#pragma once #include "ggml-impl.h" #include #include #define likely(x) __builtin_expect(!!(x), 1) #define unlikely(x) __builtin_expect(!!(x), 0) struct apir_encoder { char * cur; const char * start; const char * end; bool fatal; }; struct apir_decoder { const char * cur; const char * end; bool fatal; }; /* * new encoder and decoder */ static apir_decoder apir_new_decoder(const char * ptr, size_t size) { apir_decoder dec = { .cur = ptr, .end = ptr + size, .fatal = false, }; return dec; } static apir_encoder apir_new_encoder(char * ptr, size_t size) { apir_encoder enc = { .cur = ptr, .start = ptr, .end = ptr + size, .fatal = false, }; return enc; } /* * fatal flag handling */ static inline void apir_encoder_reset_fatal(apir_encoder * enc) { enc->fatal = false; } static inline void apir_encoder_set_fatal(apir_encoder * enc) { enc->fatal = true; } static inline bool apir_encoder_get_fatal(const apir_encoder * enc) { return enc->fatal; } static inline void apir_decoder_reset_fatal(apir_decoder * dec) { dec->fatal = false; } static inline void apir_decoder_set_fatal(apir_decoder * dec) { dec->fatal = true; } static inline bool apir_decoder_get_fatal(const apir_decoder * dec) { return dec->fatal; } /* * encode peek */ static inline bool apir_decoder_peek_internal(apir_decoder * dec, size_t size, void * val, size_t val_size) { assert(val_size <= size); if (unlikely(size > (size_t) (dec->end - dec->cur))) { GGML_LOG_ERROR("%s: reading too much from the decoder ...\n", __func__); apir_decoder_set_fatal(dec); memset(val, 0, val_size); return false; } /* we should not rely on the compiler to optimize away memcpy... */ memcpy(val, dec->cur, val_size); return true; } static inline void apir_decoder_peek(apir_decoder * dec, size_t size, void * val, size_t val_size) { apir_decoder_peek_internal(dec, size, val, val_size); } static inline const void * apir_decoder_use_inplace(apir_decoder * dec, size_t size) { if (unlikely(size > (size_t) (dec->end - dec->cur))) { GGML_LOG_ERROR("%s: reading too much from the decoder ...\n", __func__); apir_decoder_set_fatal(dec); return NULL; } const void * addr = dec->cur; dec->cur += size; return addr; } /* * read/write */ static inline void apir_decoder_read(apir_decoder * dec, size_t size, void * val, size_t val_size) { if (apir_decoder_peek_internal(dec, size, val, val_size)) { dec->cur += size; } } static inline char * apir_encoder_write(apir_encoder * enc, size_t size, const void * val, size_t val_size) { assert(val_size <= size); assert(size <= ((size_t) (enc->end - enc->cur))); char * write_addr = enc->cur; /* we should not rely on the compiler to optimize away memcpy... */ memcpy(write_addr, val, val_size); enc->cur += size; return write_addr; } /* * encode/decode */ static inline void apir_decode(apir_decoder * dec, size_t size, void * data, size_t data_size) { assert(size % 4 == 0); apir_decoder_read(dec, size, data, data_size); } static inline void apir_encode(apir_encoder * enc, size_t size, const void * data, size_t data_size) { assert(size % 4 == 0); apir_encoder_write(enc, size, data, data_size); } /* * typed encode/decode */ /* uint8_t */ static inline void apir_encode_uint8_t(apir_encoder * enc, const uint8_t * val) { apir_encode(enc, sizeof(int), val, sizeof(*val)); } static inline void apir_decode_uint8_t(apir_decoder * dec, uint8_t * val) { apir_decode(dec, sizeof(int), val, sizeof(*val)); } /* uint64_t */ static inline void apir_encode_uint64_t(apir_encoder * enc, const uint64_t * val) { apir_encode(enc, 8, val, sizeof(*val)); } static inline void apir_decode_uint64_t(apir_decoder * dec, uint64_t * val) { apir_decode(dec, 8, val, sizeof(*val)); } static inline void apir_encode_uint64_t_array(apir_encoder * enc, const uint64_t * val, uint32_t count) { const size_t size = sizeof(*val) * count; assert(size >= count); apir_encode(enc, size, val, size); } static inline void apir_decode_uint64_t_array(apir_decoder * dec, uint64_t * val, uint32_t count) { const size_t size = sizeof(*val) * count; assert(size >= count); apir_decode(dec, size, val, size); } static inline const uint64_t * apir_decode_uint64_t_array_inplace(apir_decoder * dec, uint32_t count) { return (uint64_t *) (uintptr_t) apir_decoder_use_inplace(dec, count * sizeof(uint64_t)); } /* int32_t */ static inline void apir_encode_int32_t(apir_encoder * enc, const int32_t * val) { apir_encode(enc, 4, val, sizeof(*val)); } static inline void apir_decode_int32_t(apir_decoder * dec, int32_t * val) { apir_decode(dec, 4, val, sizeof(*val)); } static inline void apir_encode_int32_t_array(apir_encoder * enc, const int32_t * val, uint32_t count) { const size_t size = sizeof(*val) * count; assert(size >= count); apir_encode(enc, size, val, size); } static inline void apir_decode_int32_t_array(apir_decoder * dec, int32_t * val, uint32_t count) { const size_t size = sizeof(*val) * count; assert(size >= count); apir_decode(dec, size, val, size); } /* array size (uint64_t) */ static inline void apir_encode_array_size(apir_encoder * enc, uint64_t size) { apir_encode_uint64_t(enc, &size); } static inline uint64_t apir_decode_array_size(apir_decoder * dec, uint64_t expected_size) { uint64_t size; apir_decode_uint64_t(dec, &size); if (size != expected_size) { GGML_LOG_ERROR("%s: Couldn't decode array from the decoder\n", __func__); apir_decoder_set_fatal(dec); size = 0; } return size; } static inline uint64_t apir_decode_array_size_unchecked(apir_decoder * dec) { uint64_t size; apir_decode_uint64_t(dec, &size); return size; } /* non-array pointer */ static inline bool apir_encode_simple_pointer(apir_encoder * enc, const void * val) { apir_encode_array_size(enc, val ? 1 : 0); return val; } static inline bool apir_decode_simple_pointer(apir_decoder * dec) { return apir_decode_array_size_unchecked(dec); } /* uint32_t */ static inline void apir_encode_uint32_t(apir_encoder * enc, const uint32_t * val) { apir_encode(enc, 4, val, sizeof(*val)); } static inline void apir_decode_uint32_t(apir_decoder * dec, uint32_t * val) { apir_decode(dec, 4, val, sizeof(*val)); } static inline void apir_encode_uint32_t_array(apir_encoder * enc, const uint32_t * val, uint32_t count) { const size_t size = sizeof(*val) * count; assert(size >= count); apir_encode(enc, size, val, size); } static inline void apir_decode_uint32_t_array(apir_decoder * dec, uint32_t * val, uint32_t count) { const size_t size = sizeof(*val) * count; assert(size >= count); apir_decode(dec, size, val, size); } /* size_t */ static inline void apir_encode_size_t(apir_encoder * enc, const size_t * val) { const uint64_t tmp = *val; apir_encode_uint64_t(enc, &tmp); } static inline void apir_decode_size_t(apir_decoder * dec, size_t * val) { uint64_t tmp; apir_decode_uint64_t(dec, &tmp); *val = tmp; } static inline void apir_encode_size_t_array(apir_encoder * enc, const size_t * val, uint32_t count) { if (sizeof(size_t) == sizeof(uint64_t)) { apir_encode_uint64_t_array(enc, (const uint64_t *) val, count); } else { for (uint32_t i = 0; i < count; i++) { apir_encode_size_t(enc, &val[i]); } } } static inline void apir_decode_size_t_array(apir_decoder * dec, size_t * val, uint32_t count) { if (sizeof(size_t) == sizeof(uint64_t)) { apir_decode_uint64_t_array(dec, (uint64_t *) val, count); } else { for (uint32_t i = 0; i < count; i++) { apir_decode_size_t(dec, &val[i]); } } } /* opaque blob */ static inline void apir_encode_blob_array(apir_encoder * enc, const void * val, size_t size) { apir_encode(enc, (size + 3) & ~3, val, size); } static inline void apir_decode_blob_array(apir_decoder * dec, void * val, size_t size) { apir_decode(dec, (size + 3) & ~3, val, size); } /* string */ static inline void apir_encode_char_array(apir_encoder * enc, const char * val, size_t size) { assert(size && strlen(val) < size); apir_encode_blob_array(enc, val, size); } static inline void apir_decode_char_array(apir_decoder * dec, char * val, size_t size) { apir_decode_blob_array(dec, val, size); if (size) { val[size - 1] = '\0'; } else { GGML_LOG_ERROR("%s: Couldn't decode the blog array\n", __func__); apir_decoder_set_fatal(dec); } } /* (temp) buffer allocation */ static inline void * apir_decoder_alloc_array(size_t size, size_t count) { size_t alloc_size; if (unlikely(__builtin_mul_overflow(size, count, &alloc_size))) { GGML_LOG_ERROR("%s: overflow in array allocation of %zu * %zu bytes\n", __func__, size, count); return NULL; } return malloc(alloc_size); } /* bool */ static inline void apir_encode_bool_t(apir_encoder * enc, const bool * val) { apir_encode(enc, sizeof(int), val, sizeof(bool)); } static inline void apir_decode_bool_t(apir_decoder * dec, bool * val) { apir_decode(dec, sizeof(int), val, sizeof(bool)); } /* apir_buffer_type_host_handle_t */ static inline void apir_encode_apir_buffer_type_host_handle_t(apir_encoder * enc, const apir_buffer_type_host_handle_t * val) { apir_encode(enc, sizeof(apir_buffer_type_host_handle_t), val, sizeof(apir_buffer_type_host_handle_t)); } static inline void apir_decode_apir_buffer_type_host_handle_t(apir_decoder * dec, apir_buffer_type_host_handle_t * val) { apir_decode(dec, sizeof(apir_buffer_type_host_handle_t), val, sizeof(apir_buffer_type_host_handle_t)); } /* apir_buffer_host_handle_t */ static inline void apir_encode_apir_buffer_host_handle_t(apir_encoder * enc, const apir_buffer_host_handle_t * val) { apir_encode(enc, sizeof(apir_buffer_host_handle_t), val, sizeof(apir_buffer_host_handle_t)); } static inline void apir_decode_apir_buffer_host_handle_t(apir_decoder * dec, apir_buffer_host_handle_t * val) { apir_decode(dec, sizeof(apir_buffer_host_handle_t), val, sizeof(apir_buffer_host_handle_t)); } /* uintptr_t */ static inline void apir_encode_uintptr_t(apir_encoder * enc, const uintptr_t * val) { apir_encode(enc, sizeof(*val), val, sizeof(*val)); } static inline void apir_decode_uintptr_t(apir_decoder * dec, uintptr_t * val) { apir_decode(dec, sizeof(*val), val, sizeof(*val)); }