#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "magiskboot.h" #include "compress.h" using namespace std; #define bwrite filter_stream::write constexpr size_t CHUNK = 0x40000; constexpr size_t LZ4_UNCOMPRESSED = 0x800000; constexpr size_t LZ4_COMPRESSED = LZ4_COMPRESSBOUND(LZ4_UNCOMPRESSED); class cpr_stream : public filter_stream { public: using filter_stream::filter_stream; using stream::read; }; class gz_strm : public cpr_stream { public: int write(const void *buf, size_t len) override { return len ? write(buf, len, Z_NO_FLUSH) : 0; } ~gz_strm() override { write(nullptr, 0, Z_FINISH); switch(mode) { case DECODE: inflateEnd(&strm); break; case ENCODE: deflateEnd(&strm); break; } } protected: enum mode_t { DECODE, ENCODE } mode; gz_strm(mode_t mode, stream_ptr &&base) : cpr_stream(std::move(base)), mode(mode) { switch(mode) { case DECODE: inflateInit2(&strm, 15 | 16); break; case ENCODE: deflateInit2(&strm, 9, Z_DEFLATED, 15 | 16, 8, Z_DEFAULT_STRATEGY); break; } } private: z_stream strm; uint8_t outbuf[CHUNK]; int write(const void *buf, size_t len, int flush) { strm.next_in = (Bytef *) buf; strm.avail_in = len; do { int code; strm.next_out = outbuf; strm.avail_out = sizeof(outbuf); switch(mode) { case DECODE: code = inflate(&strm, flush); break; case ENCODE: code = deflate(&strm, flush); break; } if (code == Z_STREAM_ERROR) { LOGW("gzip %s failed (%d)\n", mode ? "encode" : "decode", code); return -1; } bwrite(outbuf, sizeof(outbuf) - strm.avail_out); } while (strm.avail_out == 0); return len; } }; class gz_decoder : public gz_strm { public: explicit gz_decoder(stream_ptr &&base) : gz_strm(DECODE, std::move(base)) {}; }; class gz_encoder : public gz_strm { public: explicit gz_encoder(stream_ptr &&base) : gz_strm(ENCODE, std::move(base)) {}; }; class bz_strm : public cpr_stream { public: int write(const void *buf, size_t len) override { return len ? write(buf, len, BZ_RUN) : 0; } ~bz_strm() override { switch(mode) { case DECODE: BZ2_bzDecompressEnd(&strm); break; case ENCODE: write(nullptr, 0, BZ_FINISH); BZ2_bzCompressEnd(&strm); break; } } protected: enum mode_t { DECODE, ENCODE } mode; bz_strm(mode_t mode, stream_ptr &&base) : cpr_stream(std::move(base)), mode(mode) { switch(mode) { case DECODE: BZ2_bzDecompressInit(&strm, 0, 0); break; case ENCODE: BZ2_bzCompressInit(&strm, 9, 0, 0); break; } } private: bz_stream strm; char outbuf[CHUNK]; int write(const void *buf, size_t len, int flush) { strm.next_in = (char *) buf; strm.avail_in = len; do { int code; strm.avail_out = sizeof(outbuf); strm.next_out = outbuf; switch(mode) { case DECODE: code = BZ2_bzDecompress(&strm); break; case ENCODE: code = BZ2_bzCompress(&strm, flush); break; } if (code < 0) { LOGW("bzip2 %s failed (%d)\n", mode ? "encode" : "decode", code); return -1; } bwrite(outbuf, sizeof(outbuf) - strm.avail_out); } while (strm.avail_out == 0); return len; } }; class bz_decoder : public bz_strm { public: explicit bz_decoder(stream_ptr &&base) : bz_strm(DECODE, std::move(base)) {}; }; class bz_encoder : public bz_strm { public: explicit bz_encoder(stream_ptr &&base) : bz_strm(ENCODE, std::move(base)) {}; }; class lzma_strm : public cpr_stream { public: int write(const void *buf, size_t len) override { return len ? write(buf, len, LZMA_RUN) : 0; } ~lzma_strm() override { write(nullptr, 0, LZMA_FINISH); lzma_end(&strm); } protected: enum mode_t { DECODE, ENCODE_XZ, ENCODE_LZMA } mode; lzma_strm(mode_t mode, stream_ptr &&base) : cpr_stream(std::move(base)), mode(mode), strm(LZMA_STREAM_INIT) { lzma_options_lzma opt; // Initialize preset lzma_lzma_preset(&opt, 9); lzma_filter filters[] = { { .id = LZMA_FILTER_LZMA2, .options = &opt }, { .id = LZMA_VLI_UNKNOWN, .options = nullptr }, }; lzma_ret ret; switch(mode) { case DECODE: ret = lzma_auto_decoder(&strm, UINT64_MAX, 0); break; case ENCODE_XZ: ret = lzma_stream_encoder(&strm, filters, LZMA_CHECK_CRC32); break; case ENCODE_LZMA: ret = lzma_alone_encoder(&strm, &opt); break; } } private: lzma_stream strm; uint8_t outbuf[CHUNK]; int write(const void *buf, size_t len, lzma_action flush) { strm.next_in = (uint8_t *) buf; strm.avail_in = len; do { strm.avail_out = sizeof(outbuf); strm.next_out = outbuf; int code = lzma_code(&strm, flush); if (code != LZMA_OK && code != LZMA_STREAM_END) { LOGW("LZMA %s failed (%d)\n", mode ? "encode" : "decode", code); return -1; } bwrite(outbuf, sizeof(outbuf) - strm.avail_out); } while (strm.avail_out == 0); return len; } }; class lzma_decoder : public lzma_strm { public: explicit lzma_decoder(stream_ptr &&base) : lzma_strm(DECODE, std::move(base)) {} }; class xz_encoder : public lzma_strm { public: explicit xz_encoder(stream_ptr &&base) : lzma_strm(ENCODE_XZ, std::move(base)) {} }; class lzma_encoder : public lzma_strm { public: explicit lzma_encoder(stream_ptr &&base) : lzma_strm(ENCODE_LZMA, std::move(base)) {} }; class LZ4F_decoder : public cpr_stream { public: explicit LZ4F_decoder(stream_ptr &&base) : cpr_stream(std::move(base)), outbuf(nullptr) { LZ4F_createDecompressionContext(&ctx, LZ4F_VERSION); } ~LZ4F_decoder() override { LZ4F_freeDecompressionContext(ctx); delete[] outbuf; } int write(const void *buf, size_t len) override { auto ret = len; auto inbuf = reinterpret_cast(buf); if (!outbuf) read_header(inbuf, len); size_t read, write; LZ4F_errorCode_t code; do { read = len; write = outCapacity; code = LZ4F_decompress(ctx, outbuf, &write, inbuf, &read, nullptr); if (LZ4F_isError(code)) { LOGW("LZ4F decode error: %s\n", LZ4F_getErrorName(code)); return -1; } len -= read; inbuf += read; bwrite(outbuf, write); } while (len != 0 || write != 0); return ret; } private: LZ4F_decompressionContext_t ctx; uint8_t *outbuf; size_t outCapacity; void read_header(const uint8_t *&in, size_t &size) { size_t read = size; LZ4F_frameInfo_t info; LZ4F_getFrameInfo(ctx, &info, in, &read); switch (info.blockSizeID) { case LZ4F_default: case LZ4F_max64KB: outCapacity = 1 << 16; break; case LZ4F_max256KB: outCapacity = 1 << 18; break; case LZ4F_max1MB: outCapacity = 1 << 20; break; case LZ4F_max4MB: outCapacity = 1 << 22; break; } outbuf = new uint8_t[outCapacity]; in += read; size -= read; } }; class LZ4F_encoder : public cpr_stream { public: explicit LZ4F_encoder(stream_ptr &&base) : cpr_stream(std::move(base)), outbuf(nullptr), outCapacity(0) { LZ4F_createCompressionContext(&ctx, LZ4F_VERSION); } int write(const void *buf, size_t len) override { auto ret = len; if (!outbuf) write_header(); if (len == 0) return 0; auto inbuf = reinterpret_cast(buf); size_t read, write; do { read = len > BLOCK_SZ ? BLOCK_SZ : len; write = LZ4F_compressUpdate(ctx, outbuf, outCapacity, inbuf, read, nullptr); if (LZ4F_isError(write)) { LOGW("LZ4F encode error: %s\n", LZ4F_getErrorName(write)); return -1; } len -= read; inbuf += read; bwrite(outbuf, write); } while (len != 0); return ret; } ~LZ4F_encoder() override { size_t len = LZ4F_compressEnd(ctx, outbuf, outCapacity, nullptr); bwrite(outbuf, len); LZ4F_freeCompressionContext(ctx); delete[] outbuf; } private: LZ4F_compressionContext_t ctx; uint8_t *outbuf; size_t outCapacity; static constexpr size_t BLOCK_SZ = 1 << 22; void write_header() { LZ4F_preferences_t prefs { .autoFlush = 1, .compressionLevel = 9, .frameInfo = { .blockMode = LZ4F_blockIndependent, .blockSizeID = LZ4F_max4MB, .blockChecksumFlag = LZ4F_noBlockChecksum, .contentChecksumFlag = LZ4F_contentChecksumEnabled } }; outCapacity = LZ4F_compressBound(BLOCK_SZ, &prefs); outbuf = new uint8_t[outCapacity]; size_t write = LZ4F_compressBegin(ctx, outbuf, outCapacity, &prefs); bwrite(outbuf, write); } }; class LZ4_decoder : public cpr_stream { public: explicit LZ4_decoder(stream_ptr &&base) : cpr_stream(std::move(base)), out_buf(new char[LZ4_UNCOMPRESSED]), buf(new char[LZ4_COMPRESSED]), init(false), block_sz(0), buf_off(0) {} ~LZ4_decoder() override { delete[] out_buf; delete[] buf; } int write(const void *in, size_t size) override { auto ret = size; auto inbuf = static_cast(in); if (!init) { // Skip magic inbuf += 4; size -= 4; init = true; } for (int consumed; size != 0;) { if (block_sz == 0) { if (buf_off + size >= sizeof(block_sz)) { consumed = sizeof(block_sz) - buf_off; memcpy(buf + buf_off, inbuf, consumed); memcpy(&block_sz, buf, sizeof(block_sz)); buf_off = 0; } else { consumed = size; memcpy(buf + buf_off, inbuf, size); } inbuf += consumed; size -= consumed; } else if (buf_off + size >= block_sz) { consumed = block_sz - buf_off; memcpy(buf + buf_off, inbuf, consumed); inbuf += consumed; size -= consumed; int write = LZ4_decompress_safe(buf, out_buf, block_sz, LZ4_UNCOMPRESSED); if (write < 0) { LOGW("LZ4HC decompression failure (%d)\n", write); return -1; } bwrite(out_buf, write); // Reset buf_off = 0; block_sz = 0; } else { // Copy to internal buffer memcpy(buf + buf_off, inbuf, size); buf_off += size; break; } } return ret; } private: char *out_buf; char *buf; bool init; unsigned block_sz; int buf_off; }; class LZ4_encoder : public cpr_stream { public: explicit LZ4_encoder(stream_ptr &&base) : cpr_stream(std::move(base)), outbuf(new char[LZ4_COMPRESSED]), buf(new char[LZ4_UNCOMPRESSED]), init(false), buf_off(0), in_total(0) {} int write(const void *in, size_t size) override { if (!init) { bwrite("\x02\x21\x4c\x18", 4); init = true; } if (size == 0) return 0; in_total += size; const char *inbuf = (const char *) in; size_t consumed; int write; do { if (buf_off + size >= LZ4_UNCOMPRESSED) { consumed = LZ4_UNCOMPRESSED - buf_off; memcpy(buf + buf_off, inbuf, consumed); inbuf += consumed; size -= consumed; write = LZ4_compress_HC(buf, outbuf, LZ4_UNCOMPRESSED, LZ4_COMPRESSED, 9); if (write == 0) { LOGW("LZ4HC compression failure\n"); return false; } bwrite(&write, sizeof(write)); bwrite(outbuf, write); // Reset buffer buf_off = 0; } else { // Copy to internal buffer memcpy(buf + buf_off, inbuf, size); buf_off += size; size = 0; } } while (size != 0); return true; } ~LZ4_encoder() override { if (buf_off) { int write = LZ4_compress_HC(buf, outbuf, buf_off, LZ4_COMPRESSED, 9); bwrite(&write, sizeof(write)); bwrite(outbuf, write); } bwrite(&in_total, sizeof(in_total)); delete[] outbuf; delete[] buf; } private: char *outbuf; char *buf; bool init; int buf_off; unsigned in_total; }; stream_ptr get_encoder(format_t type, stream_ptr &&base) { switch (type) { case XZ: return make_unique(std::move(base)); case LZMA: return make_unique(std::move(base)); case BZIP2: return make_unique(std::move(base)); case LZ4: return make_unique(std::move(base)); case LZ4_LEGACY: return make_unique(std::move(base)); case GZIP: default: return make_unique(std::move(base)); } } stream_ptr get_decoder(format_t type, stream_ptr &&base) { switch (type) { case XZ: case LZMA: return make_unique(std::move(base)); case BZIP2: return make_unique(std::move(base)); case LZ4: return make_unique(std::move(base)); case LZ4_LEGACY: return make_unique(std::move(base)); case GZIP: default: return make_unique(std::move(base)); } } void decompress(char *infile, const char *outfile) { bool in_std = infile == "-"sv; bool rm_in = false; FILE *in_fp = in_std ? stdin : xfopen(infile, "re"); stream_ptr strm; char buf[4096]; size_t len; while ((len = fread(buf, 1, sizeof(buf), in_fp))) { if (!strm) { format_t type = check_fmt(buf, len); if (!COMPRESSED(type)) LOGE("Input file is not a supported compressed type!\n"); fprintf(stderr, "Detected format: [%s]\n", fmt2name[type]); /* If user does not provide outfile, infile has to be either * .[ext], or '-'. Outfile will be either or '-'. * If the input does not have proper format, abort */ char *ext = nullptr; if (outfile == nullptr) { outfile = infile; if (!in_std) { ext = strrchr(infile, '.'); if (ext == nullptr || strcmp(ext, fmt2ext[type]) != 0) LOGE("Input file is not a supported type!\n"); // Strip out extension and remove input *ext = '\0'; rm_in = true; fprintf(stderr, "Decompressing to [%s]\n", outfile); } } FILE *out_fp = outfile == "-"sv ? stdout : xfopen(outfile, "we"); strm = get_decoder(type, make_unique(out_fp)); if (ext) *ext = '.'; } if (strm->write(buf, len) < 0) LOGE("Decompression error!\n"); } strm.reset(nullptr); fclose(in_fp); if (rm_in) unlink(infile); } void compress(const char *method, const char *infile, const char *outfile) { auto it = name2fmt.find(method); if (it == name2fmt.end()) LOGE("Unknown compression method: [%s]\n", method); bool in_std = infile == "-"sv; bool rm_in = false; FILE *in_fp = in_std ? stdin : xfopen(infile, "re"); FILE *out_fp; if (outfile == nullptr) { if (in_std) { out_fp = stdout; } else { /* If user does not provide outfile and infile is not * STDIN, output to .[ext] */ string tmp(infile); tmp += fmt2ext[it->second]; out_fp = xfopen(tmp.data(), "we"); fprintf(stderr, "Compressing to [%s]\n", tmp.data()); rm_in = true; } } else { out_fp = outfile == "-"sv ? stdout : xfopen(outfile, "we"); } auto strm = get_encoder(it->second, make_unique(out_fp)); char buf[4096]; size_t len; while ((len = fread(buf, 1, sizeof(buf), in_fp))) { if (strm->write(buf, len) < 0) LOGE("Compression error!\n"); }; strm.reset(nullptr); fclose(in_fp); if (rm_in) unlink(infile); }