1
0
mirror of https://github.com/TomHarte/CLK.git synced 2024-11-28 06:49:39 +00:00
CLK/Machines/Acorn/Electron/Video.hpp
2024-09-08 21:12:45 -04:00

184 lines
5.8 KiB
C++
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

//
// Video.hpp
// Clock Signal
//
// Created by Thomas Harte on 10/12/2016.
// Copyright 2016 Thomas Harte. All rights reserved.
//
#pragma once
#include "../../../Outputs/CRT/CRT.hpp"
#include "../../../ClockReceiver/ClockReceiver.hpp"
#include "Interrupts.hpp"
#include <vector>
namespace Electron {
/*!
Implements the Electron's video subsystem plus appropriate signalling.
The Electron has an interlaced fully-bitmapped display with six different output modes,
running either at 40 or 80 columns. Memory is shared between video and CPU; when the video
is accessing it the CPU may not.
*/
class VideoOutput {
public:
/*!
Instantiates a VideoOutput that will read its pixels from @c memory.
The pointer supplied should be to address 0 in the unexpanded Electron's memory map.
*/
VideoOutput(const uint8_t *memory);
/// Sets the destination for output.
void set_scan_target(Outputs::Display::ScanTarget *scan_target);
/// Gets the current scan status.
Outputs::Display::ScanStatus get_scaled_scan_status() const;
/// Sets the type of output.
void set_display_type(Outputs::Display::DisplayType);
/// Gets the type of output.
Outputs::Display::DisplayType get_display_type() const;
/// Produces the next @c cycles of video output.
///
/// @returns a bit mask of all interrupts triggered.
uint8_t run_for(const Cycles cycles);
/// @returns The number of 2Mhz cycles that will pass before completion of an attempted
/// IO [/1Mhz] access that is first signalled in the upcoming cycle.
Cycles io_delay() {
return 2 + ((h_count_ >> 3)&1);
}
/// @returns The number of 2Mhz cycles that will pass before completion of an attempted
/// RAM access that is first signalled in the upcoming cycle.
Cycles ram_delay() {
if(!mode_40_ && !in_blank()) {
return 2 + ((h_active - h_count_) >> 3);
}
return io_delay();
}
/*!
Writes @c value to the register at @c address. May mutate the results of @c get_next_interrupt,
@c get_cycles_until_next_ram_availability and @c get_memory_access_range.
*/
void write(int address, uint8_t value);
/*!
@returns the number of cycles after (final cycle of last run_for batch + @c from_time)
before the video circuits will allow the CPU to access RAM.
*/
unsigned int get_cycles_until_next_ram_availability(int from_time);
private:
const uint8_t *ram_ = nullptr;
// CRT output
enum class OutputStage {
Sync, Blank, Pixels, ColourBurst,
};
OutputStage output_ = OutputStage::Blank;
int output_length_ = 0;
int screen_pitch_ = 0;
uint8_t *current_output_target_ = nullptr;
uint8_t *initial_output_target_ = nullptr;
int current_output_divider_ = 1;
Outputs::CRT::CRT crt_;
// Palettes.
uint8_t palette_[8]{};
uint8_t palette1bpp_[2]{};
uint8_t palette2bpp_[4]{};
uint8_t palette4bpp_[16]{};
template <int index, int source_bit, int target_bit>
uint8_t channel() {
if constexpr (source_bit < target_bit) {
return (palette_[index] << (target_bit - source_bit)) & (1 << target_bit);
} else {
return (palette_[index] >> (source_bit - target_bit)) & (1 << target_bit);
}
}
template <int r_index, int r_bit, int g_index, int g_bit, int b_index, int b_bit>
uint8_t palette_entry() {
return channel<r_index, r_bit, 2>() | channel<g_index, g_bit, 1>() | channel<b_index, b_bit, 0>();
}
// User-selected base address; constrained to a 64-byte boundary by the setter.
uint16_t screen_base_ = 0;
// Parameters implied by mode selection.
uint16_t mode_base_ = 0;
bool mode_40_ = true;
bool mode_text_ = false;
enum class Bpp {
One = 1, Two = 2, Four = 4
} mode_bpp_ = Bpp::One;
// Frame position.
int v_count_ = 0;
int h_count_ = 0;
bool field_ = true;
// Current working address.
uint16_t row_addr_ = 0; // Address, sans character row, adopted at the start of a row.
uint16_t byte_addr_ = 0; // Current working address, incremented as the raster moves across the line.
int char_row_ = 0; // Character row; 09 in text mode, 07 in graphics.
// Sync states.
bool vsync_int_ = false; // True => vsync active.
bool hsync_int_ = false; // True => hsync active.
// Horizontal timing parameters; all in terms of the 16Mhz pixel clock but conveniently all
// divisible by 8, so it's safe to count time with a 2Mhz input.
static constexpr int h_active = 640;
static constexpr int hsync_start = 768;
static constexpr int hsync_end = 832;
static constexpr int h_reset_addr = 1016;
static constexpr int h_total = 1024; // Minor digression from the FPGA original here;
// in this implementation the value is tested
// _after_ position increment rather than before/instead.
// So it needs to be one higher. Which is baked into
// the constant to emphasise the all-divisible-by-8 property.
static constexpr int h_half = h_total / 2;
static constexpr int hburst_start = 856;
static constexpr int hburst_end = 896;
// Vertical timing parameters; all in terms of lines. As per the horizontal parameters above,
// lines begin with their first visible pixel (or the equivalent position).
static constexpr int v_active_gph = 256;
static constexpr int v_active_txt = 250;
static constexpr int v_disp_gph = v_active_gph - 1;
static constexpr int v_disp_txt = v_active_txt - 1;
static constexpr int vsync_start = 274;
static constexpr int vsync_end = 276;
static constexpr int v_rtc = 99;
// Various signals that it was convenient to factor out.
int v_total() const {
return field_ ? 312 : 311;
}
bool last_line() const {
return char_row_ == (mode_text_ ? 9 : 7);
}
bool in_blank() const {
return h_count_ >= h_active || (mode_text_ && v_count_ >= v_active_txt) || (!mode_text_ && v_count_ >= v_active_gph) || char_row_ >= 8;
}
bool is_v_end() const {
return v_count_ == v_total();
}
};
}