// SPDX-FileCopyrightText: 2019-2024 Connor McLaughlin // SPDX-License-Identifier: CC-BY-NC-ND-4.0 #include "cd_image.h" #include "cd_subchannel_replacement.h" #include "common/assert.h" #include "common/error.h" #include "common/file_system.h" #include "common/log.h" #include "common/path.h" #include "libchdr/cdrom.h" #include #include Log_SetChannel(CDImageEcm); namespace { class CDImageEcm : public CDImage { public: CDImageEcm(); ~CDImageEcm() override; bool Open(const char* filename, Error* error); bool ReadSubChannelQ(SubChannelQ* subq, const Index& index, LBA lba_in_index) override; bool HasNonStandardSubchannel() const override; s64 GetSizeOnDisk() const override; protected: bool ReadSectorFromIndex(void* buffer, const Index& index, LBA lba_in_index) override; private: bool ReadChunks(u32 disc_offset, u32 size); std::FILE* m_fp = nullptr; enum class SectorType : u32 { Raw = 0x00, Mode1 = 0x01, Mode2Form1 = 0x02, Mode2Form2 = 0x03, Count, }; static constexpr std::array(SectorType::Count)> s_sector_sizes = { 0x930, // raw 0x803, // mode1 0x804, // mode2form1 0x918, // mode2form2 }; static constexpr std::array(SectorType::Count)> s_chunk_sizes = { 0, // raw 2352, // mode1 2336, // mode2form1 2336, // mode2form2 }; struct SectorEntry { u32 file_offset; u32 chunk_size; SectorType type; }; using DataMap = std::map; DataMap m_data_map; std::vector m_chunk_buffer; u32 m_chunk_start = 0; CDSubChannelReplacement m_sbi; }; } // namespace CDImageEcm::CDImageEcm() = default; CDImageEcm::~CDImageEcm() { if (m_fp) std::fclose(m_fp); } bool CDImageEcm::Open(const char* filename, Error* error) { m_filename = filename; m_fp = FileSystem::OpenSharedCFile(filename, "rb", FileSystem::FileShareMode::DenyWrite, error); if (!m_fp) { Error::AddPrefixFmt(error, "Failed to open binfile '{}': ", Path::GetFileName(filename)); return false; } s64 file_size; if (FileSystem::FSeek64(m_fp, 0, SEEK_END) != 0 || (file_size = FileSystem::FTell64(m_fp)) <= 0 || FileSystem::FSeek64(m_fp, 0, SEEK_SET) != 0) { ERROR_LOG("Get file size failed: errno {}", errno); if (error) error->SetErrno(errno); return false; } char header[4]; if (std::fread(header, sizeof(header), 1, m_fp) != 1 || header[0] != 'E' || header[1] != 'C' || header[2] != 'M' || header[3] != 0) { ERROR_LOG("Failed to read/invalid header"); Error::SetStringView(error, "Failed to read/invalid header"); return false; } // build sector map u32 file_offset = static_cast(std::ftell(m_fp)); u32 disc_offset = 0; for (;;) { int bits = std::fgetc(m_fp); if (bits == EOF) { ERROR_LOG("Unexpected EOF after {} chunks", m_data_map.size()); Error::SetStringFmt(error, "Unexpected EOF after {} chunks", m_data_map.size()); return false; } file_offset++; const SectorType type = static_cast(static_cast(bits) & 0x03u); u32 count = (static_cast(bits) >> 2) & 0x1F; u32 shift = 5; while (bits & 0x80) { bits = std::fgetc(m_fp); if (bits == EOF) { ERROR_LOG("Unexpected EOF after {} chunks", m_data_map.size()); Error::SetStringFmt(error, "Unexpected EOF after {} chunks", m_data_map.size()); return false; } count |= (static_cast(bits) & 0x7F) << shift; shift += 7; file_offset++; } if (count == 0xFFFFFFFFu) break; // for this sector count++; if (count >= 0x80000000u) { ERROR_LOG("Corrupted header after {} chunks", m_data_map.size()); Error::SetStringFmt(error, "Corrupted header after {} chunks", m_data_map.size()); return false; } if (type == SectorType::Raw) { while (count > 0) { const u32 size = std::min(count, 2352); m_data_map.emplace(disc_offset, SectorEntry{file_offset, size, type}); disc_offset += size; file_offset += size; count -= size; if (static_cast(file_offset) > file_size) { ERROR_LOG("Out of file bounds after {} chunks", m_data_map.size()); Error::SetStringFmt(error, "Out of file bounds after {} chunks", m_data_map.size()); } } } else { const u32 size = s_sector_sizes[static_cast(type)]; const u32 chunk_size = s_chunk_sizes[static_cast(type)]; for (u32 i = 0; i < count; i++) { m_data_map.emplace(disc_offset, SectorEntry{file_offset, chunk_size, type}); disc_offset += chunk_size; file_offset += size; if (static_cast(file_offset) > file_size) { ERROR_LOG("Out of file bounds after {} chunks", m_data_map.size()); Error::SetStringFmt(error, "Out of file bounds after {} chunks", m_data_map.size()); } } } if (std::fseek(m_fp, file_offset, SEEK_SET) != 0) { ERROR_LOG("Failed to seek to offset {} after {} chunks", file_offset, m_data_map.size()); Error::SetStringFmt(error, "Failed to seek to offset {} after {} chunks", file_offset, m_data_map.size()); return false; } } if (m_data_map.empty()) { ERROR_LOG("No data in image '{}'", filename); Error::SetStringFmt(error, "No data in image '{}'", filename); return false; } m_lba_count = disc_offset / RAW_SECTOR_SIZE; if ((disc_offset % RAW_SECTOR_SIZE) != 0) WARNING_LOG("ECM image is misaligned with offset {}", disc_offset); if (m_lba_count == 0) return false; SubChannelQ::Control control = {}; TrackMode mode = TrackMode::Mode2Raw; control.data = mode != TrackMode::Audio; // Two seconds default pregap. const u32 pregap_frames = 2 * FRAMES_PER_SECOND; Index pregap_index = {}; pregap_index.file_sector_size = RAW_SECTOR_SIZE; pregap_index.start_lba_on_disc = 0; pregap_index.start_lba_in_track = static_cast(-static_cast(pregap_frames)); pregap_index.length = pregap_frames; pregap_index.track_number = 1; pregap_index.index_number = 0; pregap_index.mode = mode; pregap_index.submode = CDImage::SubchannelMode::None; pregap_index.control.bits = control.bits; pregap_index.is_pregap = true; m_indices.push_back(pregap_index); // Data index. Index data_index = {}; data_index.file_index = 0; data_index.file_offset = 0; data_index.file_sector_size = RAW_SECTOR_SIZE; data_index.start_lba_on_disc = pregap_index.length; data_index.track_number = 1; data_index.index_number = 1; data_index.start_lba_in_track = 0; data_index.length = m_lba_count; data_index.mode = mode; data_index.submode = CDImage::SubchannelMode::None; data_index.control.bits = control.bits; m_indices.push_back(data_index); // Assume a single track. m_tracks.push_back(Track{static_cast(1), data_index.start_lba_on_disc, static_cast(0), m_lba_count, mode, SubchannelMode::None, control}); AddLeadOutIndex(); m_sbi.LoadFromImagePath(filename); m_chunk_buffer.reserve(RAW_SECTOR_SIZE * 2); return Seek(1, Position{0, 0, 0}); } bool CDImageEcm::ReadChunks(u32 disc_offset, u32 size) { DataMap::iterator next = m_data_map.lower_bound((disc_offset > RAW_SECTOR_SIZE) ? (disc_offset - RAW_SECTOR_SIZE) : 0); DataMap::iterator current = m_data_map.begin(); while (next != m_data_map.end() && next->first <= disc_offset) current = next++; // extra bytes if we need to buffer some at the start m_chunk_start = current->first; m_chunk_buffer.clear(); if (m_chunk_start < disc_offset) size += (disc_offset - current->first); u32 total_bytes_read = 0; while (total_bytes_read < size) { if (current == m_data_map.end() || std::fseek(m_fp, current->second.file_offset, SEEK_SET) != 0) return false; const u32 chunk_size = current->second.chunk_size; const u32 chunk_start = static_cast(m_chunk_buffer.size()); m_chunk_buffer.resize(chunk_start + chunk_size); if (current->second.type == SectorType::Raw) { if (std::fread(&m_chunk_buffer[chunk_start], chunk_size, 1, m_fp) != 1) return false; total_bytes_read += chunk_size; } else { // u8* sector = &m_chunk_buffer[chunk_start]; u8 sector[RAW_SECTOR_SIZE]; // TODO: needed? std::memset(sector, 0, RAW_SECTOR_SIZE); std::memset(sector + 1, 0xFF, 10); u32 skip; switch (current->second.type) { case SectorType::Mode1: { sector[0x0F] = 0x01; if (std::fread(sector + 0x00C, 0x003, 1, m_fp) != 1 || std::fread(sector + 0x010, 0x800, 1, m_fp) != 1) return false; edc_set(§or[2064], edc_compute(sector, 2064)); ecc_generate(sector); skip = 0; } break; case SectorType::Mode2Form1: { sector[0x0F] = 0x02; if (std::fread(sector + 0x014, 0x804, 1, m_fp) != 1) return false; sector[0x10] = sector[0x14]; sector[0x11] = sector[0x15]; sector[0x12] = sector[0x16]; sector[0x13] = sector[0x17]; edc_set(§or[2072], edc_compute(§or[16], 2056)); ecc_generate(sector); skip = 0x10; } break; case SectorType::Mode2Form2: { sector[0x0F] = 0x02; if (std::fread(sector + 0x014, 0x918, 1, m_fp) != 1) return false; sector[0x10] = sector[0x14]; sector[0x11] = sector[0x15]; sector[0x12] = sector[0x16]; sector[0x13] = sector[0x17]; edc_set(§or[2348], edc_compute(§or[16], 2332)); skip = 0x10; } break; default: UnreachableCode(); return false; } std::memcpy(&m_chunk_buffer[chunk_start], sector + skip, chunk_size); total_bytes_read += chunk_size; } ++current; } return true; } bool CDImageEcm::ReadSubChannelQ(SubChannelQ* subq, const Index& index, LBA lba_in_index) { if (m_sbi.GetReplacementSubChannelQ(index.start_lba_on_disc + lba_in_index, subq)) return true; return CDImage::ReadSubChannelQ(subq, index, lba_in_index); } bool CDImageEcm::HasNonStandardSubchannel() const { return (m_sbi.GetReplacementSectorCount() > 0); } bool CDImageEcm::ReadSectorFromIndex(void* buffer, const Index& index, LBA lba_in_index) { const u32 file_start = static_cast(index.file_offset) + (lba_in_index * index.file_sector_size); const u32 file_end = file_start + RAW_SECTOR_SIZE; if (file_start < m_chunk_start || file_end > (m_chunk_start + m_chunk_buffer.size())) { if (!ReadChunks(file_start, RAW_SECTOR_SIZE)) return false; } DebugAssert(file_start >= m_chunk_start && file_end <= (m_chunk_start + m_chunk_buffer.size())); const size_t chunk_offset = static_cast(file_start - m_chunk_start); std::memcpy(buffer, &m_chunk_buffer[chunk_offset], RAW_SECTOR_SIZE); return true; } s64 CDImageEcm::GetSizeOnDisk() const { return FileSystem::FSize64(m_fp); } std::unique_ptr CDImage::OpenEcmImage(const char* filename, Error* error) { std::unique_ptr image = std::make_unique(); if (!image->Open(filename, error)) return {}; return image; }