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7a90af7b5a
blender/intern/cycles/render/image.cpp
Sergey Sharybin 7a90af7b5a Packed and generated images support for Cycles 
This commit adds support of packed and generated images
for Cycles when using SVM backend. Movies are still not
supported. This changes also doesn't touch OSL which is
much less trivial to adopt for any images which are not
saved to disk.

Implementation details:

- When adding images to Image Manager is now possible
  to mark image as builtin. Builtin images will bypass
  OIIO loader and will use special loading callbacks.

- Callbacks are set by Blender Session and they're
  using C++ RNA interface to obtain needed data (pixels,
  dimensions, is_float flag).

- Image Manager assumes file path is used as reference
  to a builtin images, but in fact currently image
  datablock name is used for reference. This makes it
  easy to find an image in BlendData database.

- Added some extra properties to Image RNA:
  * channels, which denotes actual number of channels
    in ImBuf. This is needed to treat image's pixels
    correct (before it wasn't possible because API
    used internal number of channels for pixels which
    is in fact doesn't correlate with image depth)
  * is_float, which is truth if image is stored in
    float buffer of ImBuf.

- Implemented string lookup for C++ RNA collections
  for cases there's no manual lookup function.

OSL is not supported because it used own image loading
and filtering routines and there's seems to be no API
to feed pre-loaded pixels directly to the library.

Think we'll either need to add some API to support
such kind of feeding or consider OSL does not have
support of packed images at all.

Movies are not supported at this moment because of lack
of RNA API to load specified frame. It's not difficult
to solve, just need to consider what to best here:
* Either write some general python interface for ImBuf
  and use it via C++ API, or
* Write a PY API function which will return pixels for
  given frame, or
* Use bad-level BKE_* call

Anyway, small steps, further improvements later.

Reviewed by Brecht, thanks!
2013-01-12 10:59:13 +00:00

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/*
* Copyright 2011, Blender Foundation.
*
* 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.
*/
#include "device.h"
#include "image.h"
#include "scene.h"
#include "util_foreach.h"
#include "util_image.h"
#include "util_path.h"
#include "util_progress.h"
#ifdef WITH_OSL
#include <OSL/oslexec.h>
#endif
CCL_NAMESPACE_BEGIN
ImageManager::ImageManager()
{
need_update = true;
pack_images = false;
osl_texture_system = NULL;
animation_frame = 0;
tex_num_images = TEX_NUM_IMAGES;
tex_num_float_images = TEX_NUM_FLOAT_IMAGES;
tex_image_byte_start = TEX_IMAGE_BYTE_START;
}
ImageManager::~ImageManager()
{
for(size_t slot = 0; slot < images.size(); slot++)
assert(!images[slot]);
for(size_t slot = 0; slot < float_images.size(); slot++)
assert(!float_images[slot]);
}
void ImageManager::set_pack_images(bool pack_images_)
{
pack_images = pack_images_;
}
void ImageManager::set_osl_texture_system(void *texture_system)
{
osl_texture_system = texture_system;
}
void ImageManager::set_extended_image_limits(void)
{
tex_num_images = TEX_EXTENDED_NUM_IMAGES;
tex_num_float_images = TEX_EXTENDED_NUM_FLOAT_IMAGES;
tex_image_byte_start = TEX_EXTENDED_IMAGE_BYTE_START;
}
bool ImageManager::set_animation_frame_update(int frame)
{
if(frame != animation_frame) {
animation_frame = frame;
for(size_t slot = 0; slot < images.size(); slot++)
if(images[slot] && images[slot]->animated)
return true;
for(size_t slot = 0; slot < float_images.size(); slot++)
if(float_images[slot] && float_images[slot]->animated)
return true;
}
return false;
}
bool ImageManager::is_float_image(const string& filename, bool is_builtin)
{
bool is_float = false;
if(is_builtin) {
if(builtin_image_info_cb) {
int width, height, channels;
builtin_image_info_cb(filename, is_float, width, height, channels);
}
return is_float;
}
ImageInput *in = ImageInput::create(filename);
if(in) {
ImageSpec spec;
if(in->open(filename, spec)) {
/* check the main format, and channel formats;
* if any take up more than one byte, we'll need a float texture slot */
if(spec.format.basesize() > 1)
is_float = true;
for(size_t channel = 0; channel < spec.channelformats.size(); channel++) {
if(spec.channelformats[channel].basesize() > 1)
is_float = true;
}
in->close();
}
delete in;
}
return is_float;
}
int ImageManager::add_image(const string& filename, bool is_builtin, bool animated, bool& is_float)
{
Image *img;
size_t slot;
/* load image info and find out if we need a float texture */
is_float = (pack_images)? false: is_float_image(filename, is_builtin);
if(is_float) {
/* find existing image */
for(slot = 0; slot < float_images.size(); slot++) {
if(float_images[slot] && float_images[slot]->filename == filename) {
float_images[slot]->users++;
return slot;
}
}
/* find free slot */
for(slot = 0; slot < float_images.size(); slot++) {
if(!float_images[slot])
break;
}
if(slot == float_images.size()) {
/* max images limit reached */
if(float_images.size() == TEX_NUM_FLOAT_IMAGES) {
printf("ImageManager::add_image: float image limit reached %d, skipping '%s'\n",
tex_num_float_images, filename.c_str());
return -1;
}
float_images.resize(float_images.size() + 1);
}
/* add new image */
img = new Image();
img->filename = filename;
img->is_builtin = is_builtin;
img->need_load = true;
img->animated = animated;
img->users = 1;
float_images[slot] = img;
}
else {
for(slot = 0; slot < images.size(); slot++) {
if(images[slot] && images[slot]->filename == filename) {
images[slot]->users++;
return slot+tex_image_byte_start;
}
}
/* find free slot */
for(slot = 0; slot < images.size(); slot++) {
if(!images[slot])
break;
}
if(slot == images.size()) {
/* max images limit reached */
if(images.size() == tex_num_images) {
printf("ImageManager::add_image: byte image limit reached %d, skipping '%s'\n",
tex_num_images, filename.c_str());
return -1;
}
images.resize(images.size() + 1);
}
/* add new image */
img = new Image();
img->filename = filename;
img->is_builtin = is_builtin;
img->need_load = true;
img->animated = animated;
img->users = 1;
images[slot] = img;
slot += tex_image_byte_start;
}
need_update = true;
return slot;
}
void ImageManager::remove_image(const string& filename, bool is_builtin)
{
size_t slot;
for(slot = 0; slot < images.size(); slot++) {
if(images[slot] && images[slot]->filename == filename && images[slot]->is_builtin == is_builtin) {
/* decrement user count */
images[slot]->users--;
assert(images[slot]->users >= 0);
/* don't remove immediately, rather do it all together later on. one of
* the reasons for this is that on shader changes we add and remove nodes
* that use them, but we do not want to reload the image all the time. */
if(images[slot]->users == 0)
need_update = true;
break;
}
}
if(slot == images.size()) {
/* see if it's in a float texture slot */
for(slot = 0; slot < float_images.size(); slot++) {
if(float_images[slot] && float_images[slot]->filename == filename && float_images[slot]->is_builtin == is_builtin) {
/* decrement user count */
float_images[slot]->users--;
assert(float_images[slot]->users >= 0);
/* don't remove immediately, rather do it all together later on. one of
* the reasons for this is that on shader changes we add and remove nodes
* that use them, but we do not want to reload the image all the time. */
if(float_images[slot]->users == 0)
need_update = true;
break;
}
}
}
}
bool ImageManager::file_load_image(Image *img, device_vector<uchar4>& tex_img)
{
if(img->filename == "")
return false;
ImageInput *in = NULL;
int width, height, components;
if(!img->is_builtin) {
/* load image from file through OIIO */
in = ImageInput::create(img->filename);
if(!in)
return false;
ImageSpec spec;
if(!in->open(img->filename, spec)) {
delete in;
return false;
}
width = spec.width;
height = spec.height;
components = spec.nchannels;
}
else {
/* load image using builtin images callbacks */
if(!builtin_image_info_cb || !builtin_image_pixels_cb)
return false;
bool is_float;
builtin_image_info_cb(img->filename, is_float, width, height, components);
}
/* we only handle certain number of components */
if(!(components == 1 || components == 3 || components == 4)) {
if(in) {
in->close();
delete in;
}
return false;
}
/* read RGBA pixels */
uchar *pixels = (uchar*)tex_img.resize(width, height);
int scanlinesize = width*components*sizeof(uchar);
if(in) {
in->read_image(TypeDesc::UINT8,
(uchar*)pixels + (height-1)*scanlinesize,
AutoStride,
-scanlinesize,
AutoStride);
in->close();
delete in;
}
else {
builtin_image_pixels_cb(img->filename, pixels);
}
if(components == 3) {
for(int i = width*height-1; i >= 0; i--) {
pixels[i*4+3] = 255;
pixels[i*4+2] = pixels[i*3+2];
pixels[i*4+1] = pixels[i*3+1];
pixels[i*4+0] = pixels[i*3+0];
}
}
else if(components == 1) {
for(int i = width*height-1; i >= 0; i--) {
pixels[i*4+3] = 255;
pixels[i*4+2] = pixels[i];
pixels[i*4+1] = pixels[i];
pixels[i*4+0] = pixels[i];
}
}
return true;
}
bool ImageManager::file_load_float_image(Image *img, device_vector<float4>& tex_img)
{
if(img->filename == "")
return false;
ImageInput *in = NULL;
int width, height, components;
if(!img->is_builtin) {
/* load image from file through OIIO */
in = ImageInput::create(img->filename);
if(!in)
return false;
ImageSpec spec;
if(!in->open(img->filename, spec)) {
delete in;
return false;
}
/* we only handle certain number of components */
width = spec.width;
height = spec.height;
components = spec.nchannels;
}
else {
/* load image using builtin images callbacks */
if(!builtin_image_info_cb || !builtin_image_float_pixels_cb)
return false;
bool is_float;
builtin_image_info_cb(img->filename, is_float, width, height, components);
}
if(!(components == 1 || components == 3 || components == 4)) {
if(in) {
in->close();
delete in;
}
return false;
}
/* read RGBA pixels */
float *pixels = (float*)tex_img.resize(width, height);
int scanlinesize = width*components*sizeof(float);
if(in) {
in->read_image(TypeDesc::FLOAT,
(uchar*)pixels + (height-1)*scanlinesize,
AutoStride,
-scanlinesize,
AutoStride);
in->close();
delete in;
}
else {
builtin_image_float_pixels_cb(img->filename, pixels);
}
if(components == 3) {
for(int i = width*height-1; i >= 0; i--) {
pixels[i*4+3] = 1.0f;
pixels[i*4+2] = pixels[i*3+2];
pixels[i*4+1] = pixels[i*3+1];
pixels[i*4+0] = pixels[i*3+0];
}
}
else if(components == 1) {
for(int i = width*height-1; i >= 0; i--) {
pixels[i*4+3] = 1.0f;
pixels[i*4+2] = pixels[i];
pixels[i*4+1] = pixels[i];
pixels[i*4+0] = pixels[i];
}
}
return true;
}
void ImageManager::device_load_image(Device *device, DeviceScene *dscene, int slot, Progress *progress)
{
if(progress->get_cancel())
return;
if(osl_texture_system)
return;
Image *img;
bool is_float;
if(slot >= tex_image_byte_start) {
img = images[slot - tex_image_byte_start];
is_float = false;
}
else {
img = float_images[slot];
is_float = true;
}
if(is_float) {
string filename = path_filename(float_images[slot]->filename);
progress->set_status("Updating Images", "Loading " + filename);
device_vector<float4>& tex_img = dscene->tex_float_image[slot];
if(tex_img.device_pointer) {
thread_scoped_lock device_lock(device_mutex);
device->tex_free(tex_img);
}
if(!file_load_float_image(img, tex_img)) {
/* on failure to load, we set a 1x1 pixels pink image */
float *pixels = (float*)tex_img.resize(1, 1);
pixels[0] = TEX_IMAGE_MISSING_R;
pixels[1] = TEX_IMAGE_MISSING_G;
pixels[2] = TEX_IMAGE_MISSING_B;
pixels[3] = TEX_IMAGE_MISSING_A;
}
string name;
if(slot >= 10) name = string_printf("__tex_image_float_0%d", slot);
else name = string_printf("__tex_image_float_00%d", slot);
if(!pack_images) {
thread_scoped_lock device_lock(device_mutex);
device->tex_alloc(name.c_str(), tex_img, true, true);
}
}
else {
string filename = path_filename(images[slot - tex_image_byte_start]->filename);
progress->set_status("Updating Images", "Loading " + filename);
device_vector<uchar4>& tex_img = dscene->tex_image[slot - tex_image_byte_start];
if(tex_img.device_pointer) {
thread_scoped_lock device_lock(device_mutex);
device->tex_free(tex_img);
}
if(!file_load_image(img, tex_img)) {
/* on failure to load, we set a 1x1 pixels pink image */
uchar *pixels = (uchar*)tex_img.resize(1, 1);
pixels[0] = (TEX_IMAGE_MISSING_R * 255);
pixels[1] = (TEX_IMAGE_MISSING_G * 255);
pixels[2] = (TEX_IMAGE_MISSING_B * 255);
pixels[3] = (TEX_IMAGE_MISSING_A * 255);
}
string name;
if(slot >= 10) name = string_printf("__tex_image_0%d", slot);
else name = string_printf("__tex_image_00%d", slot);
if(!pack_images) {
thread_scoped_lock device_lock(device_mutex);
device->tex_alloc(name.c_str(), tex_img, true, true);
}
}
img->need_load = false;
}
void ImageManager::device_free_image(Device *device, DeviceScene *dscene, int slot)
{
Image *img;
bool is_float;
if(slot >= tex_image_byte_start) {
img = images[slot - tex_image_byte_start];
is_float = false;
}
else {
img = float_images[slot];
is_float = true;
}
if(img) {
if(osl_texture_system) {
#ifdef WITH_OSL
ustring filename(images[slot]->filename);
((OSL::TextureSystem*)osl_texture_system)->invalidate(filename);
#endif
}
else if(is_float) {
device_vector<float4>& tex_img = dscene->tex_float_image[slot];
if(tex_img.device_pointer) {
thread_scoped_lock device_lock(device_mutex);
device->tex_free(tex_img);
}
tex_img.clear();
delete float_images[slot];
float_images[slot] = NULL;
}
else {
device_vector<uchar4>& tex_img = dscene->tex_image[slot - tex_image_byte_start];
if(tex_img.device_pointer) {
thread_scoped_lock device_lock(device_mutex);
device->tex_free(tex_img);
}
tex_img.clear();
delete images[slot - tex_image_byte_start];
images[slot - tex_image_byte_start] = NULL;
}
}
}
void ImageManager::device_update(Device *device, DeviceScene *dscene, Progress& progress)
{
if(!need_update)
return;
TaskPool pool;
for(size_t slot = 0; slot < images.size(); slot++) {
if(!images[slot])
continue;
if(images[slot]->users == 0) {
device_free_image(device, dscene, slot + tex_image_byte_start);
}
else if(images[slot]->need_load) {
if(!osl_texture_system)
pool.push(function_bind(&ImageManager::device_load_image, this, device, dscene, slot + tex_image_byte_start, &progress));
}
}
for(size_t slot = 0; slot < float_images.size(); slot++) {
if(!float_images[slot])
continue;
if(float_images[slot]->users == 0) {
device_free_image(device, dscene, slot);
}
else if(float_images[slot]->need_load) {
if(!osl_texture_system)
pool.push(function_bind(&ImageManager::device_load_image, this, device, dscene, slot, &progress));
}
}
pool.wait_work();
if(pack_images)
device_pack_images(device, dscene, progress);
need_update = false;
}
void ImageManager::device_pack_images(Device *device, DeviceScene *dscene, Progress& progess)
{
/* for OpenCL, we pack all image textures inside a single big texture, and
* will do our own interpolation in the kernel */
size_t size = 0;
for(size_t slot = 0; slot < images.size(); slot++) {
if(!images[slot])
continue;
device_vector<uchar4>& tex_img = dscene->tex_image[slot];
size += tex_img.size();
}
uint4 *info = dscene->tex_image_packed_info.resize(images.size());
uchar4 *pixels = dscene->tex_image_packed.resize(size);
size_t offset = 0;
for(size_t slot = 0; slot < images.size(); slot++) {
if(!images[slot])
continue;
device_vector<uchar4>& tex_img = dscene->tex_image[slot];
info[slot] = make_uint4(tex_img.data_width, tex_img.data_height, offset, 1);
memcpy(pixels+offset, (void*)tex_img.data_pointer, tex_img.memory_size());
offset += tex_img.size();
}
if(dscene->tex_image_packed.size())
device->tex_alloc("__tex_image_packed", dscene->tex_image_packed);
if(dscene->tex_image_packed_info.size())
device->tex_alloc("__tex_image_packed_info", dscene->tex_image_packed_info);
}
void ImageManager::device_free(Device *device, DeviceScene *dscene)
{
for(size_t slot = 0; slot < images.size(); slot++)
device_free_image(device, dscene, slot + tex_image_byte_start);
for(size_t slot = 0; slot < float_images.size(); slot++)
device_free_image(device, dscene, slot);
device->tex_free(dscene->tex_image_packed);
device->tex_free(dscene->tex_image_packed_info);
dscene->tex_image_packed.clear();
dscene->tex_image_packed_info.clear();
images.clear();
float_images.clear();
}
CCL_NAMESPACE_END
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