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229 lines
7.0 KiB
C++
229 lines
7.0 KiB
C++
//
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// 6850.cpp
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// Clock Signal
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//
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// Created by Thomas Harte on 10/10/2019.
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// Copyright © 2019 Thomas Harte. All rights reserved.
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//
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#include "6850.hpp"
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#include <cassert>
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using namespace Motorola::ACIA;
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const HalfCycles ACIA::SameAsTransmit;
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ACIA::ACIA(HalfCycles transmit_clock_rate, HalfCycles receive_clock_rate) :
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transmit_clock_rate_(transmit_clock_rate),
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receive_clock_rate_((receive_clock_rate != SameAsTransmit) ? receive_clock_rate : transmit_clock_rate) {
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transmit.set_writer_clock_rate(transmit_clock_rate);
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request_to_send.set_writer_clock_rate(transmit_clock_rate);
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}
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uint8_t ACIA::read(int address) {
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if(address&1) {
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overran_ = false;
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received_data_ |= NoValueMask;
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update_interrupt_line();
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return uint8_t(received_data_);
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} else {
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return get_status();
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}
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}
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void ACIA::reset() {
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transmit.reset_writing();
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transmit.write(true);
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request_to_send.reset_writing();
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bits_received_ = bits_incoming_ = 0;
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receive_interrupt_enabled_ = transmit_interrupt_enabled_ = false;
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overran_ = false;
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next_transmission_ = received_data_ = NoValueMask;
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update_interrupt_line();
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assert(!interrupt_line_);
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}
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void ACIA::write(int address, uint8_t value) {
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if(address&1) {
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next_transmission_ = value;
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consider_transmission();
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update_interrupt_line();
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} else {
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if((value&3) == 3) {
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reset();
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} else {
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switch(value & 3) {
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default:
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case 0: divider_ = 1; break;
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case 1: divider_ = 16; break;
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case 2: divider_ = 64; break;
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}
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switch((value >> 2) & 7) {
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default:
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case 0: data_bits_ = 7; stop_bits_ = 2; parity_ = Parity::Even; break;
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case 1: data_bits_ = 7; stop_bits_ = 2; parity_ = Parity::Odd; break;
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case 2: data_bits_ = 7; stop_bits_ = 1; parity_ = Parity::Even; break;
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case 3: data_bits_ = 7; stop_bits_ = 1; parity_ = Parity::Odd; break;
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case 4: data_bits_ = 8; stop_bits_ = 2; parity_ = Parity::None; break;
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case 5: data_bits_ = 8; stop_bits_ = 1; parity_ = Parity::None; break;
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case 6: data_bits_ = 8; stop_bits_ = 1; parity_ = Parity::Even; break;
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case 7: data_bits_ = 8; stop_bits_ = 1; parity_ = Parity::Odd; break;
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}
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switch((value >> 5) & 3) {
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case 0: request_to_send.write(false); transmit_interrupt_enabled_ = false; break;
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case 1: request_to_send.write(false); transmit_interrupt_enabled_ = true; break;
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case 2: request_to_send.write(true); transmit_interrupt_enabled_ = false; break;
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case 3:
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request_to_send.write(false);
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transmit_interrupt_enabled_ = false;
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transmit.reset_writing();
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transmit.write(false);
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break;
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}
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receive.set_read_delegate(this, Storage::Time(divider_ * 2, int(receive_clock_rate_.as_integral())));
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receive_interrupt_enabled_ = value & 0x80;
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update_interrupt_line();
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}
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}
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update_clocking_observer();
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}
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void ACIA::consider_transmission() {
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if(next_transmission_ != NoValueMask && !transmit.write_data_time_remaining()) {
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// Establish start bit and [7 or 8] data bits.
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if(data_bits_ == 7) next_transmission_ &= 0x7f;
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int transmission = next_transmission_ << 1;
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// Add a parity bit, if any.
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int mask = 0x2 << data_bits_;
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if(parity_ != Parity::None) {
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transmission |= parity(uint8_t(next_transmission_)) ? mask : 0;
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mask <<= 1;
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}
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// Add stop bits.
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for(int c = 0; c < stop_bits_; ++c) {
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transmission |= mask;
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mask <<= 1;
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}
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// Output all that.
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const int total_bits = expected_bits();
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transmit.write(divider_ * 2, total_bits, transmission);
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// Mark the transmit register as empty again.
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next_transmission_ = NoValueMask;
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}
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}
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ClockingHint::Preference ACIA::preferred_clocking() const {
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// Real-time clocking is required if a transmission is ongoing; this is a courtesy for whomever
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// is on the receiving end.
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if(transmit.transmission_data_time_remaining() > 0) return ClockingHint::Preference::RealTime;
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// If a bit reception is ongoing that might lead to an interrupt, ask for real-time clocking
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// because it's unclear when the interrupt might come.
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if(bits_incoming_ && receive_interrupt_enabled_) return ClockingHint::Preference::RealTime;
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// Real-time clocking not required then.
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return ClockingHint::Preference::JustInTime;
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}
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bool ACIA::get_interrupt_line() const {
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return interrupt_line_;
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}
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int ACIA::expected_bits() {
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return 1 + data_bits_ + stop_bits_ + (parity_ != Parity::None);
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}
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uint8_t ACIA::parity(uint8_t value) {
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value ^= value >> 4;
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value ^= value >> 2;
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value ^= value >> 1;
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return value ^ (parity_ == Parity::Even);
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}
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bool ACIA::serial_line_did_produce_bit(Serial::Line<false> *, int bit) {
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// Shift this bit into the 11-bit input register; this is big enough to hold
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// the largest transmission symbol.
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++bits_received_;
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bits_incoming_ = (bits_incoming_ >> 1) | (bit << 10);
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// If that's the now-expected number of bits, update.
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const int bit_target = expected_bits();
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if(bits_received_ >= bit_target) {
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bits_received_ = 0;
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overran_ |= get_status() & 1;
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received_data_ = uint8_t(bits_incoming_ >> (12 - bit_target));
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update_interrupt_line();
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update_clocking_observer();
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return false;
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}
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// TODO: overrun, and parity.
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// Keep receiving, and consider a potential clocking change.
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if(bits_received_ == 1) update_clocking_observer();
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return true;
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}
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void ACIA::set_interrupt_delegate(InterruptDelegate *delegate) {
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interrupt_delegate_ = delegate;
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}
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void ACIA::update_interrupt_line() {
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const bool old_line = interrupt_line_;
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/*
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"Bit 7 of the control register is the rie bit. When the rie bit is high, the rdrf, ndcd,
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and ovr bits will assert the nirq output. When the rie bit is low, nirq generation is disabled."
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rie = read interrupt enable
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rdrf = receive data register full (status word bit 0)
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ndcd = data carrier detect (status word bit 2)
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over = receiver overrun (status word bit 5)
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"Bit 1 of the status register is the tdre bit. When high, the tdre bit indicates that data has been
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transferred from the transmitter data register to the output shift register. At this point, the a6850
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is ready to accept a new transmit data byte. However, if the ncts signal is high, the tdre bit remains
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low regardless of the status of the transmitter data register. Also, if transmit interrupt is enabled,
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the nirq output is asserted."
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tdre = transmitter data register empty
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ncts = clear to send
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*/
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const auto status = get_status();
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interrupt_line_ =
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(receive_interrupt_enabled_ && (status & 0x25)) ||
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(transmit_interrupt_enabled_ && (status & 0x02));
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if(interrupt_delegate_ && old_line != interrupt_line_) {
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interrupt_delegate_->acia6850_did_change_interrupt_status(this);
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}
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}
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uint8_t ACIA::get_status() {
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return
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((received_data_ & NoValueMask) ? 0x00 : 0x01) |
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((next_transmission_ == NoValueMask) ? 0x02 : 0x00) |
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// (data_carrier_detect.read() ? 0x04 : 0x00) |
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// (clear_to_send.read() ? 0x08 : 0x00) |
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(overran_ ? 0x20 : 0x00) |
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(interrupt_line_ ? 0x80 : 0x00)
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;
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// b0: receive data full.
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// b1: transmit data empty.
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// b2: DCD.
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// b3: CTS.
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// b4: framing error (i.e. no first stop bit where expected).
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// b5: receiver overran.
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// b6: parity error.
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// b7: IRQ state.
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}
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