// // Nick.hpp // Clock Signal // // Created by Thomas Harte on 14/06/2021. // Copyright © 2021 Thomas Harte. All rights reserved. // #ifndef Nick_hpp #define Nick_hpp #include #include "../../ClockReceiver/ClockReceiver.hpp" #include "../../Outputs/CRT/CRT.hpp" namespace Enterprise { class Nick { public: Nick(const uint8_t *ram); /// Writes to a Nick register; only the low two bits are decoded. void write(uint16_t address, uint8_t value); /// Reads from the Nick range. Nobody seems to be completely clear what /// this should return; I've set it up to return the last fetched video or mode /// line byte during periods when those things are being fetched, 0xff at all /// other times. Including during refresh, since I don't know what addresses /// are generated then. /// /// This likely isn't accurate, but is the most accurate guess I could make. uint8_t read(); void run_for(Cycles); Cycles get_time_until_z80_slot(Cycles after_period) const; void set_scan_target(Outputs::Display::ScanTarget *scan_target); Outputs::Display::ScanStatus get_scaled_scan_status() const; /// @returns The amount of time until the next potential change in interrupt output. Cycles get_next_sequence_point() const; /*! @returns The current state of the interrupt line — @c true for active; @c false for inactive. */ inline bool get_interrupt_line() const { return interrupt_line_; } /// Sets the type of output. void set_display_type(Outputs::Display::DisplayType); /// Gets the type of output. Outputs::Display::DisplayType get_display_type() const; private: Outputs::CRT::CRT crt_; const uint8_t *const ram_; // CPU-provided state. uint8_t line_parameter_control_ = 0xc0; uint16_t line_parameter_base_ = 0x0000; uint16_t border_colour_ = 0; // Ephemerals, related to current video position. int horizontal_counter_ = 0; uint16_t line_parameter_pointer_ = 0x0000; bool should_reload_line_parameters_ = true; uint16_t line_data_pointer_[2]; uint16_t start_line_data_pointer_[2]; mutable uint8_t last_read_ = 0xff; // Current mode line parameters. uint8_t lines_remaining_ = 0x00; uint8_t two_colour_mask_ = 0xff; int left_margin_ = 0, right_margin_ = 0; const uint16_t *alt_ind_palettes[4]; enum class Mode { Vsync, Pixel, Attr, CH256, CH128, CH64, Unused, LPixel, } mode_ = Mode::Vsync; bool is_sync_or_pixels_ = false; int bpp_ = 0; int column_size_ = 0; bool interrupt_line_ = true; int line_data_per_column_increments_[2] = {0, 0}; bool vres_ = false; bool reload_line_parameter_pointer_ = false; // An accumulator for border output regions. int border_duration_ = 0; // The destination for new pixels. static constexpr int allocation_size = 336; static_assert((allocation_size % 16) == 0, "Allocation size must be a multiple of 16"); uint16_t *pixel_pointer_ = nullptr, *allocated_pointer_ = nullptr; // Output transitions. enum class OutputType { Sync, Blank, Pixels, Border, ColourBurst }; void set_output_type(OutputType, bool force_flush = false); int output_duration_ = 0; OutputType output_type_ = OutputType::Sync; // Current palette. uint16_t palette_[16]{}; // The first column with pixels on it; will be either 8 or 10 depending // on whether the colour burst is meaningful to the current display type. int first_pixel_window_ = 10; // Specific outputters. template void output_pixel(uint16_t *target, int columns) const; template void output_character(uint16_t *target, int columns) const; template void output_attributed(uint16_t *target, int columns) const; }; } #endif /* Nick_hpp */