// // BufferingScanTarget.hpp // Clock Signal // // Created by Thomas Harte on 22/07/2020. // Copyright © 2020 Thomas Harte. All rights reserved. // #ifndef BufferingScanTarget_hpp #define BufferingScanTarget_hpp #include "../ScanTarget.hpp" #include "../DisplayMetrics.hpp" #include #include #include #include #include namespace Outputs { namespace Display { /*! Provides basic thread-safe (hopefully) circular queues for any scan target that: * will store incoming Scans into a linear circular buffer and pack regions of incoming pixel data into a 2048x2048 2d texture; * will compose whole lines of content by partioning the Scans based on sync placement and then pasting together their content; * will process those lines as necessary to map from input format to whatever suits the display; and * will then output the lines. This buffer rejects new data when full. */ class BufferingScanTarget: public Outputs::Display::ScanTarget { public: /*! @returns The DisplayMetrics object that this ScanTarget has been providing with announcements and draw overages. */ const Metrics &display_metrics(); protected: static constexpr int WriteAreaWidth = 2048; static constexpr int WriteAreaHeight = 2048; BufferingScanTarget(); // This is included because it's assumed that scan targets will want to expose one. // It is the subclass's responsibility to post timings. Metrics display_metrics_; // Extends the definition of a Scan to include two extra fields, // completing this scan's source data and destination locations. struct alignas(4) Scan { Outputs::Display::ScanTarget::Scan scan; /// Stores the y coordinate for this scan's data within the write area texture. /// Use this plus the scan's endpoints' data_offsets to locate this data in 2d. uint16_t data_y; /// Stores the y coordinate assigned to this scan within the intermediate buffers. /// Use this plus this scan's endpoints' x locations to determine where to composite /// this data for intermediate processing. uint16_t line; }; /// Defines the boundaries of a complete line of video — a 2d start and end location, /// composite phase and amplitude (if relevant), the source line in the intermediate buffer /// plus the start and end offsets of the area that is visible from the intermediate buffer. struct alignas(4) Line { struct alignas(4) 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; }; /// Provides additional metadata about lines; this is separate because it's unlikely to be of /// interest to the GPU, unlike the fields in Line. struct LineMetadata { /// @c true if this line was the first drawn after vertical sync; @c false otherwise. bool is_first_in_frame; /// @c true if this line is the first in the frame and if every single piece of output /// from the previous frame was recorded; @c false otherwise. Data can be dropped /// from a frame if performance problems mean that the emulated machine is running /// more quickly than complete frames can be generated. bool previous_frame_was_complete; }; /// Sets the area of memory to use as a scan buffer. void set_scan_buffer(Scan *buffer, size_t size); /// Sets the area of memory to use as line and line metadata buffers. void set_line_buffer(Line *line_buffer, LineMetadata *metadata_buffer, size_t size); /// Sets a new base address for the texture. /// When called this will flush all existing data and load up the /// new data size. void set_write_area(uint8_t *base); /// @returns The number of bytes per input sample, as per the latest modals. size_t write_area_data_size() const; /// Defines a segment of data now ready for output, consisting of start and endpoints for: /// /// (i) the region of the write area that has been modified; if the caller is using shared memory /// for the write area then it can ignore this information; /// /// (ii) the number of scans that have been completed; and /// /// (iii) the number of lines that have been completed. /// /// New write areas and scans are exposed only upon completion of the corresponding lines. struct OutputArea { struct Endpoint { int write_area_x, write_area_y; size_t scan; size_t line; }; Endpoint start, end; }; /// Performs @c action ensuring that no other @c perform actions, or any /// change to modals, occurs simultaneously. void perform(const std::function &action); /// Acts as per void(void) @c perform but also dequeues all latest available video output. void perform(const std::function &); /// @returns new Modals if any have been set since the last call to get_new_modals(). /// The caller must be within a @c perform block. const Modals *new_modals(); /// @returns the current @c Modals. const Modals &modals() const; private: // ScanTarget overrides. void set_modals(Modals) final; Outputs::Display::ScanTarget::Scan *begin_scan() final; void end_scan() final; uint8_t *begin_data(size_t required_length, size_t required_alignment) final; void end_data(size_t actual_length) final; void announce(Event event, bool is_visible, const Outputs::Display::ScanTarget::Scan::EndPoint &location, uint8_t colour_burst_amplitude) final; void will_change_owner() final; // Uses a texture to vend write areas. uint8_t *write_area_ = nullptr; size_t data_type_size_ = 0; // Tracks changes in raster visibility in order to populate // Lines and LineMetadatas. bool output_is_visible_ = false; // Track allocation failures. bool data_is_allocated_ = false; bool allocation_has_failed_ = false; // Ephemeral information for the begin/end functions. Scan *vended_scan_ = nullptr; int vended_write_area_pointer_ = 0; // Ephemeral state that helps in line composition. int provided_scans_ = 0; bool is_first_in_frame_ = true; bool frame_is_complete_ = true; bool previous_frame_was_complete_ = true; // By convention everything in the PointerSet points to the next instance // of whatever it is that will be used. So a client should start with whatever // is pointed to by the read pointers and carry until it gets to a value that // is equal to whatever is in the submit pointers. 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 {} // Squeezing this struct into 64 bits makes the std::atomics more likely // to be lock free; they are under LLVM x86-64. // Points to the vended area in the write area texture. // The vended area is always preceded by a guard pixel, so a // sensible default construction is write_area = 1. int32_t write_area = 1; // Points into the scan buffer. uint16_t scan_buffer = 0; // Points into the line buffer. uint16_t line = 0; }; /// A pointer to the final thing currently cleared for submission. std::atomic submit_pointers_; /// A pointer to the first thing not yet submitted for display; this is /// atomic since it also acts as the buffer into which the write_pointers_ /// may run and is therefore used by both producer and consumer. std::atomic read_pointers_; /// This is used as a spinlock to guard `perform` calls. std::atomic_flag is_updating_; /// A mutex for gettng access to anything the producer modifies — i.e. the write_pointers_, /// data_type_size_ and write_area_texture_, and all other state to do with capturing /// data, scans and lines. /// /// This is almost never contended. The main collision is a user-prompted change of modals while the /// emulation thread is running. std::mutex producer_mutex_; /// A pointer to the next thing that should be provided to the caller for data. PointerSet write_pointers_; // The owner-supplied scan buffer and size. Scan *scan_buffer_ = nullptr; size_t scan_buffer_size_ = 0; // The owner-supplied line buffer and size. Line *line_buffer_ = nullptr; LineMetadata *line_metadata_buffer_ = nullptr; size_t line_buffer_size_ = 0; // Current modals and whether they've yet been returned // from a call to @c get_new_modals. Modals modals_; bool modals_are_dirty_ = false; }; } } #endif /* BufferingScanTarget_hpp */