CLK/Machines/Amiga/Blitter.hpp

//
//  Blitter.hpp
//  Clock Signal
//
//  Created by Thomas Harte on 22/07/2021.
//  Copyright © 2021 Thomas Harte. All rights reserved.
//

#ifndef Blitter_hpp
#define Blitter_hpp

#include <cstddef>
#include <cstdint>

#include "../../ClockReceiver/ClockReceiver.hpp"
#include "DMADevice.hpp"

namespace Amiga {

/*!
	Statefully provides the next access the Blitter should make.

	TODO: determine the actual logic here, rather than
	relying on tables.
*/
class BlitterSequencer {
	public:
		enum class Channel {
			/// Tells the caller to calculate and load a new piece of output
			/// into the output pipeline if any new inputs have been provided
			/// if any inputs are enabled then a two-stage output pipeline applies:
			/// if anything is already in the pipeline then it should now be written.
			/// Then the new value should be placed into the pipeline ready for the
			/// next write slot.
			///
			/// If the pipeline is empty, this acts the same as @c None, indicating
			/// an unused DMA slot.
			Write,
			/// The caller should read from channel C.
			C,
			/// The caller should read from channel B.
			B,
			/// The caller should read from channel A.
			A,
			/// Indicates an unused DMA slot.
			None
		};

		/// Sets the current control value, which indicates which
		/// channels are enabled.
		void set_control(int control) {
			control_ = control & 0xf;
			index_ = 0;	// TODO: this probably isn't accurate; case caught is a change
						// of control values during a blit.
		}

		/// Indicates that blitting should conclude after this step, i.e.
		/// whatever is being fetched now is part of the final set of input data;
		/// this is safe to call following a fetch request on any channel.
		void complete() {
			next_phase_ =
				(control_ == 0x9 || control_ == 0xb || control_ == 0xd) ?
					Phase::PauseAndComplete : Phase::Complete;
		}

		/// Begins a blit operation.
		void begin() {
			phase_ = next_phase_ = Phase::Ongoing;
			index_ = loop_ = 0;
		}

		/// Provides the next channel to fetch from, or that a write is required,
		/// along with a count of complete channel iterations so far completed.
		std::pair<Channel, int> next() {
			switch(phase_) {
				default: break;

				case Phase::Complete:
				return std::make_pair(Channel::Write, loop_);

				case Phase::PauseAndComplete:
					phase_ = Phase::Complete;
				return std::make_pair(Channel::None, loop_);
			}

			Channel next = Channel::None;

			switch(control_) {
				default: break;

				case 1: next = next_channel(pattern1); break;
				case 2: next = next_channel(pattern2); break;
				case 3: next = next_channel(pattern3); break;
				case 4: next = next_channel(pattern4); break;
				case 5: next = next_channel(pattern5); break;
				case 6: next = next_channel(pattern6); break;
				case 7: next = next_channel(pattern7); break;
				case 8: next = next_channel(pattern8); break;
				case 9: next = next_channel(pattern9); break;
				case 10: next = next_channel(patternA); break;
				case 11: next = next_channel(patternB); break;
				case 12: next = next_channel(patternC); break;
				case 13: next = next_channel(patternD); break;
				case 14: next = next_channel(patternE); break;
				case 15: next = next_channel(patternF); break;
			}

			return std::make_pair(next, loop_);
		}

	private:
		static constexpr std::array<Channel, 2> pattern1 = { Channel::Write, Channel::None };
		static constexpr std::array<Channel, 2> pattern2 = { Channel::C, Channel::None };
		static constexpr std::array<Channel, 3> pattern3 = { Channel::C, Channel::Write, Channel::None };
		static constexpr std::array<Channel, 3> pattern4 = { Channel::B, Channel::None, Channel::None };
		static constexpr std::array<Channel, 3> pattern5 = { Channel::B, Channel::Write, Channel::None };
		static constexpr std::array<Channel, 3> pattern6 = { Channel::B, Channel::C, Channel::None };
		static constexpr std::array<Channel, 4> pattern7 = { Channel::B, Channel::C, Channel::Write, Channel::None };
		static constexpr std::array<Channel, 2> pattern8 = { Channel::A, Channel::None };
		static constexpr std::array<Channel, 2> pattern9 = { Channel::A, Channel::Write };
		static constexpr std::array<Channel, 2> patternA = { Channel::A, Channel::C };
		static constexpr std::array<Channel, 3> patternB = { Channel::A, Channel::C, Channel::Write };
		static constexpr std::array<Channel, 3> patternC = { Channel::A, Channel::B, Channel::None };
		static constexpr std::array<Channel, 3> patternD = { Channel::A, Channel::B, Channel::Write };
		static constexpr std::array<Channel, 3> patternE = { Channel::A, Channel::B, Channel::C };
		static constexpr std::array<Channel, 4> patternF = { Channel::A, Channel::B, Channel::C, Channel::Write };
		template <typename ArrayT> Channel next_channel(const ArrayT &list) {
			loop_ += index_ / list.size();
			index_ %= list.size();
			const Channel result = list[index_];
			++index_;
			if(index_ == list.size()) {
				phase_ = next_phase_;
			}
			return result;
		}

		// Current control flags, i.e. which channels are enabled.
		int control_ = 0;

		// Index into the pattern table for this blit.
		size_t index_ = 0;

		// Number of times the entire pattern table has been completed.
		int loop_ = 0;

		enum class Phase {
			/// Return the next thing in the pattern table and advance.
			/// If looping from the end of the pattern table to the start,
			/// set phase_ to next_phase_.
			Ongoing,
			/// Return a Channel::None and advancce to phase_ = Phase::Complete.
			PauseAndComplete,
			/// Return Channel::Write indefinitely.
			Complete
		};

		// Current sequencer pahse.
		Phase phase_ = Phase::Complete;
		// Phase to assume at the end of this iteration of the sequence table.
		Phase next_phase_ = Phase::Complete;
};

class Blitter: public DMADevice<4, 4> {
	public:
		using DMADevice::DMADevice;

		// Various setters; it's assumed that address decoding is handled externally.
		//
		// In all cases where a channel is identified numerically, it's taken that
		// 0 = A, 1 = B, 2 = C, 3 = D.
		void set_control(int index, uint16_t value);
		void set_first_word_mask(uint16_t value);
		void set_last_word_mask(uint16_t value);

		void set_size(uint16_t value);
		void set_minterms(uint16_t value);
//		void set_vertical_size(uint16_t value);
//		void set_horizontal_size(uint16_t value);
		void set_data(int channel, uint16_t value);

		uint16_t get_status();

		bool advance_dma();

	private:
		int width_ = 0, height_ = 0;
		int shifts_[2]{};
		uint16_t a_mask_[2] = {0xffff, 0xffff};

		bool line_mode_ = false;
		bool one_dot_ = false;
		int line_direction_ = 0;
		int line_sign_ = 1;

		uint32_t direction_ = 1;
		bool inclusive_fill_ = false;
		bool exclusive_fill_ = false;
		bool fill_carry_ = false;

		bool channel_enables_[4]{};

		uint8_t minterms_ = 0;
		uint32_t a32_ = 0, b32_ = 0;
		uint16_t a_data_ = 0, b_data_ = 0, c_data_ = 0;

		bool not_zero_flag_ = false;
};

}


#endif /* Blitter_hpp */
Sketches out a blitter class. 2021-07-22 22:43:07 +00:00			`//`
			`// Blitter.hpp`
			`// Clock Signal`
			`//`
			`// Created by Thomas Harte on 22/07/2021.`
			`// Copyright © 2021 Thomas Harte. All rights reserved.`
			`//`

			`#ifndef Blitter_hpp`
			`#define Blitter_hpp`

			`#include <cstddef>`
			`#include <cstdint>`

			`#include "../../ClockReceiver/ClockReceiver.hpp"`
Factors out DMADevice, which is now a parent of Blitter. 2021-09-15 00:51:32 +00:00			`#include "DMADevice.hpp"`
Sketches out a blitter class. 2021-07-22 22:43:07 +00:00
			`namespace Amiga {`

Add documentation, formal begin function. 2022-07-27 02:01:43 +00:00			`/*!`
			`Statefully provides the next access the Blitter should make.`

			`TODO: determine the actual logic here, rather than`
			`relying on tables.`
			`*/`
Introduce putative blitter sequencer. 2022-07-26 21:05:05 +00:00			`class BlitterSequencer {`
			`public:`
			`enum class Channel {`
Add documentation, formal begin function. 2022-07-27 02:01:43 +00:00			`/// Tells the caller to calculate and load a new piece of output`
			`/// into the output pipeline if any new inputs have been provided`
			`/// if any inputs are enabled then a two-stage output pipeline applies:`
			`/// if anything is already in the pipeline then it should now be written.`
			`/// Then the new value should be placed into the pipeline ready for the`
			`/// next write slot.`
			`///`
			`/// If the pipeline is empty, this acts the same as @c None, indicating`
			`/// an unused DMA slot.`
			`Write,`
			`/// The caller should read from channel C.`
			`C,`
			`/// The caller should read from channel B.`
			`B,`
			`/// The caller should read from channel A.`
			`A,`
			`/// Indicates an unused DMA slot.`
			`None`
Introduce putative blitter sequencer. 2022-07-26 21:05:05 +00:00			`};`

Add documentation, formal begin function. 2022-07-27 02:01:43 +00:00			`/// Sets the current control value, which indicates which`
			`/// channels are enabled.`
Introduce putative blitter sequencer. 2022-07-26 21:05:05 +00:00			`void set_control(int control) {`
Provide a loop count directly from the sequencer. This avoids the caller having to take a guess at iterations. 2022-07-29 16:14:59 +00:00			`control_ = control & 0xf;`
			`index_ = 0; // TODO: this probably isn't accurate; case caught is a change`
			`// of control values during a blit.`
Introduce putative blitter sequencer. 2022-07-26 21:05:05 +00:00			`}`

Add documentation, formal begin function. 2022-07-27 02:01:43 +00:00			`/// Indicates that blitting should conclude after this step, i.e.`
			`/// whatever is being fetched now is part of the final set of input data;`
			`/// this is safe to call following a fetch request on any channel.`
Introduce putative blitter sequencer. 2022-07-26 21:05:05 +00:00			`void complete() {`
Provide a loop count directly from the sequencer. This avoids the caller having to take a guess at iterations. 2022-07-29 16:14:59 +00:00			`next_phase_ =`
Add documentation, formal begin function. 2022-07-27 02:01:43 +00:00			`(control_ == 0x9 \|\| control_ == 0xb \|\| control_ == 0xd) ?`
			`Phase::PauseAndComplete : Phase::Complete;`
			`}`

			`/// Begins a blit operation.`
			`void begin() {`
Provide a loop count directly from the sequencer. This avoids the caller having to take a guess at iterations. 2022-07-29 16:14:59 +00:00			`phase_ = next_phase_ = Phase::Ongoing;`
			`index_ = loop_ = 0;`
Introduce putative blitter sequencer. 2022-07-26 21:05:05 +00:00			`}`

Provide a loop count directly from the sequencer. This avoids the caller having to take a guess at iterations. 2022-07-29 16:14:59 +00:00			`/// Provides the next channel to fetch from, or that a write is required,`
			`/// along with a count of complete channel iterations so far completed.`
			`std::pair<Channel, int> next() {`
Add documentation, formal begin function. 2022-07-27 02:01:43 +00:00			`switch(phase_) {`
			`default: break;`

			`case Phase::Complete:`
Provide a loop count directly from the sequencer. This avoids the caller having to take a guess at iterations. 2022-07-29 16:14:59 +00:00			`return std::make_pair(Channel::Write, loop_);`
Add documentation, formal begin function. 2022-07-27 02:01:43 +00:00
			`case Phase::PauseAndComplete:`
Provide a loop count directly from the sequencer. This avoids the caller having to take a guess at iterations. 2022-07-29 16:14:59 +00:00			`phase_ = Phase::Complete;`
			`return std::make_pair(Channel::None, loop_);`
Introduce putative blitter sequencer. 2022-07-26 21:05:05 +00:00			`}`

			`Channel next = Channel::None;`

			`switch(control_) {`
			`default: break;`

			`case 1: next = next_channel(pattern1); break;`
			`case 2: next = next_channel(pattern2); break;`
			`case 3: next = next_channel(pattern3); break;`
			`case 4: next = next_channel(pattern4); break;`
			`case 5: next = next_channel(pattern5); break;`
			`case 6: next = next_channel(pattern6); break;`
			`case 7: next = next_channel(pattern7); break;`
			`case 8: next = next_channel(pattern8); break;`
			`case 9: next = next_channel(pattern9); break;`
			`case 10: next = next_channel(patternA); break;`
			`case 11: next = next_channel(patternB); break;`
			`case 12: next = next_channel(patternC); break;`
			`case 13: next = next_channel(patternD); break;`
			`case 14: next = next_channel(patternE); break;`
			`case 15: next = next_channel(patternF); break;`
			`}`

Provide a loop count directly from the sequencer. This avoids the caller having to take a guess at iterations. 2022-07-29 16:14:59 +00:00			`return std::make_pair(next, loop_);`
Introduce putative blitter sequencer. 2022-07-26 21:05:05 +00:00			`}`

			`private:`
			`static constexpr std::array<Channel, 2> pattern1 = { Channel::Write, Channel::None };`
			`static constexpr std::array<Channel, 2> pattern2 = { Channel::C, Channel::None };`
			`static constexpr std::array<Channel, 3> pattern3 = { Channel::C, Channel::Write, Channel::None };`
			`static constexpr std::array<Channel, 3> pattern4 = { Channel::B, Channel::None, Channel::None };`
			`static constexpr std::array<Channel, 3> pattern5 = { Channel::B, Channel::Write, Channel::None };`
			`static constexpr std::array<Channel, 3> pattern6 = { Channel::B, Channel::C, Channel::None };`
			`static constexpr std::array<Channel, 4> pattern7 = { Channel::B, Channel::C, Channel::Write, Channel::None };`
			`static constexpr std::array<Channel, 2> pattern8 = { Channel::A, Channel::None };`
			`static constexpr std::array<Channel, 2> pattern9 = { Channel::A, Channel::Write };`
			`static constexpr std::array<Channel, 2> patternA = { Channel::A, Channel::C };`
			`static constexpr std::array<Channel, 3> patternB = { Channel::A, Channel::C, Channel::Write };`
			`static constexpr std::array<Channel, 3> patternC = { Channel::A, Channel::B, Channel::None };`
			`static constexpr std::array<Channel, 3> patternD = { Channel::A, Channel::B, Channel::Write };`
			`static constexpr std::array<Channel, 3> patternE = { Channel::A, Channel::B, Channel::C };`
			`static constexpr std::array<Channel, 4> patternF = { Channel::A, Channel::B, Channel::C, Channel::Write };`
			`template <typename ArrayT> Channel next_channel(const ArrayT &list) {`
Provide a loop count directly from the sequencer. This avoids the caller having to take a guess at iterations. 2022-07-29 16:14:59 +00:00			`loop_ += index_ / list.size();`
			`index_ %= list.size();`
Introduce putative blitter sequencer. 2022-07-26 21:05:05 +00:00			`const Channel result = list[index_];`
Provide a loop count directly from the sequencer. This avoids the caller having to take a guess at iterations. 2022-07-29 16:14:59 +00:00			`++index_;`
			`if(index_ == list.size()) {`
			`phase_ = next_phase_;`
			`}`
Introduce putative blitter sequencer. 2022-07-26 21:05:05 +00:00			`return result;`
			`}`

Provide a loop count directly from the sequencer. This avoids the caller having to take a guess at iterations. 2022-07-29 16:14:59 +00:00			`// Current control flags, i.e. which channels are enabled.`
Introduce putative blitter sequencer. 2022-07-26 21:05:05 +00:00			`int control_ = 0;`
Provide a loop count directly from the sequencer. This avoids the caller having to take a guess at iterations. 2022-07-29 16:14:59 +00:00
			`// Index into the pattern table for this blit.`
Add documentation, formal begin function. 2022-07-27 02:01:43 +00:00			`size_t index_ = 0;`
Provide a loop count directly from the sequencer. This avoids the caller having to take a guess at iterations. 2022-07-29 16:14:59 +00:00
			`// Number of times the entire pattern table has been completed.`
			`int loop_ = 0;`

Add documentation, formal begin function. 2022-07-27 02:01:43 +00:00			`enum class Phase {`
Provide a loop count directly from the sequencer. This avoids the caller having to take a guess at iterations. 2022-07-29 16:14:59 +00:00			`/// Return the next thing in the pattern table and advance.`
			`/// If looping from the end of the pattern table to the start,`
			`/// set phase_ to next_phase_.`
			`Ongoing,`
			`/// Return a Channel::None and advancce to phase_ = Phase::Complete.`
			`PauseAndComplete,`
			`/// Return Channel::Write indefinitely.`
			`Complete`
			`};`

			`// Current sequencer pahse.`
			`Phase phase_ = Phase::Complete;`
			`// Phase to assume at the end of this iteration of the sequence table.`
			`Phase next_phase_ = Phase::Complete;`
Introduce putative blitter sequencer. 2022-07-26 21:05:05 +00:00			`};`

Implement bitplane modulos. 2021-10-29 18:29:22 +00:00			`class Blitter: public DMADevice<4, 4> {`
Sketches out a blitter class. 2021-07-22 22:43:07 +00:00			`public:`
Factors out DMADevice, which is now a parent of Blitter. 2021-09-15 00:51:32 +00:00			`using DMADevice::DMADevice;`
Sketches out a blitter class. 2021-07-22 22:43:07 +00:00
			`// Various setters; it's assumed that address decoding is handled externally.`
			`//`
			`// In all cases where a channel is identified numerically, it's taken that`
			`// 0 = A, 1 = B, 2 = C, 3 = D.`
			`void set_control(int index, uint16_t value);`
			`void set_first_word_mask(uint16_t value);`
			`void set_last_word_mask(uint16_t value);`
Logs a bit more from the Blitter, gives it access to slots. 2021-08-10 11:17:01 +00:00
Sketches out a blitter class. 2021-07-22 22:43:07 +00:00			`void set_size(uint16_t value);`
			`void set_minterms(uint16_t value);`
Fix exclusive fill, sizing, eliminate ECS call-ins. The clock test now proceeds further, but still doesn't seem to pass. 2021-11-24 22:25:32 +00:00			`// void set_vertical_size(uint16_t value);`
			`// void set_horizontal_size(uint16_t value);`
Sketches out a blitter class. 2021-07-22 22:43:07 +00:00			`void set_data(int channel, uint16_t value);`

			`uint16_t get_status();`

Switches to a synchronous audio state machine; renames advance -> advance_dma. I can worry about how to just-in-time things once I better understand the hardware in general. 2021-11-13 20:53:41 +00:00			`bool advance_dma();`
Sketches out a blitter class. 2021-07-22 22:43:07 +00:00
			`private:`
Logs a bit more from the Blitter, gives it access to slots. 2021-08-10 11:17:01 +00:00			`int width_ = 0, height_ = 0;`
Allow for channel enables and blitting direction. 2021-09-23 22:38:37 +00:00			`int shifts_[2]{};`
Edges mildly closer to line output. 2021-09-26 23:18:12 +00:00			`uint16_t a_mask_[2] = {0xffff, 0xffff};`

Allow for channel enables and blitting direction. 2021-09-23 22:38:37 +00:00			`bool line_mode_ = false;`
Edges mildly closer to line output. 2021-09-26 23:18:12 +00:00			`bool one_dot_ = false;`
			`int line_direction_ = 0;`
			`int line_sign_ = 1;`

Allow for channel enables and blitting direction. 2021-09-23 22:38:37 +00:00			`uint32_t direction_ = 1;`
Grab further copy flags. 2021-09-29 02:11:58 +00:00			`bool inclusive_fill_ = false;`
			`bool exclusive_fill_ = false;`
			`bool fill_carry_ = false;`
Edges mildly closer to line output. 2021-09-26 23:18:12 +00:00
			`bool channel_enables_[4]{};`
Allow for channel enables and blitting direction. 2021-09-23 22:38:37 +00:00
			`uint8_t minterms_ = 0;`
Resolve resting values. 2021-09-24 02:05:59 +00:00			`uint32_t a32_ = 0, b32_ = 0;`
Apply A mask when loading into barrel shifter. 2021-10-27 03:02:28 +00:00			`uint16_t a_data_ = 0, b_data_ = 0, c_data_ = 0;`
Added some notes to self on line mode. 2021-09-21 03:08:26 +00:00
Takes a stab at BZERO. 2021-10-29 01:12:46 +00:00			`bool not_zero_flag_ = false;`
Sketches out a blitter class. 2021-07-22 22:43:07 +00:00			`};`

			`}`


			`#endif /* Blitter_hpp */`