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blender-archive/source/blender/gpu/intern/gpu_buffers.c

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/*
* ***** BEGIN GPL LICENSE BLOCK *****
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version 2
* of the License, or (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software Foundation,
* Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*
* The Original Code is Copyright (C) 2005 Blender Foundation.
* All rights reserved.
*
* The Original Code is: all of this file.
*
* Contributor(s): Brecht Van Lommel.
*
* ***** END GPL LICENSE BLOCK *****
*/
/** \file blender/gpu/intern/gpu_buffers.c
* \ingroup gpu
*
* Mesh drawing using OpenGL VBO (Vertex Buffer Objects)
*/
#include <limits.h>
#include <stddef.h>
#include <string.h>
#include "GPU_glew.h"
#include "MEM_guardedalloc.h"
#include "BLI_bitmap.h"
#include "BLI_math.h"
#include "BLI_utildefines.h"
#include "BLI_ghash.h"
#include "BLI_threads.h"
#include "DNA_meshdata_types.h"
#include "BKE_ccg.h"
#include "BKE_DerivedMesh.h"
#include "BKE_paint.h"
#include "BKE_mesh.h"
#include "BKE_pbvh.h"
#include "GPU_buffers.h"
#include "GPU_draw.h"
#include "GPU_basic_shader.h"
#include "bmesh.h"
typedef enum {
GPU_BUFFER_VERTEX_STATE = (1 << 0),
GPU_BUFFER_NORMAL_STATE = (1 << 1),
GPU_BUFFER_TEXCOORD_UNIT_0_STATE = (1 << 2),
GPU_BUFFER_TEXCOORD_UNIT_2_STATE = (1 << 3),
GPU_BUFFER_COLOR_STATE = (1 << 4),
GPU_BUFFER_ELEMENT_STATE = (1 << 5),
} GPUBufferState;
typedef struct {
GLenum gl_buffer_type;
int num_components; /* number of data components for one vertex */
} GPUBufferTypeSettings;
static size_t gpu_buffer_size_from_type(DerivedMesh *dm, GPUBufferType type);
static const GPUBufferTypeSettings gpu_buffer_type_settings[] = {
/* vertex */
{GL_ARRAY_BUFFER, 3},
/* normal */
{GL_ARRAY_BUFFER, 4}, /* we copy 3 shorts per normal but we add a fourth for alignment */
/* mcol */
{GL_ARRAY_BUFFER, 3},
/* uv */
{GL_ARRAY_BUFFER, 2},
/* uv for texpaint */
{GL_ARRAY_BUFFER, 4},
/* edge */
{GL_ELEMENT_ARRAY_BUFFER, 2},
/* uv edge */
{GL_ELEMENT_ARRAY_BUFFER, 4},
/* triangles, 1 point since we are allocating from tottriangle points, which account for all points */
{GL_ELEMENT_ARRAY_BUFFER, 1},
};
#define MAX_GPU_ATTRIB_DATA 32
#define BUFFER_OFFSET(n) ((GLubyte *)NULL + (n))
static GPUBufferState GLStates = 0;
static GPUAttrib attribData[MAX_GPU_ATTRIB_DATA] = { { -1, 0, 0 } };
static ThreadMutex buffer_mutex = BLI_MUTEX_INITIALIZER;
/* multires global buffer, can be used for many grids having the same grid size */
typedef struct GridCommonGPUBuffer {
GPUBuffer *mres_buffer;
int mres_prev_gridsize;
GLenum mres_prev_index_type;
unsigned mres_prev_totquad;
} GridCommonGPUBuffer;
void GPU_buffer_material_finalize(GPUDrawObject *gdo, GPUBufferMaterial *matinfo, int totmat)
{
int i, curmat, curelement;
/* count the number of materials used by this DerivedMesh */
for (i = 0; i < totmat; i++) {
if (matinfo[i].totelements > 0)
gdo->totmaterial++;
}
/* allocate an array of materials used by this DerivedMesh */
gdo->materials = MEM_mallocN(sizeof(GPUBufferMaterial) * gdo->totmaterial,
"GPUDrawObject.materials");
/* initialize the materials array */
for (i = 0, curmat = 0, curelement = 0; i < totmat; i++) {
if (matinfo[i].totelements > 0) {
gdo->materials[curmat] = matinfo[i];
gdo->materials[curmat].start = curelement;
gdo->materials[curmat].mat_nr = i;
gdo->materials[curmat].polys = MEM_mallocN(sizeof(int) * matinfo[i].totpolys, "GPUBufferMaterial.polys");
curelement += matinfo[i].totelements;
curmat++;
}
}
MEM_freeN(matinfo);
}
/* stores recently-deleted buffers so that new buffers won't have to
* be recreated as often
*
* only one instance of this pool is created, stored in
* gpu_buffer_pool
*
* note that the number of buffers in the pool is usually limited to
* MAX_FREE_GPU_BUFFERS, but this limit may be exceeded temporarily
* when a GPUBuffer is released outside the main thread; due to OpenGL
* restrictions it cannot be immediately released
*/
typedef struct GPUBufferPool {
/* number of allocated buffers stored */
int totbuf;
/* actual allocated length of the arrays */
int maxsize;
GPUBuffer **buffers;
} GPUBufferPool;
#define MAX_FREE_GPU_BUFFERS 8
/* create a new GPUBufferPool */
static GPUBufferPool *gpu_buffer_pool_new(void)
{
GPUBufferPool *pool;
pool = MEM_callocN(sizeof(GPUBufferPool), "GPUBuffer_Pool");
pool->maxsize = MAX_FREE_GPU_BUFFERS;
pool->buffers = MEM_mallocN(sizeof(*pool->buffers) * pool->maxsize,
"GPUBufferPool.buffers");
return pool;
}
/* remove a GPUBuffer from the pool (does not free the GPUBuffer) */
static void gpu_buffer_pool_remove_index(GPUBufferPool *pool, int index)
{
int i;
if (!pool || index < 0 || index >= pool->totbuf)
return;
/* shift entries down, overwriting the buffer at `index' */
for (i = index; i < pool->totbuf - 1; i++)
pool->buffers[i] = pool->buffers[i + 1];
/* clear the last entry */
if (pool->totbuf > 0)
pool->buffers[pool->totbuf - 1] = NULL;
pool->totbuf--;
}
/* delete the last entry in the pool */
static void gpu_buffer_pool_delete_last(GPUBufferPool *pool)
{
GPUBuffer *last;
if (pool->totbuf <= 0)
return;
/* get the last entry */
if (!(last = pool->buffers[pool->totbuf - 1]))
return;
/* delete the buffer's data */
glDeleteBuffers(1, &last->id);
/* delete the buffer and remove from pool */
MEM_freeN(last);
pool->totbuf--;
pool->buffers[pool->totbuf] = NULL;
}
/* free a GPUBufferPool; also frees the data in the pool's
* GPUBuffers */
static void gpu_buffer_pool_free(GPUBufferPool *pool)
{
if (!pool)
return;
while (pool->totbuf)
gpu_buffer_pool_delete_last(pool);
MEM_freeN(pool->buffers);
MEM_freeN(pool);
}
static void gpu_buffer_pool_free_unused(GPUBufferPool *pool)
{
if (!pool)
return;
BLI_mutex_lock(&buffer_mutex);
while (pool->totbuf)
gpu_buffer_pool_delete_last(pool);
BLI_mutex_unlock(&buffer_mutex);
}
static GPUBufferPool *gpu_buffer_pool = NULL;
static GPUBufferPool *gpu_get_global_buffer_pool(void)
{
/* initialize the pool */
if (!gpu_buffer_pool)
gpu_buffer_pool = gpu_buffer_pool_new();
return gpu_buffer_pool;
}
void GPU_global_buffer_pool_free(void)
{
gpu_buffer_pool_free(gpu_buffer_pool);
gpu_buffer_pool = NULL;
}
void GPU_global_buffer_pool_free_unused(void)
{
gpu_buffer_pool_free_unused(gpu_buffer_pool);
}
/* get a GPUBuffer of at least `size' bytes; uses one from the buffer
* pool if possible, otherwise creates a new one
*
* Thread-unsafe version for internal usage only.
*/
static GPUBuffer *gpu_buffer_alloc_intern(size_t size)
{
GPUBufferPool *pool;
GPUBuffer *buf;
int i, bestfit = -1;
size_t bufsize;
/* bad case, leads to leak of buf since buf->pointer will allocate
* NULL, leading to return without cleanup. In any case better detect early
* psy-fi */
if (size == 0)
return NULL;
pool = gpu_get_global_buffer_pool();
/* not sure if this buffer pool code has been profiled much,
* seems to me that the graphics driver and system memory
* management might do this stuff anyway. --nicholas
*/
/* check the global buffer pool for a recently-deleted buffer
* that is at least as big as the request, but not more than
* twice as big */
for (i = 0; i < pool->totbuf; i++) {
bufsize = pool->buffers[i]->size;
/* check for an exact size match */
if (bufsize == size) {
bestfit = i;
break;
}
/* smaller buffers won't fit data and buffers at least
* twice as big are a waste of memory */
else if (bufsize > size && size > (bufsize / 2)) {
/* is it closer to the required size than the
* last appropriate buffer found. try to save
* memory */
if (bestfit == -1 || pool->buffers[bestfit]->size > bufsize) {
bestfit = i;
}
}
}
/* if an acceptable buffer was found in the pool, remove it
* from the pool and return it */
if (bestfit != -1) {
buf = pool->buffers[bestfit];
gpu_buffer_pool_remove_index(pool, bestfit);
return buf;
}
/* no acceptable buffer found in the pool, create a new one */
buf = MEM_callocN(sizeof(GPUBuffer), "GPUBuffer");
buf->size = size;
glGenBuffers(1, &buf->id);
glBindBuffer(GL_ARRAY_BUFFER, buf->id);
glBufferData(GL_ARRAY_BUFFER, size, NULL, GL_STATIC_DRAW);
glBindBuffer(GL_ARRAY_BUFFER, 0);
return buf;
}
/* Same as above, but safe for threading. */
GPUBuffer *GPU_buffer_alloc(size_t size)
{
GPUBuffer *buffer;
if (size == 0) {
/* Early out, no lock needed in this case. */
return NULL;
}
BLI_mutex_lock(&buffer_mutex);
buffer = gpu_buffer_alloc_intern(size);
BLI_mutex_unlock(&buffer_mutex);
return buffer;
}
/* release a GPUBuffer; does not free the actual buffer or its data,
* but rather moves it to the pool of recently-freed buffers for
* possible re-use
*
* Thread-unsafe version for internal usage only.
*/
static void gpu_buffer_free_intern(GPUBuffer *buffer)
{
GPUBufferPool *pool;
int i;
if (!buffer)
return;
pool = gpu_get_global_buffer_pool();
/* free the last used buffer in the queue if no more space, but only
* if we are in the main thread. for e.g. rendering or baking it can
* happen that we are in other thread and can't call OpenGL, in that
* case cleanup will be done GPU_buffer_pool_free_unused */
if (BLI_thread_is_main()) {
/* in main thread, safe to decrease size of pool back
* down to MAX_FREE_GPU_BUFFERS */
while (pool->totbuf >= MAX_FREE_GPU_BUFFERS)
gpu_buffer_pool_delete_last(pool);
}
else {
/* outside of main thread, can't safely delete the
* buffer, so increase pool size */
if (pool->maxsize == pool->totbuf) {
pool->maxsize += MAX_FREE_GPU_BUFFERS;
pool->buffers = MEM_reallocN(pool->buffers,
sizeof(GPUBuffer *) * pool->maxsize);
}
}
/* shift pool entries up by one */
for (i = pool->totbuf; i > 0; i--)
pool->buffers[i] = pool->buffers[i - 1];
/* insert the buffer into the beginning of the pool */
pool->buffers[0] = buffer;
pool->totbuf++;
}
/* Same as above, but safe for threading. */
void GPU_buffer_free(GPUBuffer *buffer)
{
if (!buffer) {
/* Early output, no need to lock in this case, */
return;
}
BLI_mutex_lock(&buffer_mutex);
gpu_buffer_free_intern(buffer);
BLI_mutex_unlock(&buffer_mutex);
}
void GPU_drawobject_free(DerivedMesh *dm)
{
GPUDrawObject *gdo;
int i;
if (!dm || !(gdo = dm->drawObject))
return;
for (i = 0; i < gdo->totmaterial; i++) {
if (gdo->materials[i].polys)
MEM_freeN(gdo->materials[i].polys);
}
MEM_freeN(gdo->materials);
if (gdo->vert_points)
MEM_freeN(gdo->vert_points);
#ifdef USE_GPU_POINT_LINK
MEM_freeN(gdo->vert_points_mem);
#endif
GPU_buffer_free(gdo->points);
GPU_buffer_free(gdo->normals);
GPU_buffer_free(gdo->uv);
GPU_buffer_free(gdo->uv_tex);
GPU_buffer_free(gdo->colors);
GPU_buffer_free(gdo->edges);
GPU_buffer_free(gdo->uvedges);
GPU_buffer_free(gdo->triangles);
MEM_freeN(gdo);
dm->drawObject = NULL;
}
static GPUBuffer *gpu_try_realloc(GPUBufferPool *pool, GPUBuffer *buffer, size_t size)
{
/* try freeing an entry from the pool
* and reallocating the buffer */
gpu_buffer_free_intern(buffer);
buffer = NULL;
while (pool->totbuf && !buffer) {
gpu_buffer_pool_delete_last(pool);
buffer = gpu_buffer_alloc_intern(size);
}
return buffer;
}
static GPUBuffer *gpu_buffer_setup(DerivedMesh *dm, GPUDrawObject *object,
int type, void *user, GPUBuffer *buffer)
{
GPUBufferPool *pool;
float *varray;
int *mat_orig_to_new;
int i;
const GPUBufferTypeSettings *ts = &gpu_buffer_type_settings[type];
GLenum target = ts->gl_buffer_type;
size_t size = gpu_buffer_size_from_type(dm, type);
GLboolean uploaded;
pool = gpu_get_global_buffer_pool();
BLI_mutex_lock(&buffer_mutex);
/* alloc a GPUBuffer; fall back to legacy mode on failure */
if (!buffer) {
if (!(buffer = gpu_buffer_alloc_intern(size))) {
BLI_mutex_unlock(&buffer_mutex);
return NULL;
}
}
mat_orig_to_new = MEM_mallocN(sizeof(*mat_orig_to_new) * dm->totmat,
"GPU_buffer_setup.mat_orig_to_new");
for (i = 0; i < object->totmaterial; i++) {
/* map from original material index to new
* GPUBufferMaterial index */
mat_orig_to_new[object->materials[i].mat_nr] = i;
}
/* bind the buffer and discard previous data,
* avoids stalling gpu */
glBindBuffer(target, buffer->id);
glBufferData(target, buffer->size, NULL, GL_STATIC_DRAW);
/* attempt to map the buffer */
if (!(varray = glMapBuffer(target, GL_WRITE_ONLY))) {
buffer = gpu_try_realloc(pool, buffer, size);
/* allocation still failed; unfortunately we need to exit */
if (!(buffer && (varray = glMapBuffer(target, GL_WRITE_ONLY)))) {
if (buffer)
gpu_buffer_free_intern(buffer);
BLI_mutex_unlock(&buffer_mutex);
return NULL;
}
}
uploaded = GL_FALSE;
/* attempt to upload the data to the VBO */
while (uploaded == GL_FALSE) {
dm->copy_gpu_data(dm, type, varray, mat_orig_to_new, user);
/* glUnmapBuffer returns GL_FALSE if
* the data store is corrupted; retry
* in that case */
uploaded = glUnmapBuffer(target);
}
glBindBuffer(target, 0);
MEM_freeN(mat_orig_to_new);
BLI_mutex_unlock(&buffer_mutex);
return buffer;
}
/* get the GPUDrawObject buffer associated with a type */
static GPUBuffer **gpu_drawobject_buffer_from_type(GPUDrawObject *gdo, GPUBufferType type)
{
switch (type) {
case GPU_BUFFER_VERTEX:
return &gdo->points;
case GPU_BUFFER_NORMAL:
return &gdo->normals;
case GPU_BUFFER_COLOR:
return &gdo->colors;
case GPU_BUFFER_UV:
return &gdo->uv;
case GPU_BUFFER_UV_TEXPAINT:
return &gdo->uv_tex;
case GPU_BUFFER_EDGE:
return &gdo->edges;
case GPU_BUFFER_UVEDGE:
return &gdo->uvedges;
case GPU_BUFFER_TRIANGLES:
return &gdo->triangles;
default:
return NULL;
}
}
/* get the amount of space to allocate for a buffer of a particular type */
static size_t gpu_buffer_size_from_type(DerivedMesh *dm, GPUBufferType type)
{
const int components = gpu_buffer_type_settings[type].num_components;
switch (type) {
case GPU_BUFFER_VERTEX:
return sizeof(float) * components * (dm->drawObject->tot_loop_verts + dm->drawObject->tot_loose_point);
case GPU_BUFFER_NORMAL:
return sizeof(short) * components * dm->drawObject->tot_loop_verts;
case GPU_BUFFER_COLOR:
return sizeof(char) * components * dm->drawObject->tot_loop_verts;
case GPU_BUFFER_UV:
return sizeof(float) * components * dm->drawObject->tot_loop_verts;
case GPU_BUFFER_UV_TEXPAINT:
return sizeof(float) * components * dm->drawObject->tot_loop_verts;
case GPU_BUFFER_EDGE:
return sizeof(int) * components * dm->drawObject->totedge;
case GPU_BUFFER_UVEDGE:
return sizeof(int) * components * dm->drawObject->tot_loop_verts;
case GPU_BUFFER_TRIANGLES:
return sizeof(int) * components * dm->drawObject->tot_triangle_point;
default:
return -1;
}
}
/* call gpu_buffer_setup with settings for a particular type of buffer */
static GPUBuffer *gpu_buffer_setup_type(DerivedMesh *dm, GPUBufferType type, GPUBuffer *buf)
{
void *user_data = NULL;
/* special handling for MCol and UV buffers */
if (type == GPU_BUFFER_COLOR) {
if (!(user_data = DM_get_loop_data_layer(dm, dm->drawObject->colType)))
return NULL;
}
else if (ELEM(type, GPU_BUFFER_UV, GPU_BUFFER_UV_TEXPAINT)) {
if (!DM_get_loop_data_layer(dm, CD_MLOOPUV))
return NULL;
}
buf = gpu_buffer_setup(dm, dm->drawObject, type, user_data, buf);
return buf;
}
/* get the buffer of `type', initializing the GPUDrawObject and
* buffer if needed */
static GPUBuffer *gpu_buffer_setup_common(DerivedMesh *dm, GPUBufferType type, bool update)
{
GPUBuffer **buf;
if (!dm->drawObject)
dm->drawObject = dm->gpuObjectNew(dm);
buf = gpu_drawobject_buffer_from_type(dm->drawObject, type);
if (!(*buf))
*buf = gpu_buffer_setup_type(dm, type, NULL);
else if (update)
*buf = gpu_buffer_setup_type(dm, type, *buf);
return *buf;
}
void GPU_vertex_setup(DerivedMesh *dm)
{
if (!gpu_buffer_setup_common(dm, GPU_BUFFER_VERTEX, false))
return;
glEnableClientState(GL_VERTEX_ARRAY);
glBindBuffer(GL_ARRAY_BUFFER, dm->drawObject->points->id);
glVertexPointer(3, GL_FLOAT, 0, 0);
GLStates |= GPU_BUFFER_VERTEX_STATE;
}
void GPU_normal_setup(DerivedMesh *dm)
{
if (!gpu_buffer_setup_common(dm, GPU_BUFFER_NORMAL, false))
return;
glEnableClientState(GL_NORMAL_ARRAY);
glBindBuffer(GL_ARRAY_BUFFER, dm->drawObject->normals->id);
glNormalPointer(GL_SHORT, 4 * sizeof(short), 0);
GLStates |= GPU_BUFFER_NORMAL_STATE;
}
void GPU_uv_setup(DerivedMesh *dm)
{
if (!gpu_buffer_setup_common(dm, GPU_BUFFER_UV, false))
return;
glEnableClientState(GL_TEXTURE_COORD_ARRAY);
glBindBuffer(GL_ARRAY_BUFFER, dm->drawObject->uv->id);
glTexCoordPointer(2, GL_FLOAT, 0, 0);
GLStates |= GPU_BUFFER_TEXCOORD_UNIT_0_STATE;
}
void GPU_texpaint_uv_setup(DerivedMesh *dm)
{
if (!gpu_buffer_setup_common(dm, GPU_BUFFER_UV_TEXPAINT, false))
return;
glEnableClientState(GL_TEXTURE_COORD_ARRAY);
glBindBuffer(GL_ARRAY_BUFFER, dm->drawObject->uv_tex->id);
glTexCoordPointer(2, GL_FLOAT, 4 * sizeof(float), 0);
glClientActiveTexture(GL_TEXTURE2);
glEnableClientState(GL_TEXTURE_COORD_ARRAY);
glTexCoordPointer(2, GL_FLOAT, 4 * sizeof(float), BUFFER_OFFSET(2 * sizeof(float)));
glClientActiveTexture(GL_TEXTURE0);
GLStates |= GPU_BUFFER_TEXCOORD_UNIT_0_STATE | GPU_BUFFER_TEXCOORD_UNIT_2_STATE;
}
void GPU_color_setup(DerivedMesh *dm, int colType)
{
bool update = false;
if (!dm->drawObject) {
/* XXX Not really nice, but we need a valid gpu draw object to set the colType...
* Else we would have to add a new param to gpu_buffer_setup_common. */
dm->drawObject = dm->gpuObjectNew(dm);
dm->dirty &= ~DM_DIRTY_MCOL_UPDATE_DRAW;
dm->drawObject->colType = colType;
}
/* In paint mode, dm may stay the same during stroke, however we still want to update colors!
* Also check in case we changed color type (i.e. which MCol cdlayer we use). */
else if ((dm->dirty & DM_DIRTY_MCOL_UPDATE_DRAW) || (colType != dm->drawObject->colType)) {
update = true;
dm->dirty &= ~DM_DIRTY_MCOL_UPDATE_DRAW;
dm->drawObject->colType = colType;
}
if (!gpu_buffer_setup_common(dm, GPU_BUFFER_COLOR, update))
return;
glEnableClientState(GL_COLOR_ARRAY);
glBindBuffer(GL_ARRAY_BUFFER, dm->drawObject->colors->id);
glColorPointer(3, GL_UNSIGNED_BYTE, 0, 0);
GLStates |= GPU_BUFFER_COLOR_STATE;
}
void GPU_buffer_bind_as_color(GPUBuffer *buffer)
{
glEnableClientState(GL_COLOR_ARRAY);
glBindBuffer(GL_ARRAY_BUFFER, buffer->id);
glColorPointer(4, GL_UNSIGNED_BYTE, 0, 0);
GLStates |= GPU_BUFFER_COLOR_STATE;
}
void GPU_edge_setup(DerivedMesh *dm)
{
if (!gpu_buffer_setup_common(dm, GPU_BUFFER_EDGE, false))
return;
if (!gpu_buffer_setup_common(dm, GPU_BUFFER_VERTEX, false))
return;
glEnableClientState(GL_VERTEX_ARRAY);
glBindBuffer(GL_ARRAY_BUFFER, dm->drawObject->points->id);
glVertexPointer(3, GL_FLOAT, 0, 0);
glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, dm->drawObject->edges->id);
GLStates |= (GPU_BUFFER_VERTEX_STATE | GPU_BUFFER_ELEMENT_STATE);
}
void GPU_uvedge_setup(DerivedMesh *dm)
{
if (!gpu_buffer_setup_common(dm, GPU_BUFFER_UVEDGE, false))
return;
glEnableClientState(GL_VERTEX_ARRAY);
glBindBuffer(GL_ARRAY_BUFFER, dm->drawObject->uvedges->id);
glVertexPointer(2, GL_FLOAT, 0, 0);
GLStates |= GPU_BUFFER_VERTEX_STATE;
}
void GPU_triangle_setup(struct DerivedMesh *dm)
{
if (!gpu_buffer_setup_common(dm, GPU_BUFFER_TRIANGLES, false))
return;
glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, dm->drawObject->triangles->id);
GLStates |= GPU_BUFFER_ELEMENT_STATE;
}
static int gpu_typesize(int type)
{
switch (type) {
case GL_FLOAT:
return sizeof(float);
case GL_INT:
return sizeof(int);
case GL_UNSIGNED_INT:
return sizeof(unsigned int);
case GL_BYTE:
return sizeof(char);
case GL_UNSIGNED_BYTE:
return sizeof(unsigned char);
default:
return 0;
}
}
int GPU_attrib_element_size(GPUAttrib data[], int numdata)
{
int i, elementsize = 0;
for (i = 0; i < numdata; i++) {
int typesize = gpu_typesize(data[i].type);
if (typesize != 0)
elementsize += typesize * data[i].size;
}
return elementsize;
}
void GPU_interleaved_attrib_setup(GPUBuffer *buffer, GPUAttrib data[], int numdata, int element_size)
{
int i;
int elementsize;
size_t offset = 0;
for (i = 0; i < MAX_GPU_ATTRIB_DATA; i++) {
if (attribData[i].index != -1) {
glDisableVertexAttribArray(attribData[i].index);
}
else
break;
}
if (element_size == 0)
elementsize = GPU_attrib_element_size(data, numdata);
else
elementsize = element_size;
glBindBuffer(GL_ARRAY_BUFFER, buffer->id);
for (i = 0; i < numdata; i++) {
glEnableVertexAttribArray(data[i].index);
int info = 0;
if (data[i].type == GL_UNSIGNED_BYTE) {
info |= GPU_ATTR_INFO_SRGB;
}
glUniform1i(data[i].info_index, info);
glVertexAttribPointer(data[i].index, data[i].size, data[i].type,
GL_TRUE, elementsize, BUFFER_OFFSET(offset));
offset += data[i].size * gpu_typesize(data[i].type);
attribData[i].index = data[i].index;
attribData[i].size = data[i].size;
attribData[i].type = data[i].type;
}
attribData[numdata].index = -1;
}
void GPU_interleaved_attrib_unbind(void)
{
int i;
for (i = 0; i < MAX_GPU_ATTRIB_DATA; i++) {
if (attribData[i].index != -1) {
glDisableVertexAttribArray(attribData[i].index);
}
else
break;
}
attribData[0].index = -1;
}
void GPU_buffers_unbind(void)
{
int i;
if (GLStates & GPU_BUFFER_VERTEX_STATE)
glDisableClientState(GL_VERTEX_ARRAY);
if (GLStates & GPU_BUFFER_NORMAL_STATE)
glDisableClientState(GL_NORMAL_ARRAY);
if (GLStates & GPU_BUFFER_TEXCOORD_UNIT_0_STATE)
glDisableClientState(GL_TEXTURE_COORD_ARRAY);
if (GLStates & GPU_BUFFER_TEXCOORD_UNIT_2_STATE) {
glClientActiveTexture(GL_TEXTURE2);
glDisableClientState(GL_TEXTURE_COORD_ARRAY);
glClientActiveTexture(GL_TEXTURE0);
}
if (GLStates & GPU_BUFFER_COLOR_STATE)
glDisableClientState(GL_COLOR_ARRAY);
if (GLStates & GPU_BUFFER_ELEMENT_STATE)
glBindBuffer(GL_ELEMENT_ARRAY_BUFFER, 0);
GLStates &= ~(GPU_BUFFER_VERTEX_STATE | GPU_BUFFER_NORMAL_STATE |
GPU_BUFFER_TEXCOORD_UNIT_0_STATE | GPU_BUFFER_TEXCOORD_UNIT_2_STATE |
GPU_BUFFER_COLOR_STATE | GPU_BUFFER_ELEMENT_STATE);
for (i = 0; i < MAX_GPU_ATTRIB_DATA; i++) {
if (attribData[i].index != -1) {
glDisableVertexAttribArray(attribData[i].index);
}
else
break;
}
attribData[0].index = -1;
glBindBuffer(GL_ARRAY_BUFFER, 0);
}
void GPU_color_switch(int mode)
{
if (mode) {
if (!(GLStates & GPU_BUFFER_COLOR_STATE))
glEnableClientState(GL_COLOR_ARRAY);
GLStates |= GPU_BUFFER_COLOR_STATE;
}
else {
if (GLStates & GPU_BUFFER_COLOR_STATE)
glDisableClientState(GL_COLOR_ARRAY);
GLStates &= ~GPU_BUFFER_COLOR_STATE;
}
}
static int gpu_binding_type_gl[] =
{
GL_ARRAY_BUFFER,
GL_ELEMENT_ARRAY_BUFFER
};
void *GPU_buffer_lock(GPUBuffer *buffer, GPUBindingType binding)
{
float *varray;
int bindtypegl;
if (!buffer)
return 0;
bindtypegl = gpu_binding_type_gl[binding];
glBindBuffer(bindtypegl, buffer->id);
varray = glMapBuffer(bindtypegl, GL_WRITE_ONLY);
return varray;
}
void *GPU_buffer_lock_stream(GPUBuffer *buffer, GPUBindingType binding)
{
float *varray;
int bindtypegl;
if (!buffer)
return 0;
bindtypegl = gpu_binding_type_gl[binding];
glBindBuffer(bindtypegl, buffer->id);
/* discard previous data, avoid stalling gpu */
glBufferData(bindtypegl, buffer->size, 0, GL_STREAM_DRAW);
varray = glMapBuffer(bindtypegl, GL_WRITE_ONLY);
return varray;
}
void GPU_buffer_unlock(GPUBuffer *UNUSED(buffer), GPUBindingType binding)
{
int bindtypegl = gpu_binding_type_gl[binding];
/* note: this operation can fail, could return
* an error code from this function? */
glUnmapBuffer(bindtypegl);
glBindBuffer(bindtypegl, 0);
}
void GPU_buffer_bind(GPUBuffer *buffer, GPUBindingType binding)
{
int bindtypegl = gpu_binding_type_gl[binding];
glBindBuffer(bindtypegl, buffer->id);
}
void GPU_buffer_unbind(GPUBuffer *UNUSED(buffer), GPUBindingType binding)
{
int bindtypegl = gpu_binding_type_gl[binding];
glBindBuffer(bindtypegl, 0);
}
/* used for drawing edges */
void GPU_buffer_draw_elements(GPUBuffer *UNUSED(elements), unsigned int mode, int start, int count)
{
glDrawElements(mode, count, GL_UNSIGNED_INT, BUFFER_OFFSET(start * sizeof(unsigned int)));
}
/* XXX: the rest of the code in this file is used for optimized PBVH
* drawing and doesn't interact at all with the buffer code above */
/* Convenience struct for building the VBO. */
typedef struct {
float co[3];
short no[3];
/* inserting this to align the 'color' field to a four-byte
* boundary; drastically increases viewport performance on my
* drivers (Gallium/Radeon) --nicholasbishop */
char pad[2];
unsigned char color[3];
} VertexBufferFormat;
struct GPU_PBVH_Buffers {
/* opengl buffer handles */
GPUBuffer *vert_buf, *index_buf, *index_buf_fast;
GLenum index_type;
int *baseelemarray;
void **baseindex;
/* mesh pointers in case buffer allocation fails */
const MPoly *mpoly;
const MLoop *mloop;
const MLoopTri *looptri;
const MVert *mvert;
const int *face_indices;
int face_indices_len;
const float *vmask;
/* grid pointers */
CCGKey gridkey;
CCGElem **grids;
const DMFlagMat *grid_flag_mats;
BLI_bitmap * const *grid_hidden;
const int *grid_indices;
int totgrid;
bool has_hidden;
bool is_index_buf_global; /* Means index_buf uses global bvh's grid_common_gpu_buffer, **DO NOT** free it! */
bool use_bmesh;
unsigned int tot_tri, tot_quad;
/* The PBVH ensures that either all faces in the node are
* smooth-shaded or all faces are flat-shaded */
bool smooth;
bool show_diffuse_color;
bool use_matcaps;
float diffuse_color[4];
};
static float gpu_color_from_mask(float mask)
{
return 1.0f - mask * 0.75f;
}
static void gpu_color_from_mask_copy(float mask, const float diffuse_color[4], unsigned char out[3])
{
float mask_color;
mask_color = gpu_color_from_mask(mask) * 255.0f;
out[0] = diffuse_color[0] * mask_color;
out[1] = diffuse_color[1] * mask_color;
out[2] = diffuse_color[2] * mask_color;
}
static void gpu_color_from_mask_quad_copy(const CCGKey *key,
CCGElem *a, CCGElem *b,
CCGElem *c, CCGElem *d,
const float *diffuse_color,
unsigned char out[3])
{
float mask_color =
gpu_color_from_mask((*CCG_elem_mask(key, a) +
*CCG_elem_mask(key, b) +
*CCG_elem_mask(key, c) +
*CCG_elem_mask(key, d)) * 0.25f) * 255.0f;
out[0] = diffuse_color[0] * mask_color;
out[1] = diffuse_color[1] * mask_color;
out[2] = diffuse_color[2] * mask_color;
}
void GPU_pbvh_mesh_buffers_update(
GPU_PBVH_Buffers *buffers, const MVert *mvert,
const int *vert_indices, int totvert, const float *vmask,
const int (*face_vert_indices)[3], bool show_diffuse_color)
{
VertexBufferFormat *vert_data;
int i;
buffers->vmask = vmask;
buffers->show_diffuse_color = show_diffuse_color;
buffers->use_matcaps = GPU_material_use_matcaps_get();
{
int totelem = (buffers->smooth ? totvert : (buffers->tot_tri * 3));
float diffuse_color[4] = {0.8f, 0.8f, 0.8f, 0.8f};
if (buffers->use_matcaps)
diffuse_color[0] = diffuse_color[1] = diffuse_color[2] = 1.0;
else if (show_diffuse_color) {
const MLoopTri *lt = &buffers->looptri[buffers->face_indices[0]];
const MPoly *mp = &buffers->mpoly[lt->poly];
GPU_material_diffuse_get(mp->mat_nr + 1, diffuse_color);
}
copy_v4_v4(buffers->diffuse_color, diffuse_color);
uchar diffuse_color_ub[4];
rgba_float_to_uchar(diffuse_color_ub, diffuse_color);
/* Build VBO */
if (buffers->vert_buf)
GPU_buffer_free(buffers->vert_buf);
buffers->vert_buf = GPU_buffer_alloc(sizeof(VertexBufferFormat) * totelem);
vert_data = GPU_buffer_lock(buffers->vert_buf, GPU_BINDING_ARRAY);
if (vert_data) {
/* Vertex data is shared if smooth-shaded, but separate
* copies are made for flat shading because normals
* shouldn't be shared. */
if (buffers->smooth) {
for (i = 0; i < totvert; ++i) {
const MVert *v = &mvert[vert_indices[i]];
VertexBufferFormat *out = vert_data + i;
copy_v3_v3(out->co, v->co);
memcpy(out->no, v->no, sizeof(short) * 3);
}
for (i = 0; i < buffers->face_indices_len; i++) {
const MLoopTri *lt = &buffers->looptri[buffers->face_indices[i]];
for (uint j = 0; j < 3; j++) {
VertexBufferFormat *out = vert_data + face_vert_indices[i][j];
if (vmask) {
uint v_index = buffers->mloop[lt->tri[j]].v;
gpu_color_from_mask_copy(vmask[v_index], diffuse_color, out->color);
}
else {
copy_v3_v3_uchar(out->color, diffuse_color_ub);
}
}
}
}
else {
/* calculate normal for each polygon only once */
unsigned int mpoly_prev = UINT_MAX;
short no[3];
for (i = 0; i < buffers->face_indices_len; ++i) {
const MLoopTri *lt = &buffers->looptri[buffers->face_indices[i]];
const unsigned int vtri[3] = {
buffers->mloop[lt->tri[0]].v,
buffers->mloop[lt->tri[1]].v,
buffers->mloop[lt->tri[2]].v,
};
if (paint_is_face_hidden(lt, mvert, buffers->mloop))
continue;
/* Face normal and mask */
if (lt->poly != mpoly_prev) {
const MPoly *mp = &buffers->mpoly[lt->poly];
float fno[3];
BKE_mesh_calc_poly_normal(mp, &buffers->mloop[mp->loopstart], mvert, fno);
normal_float_to_short_v3(no, fno);
mpoly_prev = lt->poly;
}
uchar color_ub[3];
if (vmask) {
float fmask = (vmask[vtri[0]] + vmask[vtri[1]] + vmask[vtri[2]]) / 3.0f;
gpu_color_from_mask_copy(fmask, diffuse_color, color_ub);
}
else {
copy_v3_v3_uchar(color_ub, diffuse_color_ub);
}
for (uint j = 0; j < 3; j++) {
const MVert *v = &mvert[vtri[j]];
VertexBufferFormat *out = vert_data;
copy_v3_v3(out->co, v->co);
copy_v3_v3_short(out->no, no);
copy_v3_v3_uchar(out->color, color_ub);
vert_data++;
}
}
}
GPU_buffer_unlock(buffers->vert_buf, GPU_BINDING_ARRAY);
}
else {
GPU_buffer_free(buffers->vert_buf);
buffers->vert_buf = NULL;
}
}
buffers->mvert = mvert;
}
GPU_PBVH_Buffers *GPU_pbvh_mesh_buffers_build(
const int (*face_vert_indices)[3],
const MPoly *mpoly, const MLoop *mloop, const MLoopTri *looptri,
const MVert *mvert,
const int *face_indices,
const int face_indices_len)
{
GPU_PBVH_Buffers *buffers;
unsigned short *tri_data;
int i, j, tottri;
buffers = MEM_callocN(sizeof(GPU_PBVH_Buffers), "GPU_Buffers");
buffers->index_type = GL_UNSIGNED_SHORT;
buffers->smooth = mpoly[looptri[face_indices[0]].poly].flag & ME_SMOOTH;
buffers->show_diffuse_color = false;
buffers->use_matcaps = false;
/* Count the number of visible triangles */
for (i = 0, tottri = 0; i < face_indices_len; ++i) {
const MLoopTri *lt = &looptri[face_indices[i]];
if (!paint_is_face_hidden(lt, mvert, mloop))
tottri++;
}
if (tottri == 0) {
buffers->tot_tri = 0;
buffers->mpoly = mpoly;
buffers->mloop = mloop;
buffers->looptri = looptri;
buffers->face_indices = face_indices;
buffers->face_indices_len = 0;
return buffers;
}
/* An element index buffer is used for smooth shading, but flat
* shading requires separate vertex normals so an index buffer is
* can't be used there. */
if (buffers->smooth) {
buffers->index_buf = GPU_buffer_alloc(sizeof(unsigned short) * tottri * 3);
buffers->is_index_buf_global = false;
}
if (buffers->index_buf) {
/* Fill the triangle buffer */
tri_data = GPU_buffer_lock(buffers->index_buf, GPU_BINDING_INDEX);
if (tri_data) {
for (i = 0; i < face_indices_len; ++i) {
const MLoopTri *lt = &looptri[face_indices[i]];
/* Skip hidden faces */
if (paint_is_face_hidden(lt, mvert, mloop))
continue;
for (j = 0; j < 3; ++j) {
*tri_data = face_vert_indices[i][j];
tri_data++;
}
}
GPU_buffer_unlock(buffers->index_buf, GPU_BINDING_INDEX);
}
else {
if (!buffers->is_index_buf_global) {
GPU_buffer_free(buffers->index_buf);
}
buffers->index_buf = NULL;
buffers->is_index_buf_global = false;
}
}
buffers->tot_tri = tottri;
buffers->mpoly = mpoly;
buffers->mloop = mloop;
buffers->looptri = looptri;
buffers->face_indices = face_indices;
buffers->face_indices_len = face_indices_len;
return buffers;
}
void GPU_pbvh_grid_buffers_update(
GPU_PBVH_Buffers *buffers, CCGElem **grids,
const DMFlagMat *grid_flag_mats, int *grid_indices,
int totgrid, const CCGKey *key, bool show_diffuse_color)
{
VertexBufferFormat *vert_data;
int i, j, k, x, y;
buffers->show_diffuse_color = show_diffuse_color;
buffers->use_matcaps = GPU_material_use_matcaps_get();
buffers->smooth = grid_flag_mats[grid_indices[0]].flag & ME_SMOOTH;
/* Build VBO */
if (buffers->vert_buf) {
const int has_mask = key->has_mask;
float diffuse_color[4] = {0.8f, 0.8f, 0.8f, 1.0f};
if (buffers->use_matcaps)
diffuse_color[0] = diffuse_color[1] = diffuse_color[2] = 1.0;
else if (show_diffuse_color) {
const DMFlagMat *flags = &grid_flag_mats[grid_indices[0]];
GPU_material_diffuse_get(flags->mat_nr + 1, diffuse_color);
}
copy_v4_v4(buffers->diffuse_color, diffuse_color);
vert_data = GPU_buffer_lock_stream(buffers->vert_buf, GPU_BINDING_ARRAY);
if (vert_data) {
for (i = 0; i < totgrid; ++i) {
VertexBufferFormat *vd = vert_data;
CCGElem *grid = grids[grid_indices[i]];
for (y = 0; y < key->grid_size; y++) {
for (x = 0; x < key->grid_size; x++) {
CCGElem *elem = CCG_grid_elem(key, grid, x, y);
copy_v3_v3(vd->co, CCG_elem_co(key, elem));
if (buffers->smooth) {
normal_float_to_short_v3(vd->no, CCG_elem_no(key, elem));
if (has_mask) {
gpu_color_from_mask_copy(*CCG_elem_mask(key, elem),
diffuse_color, vd->color);
}
}
vd++;
}
}
if (!buffers->smooth) {
/* for flat shading, recalc normals and set the last vertex of
* each triangle in the index buffer to have the flat normal as
* that is what opengl will use */
for (j = 0; j < key->grid_size - 1; j++) {
for (k = 0; k < key->grid_size - 1; k++) {
CCGElem *elems[4] = {
CCG_grid_elem(key, grid, k, j + 1),
CCG_grid_elem(key, grid, k + 1, j + 1),
CCG_grid_elem(key, grid, k + 1, j),
CCG_grid_elem(key, grid, k, j)
};
float fno[3];
normal_quad_v3(fno,
CCG_elem_co(key, elems[0]),
CCG_elem_co(key, elems[1]),
CCG_elem_co(key, elems[2]),
CCG_elem_co(key, elems[3]));
vd = vert_data + (j + 1) * key->grid_size + k;
normal_float_to_short_v3(vd->no, fno);
if (has_mask) {
gpu_color_from_mask_quad_copy(key,
elems[0],
elems[1],
elems[2],
elems[3],
diffuse_color,
vd->color);
}
}
}
}
vert_data += key->grid_area;
}
GPU_buffer_unlock(buffers->vert_buf, GPU_BINDING_ARRAY);
}
else {
GPU_buffer_free(buffers->vert_buf);
buffers->vert_buf = NULL;
}
}
buffers->grids = grids;
buffers->grid_indices = grid_indices;
buffers->totgrid = totgrid;
buffers->grid_flag_mats = grid_flag_mats;
buffers->gridkey = *key;
//printf("node updated %p\n", buffers);
}
/* Build the element array buffer of grid indices using either
* unsigned shorts or unsigned ints. */
#define FILL_QUAD_BUFFER(type_, tot_quad_, buffer_) \
{ \
type_ *tri_data; \
int offset = 0; \
int i, j, k; \
buffer_ = GPU_buffer_alloc(sizeof(type_) * (tot_quad_) * 6); \
\
/* Fill the buffer */ \
tri_data = GPU_buffer_lock(buffer_, GPU_BINDING_INDEX); \
if (tri_data) { \
for (i = 0; i < totgrid; ++i) { \
BLI_bitmap *gh = NULL; \
if (grid_hidden) \
gh = grid_hidden[(grid_indices)[i]]; \
\
for (j = 0; j < gridsize - 1; ++j) { \
for (k = 0; k < gridsize - 1; ++k) { \
/* Skip hidden grid face */ \
if (gh && \
paint_is_grid_face_hidden(gh, \
gridsize, k, j)) \
continue; \
\
*(tri_data++) = offset + j * gridsize + k + 1; \
*(tri_data++) = offset + j * gridsize + k; \
*(tri_data++) = offset + (j + 1) * gridsize + k; \
\
*(tri_data++) = offset + (j + 1) * gridsize + k + 1; \
*(tri_data++) = offset + j * gridsize + k + 1; \
*(tri_data++) = offset + (j + 1) * gridsize + k; \
} \
} \
\
offset += gridsize * gridsize; \
} \
GPU_buffer_unlock(buffer_, GPU_BINDING_INDEX); \
} \
else { \
GPU_buffer_free(buffer_); \
(buffer_) = NULL; \
} \
} (void)0
/* end FILL_QUAD_BUFFER */
static GPUBuffer *gpu_get_grid_buffer(
int gridsize, GLenum *index_type, unsigned *totquad, GridCommonGPUBuffer **grid_common_gpu_buffer)
{
/* used in the FILL_QUAD_BUFFER macro */
BLI_bitmap * const *grid_hidden = NULL;
const int *grid_indices = NULL;
int totgrid = 1;
GridCommonGPUBuffer *gridbuff = *grid_common_gpu_buffer;
if (gridbuff == NULL) {
*grid_common_gpu_buffer = gridbuff = MEM_mallocN(sizeof(GridCommonGPUBuffer), __func__);
gridbuff->mres_buffer = NULL;
gridbuff->mres_prev_gridsize = -1;
gridbuff->mres_prev_index_type = 0;
gridbuff->mres_prev_totquad = 0;
}
/* VBO is already built */
if (gridbuff->mres_buffer && gridbuff->mres_prev_gridsize == gridsize) {
*index_type = gridbuff->mres_prev_index_type;
*totquad = gridbuff->mres_prev_totquad;
return gridbuff->mres_buffer;
}
/* we can't reuse old, delete the existing buffer */
else if (gridbuff->mres_buffer) {
GPU_buffer_free(gridbuff->mres_buffer);
}
/* Build new VBO */
*totquad = (gridsize - 1) * (gridsize - 1);
if (gridsize * gridsize < USHRT_MAX) {
*index_type = GL_UNSIGNED_SHORT;
FILL_QUAD_BUFFER(unsigned short, *totquad, gridbuff->mres_buffer);
}
else {
*index_type = GL_UNSIGNED_INT;
FILL_QUAD_BUFFER(unsigned int, *totquad, gridbuff->mres_buffer);
}
gridbuff->mres_prev_gridsize = gridsize;
gridbuff->mres_prev_index_type = *index_type;
gridbuff->mres_prev_totquad = *totquad;
return gridbuff->mres_buffer;
}
#define FILL_FAST_BUFFER(type_) \
{ \
type_ *buffer; \
buffers->index_buf_fast = GPU_buffer_alloc(sizeof(type_) * 6 * totgrid); \
buffer = GPU_buffer_lock(buffers->index_buf_fast, GPU_BINDING_INDEX); \
if (buffer) { \
int i; \
for (i = 0; i < totgrid; i++) { \
int currentquad = i * 6; \
buffer[currentquad] = i * gridsize * gridsize + gridsize - 1; \
buffer[currentquad + 1] = i * gridsize * gridsize; \
buffer[currentquad + 2] = (i + 1) * gridsize * gridsize - gridsize; \
buffer[currentquad + 3] = (i + 1) * gridsize * gridsize - 1; \
buffer[currentquad + 4] = i * gridsize * gridsize + gridsize - 1; \
buffer[currentquad + 5] = (i + 1) * gridsize * gridsize - gridsize; \
} \
GPU_buffer_unlock(buffers->index_buf_fast, GPU_BINDING_INDEX); \
} \
else { \
GPU_buffer_free(buffers->index_buf_fast); \
buffers->index_buf_fast = NULL; \
} \
} (void)0
GPU_PBVH_Buffers *GPU_pbvh_grid_buffers_build(
int *grid_indices, int totgrid, BLI_bitmap **grid_hidden, int gridsize, const CCGKey *key,
GridCommonGPUBuffer **grid_common_gpu_buffer)
{
GPU_PBVH_Buffers *buffers;
int totquad;
int fully_visible_totquad = (gridsize - 1) * (gridsize - 1) * totgrid;
buffers = MEM_callocN(sizeof(GPU_PBVH_Buffers), "GPU_Buffers");
buffers->grid_hidden = grid_hidden;
buffers->totgrid = totgrid;
buffers->show_diffuse_color = false;
buffers->use_matcaps = false;
/* Count the number of quads */
totquad = BKE_pbvh_count_grid_quads(grid_hidden, grid_indices, totgrid, gridsize);
/* totally hidden node, return here to avoid BufferData with zero below. */
if (totquad == 0)
return buffers;
/* create and fill indices of the fast buffer too */
if (totgrid * gridsize * gridsize < USHRT_MAX) {
FILL_FAST_BUFFER(unsigned short);
}
else {
FILL_FAST_BUFFER(unsigned int);
}
if (totquad == fully_visible_totquad) {
buffers->index_buf = gpu_get_grid_buffer(
gridsize, &buffers->index_type, &buffers->tot_quad, grid_common_gpu_buffer);
buffers->has_hidden = false;
buffers->is_index_buf_global = true;
}
else {
buffers->tot_quad = totquad;
if (totgrid * gridsize * gridsize < USHRT_MAX) {
buffers->index_type = GL_UNSIGNED_SHORT;
FILL_QUAD_BUFFER(unsigned short, totquad, buffers->index_buf);
}
else {
buffers->index_type = GL_UNSIGNED_INT;
FILL_QUAD_BUFFER(unsigned int, totquad, buffers->index_buf);
}
buffers->has_hidden = true;
buffers->is_index_buf_global = false;
}
/* Build coord/normal VBO */
if (buffers->index_buf)
buffers->vert_buf = GPU_buffer_alloc(sizeof(VertexBufferFormat) * totgrid * key->grid_area);
if (GLEW_ARB_draw_elements_base_vertex /* 3.2 */) {
int i;
buffers->baseelemarray = MEM_mallocN(sizeof(int) * totgrid * 2, "GPU_PBVH_Buffers.baseelemarray");
buffers->baseindex = MEM_mallocN(sizeof(void *) * totgrid, "GPU_PBVH_Buffers.baseindex");
for (i = 0; i < totgrid; i++) {
buffers->baseelemarray[i] = buffers->tot_quad * 6;
buffers->baseelemarray[i + totgrid] = i * key->grid_area;
buffers->baseindex[i] = NULL;
}
}
return buffers;
}
#undef FILL_QUAD_BUFFER
/* Output a BMVert into a VertexBufferFormat array
*
* The vertex is skipped if hidden, otherwise the output goes into
* index '*v_index' in the 'vert_data' array and '*v_index' is
* incremented.
*/
static void gpu_bmesh_vert_to_buffer_copy(BMVert *v,
VertexBufferFormat *vert_data,
int *v_index,
const float fno[3],
const float *fmask,
const int cd_vert_mask_offset,
const float diffuse_color[4])
{
if (!BM_elem_flag_test(v, BM_ELEM_HIDDEN)) {
VertexBufferFormat *vd = &vert_data[*v_index];
/* Set coord, normal, and mask */
copy_v3_v3(vd->co, v->co);
normal_float_to_short_v3(vd->no, fno ? fno : v->no);
gpu_color_from_mask_copy(
fmask ? *fmask :
BM_ELEM_CD_GET_FLOAT(v, cd_vert_mask_offset),
diffuse_color,
vd->color);
/* Assign index for use in the triangle index buffer */
/* note: caller must set: bm->elem_index_dirty |= BM_VERT; */
BM_elem_index_set(v, (*v_index)); /* set_dirty! */
(*v_index)++;
}
}
/* Return the total number of vertices that don't have BM_ELEM_HIDDEN set */
static int gpu_bmesh_vert_visible_count(GSet *bm_unique_verts,
GSet *bm_other_verts)
{
GSetIterator gs_iter;
int totvert = 0;
GSET_ITER (gs_iter, bm_unique_verts) {
BMVert *v = BLI_gsetIterator_getKey(&gs_iter);
if (!BM_elem_flag_test(v, BM_ELEM_HIDDEN))
totvert++;
}
GSET_ITER (gs_iter, bm_other_verts) {
BMVert *v = BLI_gsetIterator_getKey(&gs_iter);
if (!BM_elem_flag_test(v, BM_ELEM_HIDDEN))
totvert++;
}
return totvert;
}
/* Return the total number of visible faces */
static int gpu_bmesh_face_visible_count(GSet *bm_faces)
{
GSetIterator gh_iter;
int totface = 0;
GSET_ITER (gh_iter, bm_faces) {
BMFace *f = BLI_gsetIterator_getKey(&gh_iter);
if (!BM_elem_flag_test(f, BM_ELEM_HIDDEN))
totface++;
}
return totface;
}
/* Creates a vertex buffer (coordinate, normal, color) and, if smooth
* shading, an element index buffer. */
void GPU_pbvh_bmesh_buffers_update(
GPU_PBVH_Buffers *buffers,
BMesh *bm,
GSet *bm_faces,
GSet *bm_unique_verts,
GSet *bm_other_verts,
bool show_diffuse_color)
{
VertexBufferFormat *vert_data;
void *tri_data;
int tottri, totvert, maxvert = 0;
float diffuse_color[4] = {0.8f, 0.8f, 0.8f, 1.0f};
/* TODO, make mask layer optional for bmesh buffer */
const int cd_vert_mask_offset = CustomData_get_offset(&bm->vdata, CD_PAINT_MASK);
buffers->show_diffuse_color = show_diffuse_color;
buffers->use_matcaps = GPU_material_use_matcaps_get();
/* Count visible triangles */
tottri = gpu_bmesh_face_visible_count(bm_faces);
if (buffers->smooth) {
/* Count visible vertices */
totvert = gpu_bmesh_vert_visible_count(bm_unique_verts, bm_other_verts);
}
else
totvert = tottri * 3;
if (!tottri) {
buffers->tot_tri = 0;
return;
}
if (buffers->use_matcaps)
diffuse_color[0] = diffuse_color[1] = diffuse_color[2] = 1.0;
else if (show_diffuse_color) {
/* due to dynamic nature of dyntopo, only get first material */
GSetIterator gs_iter;
BMFace *f;
BLI_gsetIterator_init(&gs_iter, bm_faces);
f = BLI_gsetIterator_getKey(&gs_iter);
GPU_material_diffuse_get(f->mat_nr + 1, diffuse_color);
}
copy_v4_v4(buffers->diffuse_color, diffuse_color);
/* Initialize vertex buffer */
if (buffers->vert_buf)
GPU_buffer_free(buffers->vert_buf);
buffers->vert_buf = GPU_buffer_alloc(sizeof(VertexBufferFormat) * totvert);
/* Fill vertex buffer */
vert_data = GPU_buffer_lock(buffers->vert_buf, GPU_BINDING_ARRAY);
if (vert_data) {
int v_index = 0;
if (buffers->smooth) {
GSetIterator gs_iter;
/* Vertices get an index assigned for use in the triangle
* index buffer */
bm->elem_index_dirty |= BM_VERT;
GSET_ITER (gs_iter, bm_unique_verts) {
gpu_bmesh_vert_to_buffer_copy(BLI_gsetIterator_getKey(&gs_iter),
vert_data, &v_index, NULL, NULL,
cd_vert_mask_offset, diffuse_color);
}
GSET_ITER (gs_iter, bm_other_verts) {
gpu_bmesh_vert_to_buffer_copy(BLI_gsetIterator_getKey(&gs_iter),
vert_data, &v_index, NULL, NULL,
cd_vert_mask_offset, diffuse_color);
}
maxvert = v_index;
}
else {
GSetIterator gs_iter;
GSET_ITER (gs_iter, bm_faces) {
BMFace *f = BLI_gsetIterator_getKey(&gs_iter);
BLI_assert(f->len == 3);
if (!BM_elem_flag_test(f, BM_ELEM_HIDDEN)) {
BMVert *v[3];
float fmask = 0;
int i;
#if 0
BM_iter_as_array(bm, BM_VERTS_OF_FACE, f, (void**)v, 3);
#endif
BM_face_as_array_vert_tri(f, v);
/* Average mask value */
for (i = 0; i < 3; i++) {
fmask += BM_ELEM_CD_GET_FLOAT(v[i], cd_vert_mask_offset);
}
fmask /= 3.0f;
for (i = 0; i < 3; i++) {
gpu_bmesh_vert_to_buffer_copy(v[i], vert_data,
&v_index, f->no, &fmask,
cd_vert_mask_offset, diffuse_color);
}
}
}
buffers->tot_tri = tottri;
}
GPU_buffer_unlock(buffers->vert_buf, GPU_BINDING_ARRAY);
/* gpu_bmesh_vert_to_buffer_copy sets dirty index values */
bm->elem_index_dirty |= BM_VERT;
}
else {
/* Memory map failed */
GPU_buffer_free(buffers->vert_buf);
buffers->vert_buf = NULL;
return;
}
if (buffers->smooth) {
const int use_short = (maxvert < USHRT_MAX);
/* Initialize triangle index buffer */
if (buffers->index_buf && !buffers->is_index_buf_global)
GPU_buffer_free(buffers->index_buf);
buffers->is_index_buf_global = false;
buffers->index_buf = GPU_buffer_alloc((use_short ?
sizeof(unsigned short) :
sizeof(unsigned int)) * 3 * tottri);
/* Fill triangle index buffer */
tri_data = GPU_buffer_lock(buffers->index_buf, GPU_BINDING_INDEX);
if (tri_data) {
GSetIterator gs_iter;
GSET_ITER (gs_iter, bm_faces) {
BMFace *f = BLI_gsetIterator_getKey(&gs_iter);
if (!BM_elem_flag_test(f, BM_ELEM_HIDDEN)) {
BMLoop *l_iter;
BMLoop *l_first;
l_iter = l_first = BM_FACE_FIRST_LOOP(f);
do {
BMVert *v = l_iter->v;
if (use_short) {
unsigned short *elem = tri_data;
(*elem) = BM_elem_index_get(v);
elem++;
tri_data = elem;
}
else {
unsigned int *elem = tri_data;
(*elem) = BM_elem_index_get(v);
elem++;
tri_data = elem;
}
} while ((l_iter = l_iter->next) != l_first);
}
}
GPU_buffer_unlock(buffers->index_buf, GPU_BINDING_INDEX);
buffers->tot_tri = tottri;
buffers->index_type = (use_short ?
GL_UNSIGNED_SHORT :
GL_UNSIGNED_INT);
}
else {
/* Memory map failed */
if (!buffers->is_index_buf_global) {
GPU_buffer_free(buffers->index_buf);
}
buffers->index_buf = NULL;
buffers->is_index_buf_global = false;
}
}
else if (buffers->index_buf) {
if (!buffers->is_index_buf_global) {
GPU_buffer_free(buffers->index_buf);
}
buffers->index_buf = NULL;
buffers->is_index_buf_global = false;
}
}
GPU_PBVH_Buffers *GPU_pbvh_bmesh_buffers_build(bool smooth_shading)
{
GPU_PBVH_Buffers *buffers;
buffers = MEM_callocN(sizeof(GPU_PBVH_Buffers), "GPU_Buffers");
buffers->use_bmesh = true;
buffers->smooth = smooth_shading;
buffers->show_diffuse_color = false;
buffers->use_matcaps = false;
return buffers;
}
void GPU_pbvh_buffers_draw(
GPU_PBVH_Buffers *buffers, DMSetMaterial setMaterial,
bool wireframe, bool fast)
{
bool do_fast = fast && buffers->index_buf_fast;
/* sets material from the first face, to solve properly face would need to
* be sorted in buckets by materials */
if (setMaterial) {
if (buffers->face_indices_len) {
const MLoopTri *lt = &buffers->looptri[buffers->face_indices[0]];
const MPoly *mp = &buffers->mpoly[lt->poly];
if (!setMaterial(mp->mat_nr + 1, NULL))
return;
}
else if (buffers->totgrid) {
const DMFlagMat *f = &buffers->grid_flag_mats[buffers->grid_indices[0]];
if (!setMaterial(f->mat_nr + 1, NULL))
return;
}
else {
if (!setMaterial(1, NULL))
return;
}
}
if (buffers->vert_buf) {
char *base = NULL;
char *index_base = NULL;
/* weak inspection of bound options, should not be necessary ideally */
const int bound_options_old = GPU_basic_shader_bound_options();
int bound_options_new = 0;
glEnableClientState(GL_VERTEX_ARRAY);
if (!wireframe) {
glEnableClientState(GL_NORMAL_ARRAY);
glEnableClientState(GL_COLOR_ARRAY);
bound_options_new |= GPU_SHADER_USE_COLOR;
}
GPU_buffer_bind(buffers->vert_buf, GPU_BINDING_ARRAY);
if (do_fast) {
GPU_buffer_bind(buffers->index_buf_fast, GPU_BINDING_INDEX);
}
else if (buffers->index_buf) {
GPU_buffer_bind(buffers->index_buf, GPU_BINDING_INDEX);
}
if (wireframe) {
glPolygonMode(GL_FRONT_AND_BACK, GL_LINE);
}
else {
if ((buffers->smooth == false) && (buffers->face_indices_len == 0)) {
bound_options_new |= GPU_SHADER_FLAT_NORMAL;
}
}
if (bound_options_new & ~bound_options_old) {
GPU_basic_shader_bind(bound_options_old | bound_options_new);
}
if (buffers->tot_quad) {
const char *offset = base;
const bool drawall = !(buffers->has_hidden || do_fast);
if (GLEW_ARB_draw_elements_base_vertex && drawall) {
glVertexPointer(3, GL_FLOAT, sizeof(VertexBufferFormat),
offset + offsetof(VertexBufferFormat, co));
if (!wireframe) {
glNormalPointer(GL_SHORT, sizeof(VertexBufferFormat),
offset + offsetof(VertexBufferFormat, no));
glColorPointer(3, GL_UNSIGNED_BYTE, sizeof(VertexBufferFormat),
offset + offsetof(VertexBufferFormat, color));
}
glMultiDrawElementsBaseVertex(GL_TRIANGLES, buffers->baseelemarray, buffers->index_type,
(const void * const *)buffers->baseindex,
buffers->totgrid, &buffers->baseelemarray[buffers->totgrid]);
}
else {
int i, last = drawall ? buffers->totgrid : 1;
/* we could optimize this to one draw call, but it would need more memory */
for (i = 0; i < last; i++) {
glVertexPointer(3, GL_FLOAT, sizeof(VertexBufferFormat),
offset + offsetof(VertexBufferFormat, co));
if (!wireframe) {
glNormalPointer(GL_SHORT, sizeof(VertexBufferFormat),
offset + offsetof(VertexBufferFormat, no));
glColorPointer(3, GL_UNSIGNED_BYTE, sizeof(VertexBufferFormat),
offset + offsetof(VertexBufferFormat, color));
}
if (do_fast)
glDrawElements(GL_TRIANGLES, buffers->totgrid * 6, buffers->index_type, index_base);
else
glDrawElements(GL_TRIANGLES, buffers->tot_quad * 6, buffers->index_type, index_base);
offset += buffers->gridkey.grid_area * sizeof(VertexBufferFormat);
}
}
}
else if (buffers->tot_tri) {
int totelem = buffers->tot_tri * 3;
glVertexPointer(3, GL_FLOAT, sizeof(VertexBufferFormat),
(void *)(base + offsetof(VertexBufferFormat, co)));
if (!wireframe) {
glNormalPointer(GL_SHORT, sizeof(VertexBufferFormat),
(void *)(base + offsetof(VertexBufferFormat, no)));
glColorPointer(3, GL_UNSIGNED_BYTE, sizeof(VertexBufferFormat),
(void *)(base + offsetof(VertexBufferFormat, color)));
}
if (buffers->index_buf)
glDrawElements(GL_TRIANGLES, totelem, buffers->index_type, index_base);
else
glDrawArrays(GL_TRIANGLES, 0, totelem);
}
if (wireframe)
glPolygonMode(GL_FRONT_AND_BACK, GL_FILL);
GPU_buffer_unbind(buffers->vert_buf, GPU_BINDING_ARRAY);
if (buffers->index_buf || do_fast)
GPU_buffer_unbind(do_fast ? buffers->index_buf_fast : buffers->index_buf, GPU_BINDING_INDEX);
glDisableClientState(GL_VERTEX_ARRAY);
if (!wireframe) {
glDisableClientState(GL_NORMAL_ARRAY);
glDisableClientState(GL_COLOR_ARRAY);
}
if (bound_options_new & ~bound_options_old) {
GPU_basic_shader_bind(bound_options_old);
}
}
}
bool GPU_pbvh_buffers_diffuse_changed(
GPU_PBVH_Buffers *buffers, GSet *bm_faces, bool show_diffuse_color)
{
float diffuse_color[4];
bool use_matcaps = GPU_material_use_matcaps_get();
if (buffers->show_diffuse_color != show_diffuse_color)
return true;
if (buffers->use_matcaps != use_matcaps)
return true;
if ((buffers->show_diffuse_color == false) || use_matcaps)
return false;
if (buffers->looptri) {
const MLoopTri *lt = &buffers->looptri[buffers->face_indices[0]];
const MPoly *mp = &buffers->mpoly[lt->poly];
GPU_material_diffuse_get(mp->mat_nr + 1, diffuse_color);
}
else if (buffers->use_bmesh) {
/* due to dynamic nature of dyntopo, only get first material */
if (BLI_gset_size(bm_faces) > 0) {
GSetIterator gs_iter;
BMFace *f;
BLI_gsetIterator_init(&gs_iter, bm_faces);
f = BLI_gsetIterator_getKey(&gs_iter);
GPU_material_diffuse_get(f->mat_nr + 1, diffuse_color);
}
else {
return false;
}
}
else {
const DMFlagMat *flags = &buffers->grid_flag_mats[buffers->grid_indices[0]];
GPU_material_diffuse_get(flags->mat_nr + 1, diffuse_color);
}
return !equals_v3v3(diffuse_color, buffers->diffuse_color);
}
void GPU_pbvh_buffers_free(GPU_PBVH_Buffers *buffers)
{
if (buffers) {
if (buffers->vert_buf)
GPU_buffer_free(buffers->vert_buf);
if (buffers->index_buf && !buffers->is_index_buf_global)
GPU_buffer_free(buffers->index_buf);
if (buffers->index_buf_fast)
GPU_buffer_free(buffers->index_buf_fast);
if (buffers->baseelemarray)
MEM_freeN(buffers->baseelemarray);
if (buffers->baseindex)
MEM_freeN(buffers->baseindex);
MEM_freeN(buffers);
}
}
void GPU_pbvh_multires_buffers_free(GridCommonGPUBuffer **grid_common_gpu_buffer)
{
GridCommonGPUBuffer *gridbuff = *grid_common_gpu_buffer;
if (gridbuff) {
if (gridbuff->mres_buffer) {
BLI_mutex_lock(&buffer_mutex);
gpu_buffer_free_intern(gridbuff->mres_buffer);
BLI_mutex_unlock(&buffer_mutex);
}
MEM_freeN(gridbuff);
*grid_common_gpu_buffer = NULL;
}
}
/* debug function, draws the pbvh BB */
void GPU_pbvh_BB_draw(float min[3], float max[3], bool leaf)
{
const float quads[4][4][3] = {
{
{min[0], min[1], min[2]},
{max[0], min[1], min[2]},
{max[0], min[1], max[2]},
{min[0], min[1], max[2]}
},
{
{min[0], min[1], min[2]},
{min[0], max[1], min[2]},
{min[0], max[1], max[2]},
{min[0], min[1], max[2]}
},
{
{max[0], max[1], min[2]},
{max[0], min[1], min[2]},
{max[0], min[1], max[2]},
{max[0], max[1], max[2]}
},
{
{max[0], max[1], min[2]},
{min[0], max[1], min[2]},
{min[0], max[1], max[2]},
{max[0], max[1], max[2]}
},
};
if (leaf)
glColor4f(0.0, 1.0, 0.0, 0.5);
else
glColor4f(1.0, 0.0, 0.0, 0.5);
glVertexPointer(3, GL_FLOAT, 0, &quads[0][0][0]);
glDrawArrays(GL_QUADS, 0, 16);
}
void GPU_pbvh_BB_draw_init(void)
{
glPushAttrib(GL_ENABLE_BIT);
glDisable(GL_CULL_FACE);
glEnableClientState(GL_VERTEX_ARRAY);
glDisableClientState(GL_COLOR_ARRAY);
glPolygonMode(GL_FRONT_AND_BACK, GL_LINE);
glEnable(GL_BLEND);
}
void GPU_pbvh_BB_draw_end(void)
{
glPolygonMode(GL_FRONT_AND_BACK, GL_FILL);
glPopAttrib();
}
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