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c5864a46d87f1e6959e47bc82f103ec39d03ded2
86Box/src/device/serial.c
Lubomir Rintel d152e92648 Don't raise the UART interrupts if no IRQ is configured 
The 82C606 SuperIO allows reconfiguring the interrupt line used for the
UART alarm at runtime, including disabling it altogether.

While at that, correct the type in the serial_setup() prototype to be
the same as serial_t.irq uses.
2021-09-07 21:34:18 +02:00

772 lines
18 KiB
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/*
* 86Box A hypervisor and IBM PC system emulator that specializes in
* running old operating systems and software designed for IBM
* PC systems and compatibles from 1981 through fairly recent
* system designs based on the PCI bus.
*
* This file is part of the 86Box distribution.
*
* NS8250/16450/16550 UART emulation.
*
* Now passes all the AMIDIAG tests.
*
*
*
* Author: Sarah Walker, <http://pcem-emulator.co.uk/>
* Miran Grca, <mgrca8@gmail.com>
* Fred N. van Kempen, <decwiz@yahoo.com>
*
* Copyright 2008-2020 Sarah Walker.
* Copyright 2016-2020 Miran Grca.
* Copyright 2017-2020 Fred N. van Kempen.
*/
#include <stdarg.h>
#include <stdio.h>
#include <stdint.h>
#include <stdlib.h>
#include <string.h>
#include <wchar.h>
#define HAVE_STDARG_H
#include <86box/86box.h>
#include <86box/device.h>
#include <86box/timer.h>
#include <86box/machine.h>
#include <86box/io.h>
#include <86box/pic.h>
#include <86box/mem.h>
#include <86box/rom.h>
#include <86box/serial.h>
#include <86box/mouse.h>
enum
{
SERIAL_INT_LSR = 1,
SERIAL_INT_RECEIVE = 2,
SERIAL_INT_TRANSMIT = 4,
SERIAL_INT_MSR = 8,
SERIAL_INT_TIMEOUT = 16
};
static int next_inst = 0;
static serial_device_t serial_devices[SERIAL_MAX];
#ifdef ENABLE_SERIAL_LOG
int serial_do_log = ENABLE_SERIAL_LOG;
static void
serial_log(const char *fmt, ...)
{
va_list ap;
if (serial_do_log) {
va_start(ap, fmt);
pclog_ex(fmt, ap);
va_end(ap);
}
}
#else
#define serial_log(fmt, ...)
#endif
void
serial_reset_port(serial_t *dev)
{
dev->lsr = 0x60; /* Mark that both THR/FIFO and TXSR are empty. */
dev->iir = dev->ier = dev->lcr = dev->fcr = 0;
dev->fifo_enabled = 0;
dev->xmit_fifo_pos = dev->rcvr_fifo_pos = 0;
dev->rcvr_fifo_full = 0;
dev->baud_cycles = 0;
memset(dev->xmit_fifo, 0, 16);
memset(dev->rcvr_fifo, 0, 14);
}
void
serial_transmit_period(serial_t *dev)
{
double ddlab;
ddlab = (double) dev->dlab;
/* Bit period based on DLAB. */
dev->transmit_period = (16000000.0 * ddlab) / dev->clock_src;
}
void
serial_update_ints(serial_t *dev)
{
int stat = 0;
dev->iir = 1;
if ((dev->ier & 4) && (dev->int_status & SERIAL_INT_LSR)) {
/* Line status interrupt */
stat = 1;
dev->iir = 6;
} else if ((dev->ier & 1) && (dev->int_status & SERIAL_INT_TIMEOUT)) {
/* Received data available */
stat = 1;
dev->iir = 0x0c;
} else if ((dev->ier & 1) && (dev->int_status & SERIAL_INT_RECEIVE)) {
/* Received data available */
stat = 1;
dev->iir = 4;
} else if ((dev->ier & 2) && (dev->int_status & SERIAL_INT_TRANSMIT)) {
/* Transmit data empty */
stat = 1;
dev->iir = 2;
} else if ((dev->ier & 8) && (dev->int_status & SERIAL_INT_MSR)) {
/* Modem status interrupt */
stat = 1;
dev->iir = 0;
}
if (stat && (dev->irq != 0xff) && ((dev->mctrl & 8) || (dev->type == SERIAL_8250_PCJR))) {
if (dev->type >= SERIAL_NS16450)
picintlevel(1 << dev->irq);
else
picint(1 << dev->irq);
} else
picintc(1 << dev->irq);
}
static void
serial_clear_timeout(serial_t *dev)
{
/* Disable timeout timer and clear timeout condition. */
timer_disable(&dev->timeout_timer);
dev->int_status &= ~SERIAL_INT_TIMEOUT;
serial_update_ints(dev);
}
static void
write_fifo(serial_t *dev, uint8_t dat)
{
serial_log("write_fifo(%08X, %02X, %i, %i)\n", dev, dat, (dev->type >= SERIAL_NS16550) && dev->fifo_enabled, dev->rcvr_fifo_pos & 0x0f);
if ((dev->type >= SERIAL_NS16550) && dev->fifo_enabled) {
/* FIFO mode. */
timer_disable(&dev->timeout_timer);
/* Indicate overrun. */
if (dev->rcvr_fifo_full)
dev->lsr |= 0x02;
else
dev->rcvr_fifo[dev->rcvr_fifo_pos] = dat;
dev->lsr &= 0xfe;
dev->int_status &= ~SERIAL_INT_RECEIVE;
if (dev->rcvr_fifo_pos == (dev->rcvr_fifo_len - 1)) {
dev->lsr |= 0x01;
dev->int_status |= SERIAL_INT_RECEIVE;
}
if (dev->rcvr_fifo_pos < 15)
dev->rcvr_fifo_pos++;
else
dev->rcvr_fifo_full = 1;
serial_update_ints(dev);
timer_on_auto(&dev->timeout_timer, 4.0 * dev->bits * dev->transmit_period);
} else {
/* Non-FIFO mode. */
/* Indicate overrun. */
if (dev->lsr & 0x01)
dev->lsr |= 0x02;
dev->dat = dat;
dev->lsr |= 0x01;
dev->int_status |= SERIAL_INT_RECEIVE;
serial_update_ints(dev);
}
}
void
serial_write_fifo(serial_t *dev, uint8_t dat)
{
serial_log("serial_write_fifo(%08X, %02X, %i, %i)\n", dev, dat, (dev->type >= SERIAL_NS16550) && dev->fifo_enabled, dev->rcvr_fifo_pos & 0x0f);
if (!(dev->mctrl & 0x10))
write_fifo(dev, dat);
}
void
serial_transmit(serial_t *dev, uint8_t val)
{
if (dev->mctrl & 0x10)
write_fifo(dev, val);
else if (dev->sd->dev_write)
dev->sd->dev_write(dev, dev->sd->priv, val);
}
static void
serial_move_to_txsr(serial_t *dev)
{
int i = 0;
if (dev->fifo_enabled) {
dev->txsr = dev->xmit_fifo[0];
if (dev->xmit_fifo_pos > 0) {
/* Move the entire fifo forward by one byte. */
for (i = 1; i < 16; i++)
dev->xmit_fifo[i - 1] = dev->xmit_fifo[i];
/* Decrease FIFO position. */
dev->xmit_fifo_pos--;
}
} else {
dev->txsr = dev->thr;
dev->thr = 0;
}
dev->lsr &= ~0x40;
serial_log("serial_move_to_txsr(): FIFO %sabled, FIFO pos = %i\n", dev->fifo_enabled ? "en" : "dis", dev->xmit_fifo_pos & 0x0f);
if (!dev->fifo_enabled || (dev->xmit_fifo_pos == 0x0)) {
/* Update interrupts to signal THRE and that TXSR is no longer empty. */
dev->lsr |= 0x20;
dev->int_status |= SERIAL_INT_TRANSMIT;
serial_update_ints(dev);
}
if (dev->transmit_enabled & 2)
dev->baud_cycles++;
else
dev->baud_cycles = 0; /* If not moving while transmitting, reset BAUDOUT cycle count. */
if (!dev->fifo_enabled || (dev->xmit_fifo_pos == 0x0))
dev->transmit_enabled &= ~1; /* Stop moving. */
dev->transmit_enabled |= 2; /* Start transmitting. */
}
static void
serial_process_txsr(serial_t *dev)
{
serial_log("serial_process_txsr(): FIFO %sabled\n", dev->fifo_enabled ? "en" : "dis");
serial_transmit(dev, dev->txsr);
dev->txsr = 0;
/* Reset BAUDOUT cycle count. */
dev->baud_cycles = 0;
/* If FIFO is enabled and there are bytes left to transmit,
continue with the FIFO, otherwise stop. */
if (dev->fifo_enabled && (dev->xmit_fifo_pos != 0x0))
dev->transmit_enabled |= 1;
else {
/* Both FIFO/THR and TXSR are empty. */
/* If bit 5 is set, also set bit 6 to mark both THR and shift register as empty. */
if (dev->lsr & 0x20)
dev->lsr |= 0x40;
dev->transmit_enabled &= ~2;
}
dev->int_status &= ~SERIAL_INT_TRANSMIT;
serial_update_ints(dev);
}
/* Transmit_enable flags:
Bit 0 = Do move if set;
Bit 1 = Do transmit if set. */
static void
serial_transmit_timer(void *priv)
{
serial_t *dev = (serial_t *) priv;
int delay = 8; /* STOP to THRE delay is 8 BAUDOUT cycles. */
if (dev->transmit_enabled & 3) {
if ((dev->transmit_enabled & 1) && (dev->transmit_enabled & 2))
delay = dev->data_bits; /* Delay by less if already transmitting. */
dev->baud_cycles++;
/* We have processed (total bits) BAUDOUT cycles, transmit the byte. */
if ((dev->baud_cycles == dev->bits) && (dev->transmit_enabled & 2))
serial_process_txsr(dev);
/* We have processed (data bits) BAUDOUT cycles. */
if ((dev->baud_cycles == delay) && (dev->transmit_enabled & 1))
serial_move_to_txsr(dev);
if (dev->transmit_enabled & 3)
timer_on_auto(&dev->transmit_timer, dev->transmit_period);
} else {
dev->baud_cycles = 0;
return;
}
}
static void
serial_timeout_timer(void *priv)
{
serial_t *dev = (serial_t *) priv;
#ifdef ENABLE_SERIAL_LOG
serial_log("serial_timeout_timer()\n");
#endif
dev->lsr |= 0x01;
dev->int_status |= SERIAL_INT_TIMEOUT;
serial_update_ints(dev);
}
static void
serial_update_speed(serial_t *dev)
{
if (dev->transmit_enabled & 3)
timer_on_auto(&dev->transmit_timer, dev->transmit_period);
if (timer_is_enabled(&dev->timeout_timer))
timer_on_auto(&dev->timeout_timer, 4.0 * dev->bits * dev->transmit_period);
}
static void
serial_reset_fifo(serial_t *dev)
{
dev->lsr = (dev->lsr & 0xfe) | 0x60;
dev->int_status = (dev->int_status & ~SERIAL_INT_RECEIVE) | SERIAL_INT_TRANSMIT;
serial_update_ints(dev);
dev->xmit_fifo_pos = dev->rcvr_fifo_pos = 0;
dev->rcvr_fifo_full = 0;
}
void
serial_set_clock_src(serial_t *dev, double clock_src)
{
dev->clock_src = clock_src;
serial_transmit_period(dev);
serial_update_speed(dev);
}
void
serial_write(uint16_t addr, uint8_t val, void *p)
{
serial_t *dev = (serial_t *)p;
uint8_t new_msr, old;
serial_log("UART: Write %02X to port %02X\n", val, addr);
cycles -= ISA_CYCLES(8);
switch (addr & 7) {
case 0:
if (dev->lcr & 0x80) {
dev->dlab = (dev->dlab & 0xff00) | val;
serial_transmit_period(dev);
serial_update_speed(dev);
return;
}
/* Indicate FIFO/THR is no longer empty. */
dev->lsr &= 0x9f;
dev->int_status &= ~SERIAL_INT_TRANSMIT;
serial_update_ints(dev);
if ((dev->type >= SERIAL_NS16550) && dev->fifo_enabled && (dev->xmit_fifo_pos < 16)) {
/* FIFO mode, begin transmitting. */
timer_on_auto(&dev->transmit_timer, dev->transmit_period);
dev->transmit_enabled |= 1; /* Start moving. */
dev->xmit_fifo[dev->xmit_fifo_pos++] = val;
} else {
/* Non-FIFO mode, begin transmitting. */
timer_on_auto(&dev->transmit_timer, dev->transmit_period);
dev->transmit_enabled |= 1; /* Start moving. */
dev->thr = val;
}
break;
case 1:
if (dev->lcr & 0x80) {
dev->dlab = (dev->dlab & 0x00ff) | (val << 8);
serial_transmit_period(dev);
serial_update_speed(dev);
return;
}
if ((val & 2) && (dev->lsr & 0x20))
dev->int_status |= SERIAL_INT_TRANSMIT;
dev->ier = val & 0xf;
serial_update_ints(dev);
break;
case 2:
if (dev->type >= SERIAL_NS16550) {
if ((val ^ dev->fcr) & 0x01)
serial_reset_fifo(dev);
dev->fcr = val & 0xf9;
dev->fifo_enabled = val & 0x01;
if (!dev->fifo_enabled) {
memset(dev->rcvr_fifo, 0, 14);
memset(dev->xmit_fifo, 0, 16);
dev->xmit_fifo_pos = dev->rcvr_fifo_pos = 0;
dev->rcvr_fifo_full = 0;
dev->rcvr_fifo_len = 1;
break;
}
if (val & 0x02) {
memset(dev->rcvr_fifo, 0, 14);
dev->rcvr_fifo_pos = 0;
dev->rcvr_fifo_full = 0;
}
if (val & 0x04) {
memset(dev->xmit_fifo, 0, 16);
dev->xmit_fifo_pos = 0;
}
switch ((val >> 6) & 0x03) {
case 0:
dev->rcvr_fifo_len = 1;
break;
case 1:
dev->rcvr_fifo_len = 4;
break;
case 2:
dev->rcvr_fifo_len = 8;
break;
case 3:
dev->rcvr_fifo_len = 14;
break;
}
serial_log("FIFO now %sabled, receive FIFO length = %i\n", dev->fifo_enabled ? "en" : "dis", dev->rcvr_fifo_len);
}
break;
case 3:
old = dev->lcr;
dev->lcr = val;
if ((old ^ val) & 0x0f) {
/* Data bits + start bit. */
dev->bits = ((dev->lcr & 0x03) + 5) + 1;
/* Stop bits. */
dev->bits++; /* First stop bit. */
if (dev->lcr & 0x04)
dev->bits++; /* Second stop bit. */
/* Parity bit. */
if (dev->lcr & 0x08)
dev->bits++;
serial_transmit_period(dev);
serial_update_speed(dev);
}
break;
case 4:
if ((val & 2) && !(dev->mctrl & 2)) {
if (dev->sd->rcr_callback)
dev->sd->rcr_callback(dev, dev->sd->priv);
}
if (!(val & 8) && (dev->mctrl & 8))
picintc(1 << dev->irq);
if ((val ^ dev->mctrl) & 0x10)
serial_reset_fifo(dev);
dev->mctrl = val;
if (val & 0x10) {
new_msr = (val & 0x0c) << 4;
new_msr |= (val & 0x02) ? 0x10: 0;
new_msr |= (val & 0x01) ? 0x20: 0;
if ((dev->msr ^ new_msr) & 0x10)
new_msr |= 0x01;
if ((dev->msr ^ new_msr) & 0x20)
new_msr |= 0x02;
if ((dev->msr ^ new_msr) & 0x80)
new_msr |= 0x08;
if ((dev->msr & 0x40) && !(new_msr & 0x40))
new_msr |= 0x04;
dev->msr = new_msr;
dev->xmit_fifo_pos = dev->rcvr_fifo_pos = 0;
dev->rcvr_fifo_full = 0;
}
break;
case 5:
dev->lsr = (dev->lsr & 0xe0) | (val & 0x1f);
if (dev->lsr & 0x01)
dev->int_status |= SERIAL_INT_RECEIVE;
if (dev->lsr & 0x1e)
dev->int_status |= SERIAL_INT_LSR;
if (dev->lsr & 0x20)
dev->int_status |= SERIAL_INT_TRANSMIT;
serial_update_ints(dev);
break;
case 6:
dev->msr = val;
if (dev->msr & 0x0f)
dev->int_status |= SERIAL_INT_MSR;
serial_update_ints(dev);
break;
case 7:
if (dev->type >= SERIAL_NS16450)
dev->scratch = val;
break;
}
}
uint8_t
serial_read(uint16_t addr, void *p)
{
serial_t *dev = (serial_t *)p;
uint8_t i, ret = 0;
cycles -= ISA_CYCLES(8);
switch (addr & 7) {
case 0:
if (dev->lcr & 0x80) {
ret = dev->dlab & 0xff;
break;
}
if ((dev->type >= SERIAL_NS16550) && dev->fifo_enabled) {
/* FIFO mode. */
serial_clear_timeout(dev);
ret = dev->rcvr_fifo[0];
dev->rcvr_fifo_full = 0;
if (dev->rcvr_fifo_pos > 0) {
for (i = 1; i < 16; i++)
dev->rcvr_fifo[i - 1] = dev->rcvr_fifo[i];
serial_log("FIFO position %i: read %02X, next %02X\n", dev->rcvr_fifo_pos, ret, dev->rcvr_fifo[0]);
dev->rcvr_fifo_pos--;
/* At least one byte remains to be read, start the timeout
timer so that a timeout is indicated in case of no read. */
timer_on_auto(&dev->timeout_timer, 4.0 * dev->bits * dev->transmit_period);
} else {
dev->lsr &= 0xfe;
dev->int_status &= ~SERIAL_INT_RECEIVE;
serial_update_ints(dev);
}
} else {
ret = dev->dat;
dev->lsr &= 0xfe;
dev->int_status &= ~SERIAL_INT_RECEIVE;
serial_update_ints(dev);
}
serial_log("Read data: %02X\n", ret);
break;
case 1:
if (dev->lcr & 0x80)
ret = (dev->dlab >> 8) & 0xff;
else
ret = dev->ier;
break;
case 2:
ret = dev->iir;
if ((ret & 0xe) == 2) {
dev->int_status &= ~SERIAL_INT_TRANSMIT;
serial_update_ints(dev);
}
if (dev->fcr & 1)
ret |= 0xc0;
break;
case 3:
ret = dev->lcr;
break;
case 4:
ret = dev->mctrl;
break;
case 5:
ret = dev->lsr;
if (dev->lsr & 0x1f)
dev->lsr &= ~0x1e;
dev->int_status &= ~SERIAL_INT_LSR;
serial_update_ints(dev);
break;
case 6:
ret = dev->msr;
dev->msr &= ~0x0f;
dev->int_status &= ~SERIAL_INT_MSR;
serial_update_ints(dev);
break;
case 7:
ret = dev->scratch;
break;
}
serial_log("UART: Read %02X from port %02X\n", ret, addr);
return ret;
}
void
serial_remove(serial_t *dev)
{
if (dev == NULL)
return;
if (!serial_enabled[dev->inst])
return;
if (!dev->base_address)
return;
serial_log("Removing serial port %i at %04X...\n", dev->inst, dev->base_address);
io_removehandler(dev->base_address, 0x0008,
serial_read, NULL, NULL, serial_write, NULL, NULL, dev);
dev->base_address = 0x0000;
}
void
serial_setup(serial_t *dev, uint16_t addr, uint8_t irq)
{
serial_log("Adding serial port %i at %04X...\n", dev->inst, addr);
if (dev == NULL)
return;
if (!serial_enabled[dev->inst])
return;
if (dev->base_address != 0x0000)
serial_remove(dev);
dev->base_address = addr;
if (addr != 0x0000)
io_sethandler(addr, 0x0008, serial_read, NULL, NULL, serial_write, NULL, NULL, dev);
dev->irq = irq;
}
serial_t *
serial_attach(int port,
void (*rcr_callback)(struct serial_s *serial, void *p),
void (*dev_write)(struct serial_s *serial, void *p, uint8_t data),
void *priv)
{
serial_device_t *sd = &serial_devices[port];
sd->rcr_callback = rcr_callback;
sd->dev_write = dev_write;
sd->priv = priv;
return sd->serial;
}
static void
serial_speed_changed(void *priv)
{
serial_t *dev = (serial_t *) priv;
serial_update_speed(dev);
}
static void
serial_close(void *priv)
{
serial_t *dev = (serial_t *) priv;
next_inst--;
free(dev);
}
static void *
serial_init(const device_t *info)
{
serial_t *dev = (serial_t *) malloc(sizeof(serial_t));
memset(dev, 0, sizeof(serial_t));
dev->inst = next_inst;
if (serial_enabled[next_inst]) {
serial_log("Adding serial port %i...\n", next_inst);
dev->type = info->local;
memset(&(serial_devices[next_inst]), 0, sizeof(serial_device_t));
dev->sd = &(serial_devices[next_inst]);
dev->sd->serial = dev;
serial_reset_port(dev);
if (next_inst == 3)
serial_setup(dev, SERIAL4_ADDR, SERIAL4_IRQ);
else if (next_inst == 2)
serial_setup(dev, SERIAL3_ADDR, SERIAL3_IRQ);
else if ((next_inst == 1) || (info->flags & DEVICE_PCJR))
serial_setup(dev, SERIAL2_ADDR, SERIAL2_IRQ);
else if (next_inst == 0)
serial_setup(dev, SERIAL1_ADDR, SERIAL1_IRQ);
/* Default to 1200,N,7. */
dev->dlab = 96;
dev->fcr = 0x06;
dev->clock_src = 1843200.0;
serial_transmit_period(dev);
timer_add(&dev->transmit_timer, serial_transmit_timer, dev, 0);
timer_add(&dev->timeout_timer, serial_timeout_timer, dev, 0);
}
next_inst++;
return dev;
}
void
serial_set_next_inst(int ni)
{
next_inst = ni;
}
void
serial_standalone_init(void) {
if (next_inst == 0) {
device_add_inst(&i8250_device, 1);
device_add_inst(&i8250_device, 2);
device_add_inst(&i8250_device, 3);
device_add_inst(&i8250_device, 4);
} else if (next_inst == 1) {
device_add_inst(&i8250_device, 2);
device_add_inst(&i8250_device, 3);
device_add_inst(&i8250_device, 4);
} else if (next_inst == 2) {
device_add_inst(&i8250_device, 3);
device_add_inst(&i8250_device, 4);
} else
device_add_inst(&i8250_device, 4);
};
const device_t i8250_device = {
"Intel 8250(-compatible) UART",
0,
SERIAL_8250,
serial_init, serial_close, NULL,
{ NULL }, serial_speed_changed, NULL,
NULL
};
const device_t i8250_pcjr_device = {
"Intel 8250(-compatible) UART for PCjr",
DEVICE_PCJR,
SERIAL_8250_PCJR,
serial_init, serial_close, NULL,
{ NULL }, serial_speed_changed, NULL,
NULL
};
const device_t ns16450_device = {
"National Semiconductor NS16450(-compatible) UART",
0,
SERIAL_NS16450,
serial_init, serial_close, NULL,
{ NULL }, serial_speed_changed, NULL,
NULL
};
const device_t ns16550_device = {
"National Semiconductor NS16550(-compatible) UART",
0,
SERIAL_NS16550,
serial_init, serial_close, NULL,
{ NULL }, serial_speed_changed, NULL,
NULL
};
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