/* * Copyright (c) 2019 TAOS Data, Inc. * * This program is free software: you can use, redistribute, and/or modify * it under the terms of the GNU Affero General Public License, version 3 * or later ("AGPL"), as published by the Free Software Foundation. * * This program 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. * * You should have received a copy of the GNU Affero General Public License * along with this program. If not, see . */ #ifndef _TD_UTIL_ENCODE_H_ #define _TD_UTIL_ENCODE_H_ #include "tcoding.h" #include "tlist.h" #ifdef __cplusplus extern "C" { #endif typedef struct SEncoderNode SEncoderNode; typedef struct SDecoderNode SDecoderNode; typedef struct SCoderMem { struct SCoderMem* next; } SCoderMem; typedef struct { uint8_t* data; uint32_t size; uint32_t pos; SCoderMem* mList; SEncoderNode* eStack; } SEncoder; typedef struct { uint8_t* data; uint32_t size; uint32_t pos; SCoderMem* mList; SDecoderNode* dStack; } SDecoder; #define tPut(TYPE, BUF, VAL) ((TYPE*)(BUF))[0] = (VAL) #define tGet(TYPE, BUF, VAL) (VAL) = ((TYPE*)(BUF))[0] #define tRPut16(PDEST, PSRC) \ ((uint8_t*)(PDEST))[0] = ((uint8_t*)(PSRC))[1]; \ ((uint8_t*)(PDEST))[1] = ((uint8_t*)(PSRC))[0]; #define tRPut32(PDEST, PSRC) \ ((uint8_t*)(PDEST))[0] = ((uint8_t*)(PSRC))[3]; \ ((uint8_t*)(PDEST))[1] = ((uint8_t*)(PSRC))[2]; \ ((uint8_t*)(PDEST))[2] = ((uint8_t*)(PSRC))[1]; \ ((uint8_t*)(PDEST))[3] = ((uint8_t*)(PSRC))[0]; #define tRPut64(PDEST, PSRC) \ ((uint8_t*)(PDEST))[0] = ((uint8_t*)(PSRC))[7]; \ ((uint8_t*)(PDEST))[1] = ((uint8_t*)(PSRC))[6]; \ ((uint8_t*)(PDEST))[2] = ((uint8_t*)(PSRC))[5]; \ ((uint8_t*)(PDEST))[3] = ((uint8_t*)(PSRC))[4]; \ ((uint8_t*)(PDEST))[4] = ((uint8_t*)(PSRC))[3]; \ ((uint8_t*)(PDEST))[5] = ((uint8_t*)(PSRC))[2]; \ ((uint8_t*)(PDEST))[6] = ((uint8_t*)(PSRC))[1]; \ ((uint8_t*)(PDEST))[7] = ((uint8_t*)(PSRC))[0]; #define tRGet16 tRPut16 #define tRGet32 tRPut32 #define tRGet64 tRPut64 #define TD_CODER_POS(CODER) ((CODER)->pos) #define TD_CODER_CURRENT(CODER) ((CODER)->data + (CODER)->pos) #define TD_CODER_MOVE_POS(CODER, MOVE) ((CODER)->pos += (MOVE)) #define TD_CODER_CHECK_CAPACITY_FAILED(CODER, EXPSIZE) (((CODER)->size - (CODER)->pos) < (EXPSIZE)) #define tEncodeSize(E, S, SIZE, RET) \ do { \ SEncoder coder = {0}; \ tEncoderInit(&coder, NULL, 0); \ if ((E)(&coder, S) >= 0) { \ SIZE = coder.pos; \ RET = 0; \ } else { \ RET = -1; \ } \ tEncoderClear(&coder); \ } while (0) static void* tEncoderMalloc(SEncoder* pCoder, int32_t size); static void* tDecoderMalloc(SDecoder* pCoder, int32_t size); /* ------------------------ ENCODE ------------------------ */ void tEncoderInit(SEncoder* pCoder, uint8_t* data, uint32_t size); void tEncoderClear(SEncoder* pCoder); int32_t tStartEncode(SEncoder* pCoder); void tEndEncode(SEncoder* pCoder); static int32_t tEncodeU8(SEncoder* pCoder, uint8_t val); static int32_t tEncodeI8(SEncoder* pCoder, int8_t val); static int32_t tEncodeU16(SEncoder* pCoder, uint16_t val); static int32_t tEncodeI16(SEncoder* pCoder, int16_t val); static int32_t tEncodeU32(SEncoder* pCoder, uint32_t val); static int32_t tEncodeI32(SEncoder* pCoder, int32_t val); static int32_t tEncodeU64(SEncoder* pCoder, uint64_t val); static int32_t tEncodeI64(SEncoder* pCoder, int64_t val); static int32_t tEncodeU16v(SEncoder* pCoder, uint16_t val); static int32_t tEncodeI16v(SEncoder* pCoder, int16_t val); static int32_t tEncodeU32v(SEncoder* pCoder, uint32_t val); static int32_t tEncodeI32v(SEncoder* pCoder, int32_t val); static int32_t tEncodeU64v(SEncoder* pCoder, uint64_t val); static int32_t tEncodeI64v(SEncoder* pCoder, int64_t val); static int32_t tEncodeFloat(SEncoder* pCoder, float val); static int32_t tEncodeDouble(SEncoder* pCoder, double val); static int32_t tEncodeBinary(SEncoder* pCoder, const uint8_t* val, uint32_t len); static int32_t tEncodeCStrWithLen(SEncoder* pCoder, const char* val, uint32_t len); static int32_t tEncodeCStr(SEncoder* pCoder, const char* val); /* ------------------------ DECODE ------------------------ */ void tDecoderInit(SDecoder* pCoder, uint8_t* data, uint32_t size); void tDecoderClear(SDecoder* SDecoder); int32_t tStartDecode(SDecoder* pCoder); void tEndDecode(SDecoder* pCoder); static bool tDecodeIsEnd(SDecoder* pCoder); static int32_t tDecodeU8(SDecoder* pCoder, uint8_t* val); static int32_t tDecodeI8(SDecoder* pCoder, int8_t* val); static int32_t tDecodeU16(SDecoder* pCoder, uint16_t* val); static int32_t tDecodeI16(SDecoder* pCoder, int16_t* val); static int32_t tDecodeU32(SDecoder* pCoder, uint32_t* val); static int32_t tDecodeI32(SDecoder* pCoder, int32_t* val); static int32_t tDecodeU64(SDecoder* pCoder, uint64_t* val); static int32_t tDecodeI64(SDecoder* pCoder, int64_t* val); static int32_t tDecodeU16v(SDecoder* pCoder, uint16_t* val); static int32_t tDecodeI16v(SDecoder* pCoder, int16_t* val); static int32_t tDecodeU32v(SDecoder* pCoder, uint32_t* val); static int32_t tDecodeI32v(SDecoder* pCoder, int32_t* val); static int32_t tDecodeU64v(SDecoder* pCoder, uint64_t* val); static int32_t tDecodeI64v(SDecoder* pCoder, int64_t* val); static int32_t tDecodeFloat(SDecoder* pCoder, float* val); static int32_t tDecodeDouble(SDecoder* pCoder, double* val); static int32_t tDecodeBinary(SDecoder* pCoder, uint8_t** val, uint32_t* len); static int32_t tDecodeCStrAndLen(SDecoder* pCoder, char** val, uint32_t* len); static int32_t tDecodeCStr(SDecoder* pCoder, char** val); static int32_t tDecodeCStrTo(SDecoder* pCoder, char* val); /* ------------------------ IMPL ------------------------ */ #define TD_ENCODE_MACRO(CODER, VAL, TYPE, BITS) \ if ((CODER)->data) { \ if (TD_CODER_CHECK_CAPACITY_FAILED(CODER, sizeof(VAL))) return -1; \ tPut(TYPE, TD_CODER_CURRENT(CODER), (VAL)); \ } \ TD_CODER_MOVE_POS(CODER, sizeof(VAL)); \ return 0; #define TD_ENCODE_VARIANT_MACRO(CODER, VAL) \ while ((VAL) >= ENCODE_LIMIT) { \ if ((CODER)->data) { \ if (TD_CODER_CHECK_CAPACITY_FAILED(CODER, 1)) return -1; \ TD_CODER_CURRENT(CODER)[0] = ((VAL) | ENCODE_LIMIT) & 0xff; \ } \ \ (VAL) >>= 7; \ TD_CODER_MOVE_POS(CODER, 1); \ } \ \ if ((CODER)->data) { \ if (TD_CODER_CHECK_CAPACITY_FAILED(CODER, 1)) return -1; \ TD_CODER_CURRENT(CODER)[0] = (uint8_t)(VAL); \ } \ TD_CODER_MOVE_POS(CODER, 1); \ return 0; #define TD_DECODE_MACRO(CODER, PVAL, TYPE, BITS) \ if (TD_CODER_CHECK_CAPACITY_FAILED(CODER, sizeof(*(PVAL)))) return -1; \ tGet(TYPE, TD_CODER_CURRENT(CODER), *(PVAL)); \ TD_CODER_MOVE_POS(CODER, sizeof(*(PVAL))); \ return 0; #define TD_DECODE_VARIANT_MACRO(CODER, PVAL, TYPE) \ int32_t i = 0; \ if (PVAL) *(PVAL) = 0; \ for (;;) { \ if (TD_CODER_CHECK_CAPACITY_FAILED(CODER, 1)) return -1; \ TYPE tval = TD_CODER_CURRENT(CODER)[0]; \ if (tval < ENCODE_LIMIT) { \ if (PVAL) *(PVAL) |= (tval << (7 * i)); \ TD_CODER_MOVE_POS(pCoder, 1); \ break; \ } else { \ if (PVAL) *(PVAL) |= (((tval) & (ENCODE_LIMIT - 1)) << (7 * i)); \ i++; \ TD_CODER_MOVE_POS(pCoder, 1); \ } \ } \ \ return 0; // 8 static FORCE_INLINE int32_t tEncodeU8(SEncoder* pCoder, uint8_t val) { if (pCoder->data) { if (TD_CODER_CHECK_CAPACITY_FAILED(pCoder, sizeof(val))) return -1; tPut(uint8_t, TD_CODER_CURRENT(pCoder), val); } TD_CODER_MOVE_POS(pCoder, sizeof(val)); return 0; } static FORCE_INLINE int32_t tEncodeI8(SEncoder* pCoder, int8_t val) { if (pCoder->data) { if (TD_CODER_CHECK_CAPACITY_FAILED(pCoder, sizeof(val))) return -1; tPut(int8_t, TD_CODER_CURRENT(pCoder), val); } TD_CODER_MOVE_POS(pCoder, sizeof(val)); return 0; } // 16 static FORCE_INLINE int32_t tEncodeU16(SEncoder* pCoder, uint16_t val) { TD_ENCODE_MACRO(pCoder, val, uint16_t, 16); } static FORCE_INLINE int32_t tEncodeI16(SEncoder* pCoder, int16_t val) { TD_ENCODE_MACRO(pCoder, val, int16_t, 16); } // 32 static FORCE_INLINE int32_t tEncodeU32(SEncoder* pCoder, uint32_t val) { TD_ENCODE_MACRO(pCoder, val, uint32_t, 32); } static FORCE_INLINE int32_t tEncodeI32(SEncoder* pCoder, int32_t val) { TD_ENCODE_MACRO(pCoder, val, int32_t, 32); } // 64 static FORCE_INLINE int32_t tEncodeU64(SEncoder* pCoder, uint64_t val) { TD_ENCODE_MACRO(pCoder, val, uint64_t, 64); } static FORCE_INLINE int32_t tEncodeI64(SEncoder* pCoder, int64_t val) { TD_ENCODE_MACRO(pCoder, val, int64_t, 64); } // 16v static FORCE_INLINE int32_t tEncodeU16v(SEncoder* pCoder, uint16_t val) { TD_ENCODE_VARIANT_MACRO(pCoder, val); } static FORCE_INLINE int32_t tEncodeI16v(SEncoder* pCoder, int16_t val) { return tEncodeU16v(pCoder, ZIGZAGE(int16_t, val)); } // 32v static FORCE_INLINE int32_t tEncodeU32v(SEncoder* pCoder, uint32_t val) { TD_ENCODE_VARIANT_MACRO(pCoder, val); } static FORCE_INLINE int32_t tEncodeI32v(SEncoder* pCoder, int32_t val) { return tEncodeU32v(pCoder, ZIGZAGE(int32_t, val)); } // 64v static FORCE_INLINE int32_t tEncodeU64v(SEncoder* pCoder, uint64_t val) { TD_ENCODE_VARIANT_MACRO(pCoder, val); } static FORCE_INLINE int32_t tEncodeI64v(SEncoder* pCoder, int64_t val) { return tEncodeU64v(pCoder, ZIGZAGE(int64_t, val)); } static FORCE_INLINE int32_t tEncodeFloat(SEncoder* pCoder, float val) { union { uint32_t ui; float f; } v; v.f = val; return tEncodeU32(pCoder, v.ui); } static FORCE_INLINE int32_t tEncodeDouble(SEncoder* pCoder, double val) { union { uint64_t ui; double d; } v; v.d = val; return tEncodeU64(pCoder, v.ui); } static FORCE_INLINE int32_t tEncodeBinary(SEncoder* pCoder, const uint8_t* val, uint32_t len) { if (tEncodeU32v(pCoder, len) < 0) return -1; if (pCoder->data) { if (TD_CODER_CHECK_CAPACITY_FAILED(pCoder, len)) return -1; memcpy(TD_CODER_CURRENT(pCoder), val, len); } TD_CODER_MOVE_POS(pCoder, len); return 0; } static FORCE_INLINE int32_t tEncodeCStrWithLen(SEncoder* pCoder, const char* val, uint32_t len) { return tEncodeBinary(pCoder, (uint8_t*)val, len + 1); } static FORCE_INLINE int32_t tEncodeCStr(SEncoder* pCoder, const char* val) { return tEncodeCStrWithLen(pCoder, val, (uint32_t)strlen(val)); } /* ------------------------ FOR DECODER ------------------------ */ // 8 static FORCE_INLINE int32_t tDecodeU8(SDecoder* pCoder, uint8_t* val) { if (TD_CODER_CHECK_CAPACITY_FAILED(pCoder, sizeof(*val))) return -1; tGet(uint8_t, TD_CODER_CURRENT(pCoder), *val); TD_CODER_MOVE_POS(pCoder, sizeof(*val)); return 0; } static FORCE_INLINE int32_t tDecodeI8(SDecoder* pCoder, int8_t* val) { if (TD_CODER_CHECK_CAPACITY_FAILED(pCoder, sizeof(*val))) return -1; tGet(int8_t, TD_CODER_CURRENT(pCoder), *val); TD_CODER_MOVE_POS(pCoder, sizeof(*val)); return 0; } // 16 static FORCE_INLINE int32_t tDecodeU16(SDecoder* pCoder, uint16_t* val) { TD_DECODE_MACRO(pCoder, val, uint16_t, 16); } static FORCE_INLINE int32_t tDecodeI16(SDecoder* pCoder, int16_t* val) { TD_DECODE_MACRO(pCoder, val, int16_t, 16); } // 32 static FORCE_INLINE int32_t tDecodeU32(SDecoder* pCoder, uint32_t* val) { TD_DECODE_MACRO(pCoder, val, uint32_t, 32); } static FORCE_INLINE int32_t tDecodeI32(SDecoder* pCoder, int32_t* val) { TD_DECODE_MACRO(pCoder, val, int32_t, 32); } // 64 static FORCE_INLINE int32_t tDecodeU64(SDecoder* pCoder, uint64_t* val) { TD_DECODE_MACRO(pCoder, val, uint64_t, 64); } static FORCE_INLINE int32_t tDecodeI64(SDecoder* pCoder, int64_t* val) { TD_DECODE_MACRO(pCoder, val, int64_t, 64); } // 16v static FORCE_INLINE int32_t tDecodeU16v(SDecoder* pCoder, uint16_t* val) { TD_DECODE_VARIANT_MACRO(pCoder, val, uint16_t); } static FORCE_INLINE int32_t tDecodeI16v(SDecoder* pCoder, int16_t* val) { uint16_t tval; if (tDecodeU16v(pCoder, &tval) < 0) { return -1; } if (val) *val = ZIGZAGD(int16_t, tval); return 0; } // 32v static FORCE_INLINE int32_t tDecodeU32v(SDecoder* pCoder, uint32_t* val) { TD_DECODE_VARIANT_MACRO(pCoder, val, uint32_t); } static FORCE_INLINE int32_t tDecodeI32v(SDecoder* pCoder, int32_t* val) { uint32_t tval; if (tDecodeU32v(pCoder, &tval) < 0) { return -1; } if (val) *val = ZIGZAGD(int32_t, tval); return 0; } // 64v static FORCE_INLINE int32_t tDecodeU64v(SDecoder* pCoder, uint64_t* val) { TD_DECODE_VARIANT_MACRO(pCoder, val, uint64_t); } static FORCE_INLINE int32_t tDecodeI64v(SDecoder* pCoder, int64_t* val) { uint64_t tval; if (tDecodeU64v(pCoder, &tval) < 0) { return -1; } if (val) *val = ZIGZAGD(int64_t, tval); return 0; } static FORCE_INLINE int32_t tDecodeFloat(SDecoder* pCoder, float* val) { union { uint32_t ui; float f; } v; if (tDecodeU32(pCoder, &(v.ui)) < 0) { return -1; } *val = v.f; return 0; } static FORCE_INLINE int32_t tDecodeDouble(SDecoder* pCoder, double* val) { union { uint64_t ui; double d; } v; if (tDecodeU64(pCoder, &(v.ui)) < 0) { return -1; } *val = v.d; return 0; } static FORCE_INLINE int32_t tDecodeBinary(SDecoder* pCoder, uint8_t** val, uint32_t* len) { uint32_t length = 0; if (tDecodeU32v(pCoder, &length) < 0) return -1; if (len) *len = length; if (TD_CODER_CHECK_CAPACITY_FAILED(pCoder, length)) return -1; if (val) { *val = (uint8_t*)TD_CODER_CURRENT(pCoder); } TD_CODER_MOVE_POS(pCoder, length); return 0; } static FORCE_INLINE int32_t tDecodeCStrAndLen(SDecoder* pCoder, char** val, uint32_t* len) { if (tDecodeBinary(pCoder, (uint8_t**)val, len) < 0) return -1; (*len) -= 1; return 0; } static FORCE_INLINE int32_t tDecodeCStr(SDecoder* pCoder, char** val) { uint32_t len; return tDecodeCStrAndLen(pCoder, val, &len); } static int32_t tDecodeCStrTo(SDecoder* pCoder, char* val) { char* pStr; uint32_t len; if (tDecodeCStrAndLen(pCoder, &pStr, &len) < 0) return -1; memcpy(val, pStr, len + 1); return 0; } static FORCE_INLINE int32_t tDecodeBinaryAlloc(SDecoder* pCoder, void** val, uint64_t* len) { uint64_t length = 0; if (tDecodeU64v(pCoder, &length) < 0) return -1; if (len) *len = length; if (TD_CODER_CHECK_CAPACITY_FAILED(pCoder, length)) return -1; *val = taosMemoryMalloc(length); if (*val == NULL) return -1; memcpy(*val, TD_CODER_CURRENT(pCoder), length); TD_CODER_MOVE_POS(pCoder, length); return 0; } static FORCE_INLINE int32_t tDecodeCStrAndLenAlloc(SDecoder* pCoder, char** val, uint64_t* len) { if (tDecodeBinaryAlloc(pCoder, (void**)val, len) < 0) return -1; (*len) -= 1; return 0; } static FORCE_INLINE int32_t tDecodeCStrAlloc(SDecoder* pCoder, char** val) { uint64_t len; return tDecodeCStrAndLenAlloc(pCoder, val, &len); } static FORCE_INLINE bool tDecodeIsEnd(SDecoder* pCoder) { return (pCoder->size == pCoder->pos); } static FORCE_INLINE void* tEncoderMalloc(SEncoder* pCoder, int32_t size) { void* p = NULL; SCoderMem* pMem = (SCoderMem*)taosMemoryMalloc(sizeof(*pMem) + size); if (pMem) { pMem->next = pCoder->mList; pCoder->mList = pMem; p = (void*)&pMem[1]; } return p; } static FORCE_INLINE void* tDecoderMalloc(SDecoder* pCoder, int32_t size) { void* p = NULL; SCoderMem* pMem = (SCoderMem*)taosMemoryMalloc(sizeof(*pMem) + size); if (pMem) { pMem->next = pCoder->mList; pCoder->mList = pMem; p = (void*)&pMem[1]; } return p; } // =========================================== #define tPutV(p, v) \ do { \ int32_t n = 0; \ for (;;) { \ if (v <= 0x7f) { \ if (p) p[n] = v; \ n++; \ break; \ } \ if (p) p[n] = (v & 0x7f) | 0x80; \ n++; \ v >>= 7; \ } \ return n; \ } while (0) #define tGetV(p, v) \ do { \ int32_t n = 0; \ if (v) *v = 0; \ for (;;) { \ if (p[n] <= 0x7f) { \ if (v) (*v) |= (p[n] << (7 * n)); \ n++; \ break; \ } \ if (v) (*v) |= ((p[n] & 0x7f) << (7 * n)); \ n++; \ } \ return n; \ } while (0) // PUT static FORCE_INLINE int32_t tPutU8(uint8_t* p, uint8_t v) { if (p) ((uint8_t*)p)[0] = v; return sizeof(uint8_t); } static FORCE_INLINE int32_t tPutI8(uint8_t* p, int8_t v) { if (p) ((int8_t*)p)[0] = v; return sizeof(int8_t); } static FORCE_INLINE int32_t tPutU16(uint8_t* p, uint16_t v) { if (p) ((uint16_t*)p)[0] = v; return sizeof(uint16_t); } static FORCE_INLINE int32_t tPutI16(uint8_t* p, int16_t v) { if (p) ((int16_t*)p)[0] = v; return sizeof(int16_t); } static FORCE_INLINE int32_t tPutU32(uint8_t* p, uint32_t v) { if (p) ((uint32_t*)p)[0] = v; return sizeof(uint32_t); } static FORCE_INLINE int32_t tPutI32(uint8_t* p, int32_t v) { if (p) ((int32_t*)p)[0] = v; return sizeof(int32_t); } static FORCE_INLINE int32_t tPutU64(uint8_t* p, uint64_t v) { if (p) ((uint64_t*)p)[0] = v; return sizeof(uint64_t); } static FORCE_INLINE int32_t tPutI64(uint8_t* p, int64_t v) { if (p) ((int64_t*)p)[0] = v; return sizeof(int64_t); } static FORCE_INLINE int32_t tPutU16v(uint8_t* p, uint16_t v) { tPutV(p, v); } static FORCE_INLINE int32_t tPutI16v(uint8_t* p, int16_t v) { return tPutU16v(p, ZIGZAGE(int16_t, v)); } static FORCE_INLINE int32_t tPutU32v(uint8_t* p, uint32_t v) { tPutV(p, v); } static FORCE_INLINE int32_t tPutI32v(uint8_t* p, int32_t v) { return tPutU32v(p, ZIGZAGE(int32_t, v)); } static FORCE_INLINE int32_t tPutU64v(uint8_t* p, uint64_t v) { tPutV(p, v); } static FORCE_INLINE int32_t tPutI64v(uint8_t* p, int64_t v) { return tPutU64v(p, ZIGZAGE(int64_t, v)); } // GET static FORCE_INLINE int32_t tGetU8(uint8_t* p, uint8_t* v) { if (v) *v = ((uint8_t*)p)[0]; return sizeof(uint8_t); } static FORCE_INLINE int32_t tGetI8(uint8_t* p, int8_t* v) { if (v) *v = ((int8_t*)p)[0]; return sizeof(int8_t); } static FORCE_INLINE int32_t tGetU16(uint8_t* p, uint16_t* v) { if (v) *v = ((uint16_t*)p)[0]; return sizeof(uint16_t); } static FORCE_INLINE int32_t tGetI16(uint8_t* p, int16_t* v) { if (v) *v = ((int16_t*)p)[0]; return sizeof(int16_t); } static FORCE_INLINE int32_t tGetU32(uint8_t* p, uint32_t* v) { if (v) *v = ((uint32_t*)p)[0]; return sizeof(uint32_t); } static FORCE_INLINE int32_t tGetI32(uint8_t* p, int32_t* v) { if (v) *v = ((int32_t*)p)[0]; return sizeof(int32_t); } static FORCE_INLINE int32_t tGetU64(uint8_t* p, uint64_t* v) { if (v) *v = ((uint64_t*)p)[0]; return sizeof(uint64_t); } static FORCE_INLINE int32_t tGetI64(uint8_t* p, int64_t* v) { if (v) *v = ((int64_t*)p)[0]; return sizeof(int64_t); } static FORCE_INLINE int32_t tGetU16v(uint8_t* p, uint16_t* v) { tGetV(p, v); } static FORCE_INLINE int32_t tGetI16v(uint8_t* p, int16_t* v) { int32_t n; uint16_t tv; n = tGetU16v(p, &tv); if (v) *v = ZIGZAGD(int16_t, tv); return n; } static FORCE_INLINE int32_t tGetU32v(uint8_t* p, uint32_t* v) { tGetV(p, v); } static FORCE_INLINE int32_t tGetI32v(uint8_t* p, int32_t* v) { int32_t n; uint32_t tv; n = tGetU32v(p, &tv); if (v) *v = ZIGZAGD(int32_t, tv); return n; } static FORCE_INLINE int32_t tGetU64v(uint8_t* p, uint64_t* v) { tGetV(p, v); } static FORCE_INLINE int32_t tGetI64v(uint8_t* p, int64_t* v) { int32_t n; uint64_t tv; n = tGetU64v(p, &tv); if (v) *v = ZIGZAGD(int64_t, tv); return n; } // ===================== static FORCE_INLINE int32_t tPutBinary(uint8_t* p, uint8_t* pData, uint32_t nData) { int n = 0; n += tPutU32v(p ? p + n : p, nData); if (p) memcpy(p + n, pData, nData); n += nData; return n; } static FORCE_INLINE int32_t tGetBinary(uint8_t* p, uint8_t** ppData, uint32_t* nData) { int32_t n = 0; uint32_t nt; n += tGetU32v(p, &nt); if (nData) *nData = nt; if (ppData) *ppData = p + n; n += nt; return n; } #ifdef __cplusplus } #endif #endif /*_TD_UTIL_ENCODE_H_*/