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466 lines
14 KiB
C++
466 lines
14 KiB
C++
//
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// Drive.cpp
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// Clock Signal
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//
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// Created by Thomas Harte on 25/09/2016.
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// Copyright 2016 Thomas Harte. All rights reserved.
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//
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#include "Drive.hpp"
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#include "Track/UnformattedTrack.hpp"
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#include <algorithm>
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#include <cassert>
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#include <cmath>
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#include <chrono>
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#include <random>
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using namespace Storage::Disk;
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Drive::Drive(int input_clock_rate, int revolutions_per_minute, int number_of_heads, ReadyType rdy_type):
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Storage::TimedEventLoop(input_clock_rate),
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available_heads_(number_of_heads),
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ready_type_(rdy_type) {
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set_rotation_speed(revolutions_per_minute);
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const auto seed = static_cast<std::default_random_engine::result_type>(std::chrono::system_clock::now().time_since_epoch().count());
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std::default_random_engine randomiser(seed);
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// Get at least 64 bits of random information; rounding is likey to give this a slight bias.
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random_source_ = 0;
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auto half_range = (randomiser.max() - randomiser.min()) / 2;
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for(int bit = 0; bit < 64; ++bit) {
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random_source_ <<= 1;
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random_source_ |= ((randomiser() - randomiser.min()) >= half_range) ? 1 : 0;
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}
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}
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Drive::Drive(int input_clock_rate, int number_of_heads, ReadyType rdy_type) : Drive(input_clock_rate, 300, number_of_heads, rdy_type) {}
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void Drive::set_rotation_speed(float revolutions_per_minute) {
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// Rationalise the supplied speed so that cycles_per_revolution_ is exact.
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cycles_per_revolution_ = int(0.5f + float(get_input_clock_rate()) * 60.0f / revolutions_per_minute);
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// From there derive the appropriate rotational multiplier and possibly update the
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// count of cycles since the index hole proportionally.
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const float new_rotational_multiplier = float(cycles_per_revolution_) / float(get_input_clock_rate());
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cycles_since_index_hole_ = Cycles::IntType(float(cycles_since_index_hole_) * new_rotational_multiplier / rotational_multiplier_);
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rotational_multiplier_ = new_rotational_multiplier;
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cycles_since_index_hole_ %= cycles_per_revolution_;
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}
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Drive::~Drive() {
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if(disk_) disk_->flush_tracks();
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}
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void Drive::set_disk(const std::shared_ptr<Disk> &disk) {
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if(ready_type_ == ReadyType::ShugartModifiedRDY || ready_type_ == ReadyType::IBMRDY) {
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is_ready_ = false;
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}
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if(disk_) disk_->flush_tracks();
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disk_ = disk;
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has_disk_ = !!disk_;
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invalidate_track();
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did_set_disk();
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update_clocking_observer();
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}
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bool Drive::has_disk() const {
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return has_disk_;
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}
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ClockingHint::Preference Drive::preferred_clocking() {
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return (!has_disk_ || (time_until_motor_transition == Cycles(0) && !disk_is_rotating_)) ? ClockingHint::Preference::None : ClockingHint::Preference::JustInTime;
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}
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bool Drive::get_is_track_zero() const {
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return head_position_ == HeadPosition(0);
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}
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void Drive::step(HeadPosition offset) {
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if(ready_type_ == ReadyType::IBMRDY) {
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is_ready_ = true;
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}
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HeadPosition old_head_position = head_position_;
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head_position_ += offset;
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if(head_position_ < HeadPosition(0)) {
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head_position_ = HeadPosition(0);
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if(observer_) observer_->announce_drive_event(drive_name_, Activity::Observer::DriveEvent::StepBelowZero);
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} else {
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if(observer_) observer_->announce_drive_event(drive_name_, Activity::Observer::DriveEvent::StepNormal);
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}
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// If the head moved, flush the old track.
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if(head_position_ != old_head_position) {
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track_ = nullptr;
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}
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// Allow a subclass to react, if desired.
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did_step(head_position_);
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}
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std::shared_ptr<Track> Drive::step_to(HeadPosition offset) {
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HeadPosition old_head_position = head_position_;
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head_position_ = std::max(offset, HeadPosition(0));
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if(disk_ && head_position_ != old_head_position) {
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track_ = nullptr;
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setup_track();
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}
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return track_;
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}
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void Drive::set_head(int head) {
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head = std::min(head, available_heads_ - 1);
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if(head != head_) {
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head_ = head;
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track_ = nullptr;
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}
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}
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int Drive::get_head_count() const {
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return available_heads_;
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}
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bool Drive::get_tachometer() const {
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// I have made a guess here that the tachometer is a symmetric square wave;
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// if that is correct then around 60 beats per rotation appears to be correct
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// to proceed beyond the speed checks I've so far uncovered.
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constexpr float ticks_per_rotation = 60.0f; // 56 was too low; 64 too high.
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return int(get_rotation() * 2.0f * ticks_per_rotation) & 1;
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}
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float Drive::get_rotation() const {
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return get_time_into_track();
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}
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float Drive::get_time_into_track() const {
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// i.e. amount of time since the index hole was seen, as a proportion of a second,
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// converted to a proportion of a rotation.
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return float(cycles_since_index_hole_) / (float(get_input_clock_rate()) * rotational_multiplier_);
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}
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bool Drive::get_is_read_only() const {
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if(disk_) return disk_->get_is_read_only();
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return true;
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}
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bool Drive::get_is_ready() const {
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return is_ready_;
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}
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void Drive::set_motor_on(bool motor_is_on) {
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// Do nothing if the input hasn't changed.
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if(motor_input_is_on_ == motor_is_on) return;
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motor_input_is_on_ = motor_is_on;
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// If this now means that the input and the actual state are in harmony,
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// cancel any planned change and stop.
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if(disk_is_rotating_ == motor_is_on) {
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time_until_motor_transition = Cycles(0);
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return;
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}
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// If this is a transition to on, start immediately.
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// TODO: spin-up?
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// TODO: momentum.
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if(motor_is_on) {
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set_disk_is_rotating(true);
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time_until_motor_transition = Cycles(0);
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return;
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}
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// This is a transition from on to off. Simulate momentum (ha!)
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// by delaying the time until complete standstill.
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if(time_until_motor_transition == Cycles(0))
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time_until_motor_transition = get_input_clock_rate();
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}
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bool Drive::get_motor_on() const {
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return motor_input_is_on_;
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}
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bool Drive::get_index_pulse() const {
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return index_pulse_remaining_ > Cycles(0);
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}
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void Drive::set_event_delegate(Storage::Disk::Drive::EventDelegate *delegate) {
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event_delegate_ = delegate;
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}
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void Drive::advance(const Cycles cycles) {
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cycles_since_index_hole_ += cycles.as_integral();
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if(event_delegate_) event_delegate_->advance(cycles);
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}
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void Drive::run_for(const Cycles cycles) {
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// Assumed: the index pulse pulses even if the drive has stopped spinning.
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index_pulse_remaining_ = std::max(index_pulse_remaining_ - cycles, Cycles(0));
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if(time_until_motor_transition > Cycles(0)) {
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if(time_until_motor_transition > cycles) {
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time_until_motor_transition -= cycles;
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} else {
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time_until_motor_transition = Cycles(0);
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set_disk_is_rotating(!disk_is_rotating_);
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}
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}
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if(disk_is_rotating_) {
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if(has_disk_) {
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Time zero(0);
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auto number_of_cycles = cycles.as_integral();
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while(number_of_cycles) {
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auto cycles_until_next_event = get_cycles_until_next_event();
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auto cycles_to_run_for = std::min(cycles_until_next_event, number_of_cycles);
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if(!is_reading_ && cycles_until_bits_written_ > zero) {
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auto write_cycles_target = cycles_until_bits_written_.get<Cycles::IntType>();
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if(cycles_until_bits_written_.length % cycles_until_bits_written_.clock_rate) ++write_cycles_target;
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cycles_to_run_for = std::min(cycles_to_run_for, write_cycles_target);
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}
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number_of_cycles -= cycles_to_run_for;
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if(!is_reading_) {
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if(cycles_until_bits_written_ > zero) {
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Storage::Time cycles_to_run_for_time(static_cast<int>(cycles_to_run_for));
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if(cycles_until_bits_written_ <= cycles_to_run_for_time) {
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if(event_delegate_) event_delegate_->process_write_completed();
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if(cycles_until_bits_written_ <= cycles_to_run_for_time)
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cycles_until_bits_written_.set_zero();
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else
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cycles_until_bits_written_ -= cycles_to_run_for_time;
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} else {
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cycles_until_bits_written_ -= cycles_to_run_for_time;
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}
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}
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}
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TimedEventLoop::run_for(Cycles(cycles_to_run_for));
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}
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} else {
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TimedEventLoop::run_for(cycles);
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}
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}
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}
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// MARK: - Track timed event loop
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void Drive::get_next_event(float duration_already_passed) {
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if(!disk_) {
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current_event_.type = Track::Event::IndexHole;
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current_event_.length = 1.0f;
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set_next_event_time_interval((current_event_.length - duration_already_passed) * rotational_multiplier_);
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return;
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}
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// Grab a new track if not already in possession of one. This will recursively call get_next_event,
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// supplying a proper duration_already_passed.
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if(!track_) {
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random_interval_ = 0.0f;
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setup_track();
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return;
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}
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// If gain has now been turned up so as to generate noise, generate some noise.
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if(random_interval_ > 0.0f) {
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current_event_.type = Track::Event::FluxTransition;
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current_event_.length = float(2 + (random_source_&1)) / 1000000.0f;
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random_source_ = (random_source_ >> 1) | (random_source_ << 63);
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if(random_interval_ < current_event_.length) {
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current_event_.length = random_interval_;
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random_interval_ = 0.0f;
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} else {
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random_interval_ -= current_event_.length;
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}
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set_next_event_time_interval(current_event_.length);
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return;
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}
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if(track_) {
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const auto track_event = track_->get_next_event();
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current_event_.type = track_event.type;
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current_event_.length = track_event.length.get<float>();
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} else {
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current_event_.length = 1.0f;
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current_event_.type = Track::Event::IndexHole;
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}
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// Begin a 2ms period of holding the index line pulse active if this is an index pulse event.
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if(current_event_.type == Track::Event::IndexHole) {
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index_pulse_remaining_ = Cycles((get_input_clock_rate() * 2) / 1000);
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}
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// divide interval, which is in terms of a single rotation of the disk, by rotation speed to
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// convert it into revolutions per second; this is achieved by multiplying by rotational_multiplier_
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float interval = std::max((current_event_.length - duration_already_passed) * rotational_multiplier_, 0.0f);
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// An interval greater than 15ms => adjust gain up the point where noise starts happening.
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// Seed that up and leave a 15ms gap until it starts.
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constexpr float safe_gain_period = 15.0f / 1000000.0f;
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if(interval >= safe_gain_period) {
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random_interval_ = interval - safe_gain_period;
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interval = safe_gain_period;
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}
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set_next_event_time_interval(interval);
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}
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void Drive::process_next_event() {
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if(current_event_.type == Track::Event::IndexHole) {
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++ready_index_count_;
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if(ready_index_count_ == 2 && (ready_type_ == ReadyType::ShugartRDY || ready_type_ == ReadyType::ShugartModifiedRDY)) {
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is_ready_ = true;
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}
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cycles_since_index_hole_ = 0;
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}
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if(
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event_delegate_ &&
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(current_event_.type == Track::Event::IndexHole || is_reading_)
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){
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event_delegate_->process_event(current_event_);
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}
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get_next_event(0.0f);
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}
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// MARK: - Track management
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std::shared_ptr<Track> Drive::get_track() {
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if(disk_) return disk_->get_track_at_position(Track::Address(head_, head_position_));
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return nullptr;
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}
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void Drive::set_track(const std::shared_ptr<Track> &track) {
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if(disk_) disk_->set_track_at_position(Track::Address(head_, head_position_), track);
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}
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void Drive::setup_track() {
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track_ = get_track();
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if(!track_) {
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track_ = std::make_shared<UnformattedTrack>();
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}
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float offset = 0.0f;
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const auto track_time_now = get_time_into_track();
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const auto time_found = track_->seek_to(Time(track_time_now)).get<float>();
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// `time_found` can be greater than `track_time_now` if limited precision caused rounding.
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if(time_found <= track_time_now) {
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offset = track_time_now - time_found;
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}
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// Reseed cycles_since_index_hole_; 99.99% of the time it'll still be correct as is,
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// but if the track has rounded one way or the other it may now be very slightly adrift.
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cycles_since_index_hole_ = (int((time_found + offset) * cycles_per_revolution_)) % cycles_per_revolution_;
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get_next_event(offset);
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}
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void Drive::invalidate_track() {
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random_interval_ = 0.0f;
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track_ = nullptr;
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if(patched_track_) {
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set_track(patched_track_);
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patched_track_ = nullptr;
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}
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}
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// MARK: - Writing
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void Drive::begin_writing(Time bit_length, bool clamp_to_index_hole) {
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// Do nothing if already writing.
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// TODO: cope properly if there's no disk to write to.
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if(!is_reading_ || !disk_) return;
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// Get a copy of the track if that hasn't happened yet.
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if(!track_) {
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setup_track();
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}
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// Store the relevant parameters, and kick off writing.
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is_reading_ = false;
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clamp_writing_to_index_hole_ = clamp_to_index_hole;
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cycles_per_bit_ = Storage::Time(int(get_input_clock_rate())) * bit_length;
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cycles_per_bit_.simplify();
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write_segment_.length_of_a_bit = bit_length / Time(rotational_multiplier_);
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write_segment_.data.clear();
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write_start_time_ = Time(get_time_into_track());
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}
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void Drive::write_bit(bool value) {
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write_segment_.data.push_back(value);
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cycles_until_bits_written_ += cycles_per_bit_;
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}
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void Drive::end_writing() {
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// If the user modifies a track, it's scaled up to a "high" resolution and modifications
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// are plotted on top of that.
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//
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// "High" is defined as: two samples per clock relative to an idiomatic
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// 8Mhz disk controller and 300RPM disk speed.
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const size_t high_resolution_track_rate = 3200000;
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if(!is_reading_) {
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is_reading_ = true;
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if(!patched_track_) {
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// Avoid creating a new patched track if this one is already patched
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patched_track_ = std::dynamic_pointer_cast<PCMTrack>(track_);
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if(!patched_track_ || !patched_track_->is_resampled_clone()) {
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Track *const tr = track_.get();
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patched_track_.reset(PCMTrack::resampled_clone(tr, high_resolution_track_rate));
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}
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}
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patched_track_->add_segment(write_start_time_, write_segment_, clamp_writing_to_index_hole_);
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cycles_since_index_hole_ %= cycles_per_revolution_;
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invalidate_track();
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}
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}
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bool Drive::is_writing() const {
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return !is_reading_;
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}
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void Drive::set_disk_is_rotating(bool is_rotating) {
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disk_is_rotating_ = is_rotating;
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if(observer_) {
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observer_->set_drive_motor_status(drive_name_, disk_is_rotating_);
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if(announce_motor_led_) {
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observer_->set_led_status(drive_name_, disk_is_rotating_);
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}
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}
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if(!is_rotating) {
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if(ready_type_ == ReadyType::ShugartRDY) {
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is_ready_ = false;
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}
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ready_index_count_ = 0;
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if(disk_) disk_->flush_tracks();
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}
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update_clocking_observer();
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}
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void Drive::set_activity_observer(Activity::Observer *observer, const std::string &name, bool add_motor_led) {
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observer_ = observer;
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announce_motor_led_ = add_motor_led;
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if(observer) {
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drive_name_ = name;
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observer->register_drive(drive_name_);
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observer->set_drive_motor_status(drive_name_, disk_is_rotating_);
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if(add_motor_led) {
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observer->register_led(drive_name_);
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observer->set_led_status(drive_name_, disk_is_rotating_);
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}
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}
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}
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