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-rw-r--r--src/3rdparty/angle/src/libGLESv2/VertexDataManager.cpp783
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diff --git a/src/3rdparty/angle/src/libGLESv2/VertexDataManager.cpp b/src/3rdparty/angle/src/libGLESv2/VertexDataManager.cpp
new file mode 100644
index 0000000000..32c40182d3
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+++ b/src/3rdparty/angle/src/libGLESv2/VertexDataManager.cpp
@@ -0,0 +1,783 @@
+//
+// Copyright (c) 2002-2012 The ANGLE Project Authors. All rights reserved.
+// Use of this source code is governed by a BSD-style license that can be
+// found in the LICENSE file.
+//
+
+// VertexDataManager.h: Defines the VertexDataManager, a class that
+// runs the Buffer translation process.
+
+#include "libGLESv2/VertexDataManager.h"
+
+#include "common/debug.h"
+
+#include "libGLESv2/Buffer.h"
+#include "libGLESv2/Program.h"
+#include "libGLESv2/ProgramBinary.h"
+#include "libGLESv2/main.h"
+
+#include "libGLESv2/vertexconversion.h"
+#include "libGLESv2/IndexDataManager.h"
+
+namespace
+{
+ enum { INITIAL_STREAM_BUFFER_SIZE = 1024*1024 };
+ // This has to be at least 4k or else it fails on ATI cards.
+ enum { CONSTANT_VERTEX_BUFFER_SIZE = 4096 };
+}
+
+namespace gl
+{
+unsigned int VertexBuffer::mCurrentSerial = 1;
+
+int elementsInBuffer(const VertexAttribute &attribute, int size)
+{
+ int stride = attribute.stride();
+ return (size - attribute.mOffset % stride + (stride - attribute.typeSize())) / stride;
+}
+
+VertexDataManager::VertexDataManager(Context *context, IDirect3DDevice9 *device) : mContext(context), mDevice(device)
+{
+ for (int i = 0; i < MAX_VERTEX_ATTRIBS; i++)
+ {
+ mDirtyCurrentValue[i] = true;
+ mCurrentValueBuffer[i] = NULL;
+ mCurrentValueOffsets[i] = 0;
+ }
+
+ const D3DCAPS9 &caps = context->getDeviceCaps();
+ checkVertexCaps(caps.DeclTypes);
+
+ mStreamingBuffer = new StreamingVertexBuffer(mDevice, INITIAL_STREAM_BUFFER_SIZE);
+
+ if (!mStreamingBuffer)
+ {
+ ERR("Failed to allocate the streaming vertex buffer.");
+ }
+}
+
+VertexDataManager::~VertexDataManager()
+{
+ delete mStreamingBuffer;
+
+ for (int i = 0; i < MAX_VERTEX_ATTRIBS; i++)
+ {
+ delete mCurrentValueBuffer[i];
+ }
+}
+
+std::size_t VertexDataManager::writeAttributeData(ArrayVertexBuffer *vertexBuffer, GLint start, GLsizei count, const VertexAttribute &attribute, GLsizei instances)
+{
+ Buffer *buffer = attribute.mBoundBuffer.get();
+
+ int inputStride = attribute.stride();
+ int elementSize = attribute.typeSize();
+ const FormatConverter &converter = formatConverter(attribute);
+ std::size_t streamOffset = 0;
+
+ void *output = NULL;
+
+ if (vertexBuffer)
+ {
+ output = vertexBuffer->map(attribute, spaceRequired(attribute, count, instances), &streamOffset);
+ }
+
+ if (output == NULL)
+ {
+ ERR("Failed to map vertex buffer.");
+ return -1;
+ }
+
+ const char *input = NULL;
+
+ if (buffer)
+ {
+ int offset = attribute.mOffset;
+
+ input = static_cast<const char*>(buffer->data()) + offset;
+ }
+ else
+ {
+ input = static_cast<const char*>(attribute.mPointer);
+ }
+
+ if (instances == 0 || attribute.mDivisor == 0)
+ {
+ input += inputStride * start;
+ }
+
+ if (converter.identity && inputStride == elementSize)
+ {
+ memcpy(output, input, count * inputStride);
+ }
+ else
+ {
+ converter.convertArray(input, inputStride, count, output);
+ }
+
+ vertexBuffer->unmap();
+
+ return streamOffset;
+}
+
+GLenum VertexDataManager::prepareVertexData(GLint start, GLsizei count, TranslatedAttribute *translated, GLsizei instances)
+{
+ if (!mStreamingBuffer)
+ {
+ return GL_OUT_OF_MEMORY;
+ }
+
+ const VertexAttributeArray &attribs = mContext->getVertexAttributes();
+ ProgramBinary *programBinary = mContext->getCurrentProgramBinary();
+
+ for (int attributeIndex = 0; attributeIndex < MAX_VERTEX_ATTRIBS; attributeIndex++)
+ {
+ translated[attributeIndex].active = (programBinary->getSemanticIndex(attributeIndex) != -1);
+ }
+
+ // Determine the required storage size per used buffer, and invalidate static buffers that don't contain matching attributes
+ for (int i = 0; i < MAX_VERTEX_ATTRIBS; i++)
+ {
+ if (translated[i].active && attribs[i].mArrayEnabled)
+ {
+ Buffer *buffer = attribs[i].mBoundBuffer.get();
+ StaticVertexBuffer *staticBuffer = buffer ? buffer->getStaticVertexBuffer() : NULL;
+
+ if (staticBuffer)
+ {
+ if (staticBuffer->size() == 0)
+ {
+ int totalCount = elementsInBuffer(attribs[i], buffer->size());
+ staticBuffer->addRequiredSpace(spaceRequired(attribs[i], totalCount, 0));
+ }
+ else if (staticBuffer->lookupAttribute(attribs[i]) == -1)
+ {
+ // This static buffer doesn't have matching attributes, so fall back to using the streaming buffer
+ // Add the space of all previous attributes belonging to the invalidated static buffer to the streaming buffer
+ for (int previous = 0; previous < i; previous++)
+ {
+ if (translated[previous].active && attribs[previous].mArrayEnabled)
+ {
+ Buffer *previousBuffer = attribs[previous].mBoundBuffer.get();
+ StaticVertexBuffer *previousStaticBuffer = previousBuffer ? previousBuffer->getStaticVertexBuffer() : NULL;
+
+ if (staticBuffer == previousStaticBuffer)
+ {
+ mStreamingBuffer->addRequiredSpace(spaceRequired(attribs[previous], count, instances));
+ }
+ }
+ }
+
+ mStreamingBuffer->addRequiredSpace(spaceRequired(attribs[i], count, instances));
+
+ buffer->invalidateStaticData();
+ }
+ }
+ else
+ {
+ mStreamingBuffer->addRequiredSpace(spaceRequired(attribs[i], count, instances));
+ }
+ }
+ }
+
+ // Reserve the required space per used buffer
+ for (int i = 0; i < MAX_VERTEX_ATTRIBS; i++)
+ {
+ if (translated[i].active && attribs[i].mArrayEnabled)
+ {
+ Buffer *buffer = attribs[i].mBoundBuffer.get();
+ ArrayVertexBuffer *staticBuffer = buffer ? buffer->getStaticVertexBuffer() : NULL;
+ ArrayVertexBuffer *vertexBuffer = staticBuffer ? staticBuffer : mStreamingBuffer;
+
+ if (vertexBuffer)
+ {
+ vertexBuffer->reserveRequiredSpace();
+ }
+ }
+ }
+
+ // Perform the vertex data translations
+ for (int i = 0; i < MAX_VERTEX_ATTRIBS; i++)
+ {
+ if (translated[i].active)
+ {
+ if (attribs[i].mArrayEnabled)
+ {
+ Buffer *buffer = attribs[i].mBoundBuffer.get();
+
+ if (!buffer && attribs[i].mPointer == NULL)
+ {
+ // This is an application error that would normally result in a crash, but we catch it and return an error
+ ERR("An enabled vertex array has no buffer and no pointer.");
+ return GL_INVALID_OPERATION;
+ }
+
+ const FormatConverter &converter = formatConverter(attribs[i]);
+
+ StaticVertexBuffer *staticBuffer = buffer ? buffer->getStaticVertexBuffer() : NULL;
+ ArrayVertexBuffer *vertexBuffer = staticBuffer ? staticBuffer : static_cast<ArrayVertexBuffer*>(mStreamingBuffer);
+
+ std::size_t streamOffset = -1;
+
+ if (staticBuffer)
+ {
+ streamOffset = staticBuffer->lookupAttribute(attribs[i]);
+
+ if (streamOffset == -1)
+ {
+ // Convert the entire buffer
+ int totalCount = elementsInBuffer(attribs[i], buffer->size());
+ int startIndex = attribs[i].mOffset / attribs[i].stride();
+
+ streamOffset = writeAttributeData(staticBuffer, -startIndex, totalCount, attribs[i], 0);
+ }
+
+ if (streamOffset != -1)
+ {
+ streamOffset += (attribs[i].mOffset / attribs[i].stride()) * converter.outputElementSize;
+
+ if (instances == 0 || attribs[i].mDivisor == 0)
+ {
+ streamOffset += start * converter.outputElementSize;
+ }
+ }
+ }
+ else
+ {
+ streamOffset = writeAttributeData(mStreamingBuffer, start, count, attribs[i], instances);
+ }
+
+ if (streamOffset == -1)
+ {
+ return GL_OUT_OF_MEMORY;
+ }
+
+ translated[i].vertexBuffer = vertexBuffer->getBuffer();
+ translated[i].serial = vertexBuffer->getSerial();
+ translated[i].divisor = attribs[i].mDivisor;
+
+ translated[i].type = converter.d3dDeclType;
+ translated[i].stride = converter.outputElementSize;
+ translated[i].offset = streamOffset;
+ }
+ else
+ {
+ if (!mCurrentValueBuffer[i])
+ {
+ mCurrentValueBuffer[i] = new StreamingVertexBuffer(mDevice, CONSTANT_VERTEX_BUFFER_SIZE);
+ }
+
+ StreamingVertexBuffer *buffer = mCurrentValueBuffer[i];
+
+ if (mDirtyCurrentValue[i])
+ {
+ const int requiredSpace = 4 * sizeof(float);
+ buffer->addRequiredSpace(requiredSpace);
+ buffer->reserveRequiredSpace();
+ float *data = static_cast<float*>(buffer->map(VertexAttribute(), requiredSpace, &mCurrentValueOffsets[i]));
+ if (data)
+ {
+ data[0] = attribs[i].mCurrentValue[0];
+ data[1] = attribs[i].mCurrentValue[1];
+ data[2] = attribs[i].mCurrentValue[2];
+ data[3] = attribs[i].mCurrentValue[3];
+ buffer->unmap();
+ mDirtyCurrentValue[i] = false;
+ }
+ }
+
+ translated[i].vertexBuffer = mCurrentValueBuffer[i]->getBuffer();
+ translated[i].serial = mCurrentValueBuffer[i]->getSerial();
+ translated[i].divisor = 0;
+
+ translated[i].type = D3DDECLTYPE_FLOAT4;
+ translated[i].stride = 0;
+ translated[i].offset = mCurrentValueOffsets[i];
+ }
+ }
+ }
+
+ for (int i = 0; i < MAX_VERTEX_ATTRIBS; i++)
+ {
+ if (translated[i].active && attribs[i].mArrayEnabled)
+ {
+ Buffer *buffer = attribs[i].mBoundBuffer.get();
+
+ if (buffer)
+ {
+ buffer->promoteStaticUsage(count * attribs[i].typeSize());
+ }
+ }
+ }
+
+ return GL_NO_ERROR;
+}
+
+std::size_t VertexDataManager::spaceRequired(const VertexAttribute &attrib, std::size_t count, GLsizei instances) const
+{
+ size_t elementSize = formatConverter(attrib).outputElementSize;
+
+ if (instances == 0 || attrib.mDivisor == 0)
+ {
+ return elementSize * count;
+ }
+ else
+ {
+ return elementSize * ((instances + attrib.mDivisor - 1) / attrib.mDivisor);
+ }
+}
+
+// Mapping from OpenGL-ES vertex attrib type to D3D decl type:
+//
+// BYTE SHORT (Cast)
+// BYTE-norm FLOAT (Normalize) (can't be exactly represented as SHORT-norm)
+// UNSIGNED_BYTE UBYTE4 (Identity) or SHORT (Cast)
+// UNSIGNED_BYTE-norm UBYTE4N (Identity) or FLOAT (Normalize)
+// SHORT SHORT (Identity)
+// SHORT-norm SHORT-norm (Identity) or FLOAT (Normalize)
+// UNSIGNED_SHORT FLOAT (Cast)
+// UNSIGNED_SHORT-norm USHORT-norm (Identity) or FLOAT (Normalize)
+// FIXED (not in WebGL) FLOAT (FixedToFloat)
+// FLOAT FLOAT (Identity)
+
+// GLToCType maps from GL type (as GLenum) to the C typedef.
+template <GLenum GLType> struct GLToCType { };
+
+template <> struct GLToCType<GL_BYTE> { typedef GLbyte type; };
+template <> struct GLToCType<GL_UNSIGNED_BYTE> { typedef GLubyte type; };
+template <> struct GLToCType<GL_SHORT> { typedef GLshort type; };
+template <> struct GLToCType<GL_UNSIGNED_SHORT> { typedef GLushort type; };
+template <> struct GLToCType<GL_FIXED> { typedef GLuint type; };
+template <> struct GLToCType<GL_FLOAT> { typedef GLfloat type; };
+
+// This differs from D3DDECLTYPE in that it is unsized. (Size expansion is applied last.)
+enum D3DVertexType
+{
+ D3DVT_FLOAT,
+ D3DVT_SHORT,
+ D3DVT_SHORT_NORM,
+ D3DVT_UBYTE,
+ D3DVT_UBYTE_NORM,
+ D3DVT_USHORT_NORM
+};
+
+// D3DToCType maps from D3D vertex type (as enum D3DVertexType) to the corresponding C type.
+template <unsigned int D3DType> struct D3DToCType { };
+
+template <> struct D3DToCType<D3DVT_FLOAT> { typedef float type; };
+template <> struct D3DToCType<D3DVT_SHORT> { typedef short type; };
+template <> struct D3DToCType<D3DVT_SHORT_NORM> { typedef short type; };
+template <> struct D3DToCType<D3DVT_UBYTE> { typedef unsigned char type; };
+template <> struct D3DToCType<D3DVT_UBYTE_NORM> { typedef unsigned char type; };
+template <> struct D3DToCType<D3DVT_USHORT_NORM> { typedef unsigned short type; };
+
+// Encode the type/size combinations that D3D permits. For each type/size it expands to a widener that will provide the appropriate final size.
+template <unsigned int type, int size>
+struct WidenRule
+{
+};
+
+template <int size> struct WidenRule<D3DVT_FLOAT, size> : gl::NoWiden<size> { };
+template <int size> struct WidenRule<D3DVT_SHORT, size> : gl::WidenToEven<size> { };
+template <int size> struct WidenRule<D3DVT_SHORT_NORM, size> : gl::WidenToEven<size> { };
+template <int size> struct WidenRule<D3DVT_UBYTE, size> : gl::WidenToFour<size> { };
+template <int size> struct WidenRule<D3DVT_UBYTE_NORM, size> : gl::WidenToFour<size> { };
+template <int size> struct WidenRule<D3DVT_USHORT_NORM, size> : gl::WidenToEven<size> { };
+
+// VertexTypeFlags encodes the D3DCAPS9::DeclType flag and vertex declaration flag for each D3D vertex type & size combination.
+template <unsigned int d3dtype, int size>
+struct VertexTypeFlags
+{
+};
+
+template <unsigned int _capflag, unsigned int _declflag>
+struct VertexTypeFlagsHelper
+{
+ enum { capflag = _capflag };
+ enum { declflag = _declflag };
+};
+
+template <> struct VertexTypeFlags<D3DVT_FLOAT, 1> : VertexTypeFlagsHelper<0, D3DDECLTYPE_FLOAT1> { };
+template <> struct VertexTypeFlags<D3DVT_FLOAT, 2> : VertexTypeFlagsHelper<0, D3DDECLTYPE_FLOAT2> { };
+template <> struct VertexTypeFlags<D3DVT_FLOAT, 3> : VertexTypeFlagsHelper<0, D3DDECLTYPE_FLOAT3> { };
+template <> struct VertexTypeFlags<D3DVT_FLOAT, 4> : VertexTypeFlagsHelper<0, D3DDECLTYPE_FLOAT4> { };
+template <> struct VertexTypeFlags<D3DVT_SHORT, 2> : VertexTypeFlagsHelper<0, D3DDECLTYPE_SHORT2> { };
+template <> struct VertexTypeFlags<D3DVT_SHORT, 4> : VertexTypeFlagsHelper<0, D3DDECLTYPE_SHORT4> { };
+template <> struct VertexTypeFlags<D3DVT_SHORT_NORM, 2> : VertexTypeFlagsHelper<D3DDTCAPS_SHORT2N, D3DDECLTYPE_SHORT2N> { };
+template <> struct VertexTypeFlags<D3DVT_SHORT_NORM, 4> : VertexTypeFlagsHelper<D3DDTCAPS_SHORT4N, D3DDECLTYPE_SHORT4N> { };
+template <> struct VertexTypeFlags<D3DVT_UBYTE, 4> : VertexTypeFlagsHelper<D3DDTCAPS_UBYTE4, D3DDECLTYPE_UBYTE4> { };
+template <> struct VertexTypeFlags<D3DVT_UBYTE_NORM, 4> : VertexTypeFlagsHelper<D3DDTCAPS_UBYTE4N, D3DDECLTYPE_UBYTE4N> { };
+template <> struct VertexTypeFlags<D3DVT_USHORT_NORM, 2> : VertexTypeFlagsHelper<D3DDTCAPS_USHORT2N, D3DDECLTYPE_USHORT2N> { };
+template <> struct VertexTypeFlags<D3DVT_USHORT_NORM, 4> : VertexTypeFlagsHelper<D3DDTCAPS_USHORT4N, D3DDECLTYPE_USHORT4N> { };
+
+
+// VertexTypeMapping maps GL type & normalized flag to preferred and fallback D3D vertex types (as D3DVertexType enums).
+template <GLenum GLtype, bool normalized>
+struct VertexTypeMapping
+{
+};
+
+template <D3DVertexType Preferred, D3DVertexType Fallback = Preferred>
+struct VertexTypeMappingBase
+{
+ enum { preferred = Preferred };
+ enum { fallback = Fallback };
+};
+
+template <> struct VertexTypeMapping<GL_BYTE, false> : VertexTypeMappingBase<D3DVT_SHORT> { }; // Cast
+template <> struct VertexTypeMapping<GL_BYTE, true> : VertexTypeMappingBase<D3DVT_FLOAT> { }; // Normalize
+template <> struct VertexTypeMapping<GL_UNSIGNED_BYTE, false> : VertexTypeMappingBase<D3DVT_UBYTE, D3DVT_FLOAT> { }; // Identity, Cast
+template <> struct VertexTypeMapping<GL_UNSIGNED_BYTE, true> : VertexTypeMappingBase<D3DVT_UBYTE_NORM, D3DVT_FLOAT> { }; // Identity, Normalize
+template <> struct VertexTypeMapping<GL_SHORT, false> : VertexTypeMappingBase<D3DVT_SHORT> { }; // Identity
+template <> struct VertexTypeMapping<GL_SHORT, true> : VertexTypeMappingBase<D3DVT_SHORT_NORM, D3DVT_FLOAT> { }; // Cast, Normalize
+template <> struct VertexTypeMapping<GL_UNSIGNED_SHORT, false> : VertexTypeMappingBase<D3DVT_FLOAT> { }; // Cast
+template <> struct VertexTypeMapping<GL_UNSIGNED_SHORT, true> : VertexTypeMappingBase<D3DVT_USHORT_NORM, D3DVT_FLOAT> { }; // Cast, Normalize
+template <bool normalized> struct VertexTypeMapping<GL_FIXED, normalized> : VertexTypeMappingBase<D3DVT_FLOAT> { }; // FixedToFloat
+template <bool normalized> struct VertexTypeMapping<GL_FLOAT, normalized> : VertexTypeMappingBase<D3DVT_FLOAT> { }; // Identity
+
+
+// Given a GL type & norm flag and a D3D type, ConversionRule provides the type conversion rule (Cast, Normalize, Identity, FixedToFloat).
+// The conversion rules themselves are defined in vertexconversion.h.
+
+// Almost all cases are covered by Cast (including those that are actually Identity since Cast<T,T> knows it's an identity mapping).
+template <GLenum fromType, bool normalized, unsigned int toType>
+struct ConversionRule : gl::Cast<typename GLToCType<fromType>::type, typename D3DToCType<toType>::type>
+{
+};
+
+// All conversions from normalized types to float use the Normalize operator.
+template <GLenum fromType> struct ConversionRule<fromType, true, D3DVT_FLOAT> : gl::Normalize<typename GLToCType<fromType>::type> { };
+
+// Use a full specialisation for this so that it preferentially matches ahead of the generic normalize-to-float rules.
+template <> struct ConversionRule<GL_FIXED, true, D3DVT_FLOAT> : gl::FixedToFloat<GLint, 16> { };
+template <> struct ConversionRule<GL_FIXED, false, D3DVT_FLOAT> : gl::FixedToFloat<GLint, 16> { };
+
+// A 2-stage construction is used for DefaultVertexValues because float must use SimpleDefaultValues (i.e. 0/1)
+// whether it is normalized or not.
+template <class T, bool normalized>
+struct DefaultVertexValuesStage2
+{
+};
+
+template <class T> struct DefaultVertexValuesStage2<T, true> : gl::NormalizedDefaultValues<T> { };
+template <class T> struct DefaultVertexValuesStage2<T, false> : gl::SimpleDefaultValues<T> { };
+
+// Work out the default value rule for a D3D type (expressed as the C type) and
+template <class T, bool normalized>
+struct DefaultVertexValues : DefaultVertexValuesStage2<T, normalized>
+{
+};
+
+template <bool normalized> struct DefaultVertexValues<float, normalized> : gl::SimpleDefaultValues<float> { };
+
+// Policy rules for use with Converter, to choose whether to use the preferred or fallback conversion.
+// The fallback conversion produces an output that all D3D9 devices must support.
+template <class T> struct UsePreferred { enum { type = T::preferred }; };
+template <class T> struct UseFallback { enum { type = T::fallback }; };
+
+// Converter ties it all together. Given an OpenGL type/norm/size and choice of preferred/fallback conversion,
+// it provides all the members of the appropriate VertexDataConverter, the D3DCAPS9::DeclTypes flag in cap flag
+// and the D3DDECLTYPE member needed for the vertex declaration in declflag.
+template <GLenum fromType, bool normalized, int size, template <class T> class PreferenceRule>
+struct Converter
+ : gl::VertexDataConverter<typename GLToCType<fromType>::type,
+ WidenRule<PreferenceRule< VertexTypeMapping<fromType, normalized> >::type, size>,
+ ConversionRule<fromType,
+ normalized,
+ PreferenceRule< VertexTypeMapping<fromType, normalized> >::type>,
+ DefaultVertexValues<typename D3DToCType<PreferenceRule< VertexTypeMapping<fromType, normalized> >::type>::type, normalized > >
+{
+private:
+ enum { d3dtype = PreferenceRule< VertexTypeMapping<fromType, normalized> >::type };
+ enum { d3dsize = WidenRule<d3dtype, size>::finalWidth };
+
+public:
+ enum { capflag = VertexTypeFlags<d3dtype, d3dsize>::capflag };
+ enum { declflag = VertexTypeFlags<d3dtype, d3dsize>::declflag };
+};
+
+// Initialise a TranslationInfo
+#define TRANSLATION(type, norm, size, preferred) \
+ { \
+ Converter<type, norm, size, preferred>::identity, \
+ Converter<type, norm, size, preferred>::finalSize, \
+ Converter<type, norm, size, preferred>::convertArray, \
+ static_cast<D3DDECLTYPE>(Converter<type, norm, size, preferred>::declflag) \
+ }
+
+#define TRANSLATION_FOR_TYPE_NORM_SIZE(type, norm, size) \
+ { \
+ Converter<type, norm, size, UsePreferred>::capflag, \
+ TRANSLATION(type, norm, size, UsePreferred), \
+ TRANSLATION(type, norm, size, UseFallback) \
+ }
+
+#define TRANSLATIONS_FOR_TYPE(type) \
+ { \
+ { TRANSLATION_FOR_TYPE_NORM_SIZE(type, false, 1), TRANSLATION_FOR_TYPE_NORM_SIZE(type, false, 2), TRANSLATION_FOR_TYPE_NORM_SIZE(type, false, 3), TRANSLATION_FOR_TYPE_NORM_SIZE(type, false, 4) }, \
+ { TRANSLATION_FOR_TYPE_NORM_SIZE(type, true, 1), TRANSLATION_FOR_TYPE_NORM_SIZE(type, true, 2), TRANSLATION_FOR_TYPE_NORM_SIZE(type, true, 3), TRANSLATION_FOR_TYPE_NORM_SIZE(type, true, 4) }, \
+ }
+
+#define TRANSLATIONS_FOR_TYPE_NO_NORM(type) \
+ { \
+ { TRANSLATION_FOR_TYPE_NORM_SIZE(type, false, 1), TRANSLATION_FOR_TYPE_NORM_SIZE(type, false, 2), TRANSLATION_FOR_TYPE_NORM_SIZE(type, false, 3), TRANSLATION_FOR_TYPE_NORM_SIZE(type, false, 4) }, \
+ { TRANSLATION_FOR_TYPE_NORM_SIZE(type, false, 1), TRANSLATION_FOR_TYPE_NORM_SIZE(type, false, 2), TRANSLATION_FOR_TYPE_NORM_SIZE(type, false, 3), TRANSLATION_FOR_TYPE_NORM_SIZE(type, false, 4) }, \
+ }
+
+const VertexDataManager::TranslationDescription VertexDataManager::mPossibleTranslations[NUM_GL_VERTEX_ATTRIB_TYPES][2][4] = // [GL types as enumerated by typeIndex()][normalized][size-1]
+{
+ TRANSLATIONS_FOR_TYPE(GL_BYTE),
+ TRANSLATIONS_FOR_TYPE(GL_UNSIGNED_BYTE),
+ TRANSLATIONS_FOR_TYPE(GL_SHORT),
+ TRANSLATIONS_FOR_TYPE(GL_UNSIGNED_SHORT),
+ TRANSLATIONS_FOR_TYPE_NO_NORM(GL_FIXED),
+ TRANSLATIONS_FOR_TYPE_NO_NORM(GL_FLOAT)
+};
+
+void VertexDataManager::checkVertexCaps(DWORD declTypes)
+{
+ for (unsigned int i = 0; i < NUM_GL_VERTEX_ATTRIB_TYPES; i++)
+ {
+ for (unsigned int j = 0; j < 2; j++)
+ {
+ for (unsigned int k = 0; k < 4; k++)
+ {
+ if (mPossibleTranslations[i][j][k].capsFlag == 0 || (declTypes & mPossibleTranslations[i][j][k].capsFlag) != 0)
+ {
+ mAttributeTypes[i][j][k] = mPossibleTranslations[i][j][k].preferredConversion;
+ }
+ else
+ {
+ mAttributeTypes[i][j][k] = mPossibleTranslations[i][j][k].fallbackConversion;
+ }
+ }
+ }
+ }
+}
+
+// This is used to index mAttributeTypes and mPossibleTranslations.
+unsigned int VertexDataManager::typeIndex(GLenum type) const
+{
+ switch (type)
+ {
+ case GL_BYTE: return 0;
+ case GL_UNSIGNED_BYTE: return 1;
+ case GL_SHORT: return 2;
+ case GL_UNSIGNED_SHORT: return 3;
+ case GL_FIXED: return 4;
+ case GL_FLOAT: return 5;
+
+ default: UNREACHABLE(); return 5;
+ }
+}
+
+VertexBuffer::VertexBuffer(IDirect3DDevice9 *device, std::size_t size, DWORD usageFlags) : mDevice(device), mVertexBuffer(NULL)
+{
+ if (size > 0)
+ {
+ D3DPOOL pool = getDisplay()->getBufferPool(usageFlags);
+ HRESULT result = device->CreateVertexBuffer(size, usageFlags, 0, pool, &mVertexBuffer, NULL);
+ mSerial = issueSerial();
+
+ if (FAILED(result))
+ {
+ ERR("Out of memory allocating a vertex buffer of size %lu.", size);
+ }
+ }
+}
+
+VertexBuffer::~VertexBuffer()
+{
+ if (mVertexBuffer)
+ {
+ mVertexBuffer->Release();
+ }
+}
+
+void VertexBuffer::unmap()
+{
+ if (mVertexBuffer)
+ {
+ mVertexBuffer->Unlock();
+ }
+}
+
+IDirect3DVertexBuffer9 *VertexBuffer::getBuffer() const
+{
+ return mVertexBuffer;
+}
+
+unsigned int VertexBuffer::getSerial() const
+{
+ return mSerial;
+}
+
+unsigned int VertexBuffer::issueSerial()
+{
+ return mCurrentSerial++;
+}
+
+ArrayVertexBuffer::ArrayVertexBuffer(IDirect3DDevice9 *device, std::size_t size, DWORD usageFlags) : VertexBuffer(device, size, usageFlags)
+{
+ mBufferSize = size;
+ mWritePosition = 0;
+ mRequiredSpace = 0;
+}
+
+ArrayVertexBuffer::~ArrayVertexBuffer()
+{
+}
+
+void ArrayVertexBuffer::addRequiredSpace(UINT requiredSpace)
+{
+ mRequiredSpace += requiredSpace;
+}
+
+StreamingVertexBuffer::StreamingVertexBuffer(IDirect3DDevice9 *device, std::size_t initialSize) : ArrayVertexBuffer(device, initialSize, D3DUSAGE_DYNAMIC | D3DUSAGE_WRITEONLY)
+{
+}
+
+StreamingVertexBuffer::~StreamingVertexBuffer()
+{
+}
+
+void *StreamingVertexBuffer::map(const VertexAttribute &attribute, std::size_t requiredSpace, std::size_t *offset)
+{
+ void *mapPtr = NULL;
+
+ if (mVertexBuffer)
+ {
+ HRESULT result = mVertexBuffer->Lock(mWritePosition, requiredSpace, &mapPtr, D3DLOCK_NOOVERWRITE);
+
+ if (FAILED(result))
+ {
+ ERR("Lock failed with error 0x%08x", result);
+ return NULL;
+ }
+
+ *offset = mWritePosition;
+ mWritePosition += requiredSpace;
+ }
+
+ return mapPtr;
+}
+
+void StreamingVertexBuffer::reserveRequiredSpace()
+{
+ if (mRequiredSpace > mBufferSize)
+ {
+ if (mVertexBuffer)
+ {
+ mVertexBuffer->Release();
+ mVertexBuffer = NULL;
+ }
+
+ mBufferSize = std::max(mRequiredSpace, 3 * mBufferSize / 2); // 1.5 x mBufferSize is arbitrary and should be checked to see we don't have too many reallocations.
+
+ D3DPOOL pool = getDisplay()->getBufferPool(D3DUSAGE_DYNAMIC | D3DUSAGE_WRITEONLY);
+ HRESULT result = mDevice->CreateVertexBuffer(mBufferSize, D3DUSAGE_DYNAMIC | D3DUSAGE_WRITEONLY, 0, pool, &mVertexBuffer, NULL);
+ mSerial = issueSerial();
+
+ if (FAILED(result))
+ {
+ ERR("Out of memory allocating a vertex buffer of size %lu.", mBufferSize);
+ }
+
+ mWritePosition = 0;
+ }
+ else if (mWritePosition + mRequiredSpace > mBufferSize) // Recycle
+ {
+ if (mVertexBuffer)
+ {
+ void *dummy;
+ mVertexBuffer->Lock(0, 1, &dummy, D3DLOCK_DISCARD);
+ mVertexBuffer->Unlock();
+ }
+
+ mWritePosition = 0;
+ }
+
+ mRequiredSpace = 0;
+}
+
+StaticVertexBuffer::StaticVertexBuffer(IDirect3DDevice9 *device) : ArrayVertexBuffer(device, 0, D3DUSAGE_WRITEONLY)
+{
+}
+
+StaticVertexBuffer::~StaticVertexBuffer()
+{
+}
+
+void *StaticVertexBuffer::map(const VertexAttribute &attribute, std::size_t requiredSpace, std::size_t *streamOffset)
+{
+ void *mapPtr = NULL;
+
+ if (mVertexBuffer)
+ {
+ HRESULT result = mVertexBuffer->Lock(mWritePosition, requiredSpace, &mapPtr, 0);
+
+ if (FAILED(result))
+ {
+ ERR("Lock failed with error 0x%08x", result);
+ return NULL;
+ }
+
+ int attributeOffset = attribute.mOffset % attribute.stride();
+ VertexElement element = {attribute.mType, attribute.mSize, attribute.stride(), attribute.mNormalized, attributeOffset, mWritePosition};
+ mCache.push_back(element);
+
+ *streamOffset = mWritePosition;
+ mWritePosition += requiredSpace;
+ }
+
+ return mapPtr;
+}
+
+void StaticVertexBuffer::reserveRequiredSpace()
+{
+ if (!mVertexBuffer && mBufferSize == 0)
+ {
+ D3DPOOL pool = getDisplay()->getBufferPool(D3DUSAGE_WRITEONLY);
+ HRESULT result = mDevice->CreateVertexBuffer(mRequiredSpace, D3DUSAGE_WRITEONLY, 0, pool, &mVertexBuffer, NULL);
+ mSerial = issueSerial();
+
+ if (FAILED(result))
+ {
+ ERR("Out of memory allocating a vertex buffer of size %lu.", mRequiredSpace);
+ }
+
+ mBufferSize = mRequiredSpace;
+ }
+ else if (mVertexBuffer && mBufferSize >= mRequiredSpace)
+ {
+ // Already allocated
+ }
+ else UNREACHABLE(); // Static vertex buffers can't be resized
+
+ mRequiredSpace = 0;
+}
+
+std::size_t StaticVertexBuffer::lookupAttribute(const VertexAttribute &attribute)
+{
+ for (unsigned int element = 0; element < mCache.size(); element++)
+ {
+ if (mCache[element].type == attribute.mType &&
+ mCache[element].size == attribute.mSize &&
+ mCache[element].stride == attribute.stride() &&
+ mCache[element].normalized == attribute.mNormalized)
+ {
+ if (mCache[element].attributeOffset == attribute.mOffset % attribute.stride())
+ {
+ return mCache[element].streamOffset;
+ }
+ }
+ }
+
+ return -1;
+}
+
+const VertexDataManager::FormatConverter &VertexDataManager::formatConverter(const VertexAttribute &attribute) const
+{
+ return mAttributeTypes[typeIndex(attribute.mType)][attribute.mNormalized][attribute.mSize - 1];
+}
+}