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akiko.cpp
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akiko.cpp
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/*
* UAE - The Un*x Amiga Emulator
*
* CD32 Akiko emulation
*
* - C2P
* - NVRAM
* - CDROM
*
* Copyright 2001-2016 Toni Wilen
*
*/
#define EEPROM_DEBUG 0
/*
B80000-B80003: $C0CACAFE (Read-only identifier)
B80004.L: INTREQ (RO)
B80008.L: INTENA (R/W)
31 $80000000 = Subcode interrupt (One subcode buffer filled and B0018.B has changed)
30 $40000000 = Drive has received all command bytes and executed the command (PIO only)
29 $20000000 = Drive has status data pending (PIO only)
28 $10000000 = Drive command DMA transmit complete (DMA only)
27 $08000000 = Drive status DMA receive complete (DMA only)
26 $04000000 = Drive data DMA complete
25 $02000000 = DMA overflow (lost data)?
INTREQ is read-only, each interrupt bit has different clearing method (see below).
B80010.L: DMA data base address (R/W. Must be 64k aligned)
B80014.L: Command/Status/Subcode DMA base. (R/W. Must be 1024 byte aligned)
Base + 0x000: 256 byte circular command DMA buffer. (Memory to drive)
Base + 0x100: Subcode DMA buffer (Doublebuffered, 2x128 byte buffers)
Base + 0x200: 256 byte circular status DMA buffer. (Drive to memory)
B00018.B READ = Subcode DMA offset (ROM only checks if non-zero: second buffer in use)
B00018.B WRITE = Clear subcode interrupt (bit 31)
B0001D.B READ = Transmit DMA circular buffer current position.
B0001D.B WRITE = Transmit DMA circular buffer end position.
If written value is different than current: transmit DMA starts and sends command bytes to drive until value matches end position.
Clears also transmit interrupt (bit 28)
B0001E.B READ = Receive DMA circular buffer current position.
B0001F.B WRITE = Receive DMA circular buffer end position.
If written value is different than current: receive DMA fills DMA buffer if drive has response data remaining, until value matches end position.
Clears also Receive interrupt (bit 27)
B80020.W WRITE = DMA transfer block enable
Each bit marks position in DMA data address.
Bit 0 = DMA base address + 0
Bit 1 = DMA base address + 0x1000
..
Bit 14 = DMA base address + 0xe000
Bit 15 = DMA base address + 0xf000
When writing, if bit is one, matching register bit gets set, if bit is zero, nothing happens, it is not possible to clear already set bits.
All one bit blocks (CD sectors) are transferred one by one. Bit 15 is always checked and processed first, then 14 and so on..
Interrupt is generated after each transferred block and matching register bit is cleared.
Writing to this register also clears INTREQ bit 26. Writing zero will only clear interrupt.
If CONFIG data transfer DMA enable is not active: register gets cleared and writes are ignored.
Structure of each block:
0-2: zeroed
3: low 5 bits of sector number
4 to 2352: 2348 bytes raw sector data (with first 4 bytes skipped)
0xc00: 146 bytes of CD error correction data?
The rest is unused(?).
B80020.W READ = Read current DMA transfer status.
B80024.L: CONFIG (R/W)
31 $80000000 = Subcode DMA enable
30 $40000000 = Command write (to CD) DMA enable
29 $20000000 = Status read (from CD) DMA enable
28 $10000000 = Memory access mode?
27 $08000000 = Data transfer DMA enable
26 $04000000 = CD interface enable?
25 $02000000 = CD data mode?
24 $01000000 = CD data mode?
23 $00800000 = Akiko internal CIA faked vsync rate (0=50Hz,1=60Hz)
00-22 = unused
B80028.B WRITE = PIO write (If CONFIG bit 30 off). Clears also interrupt bit 30.
B80028.B READ = PIO read (If CONFIG bit 29 off). Clears also interrupt bit 29 if no data available anymore.
B80030.B NVRAM I2C IO. Bit 7 = SCL, bit 6 = SDA
B80032.B NVRAM I2C DIRECTION. Bit 7 = SCL direction, bit 6 = SDA direction)
B80038.L C2P
Commands:
1 = STOP
Size: 1 byte
Returns status response
2 = PAUSE
Size: 1 byte
Returns status response
3 = UNPAUSE
Size: 1 byte
Returns status response
4 = PLAY/READ
Size: 12 bytes
Response: 2 bytes
5 = LED (2 bytes)
Size: 2 bytes. Bit 7 set in second byte = response wanted.
Response: no response or 2 bytes. Second byte non-zero: led is currently lit.
6 = SUBCODE
Size: 1 byte
Response: 15 bytes
7 = INFO
Size: 1 byte
Response: 20 bytes (status and firmware version)
Common status response: 2 bytes
Status second byte bit 7 = Error, bit 3 = Playing, bit 0 = Door closed.
First byte of command is combined 4 bit counter and command code.
Command response's first byte is same as command.
Counter byte can be used to match command with response.
Command and response bytes have checksum byte appended.
*/
#include "sysconfig.h"
#include "sysdeps.h"
#include "options.h"
#include "memory.h"
#include "events.h"
#include "savestate.h"
#include "blkdev.h"
#include "zfile.h"
#include "threaddep/thread.h"
#include "akiko.h"
#include "gui.h"
#include "crc32.h"
#include "uae.h"
#include "custom.h"
#include "newcpu.h"
#include "flashrom.h"
#include "debug.h"
#include "rommgr.h"
#include "devices.h"
#define AKIKO_DEBUG_IO 1
#define AKIKO_DEBUG_IO_CMD 1
#define AKIKO_DEBUG_IRQ 0
int log_cd32 = 0;
// 43 48 49 4E 4F 4E 20 20 4F 2D 36 35 38 2D 32 20 32 34
#define FIRMWAREVERSION "CHINON O-658-2 24"
static void irq (void)
{
safe_interrupt_set(IRQ_SOURCE_CD32CDTV, 0, false);
}
/*
* CD32 1Kb NVRAM (EEPROM) emulation
*
* NVRAM chip is 24C08 CMOS EEPROM (1024x8 bits = 1Kb)
* Chip interface is I2C (2 wire serial)
* Akiko addresses used:
* 0xb80030: bit 7 = SCL (clock), 6 = SDA (data)
* 0xb80032: 0xb80030 data direction register (0 = input, 1 = output)
*
*/
static uae_u8 *cd32_nvram;
static int cd32_nvram_size;
static void *cd32_eeprom;
static uae_u8 cd32_i2c_direction;
static bool cd32_i2c_data_scl, cd32_i2c_data_sda;
struct zfile *cd32_flashfile;
extern uae_u8 *cubo_nvram;
static void nvram_read (void)
{
cubo_nvram = NULL;
zfile_fclose(cd32_flashfile);
cd32_flashfile = NULL;
eeprom_free(cd32_eeprom);
cd32_eeprom = NULL;
cd32_i2c_data_scl = cd32_i2c_data_sda = true;
cd32_i2c_direction = 0;
if (!currprefs.cs_cd32nvram)
return;
int maxlen = currprefs.cs_cd32nvram_size;
if (is_board_enabled(&currprefs, ROMTYPE_CUBO, 0))
maxlen += 2048 + 16;
if (!cd32_nvram || cd32_nvram_size != maxlen) {
xfree(cd32_nvram);
cd32_nvram = xmalloc(uae_u8, maxlen);
}
memset(cd32_nvram, 0, maxlen);
if (is_board_enabled(&currprefs, ROMTYPE_CUBO, 0)) {
cubo_nvram = cd32_nvram + currprefs.cs_cd32nvram_size;
}
TCHAR path[MAX_DPATH];
cfgfile_resolve_path_out_load(currprefs.flashfile, path, MAX_DPATH, PATH_ROM);
cd32_flashfile = zfile_fopen (path, _T("rb+"), ZFD_NORMAL);
if (!cd32_flashfile)
cd32_flashfile = zfile_fopen (path, _T("wb"), 0);
if (cd32_flashfile) {
size_t size = zfile_fread(cd32_nvram, 1, currprefs.cs_cd32nvram_size, cd32_flashfile);
if (size == currprefs.cs_cd32nvram_size && maxlen > currprefs.cs_cd32nvram_size)
size += zfile_fread(cubo_nvram, 1, maxlen - currprefs.cs_cd32nvram_size, cd32_flashfile);
if (size < maxlen)
zfile_fwrite(cd32_nvram + size, 1, maxlen - size, cd32_flashfile);
}
cd32_eeprom = eeprom_new(cd32_nvram, currprefs.cs_cd32nvram_size, cd32_flashfile);
}
static void akiko_nvram_write (int offset, uae_u32 v)
{
switch (offset)
{
case 0:
{
#if EEPROM_DEBUG
uae_u8 o = (cd32_i2c_data_scl ? 0x80 : 0x00) | (cd32_i2c_data_sda ? 0x40 : 0x00);
#endif
if (cd32_i2c_direction & 0x80)
cd32_i2c_data_scl = (v & 0x80) != 0;
else
cd32_i2c_data_scl = true;
eeprom_i2c_set(cd32_eeprom, BITBANG_I2C_SCL, cd32_i2c_data_scl);
if (cd32_i2c_direction & 0x40)
cd32_i2c_data_sda = (v & 0x40) != 0;
else
cd32_i2c_data_sda = true;
eeprom_i2c_set(cd32_eeprom, BITBANG_I2C_SDA, cd32_i2c_data_sda);
#if EEPROM_DEBUG
uae_u8 n = (cd32_i2c_data_scl ? 0x80 : 0x00) | (cd32_i2c_data_sda ? 0x40 : 0x00);
write_log(_T("Data write: %02x->%02x (%02x)\n"), o, v, n);
#endif
break;
}
case 2:
{
#if EEPROM_DEBUG
if (cd32_i2c_direction != v) {
write_log(_T("Direction write: %02x->%02x\n"), cd32_i2c_direction, v);
}
#endif
cd32_i2c_direction = v;
break;
}
}
}
static uae_u32 akiko_nvram_read (int offset)
{
uae_u32 v = 0;
switch (offset)
{
case 0:
v |= eeprom_i2c_set(cd32_eeprom, BITBANG_I2C_SCL, cd32_i2c_data_scl) ? 0x80 : 0x00;
v |= eeprom_i2c_set(cd32_eeprom, BITBANG_I2C_SDA, cd32_i2c_data_sda) ? 0x40 : 0x00;
#if EEPROM_DEBUG
write_log(_T("Data read: %02x\n"), v);
#endif
break;
case 2:
v = cd32_i2c_direction;
#if EEPROM_DEBUG
write_log(_T("Direction read: %02x\n"), v);
#endif
break;
}
return v;
}
/* CD32 Chunky to Planar hardware emulation
* Akiko addresses used:
* 0xb80038-0xb8003b
*/
static uae_u32 akiko_buffer[8];
static int akiko_read_offset, akiko_write_offset;
static uae_u32 akiko_result[8];
#if 0
static void akiko_c2p_do (void)
{
int i;
for (i = 0; i < 8; i++)
akiko_result[i] = 0;
/* FIXME: better c2p algoritm than this piece of crap.... */
for (i = 0; i < 8 * 32; i++) {
if (akiko_buffer[7 - (i >> 5)] & (1 << (i & 31)))
akiko_result[i & 7] |= 1 << (i >> 3);
}
}
#else
/* Optimised Chunky-to-Planar algorithm by Mequa */
static uae_u32 akiko_precalc_shift[32];
static uae_u32 akiko_precalc_bytenum[32][8];
static void akiko_c2p_precalculate(void)
{
uae_u32 i, j;
for (i = 0; i < 32; i++) {
akiko_precalc_shift[i] = 1 << i;
for (j = 0; j < 8; j++) {
akiko_precalc_bytenum[i][j] = (i >> 3) + ((7 - j) << 2);
}
}
}
static void akiko_c2p_do(void)
{
int i;
for (i = 0; i < 8; i++) {
akiko_result[i] = (((akiko_buffer[0] & akiko_precalc_shift[i]) != 0) << (akiko_precalc_bytenum[i][0]) )
| (((akiko_buffer[1] & akiko_precalc_shift[i]) != 0) << (akiko_precalc_bytenum[i][1]) )
| (((akiko_buffer[2] & akiko_precalc_shift[i]) != 0) << (akiko_precalc_bytenum[i][2]) )
| (((akiko_buffer[3] & akiko_precalc_shift[i]) != 0) << (akiko_precalc_bytenum[i][3]) )
| (((akiko_buffer[4] & akiko_precalc_shift[i]) != 0) << (akiko_precalc_bytenum[i][4]) )
| (((akiko_buffer[5] & akiko_precalc_shift[i]) != 0) << (akiko_precalc_bytenum[i][5]) )
| (((akiko_buffer[6] & akiko_precalc_shift[i]) != 0) << (akiko_precalc_bytenum[i][6]) )
| (((akiko_buffer[7] & akiko_precalc_shift[i]) != 0) << (akiko_precalc_bytenum[i][7]) )
| (((akiko_buffer[0] & akiko_precalc_shift[i+8]) != 0) << (akiko_precalc_bytenum[i+8][0]) )
| (((akiko_buffer[1] & akiko_precalc_shift[i+8]) != 0) << (akiko_precalc_bytenum[i+8][1]) )
| (((akiko_buffer[2] & akiko_precalc_shift[i+8]) != 0) << (akiko_precalc_bytenum[i+8][2]) )
| (((akiko_buffer[3] & akiko_precalc_shift[i+8]) != 0) << (akiko_precalc_bytenum[i+8][3]) )
| (((akiko_buffer[4] & akiko_precalc_shift[i+8]) != 0) << (akiko_precalc_bytenum[i+8][4]) )
| (((akiko_buffer[5] & akiko_precalc_shift[i+8]) != 0) << (akiko_precalc_bytenum[i+8][5]) )
| (((akiko_buffer[6] & akiko_precalc_shift[i+8]) != 0) << (akiko_precalc_bytenum[i+8][6]) )
| (((akiko_buffer[7] & akiko_precalc_shift[i+8]) != 0) << (akiko_precalc_bytenum[i+8][7]) )
| (((akiko_buffer[0] & akiko_precalc_shift[i+16]) != 0) << (akiko_precalc_bytenum[i+16][0]))
| (((akiko_buffer[1] & akiko_precalc_shift[i+16]) != 0) << (akiko_precalc_bytenum[i+16][1]))
| (((akiko_buffer[2] & akiko_precalc_shift[i+16]) != 0) << (akiko_precalc_bytenum[i+16][2]))
| (((akiko_buffer[3] & akiko_precalc_shift[i+16]) != 0) << (akiko_precalc_bytenum[i+16][3]))
| (((akiko_buffer[4] & akiko_precalc_shift[i+16]) != 0) << (akiko_precalc_bytenum[i+16][4]))
| (((akiko_buffer[5] & akiko_precalc_shift[i+16]) != 0) << (akiko_precalc_bytenum[i+16][5]))
| (((akiko_buffer[6] & akiko_precalc_shift[i+16]) != 0) << (akiko_precalc_bytenum[i+16][6]))
| (((akiko_buffer[7] & akiko_precalc_shift[i+16]) != 0) << (akiko_precalc_bytenum[i+16][7]))
| (((akiko_buffer[0] & akiko_precalc_shift[i+24]) != 0) << (akiko_precalc_bytenum[i+24][0]))
| (((akiko_buffer[1] & akiko_precalc_shift[i+24]) != 0) << (akiko_precalc_bytenum[i+24][1]))
| (((akiko_buffer[2] & akiko_precalc_shift[i+24]) != 0) << (akiko_precalc_bytenum[i+24][2]))
| (((akiko_buffer[3] & akiko_precalc_shift[i+24]) != 0) << (akiko_precalc_bytenum[i+24][3]))
| (((akiko_buffer[4] & akiko_precalc_shift[i+24]) != 0) << (akiko_precalc_bytenum[i+24][4]))
| (((akiko_buffer[5] & akiko_precalc_shift[i+24]) != 0) << (akiko_precalc_bytenum[i+24][5]))
| (((akiko_buffer[6] & akiko_precalc_shift[i+24]) != 0) << (akiko_precalc_bytenum[i+24][6]))
| (((akiko_buffer[7] & akiko_precalc_shift[i+24]) != 0) << (akiko_precalc_bytenum[i+24][7]));
}
}
#endif
static void akiko_c2p_write(int offset, uae_u32 v)
{
if (offset == 3)
akiko_buffer[akiko_write_offset] = 0;
akiko_buffer[akiko_write_offset] |= v << ( 8 * (3 - offset));
if (offset == 0) {
akiko_write_offset++;
akiko_write_offset &= 7;
}
akiko_read_offset = -1;
}
static uae_u32 akiko_c2p_read(int offset)
{
uae_u32 v;
if (akiko_read_offset < 0) {
akiko_c2p_do();
akiko_read_offset = 0;
}
akiko_write_offset = 0;
v = akiko_result[akiko_read_offset];
return v >> (8 * (3 - offset));
}
/* CD32 CDROM hardware emulation
* Akiko addresses used:
* 0xb80004-0xb80028
*/
#define CDINTERRUPT_SUBCODE 0x80000000
#define CDINTERRUPT_DRIVEXMIT 0x40000000 /* not used by ROM. PIO mode. */
#define CDINTERRUPT_DRIVERECV 0x20000000 /* not used by ROM. PIO mode. */
#define CDINTERRUPT_RXDMADONE 0x10000000
#define CDINTERRUPT_TXDMADONE 0x08000000
#define CDINTERRUPT_PBX 0x04000000
#define CDINTERRUPT_OVERFLOW 0x02000000
#define CDFLAG_SUBCODE 0x80000000 // 31
#define CDFLAG_TXD 0x40000000 // 30
#define CDFLAG_RXD 0x20000000 // 29
#define CDFLAG_CAS 0x10000000 // 28
#define CDFLAG_PBX 0x08000000 // 27
#define CDFLAG_ENABLE 0x04000000 // 26
#define CDFLAG_RAW 0x02000000 // 25
#define CDFLAG_MSB 0x01000000 // 24
#define CDFLAG_NTSC 0x00800000 // 23
#define CDS_ERROR 0x80
#define CDS_PLAYING 0x08
#define CDS_PLAYEND 0x00
#define CH_ERR_BADCOMMAND 0x80 // %10000000
#define CH_ERR_CHECKSUM 0x88 // %10001000
#define CH_ERR_DRAWERSTUCK 0x90 // %10010000
#define CH_ERR_DISKUNREADABLE 0x98 // %10011000
#define CH_ERR_INVALIDADDRESS 0xa0 // %10100000
#define CH_ERR_WRONGDATA 0xa8 // %10101000
#define CH_ERR_FOCUSERROR 0xc8 // %11001000
#define CH_ERR_SPINDLEERROR 0xd0 // %11010000
#define CH_ERR_TRACKINGERROR 0xd8 // %11011000
#define CH_ERR_SLEDERROR 0xe0 // %11100000
#define CH_ERR_TRACKJUMP 0xe8 // %11101000
#define CH_ERR_ABNORMALSEEK 0xf0 // %11110000
#define CH_ERR_NODISK 0xf8 // %11111000
static int subcodecounter;
#define MAX_SUBCODEBUFFER 36
static volatile int subcodebufferoffset, subcodebufferoffsetw;
static uae_u8 subcodebufferinuse[MAX_SUBCODEBUFFER];
static uae_u8 subcodebuffer[MAX_SUBCODEBUFFER * SUB_CHANNEL_SIZE];
static uae_u32 cdrom_intreq, cdrom_intena;
static uae_u8 cdrom_subcodeoffset;
static uae_u32 cdrom_addressdata, cdrom_addressmisc;
static uae_u32 subcode_address, cdrx_address, cdtx_address;
static uae_u32 cdrom_flags;
static uae_u32 cdrom_pbx;
static uae_u8 cdcomtxinx; /* 0x19 */
static uae_u8 cdcomrxinx; /* 0x1a */
static uae_u8 cdcomtxcmp; /* 0x1d */
static uae_u8 cdcomrxcmp; /* 0x1f */
static uae_u8 cdrom_result_buffer[32];
static uae_u8 cdrom_command_buffer[32];
static uae_u8 cdrom_command;
static uae_u8 cdrom_last_rx;
static int cdrom_toc_counter;
static uae_u32 cdrom_toc_crc;
static uae_u8 cdrom_toc_buffer[MAX_TOC_ENTRIES * 13];
static struct cd_toc_head cdrom_toc_cd_buffer;
static uae_u8 qcode_buf[SUBQ_SIZE];
static int qcode_valid;
static int cdrom_disk, cdrom_paused, cdrom_playing, cdrom_audiostatus;
static int cdrom_command_active;
static int cdrom_command_length;
static int cdrom_checksum_error, cdrom_unknown_command;
static int cdrom_data_offset, cdrom_speed, cdrom_sector_counter;
static int cdrom_current_sector, cdrom_seek_delay;
static int cdrom_audiotimeout;
static int cdrom_led;
static int cdrom_receive_length, cdrom_receive_offset;
static int cdrom_muted;
static int cd_initialized;
static int cdrom_tx_dma_delay, cdrom_rx_dma_delay;
static uae_u8 *sector_buffer_1, *sector_buffer_2;
static int sector_buffer_sector_1, sector_buffer_sector_2;
#define SECTOR_BUFFER_SIZE 64
static uae_u8 *sector_buffer_info_1, *sector_buffer_info_2;
static int unitnum = -1;
static uae_u8 cdrom_door = 1;
static bool akiko_inited;
static volatile int mediachanged, mediacheckcounter;
static volatile int frame2counter;
static smp_comm_pipe requests;
static volatile int akiko_thread_running;
static uae_sem_t akiko_sem, sub_sem, cda_sem;
static void checkint (void)
{
if (cdrom_intreq & cdrom_intena) {
irq ();
#if AKIKO_DEBUG_IRQ
write_log(_T("CD32: Akiko INT %08x\n"), cdrom_intreq & cdrom_intena);
#endif
#if AKIKO_DEBUG_IO
if (log_cd32 > 1)
write_log(_T("CD32: Akiko INT %08x\n"), cdrom_intreq & cdrom_intena);
#endif
}
}
static void set_status (uae_u32 status)
{
#if AKIKO_DEBUG_IO
if (log_cd32 > 1) {
if (!(cdrom_intreq & status))
write_log (_T("CD32: Akiko IRQ %08x | %08x = %08x\n"), status, cdrom_intreq, cdrom_intreq | status);
}
#endif
cdrom_intreq |= status;
checkint ();
cdrom_led ^= LED_CD_ACTIVE2;
}
static void rethink_akiko(void)
{
checkint ();
}
static void cdaudiostop_do (void)
{
qcode_valid = 0;
if (unitnum < 0)
return;
sys_command_cd_pause (unitnum, 0);
sys_command_cd_stop (unitnum);
}
static void cdaudiostop (void)
{
cdrom_audiostatus = 0;
cdrom_audiotimeout = 0;
cdrom_paused = 0;
cdrom_playing = 0;
write_comm_pipe_u32 (&requests, 0x0104, 1);
}
static void subfunc (uae_u8 *data, int cnt)
{
if (!(cdrom_flags & CDFLAG_SUBCODE))
return;
uae_sem_wait (&sub_sem);
#if 0
int total = 0;
for (int i = 0; i < MAX_SUBCODEBUFFER; i++) {
if (subcodebufferinuse[i])
total++;
}
write_log (_T("%d "), total);
#endif
if (subcodebufferinuse[subcodebufferoffsetw]) {
memset (subcodebufferinuse, 0,sizeof (subcodebufferinuse));
subcodebufferoffsetw = subcodebufferoffset = 0;
uae_sem_post (&sub_sem);
//write_log (_T("CD32: subcode buffer overflow 1\n"));
return;
}
int offset = subcodebufferoffsetw;
while (cnt > 0) {
if (subcodebufferinuse[offset]) {
write_log (_T("CD32: subcode buffer overflow 2\n"));
break;
}
subcodebufferinuse[offset] = 1;
memcpy (&subcodebuffer[offset * SUB_CHANNEL_SIZE], data, SUB_CHANNEL_SIZE);
data += SUB_CHANNEL_SIZE;
offset++;
if (offset >= MAX_SUBCODEBUFFER)
offset = 0;
cnt--;
}
subcodebufferoffsetw = offset;
uae_sem_post (&sub_sem);
}
static int statusfunc(int status, int playpos)
{
if (status == -1)
return 0;
if (status == -2)
return 10;
if (status < 0)
return 0;
if (cdrom_audiostatus != status) {
if (status == AUDIO_STATUS_IN_PROGRESS) {
if (cdrom_playing == 0)
cdrom_playing = 1;
cdrom_audiotimeout = 1;
}
if (cdrom_playing && status != AUDIO_STATUS_IN_PROGRESS && status != AUDIO_STATUS_PAUSED && status != AUDIO_STATUS_NOT_SUPPORTED) {
cdrom_audiotimeout = -1;
}
}
cdrom_audiostatus = status;
return 0;
}
static int statusfunc_imm(int status, int playpos)
{
if (status == -3 || status > AUDIO_STATUS_IN_PROGRESS)
uae_sem_post(&cda_sem);
if (status < 0)
return 0;
return statusfunc(status, playpos);
}
static void cdaudioplay_do(bool immediate)
{
uae_u32 startlsn = read_comm_pipe_u32_blocking(&requests);
uae_u32 endlsn = read_comm_pipe_u32_blocking(&requests);
uae_u32 scan = read_comm_pipe_u32_blocking(&requests);
qcode_valid = 0;
if (unitnum < 0)
return;
sys_command_cd_pause(unitnum, 0);
sys_command_cd_play(unitnum, startlsn, endlsn, scan, immediate ? statusfunc_imm : statusfunc, subfunc);
}
static bool isaudiotrack (int startlsn)
{
struct cd_toc *s = NULL;
uae_u32 addr;
int i;
if (!cdrom_toc_cd_buffer.points)
return false;
for (i = 0; i < cdrom_toc_cd_buffer.points; i++) {
s = &cdrom_toc_cd_buffer.toc[i];
addr = s->paddress;
if (s->track > 0 && s->track < 100 && addr >= startlsn)
break;
s++;
}
if (s && (s->control & 0x0c) == 0x04) {
write_log (_T("CD32: tried to play data track %d!\n"), s->track);
return false;
}
return true;
}
static struct cd_toc *get_track (int startlsn)
{
for (int i = cdrom_toc_cd_buffer.first_track_offset + 1; i <= cdrom_toc_cd_buffer.last_track_offset + 1; i++) {
struct cd_toc *s = &cdrom_toc_cd_buffer.toc[i];
uae_u32 addr = s->paddress;
if (startlsn < addr)
return s - 1;
}
return NULL;
}
static int last_play_end;
static int cd_play_audio (int startlsn, int endlsn, int scan)
{
struct cd_toc *s = NULL;
if (!cdrom_toc_cd_buffer.points)
return 0;
s = get_track (startlsn);
if (s && (s->control & 0x0c) == 0x04) {
s = get_track (startlsn + 150);
if (s && (s->control & 0x0c) == 0x04) {
write_log (_T("CD32: tried to play data track %d!\n"), s->track);
s++;
startlsn = s->paddress;
s++;
endlsn = s->paddress;
}
startlsn = s->paddress;
}
qcode_valid = 0;
last_play_end = endlsn;
cdrom_audiotimeout = 10;
cdrom_paused = 0;
write_comm_pipe_u32 (&requests, 0x0110, 0);
write_comm_pipe_u32 (&requests, startlsn, 0);
write_comm_pipe_u32 (&requests, endlsn, 0);
write_comm_pipe_u32 (&requests, scan, 1);
return 1;
}
/* read qcode */
static int last_play_pos;
static int cd_qcode (uae_u8 *d)
{
uae_u8 *buf, *s, as;
if (d)
memset (d, 0, 11);
last_play_pos = 0;
buf = qcode_buf;
as = buf[1];
buf[2] = 0x80;
if (!qcode_valid)
return 0;
if (cdrom_audiostatus != AUDIO_STATUS_IN_PROGRESS && cdrom_audiostatus != AUDIO_STATUS_PAUSED)
return 0;
s = buf + 4;
last_play_pos = msf2lsn (fromlongbcd (s + 7));
if (!d)
return 0;
buf[2] = 0;
/* ??? */
d[0] = 0;
/* CtlAdr */
d[1] = s[0];
/* Track */
d[2] = s[1];
/* Index */
d[3] = s[2];
/* TrackPos */
d[4] = s[3];
d[5] = s[4];
d[6] = s[5];
/* DiskPos */
d[7] = 0;
d[8] = s[7];
d[9] = s[8];
d[10] = s[9];
if (as == AUDIO_STATUS_IN_PROGRESS) {
/* Make sure end of disc position is not missed.
*/
if (last_play_pos >= cdrom_toc_cd_buffer.lastaddress || cdrom_toc_cd_buffer.lastaddress - last_play_pos < 10) {
int msf = lsn2msf (cdrom_toc_cd_buffer.lastaddress);
d[8] = tobcd ((uae_u8)(msf >> 16));
d[9] = tobcd ((uae_u8)(msf >> 8));
d[10] = tobcd ((uae_u8)(msf >> 0));
}
}
// write_log (_T("%02X.%02X.%02X.%02X.%02X.%02X.%02X.%02X.%02X.%02X.%02X.%02X\n"),
// d[0], d[1], d[2], d[3], d[4], d[5], d[6], d[7], d[8], d[9], d[10], d[11]);
return 0;
}
/* read toc */
static int get_cdrom_toc (void)
{
int j;
int datatrack = 0, secondtrack = 0;
cdrom_toc_counter = -1;
if (!sys_command_cd_toc (unitnum, &cdrom_toc_cd_buffer))
return 1;
memset (cdrom_toc_buffer, 0, MAX_TOC_ENTRIES * 13);
for (j = 0; j < cdrom_toc_cd_buffer.points; j++) {
struct cd_toc *s = &cdrom_toc_cd_buffer.toc[j];
uae_u8 *d = &cdrom_toc_buffer[j * 13];
int addr = s->paddress;
int msf = lsn2msf (addr);
if (s->point == 0xa0 || s->point == 0xa1)
msf = s->track << 16;
d[1] = (s->adr << 0) | (s->control << 4);
d[3] = s->point < 100 ? tobcd (s->point) : s->point;
d[8] = tobcd ((msf >> 16) & 0xff);
d[9] = tobcd ((msf >> 8) & 0xff);
d[10] = tobcd ((msf >> 0) & 0xff);
if (s->point == 1 && (s->control & 0x0c) == 0x04)
datatrack = 1;
if (s->point >= 2 && s->point < 100 && (s->control & 0x0c) != 0x04 && !secondtrack)
secondtrack = addr;
}
cdrom_toc_crc = get_crc32 (cdrom_toc_buffer, cdrom_toc_cd_buffer.points * 13);
return 0;
}
static bool is_valid_data_sector(int sector)
{
for (int i = 0; i < cdrom_toc_cd_buffer.points; i++) {
struct cd_toc *s = &cdrom_toc_cd_buffer.toc[i];
if (s->point < 1 || s->point > 99)
continue;
if ((s->control & 0x0c) != 4)
continue;
if (sector >= s->paddress && (sector < s[1].paddress || s[1].point >= 0xa1))
return true;
}
return false;
}
/* open device */
static int sys_cddev_open (void)
{
struct device_info di = { 0 };
unitnum = get_standard_cd_unit (CD_STANDARD_UNIT_CD32);
sys_command_info (unitnum, &di, 0);
write_log (_T("CD32: using drive %s (unit %d, media %d)\n"), di.label, unitnum, di.media_inserted);
/* make sure CD audio is not playing */
cdaudiostop_do ();
return 0;
}
/* close device */
static void sys_cddev_close (void)
{
if (unitnum >= 0) {
cdaudiostop_do ();
sys_command_close (unitnum);
}
unitnum = -1;
}
static bool cdrom_can_return_data(void)
{
if (cdrom_receive_length > 0)
return false;
return true;
}
static int cdrom_start_return_data (int len)
{
if (!cdrom_can_return_data())
return 0;
if (len <= 0)
return -1;
cdrom_receive_length = len;
uae_u8 checksum = 0xff;
for (int i = 0; i < cdrom_receive_length; i++) {
checksum -= cdrom_result_buffer[i];
}
cdrom_result_buffer[cdrom_receive_length++] = checksum;
#if AKIKO_DEBUG_IO_CMD
if (log_cd32 > 0) {
write_log(_T("CD32: OUT "));
for (int i = 0; i < cdrom_receive_length; i++) {
write_log(_T("%02X "), cdrom_result_buffer[i]);
}
write_log(_T("\n"));
}
#endif
cdrom_receive_offset = 0;
set_status(CDINTERRUPT_DRIVERECV);
return 1;
}
/*
RX DMA channel writes bytes to memory if DMA enabled, cdcomrxinx != cdcomrxcmp
and there is data available from CDROM firmware code.
Triggers CDINTERRUPT_RXDMADONE and stops transfer (even if there is
more data available) when cdcomrxinx matches cdcomrxcmp
*/
static void cdrom_return_data (void)
{
uae_u32 cmd_buf = cdrx_address;
if (!cdrom_receive_length)
return;
if (!(cdrom_flags & CDFLAG_RXD))
return;
if (cdcomrxinx == cdcomrxcmp)
return;
if (cdrom_rx_dma_delay > 0)
return;
#if AKIKO_DEBUG_IO_CMD
if (log_cd32 > 0)
write_log (_T("CD32: OUT IDX=0x%02X-0x%02X LEN=%d,%08x:"), cdcomrxinx, cdcomrxcmp, cdrom_receive_length, cmd_buf + cdcomrxinx);
#endif
while (cdrom_receive_offset < cdrom_receive_length) {
cdrom_last_rx = cdrom_result_buffer[cdrom_receive_offset];
put_byte (cmd_buf + cdcomrxinx, cdrom_last_rx);
cdcomrxinx++;
cdrom_receive_offset++;
if (cdcomrxinx == cdcomrxcmp) {
set_status(CDINTERRUPT_RXDMADONE);
#if AKIKO_DEBUG_IO
if (log_cd32 > 1)
write_log(_T("CD32: RXDMADONE %d/%d\n"), cdrom_receive_offset, cdrom_receive_length);
#endif
break;
}
}
if (cdrom_receive_offset == cdrom_receive_length) {
cdrom_receive_length = 0;
cdrom_receive_offset = 0;
cdrom_intreq &= ~CDINTERRUPT_DRIVERECV;
set_status(CDINTERRUPT_DRIVEXMIT);
}
}
static int cdrom_command_led (void)
{
int v = cdrom_command_buffer[1];
int old = cdrom_led;
cdrom_led &= ~LED_CD_ACTIVE;
cdrom_led |= (v & 1) ? LED_CD_ACTIVE : 0;
#if AKIKO_DEBUG_IO_CMD
if (log_cd32 > 0)
write_log(_T("CD32: LED=%d\n"), v & 1);
#endif
if (cdrom_led != old)
gui_flicker_led (LED_CD, 0, cdrom_led);
if (v & 0x80) { // result wanted?
cdrom_result_buffer[0] = cdrom_command;
cdrom_result_buffer[1] = (cdrom_led & LED_CD_ACTIVE) ? 1 : 0;
return 2;
}
return 0;
}
static int cdrom_command_idle_status (void)
{
cdrom_result_buffer[0] = 0x0a;
cdrom_result_buffer[1] = 0x70;
return 2;
}
static int cdrom_command_media_status (void)
{
cdrom_result_buffer[0] = 0x0a;
cdrom_result_buffer[1] = sys_command_ismedia (unitnum, 0) > 0 ? 0x01: 0x00;
return 2;
}
/* check if cd drive door is open or closed, return firmware info */
static int cdrom_command_status (void)
{
#if AKIKO_DEBUG_IO_CMD
if (log_cd32 > 0)
write_log(_T("CD32: INFO\n"));
#endif
cdrom_result_buffer[1] = cdrom_door;
if (unitnum >= 0)
get_cdrom_toc ();
/* firmware info */
memcpy (cdrom_result_buffer + 2, FIRMWAREVERSION, sizeof FIRMWAREVERSION);
cdrom_result_buffer[0] = cdrom_command;
cd_initialized = 2;
return 20;
}
/* return one TOC entry, each TOC entry repeats 3 times */
#define TOC_REPEAT 3
static int cdrom_return_toc_entry (void)
{
cdrom_result_buffer[0] = 6;
#if AKIKO_DEBUG_IO_CMD
if (log_cd32 > 0)
write_log (_T("CD32: TOC entry %d/%d\n"), cdrom_toc_counter / TOC_REPEAT, cdrom_toc_cd_buffer.points);
#endif
if (cdrom_toc_cd_buffer.points == 0) {
cdrom_result_buffer[1] = CDS_ERROR | cdrom_door;
return 15;
}
cdrom_result_buffer[1] = 0x0a; // unknown but real CD32 sets it
memcpy (cdrom_result_buffer + 2, cdrom_toc_buffer + (cdrom_toc_counter / TOC_REPEAT) * 13, 13);
cdrom_result_buffer[6] = tobcd(99);
cdrom_result_buffer[7] = tobcd(24 + cdrom_toc_counter / 75);
cdrom_result_buffer[8] = tobcd(cdrom_toc_counter % 75);
cdrom_toc_counter++;
if (cdrom_toc_counter / TOC_REPEAT >= cdrom_toc_cd_buffer.points)
cdrom_toc_counter = -1;
return 15;
}
static int checkerr (void)
{
if (!cdrom_disk) {
cdrom_result_buffer[1] = CH_ERR_NODISK | cdrom_door;
return 1;
}
return 0;
}
static int cdrom_command_stop (void)
{
#if AKIKO_DEBUG_IO_CMD
if (log_cd32 > 0)
write_log(_T("CD32: STOP: %d\n"), cdrom_playing);
#endif
cdrom_audiotimeout = 0;
cdrom_result_buffer[0] = cdrom_command;
if (checkerr ())
return 2;
cdrom_result_buffer[1] = 0;
cdaudiostop ();
return 2;
}
/* pause CD audio */
static int cdrom_command_pause (void)
{
#if AKIKO_DEBUG_IO_CMD