// Copyright 2008 Dolphin Emulator Project // Licensed under GPLv2+ // Refer to the license.txt file included. #ifdef _WIN32 #include #include #endif #include #include #include #include #include #include #include #include #include "Common/CommonTypes.h" #include "Common/FileUtil.h" #include "Common/Hash.h" #include "Common/MsgHandler.h" #include "Common/StringUtil.h" #include "Common/Logging/Log.h" #include "DiscIO/Blob.h" #include "DiscIO/CompressedBlob.h" #include "DiscIO/DiscScrubber.h" namespace DiscIO { CompressedBlobReader::CompressedBlobReader(const std::string& filename) : m_file_name(filename) { m_file.Open(filename, "rb"); m_file_size = File::GetSize(filename); m_file.ReadArray(&m_header, 1); SetSectorSize(m_header.block_size); // cache block pointers and hashes m_block_pointers = new u64[m_header.num_blocks]; m_file.ReadArray(m_block_pointers, m_header.num_blocks); m_hashes = new u32[m_header.num_blocks]; m_file.ReadArray(m_hashes, m_header.num_blocks); m_data_offset = (sizeof(CompressedBlobHeader)) + (sizeof(u64)) * m_header.num_blocks // skip block pointers + (sizeof(u32)) * m_header.num_blocks; // skip hashes // A compressed block is never ever longer than a decompressed block, so just header.block_size should be fine. // I still add some safety margin. m_zlib_buffer_size = m_header.block_size + 64; m_zlib_buffer = new u8[m_zlib_buffer_size]; memset(m_zlib_buffer, 0, m_zlib_buffer_size); } std::unique_ptr CompressedBlobReader::Create(const std::string& filename) { if (IsGCZBlob(filename)) return std::unique_ptr(new CompressedBlobReader(filename)); return nullptr; } CompressedBlobReader::~CompressedBlobReader() { delete [] m_zlib_buffer; delete [] m_block_pointers; delete [] m_hashes; } // IMPORTANT: Calling this function invalidates all earlier pointers gotten from this function. u64 CompressedBlobReader::GetBlockCompressedSize(u64 block_num) const { u64 start = m_block_pointers[block_num]; if (block_num < m_header.num_blocks - 1) return m_block_pointers[block_num + 1] - start; else if (block_num == m_header.num_blocks - 1) return m_header.compressed_data_size - start; else PanicAlert("GetBlockCompressedSize - illegal block number %i", (int)block_num); return 0; } void CompressedBlobReader::GetBlock(u64 block_num, u8 *out_ptr) { bool uncompressed = false; u32 comp_block_size = (u32)GetBlockCompressedSize(block_num); u64 offset = m_block_pointers[block_num] + m_data_offset; if (offset & (1ULL << 63)) { if (comp_block_size != m_header.block_size) PanicAlert("Uncompressed block with wrong size"); uncompressed = true; offset &= ~(1ULL << 63); } // clear unused part of zlib buffer. maybe this can be deleted when it works fully. memset(m_zlib_buffer + comp_block_size, 0, m_zlib_buffer_size - comp_block_size); m_file.Seek(offset, SEEK_SET); m_file.ReadBytes(m_zlib_buffer, comp_block_size); u8* source = m_zlib_buffer; u8* dest = out_ptr; // First, check hash. u32 block_hash = HashAdler32(source, comp_block_size); if (block_hash != m_hashes[block_num]) PanicAlertT("The disc image \"%s\" is corrupt.\n" "Hash of block %" PRIu64 " is %08x instead of %08x.", m_file_name.c_str(), block_num, block_hash, m_hashes[block_num]); if (uncompressed) { memcpy(dest, source, comp_block_size); } else { z_stream z; memset(&z, 0, sizeof(z)); z.next_in = source; z.avail_in = comp_block_size; if (z.avail_in > m_header.block_size) { PanicAlert("We have a problem"); } z.next_out = dest; z.avail_out = m_header.block_size; inflateInit(&z); int status = inflate(&z, Z_FULL_FLUSH); u32 uncomp_size = m_header.block_size - z.avail_out; if (status != Z_STREAM_END) { // this seem to fire wrongly from time to time // to be sure, don't use compressed isos :P PanicAlert("Failure reading block %" PRIu64 " - out of data and not at end.", block_num); } inflateEnd(&z); if (uncomp_size != m_header.block_size) PanicAlert("Wrong block size"); } } bool CompressFileToBlob(const std::string& infile, const std::string& outfile, u32 sub_type, int block_size, CompressCB callback, void* arg) { bool scrubbing = false; if (IsGCZBlob(infile)) { PanicAlertT("\"%s\" is already compressed! Cannot compress it further.", infile.c_str()); return false; } File::IOFile inf(infile, "rb"); if (!inf) { PanicAlertT("Failed to open the input file \"%s\".", infile.c_str()); return false; } File::IOFile f(outfile, "wb"); if (!f) { PanicAlertT("Failed to open the output file \"%s\".\n" "Check that you have permissions to write the target folder and that the media can be written.", outfile.c_str()); return false; } if (sub_type == 1) { if (!DiscScrubber::SetupScrub(infile, block_size)) { PanicAlertT("\"%s\" failed to be scrubbed. Probably the image is corrupt.", infile.c_str()); return false; } scrubbing = true; } z_stream z = {}; if (deflateInit(&z, 9) != Z_OK) { DiscScrubber::Cleanup(); return false; } callback("Files opened, ready to compress.", 0, arg); CompressedBlobHeader header; header.magic_cookie = kBlobCookie; header.sub_type = sub_type; header.block_size = block_size; header.data_size = File::GetSize(infile); // round upwards! header.num_blocks = (u32)((header.data_size + (block_size - 1)) / block_size); u64* offsets = new u64[header.num_blocks]; u32* hashes = new u32[header.num_blocks]; u8* out_buf = new u8[block_size]; u8* in_buf = new u8[block_size]; // seek past the header (we will write it at the end) f.Seek(sizeof(CompressedBlobHeader), SEEK_CUR); // seek past the offset and hash tables (we will write them at the end) f.Seek((sizeof(u64) + sizeof(u32)) * header.num_blocks, SEEK_CUR); // Now we are ready to write compressed data! u64 position = 0; int num_compressed = 0; int num_stored = 0; int progress_monitor = std::max(1, header.num_blocks / 1000); bool success = true; for (u32 i = 0; i < header.num_blocks; i++) { if (i % progress_monitor == 0) { const u64 inpos = inf.Tell(); int ratio = 0; if (inpos != 0) ratio = (int)(100 * position / inpos); std::string temp = StringFromFormat("%i of %i blocks. Compression ratio %i%%", i, header.num_blocks, ratio); bool was_cancelled = !callback(temp, (float)i / (float)header.num_blocks, arg); if (was_cancelled) { success = false; break; } } offsets[i] = position; size_t read_bytes; if (scrubbing) read_bytes = DiscScrubber::GetNextBlock(inf, in_buf); else inf.ReadArray(in_buf, header.block_size, &read_bytes); if (read_bytes < header.block_size) std::fill(in_buf + read_bytes, in_buf + header.block_size, 0); int retval = deflateReset(&z); z.next_in = in_buf; z.avail_in = header.block_size; z.next_out = out_buf; z.avail_out = block_size; if (retval != Z_OK) { ERROR_LOG(DISCIO, "Deflate failed"); success = false; break; } int status = deflate(&z, Z_FINISH); int comp_size = block_size - z.avail_out; u8* write_buf; int write_size; if ((status != Z_STREAM_END) || (z.avail_out < 10)) { //PanicAlert("%i %i Store %i", i*block_size, position, comp_size); // let's store uncompressed write_buf = in_buf; offsets[i] |= 0x8000000000000000ULL; write_size = block_size; num_stored++; } else { // let's store compressed //PanicAlert("Comp %i to %i", block_size, comp_size); write_buf = out_buf; write_size = comp_size; num_compressed++; } if (!f.WriteBytes(write_buf, write_size)) { PanicAlertT( "Failed to write the output file \"%s\".\n" "Check that you have enough space available on the target drive.", outfile.c_str()); success = false; break; } position += write_size; hashes[i] = HashAdler32(write_buf, write_size); } header.compressed_data_size = position; if (!success) { // Remove the incomplete output file. f.Close(); File::Delete(outfile); } else { // Okay, go back and fill in headers f.Seek(0, SEEK_SET); f.WriteArray(&header, 1); f.WriteArray(offsets, header.num_blocks); f.WriteArray(hashes, header.num_blocks); } // Cleanup delete[] in_buf; delete[] out_buf; delete[] offsets; delete[] hashes; deflateEnd(&z); DiscScrubber::Cleanup(); if (success) { callback("Done compressing disc image.", 1.0f, arg); } return success; } bool DecompressBlobToFile(const std::string& infile, const std::string& outfile, CompressCB callback, void* arg) { if (!IsGCZBlob(infile)) { PanicAlertT("File not compressed"); return false; } std::unique_ptr reader(CompressedBlobReader::Create(infile)); if (!reader) { PanicAlertT("Failed to open the input file \"%s\".", infile.c_str()); return false; } File::IOFile f(outfile, "wb"); if (!f) { PanicAlertT( "Failed to open the output file \"%s\".\n" "Check that you have permissions to write the target folder and that the media can be written.", outfile.c_str()); return false; } const CompressedBlobHeader &header = reader->GetHeader(); static const size_t BUFFER_BLOCKS = 32; size_t buffer_size = header.block_size * BUFFER_BLOCKS; size_t last_buffer_size = header.block_size * (header.num_blocks % BUFFER_BLOCKS); std::vector buffer(buffer_size); u32 num_buffers = (header.num_blocks + BUFFER_BLOCKS - 1) / BUFFER_BLOCKS; int progress_monitor = std::max(1, num_buffers / 100); bool success = true; for (u64 i = 0; i < num_buffers; i++) { if (i % progress_monitor == 0) { bool was_cancelled = !callback("Unpacking", (float)i / (float)num_buffers, arg); if (was_cancelled) { success = false; break; } } const size_t sz = i == num_buffers - 1 ? last_buffer_size : buffer_size; reader->Read(i * buffer_size, sz, buffer.data()); if (!f.WriteBytes(buffer.data(), sz)) { PanicAlertT( "Failed to write the output file \"%s\".\n" "Check that you have enough space available on the target drive.", outfile.c_str()); success = false; break; } } if (!success) { // Remove the incomplete output file. f.Close(); File::Delete(outfile); } else { f.Resize(header.data_size); } return true; } bool IsGCZBlob(const std::string& filename) { File::IOFile f(filename, "rb"); CompressedBlobHeader header; return f.ReadArray(&header, 1) && (header.magic_cookie == kBlobCookie); } } // namespace