Refactored to use range based for instead of BOOST_FOREACH

[casparcg] / accelerator / cpu / image / image_mixer.cpp

/*
* Copyright (c) 2011 Sveriges Television AB <info@casparcg.com>
*
* This file is part of CasparCG (www.casparcg.com).
*
* CasparCG 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 3 of the License, or
* (at your option) any later version.
*
* CasparCG 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 CasparCG. If not, see <http://www.gnu.org/licenses/>.
*
* Author: Robert Nagy, ronag89@gmail.com
*/

#include "../../stdafx.h"

#include "image_mixer.h"

#include "../util/xmm.h"

#include <common/assert.h>
#include <common/gl/gl_check.h>
#include <common/future.h>
#include <common/array.h>

#include <core/frame/frame.h>
#include <core/frame/frame_transform.h>
#include <core/frame/pixel_format.h>
#include <core/video_format.h>

#include <modules/ffmpeg/producer/util/util.h>

#include <asmlib.h>

#include <gl/glew.h>

#include <tbb/cache_aligned_allocator.h>
#include <tbb/parallel_for.h>
#include <tbb/parallel_for_each.h>
#include <tbb/concurrent_queue.h>

#include <boost/range.hpp>
#include <boost/range/algorithm_ext/erase.hpp>
#include <boost/thread/future.hpp>

#include <algorithm>
#include <cstdint>
#include <vector>
#include <set>

#if defined(_MSC_VER)
#pragma warning (push)
#pragma warning (disable : 4244)
#endif
extern "C" 
{
        #include <libswscale/swscale.h>
        #include <libavcodec/avcodec.h>
        #include <libavformat/avformat.h>
}
#if defined(_MSC_VER)
#pragma warning (pop)
#endif

namespace caspar { namespace accelerator { namespace cpu {
                
struct item
{
        core::pixel_format_desc                 pix_desc;
        std::array<const uint8_t*, 4>   data;
        core::image_transform                   transform;

        item()
                : pix_desc(core::pixel_format::invalid)
        {
                data.fill(0);
        }
};

bool operator==(const item& lhs, const item& rhs)
{
        return lhs.data == rhs.data && lhs.transform == rhs.transform;
}

bool operator!=(const item& lhs, const item& rhs)
{
        return !(lhs == rhs);
}
        
// 100% accurate blending with correct rounding.
inline xmm::s8_x blend(xmm::s8_x d, xmm::s8_x s)
{       
        using namespace xmm;
                
        // C(S, D) = S + D - (((T >> 8) + T) >> 8);
        // T(S, D) = S * D[A] + 0x80

        auto aaaa   = s8_x::shuffle(d, s8_x(15, 15, 15, 15, 11, 11, 11, 11, 7, 7, 7, 7, 3, 3, 3, 3));
        d                       = s8_x(u8_x::min(u8_x(d), u8_x(aaaa))); // Overflow guard. Some source files have color values which incorrectly exceed pre-multiplied alpha values, e.g. red(255) > alpha(254).

        auto xaxa       = s16_x(aaaa) >> 8;             
                              
        auto t1         = s16_x::multiply_low(s16_x(s) & 0x00FF, xaxa) + 0x80;    
        auto t2         = s16_x::multiply_low(s16_x(s) >> 8    , xaxa) + 0x80;
                
        auto xyxy       = s8_x(((t1 >> 8) + t1) >> 8);      
        auto yxyx       = s8_x((t2 >> 8) + t2);    
        auto argb   = s8_x::blend(xyxy, yxyx, s8_x(-1, 0, -1, 0));

        return s8_x(s) + (d - argb);
}
        
template<typename temporal, typename alignment>
static void kernel(uint8_t* dest, const uint8_t* source, size_t count)
{                       
        using namespace xmm;

        for(auto n = 0; n < count; n += 32)    
        {
                auto s0 = s8_x::load<temporal_tag, alignment>(dest+n+0);
                auto s1 = s8_x::load<temporal_tag, alignment>(dest+n+16);

                auto d0 = s8_x::load<temporal_tag, alignment>(source+n+0);
                auto d1 = s8_x::load<temporal_tag, alignment>(source+n+16);
                
                auto argb0 = blend(d0, s0);
                auto argb1 = blend(d1, s1);

                s8_x::store<temporal, alignment>(argb0, dest+n+0 );
                s8_x::store<temporal, alignment>(argb1, dest+n+16);
        } 
}

template<typename temporal>
static void kernel(uint8_t* dest, const uint8_t* source, size_t count)
{                       
        using namespace xmm;

        if(reinterpret_cast<int>(dest) % 16 != 0 || reinterpret_cast<int>(source) % 16 != 0)
                kernel<temporal_tag, unaligned_tag>(dest, source, count);
        else
                kernel<temporal_tag, aligned_tag>(dest, source, count);
}

class image_renderer
{
        tbb::concurrent_unordered_map<int64_t, tbb::concurrent_bounded_queue<std::shared_ptr<SwsContext>>>      sws_devices_;
        tbb::concurrent_bounded_queue<spl::shared_ptr<buffer>>                                                                                          temp_buffers_;
public: 
        std::future<array<const std::uint8_t>> operator()(std::vector<item> items, const core::video_format_desc& format_desc)
        {       
                convert(items, format_desc.width, format_desc.height);          
                                
                // Remove first field stills.
                boost::range::remove_erase_if(items, [&](const item& item)
                {
                        return item.transform.is_still && item.transform.field_mode == format_desc.field_mode; // only us last field for stills.
                });
                
                // Stills are progressive
                for (auto& item : items)
                {
                        if(item.transform.is_still)
                                item.transform.field_mode = core::field_mode::progressive;
                }

                auto result = spl::make_shared<buffer>(format_desc.size, 0);
                if(format_desc.field_mode != core::field_mode::progressive)
                {                       
                        draw(items, result->data(), format_desc.width, format_desc.height, core::field_mode::upper);
                        draw(items, result->data(), format_desc.width, format_desc.height, core::field_mode::lower);
                }
                else
                {
                        draw(items, result->data(), format_desc.width, format_desc.height,  core::field_mode::progressive);
                }

                temp_buffers_.clear();
                
                return make_ready_future(array<const std::uint8_t>(result->data(), format_desc.size, true, result));
        }

private:

        void draw(std::vector<item> items, uint8_t* dest, std::size_t width, std::size_t height, core::field_mode field_mode)
        {               
                for (auto& item : items)
                        item.transform.field_mode &= field_mode;
                
                // Remove empty items.
                boost::range::remove_erase_if(items, [&](const item& item)
                {
                        return item.transform.field_mode == core::field_mode::empty;
                });

                if(items.empty())
                        return;
                
                auto start = field_mode == core::field_mode::lower ? 1 : 0;
                auto step  = field_mode == core::field_mode::progressive ? 1 : 2;
                
                // TODO: Add support for fill translations.
                // TODO: Add support for mask rect.
                // TODO: Add support for opacity.
                // TODO: Add support for mix transition.
                // TODO: Add support for push transition.
                // TODO: Add support for wipe transition.
                // TODO: Add support for slide transition.
                tbb::parallel_for(tbb::blocked_range<std::size_t>(0, height/step), [&](const tbb::blocked_range<std::size_t>& r)
                {
                        for(auto i = r.begin(); i != r.end(); ++i)
                        {
                                auto y = i*step+start;

                                for(std::size_t n = 0; n < items.size()-1; ++n)
                                        kernel<xmm::temporal_tag>(dest + y*width*4, items[n].data.at(0) + y*width*4, width*4);
                                
                                std::size_t n = items.size()-1;                         
                                kernel<xmm::nontemporal_tag>(dest + y*width*4, items[n].data.at(0) + y*width*4, width*4);
                        }

                        _mm_mfence();
                });
        }
                
        void convert(std::vector<item>& source_items, int width, int height)
        {
                std::set<std::array<const uint8_t*, 4>> buffers;

                for (auto& item : source_items)
                        buffers.insert(item.data);
                
                auto dest_items = source_items;

                tbb::parallel_for_each(buffers.begin(), buffers.end(), [&](const std::array<const uint8_t*, 4>& data)
                {                       
                        auto pix_desc = std::find_if(source_items.begin(), source_items.end(), [&](const item& item){return item.data == data;})->pix_desc;

                        if(pix_desc.format == core::pixel_format::bgra && 
                                pix_desc.planes.at(0).width == width &&
                                pix_desc.planes.at(0).height == height)
                                return;

                        std::array<uint8_t*, 4> data2 = {};
                        for(std::size_t n = 0; n < data.size(); ++n)
                                data2.at(n) = const_cast<uint8_t*>(data[n]);

                        auto input_av_frame = ffmpeg::make_av_frame(data2, pix_desc);

                
                        int64_t key = ((static_cast<int64_t>(input_av_frame->width)      << 32) & 0xFFFF00000000) | 
                                                  ((static_cast<int64_t>(input_av_frame->height) << 16) & 0xFFFF0000) | 
                                                  ((static_cast<int64_t>(input_av_frame->format) <<  8) & 0xFF00);

                        auto& pool = sws_devices_[key];

                        std::shared_ptr<SwsContext> sws_device;
                        if(!pool.try_pop(sws_device))
                        {
                                double param;
                                sws_device.reset(sws_getContext(input_av_frame->width, input_av_frame->height, static_cast<PixelFormat>(input_av_frame->format), width, height, PIX_FMT_BGRA, SWS_BILINEAR, nullptr, nullptr, &param), sws_freeContext);
                        }
                        
                        if(!sws_device)                         
                                CASPAR_THROW_EXCEPTION(operation_failed() << msg_info("Could not create software scaling device.") << boost::errinfo_api_function("sws_getContext"));                           
                
                        auto dest_frame = spl::make_shared<buffer>(width*height*4);
                        temp_buffers_.push(dest_frame);

                        {
                                spl::shared_ptr<AVFrame> dest_av_frame(avcodec_alloc_frame(), av_free); 
                                avcodec_get_frame_defaults(dest_av_frame.get());                        
                                avpicture_fill(reinterpret_cast<AVPicture*>(dest_av_frame.get()), dest_frame->data(), PIX_FMT_BGRA, width, height);
                                
                                sws_scale(sws_device.get(), input_av_frame->data, input_av_frame->linesize, 0, input_av_frame->height, dest_av_frame->data, dest_av_frame->linesize);                           
                                pool.push(sws_device);
                        }
                                        
                        for(std::size_t n = 0; n < source_items.size(); ++n)
                        {
                                if(source_items[n].data == data)
                                {
                                        dest_items[n].data.assign(0);
                                        dest_items[n].data[0]                   = dest_frame->data();
                                        dest_items[n].pix_desc                  = core::pixel_format_desc(core::pixel_format::bgra);
                                        dest_items[n].pix_desc.planes   = { core::pixel_format_desc::plane(width, height, 4) };
                                        dest_items[n].transform                 = source_items[n].transform;
                                }
                        }
                });     

                source_items = std::move(dest_items);
        }
};
                
struct image_mixer::impl : boost::noncopyable
{       
        image_renderer                                          renderer_;
        std::vector<core::image_transform>      transform_stack_;
        std::vector<item>                                       items_; // layer/stream/items
public:
        impl() 
                : transform_stack_(1)   
        {
                CASPAR_LOG(info) << L"Initialized Streaming SIMD Extensions Accelerated CPU Image Mixer";
        }

        void begin_layer(core::blend_mode blend_mode)
        {
        }
                
        void push(const core::frame_transform& transform)
        {
                transform_stack_.push_back(transform_stack_.back()*transform.image_transform);
        }
                
        void visit(const core::const_frame& frame)
        {                       
                if(frame.pixel_format_desc().format == core::pixel_format::invalid)
                        return;

                if(frame.pixel_format_desc().planes.empty())
                        return;
                
                if(frame.pixel_format_desc().planes.at(0).size < 16)
                        return;

                if(transform_stack_.back().field_mode == core::field_mode::empty)
                        return;

                item item;
                item.pix_desc   = frame.pixel_format_desc();
                item.transform  = transform_stack_.back();
                for(int n = 0; n < item.pix_desc.planes.size(); ++n)
                        item.data.at(n) = frame.image_data(n).begin();          

                items_.push_back(item);
        }

        void pop()
        {
                transform_stack_.pop_back();
        }

        void end_layer()
        {               
        }
        
        std::future<array<const std::uint8_t>> render(const core::video_format_desc& format_desc)
        {
                return renderer_(std::move(items_), format_desc);
        }
        
        virtual core::mutable_frame create_frame(const void* tag, const core::pixel_format_desc& desc)
        {
                std::vector<array<std::uint8_t>> buffers;
                for (auto& plane : desc.planes)
                {
                        auto buf = spl::make_shared<buffer>(plane.size);
                        buffers.push_back(array<std::uint8_t>(buf->data(), plane.size, true, buf));
                }
                return core::mutable_frame(std::move(buffers), core::audio_buffer(), tag, desc);
        }
};

image_mixer::image_mixer() : impl_(new impl()){}
image_mixer::~image_mixer(){}
void image_mixer::push(const core::frame_transform& transform){impl_->push(transform);}
void image_mixer::visit(const core::const_frame& frame){impl_->visit(frame);}
void image_mixer::pop(){impl_->pop();}
std::future<array<const std::uint8_t>> image_mixer::operator()(const core::video_format_desc& format_desc){return impl_->render(format_desc);}
void image_mixer::begin_layer(core::blend_mode blend_mode){impl_->begin_layer(blend_mode);}
void image_mixer::end_layer(){impl_->end_layer();}
core::mutable_frame image_mixer::create_frame(const void* tag, const core::pixel_format_desc& desc) {return impl_->create_frame(tag, desc);}

}}}