Duckstation/src/core/cdrom.cpp
2023-09-23 14:14:52 +10:00

3424 lines
108 KiB
C++

// SPDX-FileCopyrightText: 2019-2022 Connor McLaughlin <stenzek@gmail.com>
// SPDX-License-Identifier: (GPL-3.0 OR CC-BY-NC-ND-4.0)
#include "cdrom.h"
#include "cdrom_async_reader.h"
#include "dma.h"
#include "host.h"
#include "host_interface_progress_callback.h"
#include "interrupt_controller.h"
#include "settings.h"
#include "spu.h"
#include "system.h"
#include "util/cd_image.h"
#include "util/cd_xa.h"
#include "util/imgui_manager.h"
#include "util/state_wrapper.h"
#include "common/align.h"
#include "common/bitfield.h"
#include "common/fifo_queue.h"
#include "common/file_system.h"
#include "common/heap_array.h"
#include "common/log.h"
#include "common/platform.h"
#include "imgui.h"
#include <cmath>
#include <vector>
Log_SetChannel(CDROM);
#if defined(CPU_X64)
#include <emmintrin.h>
#endif
namespace CDROM {
enum : u32
{
RAW_SECTOR_OUTPUT_SIZE = CDImage::RAW_SECTOR_SIZE - CDImage::SECTOR_SYNC_SIZE,
DATA_SECTOR_OUTPUT_SIZE = CDImage::DATA_SECTOR_SIZE,
SECTOR_SYNC_SIZE = CDImage::SECTOR_SYNC_SIZE,
SECTOR_HEADER_SIZE = CDImage::SECTOR_HEADER_SIZE,
XA_RESAMPLE_RING_BUFFER_SIZE = 32,
XA_RESAMPLE_ZIGZAG_TABLE_SIZE = 29,
XA_RESAMPLE_NUM_ZIGZAG_TABLES = 7,
PARAM_FIFO_SIZE = 16,
RESPONSE_FIFO_SIZE = 16,
DATA_FIFO_SIZE = RAW_SECTOR_OUTPUT_SIZE,
NUM_SECTOR_BUFFERS = 8,
AUDIO_FIFO_SIZE = 44100 * 2,
AUDIO_FIFO_LOW_WATERMARK = 10,
INIT_TICKS = 4000000,
ID_READ_TICKS = 33868,
MOTOR_ON_RESPONSE_TICKS = 400000,
MAX_FAST_FORWARD_RATE = 12,
FAST_FORWARD_RATE_STEP = 4,
MINIMUM_INTERRUPT_DELAY = 5000,
INTERRUPT_DELAY_CYCLES = 2000,
};
static constexpr u8 INTERRUPT_REGISTER_MASK = 0x1F;
enum class Interrupt : u8
{
DataReady = 0x01,
Complete = 0x02,
ACK = 0x03,
DataEnd = 0x04,
Error = 0x05
};
enum class Command : u16
{
Sync = 0x00,
Getstat = 0x01,
Setloc = 0x02,
Play = 0x03,
Forward = 0x04,
Backward = 0x05,
ReadN = 0x06,
MotorOn = 0x07,
Stop = 0x08,
Pause = 0x09,
Init = 0x0A,
Mute = 0x0B,
Demute = 0x0C,
Setfilter = 0x0D,
Setmode = 0x0E,
Getmode = 0x0F,
GetlocL = 0x10,
GetlocP = 0x11,
ReadT = 0x12,
GetTN = 0x13,
GetTD = 0x14,
SeekL = 0x15,
SeekP = 0x16,
SetClock = 0x17,
GetClock = 0x18,
Test = 0x19,
GetID = 0x1A,
ReadS = 0x1B,
Reset = 0x1C,
GetQ = 0x1D,
ReadTOC = 0x1E,
VideoCD = 0x1F,
None = 0xFFFF
};
enum class DriveState : u8
{
Idle,
ShellOpening,
UNUSED_Resetting,
SeekingPhysical,
SeekingLogical,
UNUSED_ReadingID,
UNUSED_ReadingTOC,
Reading,
Playing,
UNUSED_Pausing,
UNUSED_Stopping,
ChangingSession,
SpinningUp,
SeekingImplicit,
ChangingSpeedOrTOCRead
};
union StatusRegister
{
u8 bits;
BitField<u8, u8, 0, 2> index;
BitField<u8, bool, 2, 1> ADPBUSY;
BitField<u8, bool, 3, 1> PRMEMPTY;
BitField<u8, bool, 4, 1> PRMWRDY;
BitField<u8, bool, 5, 1> RSLRRDY;
BitField<u8, bool, 6, 1> DRQSTS;
BitField<u8, bool, 7, 1> BUSYSTS;
};
enum StatBits : u8
{
STAT_ERROR = (1 << 0),
STAT_MOTOR_ON = (1 << 1),
STAT_SEEK_ERROR = (1 << 2),
STAT_ID_ERROR = (1 << 3),
STAT_SHELL_OPEN = (1 << 4),
STAT_READING = (1 << 5),
STAT_SEEKING = (1 << 6),
STAT_PLAYING_CDDA = (1 << 7)
};
enum ErrorReason : u8
{
ERROR_REASON_INVALID_ARGUMENT = 0x10,
ERROR_REASON_INCORRECT_NUMBER_OF_PARAMETERS = 0x20,
ERROR_REASON_INVALID_COMMAND = 0x40,
ERROR_REASON_NOT_READY = 0x80
};
union SecondaryStatusRegister
{
u8 bits;
BitField<u8, bool, 0, 1> error;
BitField<u8, bool, 1, 1> motor_on;
BitField<u8, bool, 2, 1> seek_error;
BitField<u8, bool, 3, 1> id_error;
BitField<u8, bool, 4, 1> shell_open;
BitField<u8, bool, 5, 1> reading;
BitField<u8, bool, 6, 1> seeking;
BitField<u8, bool, 7, 1> playing_cdda;
/// Clears the CDDA/seeking bits.
ALWAYS_INLINE void ClearActiveBits() { bits &= ~(STAT_SEEKING | STAT_READING | STAT_PLAYING_CDDA); }
/// Sets the bits for seeking.
ALWAYS_INLINE void SetSeeking()
{
bits = (bits & ~(STAT_READING | STAT_PLAYING_CDDA)) | (STAT_MOTOR_ON | STAT_SEEKING);
}
/// Sets the bits for reading/playing.
ALWAYS_INLINE void SetReadingBits(bool audio)
{
bits = (bits & ~(STAT_SEEKING | STAT_READING | STAT_PLAYING_CDDA)) |
((audio) ? (STAT_MOTOR_ON | STAT_PLAYING_CDDA) : (STAT_MOTOR_ON | STAT_READING));
}
};
union ModeRegister
{
u8 bits;
BitField<u8, bool, 0, 1> cdda;
BitField<u8, bool, 1, 1> auto_pause;
BitField<u8, bool, 2, 1> report_audio;
BitField<u8, bool, 3, 1> xa_filter;
BitField<u8, bool, 4, 1> ignore_bit;
BitField<u8, bool, 5, 1> read_raw_sector;
BitField<u8, bool, 6, 1> xa_enable;
BitField<u8, bool, 7, 1> double_speed;
};
union RequestRegister
{
u8 bits;
BitField<u8, bool, 5, 1> SMEN;
BitField<u8, bool, 6, 1> BFWR;
BitField<u8, bool, 7, 1> BFRD;
};
static void SoftReset(TickCount ticks_late);
static bool IsDriveIdle();
static bool IsMotorOn();
static bool IsSeeking();
static bool IsReadingOrPlaying();
static bool CanReadMedia();
static bool HasPendingCommand();
static bool HasPendingInterrupt();
static bool HasPendingAsyncInterrupt();
static void AddCDAudioFrame(s16 left, s16 right);
static s32 ApplyVolume(s16 sample, u8 volume);
static s16 SaturateVolume(s32 volume);
static void SetInterrupt(Interrupt interrupt);
static void SetAsyncInterrupt(Interrupt interrupt);
static void ClearAsyncInterrupt();
static void DeliverAsyncInterrupt(void*, TickCount ticks, TickCount ticks_late);
static void QueueDeliverAsyncInterrupt();
static void SendACKAndStat();
static void SendErrorResponse(u8 stat_bits = STAT_ERROR, u8 reason = 0x80);
static void SendAsyncErrorResponse(u8 stat_bits = STAT_ERROR, u8 reason = 0x80);
static void UpdateStatusRegister();
static void UpdateInterruptRequest();
static bool HasPendingDiscEvent();
static TickCount GetAckDelayForCommand(Command command);
static TickCount GetTicksForSpinUp();
static TickCount GetTicksForIDRead();
static TickCount GetTicksForRead();
static TickCount GetTicksForSeek(CDImage::LBA new_lba, bool ignore_speed_change = false);
static TickCount GetTicksForStop(bool motor_was_on);
static TickCount GetTicksForSpeedChange();
static TickCount GetTicksForTOCRead();
static CDImage::LBA GetNextSectorToBeRead();
static bool CompleteSeek();
static void BeginCommand(Command command); // also update status register
static void EndCommand(); // also updates status register
static void ExecuteCommand(void*, TickCount ticks, TickCount ticks_late);
static void ExecuteTestCommand(u8 subcommand);
static void ExecuteCommandSecondResponse(void*, TickCount ticks, TickCount ticks_late);
static void QueueCommandSecondResponse(Command command, TickCount ticks);
static void ClearCommandSecondResponse();
static void UpdateCommandEvent();
static void ExecuteDrive(void*, TickCount ticks, TickCount ticks_late);
static void ClearDriveState();
static void BeginReading(TickCount ticks_late = 0, bool after_seek = false);
static void BeginPlaying(u8 track, TickCount ticks_late = 0, bool after_seek = false);
static void DoShellOpenComplete(TickCount ticks_late);
static void DoSeekComplete(TickCount ticks_late);
static void DoStatSecondResponse();
static void DoChangeSessionComplete();
static void DoSpinUpComplete();
static void DoSpeedChangeOrImplicitTOCReadComplete();
static void DoIDRead();
static void DoSectorRead();
static void ProcessDataSectorHeader(const u8* raw_sector);
static void ProcessDataSector(const u8* raw_sector, const CDImage::SubChannelQ& subq);
static void ProcessXAADPCMSector(const u8* raw_sector, const CDImage::SubChannelQ& subq);
static void ProcessCDDASector(const u8* raw_sector, const CDImage::SubChannelQ& subq);
static void StopReadingWithDataEnd();
static void StartMotor();
static void StopMotor();
static void BeginSeeking(bool logical, bool read_after_seek, bool play_after_seek);
static void UpdatePositionWhileSeeking();
static void UpdatePhysicalPosition(bool update_logical);
static void SetHoldPosition(CDImage::LBA lba, bool update_subq);
static void ResetCurrentXAFile();
static void ResetAudioDecoder();
static void LoadDataFIFO();
static void ClearSectorBuffers();
template<bool STEREO, bool SAMPLE_RATE>
static void ResampleXAADPCM(const s16* frames_in, u32 num_frames_in);
static TinyString LBAToMSFString(CDImage::LBA lba);
static std::unique_ptr<TimingEvent> s_command_event;
static std::unique_ptr<TimingEvent> s_command_second_response_event;
static std::unique_ptr<TimingEvent> s_async_interrupt_event;
static std::unique_ptr<TimingEvent> s_drive_event;
static Command s_command = Command::None;
static Command s_command_second_response = Command::None;
static DriveState s_drive_state = DriveState::Idle;
static DiscRegion s_disc_region = DiscRegion::Other;
static StatusRegister s_status = {};
static SecondaryStatusRegister s_secondary_status = {};
static ModeRegister s_mode = {};
static u8 s_interrupt_enable_register = INTERRUPT_REGISTER_MASK;
static u8 s_interrupt_flag_register = 0;
static u8 s_pending_async_interrupt = 0;
static u32 s_last_interrupt_time = 0;
static CDImage::Position s_setloc_position = {};
static CDImage::LBA s_requested_lba{};
static CDImage::LBA s_current_lba{}; // this is the hold position
static CDImage::LBA s_seek_start_lba{};
static CDImage::LBA s_seek_end_lba{};
static CDImage::LBA s_physical_lba{}; // current position of the disc with respect to time
static u32 s_physical_lba_update_tick = 0;
static u32 s_physical_lba_update_carry = 0;
static bool s_setloc_pending = false;
static bool s_read_after_seek = false;
static bool s_play_after_seek = false;
static bool s_muted = false;
static bool s_adpcm_muted = false;
static u8 s_xa_filter_file_number = 0;
static u8 s_xa_filter_channel_number = 0;
static u8 s_xa_current_file_number = 0;
static u8 s_xa_current_channel_number = 0;
static u8 s_xa_current_set = false;
static CDImage::SectorHeader s_last_sector_header{};
static CDXA::XASubHeader s_last_sector_subheader{};
static bool s_last_sector_header_valid = false; // TODO: Rename to "logical pause" or something.
static CDImage::SubChannelQ s_last_subq{};
static u8 s_last_cdda_report_frame_nibble = 0xFF;
static u8 s_play_track_number_bcd = 0xFF;
static u8 s_async_command_parameter = 0x00;
static s8 s_fast_forward_rate = 0;
static std::array<std::array<u8, 2>, 2> s_cd_audio_volume_matrix{};
static std::array<std::array<u8, 2>, 2> s_next_cd_audio_volume_matrix{};
static std::array<s32, 4> s_xa_last_samples{};
static std::array<std::array<s16, XA_RESAMPLE_RING_BUFFER_SIZE>, 2> s_xa_resample_ring_buffer{};
static u8 s_xa_resample_p = 0;
static u8 s_xa_resample_sixstep = 6;
static InlineFIFOQueue<u8, PARAM_FIFO_SIZE> s_param_fifo;
static InlineFIFOQueue<u8, RESPONSE_FIFO_SIZE> s_response_fifo;
static InlineFIFOQueue<u8, RESPONSE_FIFO_SIZE> s_async_response_fifo;
static HeapFIFOQueue<u8, DATA_FIFO_SIZE> s_data_fifo;
struct SectorBuffer
{
FixedHeapArray<u8, RAW_SECTOR_OUTPUT_SIZE> data;
u32 size;
};
static u32 s_current_read_sector_buffer = 0;
static u32 s_current_write_sector_buffer = 0;
static std::array<SectorBuffer, NUM_SECTOR_BUFFERS> s_sector_buffers;
static CDROMAsyncReader m_reader;
// two 16-bit samples packed in 32-bits
static HeapFIFOQueue<u32, AUDIO_FIFO_SIZE> s_audio_fifo;
static constexpr std::array<const char*, 15> s_drive_state_names = {
{"Idle", "Opening Shell", "Resetting", "Seeking (Physical)", "Seeking (Logical)", "Reading ID", "Reading TOC",
"Reading", "Playing", "Pausing", "Stopping", "Changing Session", "Spinning Up", "Seeking (Implicit)",
"Changing Speed/Implicit TOC Read"}};
struct CommandInfo
{
const char* name;
u8 expected_parameters;
};
static std::array<CommandInfo, 255> s_command_info = {{
{"Sync", 0}, {"Getstat", 0}, {"Setloc", 3}, {"Play", 0}, {"Forward", 0}, {"Backward", 0}, {"ReadN", 0},
{"Standby", 0}, {"Stop", 0}, {"Pause", 0}, {"Init", 0}, {"Mute", 0}, {"Demute", 0}, {"Setfilter", 2},
{"Setmode", 1}, {"Getmode", 0}, {"GetlocL", 0}, {"GetlocP", 0}, {"ReadT", 1}, {"GetTN", 0}, {"GetTD", 1},
{"SeekL", 0}, {"SeekP", 0}, {"SetClock", 0}, {"GetClock", 0}, {"Test", 1}, {"GetID", 0}, {"ReadS", 0},
{"Reset", 0}, {"GetQ", 2}, {"ReadTOC", 0}, {"VideoCD", 6}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0}, {"Unknown", 0},
{"Unknown", 0}, {"Unknown", 0}, {nullptr, 0} // Unknown
}};
} // namespace CDROM
void CDROM::Initialize()
{
s_command_event =
TimingEvents::CreateTimingEvent("CDROM Command Event", 1, 1, &CDROM::ExecuteCommand, nullptr, false);
s_command_second_response_event = TimingEvents::CreateTimingEvent(
"CDROM Command Second Response Event", 1, 1, &CDROM::ExecuteCommandSecondResponse, nullptr, false);
s_async_interrupt_event = TimingEvents::CreateTimingEvent("CDROM Async Interrupt Event", INTERRUPT_DELAY_CYCLES, 1,
&CDROM::DeliverAsyncInterrupt, nullptr, false);
s_drive_event = TimingEvents::CreateTimingEvent("CDROM Drive Event", 1, 1, &CDROM::ExecuteDrive, nullptr, false);
if (g_settings.cdrom_readahead_sectors > 0)
m_reader.StartThread(g_settings.cdrom_readahead_sectors);
Reset();
}
void CDROM::Shutdown()
{
s_drive_event.reset();
s_async_interrupt_event.reset();
s_command_second_response_event.reset();
s_command_event.reset();
m_reader.StopThread();
m_reader.RemoveMedia();
}
void CDROM::Reset()
{
s_command = Command::None;
s_command_event->Deactivate();
ClearCommandSecondResponse();
ClearDriveState();
s_status.bits = 0;
s_secondary_status.bits = 0;
s_secondary_status.motor_on = CanReadMedia();
s_secondary_status.shell_open = !CanReadMedia();
s_mode.bits = 0;
s_mode.read_raw_sector = true;
s_interrupt_enable_register = INTERRUPT_REGISTER_MASK;
s_interrupt_flag_register = 0;
s_last_interrupt_time = TimingEvents::GetGlobalTickCounter() - MINIMUM_INTERRUPT_DELAY;
ClearAsyncInterrupt();
s_setloc_position = {};
s_seek_start_lba = 0;
s_seek_end_lba = 0;
s_setloc_pending = false;
s_read_after_seek = false;
s_play_after_seek = false;
s_muted = false;
s_adpcm_muted = false;
s_xa_filter_file_number = 0;
s_xa_filter_channel_number = 0;
s_xa_current_file_number = 0;
s_xa_current_channel_number = 0;
s_xa_current_set = false;
std::memset(&s_last_sector_header, 0, sizeof(s_last_sector_header));
std::memset(&s_last_sector_subheader, 0, sizeof(s_last_sector_subheader));
s_last_sector_header_valid = false;
std::memset(&s_last_subq, 0, sizeof(s_last_subq));
s_last_cdda_report_frame_nibble = 0xFF;
s_next_cd_audio_volume_matrix[0][0] = 0x80;
s_next_cd_audio_volume_matrix[0][1] = 0x00;
s_next_cd_audio_volume_matrix[1][0] = 0x00;
s_next_cd_audio_volume_matrix[1][1] = 0x80;
s_cd_audio_volume_matrix = s_next_cd_audio_volume_matrix;
ResetAudioDecoder();
s_param_fifo.Clear();
s_response_fifo.Clear();
s_async_response_fifo.Clear();
s_data_fifo.Clear();
s_current_read_sector_buffer = 0;
s_current_write_sector_buffer = 0;
for (u32 i = 0; i < NUM_SECTOR_BUFFERS; i++)
{
s_sector_buffers[i].data.fill(0);
s_sector_buffers[i].size = 0;
}
UpdateStatusRegister();
SetHoldPosition(0, true);
}
void CDROM::SoftReset(TickCount ticks_late)
{
const bool was_double_speed = s_mode.double_speed;
ClearCommandSecondResponse();
ClearDriveState();
s_secondary_status.bits = 0;
s_secondary_status.motor_on = CanReadMedia();
s_secondary_status.shell_open = !CanReadMedia();
s_mode.bits = 0;
s_mode.read_raw_sector = true;
ClearAsyncInterrupt();
s_setloc_position = {};
s_setloc_pending = false;
s_read_after_seek = false;
s_play_after_seek = false;
s_muted = false;
s_adpcm_muted = false;
s_last_cdda_report_frame_nibble = 0xFF;
ResetAudioDecoder();
s_param_fifo.Clear();
s_async_response_fifo.Clear();
s_data_fifo.Clear();
s_current_read_sector_buffer = 0;
s_current_write_sector_buffer = 0;
for (u32 i = 0; i < NUM_SECTOR_BUFFERS; i++)
{
s_sector_buffers[i].data.fill(0);
s_sector_buffers[i].size = 0;
}
UpdateStatusRegister();
if (HasMedia())
{
const TickCount speed_change_ticks = was_double_speed ? GetTicksForSpeedChange() : 0;
const TickCount seek_ticks = (s_current_lba != 0) ? GetTicksForSeek(0) : 0;
const TickCount total_ticks = std::max<TickCount>(speed_change_ticks + seek_ticks, INIT_TICKS) - ticks_late;
Log_DevPrintf("CDROM init total disc ticks = %d (speed change = %d, seek = %d)", total_ticks, speed_change_ticks,
seek_ticks);
if (s_current_lba != 0)
{
s_drive_state = DriveState::SeekingImplicit;
s_drive_event->SetIntervalAndSchedule(total_ticks);
s_requested_lba = 0;
m_reader.QueueReadSector(s_requested_lba);
s_seek_start_lba = s_current_lba;
s_seek_end_lba = 0;
}
else
{
s_drive_state = DriveState::ChangingSpeedOrTOCRead;
s_drive_event->Schedule(total_ticks);
}
}
}
bool CDROM::DoState(StateWrapper& sw)
{
sw.Do(&s_command);
sw.DoEx(&s_command_second_response, 53, Command::None);
sw.Do(&s_drive_state);
sw.Do(&s_status.bits);
sw.Do(&s_secondary_status.bits);
sw.Do(&s_mode.bits);
bool current_double_speed = s_mode.double_speed;
sw.Do(&current_double_speed);
sw.Do(&s_interrupt_enable_register);
sw.Do(&s_interrupt_flag_register);
sw.DoEx(&s_last_interrupt_time, 57, TimingEvents::GetGlobalTickCounter() - MINIMUM_INTERRUPT_DELAY);
sw.Do(&s_pending_async_interrupt);
sw.DoPOD(&s_setloc_position);
sw.Do(&s_current_lba);
sw.Do(&s_seek_start_lba);
sw.Do(&s_seek_end_lba);
sw.DoEx(&s_physical_lba, 49, s_current_lba);
sw.DoEx(&s_physical_lba_update_tick, 49, static_cast<u32>(0));
sw.DoEx(&s_physical_lba_update_carry, 54, static_cast<u32>(0));
sw.Do(&s_setloc_pending);
sw.Do(&s_read_after_seek);
sw.Do(&s_play_after_seek);
sw.Do(&s_muted);
sw.Do(&s_adpcm_muted);
sw.Do(&s_xa_filter_file_number);
sw.Do(&s_xa_filter_channel_number);
sw.Do(&s_xa_current_file_number);
sw.Do(&s_xa_current_channel_number);
sw.Do(&s_xa_current_set);
sw.DoBytes(&s_last_sector_header, sizeof(s_last_sector_header));
sw.DoBytes(&s_last_sector_subheader, sizeof(s_last_sector_subheader));
sw.Do(&s_last_sector_header_valid);
sw.DoBytes(&s_last_subq, sizeof(s_last_subq));
sw.Do(&s_last_cdda_report_frame_nibble);
sw.Do(&s_play_track_number_bcd);
sw.Do(&s_async_command_parameter);
sw.DoEx(&s_fast_forward_rate, 49, static_cast<s8>(0));
sw.Do(&s_cd_audio_volume_matrix);
sw.Do(&s_next_cd_audio_volume_matrix);
sw.Do(&s_xa_last_samples);
sw.Do(&s_xa_resample_ring_buffer);
sw.Do(&s_xa_resample_p);
sw.Do(&s_xa_resample_sixstep);
sw.Do(&s_param_fifo);
sw.Do(&s_response_fifo);
sw.Do(&s_async_response_fifo);
sw.Do(&s_data_fifo);
sw.Do(&s_current_read_sector_buffer);
sw.Do(&s_current_write_sector_buffer);
for (u32 i = 0; i < NUM_SECTOR_BUFFERS; i++)
{
sw.Do(&s_sector_buffers[i].data);
sw.Do(&s_sector_buffers[i].size);
}
sw.Do(&s_audio_fifo);
sw.Do(&s_requested_lba);
if (sw.IsReading())
{
if (m_reader.HasMedia())
m_reader.QueueReadSector(s_requested_lba);
UpdateCommandEvent();
s_drive_event->SetState(!IsDriveIdle());
// Time will get fixed up later.
s_command_second_response_event->SetState(s_command_second_response != Command::None);
}
return !sw.HasError();
}
bool CDROM::HasMedia()
{
return m_reader.HasMedia();
}
const std::string& CDROM::GetMediaFileName()
{
return m_reader.GetMediaFileName();
}
const CDImage* CDROM::GetMedia()
{
return m_reader.GetMedia();
}
DiscRegion CDROM::GetDiscRegion()
{
return s_disc_region;
}
bool CDROM::IsMediaPS1Disc()
{
return (s_disc_region != DiscRegion::NonPS1);
}
bool CDROM::IsMediaAudioCD()
{
if (!m_reader.HasMedia())
return false;
// Check for an audio track as the first track.
return (m_reader.GetMedia()->GetTrackMode(1) == CDImage::TrackMode::Audio);
}
bool CDROM::DoesMediaRegionMatchConsole()
{
if (!g_settings.cdrom_region_check)
return true;
if (s_disc_region == DiscRegion::Other)
return false;
return System::GetRegion() == System::GetConsoleRegionForDiscRegion(s_disc_region);
}
bool CDROM::IsDriveIdle()
{
return s_drive_state == DriveState::Idle;
}
bool CDROM::IsMotorOn()
{
return s_secondary_status.motor_on;
}
bool CDROM::IsSeeking()
{
return (s_drive_state == DriveState::SeekingLogical || s_drive_state == DriveState::SeekingPhysical ||
s_drive_state == DriveState::SeekingImplicit);
}
bool CDROM::IsReadingOrPlaying()
{
return (s_drive_state == DriveState::Reading || s_drive_state == DriveState::Playing);
}
bool CDROM::CanReadMedia()
{
return (s_drive_state != DriveState::ShellOpening && m_reader.HasMedia());
}
void CDROM::InsertMedia(std::unique_ptr<CDImage> media, DiscRegion region)
{
if (CanReadMedia())
RemoveMedia(true);
Log_InfoPrintf("Inserting new media, disc region: %s, console region: %s", Settings::GetDiscRegionName(region),
Settings::GetConsoleRegionName(System::GetRegion()));
s_disc_region = region;
m_reader.SetMedia(std::move(media));
SetHoldPosition(0, true);
// motor automatically spins up
if (s_drive_state != DriveState::ShellOpening)
StartMotor();
}
std::unique_ptr<CDImage> CDROM::RemoveMedia(bool for_disc_swap)
{
if (!HasMedia())
return nullptr;
// Add an additional two seconds to the disc swap, some games don't like it happening too quickly.
TickCount stop_ticks = GetTicksForStop(true);
if (for_disc_swap)
stop_ticks += System::ScaleTicksToOverclock(System::MASTER_CLOCK * 2);
Log_InfoPrintf("Removing CD...");
std::unique_ptr<CDImage> image = m_reader.RemoveMedia();
s_last_sector_header_valid = false;
s_secondary_status.motor_on = false;
s_secondary_status.shell_open = true;
s_secondary_status.ClearActiveBits();
s_disc_region = DiscRegion::NonPS1;
// If the drive was doing anything, we need to abort the command.
ClearDriveState();
ClearCommandSecondResponse();
s_command = Command::None;
s_command_event->Deactivate();
// The console sends an interrupt when the shell is opened regardless of whether a command was executing.
if (HasPendingAsyncInterrupt())
ClearAsyncInterrupt();
SendAsyncErrorResponse(STAT_ERROR, 0x08);
// Begin spin-down timer, we can't swap the new disc in immediately for some games (e.g. Metal Gear Solid).
if (for_disc_swap)
{
s_drive_state = DriveState::ShellOpening;
s_drive_event->SetIntervalAndSchedule(stop_ticks);
}
return image;
}
bool CDROM::PrecacheMedia()
{
if (!m_reader.HasMedia())
return false;
if (m_reader.GetMedia()->HasSubImages() && m_reader.GetMedia()->GetSubImageCount() > 1)
{
Host::AddFormattedOSDMessage(15.0f,
TRANSLATE("OSDMessage", "CD image preloading not available for multi-disc image '%s'"),
FileSystem::GetDisplayNameFromPath(m_reader.GetMedia()->GetFileName()).c_str());
return false;
}
HostInterfaceProgressCallback callback;
if (!m_reader.Precache(&callback))
{
Host::AddOSDMessage(TRANSLATE_STR("OSDMessage", "Precaching CD image failed, it may be unreliable."), 15.0f);
return false;
}
return true;
}
TinyString CDROM::LBAToMSFString(CDImage::LBA lba)
{
const auto pos = CDImage::Position::FromLBA(lba);
return TinyString::from_fmt("{:02d}:{:02d}:{:02d}", pos.minute, pos.second, pos.frame);
}
void CDROM::SetReadaheadSectors(u32 readahead_sectors)
{
const bool want_thread = (readahead_sectors > 0);
if (want_thread == m_reader.IsUsingThread() && m_reader.GetReadaheadCount() == readahead_sectors)
return;
if (want_thread)
m_reader.StartThread(readahead_sectors);
else
m_reader.StopThread();
if (HasMedia())
m_reader.QueueReadSector(s_requested_lba);
}
void CDROM::CPUClockChanged()
{
// reschedule the disc read event
if (IsReadingOrPlaying())
s_drive_event->SetInterval(GetTicksForRead());
}
u8 CDROM::ReadRegister(u32 offset)
{
switch (offset)
{
case 0: // status register
Log_TracePrintf("CDROM read status register -> 0x%08X", s_status.bits);
return s_status.bits;
case 1: // always response FIFO
{
if (s_response_fifo.IsEmpty())
{
Log_DevPrint("Response FIFO empty on read");
return 0x00;
}
const u8 value = s_response_fifo.Pop();
UpdateStatusRegister();
Log_DebugPrintf("CDROM read response FIFO -> 0x%08X", ZeroExtend32(value));
return value;
}
case 2: // always data FIFO
{
const u8 value = s_data_fifo.Pop();
UpdateStatusRegister();
Log_DebugPrintf("CDROM read data FIFO -> 0x%08X", ZeroExtend32(value));
return value;
}
case 3:
{
if (s_status.index & 1)
{
const u8 value = s_interrupt_flag_register | ~INTERRUPT_REGISTER_MASK;
Log_DebugPrintf("CDROM read interrupt flag register -> 0x%02X", ZeroExtend32(value));
return value;
}
else
{
const u8 value = s_interrupt_enable_register | ~INTERRUPT_REGISTER_MASK;
Log_DebugPrintf("CDROM read interrupt enable register -> 0x%02X", ZeroExtend32(value));
return value;
}
}
break;
}
Log_ErrorPrintf("Unknown CDROM register read: offset=0x%02X, index=%d", offset,
ZeroExtend32(s_status.index.GetValue()));
Panic("Unknown CDROM register");
}
void CDROM::WriteRegister(u32 offset, u8 value)
{
if (offset == 0)
{
Log_TracePrintf("CDROM status register <- 0x%02X", value);
s_status.bits = (s_status.bits & static_cast<u8>(~3)) | (value & u8(3));
return;
}
const u32 reg = (s_status.index * 3u) + (offset - 1);
switch (reg)
{
case 0:
{
Log_DebugPrintf("CDROM command register <- 0x%02X (%s)", value, s_command_info[value].name);
BeginCommand(static_cast<Command>(value));
return;
}
case 1:
{
if (s_param_fifo.IsFull())
{
Log_WarningPrintf("Parameter FIFO overflow");
s_param_fifo.RemoveOne();
}
s_param_fifo.Push(value);
UpdateStatusRegister();
return;
}
case 2:
{
Log_DebugPrintf("Request register <- 0x%02X", value);
const RequestRegister rr{value};
// Sound map is not currently implemented, haven't found anything which uses it.
if (rr.SMEN)
Log_ErrorPrintf("Sound map enable set");
if (rr.BFWR)
Log_ErrorPrintf("Buffer write enable set");
if (rr.BFRD)
{
LoadDataFIFO();
}
else
{
Log_DebugPrintf("Clearing data FIFO");
s_data_fifo.Clear();
}
UpdateStatusRegister();
return;
}
case 3:
{
Log_ErrorPrintf("Sound map data out <- 0x%02X", value);
return;
}
case 4:
{
Log_DebugPrintf("Interrupt enable register <- 0x%02X", value);
s_interrupt_enable_register = value & INTERRUPT_REGISTER_MASK;
UpdateInterruptRequest();
return;
}
case 5:
{
Log_DebugPrintf("Interrupt flag register <- 0x%02X", value);
s_interrupt_flag_register &= ~(value & INTERRUPT_REGISTER_MASK);
if (s_interrupt_flag_register == 0)
{
if (HasPendingAsyncInterrupt())
QueueDeliverAsyncInterrupt();
else
UpdateCommandEvent();
}
// Bit 6 clears the parameter FIFO.
if (value & 0x40)
{
s_param_fifo.Clear();
UpdateStatusRegister();
}
return;
}
case 6:
{
Log_ErrorPrintf("Sound map coding info <- 0x%02X", value);
return;
}
case 7:
{
Log_DebugPrintf("Audio volume for left-to-left output <- 0x%02X", value);
s_next_cd_audio_volume_matrix[0][0] = value;
return;
}
case 8:
{
Log_DebugPrintf("Audio volume for left-to-right output <- 0x%02X", value);
s_next_cd_audio_volume_matrix[0][1] = value;
return;
}
case 9:
{
Log_DebugPrintf("Audio volume for right-to-right output <- 0x%02X", value);
s_next_cd_audio_volume_matrix[1][1] = value;
return;
}
case 10:
{
Log_DebugPrintf("Audio volume for right-to-left output <- 0x%02X", value);
s_next_cd_audio_volume_matrix[1][0] = value;
return;
}
case 11:
{
Log_DebugPrintf("Audio volume apply changes <- 0x%02X", value);
const bool adpcm_muted = ConvertToBoolUnchecked(value & u8(0x01));
if (adpcm_muted != s_adpcm_muted ||
(value & 0x20 && std::memcmp(s_cd_audio_volume_matrix.data(), s_next_cd_audio_volume_matrix.data(),
sizeof(s_cd_audio_volume_matrix)) != 0))
{
if (HasPendingDiscEvent())
s_drive_event->InvokeEarly();
SPU::GeneratePendingSamples();
}
s_adpcm_muted = adpcm_muted;
if (value & 0x20)
s_cd_audio_volume_matrix = s_next_cd_audio_volume_matrix;
return;
}
default:
{
Log_ErrorPrintf("Unknown CDROM register write: offset=0x%02X, index=%d, reg=%u, value=0x%02X", offset,
s_status.index.GetValue(), reg, value);
return;
}
}
}
void CDROM::DMARead(u32* words, u32 word_count)
{
const u32 words_in_fifo = s_data_fifo.GetSize() / 4;
if (words_in_fifo < word_count)
{
Log_ErrorPrintf("DMA read on empty/near-empty data FIFO");
std::memset(words + words_in_fifo, 0, sizeof(u32) * (word_count - words_in_fifo));
}
const u32 bytes_to_read = std::min<u32>(word_count * sizeof(u32), s_data_fifo.GetSize());
s_data_fifo.PopRange(reinterpret_cast<u8*>(words), bytes_to_read);
}
bool CDROM::HasPendingCommand()
{
return s_command != Command::None;
}
bool CDROM::HasPendingInterrupt()
{
return s_interrupt_flag_register != 0;
}
bool CDROM::HasPendingAsyncInterrupt()
{
return s_pending_async_interrupt != 0;
}
void CDROM::SetInterrupt(Interrupt interrupt)
{
s_interrupt_flag_register = static_cast<u8>(interrupt);
s_last_interrupt_time = TimingEvents::GetGlobalTickCounter();
UpdateInterruptRequest();
}
void CDROM::SetAsyncInterrupt(Interrupt interrupt)
{
if (s_interrupt_flag_register == static_cast<u8>(interrupt))
{
Log_DevPrintf("Not setting async interrupt %u because there is already one unacknowledged",
static_cast<u8>(interrupt));
s_async_response_fifo.Clear();
return;
}
Assert(s_pending_async_interrupt == 0);
s_pending_async_interrupt = static_cast<u8>(interrupt);
if (!HasPendingInterrupt())
QueueDeliverAsyncInterrupt();
}
void CDROM::ClearAsyncInterrupt()
{
s_pending_async_interrupt = 0;
s_async_interrupt_event->Deactivate();
s_async_response_fifo.Clear();
}
void CDROM::QueueDeliverAsyncInterrupt()
{
// Why do we need this mess? A few games, such as Ogre Battle, like to spam GetlocL or GetlocP while
// XA playback is going. The problem is, when that happens and an INT1 also comes in. Instead of
// reading the interrupt flag, reading the FIFO, and then clearing the interrupt, they clear the
// interrupt, then read the FIFO. If an INT1 comes in during that time, it'll read the INT1 response
// instead of the INT3 response, and the game gets confused. So, we just delay INT1s a bit, if there
// has been any recent INT3s - give it enough time to read the response out. The real console does
// something similar anyway, the INT1 task won't run immediately after the INT3 is cleared.
if (!HasPendingAsyncInterrupt())
return;
// underflows here are okay
const u32 diff = TimingEvents::GetGlobalTickCounter() - s_last_interrupt_time;
if (diff >= MINIMUM_INTERRUPT_DELAY)
{
DeliverAsyncInterrupt(nullptr, 0, 0);
}
else
{
Log_DevPrintf("Delaying async interrupt %u because it's been %u cycles since last interrupt",
s_pending_async_interrupt, diff);
s_async_interrupt_event->Schedule(INTERRUPT_DELAY_CYCLES);
}
}
void CDROM::DeliverAsyncInterrupt(void*, TickCount ticks, TickCount ticks_late)
{
if (HasPendingInterrupt())
{
// This shouldn't really happen, because we should block command execution.. but just in case.
if (!s_async_interrupt_event->IsActive())
s_async_interrupt_event->Schedule(INTERRUPT_DELAY_CYCLES);
}
else
{
s_async_interrupt_event->Deactivate();
Assert(s_pending_async_interrupt != 0 && !HasPendingInterrupt());
Log_DebugPrintf("Delivering async interrupt %u", s_pending_async_interrupt);
if (s_pending_async_interrupt == static_cast<u8>(Interrupt::DataReady))
s_current_read_sector_buffer = s_current_write_sector_buffer;
s_response_fifo.Clear();
s_response_fifo.PushFromQueue(&s_async_response_fifo);
s_interrupt_flag_register = s_pending_async_interrupt;
s_pending_async_interrupt = 0;
UpdateInterruptRequest();
UpdateStatusRegister();
UpdateCommandEvent();
}
}
void CDROM::SendACKAndStat()
{
s_response_fifo.Push(s_secondary_status.bits);
SetInterrupt(Interrupt::ACK);
}
void CDROM::SendErrorResponse(u8 stat_bits /* = STAT_ERROR */, u8 reason /* = 0x80 */)
{
s_response_fifo.Push(s_secondary_status.bits | stat_bits);
s_response_fifo.Push(reason);
SetInterrupt(Interrupt::Error);
}
void CDROM::SendAsyncErrorResponse(u8 stat_bits /* = STAT_ERROR */, u8 reason /* = 0x80 */)
{
s_async_response_fifo.Push(s_secondary_status.bits | stat_bits);
s_async_response_fifo.Push(reason);
SetAsyncInterrupt(Interrupt::Error);
}
void CDROM::UpdateStatusRegister()
{
s_status.ADPBUSY = false;
s_status.PRMEMPTY = s_param_fifo.IsEmpty();
s_status.PRMWRDY = !s_param_fifo.IsFull();
s_status.RSLRRDY = !s_response_fifo.IsEmpty();
s_status.DRQSTS = !s_data_fifo.IsEmpty();
s_status.BUSYSTS = HasPendingCommand();
DMA::SetRequest(DMA::Channel::CDROM, s_status.DRQSTS);
}
void CDROM::UpdateInterruptRequest()
{
if ((s_interrupt_flag_register & s_interrupt_enable_register) == 0)
return;
InterruptController::InterruptRequest(InterruptController::IRQ::CDROM);
}
bool CDROM::HasPendingDiscEvent()
{
return (s_drive_event->IsActive() && s_drive_event->GetTicksUntilNextExecution() <= 0);
}
TickCount CDROM::GetAckDelayForCommand(Command command)
{
if (command == Command::Init)
{
// Init takes longer.
return 80000;
}
// Tests show that the average time to acknowledge a command is significantly higher when a disc is in the drive,
// presumably because the controller is busy doing discy-things.
constexpr u32 default_ack_delay_no_disc = 15000;
constexpr u32 default_ack_delay_with_disc = 25000;
return CanReadMedia() ? default_ack_delay_with_disc : default_ack_delay_no_disc;
}
TickCount CDROM::GetTicksForSpinUp()
{
// 1 second
return System::GetTicksPerSecond();
}
TickCount CDROM::GetTicksForIDRead()
{
TickCount ticks = ID_READ_TICKS;
if (s_drive_state == DriveState::SpinningUp)
ticks += s_drive_event->GetTicksUntilNextExecution();
return ticks;
}
TickCount CDROM::GetTicksForRead()
{
const TickCount tps = System::GetTicksPerSecond();
if (g_settings.cdrom_read_speedup > 1 && !s_mode.cdda && !s_mode.xa_enable && s_mode.double_speed)
return tps / (150 * g_settings.cdrom_read_speedup);
return s_mode.double_speed ? (tps / 150) : (tps / 75);
}
TickCount CDROM::GetTicksForSeek(CDImage::LBA new_lba, bool ignore_speed_change)
{
static constexpr TickCount MIN_TICKS = 20000;
if (g_settings.cdrom_seek_speedup == 0)
return MIN_TICKS;
u32 ticks = static_cast<u32>(MIN_TICKS);
if (IsSeeking())
ticks += s_drive_event->GetTicksUntilNextExecution();
else
UpdatePhysicalPosition(false);
const u32 ticks_per_sector =
s_mode.double_speed ? static_cast<u32>(System::MASTER_CLOCK / 150) : static_cast<u32>(System::MASTER_CLOCK / 75);
const u32 ticks_per_second = static_cast<u32>(System::MASTER_CLOCK);
const CDImage::LBA current_lba = IsMotorOn() ? (IsSeeking() ? s_seek_end_lba : s_physical_lba) : 0;
const u32 lba_diff = static_cast<u32>((new_lba > current_lba) ? (new_lba - current_lba) : (current_lba - new_lba));
// Motor spin-up time.
if (!IsMotorOn())
{
ticks +=
(s_drive_state == DriveState::SpinningUp) ? s_drive_event->GetTicksUntilNextExecution() : GetTicksForSpinUp();
if (s_drive_state == DriveState::ShellOpening || s_drive_state == DriveState::SpinningUp)
ClearDriveState();
}
if (lba_diff < 32)
{
// Special case: when we land exactly on the right sector, we're already too late.
ticks += ticks_per_sector * std::min<u32>(5u, (lba_diff == 0) ? 4u : lba_diff);
}
else
{
// This is a still not a very accurate model, but it's roughly in line with the behavior of hardware tests.
const float disc_distance = 0.2323384936f * std::log(static_cast<float>((new_lba / 4500) + 1u));
float seconds;
if (lba_diff <= CDImage::FRAMES_PER_SECOND)
{
// 30ms + (diff * 30ms) + (disc distance * 30ms)
seconds = 0.03f + ((static_cast<float>(lba_diff) / static_cast<float>(CDImage::FRAMES_PER_SECOND)) * 0.03f) +
(disc_distance * 0.03f);
}
else if (lba_diff <= CDImage::FRAMES_PER_MINUTE)
{
// 150ms + (diff * 30ms) + (disc distance * 50ms)
seconds = 0.15f + ((static_cast<float>(lba_diff) / static_cast<float>(CDImage::FRAMES_PER_MINUTE)) * 0.03f) +
(disc_distance * 0.05f);
}
else
{
// 200ms + (diff * 500ms)
seconds = 0.2f + ((static_cast<float>(lba_diff) / static_cast<float>(72 * CDImage::FRAMES_PER_MINUTE)) * 0.4f);
}
ticks += static_cast<u32>(seconds * static_cast<float>(ticks_per_second));
}
if (s_drive_state == DriveState::ChangingSpeedOrTOCRead && !ignore_speed_change)
{
// we're still reading the TOC, so add that time in
const TickCount remaining_change_ticks = s_drive_event->GetTicksUntilNextExecution();
ticks += remaining_change_ticks;
Log_DevPrintf("Seek time for %u LBAs: %d (%.3f ms) (%d for speed change/implicit TOC read)", lba_diff, ticks,
(static_cast<float>(ticks) / static_cast<float>(ticks_per_second)) * 1000.0f, remaining_change_ticks);
}
else
{
Log_DevPrintf("Seek time for %u LBAs: %d (%.3f ms)", lba_diff, ticks,
(static_cast<float>(ticks) / static_cast<float>(ticks_per_second)) * 1000.0f);
}
if (g_settings.cdrom_seek_speedup > 1)
ticks = std::min<u32>(ticks / g_settings.cdrom_seek_speedup, MIN_TICKS);
return System::ScaleTicksToOverclock(static_cast<TickCount>(ticks));
}
TickCount CDROM::GetTicksForStop(bool motor_was_on)
{
return System::ScaleTicksToOverclock(motor_was_on ? (s_mode.double_speed ? 25000000 : 13000000) : 7000);
}
TickCount CDROM::GetTicksForSpeedChange()
{
static constexpr u32 ticks_single_to_double = static_cast<u32>(0.8 * static_cast<double>(System::MASTER_CLOCK));
static constexpr u32 ticks_double_to_single = static_cast<u32>(1.0 * static_cast<double>(System::MASTER_CLOCK));
return System::ScaleTicksToOverclock(s_mode.double_speed ? ticks_single_to_double : ticks_double_to_single);
}
TickCount CDROM::GetTicksForTOCRead()
{
if (!HasMedia())
return 0;
return System::GetTicksPerSecond() / 2u;
}
CDImage::LBA CDROM::GetNextSectorToBeRead()
{
if (!IsReadingOrPlaying())
return s_current_lba;
m_reader.WaitForReadToComplete();
return m_reader.GetLastReadSector();
}
void CDROM::BeginCommand(Command command)
{
TickCount ack_delay = GetAckDelayForCommand(command);
if (HasPendingCommand())
{
// The behavior here is kinda.. interesting. Some commands seem to take precedence over others, for example
// sending a Nop command followed by a GetlocP will return the GetlocP response, and the same for the inverse.
// However, other combinations result in strange behavior, for example sending a Setloc followed by a ReadN will
// fail with ERROR_REASON_INCORRECT_NUMBER_OF_PARAMETERS. This particular example happens in Voice Idol
// Collection - Pool Bar Story, and the loading time is lengthened as well as audio slowing down if this
// behavior is not correct. So, let's use a heuristic; if the number of parameters of the "old" command is
// greater than the "new" command, empty the FIFO, which will return the error when the command executes.
// Otherwise, override the command with the new one.
if (s_command_info[static_cast<u8>(s_command)].expected_parameters >
s_command_info[static_cast<u8>(command)].expected_parameters)
{
Log_WarningPrintf("Ignoring command 0x%02X (%s) and emptying FIFO as 0x%02x (%s) is still pending",
static_cast<u8>(command), s_command_info[static_cast<u8>(command)].name,
static_cast<u8>(s_command), s_command_info[static_cast<u8>(s_command)].name);
s_param_fifo.Clear();
return;
}
Log_WarningPrintf("Cancelling pending command 0x%02X (%s) for new command 0x%02X (%s)", static_cast<u8>(s_command),
s_command_info[static_cast<u8>(s_command)].name, static_cast<u8>(command),
s_command_info[static_cast<u8>(command)].name);
// subtract the currently-elapsed ack ticks from the new command
if (s_command_event->IsActive())
{
const TickCount elapsed_ticks = s_command_event->GetInterval() - s_command_event->GetTicksUntilNextExecution();
ack_delay = std::max(ack_delay - elapsed_ticks, 1);
s_command_event->Deactivate();
}
}
s_command = command;
s_command_event->SetIntervalAndSchedule(ack_delay);
UpdateCommandEvent();
UpdateStatusRegister();
}
void CDROM::EndCommand()
{
s_param_fifo.Clear();
s_command = Command::None;
s_command_event->Deactivate();
UpdateStatusRegister();
}
void CDROM::ExecuteCommand(void*, TickCount ticks, TickCount ticks_late)
{
const CommandInfo& ci = s_command_info[static_cast<u8>(s_command)];
Log_DevPrintf("CDROM executing command 0x%02X (%s), stat = 0x%02X", static_cast<u8>(s_command), ci.name,
s_secondary_status.bits);
if (s_param_fifo.GetSize() < ci.expected_parameters)
{
Log_WarningPrintf("Too few parameters for command 0x%02X (%s), expecting %u got %u", static_cast<u8>(s_command),
ci.name, ci.expected_parameters, s_param_fifo.GetSize());
SendErrorResponse(STAT_ERROR, ERROR_REASON_INCORRECT_NUMBER_OF_PARAMETERS);
EndCommand();
return;
}
if (!s_response_fifo.IsEmpty())
{
Log_DebugPrintf("Response FIFO not empty on command begin");
s_response_fifo.Clear();
}
switch (s_command)
{
case Command::Getstat:
{
Log_DebugPrintf("CDROM Getstat command");
// if bit 0 or 2 is set, send an additional byte
SendACKAndStat();
// shell open bit is cleared after sending the status
if (CanReadMedia())
s_secondary_status.shell_open = false;
EndCommand();
return;
}
case Command::Test:
{
const u8 subcommand = s_param_fifo.Pop();
ExecuteTestCommand(subcommand);
return;
}
case Command::GetID:
{
Log_DebugPrintf("CDROM GetID command");
ClearCommandSecondResponse();
if (!CanReadMedia())
{
SendErrorResponse(STAT_ERROR, ERROR_REASON_NOT_READY);
}
else
{
SendACKAndStat();
QueueCommandSecondResponse(Command::GetID, GetTicksForIDRead());
}
EndCommand();
return;
}
case Command::ReadTOC:
{
Log_DebugPrintf("CDROM ReadTOC command");
ClearCommandSecondResponse();
if (!CanReadMedia())
{
SendErrorResponse(STAT_ERROR, ERROR_REASON_NOT_READY);
}
else
{
SendACKAndStat();
SetHoldPosition(0, true);
QueueCommandSecondResponse(Command::ReadTOC, GetTicksForTOCRead());
}
EndCommand();
return;
}
case Command::Setfilter:
{
const u8 file = s_param_fifo.Peek(0);
const u8 channel = s_param_fifo.Peek(1);
Log_DebugPrintf("CDROM setfilter command 0x%02X 0x%02X", ZeroExtend32(file), ZeroExtend32(channel));
s_xa_filter_file_number = file;
s_xa_filter_channel_number = channel;
s_xa_current_set = false;
SendACKAndStat();
EndCommand();
return;
}
case Command::Setmode:
{
const u8 mode = s_param_fifo.Peek(0);
const bool speed_change = (mode & 0x80) != (s_mode.bits & 0x80);
Log_DevPrintf("CDROM setmode command 0x%02X", ZeroExtend32(mode));
s_mode.bits = mode;
SendACKAndStat();
EndCommand();
if (speed_change)
{
if (s_drive_state == DriveState::ChangingSpeedOrTOCRead)
{
// cancel the speed change if it's less than a quarter complete
if (s_drive_event->GetTicksUntilNextExecution() >= (GetTicksForSpeedChange() / 4))
{
Log_DevPrintf("Cancelling speed change event");
ClearDriveState();
}
}
else if (s_drive_state != DriveState::SeekingImplicit && s_drive_state != DriveState::ShellOpening)
{
// if we're seeking or reading, we need to add time to the current seek/read
const TickCount change_ticks = GetTicksForSpeedChange();
if (s_drive_state != DriveState::Idle)
{
Log_DevPrintf("Drive is %s, delaying event by %d ticks for speed change to %s-speed",
s_drive_state_names[static_cast<u8>(s_drive_state)], change_ticks,
s_mode.double_speed ? "double" : "single");
s_drive_event->Delay(change_ticks);
}
else
{
Log_DevPrintf("Drive is idle, speed change takes %d ticks", change_ticks);
s_drive_state = DriveState::ChangingSpeedOrTOCRead;
s_drive_event->Schedule(change_ticks);
}
}
}
return;
}
case Command::Setloc:
{
const u8 mm = s_param_fifo.Peek(0);
const u8 ss = s_param_fifo.Peek(1);
const u8 ff = s_param_fifo.Peek(2);
Log_DevPrintf("CDROM setloc command (%02X, %02X, %02X)", mm, ss, ff);
// MM must be BCD, SS must be BCD and <0x60, FF must be BCD and <0x75
if (((mm & 0x0F) > 0x09) || (mm > 0x99) || ((ss & 0x0F) > 0x09) || (ss >= 0x60) || ((ff & 0x0F) > 0x09) ||
(ff >= 0x75))
{
Log_ErrorPrintf("Invalid/out of range seek to %02X:%02X:%02X", mm, ss, ff);
SendErrorResponse(STAT_ERROR, ERROR_REASON_INVALID_ARGUMENT);
}
else
{
SendACKAndStat();
s_setloc_position.minute = PackedBCDToBinary(mm);
s_setloc_position.second = PackedBCDToBinary(ss);
s_setloc_position.frame = PackedBCDToBinary(ff);
s_setloc_pending = true;
}
EndCommand();
return;
}
case Command::SeekL:
case Command::SeekP:
{
const bool logical = (s_command == Command::SeekL);
Log_DebugPrintf("CDROM %s command", logical ? "SeekL" : "SeekP");
if (IsSeeking())
UpdatePositionWhileSeeking();
if (!CanReadMedia())
{
SendErrorResponse(STAT_ERROR, ERROR_REASON_NOT_READY);
}
else
{
SendACKAndStat();
BeginSeeking(logical, false, false);
}
EndCommand();
return;
}
case Command::ReadT:
{
const u8 session = s_param_fifo.Peek(0);
Log_DebugPrintf("CDROM ReadT command, session=%u", session);
if (!CanReadMedia() || s_drive_state == DriveState::Reading || s_drive_state == DriveState::Playing)
{
SendErrorResponse(STAT_ERROR, ERROR_REASON_NOT_READY);
}
else if (session == 0)
{
SendErrorResponse(STAT_ERROR, ERROR_REASON_INVALID_ARGUMENT);
}
else
{
ClearCommandSecondResponse();
SendACKAndStat();
s_async_command_parameter = session;
s_drive_state = DriveState::ChangingSession;
s_drive_event->Schedule(GetTicksForTOCRead());
}
EndCommand();
return;
}
case Command::ReadN:
case Command::ReadS:
{
Log_DebugPrintf("CDROM read command");
if (!CanReadMedia())
{
SendErrorResponse(STAT_ERROR, ERROR_REASON_NOT_READY);
}
else if ((!IsMediaPS1Disc() || !DoesMediaRegionMatchConsole()) && !s_mode.cdda)
{
SendErrorResponse(STAT_ERROR, ERROR_REASON_INVALID_COMMAND);
}
else
{
SendACKAndStat();
if ((!s_setloc_pending || s_setloc_position.ToLBA() == GetNextSectorToBeRead()) &&
(s_drive_state == DriveState::Reading || (IsSeeking() && s_read_after_seek)))
{
Log_DevPrintf("Ignoring read command with %s setloc, already reading/reading after seek",
s_setloc_pending ? "pending" : "same");
s_setloc_pending = false;
}
else
{
if (IsSeeking())
UpdatePositionWhileSeeking();
BeginReading();
}
}
EndCommand();
return;
}
case Command::Play:
{
const u8 track = s_param_fifo.IsEmpty() ? 0 : PackedBCDToBinary(s_param_fifo.Peek(0));
Log_DebugPrintf("CDROM play command, track=%u", track);
if (!CanReadMedia())
{
SendErrorResponse(STAT_ERROR, ERROR_REASON_NOT_READY);
}
else
{
SendACKAndStat();
if (track == 0 && (!s_setloc_pending || s_setloc_position.ToLBA() == GetNextSectorToBeRead()) &&
(s_drive_state == DriveState::Playing || (IsSeeking() && s_play_after_seek)))
{
Log_DevPrintf("Ignoring play command with no/same setloc, already playing/playing after seek");
s_fast_forward_rate = 0;
}
else
{
if (IsSeeking())
UpdatePositionWhileSeeking();
BeginPlaying(track);
}
}
EndCommand();
return;
}
case Command::Forward:
{
if (s_drive_state != DriveState::Playing || !CanReadMedia())
{
SendErrorResponse(STAT_ERROR, ERROR_REASON_NOT_READY);
}
else
{
SendACKAndStat();
if (s_fast_forward_rate < 0)
s_fast_forward_rate = 0;
s_fast_forward_rate += static_cast<s8>(FAST_FORWARD_RATE_STEP);
s_fast_forward_rate = std::min<s8>(s_fast_forward_rate, static_cast<s8>(MAX_FAST_FORWARD_RATE));
}
EndCommand();
return;
}
case Command::Backward:
{
if (s_drive_state != DriveState::Playing || !CanReadMedia())
{
SendErrorResponse(STAT_ERROR, ERROR_REASON_NOT_READY);
}
else
{
SendACKAndStat();
if (s_fast_forward_rate > 0)
s_fast_forward_rate = 0;
s_fast_forward_rate -= static_cast<s8>(FAST_FORWARD_RATE_STEP);
s_fast_forward_rate = std::max<s8>(s_fast_forward_rate, -static_cast<s8>(MAX_FAST_FORWARD_RATE));
}
EndCommand();
return;
}
case Command::Pause:
{
const bool was_reading = (s_drive_state == DriveState::Reading || s_drive_state == DriveState::Playing);
const TickCount pause_time = was_reading ? (s_mode.double_speed ? 2000000 : 1000000) : 7000;
ClearCommandSecondResponse();
SendACKAndStat();
if (s_drive_state == DriveState::SeekingLogical || s_drive_state == DriveState::SeekingPhysical)
{
// TODO: On console, this returns an error. But perhaps only during the coarse/fine seek part? Needs more
// hardware tests.
Log_WarningPrintf("CDROM Pause command while seeking from %u to %u - jumping to seek target", s_seek_start_lba,
s_seek_end_lba);
s_read_after_seek = false;
s_play_after_seek = false;
CompleteSeek();
}
else
{
// Stop reading.
s_drive_state = DriveState::Idle;
s_drive_event->Deactivate();
s_secondary_status.ClearActiveBits();
}
// Reset audio buffer here - control room cutscene audio repeats in Dino Crisis otherwise.
ResetAudioDecoder();
QueueCommandSecondResponse(Command::Pause, pause_time);
EndCommand();
return;
}
case Command::Stop:
{
const TickCount stop_time = GetTicksForStop(IsMotorOn());
ClearCommandSecondResponse();
SendACKAndStat();
StopMotor();
QueueCommandSecondResponse(Command::Stop, stop_time);
EndCommand();
return;
}
case Command::Init:
{
Log_DebugPrintf("CDROM init command");
if (s_command_second_response == Command::Init)
{
// still pending
EndCommand();
return;
}
SendACKAndStat();
if (IsSeeking())
UpdatePositionWhileSeeking();
SoftReset(ticks_late);
QueueCommandSecondResponse(Command::Init, INIT_TICKS);
return;
}
break;
case Command::MotorOn:
{
Log_DebugPrintf("CDROM motor on command");
if (IsMotorOn())
{
SendErrorResponse(STAT_ERROR, ERROR_REASON_INCORRECT_NUMBER_OF_PARAMETERS);
}
else
{
SendACKAndStat();
// still pending?
if (s_command_second_response == Command::MotorOn)
{
EndCommand();
return;
}
if (CanReadMedia())
StartMotor();
QueueCommandSecondResponse(Command::MotorOn, MOTOR_ON_RESPONSE_TICKS);
}
EndCommand();
return;
}
break;
case Command::Mute:
{
Log_DebugPrintf("CDROM mute command");
s_muted = true;
SendACKAndStat();
EndCommand();
}
break;
case Command::Demute:
{
Log_DebugPrintf("CDROM demute command");
s_muted = false;
SendACKAndStat();
EndCommand();
}
break;
case Command::GetlocL:
{
if (!s_last_sector_header_valid)
{
Log_DevPrintf("CDROM GetlocL command - header invalid, status 0x%02X", s_secondary_status.bits);
SendErrorResponse(STAT_ERROR, ERROR_REASON_NOT_READY);
}
else
{
UpdatePhysicalPosition(true);
Log_DebugPrintf("CDROM GetlocL command - [%02X:%02X:%02X]", s_last_sector_header.minute,
s_last_sector_header.second, s_last_sector_header.frame);
s_response_fifo.PushRange(reinterpret_cast<const u8*>(&s_last_sector_header), sizeof(s_last_sector_header));
s_response_fifo.PushRange(reinterpret_cast<const u8*>(&s_last_sector_subheader),
sizeof(s_last_sector_subheader));
SetInterrupt(Interrupt::ACK);
}
EndCommand();
return;
}
case Command::GetlocP:
{
if (!CanReadMedia())
{
Log_DebugPrintf("CDROM GetlocP command - not ready");
SendErrorResponse(STAT_ERROR, ERROR_REASON_NOT_READY);
}
else
{
if (IsSeeking())
UpdatePositionWhileSeeking();
else
UpdatePhysicalPosition(false);
Log_DevPrintf("CDROM GetlocP command - T%02x I%02x R[%02x:%02x:%02x] A[%02x:%02x:%02x]",
s_last_subq.track_number_bcd, s_last_subq.index_number_bcd, s_last_subq.relative_minute_bcd,
s_last_subq.relative_second_bcd, s_last_subq.relative_frame_bcd, s_last_subq.absolute_minute_bcd,
s_last_subq.absolute_second_bcd, s_last_subq.absolute_frame_bcd);
s_response_fifo.Push(s_last_subq.track_number_bcd);
s_response_fifo.Push(s_last_subq.index_number_bcd);
s_response_fifo.Push(s_last_subq.relative_minute_bcd);
s_response_fifo.Push(s_last_subq.relative_second_bcd);
s_response_fifo.Push(s_last_subq.relative_frame_bcd);
s_response_fifo.Push(s_last_subq.absolute_minute_bcd);
s_response_fifo.Push(s_last_subq.absolute_second_bcd);
s_response_fifo.Push(s_last_subq.absolute_frame_bcd);
SetInterrupt(Interrupt::ACK);
}
EndCommand();
return;
}
case Command::GetTN:
{
Log_DebugPrintf("CDROM GetTN command");
if (CanReadMedia())
{
Log_DevPrintf("GetTN -> %u %u", m_reader.GetMedia()->GetFirstTrackNumber(),
m_reader.GetMedia()->GetLastTrackNumber());
s_response_fifo.Push(s_secondary_status.bits);
s_response_fifo.Push(BinaryToBCD(Truncate8(m_reader.GetMedia()->GetFirstTrackNumber())));
s_response_fifo.Push(BinaryToBCD(Truncate8(m_reader.GetMedia()->GetLastTrackNumber())));
SetInterrupt(Interrupt::ACK);
}
else
{
SendErrorResponse(STAT_ERROR, ERROR_REASON_NOT_READY);
}
EndCommand();
}
break;
case Command::GetTD:
{
Log_DebugPrintf("CDROM GetTD command");
Assert(s_param_fifo.GetSize() >= 1);
const u8 track = PackedBCDToBinary(s_param_fifo.Peek());
if (!CanReadMedia())
{
SendErrorResponse(STAT_ERROR, ERROR_REASON_NOT_READY);
}
else if (track > m_reader.GetMedia()->GetTrackCount())
{
SendErrorResponse(STAT_ERROR, ERROR_REASON_INVALID_ARGUMENT);
}
else
{
CDImage::Position pos;
if (track == 0)
pos = CDImage::Position::FromLBA(m_reader.GetMedia()->GetLBACount());
else
pos = m_reader.GetMedia()->GetTrackStartMSFPosition(track);
s_response_fifo.Push(s_secondary_status.bits);
s_response_fifo.Push(BinaryToBCD(Truncate8(pos.minute)));
s_response_fifo.Push(BinaryToBCD(Truncate8(pos.second)));
Log_DevPrintf("GetTD %u -> %u %u", track, pos.minute, pos.second);
SetInterrupt(Interrupt::ACK);
}
EndCommand();
}
break;
case Command::Getmode:
{
Log_DebugPrintf("CDROM Getmode command");
s_response_fifo.Push(s_secondary_status.bits);
s_response_fifo.Push(s_mode.bits);
s_response_fifo.Push(0);
s_response_fifo.Push(s_xa_filter_file_number);
s_response_fifo.Push(s_xa_filter_channel_number);
SetInterrupt(Interrupt::ACK);
EndCommand();
}
break;
case Command::Sync:
{
Log_DebugPrintf("CDROM sync command");
SendErrorResponse(STAT_ERROR, ERROR_REASON_INVALID_COMMAND);
EndCommand();
}
break;
case Command::VideoCD:
{
Log_DebugPrintf("CDROM VideoCD command");
SendErrorResponse(STAT_ERROR, ERROR_REASON_INVALID_COMMAND);
// According to nocash this doesn't clear the parameter FIFO.
s_command = Command::None;
s_command_event->Deactivate();
UpdateStatusRegister();
}
break;
default:
{
Log_ErrorPrintf("Unknown CDROM command 0x%04X with %u parameters, please report", static_cast<u16>(s_command),
s_param_fifo.GetSize());
SendErrorResponse(STAT_ERROR, ERROR_REASON_INVALID_COMMAND);
EndCommand();
}
break;
}
}
void CDROM::ExecuteTestCommand(u8 subcommand)
{
switch (subcommand)
{
case 0x04: // Reset SCEx counters
{
Log_DebugPrintf("Reset SCEx counters");
s_secondary_status.motor_on = true;
s_response_fifo.Push(s_secondary_status.bits);
SetInterrupt(Interrupt::ACK);
EndCommand();
return;
}
case 0x05: // Read SCEx counters
{
Log_DebugPrintf("Read SCEx counters");
s_response_fifo.Push(s_secondary_status.bits);
s_response_fifo.Push(0); // # of TOC reads?
s_response_fifo.Push(0); // # of SCEx strings received
SetInterrupt(Interrupt::ACK);
EndCommand();
return;
}
case 0x20: // Get CDROM BIOS Date/Version
{
Log_DebugPrintf("Get CDROM BIOS Date/Version");
static constexpr u8 response[] = {0x95, 0x05, 0x16, 0xC1};
s_response_fifo.PushRange(response, countof(response));
SetInterrupt(Interrupt::ACK);
EndCommand();
return;
}
case 0x22:
{
Log_DebugPrintf("Get CDROM region ID string");
switch (System::GetRegion())
{
case ConsoleRegion::NTSC_J:
{
static constexpr u8 response[] = {'f', 'o', 'r', ' ', 'J', 'a', 'p', 'a', 'n'};
s_response_fifo.PushRange(response, countof(response));
}
break;
case ConsoleRegion::PAL:
{
static constexpr u8 response[] = {'f', 'o', 'r', ' ', 'E', 'u', 'r', 'o', 'p', 'e'};
s_response_fifo.PushRange(response, countof(response));
}
break;
case ConsoleRegion::NTSC_U:
default:
{
static constexpr u8 response[] = {'f', 'o', 'r', ' ', 'U', '/', 'C'};
s_response_fifo.PushRange(response, countof(response));
}
break;
}
SetInterrupt(Interrupt::ACK);
EndCommand();
return;
}
default:
{
Log_ErrorPrintf("Unknown test command 0x%02X, %u parameters", subcommand, s_param_fifo.GetSize());
SendErrorResponse(STAT_ERROR, ERROR_REASON_INVALID_COMMAND);
EndCommand();
return;
}
}
}
void CDROM::ExecuteCommandSecondResponse(void*, TickCount ticks, TickCount ticks_late)
{
switch (s_command_second_response)
{
case Command::GetID:
DoIDRead();
break;
case Command::ReadTOC:
case Command::Pause:
case Command::Init:
case Command::MotorOn:
case Command::Stop:
DoStatSecondResponse();
break;
default:
break;
}
s_command_second_response = Command::None;
s_command_second_response_event->Deactivate();
}
void CDROM::QueueCommandSecondResponse(Command command, TickCount ticks)
{
ClearCommandSecondResponse();
s_command_second_response = command;
s_command_second_response_event->Schedule(ticks);
}
void CDROM::ClearCommandSecondResponse()
{
if (s_command_second_response != Command::None)
{
Log_DevPrintf("Cancelling pending command 0x%02X (%s) second response", static_cast<u16>(s_command_second_response),
s_command_info[static_cast<u16>(s_command_second_response)].name);
}
s_command_second_response_event->Deactivate();
s_command_second_response = Command::None;
}
void CDROM::UpdateCommandEvent()
{
// if there's a pending interrupt, we can't execute the command yet
// so deactivate it until the interrupt is acknowledged
if (!HasPendingCommand() || HasPendingInterrupt() || HasPendingAsyncInterrupt())
{
s_command_event->Deactivate();
return;
}
else if (HasPendingCommand())
{
s_command_event->Activate();
}
}
void CDROM::ExecuteDrive(void*, TickCount ticks, TickCount ticks_late)
{
switch (s_drive_state)
{
case DriveState::ShellOpening:
DoShellOpenComplete(ticks_late);
break;
case DriveState::SeekingPhysical:
case DriveState::SeekingLogical:
DoSeekComplete(ticks_late);
break;
case DriveState::SeekingImplicit:
CompleteSeek();
break;
case DriveState::Reading:
case DriveState::Playing:
DoSectorRead();
break;
case DriveState::ChangingSession:
DoChangeSessionComplete();
break;
case DriveState::SpinningUp:
DoSpinUpComplete();
break;
case DriveState::ChangingSpeedOrTOCRead:
DoSpeedChangeOrImplicitTOCReadComplete();
break;
// old states, no longer used, but kept for save state compatibility
case DriveState::UNUSED_ReadingID:
{
ClearDriveState();
DoIDRead();
}
break;
case DriveState::UNUSED_Resetting:
case DriveState::UNUSED_ReadingTOC:
{
ClearDriveState();
DoStatSecondResponse();
}
break;
case DriveState::UNUSED_Pausing:
{
ClearDriveState();
s_secondary_status.ClearActiveBits();
DoStatSecondResponse();
}
break;
case DriveState::UNUSED_Stopping:
{
ClearDriveState();
StopMotor();
DoStatSecondResponse();
}
break;
case DriveState::Idle:
default:
break;
}
}
void CDROM::ClearDriveState()
{
s_drive_state = DriveState::Idle;
s_drive_event->Deactivate();
}
void CDROM::BeginReading(TickCount ticks_late /* = 0 */, bool after_seek /* = false */)
{
ClearSectorBuffers();
if (!after_seek && s_setloc_pending)
{
BeginSeeking(true, true, false);
return;
}
// If we were seeking, we want to start reading from the seek target, not the current sector
// Fixes crash in Disney's The Lion King - Simba's Mighty Adventure.
if (IsSeeking())
{
Log_DevPrintf("Read command while seeking, scheduling read after seek %u -> %u finishes in %d ticks",
s_seek_start_lba, s_seek_end_lba, s_drive_event->GetTicksUntilNextExecution());
// Implicit seeks won't trigger the read, so swap it for a logical.
if (s_drive_state == DriveState::SeekingImplicit)
s_drive_state = DriveState::SeekingLogical;
s_read_after_seek = true;
s_play_after_seek = false;
return;
}
Log_DebugPrintf("Starting reading @ LBA %u", s_current_lba);
const TickCount ticks = GetTicksForRead();
const TickCount first_sector_ticks = ticks + (after_seek ? 0 : GetTicksForSeek(s_current_lba)) - ticks_late;
ClearCommandSecondResponse();
ResetAudioDecoder();
s_drive_state = DriveState::Reading;
s_drive_event->SetInterval(ticks);
s_drive_event->Schedule(first_sector_ticks);
s_current_read_sector_buffer = 0;
s_current_write_sector_buffer = 0;
s_requested_lba = s_current_lba;
m_reader.QueueReadSector(s_requested_lba);
}
void CDROM::BeginPlaying(u8 track, TickCount ticks_late /* = 0 */, bool after_seek /* = false */)
{
Log_DebugPrintf("Starting playing CDDA track %x", track);
s_last_cdda_report_frame_nibble = 0xFF;
s_play_track_number_bcd = track;
s_fast_forward_rate = 0;
// if track zero, start from current position
if (track != 0)
{
// play specific track?
if (track > m_reader.GetMedia()->GetTrackCount())
{
// restart current track
track = Truncate8(m_reader.GetMedia()->GetTrackNumber());
}
s_setloc_position = m_reader.GetMedia()->GetTrackStartMSFPosition(track);
s_setloc_pending = true;
}
if (s_setloc_pending)
{
BeginSeeking(false, false, true);
return;
}
const TickCount ticks = GetTicksForRead();
const TickCount first_sector_ticks = ticks + (after_seek ? 0 : GetTicksForSeek(s_current_lba, true)) - ticks_late;
ClearCommandSecondResponse();
ClearSectorBuffers();
ResetAudioDecoder();
s_drive_state = DriveState::Playing;
s_drive_event->SetInterval(ticks);
s_drive_event->Schedule(first_sector_ticks);
s_current_read_sector_buffer = 0;
s_current_write_sector_buffer = 0;
s_requested_lba = s_current_lba;
m_reader.QueueReadSector(s_requested_lba);
}
void CDROM::BeginSeeking(bool logical, bool read_after_seek, bool play_after_seek)
{
if (!s_setloc_pending)
Log_WarningPrintf("Seeking without setloc set");
s_read_after_seek = read_after_seek;
s_play_after_seek = play_after_seek;
// TODO: Pending should stay set on seek command.
s_setloc_pending = false;
Log_DebugPrintf("Seeking to [%02u:%02u:%02u] (LBA %u) (%s)", s_setloc_position.minute, s_setloc_position.second,
s_setloc_position.frame, s_setloc_position.ToLBA(), logical ? "logical" : "physical");
const CDImage::LBA seek_lba = s_setloc_position.ToLBA();
const TickCount seek_time = GetTicksForSeek(seek_lba, play_after_seek);
ClearCommandSecondResponse();
ResetAudioDecoder();
s_secondary_status.SetSeeking();
s_last_sector_header_valid = false;
s_drive_state = logical ? DriveState::SeekingLogical : DriveState::SeekingPhysical;
s_drive_event->SetIntervalAndSchedule(seek_time);
s_seek_start_lba = s_current_lba;
s_seek_end_lba = seek_lba;
s_requested_lba = seek_lba;
m_reader.QueueReadSector(s_requested_lba);
}
void CDROM::UpdatePositionWhileSeeking()
{
DebugAssert(IsSeeking());
const float completed_frac = 1.0f - (static_cast<float>(s_drive_event->GetTicksUntilNextExecution()) /
static_cast<float>(s_drive_event->GetInterval()));
CDImage::LBA current_lba;
if (s_seek_end_lba > s_seek_start_lba)
{
current_lba =
s_seek_start_lba +
std::max<CDImage::LBA>(
static_cast<CDImage::LBA>(static_cast<float>(s_seek_end_lba - s_seek_start_lba) * completed_frac), 1);
}
else if (s_seek_end_lba < s_seek_start_lba)
{
current_lba =
s_seek_start_lba -
std::max<CDImage::LBA>(
static_cast<CDImage::LBA>(static_cast<float>(s_seek_start_lba - s_seek_end_lba) * completed_frac), 1);
}
else
{
// strange seek...
return;
}
Log_DevPrintf("Update position while seeking from %u to %u - %u (%.2f)", s_seek_start_lba, s_seek_end_lba,
current_lba, completed_frac);
// access the image directly since we want to preserve the cached data for the seek complete
CDImage::SubChannelQ subq;
if (!m_reader.ReadSectorUncached(current_lba, &subq, nullptr))
Log_ErrorPrintf("Failed to read subq for sector %u for physical position", current_lba);
else if (subq.IsCRCValid())
s_last_subq = subq;
s_current_lba = current_lba;
s_physical_lba = current_lba;
s_physical_lba_update_tick = TimingEvents::GetGlobalTickCounter();
s_physical_lba_update_carry = 0;
}
void CDROM::UpdatePhysicalPosition(bool update_logical)
{
const u32 ticks = TimingEvents::GetGlobalTickCounter();
if (IsSeeking() || IsReadingOrPlaying() || !IsMotorOn())
{
// If we're seeking+reading the first sector (no stat bits set), we need to return the set/current lba, not the last
// physical LBA. Failing to do so may result in a track-jumped position getting returned in GetlocP, which causes
// Mad Panic Coaster to go into a seek+play loop.
if ((s_secondary_status.bits & (STAT_READING | STAT_PLAYING_CDDA | STAT_MOTOR_ON)) == STAT_MOTOR_ON &&
s_current_lba != s_physical_lba)
{
Log_WarningPrintf("Jumping to hold position [%u->%u] while %s first sector", s_physical_lba, s_current_lba,
(s_drive_state == DriveState::Reading) ? "reading" : "playing");
SetHoldPosition(s_current_lba, true);
}
// Otherwise, this gets updated by the read event.
return;
}
const u32 ticks_per_read = GetTicksForRead();
const u32 diff = ticks - s_physical_lba_update_tick + s_physical_lba_update_carry;
const u32 sector_diff = diff / ticks_per_read;
const u32 carry = diff % ticks_per_read;
if (sector_diff > 0)
{
CDImage::LBA hold_offset;
CDImage::LBA sectors_per_track;
// hardware tests show that it holds much closer to the target sector in logical mode
if (s_last_sector_header_valid)
{
hold_offset = 2;
sectors_per_track = 4;
}
else
{
hold_offset = 0;
sectors_per_track =
static_cast<CDImage::LBA>(7.0f + 2.811844405f * std::log(static_cast<float>(s_current_lba / 4500u) + 1u));
}
const CDImage::LBA hold_position = s_current_lba + hold_offset;
const CDImage::LBA base =
(hold_position >= (sectors_per_track - 1)) ? (hold_position - (sectors_per_track - 1)) : hold_position;
if (s_physical_lba < base)
s_physical_lba = base;
const CDImage::LBA old_offset = s_physical_lba - base;
const CDImage::LBA new_offset = (old_offset + sector_diff) % sectors_per_track;
const CDImage::LBA new_physical_lba = base + new_offset;
#ifdef _DEBUG
Log_DevPrintf("Tick diff %u, sector diff %u, old pos %s, new pos %s", diff, sector_diff,
LBAToMSFString(s_physical_lba).c_str(), LBAToMSFString(new_physical_lba).c_str());
#endif
if (s_physical_lba != new_physical_lba)
{
s_physical_lba = new_physical_lba;
CDImage::SubChannelQ subq;
CDROMAsyncReader::SectorBuffer raw_sector;
if (!m_reader.ReadSectorUncached(new_physical_lba, &subq, update_logical ? &raw_sector : nullptr))
{
Log_ErrorPrintf("Failed to read subq for sector %u for physical position", new_physical_lba);
}
else
{
if (subq.IsCRCValid())
s_last_subq = subq;
if (update_logical)
ProcessDataSectorHeader(raw_sector.data());
}
s_physical_lba_update_tick = ticks;
s_physical_lba_update_carry = carry;
}
}
}
void CDROM::SetHoldPosition(CDImage::LBA lba, bool update_subq)
{
if (update_subq && s_physical_lba != lba && CanReadMedia())
{
CDImage::SubChannelQ subq;
if (!m_reader.ReadSectorUncached(lba, &subq, nullptr))
Log_ErrorPrintf("Failed to read subq for sector %u for physical position", lba);
else if (subq.IsCRCValid())
s_last_subq = subq;
}
s_current_lba = lba;
s_physical_lba = lba;
s_physical_lba_update_tick = TimingEvents::GetGlobalTickCounter();
s_physical_lba_update_carry = 0;
}
void CDROM::DoShellOpenComplete(TickCount ticks_late)
{
// media is now readable (if any)
ClearDriveState();
if (CanReadMedia())
StartMotor();
}
bool CDROM::CompleteSeek()
{
const bool logical = (s_drive_state == DriveState::SeekingLogical);
ClearDriveState();
bool seek_okay = m_reader.WaitForReadToComplete();
if (seek_okay)
{
const CDImage::SubChannelQ& subq = m_reader.GetSectorSubQ();
if (subq.IsCRCValid())
{
// seek and update sub-q for ReadP command
s_last_subq = subq;
const auto [seek_mm, seek_ss, seek_ff] = CDImage::Position::FromLBA(m_reader.GetLastReadSector()).ToBCD();
seek_okay = (subq.IsCRCValid() && subq.absolute_minute_bcd == seek_mm && subq.absolute_second_bcd == seek_ss &&
subq.absolute_frame_bcd == seek_ff);
if (seek_okay)
{
if (subq.IsData())
{
if (logical)
{
ProcessDataSectorHeader(m_reader.GetSectorBuffer().data());
seek_okay = (s_last_sector_header.minute == seek_mm && s_last_sector_header.second == seek_ss &&
s_last_sector_header.frame == seek_ff);
}
}
else
{
if (logical)
{
Log_WarningPrintf("Logical seek to non-data sector [%02x:%02x:%02x]%s", seek_mm, seek_ss, seek_ff,
s_read_after_seek ? ", reading after seek" : "");
// If CDDA mode isn't enabled and we're reading an audio sector, we need to fail the seek.
// Test cases:
// - Wizard's Harmony does a logical seek to an audio sector, and expects it to succeed.
// - Vib-ribbon starts a read at an audio sector, and expects it to fail.
if (s_read_after_seek)
seek_okay = s_mode.cdda;
}
}
if (subq.track_number_bcd == CDImage::LEAD_OUT_TRACK_NUMBER)
{
Log_WarningPrintf("Invalid seek to lead-out area (LBA %u)", m_reader.GetLastReadSector());
seek_okay = false;
}
}
}
s_current_lba = m_reader.GetLastReadSector();
}
s_physical_lba = s_current_lba;
s_physical_lba_update_tick = TimingEvents::GetGlobalTickCounter();
s_physical_lba_update_carry = 0;
return seek_okay;
}
void CDROM::DoSeekComplete(TickCount ticks_late)
{
const bool logical = (s_drive_state == DriveState::SeekingLogical);
const bool seek_okay = CompleteSeek();
if (seek_okay)
{
// seek complete, transition to play/read if requested
// INT2 is not sent on play/read
if (s_read_after_seek)
{
BeginReading(ticks_late, true);
}
else if (s_play_after_seek)
{
BeginPlaying(0, ticks_late, true);
}
else
{
s_secondary_status.ClearActiveBits();
s_async_response_fifo.Push(s_secondary_status.bits);
SetAsyncInterrupt(Interrupt::Complete);
}
}
else
{
Log_WarningPrintf("%s seek to [%s] failed", logical ? "Logical" : "Physical",
LBAToMSFString(m_reader.GetLastReadSector()).c_str());
s_secondary_status.ClearActiveBits();
SendAsyncErrorResponse(STAT_SEEK_ERROR, 0x04);
s_last_sector_header_valid = false;
}
s_setloc_pending = false;
s_read_after_seek = false;
s_play_after_seek = false;
UpdateStatusRegister();
}
void CDROM::DoStatSecondResponse()
{
// Mainly for Reset/MotorOn.
if (!CanReadMedia())
{
SendAsyncErrorResponse(STAT_ERROR, 0x08);
return;
}
s_async_response_fifo.Clear();
s_async_response_fifo.Push(s_secondary_status.bits);
SetAsyncInterrupt(Interrupt::Complete);
}
void CDROM::DoChangeSessionComplete()
{
Log_DebugPrintf("Changing session complete");
ClearDriveState();
s_secondary_status.ClearActiveBits();
s_secondary_status.motor_on = true;
s_async_response_fifo.Clear();
if (s_async_command_parameter == 0x01)
{
s_async_response_fifo.Push(s_secondary_status.bits);
SetAsyncInterrupt(Interrupt::Complete);
}
else
{
// we don't emulate multisession discs.. for now
SendAsyncErrorResponse(STAT_SEEK_ERROR, 0x40);
}
}
void CDROM::DoSpinUpComplete()
{
Log_DebugPrintf("Spinup complete");
s_drive_state = DriveState::Idle;
s_drive_event->Deactivate();
s_secondary_status.ClearActiveBits();
s_secondary_status.motor_on = true;
}
void CDROM::DoSpeedChangeOrImplicitTOCReadComplete()
{
Log_DebugPrintf("Speed change/implicit TOC read complete");
s_drive_state = DriveState::Idle;
s_drive_event->Deactivate();
}
void CDROM::DoIDRead()
{
Log_DebugPrintf("ID read complete");
s_secondary_status.ClearActiveBits();
s_secondary_status.motor_on = CanReadMedia();
// TODO: Audio CD.
u8 stat_byte = s_secondary_status.bits;
u8 flags_byte = 0;
if (!CanReadMedia())
{
stat_byte |= STAT_ID_ERROR;
flags_byte |= (1 << 6); // Disc Missing
}
else
{
if (IsMediaAudioCD())
{
stat_byte |= STAT_ID_ERROR;
flags_byte |= (1 << 7) | (1 << 4); // Unlicensed + Audio CD
}
else if (!IsMediaPS1Disc() || !DoesMediaRegionMatchConsole())
{
stat_byte |= STAT_ID_ERROR;
flags_byte |= (1 << 7); // Unlicensed
}
}
s_async_response_fifo.Clear();
s_async_response_fifo.Push(stat_byte);
s_async_response_fifo.Push(flags_byte);
s_async_response_fifo.Push(0x20); // TODO: Disc type from TOC
s_async_response_fifo.Push(0x00); // TODO: Session info?
static constexpr u32 REGION_STRING_LENGTH = 4;
static constexpr std::array<std::array<u8, REGION_STRING_LENGTH>, static_cast<size_t>(DiscRegion::Count)>
region_strings = {{{'S', 'C', 'E', 'I'}, {'S', 'C', 'E', 'A'}, {'S', 'C', 'E', 'E'}, {0, 0, 0, 0}, {0, 0, 0, 0}}};
s_async_response_fifo.PushRange(region_strings[static_cast<u8>(s_disc_region)].data(), REGION_STRING_LENGTH);
SetAsyncInterrupt((flags_byte != 0) ? Interrupt::Error : Interrupt::Complete);
}
void CDROM::StopReadingWithDataEnd()
{
ClearAsyncInterrupt();
s_async_response_fifo.Push(s_secondary_status.bits);
SetAsyncInterrupt(Interrupt::DataEnd);
s_secondary_status.ClearActiveBits();
ClearDriveState();
}
void CDROM::StartMotor()
{
if (s_drive_state == DriveState::SpinningUp)
{
Log_DevPrintf("Starting motor - already spinning up");
return;
}
Log_DevPrintf("Starting motor");
s_drive_state = DriveState::SpinningUp;
s_drive_event->Schedule(GetTicksForSpinUp());
}
void CDROM::StopMotor()
{
s_secondary_status.ClearActiveBits();
s_secondary_status.motor_on = false;
ClearDriveState();
SetHoldPosition(0, false);
s_last_sector_header_valid = false; // TODO: correct?
}
void CDROM::DoSectorRead()
{
// TODO: Queue the next read here and swap the buffer.
// TODO: Error handling
if (!m_reader.WaitForReadToComplete())
Panic("Sector read failed");
s_current_lba = m_reader.GetLastReadSector();
s_physical_lba = s_current_lba;
s_physical_lba_update_tick = TimingEvents::GetGlobalTickCounter();
s_physical_lba_update_carry = 0;
s_secondary_status.SetReadingBits(s_drive_state == DriveState::Playing);
const CDImage::SubChannelQ& subq = m_reader.GetSectorSubQ();
const bool subq_valid = subq.IsCRCValid();
if (subq_valid)
{
s_last_subq = subq;
}
else
{
Log_DevPrintf("Sector %u [%s] has invalid subchannel Q", s_current_lba, LBAToMSFString(s_current_lba).c_str());
}
if (subq.track_number_bcd == CDImage::LEAD_OUT_TRACK_NUMBER)
{
Log_DevPrintf("Read reached lead-out area of disc at LBA %u, stopping", m_reader.GetLastReadSector());
StopReadingWithDataEnd();
StopMotor();
return;
}
const bool is_data_sector = subq.IsData();
if (!is_data_sector)
{
if (s_play_track_number_bcd == 0)
{
// track number was not specified, but we've found the track now
s_play_track_number_bcd = subq.track_number_bcd;
Log_DebugPrintf("Setting playing track number to %u", s_play_track_number_bcd);
}
else if (s_mode.auto_pause && subq.track_number_bcd != s_play_track_number_bcd)
{
// we don't want to update the position if the track changes, so we check it before reading the actual sector.
Log_DevPrintf("Auto pause at the start of track %02x (LBA %u)", s_last_subq.track_number_bcd, s_current_lba);
StopReadingWithDataEnd();
return;
}
}
else
{
ProcessDataSectorHeader(m_reader.GetSectorBuffer().data());
}
u32 next_sector = s_current_lba + 1u;
if (is_data_sector && s_drive_state == DriveState::Reading)
{
ProcessDataSector(m_reader.GetSectorBuffer().data(), subq);
}
else if (!is_data_sector &&
(s_drive_state == DriveState::Playing || (s_drive_state == DriveState::Reading && s_mode.cdda)))
{
ProcessCDDASector(m_reader.GetSectorBuffer().data(), subq);
if (s_fast_forward_rate != 0)
next_sector = s_current_lba + SignExtend32(s_fast_forward_rate);
}
else if (s_drive_state != DriveState::Reading && s_drive_state != DriveState::Playing)
{
Panic("Not reading or playing");
}
else
{
Log_WarningPrintf("Skipping sector %u as it is a %s sector and we're not %s", s_current_lba,
is_data_sector ? "data" : "audio", is_data_sector ? "reading" : "playing");
}
s_requested_lba = next_sector;
m_reader.QueueReadSector(s_requested_lba);
}
void CDROM::ProcessDataSectorHeader(const u8* raw_sector)
{
std::memcpy(&s_last_sector_header, &raw_sector[SECTOR_SYNC_SIZE], sizeof(s_last_sector_header));
std::memcpy(&s_last_sector_subheader, &raw_sector[SECTOR_SYNC_SIZE + sizeof(s_last_sector_header)],
sizeof(s_last_sector_subheader));
s_last_sector_header_valid = true;
}
void CDROM::ProcessDataSector(const u8* raw_sector, const CDImage::SubChannelQ& subq)
{
const u32 sb_num = (s_current_write_sector_buffer + 1) % NUM_SECTOR_BUFFERS;
Log_DevPrintf("Read sector %u [%s]: mode %u submode 0x%02X into buffer %u", s_current_lba,
LBAToMSFString(s_current_lba).c_str(), ZeroExtend32(s_last_sector_header.sector_mode),
ZeroExtend32(s_last_sector_subheader.submode.bits), sb_num);
if (s_mode.xa_enable && s_last_sector_header.sector_mode == 2)
{
if (s_last_sector_subheader.submode.realtime && s_last_sector_subheader.submode.audio)
{
ProcessXAADPCMSector(raw_sector, subq);
// Audio+realtime sectors aren't delivered to the CPU.
return;
}
}
// TODO: How does XA relate to this buffering?
SectorBuffer* sb = &s_sector_buffers[sb_num];
if (sb->size > 0)
{
Log_DevPrintf("Sector buffer %u was not read, previous sector dropped",
(s_current_write_sector_buffer - 1) % NUM_SECTOR_BUFFERS);
}
if (s_mode.ignore_bit)
Log_WarningPrintf("SetMode.4 bit set on read of sector %u", s_current_lba);
if (s_mode.read_raw_sector)
{
std::memcpy(sb->data.data(), raw_sector + SECTOR_SYNC_SIZE, RAW_SECTOR_OUTPUT_SIZE);
sb->size = RAW_SECTOR_OUTPUT_SIZE;
}
else
{
// TODO: This should actually depend on the mode...
if (s_last_sector_header.sector_mode != 2)
{
Log_WarningPrintf("Ignoring non-mode2 sector at %u", s_current_lba);
return;
}
std::memcpy(sb->data.data(), raw_sector + CDImage::SECTOR_SYNC_SIZE + 12, DATA_SECTOR_OUTPUT_SIZE);
sb->size = DATA_SECTOR_OUTPUT_SIZE;
}
s_current_write_sector_buffer = sb_num;
// Deliver to CPU
if (HasPendingAsyncInterrupt())
{
Log_WarningPrintf("Data interrupt was not delivered");
ClearAsyncInterrupt();
}
if (HasPendingInterrupt())
{
const u32 sectors_missed = (s_current_write_sector_buffer - s_current_read_sector_buffer) % NUM_SECTOR_BUFFERS;
if (sectors_missed > 1)
Log_WarningPrintf("Interrupt not processed in time, missed %u sectors", sectors_missed - 1);
}
s_async_response_fifo.Push(s_secondary_status.bits);
SetAsyncInterrupt(Interrupt::DataReady);
}
static std::array<std::array<s16, 29>, 7> s_zigzag_table = {
{{0, 0x0, 0x0, 0x0, 0x0, -0x0002, 0x000A, -0x0022, 0x0041, -0x0054,
0x0034, 0x0009, -0x010A, 0x0400, -0x0A78, 0x234C, 0x6794, -0x1780, 0x0BCD, -0x0623,
0x0350, -0x016D, 0x006B, 0x000A, -0x0010, 0x0011, -0x0008, 0x0003, -0x0001},
{0, 0x0, 0x0, -0x0002, 0x0, 0x0003, -0x0013, 0x003C, -0x004B, 0x00A2,
-0x00E3, 0x0132, -0x0043, -0x0267, 0x0C9D, 0x74BB, -0x11B4, 0x09B8, -0x05BF, 0x0372,
-0x01A8, 0x00A6, -0x001B, 0x0005, 0x0006, -0x0008, 0x0003, -0x0001, 0x0},
{0, 0x0, -0x0001, 0x0003, -0x0002, -0x0005, 0x001F, -0x004A, 0x00B3, -0x0192,
0x02B1, -0x039E, 0x04F8, -0x05A6, 0x7939, -0x05A6, 0x04F8, -0x039E, 0x02B1, -0x0192,
0x00B3, -0x004A, 0x001F, -0x0005, -0x0002, 0x0003, -0x0001, 0x0, 0x0},
{0, -0x0001, 0x0003, -0x0008, 0x0006, 0x0005, -0x001B, 0x00A6, -0x01A8, 0x0372,
-0x05BF, 0x09B8, -0x11B4, 0x74BB, 0x0C9D, -0x0267, -0x0043, 0x0132, -0x00E3, 0x00A2,
-0x004B, 0x003C, -0x0013, 0x0003, 0x0, -0x0002, 0x0, 0x0, 0x0},
{-0x0001, 0x0003, -0x0008, 0x0011, -0x0010, 0x000A, 0x006B, -0x016D, 0x0350, -0x0623,
0x0BCD, -0x1780, 0x6794, 0x234C, -0x0A78, 0x0400, -0x010A, 0x0009, 0x0034, -0x0054,
0x0041, -0x0022, 0x000A, -0x0001, 0x0, 0x0001, 0x0, 0x0, 0x0},
{0x0002, -0x0008, 0x0010, -0x0023, 0x002B, 0x001A, -0x00EB, 0x027B, -0x0548, 0x0AFA,
-0x16FA, 0x53E0, 0x3C07, -0x1249, 0x080E, -0x0347, 0x015B, -0x0044, -0x0017, 0x0046,
-0x0023, 0x0011, -0x0005, 0x0, 0x0, 0x0, 0x0, 0x0, 0x0},
{-0x0005, 0x0011, -0x0023, 0x0046, -0x0017, -0x0044, 0x015B, -0x0347, 0x080E, -0x1249,
0x3C07, 0x53E0, -0x16FA, 0x0AFA, -0x0548, 0x027B, -0x00EB, 0x001A, 0x002B, -0x0023,
0x0010, -0x0008, 0x0002, 0x0, 0x0, 0x0, 0x0, 0x0, 0x0}}};
static s16 ZigZagInterpolate(const s16* ringbuf, const s16* table, u8 p)
{
s32 sum = 0;
for (u8 i = 0; i < 29; i++)
sum += (s32(ringbuf[(p - i) & 0x1F]) * s32(table[i])) / 0x8000;
return static_cast<s16>(std::clamp<s32>(sum, -0x8000, 0x7FFF));
}
std::tuple<s16, s16> CDROM::GetAudioFrame()
{
const u32 frame = s_audio_fifo.IsEmpty() ? 0u : s_audio_fifo.Pop();
const s16 left = static_cast<s16>(Truncate16(frame));
const s16 right = static_cast<s16>(Truncate16(frame >> 16));
const s16 left_out = SaturateVolume(ApplyVolume(left, s_cd_audio_volume_matrix[0][0]) +
ApplyVolume(right, s_cd_audio_volume_matrix[1][0]));
const s16 right_out = SaturateVolume(ApplyVolume(left, s_cd_audio_volume_matrix[0][1]) +
ApplyVolume(right, s_cd_audio_volume_matrix[1][1]));
return std::tuple<s16, s16>(left_out, right_out);
}
void CDROM::AddCDAudioFrame(s16 left, s16 right)
{
s_audio_fifo.Push(ZeroExtend32(static_cast<u16>(left)) | (ZeroExtend32(static_cast<u16>(right)) << 16));
}
s32 CDROM::ApplyVolume(s16 sample, u8 volume)
{
return s32(sample) * static_cast<s32>(ZeroExtend32(volume)) >> 7;
}
s16 CDROM::SaturateVolume(s32 volume)
{
return static_cast<s16>((volume < -0x8000) ? -0x8000 : ((volume > 0x7FFF) ? 0x7FFF : volume));
}
template<bool STEREO, bool SAMPLE_RATE>
void CDROM::ResampleXAADPCM(const s16* frames_in, u32 num_frames_in)
{
// Since the disc reads and SPU are running at different speeds, we might be _slightly_ behind, which is fine, since
// the SPU will over-read in the next batch to catch up.
if (s_audio_fifo.GetSize() > AUDIO_FIFO_LOW_WATERMARK)
{
Log_DevPrintf("Dropping %u XA frames because audio FIFO still has %u frames", num_frames_in,
s_audio_fifo.GetSize());
return;
}
s16* left_ringbuf = s_xa_resample_ring_buffer[0].data();
s16* right_ringbuf = s_xa_resample_ring_buffer[1].data();
u8 p = s_xa_resample_p;
u8 sixstep = s_xa_resample_sixstep;
for (u32 in_sample_index = 0; in_sample_index < num_frames_in; in_sample_index++)
{
const s16 left = *(frames_in++);
const s16 right = STEREO ? *(frames_in++) : left;
if constexpr (!STEREO)
{
UNREFERENCED_VARIABLE(right);
}
for (u32 sample_dup = 0; sample_dup < (SAMPLE_RATE ? 2 : 1); sample_dup++)
{
left_ringbuf[p] = left;
if constexpr (STEREO)
right_ringbuf[p] = right;
p = (p + 1) % 32;
sixstep--;
if (sixstep == 0)
{
sixstep = 6;
for (u32 j = 0; j < 7; j++)
{
const s16 left_interp = ZigZagInterpolate(left_ringbuf, s_zigzag_table[j].data(), p);
const s16 right_interp = STEREO ? ZigZagInterpolate(right_ringbuf, s_zigzag_table[j].data(), p) : left_interp;
AddCDAudioFrame(left_interp, right_interp);
}
}
}
}
s_xa_resample_p = p;
s_xa_resample_sixstep = sixstep;
}
void CDROM::ResetCurrentXAFile()
{
s_xa_current_channel_number = 0;
s_xa_current_file_number = 0;
s_xa_current_set = false;
}
void CDROM::ResetAudioDecoder()
{
ResetCurrentXAFile();
s_xa_last_samples.fill(0);
for (u32 i = 0; i < 2; i++)
{
s_xa_resample_ring_buffer[i].fill(0);
s_xa_resample_p = 0;
s_xa_resample_sixstep = 6;
}
s_audio_fifo.Clear();
}
void CDROM::ProcessXAADPCMSector(const u8* raw_sector, const CDImage::SubChannelQ& subq)
{
// Check for automatic ADPCM filter.
if (s_mode.xa_filter && (s_last_sector_subheader.file_number != s_xa_filter_file_number ||
s_last_sector_subheader.channel_number != s_xa_filter_channel_number))
{
Log_DebugPrintf("Skipping sector due to filter mismatch (expected %u/%u got %u/%u)", s_xa_filter_file_number,
s_xa_filter_channel_number, s_last_sector_subheader.file_number,
s_last_sector_subheader.channel_number);
return;
}
// Track the current file being played. If this is not set by the filter, it'll be set by the first file/sector which
// is read. Fixes audio in Tomb Raider III menu.
if (!s_xa_current_set)
{
// Some games (Taxi 2 and Blues Blues) have junk audio sectors with a channel number of 255.
// We need to skip them otherwise it ends up playing the incorrect file.
// TODO: Verify with a hardware test.
if (s_last_sector_subheader.channel_number == 255 && (!s_mode.xa_filter || s_xa_filter_channel_number != 255))
{
Log_WarningPrintf("Skipping XA file with file number %u and channel number %u (submode 0x%02X coding 0x%02X)",
s_last_sector_subheader.file_number, s_last_sector_subheader.channel_number,
s_last_sector_subheader.submode.bits, s_last_sector_subheader.codinginfo.bits);
return;
}
s_xa_current_file_number = s_last_sector_subheader.file_number;
s_xa_current_channel_number = s_last_sector_subheader.channel_number;
s_xa_current_set = true;
}
else if (s_last_sector_subheader.file_number != s_xa_current_file_number ||
s_last_sector_subheader.channel_number != s_xa_current_channel_number)
{
Log_DebugPrintf("Skipping sector due to current file mismatch (expected %u/%u got %u/%u)", s_xa_current_file_number,
s_xa_current_channel_number, s_last_sector_subheader.file_number,
s_last_sector_subheader.channel_number);
return;
}
// Reset current file on EOF, and play the file in the next sector.
if (s_last_sector_subheader.submode.eof)
ResetCurrentXAFile();
std::array<s16, CDXA::XA_ADPCM_SAMPLES_PER_SECTOR_4BIT> sample_buffer;
CDXA::DecodeADPCMSector(raw_sector, sample_buffer.data(), s_xa_last_samples.data());
// Only send to SPU if we're not muted.
if (s_muted || s_adpcm_muted || g_settings.cdrom_mute_cd_audio)
return;
SPU::GeneratePendingSamples();
if (s_last_sector_subheader.codinginfo.IsStereo())
{
const u32 num_samples = s_last_sector_subheader.codinginfo.GetSamplesPerSector() / 2;
if (s_last_sector_subheader.codinginfo.IsHalfSampleRate())
ResampleXAADPCM<true, true>(sample_buffer.data(), num_samples);
else
ResampleXAADPCM<true, false>(sample_buffer.data(), num_samples);
}
else
{
const u32 num_samples = s_last_sector_subheader.codinginfo.GetSamplesPerSector();
if (s_last_sector_subheader.codinginfo.IsHalfSampleRate())
ResampleXAADPCM<false, true>(sample_buffer.data(), num_samples);
else
ResampleXAADPCM<false, false>(sample_buffer.data(), num_samples);
}
}
static s16 GetPeakVolume(const u8* raw_sector, u8 channel)
{
static constexpr u32 NUM_SAMPLES = CDImage::RAW_SECTOR_SIZE / sizeof(s16);
#if defined(CPU_X64)
static_assert(Common::IsAlignedPow2(NUM_SAMPLES, 8));
const u8* current_ptr = raw_sector;
__m128i v_peak = _mm_set1_epi16(0);
for (u32 i = 0; i < NUM_SAMPLES; i += 8)
{
__m128i val = _mm_loadu_si128(reinterpret_cast<const __m128i*>(current_ptr));
v_peak = _mm_max_epi16(val, v_peak);
current_ptr += 16;
}
s16 v_peaks[8];
_mm_store_si128(reinterpret_cast<__m128i*>(v_peaks), v_peak);
if (channel == 0)
return std::max(v_peaks[0], std::max(v_peaks[2], std::max(v_peaks[4], v_peaks[6])));
else
return std::max(v_peaks[1], std::max(v_peaks[3], std::max(v_peaks[5], v_peaks[7])));
#else
const u8* current_ptr = raw_sector + (channel * sizeof(s16));
s16 peak = 0;
for (u32 i = 0; i < NUM_SAMPLES; i += 2)
{
s16 sample;
std::memcpy(&sample, current_ptr, sizeof(sample));
peak = std::max(peak, sample);
current_ptr += sizeof(s16) * 2;
}
return peak;
#endif
}
void CDROM::ProcessCDDASector(const u8* raw_sector, const CDImage::SubChannelQ& subq)
{
// For CDDA sectors, the whole sector contains the audio data.
Log_DevPrintf("Read sector %u as CDDA", s_current_lba);
// The reporting doesn't happen if we're reading with the CDDA mode bit set.
if (s_drive_state == DriveState::Playing && s_mode.report_audio)
{
const u8 frame_nibble = subq.absolute_frame_bcd >> 4;
if (s_last_cdda_report_frame_nibble != frame_nibble)
{
s_last_cdda_report_frame_nibble = frame_nibble;
ClearAsyncInterrupt();
s_async_response_fifo.Push(s_secondary_status.bits);
s_async_response_fifo.Push(subq.track_number_bcd);
s_async_response_fifo.Push(subq.index_number_bcd);
if (subq.absolute_frame_bcd & 0x10)
{
s_async_response_fifo.Push(subq.relative_minute_bcd);
s_async_response_fifo.Push(0x80 | subq.relative_second_bcd);
s_async_response_fifo.Push(subq.relative_frame_bcd);
}
else
{
s_async_response_fifo.Push(subq.absolute_minute_bcd);
s_async_response_fifo.Push(subq.absolute_second_bcd);
s_async_response_fifo.Push(subq.absolute_frame_bcd);
}
const u8 channel = subq.absolute_second_bcd & 1u;
const s16 peak_volume = std::min<s16>(GetPeakVolume(raw_sector, channel), 32767);
const u16 peak_value = (ZeroExtend16(channel) << 15) | peak_volume;
s_async_response_fifo.Push(Truncate8(peak_value)); // peak low
s_async_response_fifo.Push(Truncate8(peak_value >> 8)); // peak high
SetAsyncInterrupt(Interrupt::DataReady);
Log_DevPrintf("CDDA report at track[%02x] index[%02x] rel[%02x:%02x:%02x] abs[%02x:%02x:%02x] peak[%u:%d]",
subq.track_number_bcd, subq.index_number_bcd, subq.relative_minute_bcd, subq.relative_second_bcd,
subq.relative_frame_bcd, subq.absolute_minute_bcd, subq.absolute_second_bcd,
subq.absolute_frame_bcd, channel, peak_volume);
}
}
// Apply volume when pushing sectors to SPU.
if (s_muted || g_settings.cdrom_mute_cd_audio)
return;
SPU::GeneratePendingSamples();
constexpr bool is_stereo = true;
constexpr u32 num_samples = CDImage::RAW_SECTOR_SIZE / sizeof(s16) / (is_stereo ? 2 : 1);
const u32 remaining_space = s_audio_fifo.GetSpace();
if (remaining_space < num_samples)
{
Log_WarningPrintf("Dropping %u frames from audio FIFO", num_samples - remaining_space);
s_audio_fifo.Remove(num_samples - remaining_space);
}
const u8* sector_ptr = raw_sector;
for (u32 i = 0; i < num_samples; i++)
{
s16 samp_left, samp_right;
std::memcpy(&samp_left, sector_ptr, sizeof(samp_left));
std::memcpy(&samp_right, sector_ptr + sizeof(s16), sizeof(samp_right));
sector_ptr += sizeof(s16) * 2;
AddCDAudioFrame(samp_left, samp_right);
}
}
void CDROM::LoadDataFIFO()
{
if (!s_data_fifo.IsEmpty())
{
Log_DevPrintf("Load data fifo when not empty");
return;
}
// any data to load?
SectorBuffer& sb = s_sector_buffers[s_current_read_sector_buffer];
if (sb.size == 0)
{
Log_WarningPrintf("Attempting to load empty sector buffer");
s_data_fifo.PushRange(sb.data.data(), RAW_SECTOR_OUTPUT_SIZE);
}
else
{
s_data_fifo.PushRange(sb.data.data(), sb.size);
sb.size = 0;
}
Log_DebugPrintf("Loaded %u bytes to data FIFO from buffer %u", s_data_fifo.GetSize(), s_current_read_sector_buffer);
SectorBuffer& next_sb = s_sector_buffers[s_current_write_sector_buffer];
if (next_sb.size > 0)
{
Log_DevPrintf("Sending additional INT1 for missed sector in buffer %u", s_current_write_sector_buffer);
s_async_response_fifo.Push(s_secondary_status.bits);
SetAsyncInterrupt(Interrupt::DataReady);
}
}
void CDROM::ClearSectorBuffers()
{
for (u32 i = 0; i < NUM_SECTOR_BUFFERS; i++)
s_sector_buffers[i].size = 0;
}
void CDROM::DrawDebugWindow()
{
static const ImVec4 active_color{1.0f, 1.0f, 1.0f, 1.0f};
static const ImVec4 inactive_color{0.4f, 0.4f, 0.4f, 1.0f};
const float framebuffer_scale = Host::GetOSDScale();
ImGui::SetNextWindowSize(ImVec2(800.0f * framebuffer_scale, 560.0f * framebuffer_scale), ImGuiCond_FirstUseEver);
if (!ImGui::Begin("CDROM State", nullptr))
{
ImGui::End();
return;
}
// draw voice states
if (ImGui::CollapsingHeader("Media", ImGuiTreeNodeFlags_DefaultOpen))
{
if (m_reader.HasMedia())
{
const CDImage* media = m_reader.GetMedia();
const CDImage::Position disc_position = CDImage::Position::FromLBA(s_current_lba);
if (media->HasSubImages())
{
ImGui::Text("Filename: %s [Subimage %u of %u] [%u buffered sectors]", media->GetFileName().c_str(),
media->GetCurrentSubImage() + 1u, media->GetSubImageCount(), m_reader.GetBufferedSectorCount());
}
else
{
ImGui::Text("Filename: %s [%u buffered sectors]", media->GetFileName().c_str(),
m_reader.GetBufferedSectorCount());
}
ImGui::Text("Disc Position: MSF[%02u:%02u:%02u] LBA[%u]", disc_position.minute, disc_position.second,
disc_position.frame, disc_position.ToLBA());
if (media->GetTrackNumber() > media->GetTrackCount())
{
ImGui::Text("Track Position: Lead-out");
}
else
{
const CDImage::Position track_position = CDImage::Position::FromLBA(
s_current_lba - media->GetTrackStartPosition(static_cast<u8>(media->GetTrackNumber())));
ImGui::Text("Track Position: Number[%u] MSF[%02u:%02u:%02u] LBA[%u]", media->GetTrackNumber(),
track_position.minute, track_position.second, track_position.frame, track_position.ToLBA());
}
ImGui::Text("Last Sector: %02X:%02X:%02X (Mode %u)", s_last_sector_header.minute, s_last_sector_header.second,
s_last_sector_header.frame, s_last_sector_header.sector_mode);
}
else
{
ImGui::Text("No media inserted.");
}
}
if (ImGui::CollapsingHeader("Status/Mode", ImGuiTreeNodeFlags_DefaultOpen))
{
ImGui::Columns(3);
ImGui::Text("Status");
ImGui::NextColumn();
ImGui::Text("Secondary Status");
ImGui::NextColumn();
ImGui::Text("Mode Status");
ImGui::NextColumn();
ImGui::TextColored(s_status.ADPBUSY ? active_color : inactive_color, "ADPBUSY: %s",
s_status.ADPBUSY ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_secondary_status.error ? active_color : inactive_color, "Error: %s",
s_secondary_status.error ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_mode.cdda ? active_color : inactive_color, "CDDA: %s", s_mode.cdda ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_status.PRMEMPTY ? active_color : inactive_color, "PRMEMPTY: %s",
s_status.PRMEMPTY ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_secondary_status.motor_on ? active_color : inactive_color, "Motor On: %s",
s_secondary_status.motor_on ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_mode.auto_pause ? active_color : inactive_color, "Auto Pause: %s",
s_mode.auto_pause ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_status.PRMWRDY ? active_color : inactive_color, "PRMWRDY: %s",
s_status.PRMWRDY ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_secondary_status.seek_error ? active_color : inactive_color, "Seek Error: %s",
s_secondary_status.seek_error ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_mode.report_audio ? active_color : inactive_color, "Report Audio: %s",
s_mode.report_audio ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_status.RSLRRDY ? active_color : inactive_color, "RSLRRDY: %s",
s_status.RSLRRDY ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_secondary_status.id_error ? active_color : inactive_color, "ID Error: %s",
s_secondary_status.id_error ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_mode.xa_filter ? active_color : inactive_color, "XA Filter: %s (File %u Channel %u)",
s_mode.xa_filter ? "Yes" : "No", s_xa_filter_file_number, s_xa_filter_channel_number);
ImGui::NextColumn();
ImGui::TextColored(s_status.DRQSTS ? active_color : inactive_color, "DRQSTS: %s", s_status.DRQSTS ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_secondary_status.shell_open ? active_color : inactive_color, "Shell Open: %s",
s_secondary_status.shell_open ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_mode.ignore_bit ? active_color : inactive_color, "Ignore Bit: %s",
s_mode.ignore_bit ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_status.BUSYSTS ? active_color : inactive_color, "BUSYSTS: %s",
s_status.BUSYSTS ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_secondary_status.reading ? active_color : inactive_color, "Reading: %s",
s_secondary_status.reading ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_mode.read_raw_sector ? active_color : inactive_color, "Read Raw Sectors: %s",
s_mode.read_raw_sector ? "Yes" : "No");
ImGui::NextColumn();
ImGui::NextColumn();
ImGui::TextColored(s_secondary_status.seeking ? active_color : inactive_color, "Seeking: %s",
s_secondary_status.seeking ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_mode.xa_enable ? active_color : inactive_color, "XA Enable: %s",
s_mode.xa_enable ? "Yes" : "No");
ImGui::NextColumn();
ImGui::NextColumn();
ImGui::TextColored(s_secondary_status.playing_cdda ? active_color : inactive_color, "Playing CDDA: %s",
s_secondary_status.playing_cdda ? "Yes" : "No");
ImGui::NextColumn();
ImGui::TextColored(s_mode.double_speed ? active_color : inactive_color, "Double Speed: %s",
s_mode.double_speed ? "Yes" : "No");
ImGui::NextColumn();
ImGui::Columns(1);
ImGui::NewLine();
if (HasPendingCommand())
{
ImGui::TextColored(active_color, "Command: %s (0x%02X) (%d ticks remaining)",
s_command_info[static_cast<u8>(s_command)].name, static_cast<u8>(s_command),
s_command_event->IsActive() ? s_command_event->GetTicksUntilNextExecution() : 0);
}
else
{
ImGui::TextColored(inactive_color, "Command: None");
}
if (IsDriveIdle())
{
ImGui::TextColored(inactive_color, "Drive: Idle");
}
else
{
ImGui::TextColored(active_color, "Drive: %s (%d ticks remaining)",
s_drive_state_names[static_cast<u8>(s_drive_state)],
s_drive_event->IsActive() ? s_drive_event->GetTicksUntilNextExecution() : 0);
}
ImGui::Text("Interrupt Enable Register: 0x%02X", s_interrupt_enable_register);
ImGui::Text("Interrupt Flag Register: 0x%02X", s_interrupt_flag_register);
if (HasPendingAsyncInterrupt())
{
ImGui::SameLine();
ImGui::TextColored(inactive_color, " (0x%02X pending)", s_pending_async_interrupt);
}
}
if (ImGui::CollapsingHeader("CD Audio", ImGuiTreeNodeFlags_DefaultOpen))
{
if (s_drive_state == DriveState::Reading && s_mode.xa_enable)
{
ImGui::TextColored(active_color, "Playing: XA-ADPCM (File %u / Channel %u)", s_xa_current_file_number,
s_xa_current_channel_number);
}
else if (s_drive_state == DriveState::Playing)
{
ImGui::TextColored(active_color, "Playing: CDDA (Track %x)", s_last_subq.track_number_bcd);
}
else
{
ImGui::TextColored(inactive_color, "Playing: Inactive");
}
ImGui::TextColored(s_muted ? inactive_color : active_color, "Muted: %s", s_muted ? "Yes" : "No");
ImGui::Text("Left Output: Left Channel=%02X (%u%%), Right Channel=%02X (%u%%)", s_cd_audio_volume_matrix[0][0],
ZeroExtend32(s_cd_audio_volume_matrix[0][0]) * 100 / 0x80, s_cd_audio_volume_matrix[1][0],
ZeroExtend32(s_cd_audio_volume_matrix[1][0]) * 100 / 0x80);
ImGui::Text("Right Output: Left Channel=%02X (%u%%), Right Channel=%02X (%u%%)", s_cd_audio_volume_matrix[0][1],
ZeroExtend32(s_cd_audio_volume_matrix[0][1]) * 100 / 0x80, s_cd_audio_volume_matrix[1][1],
ZeroExtend32(s_cd_audio_volume_matrix[1][1]) * 100 / 0x80);
ImGui::Text("Audio FIFO Size: %u frames", s_audio_fifo.GetSize());
}
ImGui::End();
}