@HLEFunction(nid = 0x4C06E472, version = 150)
public int sceGeContinue() {
PspGeList list;
if (ExternalGE.isActive()) {
list = ExternalGE.getCurrentList();
} else {
list = VideoEngine.getInstance().getCurrentList();
}
if (list != null) {
synchronized (this) {
if (list.status == PSP_GE_LIST_END_REACHED) {
Memory mem = Memory.getInstance();
if (mem.read32(list.getPc()) == (GeCommands.FINISH << 24)
&& mem.read32(list.getPc() + 4) == (GeCommands.END << 24)) {
list.readNextInstruction();
list.readNextInstruction();
}
}
list.restartList();
}
}
return 0;
}
public int sceKernelReferLwMutexStatus(int workAreaAddr, int addr) {
Memory mem = Processor.memory;
int uid = mem.read32(workAreaAddr);
if (log.isDebugEnabled()) {
log.debug(
"sceKernelReferLwMutexStatus (workAreaAddr=0x"
+ Integer.toHexString(workAreaAddr)
+ ", addr=0x"
+ addr
+ ")");
}
SceKernelLwMutexInfo info = lwMutexMap.get(uid);
if (info == null) {
log.warn("sceKernelReferLwMutexStatus unknown UID " + Integer.toHexString(uid));
return ERROR_KERNEL_LWMUTEX_NOT_FOUND;
}
if (!Memory.isAddressGood(addr)) {
log.warn("sceKernelReferLwMutexStatus bad address 0x" + Integer.toHexString(addr));
return -1;
}
info.write(mem, addr);
return 0;
}
public int sceKernelUnlockLwMutex(int workAreaAddr, int count) {
Memory mem = Processor.memory;
int uid = mem.read32(workAreaAddr);
if (log.isDebugEnabled()) {
log.debug(
"sceKernelUnlockLwMutex (workAreaAddr=0x"
+ Integer.toHexString(workAreaAddr)
+ ", count="
+ count
+ ")");
}
SceKernelLwMutexInfo info = lwMutexMap.get(uid);
if (info == null) {
log.warn("sceKernelUnlockLwMutex unknown uid");
return ERROR_KERNEL_LWMUTEX_NOT_FOUND;
}
if (info.lockedCount == 0) {
log.debug("sceKernelUnlockLwMutex not locked");
return ERROR_KERNEL_LWMUTEX_UNLOCKED;
}
if (info.lockedCount < 0) {
log.warn("sceKernelUnlockLwMutex underflow");
return ERROR_KERNEL_LWMUTEX_UNLOCK_UNDERFLOW;
}
info.lockedCount -= count;
if (info.lockedCount == 0) {
onLwMutexModified(info);
}
return 0;
}
@Override
public void resolve(Memory mem, int address) {
if (!hasSavedValue) {
savedValue = mem.read32(getImportAddress());
hasSavedValue = true;
}
// Perform a R_MIPS_32 relocation
// Retrieve the current 32bit value
int value = mem.read32(getImportAddress());
// Relocate the value
value += address;
// Write back the relocated 32bit value
mem.write32(getImportAddress(), value);
}
public int sceKernelTryLockLwMutex(int workAreaAddr, int count) {
Memory mem = Processor.memory;
int uid = mem.read32(workAreaAddr);
if (log.isDebugEnabled()) {
log.debug("sceKernelTryLockLwMutex redirecting to hleKernelLockLwMutex");
}
return hleKernelLockLwMutex(uid, count, 0, false, false);
}
public int sceKernelLockLwMutexCB(int workAreaAddr, int count, int timeout_addr) {
Memory mem = Processor.memory;
int uid = mem.read32(workAreaAddr);
if (log.isDebugEnabled()) {
log.debug("sceKernelLockLwMutexCB redirecting to hleKernelLockLwMutex");
}
return hleKernelLockLwMutex(uid, count, timeout_addr, true, true);
}
public int getAddress(Memory mem, int i) {
if (ptr_index != 0 && index != 0) {
int addr = ptr_index + i * index;
switch (index) {
case 1:
i = mem.read8(addr);
break; // GU_INDEX_8BIT
case 2:
i = mem.read16(addr);
break; // GU_INDEX_16BIT
case 3:
i = mem.read32(addr);
break; // GU_INDEX_UNK3 (assume 32bit)
}
}
return ptr_vertex + i * vertexSize;
}
public int sceKernelDeleteLwMutex(int workAreaAddr) {
Memory mem = Processor.memory;
int uid = mem.read32(workAreaAddr);
if (log.isDebugEnabled()) {
log.debug("sceKernelDeleteLwMutex (workAreaAddr='" + Integer.toHexString(workAreaAddr) + ")");
}
SceKernelLwMutexInfo info = lwMutexMap.remove(uid);
if (info == null) {
log.warn("sceKernelDeleteLwMutex unknown UID " + Integer.toHexString(uid));
return ERROR_KERNEL_LWMUTEX_NOT_FOUND;
}
mem.write32(workAreaAddr, 0); // Clear uid.
onLwMutexDeleted(uid);
return 0;
}
public void atracSetData(
int atracID, int codecType, int address, int length, int atracFileSize, int atracHash) {
this.atracFileSize = atracFileSize;
this.atracBufferAddress = address;
this.atracHash = atracHash;
id = generateID(address, length, atracFileSize);
closeStreams();
atracEndSample = -1;
requireAllAtracData = false;
int memoryCodecType = sceAtrac3plus.getCodecType(address);
if (memoryCodecType != codecType && memoryCodecType != 0) {
Modules.log.info(
String.format(
"Different CodecType received %d != %d, assuming %d",
codecType, memoryCodecType, memoryCodecType));
codecType = memoryCodecType;
}
if (codecType == 0x00001001) {
Modules.log.info("Decodable AT3 data detected.");
if (checkMediaEngineState()) {
me.finish();
atracChannel = new PacketChannel();
atracChannel.setTotalStreamSize(atracFileSize);
atracChannel.setFarRewindAllowed(true);
atracChannel.write(address, length);
// Defer the initialization of the MediaEngine until atracDecodeData()
// to ensure we have enough data into the channel.
atracEndSample = 0;
return;
}
} else if (codecType == 0x00001000) {
if (checkMediaEngineState() && ExternalDecoder.isEnabled()) {
String decodedFile =
externalDecoder.decodeAtrac(address, length, atracFileSize, atracHash, this);
if (decodedFile != null) {
Modules.log.info("AT3+ data decoded by the external decoder.");
me.finish();
atracChannel = null;
me.init(new FileProtocolHandler(decodedFile), false, true, 0, 0);
atracEndSample = -1;
return;
} else if (requireAllAtracData) {
// The external decoder requires all the atrac data
// before it can try to decode the atrac.
me.finish();
atracChannel = new PacketChannel();
atracChannel.setTotalStreamSize(atracFileSize);
atracChannel.write(address, length);
return;
}
Modules.log.info("AT3+ data could not be decoded by the external decoder.");
} else {
Modules.log.info("Undecodable AT3+ data detected.");
}
}
me = null;
File decodedFile = new File(getCompleteFileName(decodedAtracSuffix));
if (!decodedFile.canRead()) {
// Try to read the decoded file using an alternate file name,
// without HashCode. These files can be generated by external tools
// decoding the Atrac3+ files. These tools can't generate the HashCode.
//
// Use the following alternate file name scheme:
// Atrac-SSSSSSSS-NNNNNNNN-DDDDDDDD.at3.decoded
// where SSSSSSSS is the file size in Hex
// NNNNNNNN is the number of samples in Hex found in the "fact" Chunk
// DDDDDDDD are the first 32-bit in Hex found in the "data" Chunk
int numberOfSamples = 0;
int data = 0;
// Scan the Atrac data for NNNNNNNN and DDDDDDDD values
Memory mem = Memory.getInstance();
int scanAddress = address + 12;
int endScanAddress = address + length;
while (scanAddress < endScanAddress) {
int chunkHeader = mem.read32(scanAddress);
int chunkSize = mem.read32(scanAddress + 4);
if (chunkHeader == waveFactChunkHeader) {
numberOfSamples = mem.read32(scanAddress + 8);
} else if (chunkHeader == waveDataChunkHeader) {
data = mem.read32(scanAddress + 8);
break;
}
// Go to the next Chunk
scanAddress += chunkSize + 8;
}
File alternateDecodedFile =
new File(
String.format(
"%sAtrac-%08X-%08X-%08X%s",
getBaseDirectory(), atracFileSize, numberOfSamples, data, decodedAtracSuffix));
if (alternateDecodedFile.canRead()) {
decodedFile = alternateDecodedFile;
}
}
File atracFile = new File(getCompleteFileName(atracSuffix));
if (decodedFile.canRead()) {
try {
decodedStream = new RandomAccessFile(decodedFile, "r");
atracEndSample = (int) (decodedFile.length() / 4);
} catch (FileNotFoundException e) {
// Decoded file should already be present
Modules.log.warn(e);
}
} else if (atracFile.canRead() && atracFile.length() == atracFileSize) {
// Atrac file is already written, no need to write it again
} else if (sceAtrac3plus.isEnableConnector()) {
commandFileDirty = true;
displayInstructions();
new File(getBaseDirectory()).mkdirs();
try {
atracStream = new FileOutputStream(getCompleteFileName(atracSuffix));
byte[] buffer = new byte[length];
IMemoryReader memoryReader = MemoryReader.getMemoryReader(address, length, 1);
for (int i = 0; i < length; i++) {
buffer[i] = (byte) memoryReader.readNext();
}
atracStream.write(buffer);
} catch (IOException e) {
Modules.log.warn(e);
}
generateCommandFile();
}
}
