1
0
mirror of https://github.com/TomHarte/CLK.git synced 2024-11-30 04:50:08 +00:00
CLK/Components/1770/1770.cpp

461 lines
11 KiB
C++

//
// 1770.cpp
// Clock Signal
//
// Created by Thomas Harte on 17/09/2016.
// Copyright © 2016 Thomas Harte. All rights reserved.
//
#include "1770.hpp"
#include "../../Storage/Disk/Encodings/MFM.hpp"
using namespace WD;
WD1770::WD1770() :
Storage::Disk::Controller(8000000, 16, 300),
status_(0),
interesting_event_mask_(Event::Command),
resume_point_(0),
delay_time_(0),
index_hole_count_target_(-1),
is_awaiting_marker_value_(false),
is_reading_data_(false)
{
set_is_double_density(false);
posit_event(Event::Command);
}
void WD1770::set_is_double_density(bool is_double_density)
{
is_double_density_ = is_double_density;
Storage::Time bit_length;
bit_length.length = 1;
bit_length.clock_rate = is_double_density ? 500000 : 250000;
set_expected_bit_length(bit_length);
if(!is_double_density) is_awaiting_marker_value_ = false;
}
void WD1770::set_register(int address, uint8_t value)
{
switch(address&3)
{
case 0:
command_ = value;
posit_event(Event::Command);
// TODO: is this force interrupt?
break;
case 1: track_ = value; break;
case 2: sector_ = value; break;
case 3: data_ = value; break;
}
}
uint8_t WD1770::get_register(int address)
{
switch(address&3)
{
default: return status_;
case 1: return track_;
case 2: return sector_;
case 3: status_ &= ~Flag::DataRequest; return data_;
}
}
void WD1770::run_for_cycles(unsigned int number_of_cycles)
{
Storage::Disk::Controller::run_for_cycles((int)number_of_cycles);
if(delay_time_)
{
if(delay_time_ <= number_of_cycles)
{
delay_time_ = 0;
posit_event(Event::Timer);
}
else
{
delay_time_ -= number_of_cycles;
}
}
}
void WD1770::process_input_bit(int value, unsigned int cycles_since_index_hole)
{
shift_register_ = (shift_register_ << 1) | value;
bits_since_token_++;
Token::Type token_type = Token::Byte;
if(!is_reading_data_)
{
if(!is_double_density_)
{
switch(shift_register_ & 0xffff)
{
case Storage::Encodings::MFM::FMIndexAddressMark:
token_type = Token::Index;
break;
case Storage::Encodings::MFM::FMIDAddressMark:
token_type = Token::ID;
break;
case Storage::Encodings::MFM::FMDataAddressMark:
token_type = Token::Data;
break;
case Storage::Encodings::MFM::FMDeletedDataAddressMark:
token_type = Token::DeletedData;
break;
default:
break;
}
}
else
{
switch(shift_register_ & 0xffff)
{
case Storage::Encodings::MFM::MFMIndexAddressMark:
bits_since_token_ = 0;
is_awaiting_marker_value_ = true;
return;
case Storage::Encodings::MFM::MFMAddressMark:
bits_since_token_ = 0;
is_awaiting_marker_value_ = true;
return;
default:
break;
}
}
if(token_type != Token::Byte)
{
latest_token_.type = token_type;
bits_since_token_ = 0;
posit_event(Event::Token);
return;
}
}
if(bits_since_token_ == 16)
{
latest_token_.type = Token::Byte;
latest_token_.byte_value = (uint8_t)(
((shift_register_ & 0x0001) >> 0) |
((shift_register_ & 0x0004) >> 1) |
((shift_register_ & 0x0010) >> 2) |
((shift_register_ & 0x0040) >> 3) |
((shift_register_ & 0x0100) >> 4) |
((shift_register_ & 0x0400) >> 5) |
((shift_register_ & 0x1000) >> 6) |
((shift_register_ & 0x4000) >> 7));
bits_since_token_ = 0;
if(is_awaiting_marker_value_ && is_double_density_)
{
is_awaiting_marker_value_ = false;
switch(latest_token_.byte_value)
{
case Storage::Encodings::MFM::MFMIndexAddressByte:
latest_token_.type = Token::Index;
break;
case Storage::Encodings::MFM::MFMIDAddressByte:
latest_token_.type = Token::ID;
break;
case Storage::Encodings::MFM::MFMDataAddressByte:
latest_token_.type = Token::Data;
break;
case Storage::Encodings::MFM::MFMDeletedDataAddressByte:
latest_token_.type = Token::DeletedData;
break;
default: break;
}
}
posit_event(Event::Token);
return;
}
}
void WD1770::process_index_hole()
{
index_hole_count_++;
posit_event(Event::IndexHole);
if(index_hole_count_target_ == index_hole_count_)
{
posit_event(Event::IndexHoleTarget);
index_hole_count_target_ = -1;
}
// motor power-down
if(index_hole_count_ == 9 && !(status_&Flag::Busy))
{
status_ &= ~Flag::MotorOn;
set_motor_on(false);
}
}
// +------+----------+-------------------------+
// ! ! ! BITS !
// ! TYPE ! COMMAND ! 7 6 5 4 3 2 1 0 !
// +------+----------+-------------------------+
// ! 1 ! Restore ! 0 0 0 0 h v r1 r0 !
// ! 1 ! Seek ! 0 0 0 1 h v r1 r0 !
// ! 1 ! Step ! 0 0 1 u h v r1 r0 !
// ! 1 ! Step-in ! 0 1 0 u h v r1 r0 !
// ! 1 ! Step-out ! 0 1 1 u h v r1 r0 !
// ! 2 ! Rd sectr ! 1 0 0 m h E 0 0 !
// ! 2 ! Wt sectr ! 1 0 1 m h E P a0 !
// ! 3 ! Rd addr ! 1 1 0 0 h E 0 0 !
// ! 3 ! Rd track ! 1 1 1 0 h E 0 0 !
// ! 3 ! Wt track ! 1 1 1 1 h E P 0 !
// ! 4 ! Forc int ! 1 1 0 1 i3 i2 i1 i0 !
// +------+----------+-------------------------+
#define WAIT_FOR_EVENT(mask) resume_point_ = __LINE__; interesting_event_mask_ = mask; return; case __LINE__:
#define WAIT_FOR_TIME(ms) resume_point_ = __LINE__; interesting_event_mask_ = Event::Timer; delay_time_ = ms * 8000; if(delay_time_) return; case __LINE__:
#define BEGIN_SECTION() switch(resume_point_) { default:
#define END_SECTION() 0; }
#define READ_ID() \
if(new_event_type == Event::Token) \
{ \
if(!distance_into_section_ && latest_token_.type == Token::ID) {is_reading_data_ = true; distance_into_section_++; } \
else if(distance_into_section_ && distance_into_section_ < 7 && latest_token_.type == Token::Byte) \
{ \
header[distance_into_section_ - 1] = latest_token_.byte_value; \
distance_into_section_++; \
} \
}
#define CONCATENATE(x, y) x ## y
#define INDIRECT_CONCATENATE(x, y) TOKENPASTE(x, y)
#define LINE_LABEL INDIRECT_CONCATENATE(label, __LINE__)
#define SPIN_UP() \
status_ |= Flag::MotorOn; \
set_motor_on(true); \
index_hole_count_ = 0; \
index_hole_count_target_ = 6; \
WAIT_FOR_EVENT(Event::IndexHoleTarget);
void WD1770::posit_event(Event new_event_type)
{
if(!(interesting_event_mask_ & (int)new_event_type)) return;
interesting_event_mask_ &= ~new_event_type;
BEGIN_SECTION()
// Wait for a new command, branch to the appropriate handler.
wait_for_command:
printf("Idle...\n");
is_reading_data_ = false;
status_ &= ~Flag::Busy;
index_hole_count_ = 0;
WAIT_FOR_EVENT(Event::Command);
printf("Starting %02x\n", command_);
status_ |= Flag::Busy;
if(!(command_ & 0x80)) goto begin_type_1;
if(!(command_ & 0x40)) goto begin_type_2;
goto begin_type_3;
/*
Type 1 entry point.
*/
begin_type_1:
// Set initial flags, skip spin-up if possible.
status_ &= ~(Flag::DataRequest | Flag::DataRequest | Flag::SeekError);
set_interrupt_request(false);
if((command_&0x08) || (status_ & Flag::MotorOn)) goto test_type1_type;
// Perform spin up.
SPIN_UP();
status_ |= Flag::SpinUp;
test_type1_type:
// Set step direction if this is a step in or out.
if((command_ >> 5) == 2) step_direction_ = 1;
if((command_ >> 5) == 3) step_direction_ = 0;
if((command_ >> 5) != 0) goto perform_step_command;
// This is now definitely either a seek or a restore; if it's a restore then set track to 0xff and data to 0x00.
if(!(command_ & 0x10))
{
track_ = 0xff;
data_ = 0;
}
perform_seek_or_restore_command:
if(track_ == data_) goto verify;
step_direction_ = (data_ > track_);
adjust_track:
if(step_direction_) track_++; else track_--;
perform_step:
if(!step_direction_ && get_is_track_zero())
{
track_ = 0;
goto verify;
}
step(step_direction_ ? 1 : -1);
int time_to_wait;
switch(command_ & 3)
{
default:
case 0: time_to_wait = 6; break; // 2 on a 1772
case 1: time_to_wait = 12; break; // 3 on a 1772
case 2: time_to_wait = 20; break; // 5 on a 1772
case 3: time_to_wait = 30; break; // 6 on a 1772
}
WAIT_FOR_TIME(time_to_wait);
if(command_ >> 5) goto verify;
goto perform_seek_or_restore_command;
perform_step_command:
if(command_ & 0x10) goto adjust_track;
goto perform_step;
verify:
if(!(command_ & 0x04))
{
set_interrupt_request(true);
goto wait_for_command;
}
index_hole_count_ = 0;
distance_into_section_ = 0;
verify_read_data:
WAIT_FOR_EVENT(Event::IndexHole | Event::Token);
READ_ID();
if(index_hole_count_ == 6)
{
set_interrupt_request(true);
status_ |= Flag::SeekError;
goto wait_for_command;
}
if(distance_into_section_ == 7)
{
is_reading_data_ = false;
// TODO: CRC check
if(header[0] == track_)
{
printf("Reached track %d\n", track_);
status_ &= ~Flag::CRCError;
set_interrupt_request(true);
goto wait_for_command;
}
distance_into_section_ = 0;
}
goto verify_read_data;
/*
Type 2 entry point.
*/
begin_type_2:
status_ &= ~(Flag::DataRequest | Flag::LostData | Flag::RecordNotFound | Flag::WriteProtect | Flag::RecordType);
set_interrupt_request(false);
distance_into_section_ = 0;
if((command_&0x08) || (status_ & Flag::MotorOn)) goto test_type2_delay;
// Perform spin up.
SPIN_UP();
test_type2_delay:
index_hole_count_ = 0;
if(!(command_ & 0x04)) goto test_type2_write_protection;
WAIT_FOR_TIME(30);
test_type2_write_protection:
if(command_&0x20) // TODO:: && is_write_protected
{
set_interrupt_request(true);
status_ |= Flag::WriteProtect;
goto wait_for_command;
}
type2_get_header:
WAIT_FOR_EVENT(Event::IndexHole | Event::Token);
READ_ID();
if(index_hole_count_ == 5)
{
set_interrupt_request(true);
status_ |= Flag::RecordNotFound;
goto wait_for_command;
}
if(distance_into_section_ == 7)
{
is_reading_data_ = false;
if(header[0] == track_ && header[2] == sector_)
{
// TODO: test CRC
goto type2_read_or_write_data;
}
distance_into_section_ = 0;
}
goto type2_get_header;
type2_read_or_write_data:
if(command_&0x20) goto type2_write_data;
goto type2_read_data;
type2_read_data:
WAIT_FOR_EVENT(Event::Token);
// TODO: timeout
if(latest_token_.type == Token::Data || latest_token_.type == Token::DeletedData)
{
status_ |= (latest_token_.type == Token::DeletedData) ? Flag::RecordType : 0;
distance_into_section_ = 0;
is_reading_data_ = true;
goto type2_read_byte;
}
goto type2_read_data;
type2_read_byte:
WAIT_FOR_EVENT(Event::Token);
if(latest_token_.type != Token::Byte) goto type2_read_byte;
if(status_ & Flag::DataRequest) status_ |= Flag::LostData;
data_ = latest_token_.byte_value;
status_ |= Flag::DataRequest;
distance_into_section_++;
if(distance_into_section_ == 128 << header[3])
{
distance_into_section_ = 0;
goto type2_check_crc;
}
goto type2_read_byte;
type2_check_crc:
WAIT_FOR_EVENT(Event::Token);
if(latest_token_.type != Token::Byte) goto type2_read_byte;
header[distance_into_section_] = latest_token_.byte_value;
distance_into_section_++;
if(distance_into_section_ == 2)
{
// TODO: check CRC
if(command_ & 0x10)
{
sector_++;
goto test_type2_write_protection;
}
set_interrupt_request(true);
printf("Read sector %d\n", sector_);
goto wait_for_command;
}
goto type2_check_crc;
type2_write_data:
printf("!!!TODO: data portion of sector!!!\n");
begin_type_3:
printf("!!!TODO: type 3 commands!!!\n");
END_SECTION()
}