Exemplo n.º 1
0
void internal_lessequal(long a, float b)
{
  //printf("Inside internal add\n");

  //b must be wrapped in a PyArrayObject
  PyArrayObject *scalar = (PyArrayObject*)_malloc_align(sizeof(PyArrayObject),7);
  scalar->blockData = (char**)_malloc_align(sizeof(char*),7);
  scalar->blockData[0] = (char*)_malloc_align(sizeof(float),7);
  ((float*)(scalar->blockData[0]))[0] = b;
  scalar->numberOfBlocks = 1;

  //Setting the Operation object
  Operation_t op1;
  op1.shaderSize = arraylessequal_arrayscalar_size;
  op1.EA_shader  = arraylessequal_arrayscalar;
  op1.obj[0]     = a;
  op1.obj[1]     = scalar;
  op1.obj[2]     = a;

  //printf("arraymultiply: %d\n",arraydivide);
  //printf("&arraymultiply: %d\n",&arraydivide);

  op1.num_SPES   = speThreads;
  unsigned int i = 0;

  for(i = 0;i<speThreads;i++)
    {
      spe_pointer_addr[i][0] = &op1;
    }

  //printf("Adr of op1 sat. It is: %x\n",&op1);

  unsigned int state = 1;
  unsigned int y;

  for ( y = 0 ; y < speThreads ; y++ )
    {
      //printf("Sending state to disp\n");
      spe_in_mbox_write ( speData[y].spe_ctx, &state, 1, SPE_MBOX_ALL_BLOCKING );
      //printf("TO THE DISP. THE SUM STATE: %d, has just been sent\n",&state);
      //printf("This is the actual value: %d\n",state);
    }

  //printf("ADD Waiting for the SPE's\n");//ALSO, check that the structure used is correct!
  // Waiting for SPEs!
  //printf( "Waiting for SPEs\n" );
  unsigned int checked = 0;
  unsigned int r;
  while( checked < speThreads )
    {
      if ( spe_out_mbox_status( speData[checked].spe_ctx ) )
        {
          spe_out_mbox_read( speData[checked].spe_ctx, &r, 1 );
          checked++;
          //printf("Something read on the inbox\n");
        }
    }
  //printf("Done waiting on threads to finish in LESSEQUAL\n");

}
Exemplo n.º 2
0
void Scene::KDInitBuild(int maxleafsize, int extradepth, bool loadpolys)
{
	if(loadpolys)
		LoadPolygons(this, &worldaabb);
	else
		ComputeWorldAABB(&worldaabb, this);

	if(numnodes > 0)
	{
		#ifdef _CELL
			_free_align(nodes);
		#else
			delete [] nodes;
		#endif
	
		#ifdef _CELL
			_free_align(leafpolys);
			_free_align(leaves);		
		#else
			delete [] leafpolys;
			delete [] leaves;
		#endif

		numnodes = 0;
	}	

	if(numpolys < maxleafsize)
		maxnumleaves = numpolys;
	else
		maxnumleaves = numpolys / maxleafsize;
	
	maxdepth = (int)(log2(maxnumleaves) + 0.5 + extradepth);
	maxnumleaves = (int)pow(2.0f, maxdepth);
	numnodes = (int)pow(2.0f, maxdepth+1) - 1;

	#ifdef _CELL
		leafpolys = (kdleafpoly_t*)_malloc_align(sizeof(kdleafpoly_t) * maxnumleaves, 4);
		leaves = (int*)_malloc_align(maxnumleaves*sizeof(int), 7);
	#else
		leafpolys = new kdleafpoly_t[maxnumleaves];
		leaves = new int[maxnumleaves];
	#endif

	for(int i=0; i < maxnumleaves; i++)
		leaves[i] = 0;
	
	numleaves = maxnumleaves;
	numleafpolys = 0;
	
	#ifdef _CELL
		nodes = (kdnode_t*)_malloc_align(numnodes*sizeof(kdnode_t), 7);
	#else
		nodes = new kdnode_t[numnodes];
	#endif
}
Exemplo n.º 3
0
void KDBuildJob::ResetMinMaxBin(minmaxbin_t *mmb, int nbins, int index)
{
	if(nbins != numbins[index])
	{
		if(numbins[index] > 0)
		{
			#ifdef _CELL
				_free_align(minbins[index]);
				_free_align(maxbins[index]);
			#else
				delete [] minbins[index];
				delete [] maxbins[index];
			#endif
		}

		numbins[index] = nbins;

		#ifdef _CELL
			minbins[index] = (bin_t*)_malloc_align(numbins[index] * sizeof(bin_t), 7);
			maxbins[index] = (bin_t*)_malloc_align(numbins[index] * sizeof(bin_t), 7);			
		#else
			minbins[index] = new bin_t[numbins[index]];
			maxbins[index] = new bin_t[numbins[index]];
		#endif
	}

	int i;

	#ifdef _CELL
	vector float zero = spu_splats(0.0f);
	vector float *vminbins = (vector float*)minbins[index];
	vector float *vmaxbins = (vector float*)maxbins[index];

	for(i=0; i < numbins[index]; i++)
	{
		vminbins[i] = zero;
		vmaxbins[i] = zero;		
	}

	#else
	for(i=0; i < numbins[index]; i++)
	{
		minbins[index][i].b[0] = maxbins[index][i].b[0] = 0;
		minbins[index][i].b[1] = maxbins[index][i].b[1] = 0;
		minbins[index][i].b[2] = maxbins[index][i].b[2] = 0;
	}
	#endif

	mmb->minbins = minbins[index];
	mmb->maxbins = maxbins[index];


	mmb->numbins = numbins[index];
	mmb->bestcost = 1000000;
}
Exemplo n.º 4
0
PyObject *setcbe(PyObject *self, PyObject *args)
{
  PyArrayObjectTest *resultObj = _malloc_align(sizeof(PyArrayObjectTest),7); 
  PyObject *result = NULL;

  //We read a, but so far we don't use it.
  long a;

  resultObj->a = 7;
  resultObj->b = 8;



  if (PyArg_ParseTuple(args, "i", &a)) {
    result = Py_BuildValue("i", resultObj);
  } /* otherwise there is an error,
     * the exception already raised by PyArg_ParseTuple, and NULL is
     * returned.
     */

  //Call something interesting
  //testFunction(5);

  return result;
}
Exemplo n.º 5
0
void sMakeMatrix( unsigned int x, unsigned int y, unsigned int blocksize, float value, PyArrayObject *obj )
{
	//obj->blockData = (char **)memalign( 16, ( 4 * x * y + 15 ) & ~15 );
	obj->blockData = (char **)_malloc_align( 4 * x * y, 4 );
	//printf( "TEST=%u\n", ( 4 * x * y + 15 ) & ~15 );
	obj->numberOfBlocks     = x * y;
	obj->numberOfBlocksXDim = x;
	obj->numberOfBlocksYDim = y;
	obj->paddingx           = paddingx;
	obj->size_in_bytes      = 4;
	obj->blockSizes         = blocksize*blocksize;

	void *tmp[_CHEAT_LEVEL];
	unsigned int i;
	for( i = 0 ; i < _CHEAT_LEVEL ; i++ )
	{
		tmp[i] = sMakeBlock( blocksize*blocksize, value );
	}

	for( i = 0 ; i < x ; i++ )
	{
		obj->blockData[i] = tmp[i%_CHEAT_LEVEL];
		//printf( "1.=%f\n", *(float*)obj->blockData[i] );
	}
}
Exemplo n.º 6
0
void LoadPolygons(Scene *scene, aabb_t *worldaabb)
{
	if(numpolys > 0)
	{
		#ifdef _CELL
			_free_align(polys);
		#else
			delete [] polys;
		#endif

		numpolys = 0;	
	}
	
	vector<Mesh*>::iterator it;

	numpolys = 0;

	for(it = scene->meshlist.begin(); it != scene->meshlist.end(); it++)
	{
		Mesh *m = (*it);

		numpolys += m->NumTriangles();
	}

	#ifdef _CELL
		polys = (kdpolyp_t*)_malloc_align(sizeof(kdpolyp_t) * numpolys, 7);
	#else
		polys = new kdpolyp_t[numpolys];
	#endif

	int index = 0;

	AABB waabb(worldaabb);

	waabb.Reset();

	for(it = scene->meshlist.begin(); it != scene->meshlist.end(); it++)
	{
		Mesh *m = (*it);
		triangle_t *triangles = m->GetTriangles();
		normal_t *normals = m->GetNormals();
		color_t *colors = m->GetColors();
		aabb_t *m_aabbs = m->GetAABBs();

		for(int i=0; i < m->NumTriangles(); i++)
		{
			polys[index].triangle = &triangles[i];
			polys[index].normal = &normals[i];
			polys[index].color = colors[i].c;
		
			m_aabbs[i].poly = &polys[index];

			waabb.Union(&m_aabbs[i]);

			index++;
		}		
	}
}
Exemplo n.º 7
0
PyObject *_initializeVector(PyObject *self, PyObject *args)
{
  PyObject *result = NULL;

  long a;

  PyArrayObject *resultObj = _malloc_align(sizeof(PyArrayObject),7);
  result = Py_BuildValue("i", resultObj);
  /* otherwise there is an error,
   * the exception already raised by PyArg_ParseTuple, and NULL is
   * returned.
   */

  //Setting the PyArrayObject
  resultObj->numberOfBlocks = _numberOfBlocks*_numberOfBlocks;
  resultObj->numberOfBlocksXDim = _numberOfBlocks*_numberOfBlocks;
  resultObj->numberOfBlocksYDim = 1;
  resultObj->blockSize = _blockSize;//in elements
  resultObj->nd = 1;
  resultObj->blockData = (char**)_malloc_align(sizeof(char*)*_numberOfBlocks*_numberOfBlocks,7);
  unsigned int i = 0;
  resultObj->blockData[0] = (char*)_malloc_align(sizeof(char)*_blockSize*_blockSize*4,7);
  //printf("start blockData[0] : %d,%x\n",resultObj->blockData[0],resultObj->blockData[0]);
  for(i = 1;i<_numberOfBlocks*_numberOfBlocks;i++)
    {
      resultObj->blockData[i] = resultObj->blockData[0];
      //printf("In loop\n");
      //printf("blockData[i] : %d,%x\n",resultObj->blockData[i],resultObj->blockData[i]);
      //printf("blockData[0] : %d,%x\n",resultObj->blockData[0],resultObj->blockData[0]);
      //printf("In loop out\n");
    }
  //printf("blockData[0] : %d,%x\n",resultObj->blockData[0],resultObj->blockData[0]);
  //printf("blockData[1] : %d,%x\n",resultObj->blockData[1],resultObj->blockData[1]);
  //printf("Based on sizes: %d and %d: \n",sizeof(char*)*_numberOfBlocks*_numberOfBlocks,sizeof(char)*_blockSize*_blockSize*4);

  //Fill zeros in the block
    for(i=0;i<_blockSize*_blockSize;i++)
    {
      ((unsigned int*)resultObj->blockData[0])[i] = 0;
    }

  
  return result;
}
Exemplo n.º 8
0
void *sMakeBlock( unsigned int elements, float value )
{
	//void *block = (void *)memalign( 16, ( 4 * elements + 15 ) & ~15 );
	void *block = (void*)_malloc_align( 4 * elements, 7 );
	void *p = block;
	unsigned int i;
	for( i = 0 ; i < elements ; i++ )
	{
		//*(float*)p = i;
		*(float*)p = value;
		//printf( "%f, ", *(float*)p );
		p += 4;
	}
	return block;
}
Exemplo n.º 9
0
void*
malloc_align(size_t count, size_t align)
{
    return _malloc_align(count, align);
}
Exemplo n.º 10
0
/* loads the scene using DMA - blocks until done */
void load_scene(unsigned long long ea, scene_t *scene)
{
	unsigned int i = 0;
	object3d_t *objects = 0;
	pointlight_t *lights = 0;
	point_t *v = 0;

#if defined(_DEBUG) && _DEBUG > 2
	printf("Transferring %d bytes to LSaddr(%8lX) from EAadd(%8lX:%8lX) for SCENE\n",
		sizeof(scene_t),
		&scene,
		mfc_ea2h(ea),
		mfc_ea2l(ea));
#endif
	/* DMA request for scene */
	spu_mfcdma64(scene,
		mfc_ea2h(ea),
		mfc_ea2l(ea),
		sizeof(scene_t),
		SPUDMA_SCENE,
		MFC_GET_CMD);
	
	/* wait for request to complete */
	spu_writech(MFC_WrTagMask, 1 << SPUDMA_SCENE);
	mfc_read_tag_status_all();
	
	
	/* copy over objects */
	objects = _malloc_align(sizeof(object3d_t) * scene->nObjects, 4);
#if defined(_DEBUG) && _DEBUG > 2
	printf("Transferring %d bytes to LSaddr(%8lX) from EAadd(%8lX:%8lX) for OBJECTS\n",
		sizeof(object3d_t) * scene->nObjects,
		objects,
		mfc_ea2h(scene->objects_ea),
		mfc_ea2l(scene->objects_ea));
#endif
	/* initiate DMA */
	spu_mfcdma64(objects,
		mfc_ea2h(scene->objects_ea),
		mfc_ea2l(scene->objects_ea),
		sizeof(object3d_t) * scene->nObjects,
		SPUDMA_OBJECTS,
		MFC_GET_CMD);
	
	/* copy over lights */
	lights = _malloc_align(sizeof(pointlight_t) * scene->nLights, 4);	
#if defined(_DEBUG) && _DEBUG > 2
	printf("Transferring %d bytes to LSaddr(%8X) from EAadd(%8lX:%8lX) for LIGHTS\n",
		sizeof(pointlight_t) * scene->nLights,
		lights,
		mfc_ea2h(scene->lights_ea),
		mfc_ea2l(scene->lights_ea));
#endif
	/* initiate DMA for lights */
	spu_mfcdma64(lights,
		mfc_ea2h(scene->lights_ea),
		mfc_ea2l(scene->lights_ea),
		sizeof(pointlight_t) * scene->nLights,
		SPUDMA_LIGHTS,
		MFC_GET_CMD);
	
	/* wait for objects to complete */
	spu_writech(MFC_WrTagMask, 1 << SPUDMA_OBJECTS);
	mfc_read_tag_status_all();
	/* assign local store pointer to objects */
	scene->objects = objects;

	/* iterate each object locally */
	for(; i < scene->nObjects; ++i)
	{
		if(objects[i].geometryType == GEOMETRY_POLYGON)
		{
			/* allocate memory for vertex */
			v = _malloc_align(sizeof(point_t) 
				* objects[i].poly_obj.nVerticies, 4);
			/* initiate DMA to get verticies */
			spu_mfcdma64(v,
				mfc_ea2h(objects[i].poly_obj.vertex_ea),
				mfc_ea2l(objects[i].poly_obj.vertex_ea),
				sizeof(point_t)
				* objects[i].poly_obj.nVerticies,
				SPUDMA_VERTEXES,
				MFC_GET_CMD);
			/* assign local store pointer - WARNING - safe? */
			objects[i].poly_obj.vertex = v;				
		}
	}
	
	/* wait for all DMA to finish (vertexes, lights) */
	spu_writech(MFC_WrTagMask, 1 << SPUDMA_LIGHTS |
				1 << SPUDMA_VERTEXES );
	mfc_read_tag_status_all();
	/* assign local store lights pointer */
	scene->lights = lights;
}
Exemplo n.º 11
0
int main( unsigned long long id  __attribute__ ((unused)), unsigned long long argv )
{
	unsigned int i, EA = argv;
	/*
	 * Allocate memory
	 *
	 */

	// Info
	LS_ShaderInfo shaderinfo;

	// Memory for the shader
	unsigned int *shader[__NUMBER_OF_SHADERS];
	for( i = 0 ; i < __NUMBER_OF_SHADERS ; i++ )
	{
		shader[i] = (unsigned int *)_malloc_align( __SHADER_SIZE, 7 );
	}

	// Memory for the blocks
	char *blocks[(__NUMBER_OF_BLOCKS_IN_MEM) * 2];
	for( i = 0 ; i < __NUMBER_OF_BLOCKS_IN_MEM * 2 ; i++ )
	{
		blocks[i] = (char *)_malloc_align( __BLOCK_DATA_SIZE, 7 );
		shaderinfo.LS_blockDataArea[i] = blocks[i];
	}

	// Memory for metadata
	char *meta = (char *)_malloc_align( __META_DATA_SIZE, 7 );
	shaderinfo.LS_shaderMemory = meta;

	Operation_t myop[__NUMBER_OF_SHADERS];
	unsigned int PPE_addr[__NUMBER_OF_SHADERS] __attribute__((aligned(16)));
	unsigned int EA_result[__NUMBER_OF_SHADERS];

	// Getting SPE id
	SPE_id   = mb_getmbox( );
	// SELF CHECK
	//if ( SPE_id == 0 ) SelfCheck();
	//printf( "SPE[%u]: SPE_* is at %#x\n", SPE_id, EA );

	//printf( "[SPE(%u)]Check!!!\n", SPE_id );

	// SPU program fragment prototype
	void (*run)( unsigned int SPE_id, LS_ShaderInfo *info, Operation_t *myop, Functions_t *funcs ) = NULL;
	void (*runr)( unsigned int SPE_id, unsigned int EA_result, LS_ShaderInfo *info, Operation_t *myop, Functions_t *funcs ) = NULL;

	// Getting SPE id
	unsigned int seed = mb_getmbox( );
	// Init random
	mc_rand_ks_init( seed );

	// Common Functions
	Functions_t funcs;
	funcs.printuint      = PrintUInt;
	funcs.printint       = PrintInt;
	funcs.printe         = PrintE;
	funcs.printchar      = PrintChar;
	funcs.printfloat     = PrintFloat;
	funcs.printaddr      = PrintAddr;
	funcs.printstr       = PrintString;
	funcs.printfloat3    = PrintFloat3;
	funcs.printfloat3v   = PrintFloat3v;
	funcs.printfloatv    = PrintFloatv;
	funcs.printfloatrow  = PrintFloatRow;

	//funcs.printf         = printf2;

	funcs.rand_0_to_1_f  = mc_rand_ks_0_to_1_f4;
	//funcs.rand_0_to_1_fm = mc_rand_ks_0_to_1_array_f4;

	unsigned int running = 1, task = 0;

//	prof_clear();
//	prof_start();

	unsigned int idt;

	// THA LOOP
	while( running )
	{
		task = mb_getmbox( );

		Printf1( "[SPE(%u)]Got state %u\n", SPE_id, task );

		// Transfer operation and run shader with no return value
		// 0 -> 99
		if( task < 100 )
		{
			idt = task;

			CHECKBOUNDS( idt );

			Printf1( "SPE[%u]: Get shader for slot %u\n", SPE_id, idt );

			GetSPEAddr( EA, PPE_addr );
			GetOperation( PPE_addr[idt], &myop[idt] );
			GetShader( (unsigned int)myop[idt].EA_shader, myop[idt].shaderSize, shader[idt] );
			Printf1( "SPE[%u]: Shader recieved for slot\n", SPE_id );
			run = (void *)shader[0];

			Printf1( "SPE[%u]: --- Running shader! ----------\n", SPE_id );
			run( SPE_id, &shaderinfo, &myop[idt], &funcs );
			Printf1( "SPE[%u]: --- End of shader! -----------\n", SPE_id );

			spu_writech( SPU_WrOutMbox, 1 );
		}

		// Transfer operation and run shader WITH return value
		// 100 -> 199
		else if( task < 200 )
		{
			idt = task - 100;

			CHECKBOUNDS( idt );

			Printf1( "SPE[%u]: Get shader with return value for slot %u\n", SPE_id, idt );

			EA_result[idt] = mb_getmbox( );
			GetSPEAddr( EA, PPE_addr );
			GetOperation( PPE_addr[idt], &myop[idt] );
			GetShader( (unsigned int)myop[idt].EA_shader, myop[idt].shaderSize, shader[idt] );
			runr = (void *)shader[idt];

			Printf1( "SPE[%u]: --- Running shader! ----------\n", SPE_id );
			runr( SPE_id, EA_result[idt], &shaderinfo, &myop[idt], &funcs );

			Printf1( "SPE[%u]: --- End of shader! -----------\n", SPE_id );

			spu_writech( SPU_WrOutMbox, 1 );
		}


		// Transfer operation and shader WITHOUT return value
		// 200 -> 299
		else if( task < 300 )
		{
			idt = task - 200;

			CHECKBOUNDS( idt );

			Printf1( "SPE[%u]: Get shader for slot %u\n", SPE_id, idt );
			GetSPEAddr( EA, PPE_addr );
			GetOperation( PPE_addr[idt], &myop[idt] );
			GetShader( (unsigned int)myop[idt].EA_shader, myop[idt].shaderSize, shader[idt] );
			spu_writech( SPU_WrOutMbox, 1 );
		}

		// Run shader with no return value
		// 300 -> 399
		else if( task < 400 )
		{
			idt = task - 300;

			CHECKBOUNDS( idt );

			Printf1( "SPE[%u]: Run shader from slot %u\n", SPE_id, idt );
			run = (void *)shader[idt];
			run( SPE_id, &shaderinfo, &myop[idt], &funcs );
			spu_writech( SPU_WrOutMbox, 1 );
		}

		// Transfer operation and shader WITH return value
		// 400 -> 499
		else if( task < 500 )
		{
			idt = task - 400;

			CHECKBOUNDS( idt );

			Printf1( "SPE[%u]: Get shader with return value for slot %u\n", SPE_id, idt );
			EA_result[idt] = mb_getmbox( );
			GetSPEAddr( EA, PPE_addr );
			GetOperation( PPE_addr[idt], &myop[idt] );
			GetShader( (unsigned int)myop[idt].EA_shader, myop[idt].shaderSize, shader[idt] );
			Printf1( "SPE[%u]: Done getting operation %u\n", SPE_id, idt );
			spu_writech( SPU_WrOutMbox, 1 );
		}

		// Run shader WITH return value
		// 500 -> 599
		else if( task < 600 )
		{
			idt = task - 500;

			CHECKBOUNDS( idt );

			Printf1( "SPE[%u]: Run shader with return value from slot %u\n", SPE_id, idt );
			runr = (void *)shader[0];
			runr( SPE_id, EA_result[idt], &shaderinfo, &myop[0], &funcs );
			spu_writech( SPU_WrOutMbox, 1 );
		}

		// Sanity check!!!
		else if( task == 1000 )
		{
			spu_writech( SPU_WrOutMbox, 123 );
		}

		// DEFAULT
		else
		{
			Printf1( "[SPE(%u)]No such instruction, quitting\n", SPE_id );
			running = 0;
		}





//		switch( task )
//		{
//		case 0: // QUIT
//			Printf1( "[SPE(%u)]Quitting\n", SPE_id );
//
//			running = 0;
//			break;
//
//			/*
//			 * Get an operation with no return value
//			 *
//			 */
//		case 1: // Get operation and run
//			GetSPEAddr( EA, PPE_addr );
//			GetOperation( PPE_addr[0], &myop[0] );
//			GetShader( (unsigned int)myop[0].EA_shader, myop[0].shaderSize, shader[0] );
//			run = (void *)shader[0];
//
//			Printf1( "SPE[%u]: --- Running shader! ----------\n", SPE_id );
//			run( SPE_id, &shaderinfo, &myop[0], &funcs );
//			Printf1( "SPE[%u]: --- End of shader! -----------\n", SPE_id );
//
//			spu_writech( SPU_WrOutMbox, 1 );
//			break;
//
//			/*
//			 * Get an operation with a return value
//			 *
//			 */
//		case 2: // Get operation with return value and run
//			EA_result = mb_getmbox( );
//			GetSPEAddr( EA, PPE_addr );
//			GetOperation( PPE_addr[0], &myop[0] );
//			GetShader( (unsigned int)myop[0].EA_shader, myop[0].shaderSize, shader[0] );
//			runr = (void *)shader[0];
//
//			Printf1( "SPE[%u]: --- Running shader! ----------\n", SPE_id );
//			runr( SPE_id, EA_result, &shaderinfo, &myop[0], &funcs );
//
//			Printf1( "SPE[%u]: --- End of shader! -----------\n", SPE_id );
//
//			spu_writech( SPU_WrOutMbox, 1 );
//			break;
//
//		case 3: // Get operation without return value NO RUN!
//
//			GetSPEAddr( EA, PPE_addr );
//			GetOperation( PPE_addr[0], &myop[0] );
//			GetShader( (unsigned int)myop[0].EA_shader, myop[0].shaderSize, shader[0] );
//			run = (void *)shader[0];
//
//			spu_writech( SPU_WrOutMbox, 1 );
//			break;
//
//
//		case 4: // Get operation  with return value NO RUN!
//
//			EA_result = mb_getmbox( );
//			GetSPEAddr( EA, PPE_addr );
//			GetOperation( PPE_addr[0], &myop[0] );
//			GetShader( (unsigned int)myop[0].EA_shader, myop[0].shaderSize, shader[0] );
//			runr = (void *)shader[0];
//
//			spu_writech( SPU_WrOutMbox, 1 );
//			break;
//
//		case 5: // RUN!!!! with _NO_ return value
//			Printf1( "SPE[%u]: --- Running shader! ----------\n", SPE_id );
//
//			run( SPE_id, &shaderinfo, &myop[0], &funcs );
//			Printf1( "SPE[%u]: --- End of shader! -----------\n", SPE_id );
//			spu_writech( SPU_WrOutMbox, 1 );
//			break;
//
//		case 6: // RUN!!!! with return value
//
//			Printf1( "SPE[%u]: --- Running shader! ----------\n", SPE_id );
//
//			runr( SPE_id, EA_result, &shaderinfo, &myop[0], &funcs );
//
//			Printf1( "SPE[%u]: --- End of shader! -----------\n", SPE_id );
//
//			spu_writech( SPU_WrOutMbox, 1 );
//			break;
//
//		/*
//		 * Operations with no return values
//		 */
//		case 100: // Get a shader for slot 0
//			Printf1( "SPE[%u]: Get shader for slot 0\n", SPE_id );
//			GetSPEAddr( EA, PPE_addr );
//			GetOperation( PPE_addr[0], &myop[0] );
//			GetShader( (unsigned int)myop[0].EA_shader, myop[0].shaderSize, shader[0] );
//			break;
//
//		case 101: // Get a shader for slot 1
//			Printf1( "SPE[%u]: Get shader for slot 1\n", SPE_id );
//			GetSPEAddr( EA, PPE_addr );
//			GetOperation( PPE_addr[1], &myop[1] );
//			GetShader( (unsigned int)myop[1].EA_shader, myop[1].shaderSize, shader[1] );
//			break;
//
//		case 102: // Get a shader for slot 2
//			Printf1( "SPE[%u]: Get shader for slot 2\n", SPE_id );
//			GetSPEAddr( EA, PPE_addr );
//			GetOperation( PPE_addr[2], &myop[2] );
//			GetShader( (unsigned int)myop[2].EA_shader, myop[2].shaderSize, shader[2] );
//			break;
//
//		case 103: // Get a shader for slot 3
//			Printf1( "SPE[%u]: Get shader for slot 3\n", SPE_id );
//			GetSPEAddr( EA, PPE_addr );
//			GetOperation( PPE_addr[3], &myop[3] );
//			GetShader( (unsigned int)myop[3].EA_shader, myop[3].shaderSize, shader[3] );
//			break;
//
//		case 110: // Run slot 0
//			Printf1( "SPE[%u]: Run shader from slot 0\n", SPE_id );
//			run = (void *)shader[0];
//			run( SPE_id, &shaderinfo, &myop[0], &funcs );
//			spu_writech( SPU_WrOutMbox, 1 );
//			break;
//
//		case 111: // Run slot 1
//			Printf1( "SPE[%u]: Run shader from slot 1\n", SPE_id );
//			run = (void *)shader[1];
//			run( SPE_id, &shaderinfo, &myop[1], &funcs );
//			spu_writech( SPU_WrOutMbox, 1 );
//			break;
//
//		case 112: // Run slot 2
//			Printf1( "SPE[%u]: Run shader from slot 2\n", SPE_id );
//			run = (void *)shader[2];
//			run( SPE_id, &shaderinfo, &myop[2], &funcs );
//			spu_writech( SPU_WrOutMbox, 1 );
//			break;
//
//		case 113: // Run slot 3
//			Printf1( "SPE[%u]: Run shader from slot 3\n", SPE_id );
//			run = (void *)shader[3];
//			Printf1( "SPE[%u]: Run shader from slot 3\n", SPE_id );
//			run( SPE_id, &shaderinfo, &myop[3], &funcs );
//			spu_writech( SPU_WrOutMbox, 1 );
//			break;
//
//			/*
//			 * Update operations
//			 */
//
//		case 120: // Update operation for slot 0
//			Printf1( "SPE[%u]: Update operation for slot 0\n", SPE_id );
//			GetSPEAddr( EA, PPE_addr );
//			GetOperation( PPE_addr[0], &myop[0] );
//			break;
//
//		case 121: // Update operation for slot 1
//			Printf1( "SPE[%u]: Update operation for slot 1\n", SPE_id );
//			GetSPEAddr( EA, PPE_addr );
//			GetOperation( PPE_addr[1], &myop[1] );
//			break;
//
//		case 122: // Update operation for slot 2
//			Printf1( "SPE[%u]: Update operation for slot 2\n", SPE_id );
//			GetSPEAddr( EA, PPE_addr );
//			GetOperation( PPE_addr[2], &myop[2] );
//			break;
//
//		case 123: // Update operation for slot 3
//			Printf1( "SPE[%u]: Update operation for slot 3\n", SPE_id );
//			GetSPEAddr( EA, PPE_addr );
//			GetOperation( PPE_addr[3], &myop[3] );
//			break;
//
//		/*
//		 * Operations with return values
//		 */
//		case 200: // Get a shader for slot 0
//			Printf1( "SPE[%u]: Run shader with return value from slot 0\n", SPE_id );
//			EA_result = mb_getmbox( );
//			GetOperation( PPE_addr[0], &myop[0] );
//			GetShader( (unsigned int)myop[0].EA_shader, myop[0].shaderSize, shader[0] );
//			break;
//
//		case 201: // Get a shader for slot 1
//			Printf1( "SPE[%u]: Run shader with return value from slot 1\n", SPE_id );
//			EA_result = mb_getmbox( );
//			GetOperation( PPE_addr[0], &myop[1] );
//			GetShader( (unsigned int)myop[1].EA_shader, myop[1].shaderSize, shader[1] );
//			break;
//
//		case 210: // Run slot 0
//			runr = (void *)shader[0];
//			runr( SPE_id, EA_result, &shaderinfo, &myop[0], &funcs );
//			spu_writech( SPU_WrOutMbox, 1 );
//			break;
//
//		case 211: // Run slot 1
//			runr = (void *)shader[1];
//			runr( SPE_id, EA_result, &shaderinfo, &myop[1], &funcs );
//			spu_writech( SPU_WrOutMbox, 1 );
//			break;
//
//		case 1000: // Sanity check
//			spu_writech( SPU_WrOutMbox, 123 );
//			break;
//
//
//		default:
//			Printf1( "[SPE(%u)]No such instruction, quitting\n", SPE_id );
//			running = 0;
//		}
	}

	//prof_stop();

	return 1;
}
Exemplo n.º 12
0
void* malloc_align7(unsigned int size)
{
	return _malloc_align(size, 7);
}