/* GL locking is done by the caller */
static void drawStridedSlowVs(IWineD3DDevice *iface, const struct wined3d_stream_info *si, UINT numberOfVertices,
GLenum glPrimitiveType, const void *idxData, UINT idxSize, UINT startIdx)
{
IWineD3DDeviceImpl *This = (IWineD3DDeviceImpl *) iface;
const struct wined3d_gl_info *gl_info = &This->adapter->gl_info;
LONG SkipnStrides = startIdx + This->stateBlock->loadBaseVertexIndex;
const WORD *pIdxBufS = NULL;
const DWORD *pIdxBufL = NULL;
UINT vx_index;
int i;
IWineD3DStateBlockImpl *stateblock = This->stateBlock;
const BYTE *ptr;
if (idxSize)
{
/* Immediate mode drawing can't make use of indices in a vbo - get the
* data from the index buffer. If the index buffer has no vbo (not
* supported or other reason), or with user pointer drawing idxData
* will be non-NULL. */
if (!idxData)
idxData = buffer_get_sysmem((struct wined3d_buffer *)This->stateBlock->pIndexData, gl_info);
if (idxSize == 2) pIdxBufS = idxData;
else pIdxBufL = idxData;
} else if (idxData) {
ERR("non-NULL idxData with 0 idxSize, this should never happen\n");
return;
}
/* Start drawing in GL */
glBegin(glPrimitiveType);
for (vx_index = 0; vx_index < numberOfVertices; ++vx_index) {
if (idxData != NULL) {
/* Indexed so work out the number of strides to skip */
if (idxSize == 2)
SkipnStrides = pIdxBufS[startIdx + vx_index] + stateblock->loadBaseVertexIndex;
else
SkipnStrides = pIdxBufL[startIdx + vx_index] + stateblock->loadBaseVertexIndex;
}
for (i = MAX_ATTRIBS - 1; i >= 0; i--)
{
if (!(si->use_map & (1 << i))) continue;
ptr = si->elements[i].data +
si->elements[i].stride * SkipnStrides +
stateblock->streamOffset[si->elements[i].stream_idx];
send_attribute(This, si->elements[i].format_desc->format, i, ptr);
}
SkipnStrides++;
}
glEnd();
}
static inline void remove_vbos(IWineD3DDeviceImpl *This, struct wined3d_stream_info *s)
{
unsigned int i;
for (i = 0; i < (sizeof(s->elements) / sizeof(*s->elements)); ++i)
{
struct wined3d_stream_info_element *e;
if (!(s->use_map & (1 << i))) continue;
e = &s->elements[i];
if (e->buffer_object)
{
struct wined3d_buffer *vb = (struct wined3d_buffer *)This->stateBlock->streamSource[e->stream_idx];
e->buffer_object = 0;
e->data = (BYTE *)((unsigned long)e->data + (unsigned long)buffer_get_sysmem(vb));
}
}
}
static void remove_vbos(const struct wined3d_gl_info *gl_info,
const struct wined3d_state *state, struct wined3d_stream_info *s)
{
unsigned int i;
for (i = 0; i < (sizeof(s->elements) / sizeof(*s->elements)); ++i)
{
struct wined3d_stream_info_element *e;
if (!(s->use_map & (1 << i))) continue;
e = &s->elements[i];
if (e->buffer_object)
{
struct wined3d_buffer *vb = state->streams[e->stream_idx].buffer;
e->buffer_object = 0;
e->data = (BYTE *)((ULONG_PTR)e->data + (ULONG_PTR)buffer_get_sysmem(vb, gl_info));
}
}
}
/* Tesselates a high order rectangular patch into single triangles using gl evaluators
*
* The problem is that OpenGL does not offer a direct way to return the tesselated primitives,
* and they can't be sent off for rendering directly either. Tesselating is slow, so we want
* to cache the patches in a vertex buffer. But more importantly, gl can't bind generated
* attributes to numbered shader attributes, so we have to store them and rebind them as needed
* in drawprim.
*
* To read back, the opengl feedback mode is used. This creates a problem because we want
* untransformed, unlit vertices, but feedback runs everything through transform and lighting.
* Thus disable lighting and set identity matrices to get unmodified colors and positions.
* To overcome clipping find the biggest x, y and z values of the vertices in the patch and scale
* them to [-1.0;+1.0] and set the viewport up to scale them back.
*
* Normals are more tricky: Draw white vertices with 3 directional lights, and calculate the
* resulting colors back to the normals.
*
* NOTE: This function activates a context for blitting, modifies matrices & viewport, but
* does not restore it because normally a draw follows immediately afterwards. The caller is
* responsible of taking care that either the gl states are restored, or the context activated
* for drawing to reset the lastWasBlit flag.
*/
HRESULT tesselate_rectpatch(IWineD3DDeviceImpl *This,
struct WineD3DRectPatch *patch) {
unsigned int i, j, num_quads, out_vertex_size, buffer_size, d3d_out_vertex_size;
float max_x = 0.0f, max_y = 0.0f, max_z = 0.0f, neg_z = 0.0f;
struct wined3d_stream_info stream_info;
struct wined3d_stream_info_element *e;
struct wined3d_context *context;
const BYTE *data;
const WINED3DRECTPATCH_INFO *info = &patch->RectPatchInfo;
DWORD vtxStride;
GLenum feedback_type;
GLfloat *feedbuffer;
/* Simply activate the context for blitting. This disables all the things we don't want and
* takes care of dirtifying. Dirtifying is preferred over pushing / popping, since drawing the
* patch (as opposed to normal draws) will most likely need different changes anyway. */
context = context_acquire(This, NULL, CTXUSAGE_BLIT);
/* First, locate the position data. This is provided in a vertex buffer in the stateblock.
* Beware of vbos
*/
device_stream_info_from_declaration(This, FALSE, &stream_info, NULL);
e = &stream_info.elements[WINED3D_FFP_POSITION];
if (e->buffer_object)
{
struct wined3d_buffer *vb;
vb = (struct wined3d_buffer *)This->stateBlock->streamSource[e->stream_idx];
e->data = (BYTE *)((unsigned long)e->data + (unsigned long)buffer_get_sysmem(vb));
}
vtxStride = e->stride;
data = e->data +
vtxStride * info->Stride * info->StartVertexOffsetHeight +
vtxStride * info->StartVertexOffsetWidth;
/* Not entirely sure about what happens with transformed vertices */
if (stream_info.position_transformed) FIXME("Transformed position in rectpatch generation\n");
if(vtxStride % sizeof(GLfloat)) {
/* glMap2f reads vertex sizes in GLfloats, the d3d stride is in bytes.
* I don't see how the stride could not be a multiple of 4, but make sure
* to check it
*/
ERR("Vertex stride is not a multiple of sizeof(GLfloat)\n");
}
if(info->Basis != WINED3DBASIS_BEZIER) {
FIXME("Basis is %s, how to handle this?\n", debug_d3dbasis(info->Basis));
}
if(info->Degree != WINED3DDEGREE_CUBIC) {
FIXME("Degree is %s, how to handle this?\n", debug_d3ddegree(info->Degree));
}
/* First, get the boundary cube of the input data */
for(j = 0; j < info->Height; j++) {
for(i = 0; i < info->Width; i++) {
const float *v = (const float *)(data + vtxStride * i + vtxStride * info->Stride * j);
if(fabs(v[0]) > max_x) max_x = fabs(v[0]);
if(fabs(v[1]) > max_y) max_y = fabs(v[1]);
if(fabs(v[2]) > max_z) max_z = fabs(v[2]);
if(v[2] < neg_z) neg_z = v[2];
}
}
/* This needs some improvements in the vertex decl code */
FIXME("Cannot find data to generate. Only generating position and normals\n");
patch->has_normals = TRUE;
patch->has_texcoords = FALSE;
ENTER_GL();
glMatrixMode(GL_PROJECTION);
checkGLcall("glMatrixMode(GL_PROJECTION)");
glLoadIdentity();
checkGLcall("glLoadIndentity()");
glScalef(1.0f / (max_x), 1.0f / (max_y), max_z == 0.0f ? 1.0f : 1.0f / (2.0f * max_z));
glTranslatef(0.0f, 0.0f, 0.5f);
checkGLcall("glScalef");
glViewport(-max_x, -max_y, 2 * (max_x), 2 * (max_y));
checkGLcall("glViewport");
/* Some states to take care of. If we're in wireframe opengl will produce lines, and confuse
* our feedback buffer parser
*/
glPolygonMode(GL_FRONT_AND_BACK, GL_FILL);
checkGLcall("glPolygonMode(GL_FRONT_AND_BACK, GL_FILL)");
IWineD3DDeviceImpl_MarkStateDirty(This, STATE_RENDER(WINED3DRS_FILLMODE));
if(patch->has_normals) {
static const GLfloat black[] = {0.0f, 0.0f, 0.0f, 0.0f};
static const GLfloat red[] = {1.0f, 0.0f, 0.0f, 0.0f};
static const GLfloat green[] = {0.0f, 1.0f, 0.0f, 0.0f};
static const GLfloat blue[] = {0.0f, 0.0f, 1.0f, 0.0f};
static const GLfloat white[] = {1.0f, 1.0f, 1.0f, 1.0f};
glEnable(GL_LIGHTING);
checkGLcall("glEnable(GL_LIGHTING)");
glLightModelfv(GL_LIGHT_MODEL_AMBIENT, black);
checkGLcall("glLightModel for MODEL_AMBIENT");
IWineD3DDeviceImpl_MarkStateDirty(This, STATE_RENDER(WINED3DRS_AMBIENT));
for (i = 3; i < context->gl_info->limits.lights; ++i)
{
glDisable(GL_LIGHT0 + i);
checkGLcall("glDisable(GL_LIGHT0 + i)");
IWineD3DDeviceImpl_MarkStateDirty(This, STATE_ACTIVELIGHT(i));
}
IWineD3DDeviceImpl_MarkStateDirty(This, STATE_ACTIVELIGHT(0));
glLightfv(GL_LIGHT0, GL_DIFFUSE, red);
glLightfv(GL_LIGHT0, GL_SPECULAR, black);
glLightfv(GL_LIGHT0, GL_AMBIENT, black);
glLightfv(GL_LIGHT0, GL_POSITION, red);
glEnable(GL_LIGHT0);
checkGLcall("Setting up light 1");
IWineD3DDeviceImpl_MarkStateDirty(This, STATE_ACTIVELIGHT(1));
glLightfv(GL_LIGHT1, GL_DIFFUSE, green);
glLightfv(GL_LIGHT1, GL_SPECULAR, black);
glLightfv(GL_LIGHT1, GL_AMBIENT, black);
glLightfv(GL_LIGHT1, GL_POSITION, green);
glEnable(GL_LIGHT1);
checkGLcall("Setting up light 2");
IWineD3DDeviceImpl_MarkStateDirty(This, STATE_ACTIVELIGHT(2));
glLightfv(GL_LIGHT2, GL_DIFFUSE, blue);
glLightfv(GL_LIGHT2, GL_SPECULAR, black);
glLightfv(GL_LIGHT2, GL_AMBIENT, black);
glLightfv(GL_LIGHT2, GL_POSITION, blue);
glEnable(GL_LIGHT2);
checkGLcall("Setting up light 3");
IWineD3DDeviceImpl_MarkStateDirty(This, STATE_MATERIAL);
IWineD3DDeviceImpl_MarkStateDirty(This, STATE_RENDER(WINED3DRS_COLORVERTEX));
glDisable(GL_COLOR_MATERIAL);
glMaterialfv(GL_FRONT_AND_BACK, GL_EMISSION, black);
glMaterialfv(GL_FRONT_AND_BACK, GL_SPECULAR, black);
glMaterialfv(GL_FRONT_AND_BACK, GL_DIFFUSE, white);
checkGLcall("Setting up materials");
}
/* Enable the needed maps.
* GL_MAP2_VERTEX_3 is needed for positional data.
* GL_AUTO_NORMAL to generate normals from the position. Do not use GL_MAP2_NORMAL.
* GL_MAP2_TEXTURE_COORD_4 for texture coords
*/
num_quads = ceilf(patch->numSegs[0]) * ceilf(patch->numSegs[1]);
out_vertex_size = 3 /* position */;
d3d_out_vertex_size = 3;
glEnable(GL_MAP2_VERTEX_3);
if(patch->has_normals && patch->has_texcoords) {
FIXME("Texcoords not handled yet\n");
feedback_type = GL_3D_COLOR_TEXTURE;
out_vertex_size += 8;
d3d_out_vertex_size += 7;
glEnable(GL_AUTO_NORMAL);
glEnable(GL_MAP2_TEXTURE_COORD_4);
} else if(patch->has_texcoords) {
FIXME("Texcoords not handled yet\n");
feedback_type = GL_3D_COLOR_TEXTURE;
out_vertex_size += 7;
d3d_out_vertex_size += 4;
glEnable(GL_MAP2_TEXTURE_COORD_4);
} else if(patch->has_normals) {
feedback_type = GL_3D_COLOR;
out_vertex_size += 4;
d3d_out_vertex_size += 3;
glEnable(GL_AUTO_NORMAL);
} else {
feedback_type = GL_3D;
}
checkGLcall("glEnable vertex attrib generation");
buffer_size = num_quads * out_vertex_size * 2 /* triangle list */ * 3 /* verts per tri */
+ 4 * num_quads /* 2 triangle markers per quad + num verts in tri */;
feedbuffer = HeapAlloc(GetProcessHeap(), HEAP_ZERO_MEMORY, buffer_size * sizeof(float) * 8);
glMap2f(GL_MAP2_VERTEX_3,
0.0f, 1.0f, vtxStride / sizeof(float), info->Width,
0.0f, 1.0f, info->Stride * vtxStride / sizeof(float), info->Height,
(const GLfloat *)data);
checkGLcall("glMap2f");
if(patch->has_texcoords) {
glMap2f(GL_MAP2_TEXTURE_COORD_4,
0.0f, 1.0f, vtxStride / sizeof(float), info->Width,
0.0f, 1.0f, info->Stride * vtxStride / sizeof(float), info->Height,
(const GLfloat *)data);
checkGLcall("glMap2f");
}
glMapGrid2f(ceilf(patch->numSegs[0]), 0.0f, 1.0f, ceilf(patch->numSegs[1]), 0.0f, 1.0f);
checkGLcall("glMapGrid2f");
glFeedbackBuffer(buffer_size * 2, feedback_type, feedbuffer);
checkGLcall("glFeedbackBuffer");
glRenderMode(GL_FEEDBACK);
glEvalMesh2(GL_FILL, 0, ceilf(patch->numSegs[0]), 0, ceilf(patch->numSegs[1]));
checkGLcall("glEvalMesh2");
i = glRenderMode(GL_RENDER);
if(i == -1) {
LEAVE_GL();
ERR("Feedback failed. Expected %d elements back\n", buffer_size);
HeapFree(GetProcessHeap(), 0, feedbuffer);
context_release(context);
return WINED3DERR_DRIVERINTERNALERROR;
} else if(i != buffer_size) {
LEAVE_GL();
ERR("Unexpected amount of elements returned. Expected %d, got %d\n", buffer_size, i);
HeapFree(GetProcessHeap(), 0, feedbuffer);
context_release(context);
return WINED3DERR_DRIVERINTERNALERROR;
} else {
TRACE("Got %d elements as expected\n", i);
}
HeapFree(GetProcessHeap(), 0, patch->mem);
patch->mem = HeapAlloc(GetProcessHeap(), HEAP_ZERO_MEMORY, num_quads * 6 * d3d_out_vertex_size * sizeof(float) * 8);
i = 0;
for(j = 0; j < buffer_size; j += (3 /* num verts */ * out_vertex_size + 2 /* tri marker */)) {
if(feedbuffer[j] != GL_POLYGON_TOKEN) {
ERR("Unexpected token: %f\n", feedbuffer[j]);
continue;
}
if(feedbuffer[j + 1] != 3) {
ERR("Unexpected polygon: %f corners\n", feedbuffer[j + 1]);
continue;
}
/* Somehow there are different ideas about back / front facing, so fix up the
* vertex order
*/
patch->mem[i + 0] = feedbuffer[j + out_vertex_size * 2 + 2]; /* x, triangle 2 */
patch->mem[i + 1] = feedbuffer[j + out_vertex_size * 2 + 3]; /* y, triangle 2 */
patch->mem[i + 2] = (feedbuffer[j + out_vertex_size * 2 + 4] - 0.5f) * 4.0f * max_z; /* z, triangle 3 */
if(patch->has_normals) {
patch->mem[i + 3] = feedbuffer[j + out_vertex_size * 2 + 5];
patch->mem[i + 4] = feedbuffer[j + out_vertex_size * 2 + 6];
patch->mem[i + 5] = feedbuffer[j + out_vertex_size * 2 + 7];
}
i += d3d_out_vertex_size;
patch->mem[i + 0] = feedbuffer[j + out_vertex_size * 1 + 2]; /* x, triangle 2 */
patch->mem[i + 1] = feedbuffer[j + out_vertex_size * 1 + 3]; /* y, triangle 2 */
patch->mem[i + 2] = (feedbuffer[j + out_vertex_size * 1 + 4] - 0.5f) * 4.0f * max_z; /* z, triangle 2 */
if(patch->has_normals) {
patch->mem[i + 3] = feedbuffer[j + out_vertex_size * 1 + 5];
patch->mem[i + 4] = feedbuffer[j + out_vertex_size * 1 + 6];
patch->mem[i + 5] = feedbuffer[j + out_vertex_size * 1 + 7];
}
i += d3d_out_vertex_size;
patch->mem[i + 0] = feedbuffer[j + out_vertex_size * 0 + 2]; /* x, triangle 1 */
patch->mem[i + 1] = feedbuffer[j + out_vertex_size * 0 + 3]; /* y, triangle 1 */
patch->mem[i + 2] = (feedbuffer[j + out_vertex_size * 0 + 4] - 0.5f) * 4.0f * max_z; /* z, triangle 1 */
if(patch->has_normals) {
patch->mem[i + 3] = feedbuffer[j + out_vertex_size * 0 + 5];
patch->mem[i + 4] = feedbuffer[j + out_vertex_size * 0 + 6];
patch->mem[i + 5] = feedbuffer[j + out_vertex_size * 0 + 7];
}
i += d3d_out_vertex_size;
}
if(patch->has_normals) {
/* Now do the same with reverse light directions */
static const GLfloat x[] = {-1.0f, 0.0f, 0.0f, 0.0f};
static const GLfloat y[] = { 0.0f, -1.0f, 0.0f, 0.0f};
static const GLfloat z[] = { 0.0f, 0.0f, -1.0f, 0.0f};
glLightfv(GL_LIGHT0, GL_POSITION, x);
glLightfv(GL_LIGHT1, GL_POSITION, y);
glLightfv(GL_LIGHT2, GL_POSITION, z);
checkGLcall("Setting up reverse light directions");
glRenderMode(GL_FEEDBACK);
checkGLcall("glRenderMode(GL_FEEDBACK)");
glEvalMesh2(GL_FILL, 0, ceilf(patch->numSegs[0]), 0, ceilf(patch->numSegs[1]));
checkGLcall("glEvalMesh2");
i = glRenderMode(GL_RENDER);
checkGLcall("glRenderMode(GL_RENDER)");
i = 0;
for(j = 0; j < buffer_size; j += (3 /* num verts */ * out_vertex_size + 2 /* tri marker */)) {
if(feedbuffer[j] != GL_POLYGON_TOKEN) {
ERR("Unexpected token: %f\n", feedbuffer[j]);
continue;
}
if(feedbuffer[j + 1] != 3) {
ERR("Unexpected polygon: %f corners\n", feedbuffer[j + 1]);
continue;
}
if(patch->mem[i + 3] == 0.0f)
patch->mem[i + 3] = -feedbuffer[j + out_vertex_size * 2 + 5];
if(patch->mem[i + 4] == 0.0f)
patch->mem[i + 4] = -feedbuffer[j + out_vertex_size * 2 + 6];
if(patch->mem[i + 5] == 0.0f)
patch->mem[i + 5] = -feedbuffer[j + out_vertex_size * 2 + 7];
normalize_normal(patch->mem + i + 3);
i += d3d_out_vertex_size;
if(patch->mem[i + 3] == 0.0f)
patch->mem[i + 3] = -feedbuffer[j + out_vertex_size * 1 + 5];
if(patch->mem[i + 4] == 0.0f)
patch->mem[i + 4] = -feedbuffer[j + out_vertex_size * 1 + 6];
if(patch->mem[i + 5] == 0.0f)
patch->mem[i + 5] = -feedbuffer[j + out_vertex_size * 1 + 7];
normalize_normal(patch->mem + i + 3);
i += d3d_out_vertex_size;
if(patch->mem[i + 3] == 0.0f)
patch->mem[i + 3] = -feedbuffer[j + out_vertex_size * 0 + 5];
if(patch->mem[i + 4] == 0.0f)
patch->mem[i + 4] = -feedbuffer[j + out_vertex_size * 0 + 6];
if(patch->mem[i + 5] == 0.0f)
patch->mem[i + 5] = -feedbuffer[j + out_vertex_size * 0 + 7];
normalize_normal(patch->mem + i + 3);
i += d3d_out_vertex_size;
}
}
glDisable(GL_MAP2_VERTEX_3);
glDisable(GL_AUTO_NORMAL);
glDisable(GL_MAP2_NORMAL);
glDisable(GL_MAP2_TEXTURE_COORD_4);
checkGLcall("glDisable vertex attrib generation");
LEAVE_GL();
context_release(context);
HeapFree(GetProcessHeap(), 0, feedbuffer);
vtxStride = 3 * sizeof(float);
if(patch->has_normals) {
vtxStride += 3 * sizeof(float);
}
if(patch->has_texcoords) {
vtxStride += 4 * sizeof(float);
}
memset(&patch->strided, 0, sizeof(patch->strided));
patch->strided.position.format = WINED3DFMT_R32G32B32_FLOAT;
patch->strided.position.lpData = (BYTE *) patch->mem;
patch->strided.position.dwStride = vtxStride;
if(patch->has_normals) {
patch->strided.normal.format = WINED3DFMT_R32G32B32_FLOAT;
patch->strided.normal.lpData = (BYTE *) patch->mem + 3 * sizeof(float) /* pos */;
patch->strided.normal.dwStride = vtxStride;
}
if(patch->has_texcoords) {
patch->strided.texCoords[0].format = WINED3DFMT_R32G32B32A32_FLOAT;
patch->strided.texCoords[0].lpData = (BYTE *) patch->mem + 3 * sizeof(float) /* pos */;
if(patch->has_normals) {
patch->strided.texCoords[0].lpData += 3 * sizeof(float);
}
patch->strided.texCoords[0].dwStride = vtxStride;
}
return WINED3D_OK;
}
/* GL locking is done by the caller */
static void drawStridedSlow(IWineD3DDevice *iface, const struct wined3d_context *context,
const struct wined3d_stream_info *si, UINT NumVertexes, GLenum glPrimType,
const void *idxData, UINT idxSize, UINT startIdx)
{
unsigned int textureNo = 0;
const WORD *pIdxBufS = NULL;
const DWORD *pIdxBufL = NULL;
UINT vx_index;
IWineD3DDeviceImpl *This = (IWineD3DDeviceImpl *)iface;
const UINT *streamOffset = This->stateBlock->streamOffset;
long SkipnStrides = startIdx + This->stateBlock->loadBaseVertexIndex;
BOOL pixelShader = use_ps(This->stateBlock);
BOOL specular_fog = FALSE;
const BYTE *texCoords[WINED3DDP_MAXTEXCOORD];
const BYTE *diffuse = NULL, *specular = NULL, *normal = NULL, *position = NULL;
const struct wined3d_gl_info *gl_info = context->gl_info;
UINT texture_stages = gl_info->limits.texture_stages;
const struct wined3d_stream_info_element *element;
UINT num_untracked_materials;
DWORD tex_mask = 0;
TRACE("Using slow vertex array code\n");
/* Variable Initialization */
if (idxSize != 0) {
/* Immediate mode drawing can't make use of indices in a vbo - get the data from the index buffer.
* If the index buffer has no vbo(not supported or other reason), or with user pointer drawing
* idxData will be != NULL
*/
if(idxData == NULL) {
idxData = buffer_get_sysmem((struct wined3d_buffer *) This->stateBlock->pIndexData);
}
if (idxSize == 2) pIdxBufS = idxData;
else pIdxBufL = idxData;
} else if (idxData) {
ERR("non-NULL idxData with 0 idxSize, this should never happen\n");
return;
}
/* Start drawing in GL */
glBegin(glPrimType);
if (si->use_map & (1 << WINED3D_FFP_POSITION))
{
element = &si->elements[WINED3D_FFP_POSITION];
position = element->data + streamOffset[element->stream_idx];
}
if (si->use_map & (1 << WINED3D_FFP_NORMAL))
{
element = &si->elements[WINED3D_FFP_NORMAL];
normal = element->data + streamOffset[element->stream_idx];
}
else
{
glNormal3f(0, 0, 0);
}
num_untracked_materials = context->num_untracked_materials;
if (si->use_map & (1 << WINED3D_FFP_DIFFUSE))
{
element = &si->elements[WINED3D_FFP_DIFFUSE];
diffuse = element->data + streamOffset[element->stream_idx];
if (num_untracked_materials && element->format_desc->format != WINED3DFMT_B8G8R8A8_UNORM)
FIXME("Implement diffuse color tracking from %s\n", debug_d3dformat(element->format_desc->format));
}
else
{
glColor4f(1.0f, 1.0f, 1.0f, 1.0f);
}
if (si->use_map & (1 << WINED3D_FFP_SPECULAR))
{
element = &si->elements[WINED3D_FFP_SPECULAR];
specular = element->data + streamOffset[element->stream_idx];
/* special case where the fog density is stored in the specular alpha channel */
if (This->stateBlock->renderState[WINED3DRS_FOGENABLE]
&& (This->stateBlock->renderState[WINED3DRS_FOGVERTEXMODE] == WINED3DFOG_NONE
|| si->elements[WINED3D_FFP_POSITION].format_desc->format == WINED3DFMT_R32G32B32A32_FLOAT)
&& This->stateBlock->renderState[WINED3DRS_FOGTABLEMODE] == WINED3DFOG_NONE)
{
if (gl_info->supported[EXT_FOG_COORD])
{
if (element->format_desc->format == WINED3DFMT_B8G8R8A8_UNORM) specular_fog = TRUE;
else FIXME("Implement fog coordinates from %s\n", debug_d3dformat(element->format_desc->format));
}
else
{
static BOOL warned;
if (!warned)
{
/* TODO: Use the fog table code from old ddraw */
FIXME("Implement fog for transformed vertices in software\n");
warned = TRUE;
}
}
}
}
else if (gl_info->supported[EXT_SECONDARY_COLOR])
{
GL_EXTCALL(glSecondaryColor3fEXT)(0, 0, 0);
}
for (textureNo = 0; textureNo < texture_stages; ++textureNo)
{
int coordIdx = This->stateBlock->textureState[textureNo][WINED3DTSS_TEXCOORDINDEX];
DWORD texture_idx = This->texUnitMap[textureNo];
if (!gl_info->supported[ARB_MULTITEXTURE] && textureNo > 0)
{
FIXME("Program using multiple concurrent textures which this opengl implementation doesn't support\n");
continue;
}
if (!pixelShader && !This->stateBlock->textures[textureNo]) continue;
if (texture_idx == WINED3D_UNMAPPED_STAGE) continue;
if (coordIdx > 7)
{
TRACE("tex: %d - Skip tex coords, as being system generated\n", textureNo);
continue;
}
else if (coordIdx < 0)
{
FIXME("tex: %d - Coord index %d is less than zero, expect a crash.\n", textureNo, coordIdx);
continue;
}
if (si->use_map & (1 << (WINED3D_FFP_TEXCOORD0 + coordIdx)))
{
element = &si->elements[WINED3D_FFP_TEXCOORD0 + coordIdx];
texCoords[coordIdx] = element->data + streamOffset[element->stream_idx];
tex_mask |= (1 << textureNo);
}
else
{
TRACE("tex: %d - Skipping tex coords, as no data supplied\n", textureNo);
if (gl_info->supported[ARB_MULTITEXTURE])
GL_EXTCALL(glMultiTexCoord4fARB(GL_TEXTURE0_ARB + texture_idx, 0, 0, 0, 1));
else
glTexCoord4f(0, 0, 0, 1);
}
}
/* We shouldn't start this function if any VBO is involved. Should I put a safety check here?
* Guess it's not necessary(we crash then anyway) and would only eat CPU time
*/
/* For each primitive */
for (vx_index = 0; vx_index < NumVertexes; ++vx_index) {
UINT texture, tmp_tex_mask;
/* Blending data and Point sizes are not supported by this function. They are not supported by the fixed
* function pipeline at all. A Fixme for them is printed after decoding the vertex declaration
*/
/* For indexed data, we need to go a few more strides in */
if (idxData != NULL) {
/* Indexed so work out the number of strides to skip */
if (idxSize == 2)
SkipnStrides = pIdxBufS[startIdx + vx_index] + This->stateBlock->loadBaseVertexIndex;
else
SkipnStrides = pIdxBufL[startIdx + vx_index] + This->stateBlock->loadBaseVertexIndex;
}
tmp_tex_mask = tex_mask;
for (texture = 0; tmp_tex_mask; tmp_tex_mask >>= 1, ++texture)
{
int coord_idx;
const void *ptr;
DWORD texture_idx;
if (!(tmp_tex_mask & 1)) continue;
coord_idx = This->stateBlock->textureState[texture][WINED3DTSS_TEXCOORDINDEX];
ptr = texCoords[coord_idx] + (SkipnStrides * si->elements[WINED3D_FFP_TEXCOORD0 + coord_idx].stride);
texture_idx = This->texUnitMap[texture];
multi_texcoord_funcs[si->elements[WINED3D_FFP_TEXCOORD0 + coord_idx].format_desc->emit_idx](
GL_TEXTURE0_ARB + texture_idx, ptr);
}
/* Diffuse -------------------------------- */
if (diffuse) {
const void *ptrToCoords = diffuse + SkipnStrides * si->elements[WINED3D_FFP_DIFFUSE].stride;
diffuse_funcs[si->elements[WINED3D_FFP_DIFFUSE].format_desc->emit_idx](ptrToCoords);
if (num_untracked_materials)
{
DWORD diffuseColor = ((const DWORD *)ptrToCoords)[0];
unsigned char i;
float color[4];
color[0] = D3DCOLOR_B_R(diffuseColor) / 255.0f;
color[1] = D3DCOLOR_B_G(diffuseColor) / 255.0f;
color[2] = D3DCOLOR_B_B(diffuseColor) / 255.0f;
color[3] = D3DCOLOR_B_A(diffuseColor) / 255.0f;
for (i = 0; i < num_untracked_materials; ++i)
{
glMaterialfv(GL_FRONT_AND_BACK, context->untracked_materials[i], color);
}
}
}
/* Specular ------------------------------- */
if (specular) {
const void *ptrToCoords = specular + SkipnStrides * si->elements[WINED3D_FFP_SPECULAR].stride;
specular_funcs[si->elements[WINED3D_FFP_SPECULAR].format_desc->emit_idx](ptrToCoords);
if (specular_fog)
{
DWORD specularColor = *(const DWORD *)ptrToCoords;
GL_EXTCALL(glFogCoordfEXT(specularColor >> 24));
}
}
/* Normal -------------------------------- */
if (normal != NULL) {
const void *ptrToCoords = normal + SkipnStrides * si->elements[WINED3D_FFP_NORMAL].stride;
normal_funcs[si->elements[WINED3D_FFP_NORMAL].format_desc->emit_idx](ptrToCoords);
}
/* Position -------------------------------- */
if (position) {
const void *ptrToCoords = position + SkipnStrides * si->elements[WINED3D_FFP_POSITION].stride;
position_funcs[si->elements[WINED3D_FFP_POSITION].format_desc->emit_idx](ptrToCoords);
}
/* For non indexed mode, step onto next parts */
if (idxData == NULL) {
++SkipnStrides;
}
}
glEnd();
checkGLcall("glEnd and previous calls");
}
/* GL locking is done by the caller */
static inline void drawStridedInstanced(IWineD3DDevice *iface, const struct wined3d_stream_info *si,
UINT numberOfVertices, GLenum glPrimitiveType, const void *idxData, UINT idxSize,
UINT startIdx)
{
UINT numInstances = 0, i;
int numInstancedAttribs = 0, j;
UINT instancedData[sizeof(si->elements) / sizeof(*si->elements) /* 16 */];
IWineD3DDeviceImpl *This = (IWineD3DDeviceImpl *) iface;
IWineD3DStateBlockImpl *stateblock = This->stateBlock;
if (idxSize == 0) {
/* This is a nasty thing. MSDN says no hardware supports that and apps have to use software vertex processing.
* We don't support this for now
*
* Shouldn't be too hard to support with opengl, in theory just call glDrawArrays instead of drawElements.
* But the StreamSourceFreq value has a different meaning in that situation.
*/
FIXME("Non-indexed instanced drawing is not supported\n");
return;
}
TRACE("(%p) : glElements(%x, %d, ...)\n", This, glPrimitiveType, numberOfVertices);
/* First, figure out how many instances we have to draw */
for(i = 0; i < MAX_STREAMS; i++) {
/* Look at the streams and take the first one which matches */
if(((stateblock->streamFlags[i] & WINED3DSTREAMSOURCE_INSTANCEDATA) || (stateblock->streamFlags[i] & WINED3DSTREAMSOURCE_INDEXEDDATA)) && stateblock->streamSource[i]) {
/* D3D9 could set streamFreq 0 with (INSTANCEDATA or INDEXEDDATA) and then it is handled as 1. See d3d9/tests/visual.c-> stream_test() */
if(stateblock->streamFreq[i] == 0){
numInstances = 1;
} else {
numInstances = stateblock->streamFreq[i]; /* use the specified number of instances from the first matched stream. See d3d9/tests/visual.c-> stream_test() */
}
break; /* break, because only the first suitable value is interesting */
}
}
for (i = 0; i < sizeof(si->elements) / sizeof(*si->elements); ++i)
{
if (!(si->use_map & (1 << i))) continue;
if (stateblock->streamFlags[si->elements[i].stream_idx] & WINED3DSTREAMSOURCE_INSTANCEDATA)
{
instancedData[numInstancedAttribs] = i;
numInstancedAttribs++;
}
}
/* now draw numInstances instances :-) */
for(i = 0; i < numInstances; i++) {
/* Specify the instanced attributes using immediate mode calls */
for(j = 0; j < numInstancedAttribs; j++) {
const BYTE *ptr = si->elements[instancedData[j]].data +
si->elements[instancedData[j]].stride * i +
stateblock->streamOffset[si->elements[instancedData[j]].stream_idx];
if (si->elements[instancedData[j]].buffer_object)
{
struct wined3d_buffer *vb =
(struct wined3d_buffer *)stateblock->streamSource[si->elements[instancedData[j]].stream_idx];
ptr += (long) buffer_get_sysmem(vb);
}
send_attribute(This, si->elements[instancedData[j]].format_desc->format, instancedData[j], ptr);
}
glDrawElements(glPrimitiveType, numberOfVertices, idxSize == 2 ? GL_UNSIGNED_SHORT : GL_UNSIGNED_INT,
(const char *)idxData+(idxSize * startIdx));
checkGLcall("glDrawElements");
}
}
/* GL locking is done by the caller */
static void drawStridedInstanced(const struct wined3d_gl_info *gl_info, const struct wined3d_state *state,
const struct wined3d_stream_info *si, UINT numberOfVertices, GLenum glPrimitiveType,
const void *idxData, UINT idxSize, UINT startIdx)
{
UINT numInstances = 0, i;
int numInstancedAttribs = 0, j;
UINT instancedData[sizeof(si->elements) / sizeof(*si->elements) /* 16 */];
if (!idxSize)
{
/* This is a nasty thing. MSDN says no hardware supports that and apps have to use software vertex processing.
* We don't support this for now
*
* Shouldn't be too hard to support with opengl, in theory just call glDrawArrays instead of drawElements.
* But the StreamSourceFreq value has a different meaning in that situation.
*/
FIXME("Non-indexed instanced drawing is not supported\n");
return;
}
/* First, figure out how many instances we have to draw */
for (i = 0; i < MAX_STREAMS; ++i)
{
/* Look at the streams and take the first one which matches */
if (state->streams[i].buffer
&& ((state->streams[i].flags & WINED3DSTREAMSOURCE_INSTANCEDATA)
|| (state->streams[i].flags & WINED3DSTREAMSOURCE_INDEXEDDATA)))
{
/* Use the specified number of instances from the first matched
* stream. A streamFreq of 0 (with INSTANCEDATA or INDEXEDDATA)
* is handled as 1. See d3d9/tests/visual.c-> stream_test(). */
numInstances = state->streams[i].frequency ? state->streams[i].frequency : 1;
break;
}
}
for (i = 0; i < sizeof(si->elements) / sizeof(*si->elements); ++i)
{
if (!(si->use_map & (1 << i))) continue;
if (state->streams[si->elements[i].stream_idx].flags & WINED3DSTREAMSOURCE_INSTANCEDATA)
{
instancedData[numInstancedAttribs] = i;
numInstancedAttribs++;
}
}
/* now draw numInstances instances :-) */
for(i = 0; i < numInstances; i++) {
/* Specify the instanced attributes using immediate mode calls */
for(j = 0; j < numInstancedAttribs; j++) {
const BYTE *ptr = si->elements[instancedData[j]].data
+ si->elements[instancedData[j]].stride * i
+ state->streams[si->elements[instancedData[j]].stream_idx].offset;
if (si->elements[instancedData[j]].buffer_object)
{
struct wined3d_buffer *vb = state->streams[si->elements[instancedData[j]].stream_idx].buffer;
ptr += (ULONG_PTR)buffer_get_sysmem(vb, gl_info);
}
send_attribute(gl_info, si->elements[instancedData[j]].format->id, instancedData[j], ptr);
}
glDrawElements(glPrimitiveType, numberOfVertices, idxSize == 2 ? GL_UNSIGNED_SHORT : GL_UNSIGNED_INT,
(const char *)idxData+(idxSize * startIdx));
checkGLcall("glDrawElements");
}
}
