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/*
* Copyright 2011-2013 Blender Foundation
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#ifdef WITH_OPENCL
#include "opencl.h"
#include "buffers.h"
#include "kernel_types.h"
#include "kernel_split_data_types.h"
#include "device_split_kernel.h"
#include "util_logging.h"
#include "util_md5.h"
#include "util_path.h"
#include "util_time.h"
CCL_NAMESPACE_BEGIN
class OpenCLSplitKernel;
static string get_build_options(OpenCLDeviceBase *device, const DeviceRequestedFeatures& requested_features)
{
string build_options = "-D__SPLIT_KERNEL__ ";
build_options += requested_features.get_build_options();
/* Set compute device build option. */
cl_device_type device_type;
OpenCLInfo::get_device_type(device->cdDevice, &device_type, &device->ciErr);
assert(device->ciErr == CL_SUCCESS);
if(device_type == CL_DEVICE_TYPE_GPU) {
build_options += " -D__COMPUTE_DEVICE_GPU__";
}
return build_options;
}
/* OpenCLDeviceSplitKernel's declaration/definition. */
class OpenCLDeviceSplitKernel : public OpenCLDeviceBase
{
public:
DeviceSplitKernel *split_kernel;
OpenCLProgram program_data_init;
OpenCLProgram program_state_buffer_size;
OpenCLDeviceSplitKernel(DeviceInfo& info, Stats &stats, bool background_);
~OpenCLDeviceSplitKernel()
{
task_pool.stop();
/* Release kernels */
program_data_init.release();
delete split_kernel;
}
virtual bool load_kernels(const DeviceRequestedFeatures& requested_features,
vector<OpenCLDeviceBase::OpenCLProgram*> &programs)
{
bool single_program = OpenCLInfo::use_single_program();
program_data_init = OpenCLDeviceBase::OpenCLProgram(this,
single_program ? "split" : "split_data_init",
single_program ? "kernel_split.cl" : "kernel_data_init.cl",
get_build_options(this, requested_features));
program_data_init.add_kernel(ustring("path_trace_data_init"));
programs.push_back(&program_data_init);
program_state_buffer_size = OpenCLDeviceBase::OpenCLProgram(this,
single_program ? "split" : "split_state_buffer_size",
single_program ? "kernel_split.cl" : "kernel_state_buffer_size.cl",
get_build_options(this, requested_features));
program_state_buffer_size.add_kernel(ustring("path_trace_state_buffer_size"));
programs.push_back(&program_state_buffer_size);
return split_kernel->load_kernels(requested_features);
}
void thread_run(DeviceTask *task)
{
if(task->type == DeviceTask::FILM_CONVERT) {
film_convert(*task, task->buffer, task->rgba_byte, task->rgba_half);
}
else if(task->type == DeviceTask::SHADER) {
shader(*task);
}
else if(task->type == DeviceTask::PATH_TRACE) {
RenderTile tile;
/* Copy dummy KernelGlobals related to OpenCL from kernel_globals.h to
* fetch its size.
*/
typedef struct KernelGlobals {
ccl_constant KernelData *data;
#define KERNEL_TEX(type, ttype, name) \
ccl_global type *name;
#include "kernel_textures.h"
#undef KERNEL_TEX
SplitData split_data;
SplitParams split_param_data;
} KernelGlobals;
/* Allocate buffer for kernel globals */
device_memory kgbuffer;
kgbuffer.resize(sizeof(KernelGlobals));
mem_alloc("kernel_globals", kgbuffer, MEM_READ_WRITE);
/* Keep rendering tiles until done. */
while(task->acquire_tile(this, tile)) {
split_kernel->path_trace(task,
tile,
kgbuffer,
*const_mem_map["__data"]);
/* Complete kernel execution before release tile. */
/* This helps in multi-device render;
* The device that reaches the critical-section function
* release_tile waits (stalling other devices from entering
* release_tile) for all kernels to complete. If device1 (a
* slow-render device) reaches release_tile first then it would
* stall device2 (a fast-render device) from proceeding to render
* next tile.
*/
clFinish(cqCommandQueue);
task->release_tile(tile);
}
mem_free(kgbuffer);
}
}
protected:
/* ** Those guys are for workign around some compiler-specific bugs ** */
string build_options_for_base_program(
const DeviceRequestedFeatures& requested_features)
{
return requested_features.get_build_options();
}
friend class OpenCLSplitKernel;
friend class OpenCLSplitKernelFunction;
};
class OpenCLSplitKernelFunction : public SplitKernelFunction {
public:
OpenCLDeviceSplitKernel* device;
OpenCLDeviceBase::OpenCLProgram program;
OpenCLSplitKernelFunction(OpenCLDeviceSplitKernel* device) : device(device) {}
~OpenCLSplitKernelFunction() { program.release(); }
virtual bool enqueue(const KernelDimensions& dim, device_memory& kg, device_memory& data)
{
device->kernel_set_args(program(), 0, kg, data);
device->ciErr = clEnqueueNDRangeKernel(device->cqCommandQueue,
program(),
2,
NULL,
dim.global_size,
dim.local_size,
0,
NULL,
NULL);
device->opencl_assert_err(device->ciErr, "clEnqueueNDRangeKernel");
if(device->ciErr != CL_SUCCESS) {
string message = string_printf("OpenCL error: %s in clEnqueueNDRangeKernel()",
clewErrorString(device->ciErr));
device->opencl_error(message);
return false;
}
return true;
}
};
class OpenCLSplitKernel : public DeviceSplitKernel {
OpenCLDeviceSplitKernel *device;
public:
explicit OpenCLSplitKernel(OpenCLDeviceSplitKernel *device) : DeviceSplitKernel(device), device(device) {
}
virtual SplitKernelFunction* get_split_kernel_function(string kernel_name,
const DeviceRequestedFeatures& requested_features)
{
OpenCLSplitKernelFunction* kernel = new OpenCLSplitKernelFunction(device);
bool single_program = OpenCLInfo::use_single_program();
kernel->program =
OpenCLDeviceBase::OpenCLProgram(device,
single_program ? "split" : "split_" + kernel_name,
single_program ? "kernel_split.cl" : "kernel_" + kernel_name + ".cl",
get_build_options(device, requested_features));
kernel->program.add_kernel(ustring("path_trace_" + kernel_name));
kernel->program.load();
if(!kernel->program.is_loaded()) {
delete kernel;
return NULL;
}
return kernel;
}
virtual uint64_t state_buffer_size(device_memory& kg, device_memory& data, size_t num_threads)
{
device_vector<uint64_t> size_buffer;
size_buffer.resize(1);
device->mem_alloc(NULL, size_buffer, MEM_READ_WRITE);
uint threads = num_threads;
device->kernel_set_args(device->program_state_buffer_size(), 0, kg, data, threads, size_buffer);
size_t global_size = 64;
device->ciErr = clEnqueueNDRangeKernel(device->cqCommandQueue,
device->program_state_buffer_size(),
1,
NULL,
&global_size,
NULL,
0,
NULL,
NULL);
device->opencl_assert_err(device->ciErr, "clEnqueueNDRangeKernel");
device->mem_copy_from(size_buffer, 0, 1, 1, sizeof(uint64_t));
device->mem_free(size_buffer);
if(device->ciErr != CL_SUCCESS) {
string message = string_printf("OpenCL error: %s in clEnqueueNDRangeKernel()",
clewErrorString(device->ciErr));
device->opencl_error(message);
return 0;
}
return *size_buffer.get_data();
}
virtual bool enqueue_split_kernel_data_init(const KernelDimensions& dim,
RenderTile& rtile,
int num_global_elements,
device_memory& kernel_globals,
device_memory& kernel_data,
device_memory& split_data,
device_memory& ray_state,
device_memory& queue_index,
device_memory& use_queues_flag,
device_memory& work_pool_wgs
)
{
cl_int dQueue_size = dim.global_size[0] * dim.global_size[1];
/* Set the range of samples to be processed for every ray in
* path-regeneration logic.
*/
cl_int start_sample = rtile.start_sample;
cl_int end_sample = rtile.start_sample + rtile.num_samples;
cl_uint start_arg_index =
device->kernel_set_args(device->program_data_init(),
0,
kernel_globals,
kernel_data,
split_data,
num_global_elements,
ray_state,
rtile.rng_state);
/* TODO(sergey): Avoid map lookup here. */
#define KERNEL_TEX(type, ttype, name) \
device->set_kernel_arg_mem(device->program_data_init(), &start_arg_index, #name);
#include "kernel_textures.h"
#undef KERNEL_TEX
start_arg_index +=
device->kernel_set_args(device->program_data_init(),
start_arg_index,
start_sample,
end_sample,
rtile.x,
rtile.y,
rtile.w,
rtile.h,
rtile.offset,
rtile.stride,
queue_index,
dQueue_size,
use_queues_flag,
work_pool_wgs,
rtile.num_samples,
rtile.buffer);
/* Enqueue ckPathTraceKernel_data_init kernel. */
device->ciErr = clEnqueueNDRangeKernel(device->cqCommandQueue,
device->program_data_init(),
2,
NULL,
dim.global_size,
dim.local_size,
0,
NULL,
NULL);
device->opencl_assert_err(device->ciErr, "clEnqueueNDRangeKernel");
if(device->ciErr != CL_SUCCESS) {
string message = string_printf("OpenCL error: %s in clEnqueueNDRangeKernel()",
clewErrorString(device->ciErr));
device->opencl_error(message);
return false;
}
return true;
}
virtual int2 split_kernel_local_size()
{
return make_int2(64, 1);
}
virtual int2 split_kernel_global_size(device_memory& kg, device_memory& data, DeviceTask */*task*/)
{
cl_device_type type = OpenCLInfo::get_device_type(device->cdDevice);
/* Use small global size on CPU devices as it seems to be much faster. */
if(type == CL_DEVICE_TYPE_CPU) {
VLOG(1) << "Global size: (64, 64).";
return make_int2(64, 64);
}
cl_ulong max_buffer_size;
clGetDeviceInfo(device->cdDevice, CL_DEVICE_MAX_MEM_ALLOC_SIZE, sizeof(cl_ulong), &max_buffer_size, NULL);
VLOG(1) << "Maximum device allocation size: "
<< string_human_readable_number(max_buffer_size) << " bytes. ("
<< string_human_readable_size(max_buffer_size) << ").";
size_t num_elements = max_elements_for_max_buffer_size(kg, data, max_buffer_size / 2);
int2 global_size = make_int2(round_down((int)sqrt(num_elements), 64), (int)sqrt(num_elements));
VLOG(1) << "Global size: " << global_size << ".";
return global_size;
}
};
OpenCLDeviceSplitKernel::OpenCLDeviceSplitKernel(DeviceInfo& info, Stats &stats, bool background_)
: OpenCLDeviceBase(info, stats, background_)
{
split_kernel = new OpenCLSplitKernel(this);
background = background_;
}
Device *opencl_create_split_device(DeviceInfo& info, Stats& stats, bool background)
{
return new OpenCLDeviceSplitKernel(info, stats, background);
}
CCL_NAMESPACE_END
#endif /* WITH_OPENCL */
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