAMP_STAMP_IRQHandler .word RTC_WKUP_IRQHandler .word FLASH_IRQHandler .word RCC_IRQHandler .word EXTI0_IRQHandler .word EXTI1_IRQHandler .word EXTI2_IRQHandler .word EXTI3_IRQHandler .word EXTI4_IRQHandler .word DMA1_Channel1_IRQHandler .word DMA1_Channel2_IRQHandler .word DMA1_Channel3_IRQHandler .word DMA1_Channel4_IRQHandler .word DMA1_Channel5_IRQHandler .word DMA1_Channel6_IRQHandler .word DMA1_Channel7_IRQHandler .word ADC1_2_IRQHandler .word CAN1_TX_IRQHandler .word CAN1_RX0_IRQHandler .word CAN1_RX1_IRQHandler .word CAN1_SCE_IRQHandler .word EXTI9_5_IRQHandler .word TIM1_BRK_TIM15_IRQHandler .word TIM1_UP_TIM16_IRQHandler .word TIM1_TRG_COM_TIM17_IRQHandler .word TIM1_CC_IRQHandler .word TIM2_IRQHandler .word TIM3_IRQHandler .word TIM4_IRQHandler .word I2C1_EV_IRQHandler .word I2C1_ER_IRQHandler .word I2C2_EV_IRQHandler .word I2C2_ER_IRQHandler .word SPI1_IRQHandler .word SPI2_IRQHandler .word USART1_IRQHandler .word USART2_IRQHandler .word USART3_IRQHandler .word EXTI15_10_IRQHandler .word RTC_Alarm_IRQHandler .word DFSDM1_FLT3_IRQHandler .word TIM8_BRK_IRQHandler .word TIM8_UP_IRQHandler .word TIM8_TRG_COM_IRQHandler .word TIM8_CC_IRQHandler .word ADC3_IRQHandler .word FMC_IRQHandler .word SDMMC1_IRQHandler .word TIM5_IRQHandler .word SPI3_IRQHandler .word UART4_IRQHandler .word UART5_IRQHandler .word TIM6_DAC_IRQHandler .word TIM7_IRQHandler .word DMA2_Channel1_IRQHandler .word DMA2_Channel2_IRQHandler .word DMA2_Channel3_IRQHandler .word DMA2_Channel4_IRQHandler .word DMA2_Channel5_IRQHandler .word DFSDM1_FLT0_IRQHandler .word DFSDM1_FLT1_IRQHandler .word DFSDM1_FLT2_IRQHandler .word COMP_IRQHandler .word LPTIM1_IRQHandler .word LPTIM2_IRQHandler .word OTG_FS_IRQHandler .word DMA2_Channel6_IRQHandler .word DMA2_Channel7_IRQHandler .word LPUART1_IRQHandler .word QUADSPI_IRQHandler .word I2C3_EV_IRQHandler .word I2C3_ER_IRQHandler .word SAI1_IRQHandler .word SAI2_IRQHandler .word SWPMI1_IRQHandler .word TSC_IRQHandler .word LCD_IRQHandler .word 0 .word RNG_IRQHandler .word FPU_IRQHandler /******************************************************************************* * * Provide weak aliases for each Exception handler to the Default_Handler. * As they are weak aliases, any function with the same name will override * this definition. * *******************************************************************************/ .weak NMI_Handler .thumb_set NMI_Handler,Default_Handler .weak HardFault_Handler .thumb_set HardFault_Handler,Default_Handler .weak MemManage_Handler .thumb_set MemManage_Handler,Default_Handler .weak BusFault_Handler .thumb_set BusFault_Handler,Default_Handler .weak UsageFault_Handler .thumb_set UsageFault_Handler,Default_Handler .weak SVC_Handler .thumb_set SVC_Handler,Default_Handler .weak DebugMon_Handler .thumb_set DebugMon_Handler,Default_Handler .weak PendSV_Handler .thumb_set PendSV_Handler,Default_Handler .weak SysTick_Handler .thumb_set SysTick_Handler,Default_Handler .weak WWDG_IRQHandler .thumb_set WWDG_IRQHandler,Default_Handler .weak PVD_PVM_IRQHandler .thumb_set PVD_PVM_IRQHandler,Default_Handler .weak TAMP_STAMP_IRQHandler .thumb_set TAMP_STAMP_IRQHandler,Default_Handler .weak RTC_WKUP_IRQHandler .thumb_set RTC_WKUP_IRQHandler,Default_Handler .weak FLASH_IRQHandler .thumb_set FLASH_IRQHandler,Default_Handler .weak RCC_IRQHandler .thumb_set RCC_IRQHandler,Default_Handler .weak EXTI0_IRQHandler .thumb_set EXTI0_IRQHandler,Default_Handler .weak EXTI1_IRQHandler .thumb_set EXTI1_IRQHandler,Default_Handler .weak EXTI2_IRQHandler .thumb_set EXTI2_IRQHandler,Default_Handler .weak EXTI3_IRQHandler .thumb_set EXTI3_IRQHandler,Default_Handler .weak EXTI4_IRQHandler .thumb_set EXTI4_IRQHandler,Default_Handler .weak DMA1_Channel1_IRQHandler .thumb_set DMA1_Channel1_IRQHandler,Default_Handler .weak DMA1_Channel2_IRQHandler .thumb_set DMA1_Channel2_IRQHandler,Default_Handler .weak DMA1_Channel3_IRQHandler .thumb_set DMA1_Channel3_IRQHandler,Default_Handler .weak DMA1_Channel4_IRQHandler .thumb_set DMA1_Channel4_IRQHandler,Default_Handler .weak DMA1_Channel5_IRQHandler .thumb_set DMA1_Channel5_IRQHandler,Default_Handler .weak DMA1_Channel6_IRQHandler .thumb_set DMA1_Channel6_IRQHandler,Default_Handler .weak DMA1_Channel7_IRQHandler .thumb_set DMA1_Channel7_IRQHandler,Default_Handler .weak ADC1_2_IRQHandler .thumb_set ADC1_2_IRQHandler,Default_Handler .weak CAN1_TX_IRQHandler .thumb_set CAN1_TX_IRQHandler,Default_Handler .weak CAN1_RX0_IRQHandler .thumb_set CAN1_RX0_IRQHandler,Default_Handler .weak CAN1_RX1_IRQHandler .thumb_set CAN1_RX1_IRQHandler,Default_Handler .weak CAN1_SCE_IRQHandler .thumb_set CAN1_SCE_IRQHandler,Default_Handler .weak EXTI9_5_IRQHandler .thumb_set EXTI9_5_IRQHandler,Default_Handler .weak TIM1_BRK_TIM15_IRQHandler .thumb_set TIM1_BRK_TIM15_IRQHandler,Default_Handler .weak TIM1_UP_TIM16_IRQHandler .thumb_set TIM1_UP_TIM16_IRQHandler,Default_Handler .weak TIM1_TRG_COM_TIM17_IRQHandler .thumb_set TIM1_TRG_COM_TIM17_IRQHandler,Default_Handler .weak TIM1_CC_IRQHandler .thumb_set TIM1_CC_IRQHandler,Default_Handler .weak TIM2_IRQHandler .thumb_set TIM2_IRQHandler,Default_Handler .weak TIM3_IRQHandler .thumb_set TIM3_IRQHandler,Default_Handler .weak TIM4_IRQHandler .thumb_set TIM4_IRQHandler,Default_Handler .weak I2C1_EV_IRQHandler .thumb_set I2C1_EV_IRQHandler,Default_Handler .weak I2C1_ER_IRQHandler .thumb_set I2C1_ER_IRQHandler,Default_Handler .weak I2C2_EV_IRQHandler .thumb_set I2C2_EV_IRQHandler,Default_Handler .weak I2C2_ER_IRQHandler .thumb_set I2C2_ER_IRQHandler,Default_Handler .weak SPI1_IRQHandler .thumb_set SPI1_IRQHandler,Default_Handler .weak SPI2_IRQHandler .thumb_set SPI2_IRQHandler,Default_Handler .weak USART1_IRQHandler .thumb_set USART1_IRQHandler,Default_Handler .weak USART2_IRQHandler .thumb_set USART2_IRQHandler,Default_Handler .weak USART3_IRQHandler .thumb_set USART3_IRQHandler,Default_Handler .weak EXTI15_10_IRQHandler .thumb_set EXTI15_10_IRQHandler,Default_Handler .weak RTC_Alarm_IRQHandler .thumb_set RTC_Alarm_IRQHandler,Default_Handler .weak DFSDM1_FLT3_IRQHandler .thumb_set DFSDM1_FLT3_IRQHandler,Default_Handler .weak TIM8_BRK_IRQHandler .thumb_set TIM8_BRK_IRQHandler,Default_Handler .weak TIM8_UP_IRQHandler .thumb_set TIM8_UP_IRQHandler,Default_Handler .weak TIM8_TRG_COM_IRQHandler .thumb_set TIM8_TRG_COM_IRQHandler,Default_Handler .weak TIM8_CC_IRQHandler .thumb_set TIM8_CC_IRQHandler,Default_Handler .weak ADC3_IRQHandler .thumb_set ADC3_IRQHandler,Default_Handler .weak FMC_IRQHandler .thumb_set FMC_IRQHandler,Default_Handler .weak SDMMC1_IRQHandler .thumb_set SDMMC1_IRQHandler,Default_Handler .weak TIM5_IRQHandler .thumb_set TIM5_IRQHandler,Default_Handler .weak SPI3_IRQHandler .thumb_set SPI3_IRQHandler,Default_Handler .weak UART4_IRQHandler .thumb_set UART4_IRQHandler,Default_Handler .weak UART5_IRQHandler .thumb_set UART5_IRQHandler,Default_Handler .weak TIM6_DAC_IRQHandler .thumb_set TIM6_DAC_IRQHandler,Default_Handler .weak TIM7_IRQHandler .thumb_set TIM7_IRQHandler,Default_Handler .weak DMA2_Channel1_IRQHandler .thumb_set DMA2_Channel1_IRQHandler,Default_Handler .weak DMA2_Channel2_IRQHandler .thumb_set DMA2_Channel2_IRQHandler,Default_Handler .weak DMA2_Channel3_IRQHandler .thumb_set DMA2_Channel3_IRQHandler,Default_Handler .weak DMA2_Channel4_IRQHandler .thumb_set DMA2_Channel4_IRQHandler,Default_Handler .weak DMA2_Channel5_IRQHandler .thumb_set DMA2_Channel5_IRQHandler,Default_Handler .weak DFSDM1_FLT0_IRQHandler .thumb_set DFSDM1_FLT0_IRQHandler,Default_Handler .weak DFSDM1_FLT1_IRQHandler .thumb_set DFSDM1_FLT1_IRQHandler,Default_Handler .weak DFSDM1_FLT2_IRQHandler .thumb_set DFSDM1_FLT2_IRQHandler,Default_Handler .weak COMP_IRQHandler .thumb_set COMP_IRQHandler,Default_Handler .weak LPTIM1_IRQHandler .thumb_set LPTIM1_IRQHandler,Default_Handler .weak LPTIM2_IRQHandler .thumb_set LPTIM2_IRQHandler,Default_Handler .weak OTG_FS_IRQHandler .thumb_set OTG_FS_IRQHandler,Default_Handler .weak DMA2_Channel6_IRQHandler .thumb_set DMA2_Channel6_IRQHandler,Default_Handler .weak DMA2_Channel7_IRQHandler .thumb_set DMA2_Channel7_IRQHandler,Default_Handler .weak LPUART1_IRQHandler .thumb_set LPUART1_IRQHandler,Default_Handler .weak QUADSPI_IRQHandler .thumb_set QUADSPI_IRQHandler,Default_Handler .weak I2C3_EV_IRQHandler .thumb_set I2C3_EV_IRQHandler,Default_Handler .weak I2C3_ER_IRQHandler .thumb_set I2C3_ER_IRQHandler,Default_Handler .weak SAI1_IRQHandler .thumb_set SAI1_IRQHandler,Default_Handler .weak SAI2_IRQHandler .thumb_set SAI2_IRQHandler,Default_Handler .weak SWPMI1_IRQHandler .thumb_set SWPMI1_IRQHandler,Default_Handler .weak TSC_IRQHandler .thumb_set TSC_IRQHandler,Default_Handler .weak LCD_IRQHandler .thumb_set LCD_IRQHandler,Default_Handler .weak RNG_IRQHandler .thumb_set RNG_IRQHandler,Default_Handler .weak FPU_IRQHandler .thumb_set FPU_IRQHandler,Default_Handler /************************ (C) COPYRIGHT STMicroelectronics *****END OF FILE****/

yusefkarim/firmware-playground

27,668

tm4c123/UTx_labs/Lab12_TuningFork/startup.s

; <<< Use Configuration Wizard in Context Menu >>> ;****************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;****************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;****************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Stack EQU 0x00000400 ;****************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Heap EQU 0x00000000 ;****************************************************************************** ; ; Allocate space for the stack. ; ;****************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;****************************************************************************** ; ; Allocate space for the heap. ; ;****************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;****************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;****************************************************************************** PRESERVE8 ;****************************************************************************** ; ; Place code into the reset code section. ; ;****************************************************************************** AREA RESET, CODE, READONLY THUMB ;****************************************************************************** ; ; The vector table. ; ;****************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;****************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;****************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;****************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;****************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;****************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;****************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;****************************************************************************** AREA |.text|, CODE, READONLY ;****************************************************************************** ; ; Useful functions. ; ;****************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;*********** DisableInterrupts *************** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;*********** EnableInterrupts *************** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;*********** StartCritical ************************ ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;*********** EndCritical ************************ ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;*********** WaitForInterrupt ************************ ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;****************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;****************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Tell the assembler that we're done. ; ;****************************************************************************** END

yusefkarim/firmware-playground

27,668

tm4c123/UTx_labs/Lab8_SwitchLEDinterface/Startup.s

; <<< Use Configuration Wizard in Context Menu >>> ;****************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;****************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;****************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Stack EQU 0x00000400 ;****************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Heap EQU 0x00000000 ;****************************************************************************** ; ; Allocate space for the stack. ; ;****************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;****************************************************************************** ; ; Allocate space for the heap. ; ;****************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;****************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;****************************************************************************** PRESERVE8 ;****************************************************************************** ; ; Place code into the reset code section. ; ;****************************************************************************** AREA RESET, CODE, READONLY THUMB ;****************************************************************************** ; ; The vector table. ; ;****************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;****************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;****************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;****************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;****************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;****************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;****************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;****************************************************************************** AREA |.text|, CODE, READONLY ;****************************************************************************** ; ; Useful functions. ; ;****************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;*********** DisableInterrupts *************** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;*********** EnableInterrupts *************** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;*********** StartCritical ************************ ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;*********** EndCritical ************************ ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;*********** WaitForInterrupt ************************ ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;****************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;****************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Tell the assembler that we're done. ; ;****************************************************************************** END

yusefkarim/firmware-playground

27,668

tm4c123/UTx_labs/Lab7_HeartBlock/Startup.s

; <<< Use Configuration Wizard in Context Menu >>> ;****************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;****************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;****************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Stack EQU 0x00000400 ;****************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Heap EQU 0x00000000 ;****************************************************************************** ; ; Allocate space for the stack. ; ;****************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;****************************************************************************** ; ; Allocate space for the heap. ; ;****************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;****************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;****************************************************************************** PRESERVE8 ;****************************************************************************** ; ; Place code into the reset code section. ; ;****************************************************************************** AREA RESET, CODE, READONLY THUMB ;****************************************************************************** ; ; The vector table. ; ;****************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;****************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;****************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;****************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;****************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;****************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;****************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;****************************************************************************** AREA |.text|, CODE, READONLY ;****************************************************************************** ; ; Useful functions. ; ;****************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;*********** DisableInterrupts *************** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;*********** EnableInterrupts *************** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;*********** StartCritical ************************ ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;*********** EndCritical ************************ ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;*********** WaitForInterrupt ************************ ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;****************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;****************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Tell the assembler that we're done. ; ;****************************************************************************** END

yusefkarim/firmware-playground

27,668

tm4c123/UTx_labs/Lab6_BranchingFunctionsDelays/Startup.s

; <<< Use Configuration Wizard in Context Menu >>> ;****************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;****************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;****************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Stack EQU 0x00000400 ;****************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Heap EQU 0x00000000 ;****************************************************************************** ; ; Allocate space for the stack. ; ;****************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;****************************************************************************** ; ; Allocate space for the heap. ; ;****************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;****************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;****************************************************************************** PRESERVE8 ;****************************************************************************** ; ; Place code into the reset code section. ; ;****************************************************************************** AREA RESET, CODE, READONLY THUMB ;****************************************************************************** ; ; The vector table. ; ;****************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;****************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;****************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;****************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;****************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;****************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;****************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;****************************************************************************** AREA |.text|, CODE, READONLY ;****************************************************************************** ; ; Useful functions. ; ;****************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;*********** DisableInterrupts *************** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;*********** EnableInterrupts *************** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;*********** StartCritical ************************ ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;*********** EndCritical ************************ ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;*********** WaitForInterrupt ************************ ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;****************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;****************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Tell the assembler that we're done. ; ;****************************************************************************** END

yusefkarim/firmware-playground

27,668

tm4c123/UTx_labs/Lab11_UART/startup.s

; <<< Use Configuration Wizard in Context Menu >>> ;****************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;****************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;****************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Stack EQU 0x00000400 ;****************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Heap EQU 0x00000000 ;****************************************************************************** ; ; Allocate space for the stack. ; ;****************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;****************************************************************************** ; ; Allocate space for the heap. ; ;****************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;****************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;****************************************************************************** PRESERVE8 ;****************************************************************************** ; ; Place code into the reset code section. ; ;****************************************************************************** AREA RESET, CODE, READONLY THUMB ;****************************************************************************** ; ; The vector table. ; ;****************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;****************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;****************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;****************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;****************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;****************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;****************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;****************************************************************************** AREA |.text|, CODE, READONLY ;****************************************************************************** ; ; Useful functions. ; ;****************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;*********** DisableInterrupts *************** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;*********** EnableInterrupts *************** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;*********** StartCritical ************************ ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;*********** EndCritical ************************ ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;*********** WaitForInterrupt ************************ ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;****************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;****************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Tell the assembler that we're done. ; ;****************************************************************************** END

yusefkarim/firmware-playground

27,668

tm4c123/UTx_labs/Lab14_MeasurementOfDistance/startup.s

; <<< Use Configuration Wizard in Context Menu >>> ;****************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;****************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;****************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Stack EQU 0x00000400 ;****************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Heap EQU 0x00000000 ;****************************************************************************** ; ; Allocate space for the stack. ; ;****************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;****************************************************************************** ; ; Allocate space for the heap. ; ;****************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;****************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;****************************************************************************** PRESERVE8 ;****************************************************************************** ; ; Place code into the reset code section. ; ;****************************************************************************** AREA RESET, CODE, READONLY THUMB ;****************************************************************************** ; ; The vector table. ; ;****************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;****************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;****************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;****************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;****************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;****************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;****************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;****************************************************************************** AREA |.text|, CODE, READONLY ;****************************************************************************** ; ; Useful functions. ; ;****************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;*********** DisableInterrupts *************** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;*********** EnableInterrupts *************** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;*********** StartCritical ************************ ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;*********** EndCritical ************************ ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;*********** WaitForInterrupt ************************ ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;****************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;****************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Tell the assembler that we're done. ; ;****************************************************************************** END

yusefkarim/firmware-playground

27,668

tm4c123/UTx_labs/Lab10_TrafficLight/startup.s

; <<< Use Configuration Wizard in Context Menu >>> ;****************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;****************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;****************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Stack EQU 0x00000400 ;****************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Heap EQU 0x00000000 ;****************************************************************************** ; ; Allocate space for the stack. ; ;****************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;****************************************************************************** ; ; Allocate space for the heap. ; ;****************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;****************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;****************************************************************************** PRESERVE8 ;****************************************************************************** ; ; Place code into the reset code section. ; ;****************************************************************************** AREA RESET, CODE, READONLY THUMB ;****************************************************************************** ; ; The vector table. ; ;****************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;****************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;****************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;****************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;****************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;****************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;****************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;****************************************************************************** AREA |.text|, CODE, READONLY ;****************************************************************************** ; ; Useful functions. ; ;****************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;*********** DisableInterrupts *************** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;*********** EnableInterrupts *************** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;*********** StartCritical ************************ ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;*********** EndCritical ************************ ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;*********** WaitForInterrupt ************************ ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;****************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;****************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Tell the assembler that we're done. ; ;****************************************************************************** END

yusefkarim/firmware-playground

27,668

tm4c123/UTx_labs/Lab13_DAC/startup.s

; <<< Use Configuration Wizard in Context Menu >>> ;****************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;****************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;****************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Stack EQU 0x00000400 ;****************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Heap EQU 0x00000000 ;****************************************************************************** ; ; Allocate space for the stack. ; ;****************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;****************************************************************************** ; ; Allocate space for the heap. ; ;****************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;****************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;****************************************************************************** PRESERVE8 ;****************************************************************************** ; ; Place code into the reset code section. ; ;****************************************************************************** AREA RESET, CODE, READONLY THUMB ;****************************************************************************** ; ; The vector table. ; ;****************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;****************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;****************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;****************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;****************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;****************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;****************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;****************************************************************************** AREA |.text|, CODE, READONLY ;****************************************************************************** ; ; Useful functions. ; ;****************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;*********** DisableInterrupts *************** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;*********** EnableInterrupts *************** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;*********** StartCritical ************************ ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;*********** EndCritical ************************ ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;*********** WaitForInterrupt ************************ ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;****************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;****************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Tell the assembler that we're done. ; ;****************************************************************************** END

yusefkarim/firmware-playground

27,668

tm4c123/UTx_labs/Lab9_FunctionalDebugging/Startup.s

; <<< Use Configuration Wizard in Context Menu >>> ;****************************************************************************** ; ; startup_rvmdk.S - Startup code for use with Keil's uVision. ; ; Copyright (c) 2012 Texas Instruments Incorporated. All rights reserved. ; Software License Agreement ; ; Texas Instruments (TI) is supplying this software for use solely and ; exclusively on TI's microcontroller products. The software is owned by ; TI and/or its suppliers, and is protected under applicable copyright ; laws. You may not combine this software with "viral" open-source ; software in order to form a larger program. ; ; THIS SOFTWARE IS PROVIDED "AS IS" AND WITH ALL FAULTS. ; NO WARRANTIES, WHETHER EXPRESS, IMPLIED OR STATUTORY, INCLUDING, BUT ; NOT LIMITED TO, IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR ; A PARTICULAR PURPOSE APPLY TO THIS SOFTWARE. TI SHALL NOT, UNDER ANY ; CIRCUMSTANCES, BE LIABLE FOR SPECIAL, INCIDENTAL, OR CONSEQUENTIAL ; DAMAGES, FOR ANY REASON WHATSOEVER. ; ; This is part of revision 9453 of the EK-LM4F120XL Firmware Package. ; ;****************************************************************************** ; Edited to conform with ISR names as described in ; "Embedded Systems: Introduction to ARM Cortex M Microcontrollers", ; ISBN: 978-1469998749, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real Time Interfacing to ARM Cortex M Microcontrollers", ; ISBN: 978-1463590154, Jonathan Valvano, copyright (c) 2012 ; "Embedded Systems: Real-Time Operating Systems for ARM Cortex M Microcontrollers", ; ISBN: 978-1466468863, Jonathan Valvano, copyright (c) 2013 ; ;****************************************************************************** ; ; <o> Stack Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Stack EQU 0x00000400 ;****************************************************************************** ; ; <o> Heap Size (in Bytes) <0x0-0xFFFFFFFF:8> ; ;****************************************************************************** Heap EQU 0x00000000 ;****************************************************************************** ; ; Allocate space for the stack. ; ;****************************************************************************** AREA STACK, NOINIT, READWRITE, ALIGN=3 StackMem SPACE Stack __initial_sp ;****************************************************************************** ; ; Allocate space for the heap. ; ;****************************************************************************** AREA HEAP, NOINIT, READWRITE, ALIGN=3 __heap_base HeapMem SPACE Heap __heap_limit ;****************************************************************************** ; ; Indicate that the code in this file preserves 8-byte alignment of the stack. ; ;****************************************************************************** PRESERVE8 ;****************************************************************************** ; ; Place code into the reset code section. ; ;****************************************************************************** AREA RESET, CODE, READONLY THUMB ;****************************************************************************** ; ; The vector table. ; ;****************************************************************************** EXPORT __Vectors __Vectors DCD StackMem + Stack ; Top of Stack DCD Reset_Handler ; Reset Handler DCD NMI_Handler ; NMI Handler DCD HardFault_Handler ; Hard Fault Handler DCD MemManage_Handler ; MPU Fault Handler DCD BusFault_Handler ; Bus Fault Handler DCD UsageFault_Handler ; Usage Fault Handler DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD SVC_Handler ; SVCall Handler DCD DebugMon_Handler ; Debug Monitor Handler DCD 0 ; Reserved DCD PendSV_Handler ; PendSV Handler DCD SysTick_Handler ; SysTick Handler DCD GPIOPortA_Handler ; GPIO Port A DCD GPIOPortB_Handler ; GPIO Port B DCD GPIOPortC_Handler ; GPIO Port C DCD GPIOPortD_Handler ; GPIO Port D DCD GPIOPortE_Handler ; GPIO Port E DCD UART0_Handler ; UART0 Rx and Tx DCD UART1_Handler ; UART1 Rx and Tx DCD SSI0_Handler ; SSI0 Rx and Tx DCD I2C0_Handler ; I2C0 Master and Slave DCD PWM0Fault_Handler ; PWM 0 Fault DCD PWM0Generator0_Handler ; PWM 0 Generator 0 DCD PWM0Generator1_Handler ; PWM 0 Generator 1 DCD PWM0Generator2_Handler ; PWM 0 Generator 2 DCD Quadrature0_Handler ; Quadrature Encoder 0 DCD ADC0Seq0_Handler ; ADC0 Sequence 0 DCD ADC0Seq1_Handler ; ADC0 Sequence 1 DCD ADC0Seq2_Handler ; ADC0 Sequence 2 DCD ADC0Seq3_Handler ; ADC0 Sequence 3 DCD WDT_Handler ; Watchdog DCD Timer0A_Handler ; Timer 0 subtimer A DCD Timer0B_Handler ; Timer 0 subtimer B DCD Timer1A_Handler ; Timer 1 subtimer A DCD Timer1B_Handler ; Timer 1 subtimer B DCD Timer2A_Handler ; Timer 2 subtimer A DCD Timer2B_Handler ; Timer 2 subtimer B DCD Comp0_Handler ; Analog Comp 0 DCD Comp1_Handler ; Analog Comp 1 DCD Comp2_Handler ; Analog Comp 2 DCD SysCtl_Handler ; System Control DCD FlashCtl_Handler ; Flash Control DCD GPIOPortF_Handler ; GPIO Port F DCD GPIOPortG_Handler ; GPIO Port G DCD GPIOPortH_Handler ; GPIO Port H DCD UART2_Handler ; UART2 Rx and Tx DCD SSI1_Handler ; SSI1 Rx and Tx DCD Timer3A_Handler ; Timer 3 subtimer A DCD Timer3B_Handler ; Timer 3 subtimer B DCD I2C1_Handler ; I2C1 Master and Slave DCD Quadrature1_Handler ; Quadrature Encoder 1 DCD CAN0_Handler ; CAN0 DCD CAN1_Handler ; CAN1 DCD CAN2_Handler ; CAN2 DCD Ethernet_Handler ; Ethernet DCD Hibernate_Handler ; Hibernate DCD USB0_Handler ; USB0 DCD PWM0Generator3_Handler ; PWM 0 Generator 3 DCD uDMA_Handler ; uDMA Software Transfer DCD uDMA_Error ; uDMA Error DCD ADC1Seq0_Handler ; ADC1 Sequence 0 DCD ADC1Seq1_Handler ; ADC1 Sequence 1 DCD ADC1Seq2_Handler ; ADC1 Sequence 2 DCD ADC1Seq3_Handler ; ADC1 Sequence 3 DCD I2S0_Handler ; I2S0 DCD ExtBus_Handler ; External Bus Interface 0 DCD GPIOPortJ_Handler ; GPIO Port J DCD GPIOPortK_Handler ; GPIO Port K DCD GPIOPortL_Handler ; GPIO Port L DCD SSI2_Handler ; SSI2 Rx and Tx DCD SSI3_Handler ; SSI3 Rx and Tx DCD UART3_Handler ; UART3 Rx and Tx DCD UART4_Handler ; UART4 Rx and Tx DCD UART5_Handler ; UART5 Rx and Tx DCD UART6_Handler ; UART6 Rx and Tx DCD UART7_Handler ; UART7 Rx and Tx DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD I2C2_Handler ; I2C2 Master and Slave DCD I2C3_Handler ; I2C3 Master and Slave DCD Timer4A_Handler ; Timer 4 subtimer A DCD Timer4B_Handler ; Timer 4 subtimer B DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD 0 ; Reserved DCD Timer5A_Handler ; Timer 5 subtimer A DCD Timer5B_Handler ; Timer 5 subtimer B DCD WideTimer0A_Handler ; Wide Timer 0 subtimer A DCD WideTimer0B_Handler ; Wide Timer 0 subtimer B DCD WideTimer1A_Handler ; Wide Timer 1 subtimer A DCD WideTimer1B_Handler ; Wide Timer 1 subtimer B DCD WideTimer2A_Handler ; Wide Timer 2 subtimer A DCD WideTimer2B_Handler ; Wide Timer 2 subtimer B DCD WideTimer3A_Handler ; Wide Timer 3 subtimer A DCD WideTimer3B_Handler ; Wide Timer 3 subtimer B DCD WideTimer4A_Handler ; Wide Timer 4 subtimer A DCD WideTimer4B_Handler ; Wide Timer 4 subtimer B DCD WideTimer5A_Handler ; Wide Timer 5 subtimer A DCD WideTimer5B_Handler ; Wide Timer 5 subtimer B DCD FPU_Handler ; FPU DCD PECI0_Handler ; PECI 0 DCD LPC0_Handler ; LPC 0 DCD I2C4_Handler ; I2C4 Master and Slave DCD I2C5_Handler ; I2C5 Master and Slave DCD GPIOPortM_Handler ; GPIO Port M DCD GPIOPortN_Handler ; GPIO Port N DCD Quadrature2_Handler ; Quadrature Encoder 2 DCD Fan0_Handler ; Fan 0 DCD 0 ; Reserved DCD GPIOPortP_Handler ; GPIO Port P (Summary or P0) DCD GPIOPortP1_Handler ; GPIO Port P1 DCD GPIOPortP2_Handler ; GPIO Port P2 DCD GPIOPortP3_Handler ; GPIO Port P3 DCD GPIOPortP4_Handler ; GPIO Port P4 DCD GPIOPortP5_Handler ; GPIO Port P5 DCD GPIOPortP6_Handler ; GPIO Port P6 DCD GPIOPortP7_Handler ; GPIO Port P7 DCD GPIOPortQ_Handler ; GPIO Port Q (Summary or Q0) DCD GPIOPortQ1_Handler ; GPIO Port Q1 DCD GPIOPortQ2_Handler ; GPIO Port Q2 DCD GPIOPortQ3_Handler ; GPIO Port Q3 DCD GPIOPortQ4_Handler ; GPIO Port Q4 DCD GPIOPortQ5_Handler ; GPIO Port Q5 DCD GPIOPortQ6_Handler ; GPIO Port Q6 DCD GPIOPortQ7_Handler ; GPIO Port Q7 DCD GPIOPortR_Handler ; GPIO Port R DCD GPIOPortS_Handler ; GPIO Port S DCD PWM1Generator0_Handler ; PWM 1 Generator 0 DCD PWM1Generator1_Handler ; PWM 1 Generator 1 DCD PWM1Generator2_Handler ; PWM 1 Generator 2 DCD PWM1Generator3_Handler ; PWM 1 Generator 3 DCD PWM1Fault_Handler ; PWM 1 Fault ;****************************************************************************** ; ; This is the code that gets called when the processor first starts execution ; following a reset event. ; ;****************************************************************************** EXPORT Reset_Handler Reset_Handler ; ; DO NOT enable the floating-point unit. This must be done here to handle the ; case where main() uses floating-point and the function prologue saves ; floating-point registers (which will fault if floating-point is not ; enabled). Any configuration of the floating-point unit using ; DriverLib APIs must be done here prior to the floating-point unit ; being enabled. ; ; Note that this does not use DriverLib since it might not be included ; in this project. ; ; MOVW R0, #0xED88 ; MOVT R0, #0xE000 ; LDR R1, [R0] ; ORR R1, #0x00F00000 ; STR R1, [R0] ; ; Call the C library enty point that handles startup. This will copy ; the .data section initializers from flash to SRAM and zero fill the ; .bss section. ; IMPORT __main B __main ;****************************************************************************** ; ; This is the code that gets called when the processor receives a NMI. This ; simply enters an infinite loop, preserving the system state for examination ; by a debugger. ; ;****************************************************************************** NMI_Handler PROC EXPORT NMI_Handler [WEAK] B . ENDP ;****************************************************************************** ; ; This is the code that gets called when the processor receives a fault ; interrupt. This simply enters an infinite loop, preserving the system state ; for examination by a debugger. ; ;****************************************************************************** HardFault_Handler\ PROC EXPORT HardFault_Handler [WEAK] B . ENDP MemManage_Handler\ PROC EXPORT MemManage_Handler [WEAK] B . ENDP BusFault_Handler\ PROC EXPORT BusFault_Handler [WEAK] B . ENDP UsageFault_Handler\ PROC EXPORT UsageFault_Handler [WEAK] B . ENDP SVC_Handler PROC EXPORT SVC_Handler [WEAK] B . ENDP DebugMon_Handler\ PROC EXPORT DebugMon_Handler [WEAK] B . ENDP PendSV_Handler PROC EXPORT PendSV_Handler [WEAK] B . ENDP SysTick_Handler PROC EXPORT SysTick_Handler [WEAK] B . ENDP IntDefaultHandler\ PROC EXPORT GPIOPortA_Handler [WEAK] EXPORT GPIOPortB_Handler [WEAK] EXPORT GPIOPortC_Handler [WEAK] EXPORT GPIOPortD_Handler [WEAK] EXPORT GPIOPortE_Handler [WEAK] EXPORT UART0_Handler [WEAK] EXPORT UART1_Handler [WEAK] EXPORT SSI0_Handler [WEAK] EXPORT I2C0_Handler [WEAK] EXPORT PWM0Fault_Handler [WEAK] EXPORT PWM0Generator0_Handler [WEAK] EXPORT PWM0Generator1_Handler [WEAK] EXPORT PWM0Generator2_Handler [WEAK] EXPORT Quadrature0_Handler [WEAK] EXPORT ADC0Seq0_Handler [WEAK] EXPORT ADC0Seq1_Handler [WEAK] EXPORT ADC0Seq2_Handler [WEAK] EXPORT ADC0Seq3_Handler [WEAK] EXPORT WDT_Handler [WEAK] EXPORT Timer0A_Handler [WEAK] EXPORT Timer0B_Handler [WEAK] EXPORT Timer1A_Handler [WEAK] EXPORT Timer1B_Handler [WEAK] EXPORT Timer2A_Handler [WEAK] EXPORT Timer2B_Handler [WEAK] EXPORT Comp0_Handler [WEAK] EXPORT Comp1_Handler [WEAK] EXPORT Comp2_Handler [WEAK] EXPORT SysCtl_Handler [WEAK] EXPORT FlashCtl_Handler [WEAK] EXPORT GPIOPortF_Handler [WEAK] EXPORT GPIOPortG_Handler [WEAK] EXPORT GPIOPortH_Handler [WEAK] EXPORT UART2_Handler [WEAK] EXPORT SSI1_Handler [WEAK] EXPORT Timer3A_Handler [WEAK] EXPORT Timer3B_Handler [WEAK] EXPORT I2C1_Handler [WEAK] EXPORT Quadrature1_Handler [WEAK] EXPORT CAN0_Handler [WEAK] EXPORT CAN1_Handler [WEAK] EXPORT CAN2_Handler [WEAK] EXPORT Ethernet_Handler [WEAK] EXPORT Hibernate_Handler [WEAK] EXPORT USB0_Handler [WEAK] EXPORT PWM0Generator3_Handler [WEAK] EXPORT uDMA_Handler [WEAK] EXPORT uDMA_Error [WEAK] EXPORT ADC1Seq0_Handler [WEAK] EXPORT ADC1Seq1_Handler [WEAK] EXPORT ADC1Seq2_Handler [WEAK] EXPORT ADC1Seq3_Handler [WEAK] EXPORT I2S0_Handler [WEAK] EXPORT ExtBus_Handler [WEAK] EXPORT GPIOPortJ_Handler [WEAK] EXPORT GPIOPortK_Handler [WEAK] EXPORT GPIOPortL_Handler [WEAK] EXPORT SSI2_Handler [WEAK] EXPORT SSI3_Handler [WEAK] EXPORT UART3_Handler [WEAK] EXPORT UART4_Handler [WEAK] EXPORT UART5_Handler [WEAK] EXPORT UART6_Handler [WEAK] EXPORT UART7_Handler [WEAK] EXPORT I2C2_Handler [WEAK] EXPORT I2C3_Handler [WEAK] EXPORT Timer4A_Handler [WEAK] EXPORT Timer4B_Handler [WEAK] EXPORT Timer5A_Handler [WEAK] EXPORT Timer5B_Handler [WEAK] EXPORT WideTimer0A_Handler [WEAK] EXPORT WideTimer0B_Handler [WEAK] EXPORT WideTimer1A_Handler [WEAK] EXPORT WideTimer1B_Handler [WEAK] EXPORT WideTimer2A_Handler [WEAK] EXPORT WideTimer2B_Handler [WEAK] EXPORT WideTimer3A_Handler [WEAK] EXPORT WideTimer3B_Handler [WEAK] EXPORT WideTimer4A_Handler [WEAK] EXPORT WideTimer4B_Handler [WEAK] EXPORT WideTimer5A_Handler [WEAK] EXPORT WideTimer5B_Handler [WEAK] EXPORT FPU_Handler [WEAK] EXPORT PECI0_Handler [WEAK] EXPORT LPC0_Handler [WEAK] EXPORT I2C4_Handler [WEAK] EXPORT I2C5_Handler [WEAK] EXPORT GPIOPortM_Handler [WEAK] EXPORT GPIOPortN_Handler [WEAK] EXPORT Quadrature2_Handler [WEAK] EXPORT Fan0_Handler [WEAK] EXPORT GPIOPortP_Handler [WEAK] EXPORT GPIOPortP1_Handler [WEAK] EXPORT GPIOPortP2_Handler [WEAK] EXPORT GPIOPortP3_Handler [WEAK] EXPORT GPIOPortP4_Handler [WEAK] EXPORT GPIOPortP5_Handler [WEAK] EXPORT GPIOPortP6_Handler [WEAK] EXPORT GPIOPortP7_Handler [WEAK] EXPORT GPIOPortQ_Handler [WEAK] EXPORT GPIOPortQ1_Handler [WEAK] EXPORT GPIOPortQ2_Handler [WEAK] EXPORT GPIOPortQ3_Handler [WEAK] EXPORT GPIOPortQ4_Handler [WEAK] EXPORT GPIOPortQ5_Handler [WEAK] EXPORT GPIOPortQ6_Handler [WEAK] EXPORT GPIOPortQ7_Handler [WEAK] EXPORT GPIOPortR_Handler [WEAK] EXPORT GPIOPortS_Handler [WEAK] EXPORT PWM1Generator0_Handler [WEAK] EXPORT PWM1Generator1_Handler [WEAK] EXPORT PWM1Generator2_Handler [WEAK] EXPORT PWM1Generator3_Handler [WEAK] EXPORT PWM1Fault_Handler [WEAK] GPIOPortA_Handler GPIOPortB_Handler GPIOPortC_Handler GPIOPortD_Handler GPIOPortE_Handler UART0_Handler UART1_Handler SSI0_Handler I2C0_Handler PWM0Fault_Handler PWM0Generator0_Handler PWM0Generator1_Handler PWM0Generator2_Handler Quadrature0_Handler ADC0Seq0_Handler ADC0Seq1_Handler ADC0Seq2_Handler ADC0Seq3_Handler WDT_Handler Timer0A_Handler Timer0B_Handler Timer1A_Handler Timer1B_Handler Timer2A_Handler Timer2B_Handler Comp0_Handler Comp1_Handler Comp2_Handler SysCtl_Handler FlashCtl_Handler GPIOPortF_Handler GPIOPortG_Handler GPIOPortH_Handler UART2_Handler SSI1_Handler Timer3A_Handler Timer3B_Handler I2C1_Handler Quadrature1_Handler CAN0_Handler CAN1_Handler CAN2_Handler Ethernet_Handler Hibernate_Handler USB0_Handler PWM0Generator3_Handler uDMA_Handler uDMA_Error ADC1Seq0_Handler ADC1Seq1_Handler ADC1Seq2_Handler ADC1Seq3_Handler I2S0_Handler ExtBus_Handler GPIOPortJ_Handler GPIOPortK_Handler GPIOPortL_Handler SSI2_Handler SSI3_Handler UART3_Handler UART4_Handler UART5_Handler UART6_Handler UART7_Handler I2C2_Handler I2C3_Handler Timer4A_Handler Timer4B_Handler Timer5A_Handler Timer5B_Handler WideTimer0A_Handler WideTimer0B_Handler WideTimer1A_Handler WideTimer1B_Handler WideTimer2A_Handler WideTimer2B_Handler WideTimer3A_Handler WideTimer3B_Handler WideTimer4A_Handler WideTimer4B_Handler WideTimer5A_Handler WideTimer5B_Handler FPU_Handler PECI0_Handler LPC0_Handler I2C4_Handler I2C5_Handler GPIOPortM_Handler GPIOPortN_Handler Quadrature2_Handler Fan0_Handler GPIOPortP_Handler GPIOPortP1_Handler GPIOPortP2_Handler GPIOPortP3_Handler GPIOPortP4_Handler GPIOPortP5_Handler GPIOPortP6_Handler GPIOPortP7_Handler GPIOPortQ_Handler GPIOPortQ1_Handler GPIOPortQ2_Handler GPIOPortQ3_Handler GPIOPortQ4_Handler GPIOPortQ5_Handler GPIOPortQ6_Handler GPIOPortQ7_Handler GPIOPortR_Handler GPIOPortS_Handler PWM1Generator0_Handler PWM1Generator1_Handler PWM1Generator2_Handler PWM1Generator3_Handler PWM1Fault_Handler B . ENDP ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Some code in the normal code section for initializing the heap and stack. ; ;****************************************************************************** AREA |.text|, CODE, READONLY ;****************************************************************************** ; ; Useful functions. ; ;****************************************************************************** EXPORT DisableInterrupts EXPORT EnableInterrupts EXPORT StartCritical EXPORT EndCritical EXPORT WaitForInterrupt ;*********** DisableInterrupts *************** ; disable interrupts ; inputs: none ; outputs: none DisableInterrupts CPSID I BX LR ;*********** EnableInterrupts *************** ; enable interrupts ; inputs: none ; outputs: none EnableInterrupts CPSIE I BX LR ;*********** StartCritical ************************ ; make a copy of previous I bit, disable interrupts ; inputs: none ; outputs: previous I bit StartCritical MRS R0, PRIMASK ; save old status CPSID I ; mask all (except faults) BX LR ;*********** EndCritical ************************ ; using the copy of previous I bit, restore I bit to previous value ; inputs: previous I bit ; outputs: none EndCritical MSR PRIMASK, R0 BX LR ;*********** WaitForInterrupt ************************ ; go to low power mode while waiting for the next interrupt ; inputs: none ; outputs: none WaitForInterrupt WFI BX LR ;****************************************************************************** ; ; The function expected of the C library startup code for defining the stack ; and heap memory locations. For the C library version of the startup code, ; provide this function so that the C library initialization code can find out ; the location of the stack and heap. ; ;****************************************************************************** IF :DEF: __MICROLIB EXPORT __initial_sp EXPORT __heap_base EXPORT __heap_limit ELSE IMPORT __use_two_region_memory EXPORT __user_initial_stackheap __user_initial_stackheap LDR R0, =HeapMem LDR R1, =(StackMem + Stack) LDR R2, =(HeapMem + Heap) LDR R3, =StackMem BX LR ENDIF ;****************************************************************************** ; ; Make sure the end of this section is aligned. ; ;****************************************************************************** ALIGN ;****************************************************************************** ; ; Tell the assembler that we're done. ; ;****************************************************************************** END

yusefkarim/firmware-playground

9,878

stm32f1/CMSIS/src/startup_stm32f103xb.s

/** *************** (C) COPYRIGHT 2017 STMicroelectronics ************************ * @file startup_stm32f103xb.s * @author MCD Application Team * @brief STM32F103xB Devices vector table for Atollic toolchain. * This module performs: * - Set the initial SP * - Set the initial PC == Reset_Handler, * - Set the vector table entries with the exceptions ISR address * - Configure the clock system * - Branches to main in the C library (which eventually * calls main()). * After Reset the Cortex-M3 processor is in Thread mode, * priority is Privileged, and the Stack is set to Main. ****************************************************************************** * @attention * * <h2><center>© Copyright (c) 2017 STMicroelectronics. * All rights reserved.</center></h2> * * This software component is licensed by ST under BSD 3-Clause license, * the "License"; You may not use this file except in compliance with the * License. You may obtain a copy of the License at: * opensource.org/licenses/BSD-3-Clause * ****************************************************************************** */ .syntax unified .cpu cortex-m3 .fpu softvfp .thumb .global g_pfnVectors .global Default_Handler /* start address for the initialization values of the .data section. defined in linker script */ .word _sidata /* start address for the .data section. defined in linker script */ .word _sdata /* end address for the .data section. defined in linker script */ .word _edata /* start address for the .bss section. defined in linker script */ .word _sbss /* end address for the .bss section. defined in linker script */ .word _ebss .equ BootRAM, 0xF108F85F /** * @brief This is the code that gets called when the processor first * starts execution following a reset event. Only the absolutely * necessary set is performed, after which the application * supplied main() routine is called. * @param None * @retval : None */ .section .text.Reset_Handler .weak Reset_Handler .type Reset_Handler, %function Reset_Handler: /* Copy the data segment initializers from flash to SRAM */ movs r1, #0 b LoopCopyDataInit CopyDataInit: ldr r3, =_sidata ldr r3, [r3, r1] str r3, [r0, r1] adds r1, r1, #4 LoopCopyDataInit: ldr r0, =_sdata ldr r3, =_edata adds r2, r0, r1 cmp r2, r3 bcc CopyDataInit ldr r2, =_sbss b LoopFillZerobss /* Zero fill the bss segment. */ FillZerobss: movs r3, #0 str r3, [r2], #4 LoopFillZerobss: ldr r3, = _ebss cmp r2, r3 bcc FillZerobss /* Call the clock system intitialization function.*/ bl SystemInit /* Call static constructors */ bl __libc_init_array /* Call the application's entry point.*/ bl main bx lr .size Reset_Handler, .-Reset_Handler /** * @brief This is the code that gets called when the processor receives an * unexpected interrupt. This simply enters an infinite loop, preserving * the system state for examination by a debugger. * * @param None * @retval : None */ .section .text.Default_Handler,"ax",%progbits Default_Handler: Infinite_Loop: b Infinite_Loop .size Default_Handler, .-Default_Handler /****************************************************************************** * * The minimal vector table for a Cortex M3. Note that the proper constructs * must be placed on this to ensure that it ends up at physical address * 0x0000.0000. * ******************************************************************************/ .section .isr_vector,"a",%progbits .type g_pfnVectors, %object .size g_pfnVectors, .-g_pfnVectors g_pfnVectors: .word _estack .word Reset_Handler .word NMI_Handler .word HardFault_Handler .word MemManage_Handler .word BusFault_Handler .word UsageFault_Handler .word 0 .word 0 .word 0 .word 0 .word SVC_Handler .word DebugMon_Handler .word 0 .word PendSV_Handler .word SysTick_Handler .word WWDG_IRQHandler .word PVD_IRQHandler .word TAMPER_IRQHandler .word RTC_IRQHandler .word FLASH_IRQHandler .word RCC_IRQHandler .word EXTI0_IRQHandler .word EXTI1_IRQHandler .word EXTI2_IRQHandler .word EXTI3_IRQHandler .word EXTI4_IRQHandler .word DMA1_Channel1_IRQHandler .word DMA1_Channel2_IRQHandler .word DMA1_Channel3_IRQHandler .word DMA1_Channel4_IRQHandler .word DMA1_Channel5_IRQHandler .word DMA1_Channel6_IRQHandler .word DMA1_Channel7_IRQHandler .word ADC1_2_IRQHandler .word USB_HP_CAN1_TX_IRQHandler .word USB_LP_CAN1_RX0_IRQHandler .word CAN1_RX1_IRQHandler .word CAN1_SCE_IRQHandler .word EXTI9_5_IRQHandler .word TIM1_BRK_IRQHandler .word TIM1_UP_IRQHandler .word TIM1_TRG_COM_IRQHandler .word TIM1_CC_IRQHandler .word TIM2_IRQHandler .word TIM3_IRQHandler .word TIM4_IRQHandler .word I2C1_EV_IRQHandler .word I2C1_ER_IRQHandler .word I2C2_EV_IRQHandler .word I2C2_ER_IRQHandler .word SPI1_IRQHandler .word SPI2_IRQHandler .word USART1_IRQHandler .word USART2_IRQHandler .word USART3_IRQHandler .word EXTI15_10_IRQHandler .word RTC_Alarm_IRQHandler .word USBWakeUp_IRQHandler .word 0 .word 0 .word 0 .word 0 .word 0 .word 0 .word 0 .word BootRAM /* @0x108. This is for boot in RAM mode for STM32F10x Medium Density devices. */ /******************************************************************************* * * Provide weak aliases for each Exception handler to the Default_Handler. * As they are weak aliases, any function with the same name will override * this definition. * *******************************************************************************/ .weak NMI_Handler .thumb_set NMI_Handler,Default_Handler .weak HardFault_Handler .thumb_set HardFault_Handler,Default_Handler .weak MemManage_Handler .thumb_set MemManage_Handler,Default_Handler .weak BusFault_Handler .thumb_set BusFault_Handler,Default_Handler .weak UsageFault_Handler .thumb_set UsageFault_Handler,Default_Handler .weak SVC_Handler .thumb_set SVC_Handler,Default_Handler .weak DebugMon_Handler .thumb_set DebugMon_Handler,Default_Handler .weak PendSV_Handler .thumb_set PendSV_Handler,Default_Handler .weak SysTick_Handler .thumb_set SysTick_Handler,Default_Handler .weak WWDG_IRQHandler .thumb_set WWDG_IRQHandler,Default_Handler .weak PVD_IRQHandler .thumb_set PVD_IRQHandler,Default_Handler .weak TAMPER_IRQHandler .thumb_set TAMPER_IRQHandler,Default_Handler .weak RTC_IRQHandler .thumb_set RTC_IRQHandler,Default_Handler .weak FLASH_IRQHandler .thumb_set FLASH_IRQHandler,Default_Handler .weak RCC_IRQHandler .thumb_set RCC_IRQHandler,Default_Handler .weak EXTI0_IRQHandler .thumb_set EXTI0_IRQHandler,Default_Handler .weak EXTI1_IRQHandler .thumb_set EXTI1_IRQHandler,Default_Handler .weak EXTI2_IRQHandler .thumb_set EXTI2_IRQHandler,Default_Handler .weak EXTI3_IRQHandler .thumb_set EXTI3_IRQHandler,Default_Handler .weak EXTI4_IRQHandler .thumb_set EXTI4_IRQHandler,Default_Handler .weak DMA1_Channel1_IRQHandler .thumb_set DMA1_Channel1_IRQHandler,Default_Handler .weak DMA1_Channel2_IRQHandler .thumb_set DMA1_Channel2_IRQHandler,Default_Handler .weak DMA1_Channel3_IRQHandler .thumb_set DMA1_Channel3_IRQHandler,Default_Handler .weak DMA1_Channel4_IRQHandler .thumb_set DMA1_Channel4_IRQHandler,Default_Handler .weak DMA1_Channel5_IRQHandler .thumb_set DMA1_Channel5_IRQHandler,Default_Handler .weak DMA1_Channel6_IRQHandler .thumb_set DMA1_Channel6_IRQHandler,Default_Handler .weak DMA1_Channel7_IRQHandler .thumb_set DMA1_Channel7_IRQHandler,Default_Handler .weak ADC1_2_IRQHandler .thumb_set ADC1_2_IRQHandler,Default_Handler .weak USB_HP_CAN1_TX_IRQHandler .thumb_set USB_HP_CAN1_TX_IRQHandler,Default_Handler .weak USB_LP_CAN1_RX0_IRQHandler .thumb_set USB_LP_CAN1_RX0_IRQHandler,Default_Handler .weak CAN1_RX1_IRQHandler .thumb_set CAN1_RX1_IRQHandler,Default_Handler .weak CAN1_SCE_IRQHandler .thumb_set CAN1_SCE_IRQHandler,Default_Handler .weak EXTI9_5_IRQHandler .thumb_set EXTI9_5_IRQHandler,Default_Handler .weak TIM1_BRK_IRQHandler .thumb_set TIM1_BRK_IRQHandler,Default_Handler .weak TIM1_UP_IRQHandler .thumb_set TIM1_UP_IRQHandler,Default_Handler .weak TIM1_TRG_COM_IRQHandler .thumb_set TIM1_TRG_COM_IRQHandler,Default_Handler .weak TIM1_CC_IRQHandler .thumb_set TIM1_CC_IRQHandler,Default_Handler .weak TIM2_IRQHandler .thumb_set TIM2_IRQHandler,Default_Handler .weak TIM3_IRQHandler .thumb_set TIM3_IRQHandler,Default_Handler .weak TIM4_IRQHandler .thumb_set TIM4_IRQHandler,Default_Handler .weak I2C1_EV_IRQHandler .thumb_set I2C1_EV_IRQHandler,Default_Handler .weak I2C1_ER_IRQHandler .thumb_set I2C1_ER_IRQHandler,Default_Handler .weak I2C2_EV_IRQHandler .thumb_set I2C2_EV_IRQHandler,Default_Handler .weak I2C2_ER_IRQHandler .thumb_set I2C2_ER_IRQHandler,Default_Handler .weak SPI1_IRQHandler .thumb_set SPI1_IRQHandler,Default_Handler .weak SPI2_IRQHandler .thumb_set SPI2_IRQHandler,Default_Handler .weak USART1_IRQHandler .thumb_set USART1_IRQHandler,Default_Handler .weak USART2_IRQHandler .thumb_set USART2_IRQHandler,Default_Handler .weak USART3_IRQHandler .thumb_set USART3_IRQHandler,Default_Handler .weak EXTI15_10_IRQHandler .thumb_set EXTI15_10_IRQHandler,Default_Handler .weak RTC_Alarm_IRQHandler .thumb_set RTC_Alarm_IRQHandler,Default_Handler .weak USBWakeUp_IRQHandler .thumb_set USBWakeUp_IRQHandler,Default_Handler /************************ (C) COPYRIGHT STMicroelectronics *****END OF FILE****/

YuXuaann/Compile

1,028

task1/src/sample-32.s

.file "sample.c" .text .globl main .type main, @function main: .LFB0: .cfi_startproc endbr32 pushl %ebp .cfi_def_cfa_offset 8 .cfi_offset 5, -8 movl %esp, %ebp .cfi_def_cfa_register 5 subl $16, %esp call __x86.get_pc_thunk.ax addl $_GLOBAL_OFFSET_TABLE_, %eax movl $4, -4(%ebp) cmpl $0, -4(%ebp) je .L2 addl $4, -4(%ebp) jmp .L3 .L2: sall $2, -4(%ebp) .L3: movl $0, %eax leave .cfi_restore 5 .cfi_def_cfa 4, 4 ret .cfi_endproc .LFE0: .size main, .-main .section .text.__x86.get_pc_thunk.ax,"axG",@progbits,__x86.get_pc_thunk.ax,comdat .globl __x86.get_pc_thunk.ax .hidden __x86.get_pc_thunk.ax .type __x86.get_pc_thunk.ax, @function __x86.get_pc_thunk.ax: .LFB1: .cfi_startproc movl (%esp), %eax ret .cfi_endproc .LFE1: .ident "GCC: (Ubuntu 9.5.0-1ubuntu1~22.04) 9.5.0" .section .note.GNU-stack,"",@progbits .section .note.gnu.property,"a" .align 4 .long 1f - 0f .long 4f - 1f .long 5 0: .string "GNU" 1: .align 4 .long 0xc0000002 .long 3f - 2f 2: .long 0x3 3: .align 4 4: