2020-04-22 16:56:21 +00:00
//========= Copyright Valve Corporation, All rights reserved. ============//
//
// Purpose: tracks VB allocations (and compressed/uncompressed vertex memory usage)
//
//===========================================================================//
# include "materialsystem/imaterial.h"
# include "imeshdx8.h"
# include "convar.h"
# include "tier1/utlhash.h"
# include "tier1/utlstack.h"
# include "materialsystem/ivballoctracker.h"
//-----------------------------------------------------------------------------
//
// Types
//
//-----------------------------------------------------------------------------
# if ENABLE_VB_ALLOC_TRACKER
// FIXME: combine this into the lower bits of VertexFormat_t
typedef uint64 VertexElementMap_t ;
enum Saving_t
{
SAVING_COMPRESSION = 0 ,
SAVING_REMOVAL = 1 ,
SAVING_ALIGNMENT = 2
} ;
struct ElementData
{
VertexElement_t element ;
int uncompressed ; // uncompressed vertex size
int currentCompressed ; // current compressed vertex element size
int idealCompressed ; // ideal future compressed vertex element size
const char * name ;
} ;
class CounterData
{
public :
CounterData ( ) : m_memCount ( 0 ) , m_vertCount ( 0 ) , m_paddingCount ( 0 )
{
for ( int i = 0 ; i < VERTEX_ELEMENT_NUMELEMENTS ; i + + )
{
m_elementsCompressed [ i ] = 0 ;
m_elementsUncompressed [ i ] = 0 ;
}
m_AllocatorName [ 0 ] = 0 ;
}
static const int MAX_NAME_SIZE = 128 ;
int m_memCount ;
int m_vertCount ;
int m_paddingCount ;
int m_elementsCompressed [ VERTEX_ELEMENT_NUMELEMENTS ] ; // Number of compressed verts using each element
int m_elementsUncompressed [ VERTEX_ELEMENT_NUMELEMENTS ] ; // Number of uncompressed verts using each element
char m_AllocatorName [ MAX_NAME_SIZE ] ;
} ;
class AllocData
{
public :
AllocData ( void * buffer , int bufferSize , VertexFormat_t fmt , int numVerts , int allocatorHash )
: m_buffer ( buffer ) , m_bufferSize ( bufferSize ) , m_fmt ( fmt ) , m_numVerts ( numVerts ) , m_allocatorHash ( allocatorHash ) { }
AllocData ( ) : m_buffer ( NULL ) , m_bufferSize ( 0 ) , m_fmt ( 0 ) , m_numVerts ( 0 ) , m_allocatorHash ( 0 ) { }
VertexFormat_t m_fmt ;
void * m_buffer ;
int m_bufferSize ;
int m_numVerts ;
short m_allocatorHash ;
} ;
typedef CUtlHashFixed < CounterData , 64 > CCounterTable ;
typedef CUtlHashFixed < AllocData , 4096 > CAllocTable ;
typedef CUtlStack < short > CAllocNameHashes ;
# endif // ENABLE_VB_ALLOC_TRACKER
class CVBAllocTracker : public IVBAllocTracker
{
public :
virtual void CountVB ( void * buffer , bool isDynamic , int bufferSize , int vertexSize , VertexFormat_t fmt ) ;
virtual void UnCountVB ( void * buffer ) ;
virtual bool TrackMeshAllocations ( const char * allocatorName ) ;
void DumpVBAllocs ( ) ;
# if ENABLE_VB_ALLOC_TRACKER
public :
CVBAllocTracker ( ) : m_bSuperSpew ( false ) { m_MeshAllocatorName [ 0 ] = 0 ; }
private :
UtlHashFixedHandle_t TrackAlloc ( void * buffer , int bufferSize , VertexFormat_t fmt , int numVerts , short allocatorHash ) ;
bool KillAlloc ( void * buffer , int & bufferSize , VertexFormat_t & fmt , int & numVerts , short & allocatorHash ) ;
UtlHashFixedHandle_t GetCounterHandle ( const char * allocatorName , short allocatorHash ) ;
void SpewElements ( const char * allocatorName , short nameHash ) ;
int ComputeVertexSize ( VertexElementMap_t map , VertexFormat_t fmt , bool compressed ) ;
VertexElementMap_t ComputeElementMap ( VertexFormat_t fmt , int vertexSize , bool isDynamic ) ;
void UpdateElements ( CounterData & data , VertexFormat_t fmt , int numVerts , int vertexSize ,
bool isDynamic , bool isCompressed ) ;
int ComputeAlignmentWastage ( int bufferSize ) ;
void AddSaving ( int & alreadySaved , int & yetToSave , const char * allocatorName , VertexElement_t element , Saving_t savingType ) ;
void SpewExpectedSavings ( void ) ;
void UpdateData ( const char * allocatorName , short allocatorKey , int bufferSize , VertexFormat_t fmt ,
int numVerts , int vertexSize , bool isDynamic , bool isCompressed ) ;
const char * GetNameString ( int allocatorKey ) ;
void SpewData ( const char * allocatorName , short nameHash = 0 ) ;
void SpewDataSometimes ( int inc ) ;
static const int SPEW_RATE = 64 ;
static const int MAX_ALLOCATOR_NAME_SIZE = 128 ;
char m_MeshAllocatorName [ MAX_ALLOCATOR_NAME_SIZE ] ;
bool m_bSuperSpew ;
CCounterTable m_VBCountTable ;
CAllocTable m_VBAllocTable ;
CAllocNameHashes m_VBTableNameHashes ;
// We use a mutex since allocation tracking is accessed from multiple loading threads.
// CThreadFastMutex is used as contention is expected to be low during loading.
CThreadFastMutex m_VBAllocMutex ;
# endif // ENABLE_VB_ALLOC_TRACKER
} ;
//-----------------------------------------------------------------------------
//
// Global data
//
//-----------------------------------------------------------------------------
# if ENABLE_VB_ALLOC_TRACKER
// FIXME: do this in a better way:
static const ElementData positionElement = { VERTEX_ELEMENT_POSITION , 12 , 12 , 8 , " POSITION " } ; // (UNDONE: need vertex shader to scale, may cause cracking w/ static props)
static const ElementData normalElement = { VERTEX_ELEMENT_NORMAL , 12 , 4 , 4 , " NORMAL " } ; // (UNDONE: PC (2x16-byte Ravi method) or 360 (D3DDECLTYPE_HEND3N))
static const ElementData colorElement = { VERTEX_ELEMENT_COLOR , 4 , 4 , 4 , " COLOR " } ; // (already minimal)
static const ElementData specularElement = { VERTEX_ELEMENT_SPECULAR , 4 , 4 , 4 , " SPECULAR " } ; // (already minimal)
static const ElementData tangentSElement = { VERTEX_ELEMENT_TANGENT_S , 12 , 12 , 4 , " TANGENT_S " } ; // (all-but-unused)
static const ElementData tangentTElement = { VERTEX_ELEMENT_TANGENT_T , 12 , 12 , 4 , " TANGENT_T " } ; // (all-but-unused)
static const ElementData wrinkleElement = { VERTEX_ELEMENT_WRINKLE , 4 , 4 , 0 , " WRINKLE " } ; // (UNDONE: compress it as a SHORTN in Position.w - is it [0,1]?)
static const ElementData boneIndexElement = { VERTEX_ELEMENT_BONEINDEX , 4 , 4 , 4 , " BONEINDEX " } ; // (already minimal)
static const ElementData boneWeight1Element = { VERTEX_ELEMENT_BONEWEIGHTS1 , 4 , 4 , 4 , " BONEWEIGHT1 " } ; // (unused)
static const ElementData boneWeight2Element = { VERTEX_ELEMENT_BONEWEIGHTS2 , 8 , 8 , 4 , " BONEWEIGHT2 " } ; // (UNDONE: take care w.r.t cracking in flex regions)
static const ElementData boneWeight3Element = { VERTEX_ELEMENT_BONEWEIGHTS3 , 12 , 12 , 8 , " BONEWEIGHT3 " } ; // (unused)
static const ElementData boneWeight4Element = { VERTEX_ELEMENT_BONEWEIGHTS4 , 16 , 16 , 8 , " BONEWEIGHT4 " } ; // (unused)
static const ElementData userData1Element = { VERTEX_ELEMENT_USERDATA1 , 4 , 4 , 4 , " USERDATA1 " } ; // (unused)
static const ElementData userData2Element = { VERTEX_ELEMENT_USERDATA2 , 8 , 8 , 4 , " USERDATA2 " } ; // (unused)
static const ElementData userData3Element = { VERTEX_ELEMENT_USERDATA3 , 12 , 12 , 4 , " USERDATA3 " } ; // (unused)
# if ( COMPRESSED_NORMALS_TYPE == COMPRESSED_NORMALS_SEPARATETANGENTS_SHORT2 )
static const ElementData userData4Element = { VERTEX_ELEMENT_USERDATA4 , 16 , 4 , 4 , " USERDATA4 " } ; // (UNDONE: PC (2x16-byte Ravi method) or 360 (D3DDECLTYPE_HEND3N))
# else // ( COMPRESSED_NORMALS_TYPE == COMPRESSED_NORMALS_COMBINEDTANGENTS_UBYTE4 )
static const ElementData userData4Element = { VERTEX_ELEMENT_USERDATA4 , 16 , 0 , 0 , " USERDATA4 " } ; // (UNDONE: PC (2x16-byte Ravi method) or 360 (D3DDECLTYPE_HEND3N))
# endif
static const ElementData texCoord1D0Element = { VERTEX_ELEMENT_TEXCOORD1D_0 , 4 , 4 , 4 , " TEXCOORD1D_0 " } ; // (not worth compressing)
static const ElementData texCoord1D1Element = { VERTEX_ELEMENT_TEXCOORD1D_1 , 4 , 4 , 4 , " TEXCOORD1D_1 " } ; // (not worth compressing)
static const ElementData texCoord1D2Element = { VERTEX_ELEMENT_TEXCOORD1D_2 , 4 , 4 , 4 , " TEXCOORD1D_2 " } ; // (not worth compressing)
static const ElementData texCoord1D3Element = { VERTEX_ELEMENT_TEXCOORD1D_3 , 4 , 4 , 4 , " TEXCOORD1D_3 " } ; // (not worth compressing)
static const ElementData texCoord1D4Element = { VERTEX_ELEMENT_TEXCOORD1D_4 , 4 , 4 , 4 , " TEXCOORD1D_4 " } ; // (not worth compressing)
static const ElementData texCoord1D5Element = { VERTEX_ELEMENT_TEXCOORD1D_5 , 4 , 4 , 4 , " TEXCOORD1D_5 " } ; // (not worth compressing)
static const ElementData texCoord1D6Element = { VERTEX_ELEMENT_TEXCOORD1D_6 , 4 , 4 , 4 , " TEXCOORD1D_6 " } ; // (not worth compressing)
static const ElementData texCoord1D7Element = { VERTEX_ELEMENT_TEXCOORD1D_7 , 4 , 4 , 4 , " TEXCOORD1D_7 " } ; // (not worth compressing)
static const ElementData texCoord2D0Element = { VERTEX_ELEMENT_TEXCOORD2D_0 , 8 , 8 , 4 , " TEXCOORD2D_0 " } ; // (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData texCoord2D1Element = { VERTEX_ELEMENT_TEXCOORD2D_1 , 8 , 8 , 4 , " TEXCOORD2D_1 " } ; // (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData texCoord2D2Element = { VERTEX_ELEMENT_TEXCOORD2D_2 , 8 , 8 , 4 , " TEXCOORD2D_2 " } ; // (all-but-unused)
static const ElementData texCoord2D3Element = { VERTEX_ELEMENT_TEXCOORD2D_3 , 8 , 8 , 4 , " TEXCOORD2D_3 " } ; // (unused)
static const ElementData texCoord2D4Element = { VERTEX_ELEMENT_TEXCOORD2D_4 , 8 , 8 , 4 , " TEXCOORD2D_4 " } ; // (unused)
static const ElementData texCoord2D5Element = { VERTEX_ELEMENT_TEXCOORD2D_5 , 8 , 8 , 4 , " TEXCOORD2D_5 " } ; // (unused)
static const ElementData texCoord2D6Element = { VERTEX_ELEMENT_TEXCOORD2D_6 , 8 , 8 , 4 , " TEXCOORD2D_6 " } ; // (unused)
static const ElementData texCoord2D7Element = { VERTEX_ELEMENT_TEXCOORD2D_7 , 8 , 8 , 4 , " TEXCOORD2D_7 " } ; // (unused)
static const ElementData texCoord3D0Element = { VERTEX_ELEMENT_TEXCOORD3D_0 , 12 , 12 , 8 , " TEXCOORD3D_0 " } ; // FIXME: used how much? (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData texCoord3D1Element = { VERTEX_ELEMENT_TEXCOORD3D_1 , 12 , 12 , 8 , " TEXCOORD3D_1 " } ; // FIXME: used how much? (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData texCoord3D2Element = { VERTEX_ELEMENT_TEXCOORD3D_2 , 12 , 12 , 8 , " TEXCOORD3D_2 " } ; // FIXME: used how much? (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData texCoord3D3Element = { VERTEX_ELEMENT_TEXCOORD3D_3 , 12 , 12 , 8 , " TEXCOORD3D_3 " } ; // FIXME: used how much? (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData texCoord3D4Element = { VERTEX_ELEMENT_TEXCOORD3D_4 , 12 , 12 , 8 , " TEXCOORD3D_4 " } ; // FIXME: used how much? (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData texCoord3D5Element = { VERTEX_ELEMENT_TEXCOORD3D_5 , 12 , 12 , 8 , " TEXCOORD3D_5 " } ; // FIXME: used how much? (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData texCoord3D6Element = { VERTEX_ELEMENT_TEXCOORD3D_6 , 12 , 12 , 8 , " TEXCOORD3D_6 " } ; // FIXME: used how much? (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData texCoord3D7Element = { VERTEX_ELEMENT_TEXCOORD3D_7 , 12 , 12 , 8 , " TEXCOORD3D_7 " } ; // FIXME: used how much? (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData texCoord4D0Element = { VERTEX_ELEMENT_TEXCOORD4D_0 , 16 , 16 , 8 , " TEXCOORD4D_0 " } ; // FIXME: used how much? (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData texCoord4D1Element = { VERTEX_ELEMENT_TEXCOORD4D_1 , 16 , 16 , 8 , " TEXCOORD4D_1 " } ; // FIXME: used how much? (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData texCoord4D2Element = { VERTEX_ELEMENT_TEXCOORD4D_2 , 16 , 16 , 8 , " TEXCOORD4D_2 " } ; // FIXME: used how much? (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData texCoord4D3Element = { VERTEX_ELEMENT_TEXCOORD4D_3 , 16 , 16 , 8 , " TEXCOORD4D_3 " } ; // FIXME: used how much? (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData texCoord4D4Element = { VERTEX_ELEMENT_TEXCOORD4D_4 , 16 , 16 , 8 , " TEXCOORD4D_4 " } ; // FIXME: used how much? (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData texCoord4D5Element = { VERTEX_ELEMENT_TEXCOORD4D_5 , 16 , 16 , 8 , " TEXCOORD4D_5 " } ; // FIXME: used how much? (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData texCoord4D6Element = { VERTEX_ELEMENT_TEXCOORD4D_6 , 16 , 16 , 8 , " TEXCOORD4D_6 " } ; // FIXME: used how much? (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData texCoord4D7Element = { VERTEX_ELEMENT_TEXCOORD4D_7 , 16 , 16 , 8 , " TEXCOORD4D_7 " } ; // FIXME: used how much? (UNDONE: need vertex shader to take scale, account for clamping)
static const ElementData elementTable [ VERTEX_ELEMENT_NUMELEMENTS ] = { positionElement ,
normalElement ,
colorElement ,
specularElement ,
tangentSElement ,
tangentTElement ,
wrinkleElement ,
boneIndexElement ,
boneWeight1Element , boneWeight2Element , boneWeight3Element , boneWeight4Element ,
userData1Element , userData2Element , userData3Element , userData4Element ,
texCoord1D0Element , texCoord1D1Element , texCoord1D2Element , texCoord1D3Element , texCoord1D4Element , texCoord1D5Element , texCoord1D6Element , texCoord1D7Element ,
texCoord2D0Element , texCoord2D1Element , texCoord2D2Element , texCoord2D3Element , texCoord2D4Element , texCoord2D5Element , texCoord2D6Element , texCoord2D7Element ,
texCoord3D0Element , texCoord3D1Element , texCoord3D2Element , texCoord3D3Element , texCoord3D4Element , texCoord3D5Element , texCoord3D6Element , texCoord3D7Element ,
texCoord4D0Element , texCoord4D1Element , texCoord4D2Element , texCoord4D3Element , texCoord4D4Element , texCoord4D5Element , texCoord4D6Element , texCoord4D7Element ,
} ;
static ConVar mem_vballocspew ( " mem_vballocspew " , " 0 " , FCVAR_CHEAT , " How often to spew vertex buffer allocation stats - 1: every alloc, 2+: every 2+ allocs, 0: off " ) ;
# endif // ENABLE_VB_ALLOC_TRACKER
//-----------------------------------------------------------------------------
// Singleton instance exposed to the engine
//-----------------------------------------------------------------------------
CVBAllocTracker g_VBAllocTrackerShaderAPI ;
EXPOSE_SINGLE_INTERFACE_GLOBALVAR ( CVBAllocTracker , IVBAllocTracker ,
VB_ALLOC_TRACKER_INTERFACE_VERSION , g_VBAllocTrackerShaderAPI ) ;
//-----------------------------------------------------------------------------
//
// VB alloc-tracking code starts here
//
//-----------------------------------------------------------------------------
# if ENABLE_VB_ALLOC_TRACKER
UtlHashFixedHandle_t CVBAllocTracker : : TrackAlloc ( void * buffer , int bufferSize , VertexFormat_t fmt , int numVerts , short allocatorHash )
{
AllocData newData ( buffer , bufferSize , fmt , numVerts , allocatorHash ) ;
2022-02-23 11:50:30 +00:00
UtlHashFixedHandle_t handle = m_VBAllocTable . Insert ( ( intp ) buffer , newData ) ;
2020-04-22 16:56:21 +00:00
if ( handle = = m_VBAllocTable . InvalidHandle ( ) )
{
Warning ( " [VBMEM] VBMemAllocTable hash collision (grow table). \n " ) ;
}
return handle ;
}
bool CVBAllocTracker : : KillAlloc ( void * buffer , int & bufferSize , VertexFormat_t & fmt , int & numVerts , short & allocatorHash )
{
2022-02-23 11:50:30 +00:00
UtlHashFixedHandle_t handle = m_VBAllocTable . Find ( ( intp ) buffer ) ;
2020-04-22 16:56:21 +00:00
if ( handle ! = m_VBAllocTable . InvalidHandle ( ) )
{
AllocData & data = m_VBAllocTable . Element ( handle ) ;
bufferSize = data . m_bufferSize ;
fmt = data . m_fmt ;
numVerts = data . m_numVerts ;
allocatorHash = data . m_allocatorHash ;
m_VBAllocTable . Remove ( handle ) ;
return true ;
}
Warning ( " [VBMEM] VBMemAllocTable failed to find alloc entry... \n " ) ;
return false ;
}
UtlHashFixedHandle_t CVBAllocTracker : : GetCounterHandle ( const char * allocatorName , short allocatorHash )
{
UtlHashFixedHandle_t handle = m_VBCountTable . Find ( allocatorHash ) ;
if ( handle = = m_VBCountTable . InvalidHandle ( ) )
{
CounterData newData ;
Assert ( ( allocatorName ! = NULL ) & & ( allocatorName [ 0 ] ! = 0 ) ) ;
V_strncpy ( newData . m_AllocatorName , allocatorName , CounterData : : MAX_NAME_SIZE ) ;
handle = m_VBCountTable . Insert ( allocatorHash , newData ) ;
m_VBTableNameHashes . Push ( allocatorHash ) ;
}
if ( handle = = m_VBCountTable . InvalidHandle ( ) )
{
Warning ( " [VBMEM] CounterData hash collision (grow table). \n " ) ;
}
return handle ;
}
void CheckForElementTableUpdates ( const ElementData & element )
{
// Ensure that 'elementTable' gets updated if VertexElement_t ever changes:
int tableIndex = & element - & ( elementTable [ 0 ] ) ;
Assert ( tableIndex = = element . element ) ;
if ( tableIndex ! = element . element )
{
static int timesToSpew = 20 ;
if ( timesToSpew > 0 )
{
Warning ( " VertexElement_t structure has changed, ElementData table in cvballoctracker needs updating! \n " ) ;
timesToSpew - - ;
}
}
}
void CVBAllocTracker : : SpewElements ( const char * allocatorName , short nameHash )
{
short allocatorHash = allocatorName ? HashString ( allocatorName ) : nameHash ;
UtlHashFixedHandle_t handle = GetCounterHandle ( allocatorName , allocatorHash ) ;
if ( handle ! = m_VBCountTable . InvalidHandle ( ) )
{
CounterData & data = m_VBCountTable . Element ( handle ) ;
int originalSum = 0 , currentSum = 0 , idealSum = 0 ;
for ( int i = 0 ; i < VERTEX_ELEMENT_NUMELEMENTS ; i + + )
{
CheckForElementTableUpdates ( elementTable [ i ] ) ;
int numCompressed = data . m_elementsCompressed [ i ] ;
int numUncompressed = data . m_elementsUncompressed [ i ] ;
int numVerts = numCompressed + numUncompressed ;
originalSum + = numVerts * elementTable [ i ] . uncompressed ;
currentSum + = numCompressed * elementTable [ i ] . currentCompressed + numUncompressed * elementTable [ i ] . uncompressed ;
idealSum + = numVerts * elementTable [ i ] . idealCompressed ;
}
if ( originalSum > 0 )
{
Msg ( " [VBMEM] ----elements (%s)----: \n " , data . m_AllocatorName ) ;
for ( int i = 0 ; i < VERTEX_ELEMENT_NUMELEMENTS ; i + + )
{
// We count vertices (converted to bytes via elementTable)
int numCompressed = data . m_elementsCompressed [ i ] ;
int numUncompressed = data . m_elementsUncompressed [ i ] ;
int numVerts = numCompressed + numUncompressed ;
const ElementData & elementData = elementTable [ i ] ;
if ( numVerts > 0 )
{
Msg ( " element: %5.2f MB 'U', %5.2f MB 'C', %5.2f MB 'I', %6.2f MB 'D', %s \n " ,
numVerts * elementData . uncompressed / ( 1024.0f * 1024.0f ) ,
( numCompressed * elementData . currentCompressed + numUncompressed * elementData . uncompressed ) / ( 1024.0f * 1024.0f ) ,
numVerts * elementData . idealCompressed / ( 1024.0f * 1024.0f ) ,
- ( numCompressed * elementData . currentCompressed + numUncompressed * elementData . uncompressed - numVerts * elementData . idealCompressed ) / ( 1024.0f * 1024.0f ) ,
elementData . name ) ;
}
}
Msg ( " [VBMEM] total: %5.2f MB 'U', %5.2f MB 'C', %5.2f MB 'I', %6.2f MB 'D' \n " ,
originalSum / ( 1024.0f * 1024.0f ) ,
currentSum / ( 1024.0f * 1024.0f ) ,
idealSum / ( 1024.0f * 1024.0f ) ,
- ( currentSum - idealSum ) / ( 1024.0f * 1024.0f ) ) ;
Msg ( " [VBMEM] ----elements (%s)----: \n " , data . m_AllocatorName ) ;
}
}
}
int CVBAllocTracker : : ComputeVertexSize ( VertexElementMap_t map , VertexFormat_t fmt , bool compressed )
{
int vertexSize = 0 ;
for ( int i = 0 ; i < VERTEX_ELEMENT_NUMELEMENTS ; i + + )
{
const ElementData & element = elementTable [ i ] ;
CheckForElementTableUpdates ( element ) ;
VertexElementMap_t LSB = 1 ;
if ( map & ( LSB < < i ) )
{
vertexSize + = compressed ? element . currentCompressed : element . uncompressed ;
}
}
// On PC (see CVertexBufferBase::ComputeVertexDescription() in meshbase.cpp)
// vertex strides are aligned to 16 bytes:
bool bCacheAlign = ( fmt & VERTEX_FORMAT_USE_EXACT_FORMAT ) = = 0 ;
if ( bCacheAlign & & ( vertexSize > 16 ) & & IsPC ( ) )
{
vertexSize = ( vertexSize + 0xF ) & ( ~ 0xF ) ;
}
return vertexSize ;
}
VertexElementMap_t CVBAllocTracker : : ComputeElementMap ( VertexFormat_t fmt , int vertexSize , bool isDynamic )
{
VertexElementMap_t map = 0 , LSB = 1 ;
if ( fmt & VERTEX_POSITION ) map | = LSB < < VERTEX_ELEMENT_POSITION ;
if ( fmt & VERTEX_NORMAL ) map | = LSB < < VERTEX_ELEMENT_NORMAL ;
if ( fmt & VERTEX_COLOR ) map | = LSB < < VERTEX_ELEMENT_COLOR ;
if ( fmt & VERTEX_SPECULAR ) map | = LSB < < VERTEX_ELEMENT_SPECULAR ;
if ( fmt & VERTEX_TANGENT_S ) map | = LSB < < VERTEX_ELEMENT_TANGENT_S ;
if ( fmt & VERTEX_TANGENT_T ) map | = LSB < < VERTEX_ELEMENT_TANGENT_T ;
if ( fmt & VERTEX_WRINKLE ) map | = LSB < < VERTEX_ELEMENT_WRINKLE ;
if ( fmt & VERTEX_BONE_INDEX ) map | = LSB < < VERTEX_ELEMENT_BONEINDEX ;
int numBones = NumBoneWeights ( fmt ) ;
if ( numBones > 0 ) map | = LSB < < ( VERTEX_ELEMENT_BONEWEIGHTS1 + numBones - 1 ) ;
int userDataSize = UserDataSize ( fmt ) ;
if ( userDataSize > 0 ) map | = LSB < < ( VERTEX_ELEMENT_USERDATA1 + userDataSize - 1 ) ;
for ( int i = 0 ; i < VERTEX_MAX_TEXTURE_COORDINATES ; + + i )
{
VertexElement_t texCoordElements [ 4 ] = { VERTEX_ELEMENT_TEXCOORD1D_0 , VERTEX_ELEMENT_TEXCOORD2D_0 , VERTEX_ELEMENT_TEXCOORD3D_0 , VERTEX_ELEMENT_TEXCOORD4D_0 } ;
int nCoordSize = TexCoordSize ( i , fmt ) ;
if ( nCoordSize > 0 )
{
Assert ( i < 4 ) ;
if ( i < 4 )
{
map | = LSB < < ( texCoordElements [ nCoordSize - 1 ] + i ) ;
}
}
}
if ( map = = 0 )
{
if ( ! isDynamic )
{
// We expect all (non-dynamic) VB allocs to specify a vertex format
// Warning("[VBMEM] unknown vertex format\n");
return 0 ;
}
}
else
{
if ( vertexSize ! = 0 )
{
// Make sure elementTable above matches external computations of vertex size
// FIXME: make this assert dependent on whether the current VB is compressed or not
VertexCompressionType_t compressionType = CompressionType ( fmt ) ;
bool isCompressedAlloc = ( compressionType = = VERTEX_COMPRESSION_ON ) ;
// FIXME: once we've finalised which elements we're compressing for ship, update
// elementTable to reflect that and re-enable this assert for compressed verts
if ( ! isCompressedAlloc )
{
Assert ( vertexSize = = ComputeVertexSize ( map , fmt , isCompressedAlloc ) ) ;
}
}
}
return map ;
}
void CVBAllocTracker : : UpdateElements ( CounterData & data , VertexFormat_t fmt , int numVerts , int vertexSize ,
bool isDynamic , bool isCompressed )
{
VertexElementMap_t map = ComputeElementMap ( fmt , vertexSize , isDynamic ) ;
if ( map ! = 0 )
{
for ( int i = 0 ; i < VERTEX_ELEMENT_NUMELEMENTS ; i + + )
{
// Count vertices (get bytes from our elements table)
VertexElementMap_t LSB = 1 ;
if ( map & ( LSB < < i ) )
{
if ( isCompressed )
data . m_elementsCompressed [ i ] + = numVerts ;
else
data . m_elementsUncompressed [ i ] + = numVerts ;
}
}
}
}
int CVBAllocTracker : : ComputeAlignmentWastage ( int bufferSize )
{
if ( ! IsX360 ( ) )
return 0 ;
// VBs are 4KB-aligned on 360, so we waste thiiiiiis much:
return ( ( 4096 - ( bufferSize & 4095 ) ) & 4095 ) ;
}
void CVBAllocTracker : : AddSaving ( int & alreadySaved , int & yetToSave , const char * allocatorName , VertexElement_t element , Saving_t savingType )
{
UtlHashFixedHandle_t handle = GetCounterHandle ( allocatorName , HashString ( allocatorName ) ) ;
if ( handle ! = m_VBCountTable . InvalidHandle ( ) )
{
CheckForElementTableUpdates ( elementTable [ element ] ) ;
CounterData & counterData = m_VBCountTable . Element ( handle ) ;
const ElementData & elementData = elementTable [ element ] ;
int numVerts = counterData . m_vertCount ;
int numCompressed = counterData . m_elementsCompressed [ element ] ;
int numUncompressed = counterData . m_elementsUncompressed [ element ] ;
switch ( savingType )
{
case SAVING_COMPRESSION :
alreadySaved + = numCompressed * ( elementData . uncompressed - elementData . currentCompressed ) ;
yetToSave + = numUncompressed * ( elementData . uncompressed - elementData . currentCompressed ) ;
break ;
case SAVING_REMOVAL :
alreadySaved + = elementData . uncompressed * ( numVerts - ( numUncompressed + numCompressed ) ) ;
yetToSave + = numUncompressed * elementData . uncompressed + numCompressed * elementData . uncompressed ;
break ;
case SAVING_ALIGNMENT :
yetToSave + = counterData . m_paddingCount ;
break ;
default :
Assert ( 0 ) ;
break ;
}
}
}
void CVBAllocTracker : : SpewExpectedSavings ( void )
{
int alreadySaved = 0 , yetToSave = 0 ;
// We have removed bone weights+indices from static props
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (prop_static) " , VERTEX_ELEMENT_BONEWEIGHTS2 , SAVING_REMOVAL ) ;
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (prop_static) " , VERTEX_ELEMENT_BONEINDEX , SAVING_REMOVAL ) ;
// We have removed vertex colors from all models (color should only ever be in stream1, for static vertex lighting)
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (prop_dynamic) " , VERTEX_ELEMENT_COLOR , SAVING_REMOVAL ) ;
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (prop_static) " , VERTEX_ELEMENT_COLOR , SAVING_REMOVAL ) ;
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (character) " , VERTEX_ELEMENT_COLOR , SAVING_REMOVAL ) ;
// We expect to compress texcoords (DONE: normals+tangents, boneweights) for all studiomdls
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (prop_dynamic) " , VERTEX_ELEMENT_NORMAL , SAVING_COMPRESSION ) ;
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (prop_static) " , VERTEX_ELEMENT_NORMAL , SAVING_COMPRESSION ) ;
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (character) " , VERTEX_ELEMENT_NORMAL , SAVING_COMPRESSION ) ;
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (prop_dynamic) " , VERTEX_ELEMENT_USERDATA4 , SAVING_COMPRESSION ) ;
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (prop_static) " , VERTEX_ELEMENT_USERDATA4 , SAVING_COMPRESSION ) ;
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (character) " , VERTEX_ELEMENT_USERDATA4 , SAVING_COMPRESSION ) ;
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (prop_dynamic) " , VERTEX_ELEMENT_TEXCOORD2D_0 , SAVING_COMPRESSION ) ;
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (prop_static) " , VERTEX_ELEMENT_TEXCOORD2D_0 , SAVING_COMPRESSION ) ;
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (character) " , VERTEX_ELEMENT_TEXCOORD2D_0 , SAVING_COMPRESSION ) ;
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (character) " , VERTEX_ELEMENT_BONEWEIGHTS1 , SAVING_COMPRESSION ) ;
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (character) " , VERTEX_ELEMENT_BONEWEIGHTS2 , SAVING_COMPRESSION ) ;
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (prop_dynamic) " , VERTEX_ELEMENT_BONEWEIGHTS1 , SAVING_COMPRESSION ) ;
AddSaving ( alreadySaved , yetToSave , " R_StudioCreateStaticMeshes (prop_dynamic) " , VERTEX_ELEMENT_BONEWEIGHTS2 , SAVING_COMPRESSION ) ;
// UNDONE: compress bone weights for studiomdls? (issue: possible flex artifacts, but 2xSHORTN probably ok)
// UNDONE: compress positions (+wrinkle) for studiomdls? (issue: possible flex artifacts)
// UNDONE: disable tangents for non-bumped models (issue: forcedmaterialoverride support... don't think that needs tangents, though
// however, if we use UBYTE4 normal+tangent encoding, removing tangents saves nothing)
if ( IsX360 ( ) )
{
// We expect to avoid 4-KB-alignment wastage for color meshes, by allocating them
// out of a single, shared VB and adding per-mesh offsets in vertex shaders
AddSaving ( alreadySaved , yetToSave , " CColorMeshData::CreateResource " , VERTEX_ELEMENT_USERDATA4 , SAVING_ALIGNMENT ) ;
}
Msg ( " [VBMEM] \n " ) ;
Msg ( " [VBMEM] Total expected memory saving by disabling/compressing vertex elements: %6.2f MB \n " , yetToSave / ( 1024.0f * 1024.0f ) ) ;
Msg ( " [VBMEM] ( total memory already saved: %6.2f MB) \n " , alreadySaved / ( 1024.0f * 1024.0f ) ) ;
Msg ( " [VBMEM] - compression of model texcoords, [DONE: normals+tangents, bone weights] \n " ) ;
Msg ( " [VBMEM] - avoidance of 4-KB alignment wastage for color meshes (on 360) \n " ) ;
Msg ( " [VBMEM] - [DONE: removal of unneeded bone weights+indices on models] \n " ) ;
Msg ( " [VBMEM] \n " ) ;
}
void CVBAllocTracker : : UpdateData ( const char * allocatorName , short allocatorKey , int bufferSize , VertexFormat_t fmt ,
int numVerts , int vertexSize , bool isDynamic , bool isCompressed )
{
UtlHashFixedHandle_t handle = GetCounterHandle ( allocatorName , allocatorKey ) ;
if ( handle ! = m_VBCountTable . InvalidHandle ( ) )
{
CounterData & data = m_VBCountTable . Element ( handle ) ;
data . m_memCount + = bufferSize ;
Assert ( data . m_memCount > = 0 ) ;
data . m_vertCount + = numVerts ;
Assert ( data . m_vertCount > = 0 ) ;
data . m_paddingCount + = ( bufferSize < 0 ? - 1 : + 1 ) * ComputeAlignmentWastage ( abs ( bufferSize ) ) ;
UpdateElements ( data , fmt , numVerts , vertexSize , isDynamic , isCompressed ) ;
}
}
const char * CVBAllocTracker : : GetNameString ( int allocatorKey )
{
UtlHashFixedHandle_t handle = GetCounterHandle ( NULL , allocatorKey ) ;
if ( handle ! = m_VBCountTable . InvalidHandle ( ) )
{
CounterData & data = m_VBCountTable . Element ( handle ) ;
return data . m_AllocatorName ;
}
return " null " ;
}
void CVBAllocTracker : : SpewData ( const char * allocatorName , short nameHash )
{
short allocatorHash = allocatorName ? HashString ( allocatorName ) : nameHash ;
UtlHashFixedHandle_t handle = GetCounterHandle ( allocatorName , allocatorHash ) ;
if ( handle ! = m_VBCountTable . InvalidHandle ( ) )
{
CounterData & data = m_VBCountTable . Element ( handle ) ;
if ( data . m_memCount > 0 )
{
Msg ( " [VBMEM] running mem usage: (%5.2f M-verts) %6.2f MB | '%s' \n " ,
data . m_vertCount / ( 1024.0f * 1024.0f ) ,
data . m_memCount / ( 1024.0f * 1024.0f ) ,
data . m_AllocatorName ) ;
}
if ( data . m_paddingCount > 0 )
{
Msg ( " [VBMEM] 4KB VB alignment wastage: %6.2f MB | '%s' \n " ,
data . m_paddingCount / ( 1024.0f * 1024.0f ) ,
data . m_AllocatorName ) ;
}
}
}
void CVBAllocTracker : : SpewDataSometimes ( int inc )
{
static int count = 0 ;
if ( inc < 0 ) count + = inc ;
Assert ( count > = 0 ) ;
int period = mem_vballocspew . GetInt ( ) ;
if ( period > = 1 )
{
if ( ( count % period ) = = 0 )
{
Msg ( " [VBMEM] Status after %d VB allocs: \n " , count ) ;
//#define ROUND_UP( _x_ ) ( ( ( _x_ ) + 31 ) & 31 )
//Msg( "[VBMEM] Conservative estimate of mem used to track allocs: %d\n", 4096*ROUND_UP( 4 + sizeof( CUtlPtrLinkedList<AllocData> ) ) + count*ROUND_UP( sizeof( AllocData ) + 8 ) );
SpewData ( " total_static " ) ;
SpewData ( " unknown " ) ;
}
}
if ( inc > 0 ) count + = inc ;
}
void CVBAllocTracker : : DumpVBAllocs ( )
{
m_VBAllocMutex . Lock ( ) ;
Msg ( " [VBMEM] ----running totals---- \n " ) ;
for ( int i = ( m_VBTableNameHashes . Count ( ) - 1 ) ; i > = 0 ; i - - )
{
short nameHash = m_VBTableNameHashes . Element ( i ) ;
SpewElements ( NULL , nameHash ) ;
}
Msg ( " [VBMEM] \n " ) ;
Msg ( " [VBMEM] 'U' - original memory usage (all vertices uncompressed) \n " ) ;
Msg ( " [VBMEM] 'C' - current memory usage (some compression) \n " ) ;
Msg ( " [VBMEM] 'I' - ideal memory usage (all verts maximally compressed) \n " ) ;
Msg ( " [VBMEM] 'D' - difference between C and I (-> how much more compression could save) \n " ) ;
Msg ( " [VBMEM] 'W' - memory wasted due to 4-KB vertex buffer alignment \n " ) ;
Msg ( " [VBMEM] \n " ) ;
for ( int i = ( m_VBTableNameHashes . Count ( ) - 1 ) ; i > = 0 ; i - - )
{
short nameHash = m_VBTableNameHashes . Element ( i ) ;
SpewData ( NULL , nameHash ) ;
}
SpewExpectedSavings ( ) ;
Msg ( " [VBMEM] ----running totals---- \n " ) ;
m_VBAllocMutex . Unlock ( ) ;
}
# endif // ENABLE_VB_ALLOC_TRACKER
void CVBAllocTracker : : CountVB ( void * buffer , bool isDynamic , int bufferSize , int vertexSize , VertexFormat_t fmt )
{
# if ENABLE_VB_ALLOC_TRACKER
m_VBAllocMutex . Lock ( ) ;
// Update VB memory counts for the relevant allocation type
// (NOTE: we have 'unknown', 'dynamic' and 'total' counts)
const char * allocatorName = ( m_MeshAllocatorName [ 0 ] = = 0 ) ? " unknown " : m_MeshAllocatorName ;
if ( isDynamic ) allocatorName = " total_dynamic " ;
int numVerts = ( vertexSize > 0 ) ? ( bufferSize / vertexSize ) : 0 ;
short totalStaticKey = HashString ( " total_static " ) ;
short key = HashString ( allocatorName ) ;
bool isCompressed = ( VERTEX_COMPRESSION_NONE ! = CompressionType ( fmt ) ) ;
if ( m_MeshAllocatorName [ 0 ] = = 0 )
{
Warning ( " [VBMEM] unknown allocation! \n " ) ;
}
// Add to the VB memory counters
TrackAlloc ( buffer , bufferSize , fmt , numVerts , key ) ;
if ( ! isDynamic )
{
// Keep dynamic allocs out of the total (dynamic VBs don't get compressed)
UpdateData ( " total_static " , totalStaticKey , bufferSize , fmt , numVerts , vertexSize , isDynamic , isCompressed ) ;
}
UpdateData ( allocatorName , key , bufferSize , fmt , numVerts , vertexSize , isDynamic , isCompressed ) ;
if ( m_bSuperSpew )
{
// Spew every alloc
Msg ( " [VBMEM] VB-alloc | %6.2f MB | %s | %s \n " , bufferSize / ( 1024.0f * 1024.0f ) , ( isDynamic ? " DYNamic " : " STAtic " ) , allocatorName ) ;
SpewData ( allocatorName ) ;
}
SpewDataSometimes ( + 1 ) ;
m_VBAllocMutex . Unlock ( ) ;
# endif // ENABLE_VB_ALLOC_TRACKER
}
void CVBAllocTracker : : UnCountVB ( void * buffer )
{
# if ENABLE_VB_ALLOC_TRACKER
m_VBAllocMutex . Lock ( ) ;
short totalKey = HashString ( " total_static " ) ;
short dynamicKey = HashString ( " total_dynamic " ) ;
int bufferSize ;
VertexFormat_t fmt ;
int numVerts ;
short key ;
// We have to store allocation data because the caller often doesn't know what it alloc'd :o/
if ( KillAlloc ( buffer , bufferSize , fmt , numVerts , key ) )
{
bool isCompressed = ( VERTEX_COMPRESSION_NONE ! = CompressionType ( fmt ) ) ;
bool isDynamic = ( key = = dynamicKey ) ;
// Subtract from the VB memory counters
if ( ! isDynamic )
{
UpdateData ( NULL , totalKey , - bufferSize , fmt , - numVerts , 0 , isDynamic , isCompressed ) ;
}
UpdateData ( NULL , key , - bufferSize , fmt , - numVerts , 0 , isDynamic , isCompressed ) ;
const char * nameString = GetNameString ( key ) ;
if ( m_bSuperSpew )
{
Msg ( " [VBMEM] VB-free | %6.2f MB | %s | %s \n " , bufferSize / ( 1024.0f * 1024.0f ) , ( isDynamic ? " DYNamic " : " STAtic " ) , nameString ) ;
SpewData ( nameString ) ;
}
SpewDataSometimes ( - 1 ) ;
}
m_VBAllocMutex . Unlock ( ) ;
# endif // ENABLE_VB_ALLOC_TRACKER
}
bool CVBAllocTracker : : TrackMeshAllocations ( const char * allocatorName )
{
# if ENABLE_VB_ALLOC_TRACKER
// Tracks mesh allocations by name (set this before an alloc, clear it after)
if ( m_MeshAllocatorName [ 0 ] )
{
return true ;
}
m_VBAllocMutex . Lock ( ) ;
if ( allocatorName )
{
Assert ( m_MeshAllocatorName [ 0 ] = = 0 ) ;
V_strncpy ( m_MeshAllocatorName , allocatorName , MAX_ALLOCATOR_NAME_SIZE ) ;
}
else
{
m_MeshAllocatorName [ 0 ] = 0 ;
}
m_VBAllocMutex . Unlock ( ) ;
# endif // ENABLE_VB_ALLOC_TRACKER
return false ;
}
# ifndef RETAIL
static void CC_DumpVBMemAllocs ( )
{
# if ( ENABLE_VB_ALLOC_TRACKER == 0 )
Warning ( " ENABLE_VB_ALLOC_TRACKER must be 1 to enable VB mem alloc tracking \n " ) ;
# else
g_VBAllocTrackerShaderAPI . DumpVBAllocs ( ) ;
# endif
}
static ConCommand mem_dumpvballocs ( " mem_dumpvballocs " , CC_DumpVBMemAllocs , " Dump VB memory allocation stats. " , FCVAR_CHEAT ) ;
# endif // RETAIL