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CLK/Storage/Disk/DiskController.cpp

157 lines
3.8 KiB
C++

//
// DiskController.cpp
// Clock Signal
//
// Created by Thomas Harte on 14/07/2016.
// Copyright © 2016 Thomas Harte. All rights reserved.
//
#include "DiskController.hpp"
using namespace Storage::Disk;
Controller::Controller(unsigned int clock_rate, unsigned int clock_rate_multiplier, unsigned int revolutions_per_minute) :
_clock_rate(clock_rate * clock_rate_multiplier),
_clock_rate_multiplier(clock_rate_multiplier),
TimedEventLoop(clock_rate * clock_rate_multiplier)
{
_rotational_multiplier.length = 60;
_rotational_multiplier.clock_rate = revolutions_per_minute;
_rotational_multiplier.simplify();
// seed this class with a PLL, any PLL, so that it's safe to assume non-nullptr later
Time one;
set_expected_bit_length(one);
}
void Controller::setup_track() // Time initial_offset
{
_track = _drive->get_track();
// _track = _disk->get_track_at_position(0, (unsigned int)_head_position);
// TODO: probably a better implementation of the empty track?
/* Time offset;
if(_track && _time_into_track.length > 0)
{
Time time_found = _track->seek_to(_time_into_track).simplify();
offset = (_time_into_track - time_found).simplify();
_time_into_track = time_found;
}
else
{
offset = _time_into_track;
_time_into_track.set_zero();
}*/
reset_timer();
get_next_event();
// reset_timer_to_offset(offset * _rotational_multiplier);
}
void Controller::run_for_cycles(int number_of_cycles)
{
if(_drive && _drive->has_disk() && _motor_is_on)
{
if(!_track) setup_track();
number_of_cycles *= _clock_rate_multiplier;
while(number_of_cycles)
{
int cycles_until_next_event = (int)get_cycles_until_next_event();
int cycles_to_run_for = std::min(cycles_until_next_event, number_of_cycles);
_cycles_since_index_hole += (unsigned int)cycles_to_run_for;
number_of_cycles -= cycles_to_run_for;
_pll->run_for_cycles(cycles_to_run_for);
TimedEventLoop::run_for_cycles(cycles_to_run_for);
}
}
}
#pragma mark - Track timed event loop
void Controller::get_next_event()
{
if(_track)
_current_event = _track->get_next_event();
else
{
_current_event.length.length = 1;
_current_event.length.clock_rate = 1;
_current_event.type = Track::Event::IndexHole;
}
// divide interval, which is in terms of a rotation of the disk, by rotation speed, and
// convert it into revolutions per second
set_next_event_time_interval(_current_event.length * _rotational_multiplier);
}
void Controller::process_next_event()
{
switch(_current_event.type)
{
case Track::Event::FluxTransition:
_pll->add_pulse();
_time_into_track += _current_event.length;
break;
case Track::Event::IndexHole:
_cycles_since_index_hole = 0;
_time_into_track.set_zero();
process_index_hole();
break;
}
get_next_event();
}
#pragma mark - PLL control and delegate
void Controller::set_expected_bit_length(Time bit_length)
{
_bit_length = bit_length;
// this conversion doesn't need to be exact because there's a lot of variation to be taken
// account of in rotation speed, air turbulence, etc, so a direct conversion will do
int clocks_per_bit = (int)((bit_length.length * _clock_rate) / bit_length.clock_rate);
_pll.reset(new DigitalPhaseLockedLoop(clocks_per_bit, clocks_per_bit / 5, 3));
_pll->set_delegate(this);
}
void Controller::digital_phase_locked_loop_output_bit(int value)
{
process_input_bit(value, _cycles_since_index_hole);
}
#pragma mark - Drive actions
bool Controller::get_is_track_zero()
{
if(!_drive) return false;
return _drive->get_is_track_zero();
}
void Controller::step(int direction)
{
if(_drive) _drive->step(direction);
invalidate_track();
}
void Controller::set_motor_on(bool motor_on)
{
_motor_is_on = motor_on;
}
bool Controller::get_motor_on()
{
return _motor_is_on;
}
void Controller::set_drive(std::shared_ptr<Drive> drive)
{
_drive = drive;
invalidate_track();
}
void Controller::invalidate_track()
{
_track = nullptr;
}