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# ifndef _WIN32
# include "common.h"
# include "crossplatform.h"
# include <pthread.h>
# include <signal.h>
# include <semaphore.h>
# include <sys/types.h>
# include <unistd.h>
# include <sys/time.h>
# include <sys/statvfs.h>
# include <sys/types.h>
# include <sys/stat.h>
# include <fcntl.h>
# include <sys/resource.h>
# include <sys/syscall.h>
# include "CdStream.h"
# include "rwcore.h"
# include "RwHelper.h"
# define CDDEBUG(f, ...) debug ("%s: " f "\n", "cdvd_stream", ## __VA_ARGS__)
# define CDTRACE(f, ...) printf("%s: " f "\n", "cdvd_stream", ## __VA_ARGS__)
// #define ONE_THREAD_PER_CHANNEL // Don't use if you're not on SSD/Flash. (Also you may want to benefit from this via using all channels in Streaming.cpp)
bool flushStream [ MAX_CDCHANNELS ] ;
struct CdReadInfo
{
uint32 nSectorOffset ;
uint32 nSectorsToRead ;
void * pBuffer ;
bool bLocked ;
bool bReading ;
int32 nStatus ;
# ifdef ONE_THREAD_PER_CHANNEL
int8 nThreadStatus ; // 0: created 1:initalized 2:abort now
pthread_t pChannelThread ;
sem_t pStartSemaphore ;
# endif
sem_t pDoneSemaphore ; // used for CdStreamSync
int32 hFile ;
} ;
char gCdImageNames [ MAX_CDIMAGES + 1 ] [ 64 ] ;
int32 gNumImages ;
int32 gNumChannels ;
int32 gImgFiles [ MAX_CDIMAGES ] ; // -1: error 0:unused otherwise: fd
char * gImgNames [ MAX_CDIMAGES ] ;
# ifndef ONE_THREAD_PER_CHANNEL
pthread_t _gCdStreamThread ;
sem_t gCdStreamSema ; // released when we have new thing to read(so channel is set)
int8 gCdStreamThreadStatus ; // 0: created 1:initalized 2:abort now
Queue gChannelRequestQ ;
bool _gbCdStreamOverlapped ;
# endif
CdReadInfo * gpReadInfo ;
int32 lastPosnRead ;
int _gdwCdStreamFlags ;
void * CdStreamThread ( void * channelId ) ;
void
CdStreamInitThread ( void )
{
int status ;
# ifndef ONE_THREAD_PER_CHANNEL
gChannelRequestQ . items = ( int32 * ) calloc ( gNumChannels + 1 , sizeof ( int32 ) ) ;
gChannelRequestQ . head = 0 ;
gChannelRequestQ . tail = 0 ;
gChannelRequestQ . size = gNumChannels + 1 ;
ASSERT ( gChannelRequestQ . items ! = nil ) ;
status = sem_init ( & gCdStreamSema , 0 , 0 ) ;
# endif
if ( status = = - 1 ) {
CDTRACE ( " failed to create stream semaphore " ) ;
ASSERT ( 0 ) ;
return ;
}
if ( gNumChannels > 0 )
{
for ( int32 i = 0 ; i < gNumChannels ; i + + )
{
status = sem_init ( & gpReadInfo [ i ] . pDoneSemaphore , 0 , 0 ) ;
if ( status = = - 1 )
{
CDTRACE ( " failed to create sync semaphore " ) ;
ASSERT ( 0 ) ;
return ;
}
# ifdef ONE_THREAD_PER_CHANNEL
status = sem_init ( & gpReadInfo [ i ] . pStartSemaphore , 0 , 0 ) ;
if ( status = = - 1 )
{
CDTRACE ( " failed to create start semaphore " ) ;
ASSERT ( 0 ) ;
return ;
}
gpReadInfo [ i ] . nThreadStatus = 0 ;
int * channelI = ( int * ) malloc ( sizeof ( int ) ) ;
* channelI = i ;
status = pthread_create ( & gpReadInfo [ i ] . pChannelThread , NULL , CdStreamThread , ( void * ) channelI ) ;
if ( status = = - 1 )
{
CDTRACE ( " failed to create sync thread " ) ;
ASSERT ( 0 ) ;
return ;
}
# endif
}
}
# ifndef ONE_THREAD_PER_CHANNEL
debug ( " Using one streaming thread for all channels \n " ) ;
status = pthread_create ( & _gCdStreamThread , NULL , CdStreamThread , nil ) ;
gCdStreamThreadStatus = 0 ;
if ( status = = - 1 )
{
CDTRACE ( " failed to create sync thread " ) ;
ASSERT ( 0 ) ;
return ;
}
# else
debug ( " Using seperate streaming threads for each channel \n " ) ;
# endif
}
void
CdStreamInit ( int32 numChannels )
{
struct statvfs fsInfo ;
if ( ( statvfs ( " models/gta3.img " , & fsInfo ) ) < 0 )
{
CDTRACE ( " can't get filesystem info " ) ;
ASSERT ( 0 ) ;
return ;
}
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# ifdef __linux__
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_gdwCdStreamFlags = O_RDONLY | O_NOATIME ;
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# elif __FreeBSD__
_gdwCdStreamFlags = O_RDONLY ;
# endif
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// People say it's slower
/*
if ( fsInfo . f_bsize < = CDSTREAM_SECTOR_SIZE )
{
_gdwCdStreamFlags | = O_DIRECT ;
debug ( " Using no buffered loading for streaming \n " ) ;
}
*/
void * pBuffer = ( void * ) RwMallocAlign ( CDSTREAM_SECTOR_SIZE , fsInfo . f_bsize ) ;
ASSERT ( pBuffer ! = nil ) ;
gNumImages = 0 ;
gNumChannels = numChannels ;
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gpReadInfo = ( CdReadInfo * ) calloc ( numChannels , sizeof ( CdReadInfo ) ) ;
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ASSERT ( gpReadInfo ! = nil ) ;
CDDEBUG ( " read info %p " , gpReadInfo ) ;
CdStreamInitThread ( ) ;
ASSERT ( pBuffer ! = nil ) ;
RwFreeAlign ( pBuffer ) ;
}
uint32
GetGTA3ImgSize ( void )
{
ASSERT ( gImgFiles [ 0 ] > 0 ) ;
struct stat statbuf ;
char path [ PATH_MAX ] ;
realpath ( gImgNames [ 0 ] , path ) ;
if ( stat ( path , & statbuf ) = = - 1 ) {
// Try case-insensitivity
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char * real = casepath ( gImgNames [ 0 ] , false ) ;
if ( real )
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{
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realpath ( real , path ) ;
free ( real ) ;
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if ( stat ( path , & statbuf ) ! = - 1 )
goto ok ;
}
CDTRACE ( " can't get size of gta3.img " ) ;
ASSERT ( 0 ) ;
return 0 ;
}
ok :
return statbuf . st_size ;
}
void
CdStreamShutdown ( void )
{
// Destroying semaphores and free(gpReadInfo) will be done at threads
# ifndef ONE_THREAD_PER_CHANNEL
gCdStreamThreadStatus = 2 ;
sem_post ( & gCdStreamSema ) ;
# endif
# ifdef ONE_THREAD_PER_CHANNEL
for ( int32 i = 0 ; i < gNumChannels ; i + + ) {
gpReadInfo [ i ] . nThreadStatus = 2 ;
sem_post ( & gpReadInfo [ i ] . pStartSemaphore ) ;
}
# endif
}
int32
CdStreamRead ( int32 channel , void * buffer , uint32 offset , uint32 size )
{
ASSERT ( channel < gNumChannels ) ;
ASSERT ( buffer ! = nil ) ;
lastPosnRead = size + offset ;
ASSERT ( _GET_INDEX ( offset ) < MAX_CDIMAGES ) ;
int32 hImage = gImgFiles [ _GET_INDEX ( offset ) ] ;
ASSERT ( hImage > 0 ) ;
CdReadInfo * pChannel = & gpReadInfo [ channel ] ;
ASSERT ( pChannel ! = nil ) ;
pChannel - > hFile = hImage - 1 ;
if ( pChannel - > nSectorsToRead ! = 0 | | pChannel - > bReading )
return STREAM_NONE ;
pChannel - > nStatus = STREAM_NONE ;
pChannel - > nSectorOffset = _GET_OFFSET ( offset ) ;
pChannel - > nSectorsToRead = size ;
pChannel - > pBuffer = buffer ;
pChannel - > bLocked = 0 ;
# ifndef ONE_THREAD_PER_CHANNEL
AddToQueue ( & gChannelRequestQ , channel ) ;
if ( sem_post ( & gCdStreamSema ) ! = 0 )
printf ( " Signal Sema Error \n " ) ;
# else
if ( sem_post ( & gpReadInfo [ channel ] . pStartSemaphore ) ! = 0 )
printf ( " Signal Sema Error \n " ) ;
# endif
return STREAM_SUCCESS ;
}
int32
CdStreamGetStatus ( int32 channel )
{
ASSERT ( channel < gNumChannels ) ;
CdReadInfo * pChannel = & gpReadInfo [ channel ] ;
ASSERT ( pChannel ! = nil ) ;
# ifdef ONE_THREAD_PER_CHANNEL
if ( pChannel - > nThreadStatus = = 2 )
return STREAM_NONE ;
# else
if ( gCdStreamThreadStatus = = 2 )
return STREAM_NONE ;
# endif
if ( pChannel - > bReading )
return STREAM_READING ;
if ( pChannel - > nSectorsToRead ! = 0 )
return STREAM_WAITING ;
if ( pChannel - > nStatus ! = STREAM_NONE )
{
int32 status = pChannel - > nStatus ;
pChannel - > nStatus = STREAM_NONE ;
return status ;
}
return STREAM_NONE ;
}
int32
CdStreamGetLastPosn ( void )
{
return lastPosnRead ;
}
// wait for channel to finish reading
int32
CdStreamSync ( int32 channel )
{
ASSERT ( channel < gNumChannels ) ;
CdReadInfo * pChannel = & gpReadInfo [ channel ] ;
ASSERT ( pChannel ! = nil ) ;
if ( flushStream [ channel ] ) {
# ifdef ONE_THREAD_PER_CHANNEL
pChannel - > nSectorsToRead = 0 ;
pthread_kill ( gpReadInfo [ channel ] . pChannelThread , SIGINT ) ;
# else
if ( pChannel - > bReading ) {
pChannel - > nSectorsToRead = 0 ;
pthread_kill ( _gCdStreamThread , SIGINT ) ;
} else {
pChannel - > nSectorsToRead = 0 ;
}
# endif
pChannel - > bReading = false ;
flushStream [ channel ] = false ;
return STREAM_NONE ;
}
if ( pChannel - > nSectorsToRead ! = 0 )
{
pChannel - > bLocked = true ;
sem_wait ( & pChannel - > pDoneSemaphore ) ;
}
pChannel - > bReading = false ;
return pChannel - > nStatus ;
}
void
AddToQueue ( Queue * queue , int32 item )
{
ASSERT ( queue ! = nil ) ;
ASSERT ( queue - > items ! = nil ) ;
queue - > items [ queue - > tail ] = item ;
queue - > tail = ( queue - > tail + 1 ) % queue - > size ;
if ( queue - > head = = queue - > tail )
debug ( " Queue is full \n " ) ;
}
int32
GetFirstInQueue ( Queue * queue )
{
ASSERT ( queue ! = nil ) ;
if ( queue - > head = = queue - > tail )
return - 1 ;
ASSERT ( queue - > items ! = nil ) ;
return queue - > items [ queue - > head ] ;
}
void
RemoveFirstInQueue ( Queue * queue )
{
ASSERT ( queue ! = nil ) ;
if ( queue - > head = = queue - > tail )
{
debug ( " Queue is empty \n " ) ;
return ;
}
queue - > head = ( queue - > head + 1 ) % queue - > size ;
}
void * CdStreamThread ( void * param )
{
debug ( " Created cdstream thread \n " ) ;
# ifndef ONE_THREAD_PER_CHANNEL
while ( gCdStreamThreadStatus ! = 2 ) {
sem_wait ( & gCdStreamSema ) ;
int32 channel = GetFirstInQueue ( & gChannelRequestQ ) ;
# else
int channel = * ( ( int * ) param ) ;
while ( gpReadInfo [ channel ] . nThreadStatus ! = 2 ) {
sem_wait ( & gpReadInfo [ channel ] . pStartSemaphore ) ;
# endif
ASSERT ( channel < gNumChannels ) ;
CdReadInfo * pChannel = & gpReadInfo [ channel ] ;
ASSERT ( pChannel ! = nil ) ;
# ifdef ONE_THREAD_PER_CHANNEL
if ( gpReadInfo [ channel ] . nThreadStatus = = 0 ) {
gpReadInfo [ channel ] . nThreadStatus = 1 ;
# else
if ( gCdStreamThreadStatus = = 0 ) {
gCdStreamThreadStatus = 1 ;
# endif
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# ifdef __linux__
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pid_t tid = syscall ( SYS_gettid ) ;
int ret = setpriority ( PRIO_PROCESS , tid , getpriority ( PRIO_PROCESS , getpid ( ) ) + 1 ) ;
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# endif
}
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// spurious wakeup or we sent interrupt signal for flushing
if ( pChannel - > nSectorsToRead = = 0 )
continue ;
pChannel - > bReading = true ;
if ( pChannel - > nStatus = = STREAM_NONE )
{
ASSERT ( pChannel - > hFile > = 0 ) ;
ASSERT ( pChannel - > pBuffer ! = nil ) ;
lseek ( pChannel - > hFile , pChannel - > nSectorOffset * CDSTREAM_SECTOR_SIZE , SEEK_SET ) ;
if ( read ( pChannel - > hFile , pChannel - > pBuffer , pChannel - > nSectorsToRead * CDSTREAM_SECTOR_SIZE ) = = - 1 ) {
// pChannel->nSectorsToRead == 0 at this point means we wanted to flush channel
pChannel - > nStatus = pChannel - > nSectorsToRead = = 0 ? STREAM_NONE : STREAM_ERROR ;
} else {
pChannel - > nStatus = STREAM_NONE ;
}
}
# ifndef ONE_THREAD_PER_CHANNEL
RemoveFirstInQueue ( & gChannelRequestQ ) ;
# endif
pChannel - > nSectorsToRead = 0 ;
if ( pChannel - > bLocked )
{
sem_post ( & pChannel - > pDoneSemaphore ) ;
}
pChannel - > bReading = false ;
}
# ifndef ONE_THREAD_PER_CHANNEL
for ( int32 i = 0 ; i < gNumChannels ; i + + )
{
sem_destroy ( & gpReadInfo [ i ] . pDoneSemaphore ) ;
}
sem_destroy ( & gCdStreamSema ) ;
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free ( gChannelRequestQ . items ) ;
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# else
sem_destroy ( & gpReadInfo [ channel ] . pStartSemaphore ) ;
sem_destroy ( & gpReadInfo [ channel ] . pDoneSemaphore ) ;
# endif
free ( gpReadInfo ) ;
pthread_exit ( nil ) ;
}
bool
CdStreamAddImage ( char const * path )
{
ASSERT ( path ! = nil ) ;
ASSERT ( gNumImages < MAX_CDIMAGES ) ;
gImgFiles [ gNumImages ] = open ( path , _gdwCdStreamFlags ) ;
// Fix case sensitivity and backslashes.
if ( gImgFiles [ gNumImages ] = = - 1 ) {
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char * real = casepath ( path , false ) ;
if ( real )
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{
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gImgFiles [ gNumImages ] = open ( real , _gdwCdStreamFlags ) ;
free ( real ) ;
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}
}
if ( gImgFiles [ gNumImages ] = = - 1 ) {
assert ( false ) ;
return false ;
}
gImgNames [ gNumImages ] = strdup ( path ) ;
gImgFiles [ gNumImages ] + + ; // because -1: error 0: not used
strcpy ( gCdImageNames [ gNumImages ] , path ) ;
gNumImages + + ;
return true ;
}
char *
CdStreamGetImageName ( int32 cd )
{
ASSERT ( cd < MAX_CDIMAGES ) ;
if ( gImgFiles [ cd ] > 0 )
return gCdImageNames [ cd ] ;
return nil ;
}
void
CdStreamRemoveImages ( void )
{
for ( int32 i = 0 ; i < gNumChannels ; i + + )
CdStreamSync ( i ) ;
for ( int32 i = 0 ; i < gNumImages ; i + + )
{
close ( gImgFiles [ i ] - 1 ) ;
free ( gImgNames [ i ] ) ;
gImgFiles [ i ] = 0 ;
}
gNumImages = 0 ;
}
int32
CdStreamGetNumImages ( void )
{
return gNumImages ;
}
# endif