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CLK/Outputs/OpenGL/ScanTarget.hpp
2019-10-20 17:22:41 -04:00

255 lines
8.1 KiB
C++

//
// ScanTarget.hpp
// Clock Signal
//
// Created by Thomas Harte on 05/11/2018.
// Copyright © 2018 Thomas Harte. All rights reserved.
//
#ifndef ScanTarget_hpp
#define ScanTarget_hpp
#include "../Log.hpp"
#include "../DisplayMetrics.hpp"
#include "../ScanTarget.hpp"
#include "OpenGL.hpp"
#include "Primitives/TextureTarget.hpp"
#include "Primitives/Rectangle.hpp"
#include "../../SignalProcessing/FIRFilter.hpp"
#include <array>
#include <atomic>
#include <cstdint>
#include <chrono>
#include <list>
#include <memory>
#include <string>
#include <vector>
namespace Outputs {
namespace Display {
namespace OpenGL {
/*!
Provides a ScanTarget that uses OpenGL to render its output;
this uses various internal buffers so that the only geometry
drawn to the target framebuffer is a quad.
*/
class ScanTarget: public Outputs::Display::ScanTarget {
public:
ScanTarget(GLuint target_framebuffer = 0, float output_gamma = 2.2f);
~ScanTarget();
void set_target_framebuffer(GLuint);
/*! Pushes the current state of output to the target framebuffer. */
void draw(int output_width, int output_height);
/*! Processes all the latest input, at a resolution suitable for later output to a framebuffer of the specified size. */
void update(int output_width, int output_height);
/*! @returns The DisplayMetrics object that this ScanTarget has been providing with announcements and draw overages. */
Metrics &display_metrics();
private:
#ifndef NDEBUG
struct OpenGLVersionDumper {
OpenGLVersionDumper() {
// Note the OpenGL version, as the first thing this class does prior to construction.
LOG("Constructing scan target with OpenGL " << glGetString(GL_VERSION) << "; shading language version " << glGetString(GL_SHADING_LANGUAGE_VERSION));
}
} dumper_;
#endif
static constexpr int WriteAreaWidth = 2048;
static constexpr int WriteAreaHeight = 2048;
static constexpr int LineBufferWidth = 2048;
static constexpr int LineBufferHeight = 2048;
GLuint target_framebuffer_;
const float output_gamma_;
// Outputs::Display::ScanTarget overrides.
void set_modals(Modals) override;
Scan *begin_scan() override;
void end_scan() override;
uint8_t *begin_data(size_t required_length, size_t required_alignment) override;
void end_data(size_t actual_length) override;
void submit() override;
void announce(Event event, bool is_visible, const Outputs::Display::ScanTarget::Scan::EndPoint &location, uint8_t colour_burst_amplitude) override;
void will_change_owner() override;
bool output_is_visible_ = false;
Metrics display_metrics_;
int resolution_reduction_level_ = 1;
int output_height_ = 0;
size_t lines_submitted_ = 0;
std::chrono::high_resolution_clock::time_point line_submission_begin_time_;
// Extends the definition of a Scan to include two extra fields,
// relevant to the way that this scan target processes video.
struct Scan {
Outputs::Display::ScanTarget::Scan scan;
/// Stores the y coordinate that this scan's data is at, within the write area texture.
uint16_t data_y;
/// Stores the y coordinate of this scan within the line buffer.
uint16_t line;
};
struct PointerSet {
// This constructor is here to appease GCC's interpretation of
// an ambiguity in the C++ standard; cf. https://stackoverflow.com/questions/17430377
PointerSet() noexcept {}
// The sizes below might be less hassle as something more natural like ints,
// but squeezing this struct into 64 bits makes the std::atomics more likely
// to be lock free; they are under LLVM x86-64.
int write_area = 0;
uint16_t scan_buffer = 0;
uint16_t line = 0;
};
/// A pointer to the next thing that should be provided to the caller for data.
PointerSet write_pointers_;
/// A pointer to the final thing currently cleared for submission.
std::atomic<PointerSet> submit_pointers_;
/// A pointer to the first thing not yet submitted for display.
std::atomic<PointerSet> read_pointers_;
/// Maintains a buffer of the most recent scans.
std::array<Scan, 16384> scan_buffer_;
// Maintains a list of composite scan buffer coordinates; the Line struct
// is transported to the GPU in its entirety; the LineMetadatas live in CPU
// space only.
struct Line {
struct EndPoint {
uint16_t x, y;
uint16_t cycles_since_end_of_horizontal_retrace;
int16_t composite_angle;
} end_points[2];
uint16_t line;
uint8_t composite_amplitude;
};
struct LineMetadata {
bool is_first_in_frame;
bool previous_frame_was_complete;
};
std::array<Line, LineBufferHeight> line_buffer_;
std::array<LineMetadata, LineBufferHeight> line_metadata_buffer_;
// Contains the first composition of scans into lines;
// they're accumulated prior to output to allow for continuous
// application of any necessary conversions — e.g. composite processing.
TextureTarget unprocessed_line_texture_;
// Contains pre-lowpass-filtered chrominance information that is
// part-QAM-demoduled, if dealing with a QAM data source.
std::unique_ptr<TextureTarget> qam_chroma_texture_;
// Scans are accumulated to the accumulation texture; the full-display
// rectangle is used to ensure untouched pixels properly decay.
std::unique_ptr<TextureTarget> accumulation_texture_;
Rectangle full_display_rectangle_;
bool stencil_is_valid_ = false;
// Ephemeral state that helps in line composition.
Line *active_line_ = nullptr;
int provided_scans_ = 0;
bool is_first_in_frame_ = true;
bool frame_is_complete_ = true;
bool previous_frame_was_complete_ = true;
// OpenGL storage handles for buffer data.
GLuint scan_buffer_name_ = 0, scan_vertex_array_ = 0;
GLuint line_buffer_name_ = 0, line_vertex_array_ = 0;
template <typename T> void allocate_buffer(const T &array, GLuint &buffer_name, GLuint &vertex_array_name);
template <typename T> void patch_buffer(const T &array, GLuint target, uint16_t submit_pointer, uint16_t read_pointer);
// Uses a texture to vend write areas.
std::vector<uint8_t> write_area_texture_;
size_t data_type_size_ = 0;
GLuint write_area_texture_name_ = 0;
bool texture_exists_ = false;
// Ephemeral information for the begin/end functions.
Scan *vended_scan_ = nullptr;
int vended_write_area_pointer_ = 0;
// Track allocation failures.
bool data_is_allocated_ = false;
bool allocation_has_failed_ = false;
bool line_allocation_has_failed_ = false;
// Receives scan target modals.
Modals modals_;
bool modals_are_dirty_ = false;
void setup_pipeline();
enum class ShaderType {
Composition,
Conversion,
QAMSeparation
};
/*!
Calls @c taret.enable_vertex_attribute_with_pointer to attach all
globals for shaders of @c type to @c target.
*/
static void enable_vertex_attributes(ShaderType type, Shader &target);
void set_uniforms(ShaderType type, Shader &target) const;
std::vector<std::string> bindings(ShaderType type) const;
GLsync fence_ = nullptr;
std::atomic_flag is_updating_;
std::atomic_flag is_drawing_to_accumulation_buffer_;
std::unique_ptr<Shader> input_shader_;
std::unique_ptr<Shader> output_shader_;
std::unique_ptr<Shader> qam_separation_shader_;
/*!
Produces a shader that composes fragment of the input stream to a single buffer,
normalising the data into one of four forms: RGB, 8-bit luminance,
phase-linked luminance or luminance+phase offset.
*/
std::unique_ptr<Shader> composition_shader() const;
/*!
Produces a shader that reads from a composition buffer and converts to host
output RGB, decoding composite or S-Video as necessary.
*/
std::unique_ptr<Shader> conversion_shader() const;
/*!
Produces a shader that writes separated but not-yet filtered QAM components
from the unprocessed line texture to the QAM chroma texture, at a fixed
size of four samples per colour clock, point sampled.
*/
std::unique_ptr<Shader> qam_separation_shader() const;
void set_sampling_window(int output_Width, int output_height, Shader &target);
std::string sampling_function() const;
/*!
@returns true if the current display type is a 'soft' one, i.e. one in which
contrast tends to be low, such as a composite colour display.
*/
bool is_soft_display_type();
};
}
}
}
#endif /* ScanTarget_hpp */