void tex_alloc(device_memory &mem)
{
VLOG(1) << "Texture allocate: " << mem.name << ", "
<< string_human_readable_number(mem.memory_size()) << " bytes. ("
<< string_human_readable_size(mem.memory_size()) << ")";
if (mem.interpolation == INTERPOLATION_NONE) {
/* Data texture. */
kernel_tex_copy(&kernel_globals, mem.name, mem.host_pointer, mem.data_size);
}
else {
/* Image Texture. */
int flat_slot = 0;
if (string_startswith(mem.name, "__tex_image")) {
int pos = string(mem.name).rfind("_");
flat_slot = atoi(mem.name + pos + 1);
}
else {
assert(0);
}
if (flat_slot >= texture_info.size()) {
/* Allocate some slots in advance, to reduce amount
* of re-allocations. */
texture_info.resize(flat_slot + 128);
}
TextureInfo &info = texture_info[flat_slot];
info.data = (uint64_t)mem.host_pointer;
info.cl_buffer = 0;
info.interpolation = mem.interpolation;
info.extension = mem.extension;
info.width = mem.data_width;
info.height = mem.data_height;
info.depth = mem.data_depth;
need_texture_info = true;
}
mem.device_pointer = (device_ptr)mem.host_pointer;
mem.device_size = mem.memory_size();
stats.mem_alloc(mem.device_size);
}
bool ImageManager::file_load_float_image(Image *img, device_vector<float4>& tex_img)
{
if(img->filename == "")
return false;
/* load image from file through OIIO */
ImageInput *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 */
int width = spec.width;
int height = spec.height;
int components = spec.nchannels;
if(!(components == 1 || components == 3 || components == 4)) {
in->close();
delete in;
return false;
}
printf("loading float image: '%s' %dx%d\n", img->filename.c_str(), width, height);
/* read RGBA pixels */
float *pixels = (float*)tex_img.resize(width, height);
int scanlinesize = width*components*sizeof(float);
in->read_image(TypeDesc::FLOAT,
(uchar*)pixels + (height-1)*scanlinesize,
AutoStride,
-scanlinesize,
AutoStride);
in->close();
delete in;
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;
}
bool ImageManager::file_load_half_image(Image *img, ImageDataType type, device_vector<T>& tex_img)
{
ImageInput *in = NULL;
int width, height, depth, components;
if(!file_load_image_generic(img, &in, width, height, depth, components))
return false;
/* read RGBA pixels */
half *pixels = (half*)tex_img.resize(width, height, depth);
if(pixels == NULL) {
return false;
}
if(in) {
half *readpixels = pixels;
vector<half> tmppixels;
if(components > 4) {
tmppixels.resize(((size_t)width)*height*components);
readpixels = &tmppixels[0];
}
if(depth <= 1) {
size_t scanlinesize = ((size_t)width)*components*sizeof(half);
in->read_image(TypeDesc::HALF,
(uchar*)readpixels + (height-1)*scanlinesize,
AutoStride,
-scanlinesize,
AutoStride);
}
else {
in->read_image(TypeDesc::HALF, (uchar*)readpixels);
}
if(components > 4) {
size_t dimensions = ((size_t)width)*height;
for(size_t i = dimensions-1, pixel = 0; pixel < dimensions; pixel++, i--) {
pixels[i*4+3] = tmppixels[i*components+3];
pixels[i*4+2] = tmppixels[i*components+2];
pixels[i*4+1] = tmppixels[i*components+1];
pixels[i*4+0] = tmppixels[i*components+0];
}
tmppixels.clear();
}
in->close();
delete in;
}
#if 0
/* TODO(dingto): Support half for ImBuf. */
else {
builtin_image_float_pixels_cb(img->filename, img->builtin_data, pixels);
}
#endif
/* Check if we actually have a half4 slot, in case components == 1, but device
* doesn't support single channel textures. */
if(type == IMAGE_DATA_TYPE_HALF4) {
size_t num_pixels = ((size_t)width) * height * depth;
if(components == 2) {
/* grayscale + alpha */
for(size_t i = num_pixels-1, pixel = 0; pixel < num_pixels; pixel++, i--) {
pixels[i*4+3] = pixels[i*2+1];
pixels[i*4+2] = pixels[i*2+0];
pixels[i*4+1] = pixels[i*2+0];
pixels[i*4+0] = pixels[i*2+0];
}
}
else if(components == 3) {
/* RGB */
for(size_t i = num_pixels-1, pixel = 0; pixel < num_pixels; pixel++, 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) {
/* grayscale */
for(size_t i = num_pixels-1, pixel = 0; pixel < num_pixels; pixel++, 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];
}
}
if(img->use_alpha == false) {
for(size_t i = num_pixels-1, pixel = 0; pixel < num_pixels; pixel++, i--) {
pixels[i*4+3] = 1.0f;
}
}
}
return true;
}
bool ImageManager::file_load_float_image(Image *img, ImageDataType type, device_vector<T>& tex_img)
{
ImageInput *in = NULL;
int width, height, depth, components;
if(!file_load_image_generic(img, &in, width, height, depth, components))
return false;
/* read RGBA pixels */
float *pixels = (float*)tex_img.resize(width, height, depth);
if(pixels == NULL) {
return false;
}
bool cmyk = false;
if(in) {
float *readpixels = pixels;
vector<float> tmppixels;
if(components > 4) {
tmppixels.resize(((size_t)width)*height*components);
readpixels = &tmppixels[0];
}
if(depth <= 1) {
size_t scanlinesize = ((size_t)width)*components*sizeof(float);
in->read_image(TypeDesc::FLOAT,
(uchar*)readpixels + (height-1)*scanlinesize,
AutoStride,
-scanlinesize,
AutoStride);
}
else {
in->read_image(TypeDesc::FLOAT, (uchar*)readpixels);
}
if(components > 4) {
size_t dimensions = ((size_t)width)*height;
for(size_t i = dimensions-1, pixel = 0; pixel < dimensions; pixel++, i--) {
pixels[i*4+3] = tmppixels[i*components+3];
pixels[i*4+2] = tmppixels[i*components+2];
pixels[i*4+1] = tmppixels[i*components+1];
pixels[i*4+0] = tmppixels[i*components+0];
}
tmppixels.clear();
}
cmyk = strcmp(in->format_name(), "jpeg") == 0 && components == 4;
in->close();
delete in;
}
else {
builtin_image_float_pixels_cb(img->filename, img->builtin_data, pixels);
}
/* Check if we actually have a float4 slot, in case components == 1, but device
* doesn't support single channel textures. */
if(type == IMAGE_DATA_TYPE_FLOAT4) {
size_t num_pixels = ((size_t)width) * height * depth;
if(cmyk) {
/* CMYK */
for(size_t i = num_pixels-1, pixel = 0; pixel < num_pixels; pixel++, i--) {
pixels[i*4+3] = 255;
pixels[i*4+2] = (pixels[i*4+2]*pixels[i*4+3])/255;
pixels[i*4+1] = (pixels[i*4+1]*pixels[i*4+3])/255;
pixels[i*4+0] = (pixels[i*4+0]*pixels[i*4+3])/255;
}
}
else if(components == 2) {
/* grayscale + alpha */
for(size_t i = num_pixels-1, pixel = 0; pixel < num_pixels; pixel++, i--) {
pixels[i*4+3] = pixels[i*2+1];
pixels[i*4+2] = pixels[i*2+0];
pixels[i*4+1] = pixels[i*2+0];
pixels[i*4+0] = pixels[i*2+0];
}
}
else if(components == 3) {
/* RGB */
for(size_t i = num_pixels-1, pixel = 0; pixel < num_pixels; pixel++, 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) {
/* grayscale */
for(size_t i = num_pixels-1, pixel = 0; pixel < num_pixels; pixel++, 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];
}
}
if(img->use_alpha == false) {
for(size_t i = num_pixels-1, pixel = 0; pixel < num_pixels; pixel++, i--) {
pixels[i*4+3] = 1.0f;
}
}
}
return true;
}
bool ImageManager::file_load_image(Image *img,
ImageDataType type,
int texture_limit,
device_vector<DeviceType>& tex_img)
{
const StorageType alpha_one = (FileFormat == TypeDesc::UINT8)? 255 : 1;
ImageInput *in = NULL;
int width, height, depth, components;
if(!file_load_image_generic(img, &in, width, height, depth, components)) {
return false;
}
/* Read RGBA pixels. */
vector<StorageType> pixels_storage;
StorageType *pixels;
const size_t max_size = max(max(width, height), depth);
if(max_size == 0) {
/* Don't bother with invalid images. */
return false;
}
if(texture_limit > 0 && max_size > texture_limit) {
pixels_storage.resize(((size_t)width)*height*depth*4);
pixels = &pixels_storage[0];
}
else {
pixels = (StorageType*)tex_img.resize(width, height, depth);
}
if(pixels == NULL) {
/* Could be that we've run out of memory. */
return false;
}
bool cmyk = false;
const size_t num_pixels = ((size_t)width) * height * depth;
if(in) {
StorageType *readpixels = pixels;
vector<StorageType> tmppixels;
if(components > 4) {
tmppixels.resize(((size_t)width)*height*components);
readpixels = &tmppixels[0];
}
if(depth <= 1) {
size_t scanlinesize = ((size_t)width)*components*sizeof(StorageType);
in->read_image(FileFormat,
(uchar*)readpixels + (height-1)*scanlinesize,
AutoStride,
-scanlinesize,
AutoStride);
}
else {
in->read_image(FileFormat, (uchar*)readpixels);
}
if(components > 4) {
size_t dimensions = ((size_t)width)*height;
for(size_t i = dimensions-1, pixel = 0; pixel < dimensions; pixel++, i--) {
pixels[i*4+3] = tmppixels[i*components+3];
pixels[i*4+2] = tmppixels[i*components+2];
pixels[i*4+1] = tmppixels[i*components+1];
pixels[i*4+0] = tmppixels[i*components+0];
}
tmppixels.clear();
}
cmyk = strcmp(in->format_name(), "jpeg") == 0 && components == 4;
in->close();
delete in;
}
else {
if(FileFormat == TypeDesc::FLOAT) {
builtin_image_float_pixels_cb(img->filename,
img->builtin_data,
(float*)&pixels[0],
num_pixels * components,
img->builtin_free_cache);
}
else if(FileFormat == TypeDesc::UINT8) {
builtin_image_pixels_cb(img->filename,
img->builtin_data,
(uchar*)&pixels[0],
num_pixels * components,
img->builtin_free_cache);
}
else {
/* TODO(dingto): Support half for ImBuf. */
}
}
/* Check if we actually have a float4 slot, in case components == 1,
* but device doesn't support single channel textures.
*/
bool is_rgba = (type == IMAGE_DATA_TYPE_FLOAT4 ||
type == IMAGE_DATA_TYPE_HALF4 ||
type == IMAGE_DATA_TYPE_BYTE4);
if(is_rgba) {
if(cmyk) {
/* CMYK */
for(size_t i = num_pixels-1, pixel = 0; pixel < num_pixels; pixel++, i--) {
pixels[i*4+2] = (pixels[i*4+2]*pixels[i*4+3])/255;
pixels[i*4+1] = (pixels[i*4+1]*pixels[i*4+3])/255;
pixels[i*4+0] = (pixels[i*4+0]*pixels[i*4+3])/255;
pixels[i*4+3] = alpha_one;
}
}
else if(components == 2) {
/* grayscale + alpha */
for(size_t i = num_pixels-1, pixel = 0; pixel < num_pixels; pixel++, i--) {
pixels[i*4+3] = pixels[i*2+1];
pixels[i*4+2] = pixels[i*2+0];
pixels[i*4+1] = pixels[i*2+0];
pixels[i*4+0] = pixels[i*2+0];
}
}
else if(components == 3) {
/* RGB */
for(size_t i = num_pixels-1, pixel = 0; pixel < num_pixels; pixel++, i--) {
pixels[i*4+3] = alpha_one;
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) {
/* grayscale */
for(size_t i = num_pixels-1, pixel = 0; pixel < num_pixels; pixel++, i--) {
pixels[i*4+3] = alpha_one;
pixels[i*4+2] = pixels[i];
pixels[i*4+1] = pixels[i];
pixels[i*4+0] = pixels[i];
}
}
if(img->use_alpha == false) {
for(size_t i = num_pixels-1, pixel = 0; pixel < num_pixels; pixel++, i--) {
pixels[i*4+3] = alpha_one;
}
}
}
/* Make sure we don't have buggy values. */
if(FileFormat == TypeDesc::FLOAT) {
/* For RGBA buffers we put all channels to 0 if either of them is not
* finite. This way we avoid possible artifacts caused by fully changed
* hue.
*/
if(is_rgba) {
for(size_t i = 0; i < num_pixels; i += 4) {
StorageType *pixel = &pixels[i*4];
if(!isfinite(pixel[0]) ||
!isfinite(pixel[1]) ||
!isfinite(pixel[2]) ||
!isfinite(pixel[3]))
{
pixel[0] = 0;
pixel[1] = 0;
pixel[2] = 0;
pixel[3] = 0;
}
}
}
else {
for(size_t i = 0; i < num_pixels; ++i) {
StorageType *pixel = &pixels[i];
if(!isfinite(pixel[0])) {
pixel[0] = 0;
}
}
}
}
/* Scale image down if needed. */
if(pixels_storage.size() > 0) {
float scale_factor = 1.0f;
while(max_size * scale_factor > texture_limit) {
scale_factor *= 0.5f;
}
VLOG(1) << "Scaling image " << img->filename
<< " by a factor of " << scale_factor << ".";
vector<StorageType> scaled_pixels;
size_t scaled_width, scaled_height, scaled_depth;
util_image_resize_pixels(pixels_storage,
width, height, depth,
is_rgba ? 4 : 1,
scale_factor,
&scaled_pixels,
&scaled_width, &scaled_height, &scaled_depth);
StorageType *texture_pixels = (StorageType*)tex_img.resize(scaled_width,
scaled_height,
scaled_depth);
memcpy(texture_pixels,
&scaled_pixels[0],
scaled_pixels.size() * sizeof(StorageType));
}
return true;
}
bool ImageManager::file_load_image(Image *img, device_vector<uchar4>& tex_img)
{
if(img->filename == "")
return false;
fprintf(stderr, "image input disabled\n");
#if 0
/* load image from file through OIIO */
ImageInput *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 */
int width = spec.width;
int height = spec.height;
int components = spec.nchannels;
if(!(components == 1 || components == 3 || components == 4)) {
in->close();
delete in;
return false;
}
/* read RGBA pixels */
uchar *pixels = (uchar*)tex_img.resize(width, height);
int scanlinesize = width*components*sizeof(uchar);
in->read_image(TypeDesc::UINT8,
(uchar*)pixels + (height-1)*scanlinesize,
AutoStride,
-scanlinesize,
AutoStride);
in->close();
delete in;
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;
#endif
return false;
}