//===--- Compression.cpp - Compression implementation ---------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file implements compression functions. // //===----------------------------------------------------------------------===// #include "llvm/Support/Compression.h" #include "llvm/ADT/SmallVector.h" #include "llvm/ADT/StringRef.h" #include "llvm/Config/config.h" #include "llvm/Support/Compiler.h" #include "llvm/Support/Error.h" #include "llvm/Support/ErrorHandling.h" #if LLVM_ENABLE_ZLIB #include #endif #if LLVM_ENABLE_ZSTD #include #endif using namespace llvm; using namespace llvm::compression; #if LLVM_ENABLE_ZLIB static StringRef convertZlibCodeToString(int Code) { switch (Code) { case Z_MEM_ERROR: return "zlib error: Z_MEM_ERROR"; case Z_BUF_ERROR: return "zlib error: Z_BUF_ERROR"; case Z_STREAM_ERROR: return "zlib error: Z_STREAM_ERROR"; case Z_DATA_ERROR: return "zlib error: Z_DATA_ERROR"; case Z_OK: default: llvm_unreachable("unknown or unexpected zlib status code"); } } bool zlib::isAvailable() { return true; } void zlib::compress(ArrayRef Input, SmallVectorImpl &CompressedBuffer, int Level) { unsigned long CompressedSize = ::compressBound(Input.size()); CompressedBuffer.resize_for_overwrite(CompressedSize); int Res = ::compress2((Bytef *)CompressedBuffer.data(), &CompressedSize, (const Bytef *)Input.data(), Input.size(), Level); if (Res == Z_MEM_ERROR) report_bad_alloc_error("Allocation failed"); assert(Res == Z_OK); // Tell MemorySanitizer that zlib output buffer is fully initialized. // This avoids a false report when running LLVM with uninstrumented ZLib. __msan_unpoison(CompressedBuffer.data(), CompressedSize); if (CompressedSize < CompressedBuffer.size()) CompressedBuffer.truncate(CompressedSize); } Error zlib::uncompress(ArrayRef Input, uint8_t *UncompressedBuffer, size_t &UncompressedSize) { int Res = ::uncompress((Bytef *)UncompressedBuffer, (uLongf *)&UncompressedSize, (const Bytef *)Input.data(), Input.size()); // Tell MemorySanitizer that zlib output buffer is fully initialized. // This avoids a false report when running LLVM with uninstrumented ZLib. __msan_unpoison(UncompressedBuffer, UncompressedSize); return Res ? make_error(convertZlibCodeToString(Res), inconvertibleErrorCode()) : Error::success(); } Error zlib::uncompress(ArrayRef Input, SmallVectorImpl &UncompressedBuffer, size_t UncompressedSize) { UncompressedBuffer.resize_for_overwrite(UncompressedSize); Error E = zlib::uncompress(Input, UncompressedBuffer.data(), UncompressedSize); if (UncompressedSize < UncompressedBuffer.size()) UncompressedBuffer.truncate(UncompressedSize); return E; } #else bool zlib::isAvailable() { return false; } void zlib::compress(ArrayRef Input, SmallVectorImpl &CompressedBuffer, int Level) { llvm_unreachable("zlib::compress is unavailable"); } Error zlib::uncompress(ArrayRef Input, uint8_t *UncompressedBuffer, size_t &UncompressedSize) { llvm_unreachable("zlib::uncompress is unavailable"); } Error zlib::uncompress(ArrayRef Input, SmallVectorImpl &UncompressedBuffer, size_t UncompressedSize) { llvm_unreachable("zlib::uncompress is unavailable"); } #endif #if LLVM_ENABLE_ZSTD bool zstd::isAvailable() { return true; } void zstd::compress(ArrayRef Input, SmallVectorImpl &CompressedBuffer, int Level) { unsigned long CompressedBufferSize = ::ZSTD_compressBound(Input.size()); CompressedBuffer.resize_for_overwrite(CompressedBufferSize); unsigned long CompressedSize = ::ZSTD_compress((char *)CompressedBuffer.data(), CompressedBufferSize, (const char *)Input.data(), Input.size(), Level); if (ZSTD_isError(CompressedSize)) report_bad_alloc_error("Allocation failed"); // Tell MemorySanitizer that zstd output buffer is fully initialized. // This avoids a false report when running LLVM with uninstrumented ZLib. __msan_unpoison(CompressedBuffer.data(), CompressedSize); if (CompressedSize < CompressedBuffer.size()) CompressedBuffer.truncate(CompressedSize); } Error zstd::uncompress(ArrayRef Input, uint8_t *UncompressedBuffer, size_t &UncompressedSize) { const size_t Res = ::ZSTD_decompress(UncompressedBuffer, UncompressedSize, (const uint8_t *)Input.data(), Input.size()); UncompressedSize = Res; // Tell MemorySanitizer that zstd output buffer is fully initialized. // This avoids a false report when running LLVM with uninstrumented ZLib. __msan_unpoison(UncompressedBuffer, UncompressedSize); return ZSTD_isError(Res) ? make_error(ZSTD_getErrorName(Res), inconvertibleErrorCode()) : Error::success(); } Error zstd::uncompress(ArrayRef Input, SmallVectorImpl &UncompressedBuffer, size_t UncompressedSize) { UncompressedBuffer.resize_for_overwrite(UncompressedSize); Error E = zstd::uncompress(Input, UncompressedBuffer.data(), UncompressedSize); if (UncompressedSize < UncompressedBuffer.size()) UncompressedBuffer.truncate(UncompressedSize); return E; } #else bool zstd::isAvailable() { return false; } void zstd::compress(ArrayRef Input, SmallVectorImpl &CompressedBuffer, int Level) { llvm_unreachable("zstd::compress is unavailable"); } Error zstd::uncompress(ArrayRef Input, uint8_t *UncompressedBuffer, size_t &UncompressedSize) { llvm_unreachable("zstd::uncompress is unavailable"); } Error zstd::uncompress(ArrayRef Input, SmallVectorImpl &UncompressedBuffer, size_t UncompressedSize) { llvm_unreachable("zstd::uncompress is unavailable"); } #endif