qemu-e2k/hw/char/escc.c

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/*
* QEMU ESCC (Z8030/Z8530/Z85C30/SCC/ESCC) serial port emulation
*
* Copyright (c) 2003-2005 Fabrice Bellard
*
* Permission is hereby granted, free of charge, to any person obtaining a copy
* of this software and associated documentation files (the "Software"), to deal
* in the Software without restriction, including without limitation the rights
* to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
* copies of the Software, and to permit persons to whom the Software is
* furnished to do so, subject to the following conditions:
*
* The above copyright notice and this permission notice shall be included in
* all copies or substantial portions of the Software.
*
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
* IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
* FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL
* THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
* LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
* OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
* THE SOFTWARE.
*/
#include "qemu/osdep.h"
#include "hw/irq.h"
#include "hw/qdev-properties.h"
#include "hw/qdev-properties-system.h"
#include "hw/sysbus.h"
#include "migration/vmstate.h"
#include "qemu/module.h"
#include "hw/char/escc.h"
#include "ui/console.h"
#include "trace.h"
/*
* Chipset docs:
* "Z80C30/Z85C30/Z80230/Z85230/Z85233 SCC/ESCC User Manual",
* http://www.zilog.com/docs/serial/scc_escc_um.pdf
*
* On Sparc32 this is the serial port, mouse and keyboard part of chip STP2001
* (Slave I/O), also produced as NCR89C105. See
* http://www.ibiblio.org/pub/historic-linux/early-ports/Sparc/NCR/NCR89C105.txt
*
* The serial ports implement full AMD AM8530 or Zilog Z8530 chips,
* mouse and keyboard ports don't implement all functions and they are
* only asynchronous. There is no DMA.
*
* Z85C30 is also used on PowerMacs and m68k Macs.
*
* There are some small differences between Sparc version (sunzilog)
* and PowerMac (pmac):
* Offset between control and data registers
* There is some kind of lockup bug, but we can ignore it
* CTS is inverted
* DMA on pmac using DBDMA chip
* pmac can do IRDA and faster rates, sunzilog can only do 38400
* pmac baud rate generator clock is 3.6864 MHz, sunzilog 4.9152 MHz
*
* Linux driver for m68k Macs is the same as for PowerMac (pmac_zilog),
* but registers are grouped by type and not by channel:
* channel is selected by bit 0 of the address (instead of bit 1)
* and register is selected by bit 1 of the address (instead of bit 0).
*/
/*
* Modifications:
* 2006-Aug-10 Igor Kovalenko : Renamed KBDQueue to SERIOQueue, implemented
* serial mouse queue.
* Implemented serial mouse protocol.
*
* 2010-May-23 Artyom Tarasenko: Reworked IUS logic
*/
#define CHN_C(s) ((s)->chn == escc_chn_b ? 'b' : 'a')
#define SERIAL_CTRL 0
#define SERIAL_DATA 1
#define W_CMD 0
#define CMD_PTR_MASK 0x07
#define CMD_CMD_MASK 0x38
#define CMD_HI 0x08
#define CMD_CLR_TXINT 0x28
#define CMD_CLR_IUS 0x38
#define W_INTR 1
#define INTR_INTALL 0x01
#define INTR_TXINT 0x02
#define INTR_PAR_SPEC 0x04
#define INTR_RXMODEMSK 0x18
#define INTR_RXINT1ST 0x08
#define INTR_RXINTALL 0x10
#define INTR_WTRQ_TXRX 0x20
#define W_IVEC 2
#define W_RXCTRL 3
#define RXCTRL_RXEN 0x01
#define RXCTRL_HUNT 0x10
#define W_TXCTRL1 4
#define TXCTRL1_PAREN 0x01
#define TXCTRL1_PAREV 0x02
#define TXCTRL1_1STOP 0x04
#define TXCTRL1_1HSTOP 0x08
#define TXCTRL1_2STOP 0x0c
#define TXCTRL1_STPMSK 0x0c
#define TXCTRL1_CLK1X 0x00
#define TXCTRL1_CLK16X 0x40
#define TXCTRL1_CLK32X 0x80
#define TXCTRL1_CLK64X 0xc0
#define TXCTRL1_CLKMSK 0xc0
#define W_TXCTRL2 5
#define TXCTRL2_TXCRC 0x01
#define TXCTRL2_TXEN 0x08
#define TXCTRL2_BITMSK 0x60
#define TXCTRL2_5BITS 0x00
#define TXCTRL2_7BITS 0x20
#define TXCTRL2_6BITS 0x40
#define TXCTRL2_8BITS 0x60
#define W_SYNC1 6
#define W_SYNC2 7
#define W_TXBUF 8
#define W_MINTR 9
#define MINTR_VIS 0x01
#define MINTR_NV 0x02
#define MINTR_STATUSHI 0x10
#define MINTR_SOFTIACK 0x20
#define MINTR_RST_MASK 0xc0
#define MINTR_RST_B 0x40
#define MINTR_RST_A 0x80
#define MINTR_RST_ALL 0xc0
#define W_MISC1 10
#define MISC1_ENC_MASK 0x60
#define W_CLOCK 11
#define CLOCK_TRXC 0x08
#define W_BRGLO 12
#define W_BRGHI 13
#define W_MISC2 14
#define MISC2_BRG_EN 0x01
#define MISC2_BRG_SRC 0x02
#define MISC2_LCL_LOOP 0x10
#define MISC2_PLLCMD0 0x20
#define MISC2_PLLCMD1 0x40
#define MISC2_PLLCMD2 0x80
#define W_EXTINT 15
#define EXTINT_DCD 0x08
#define EXTINT_SYNCINT 0x10
#define EXTINT_CTSINT 0x20
#define EXTINT_TXUNDRN 0x40
#define EXTINT_BRKINT 0x80
#define R_STATUS 0
#define STATUS_RXAV 0x01
#define STATUS_ZERO 0x02
#define STATUS_TXEMPTY 0x04
#define STATUS_DCD 0x08
#define STATUS_SYNC 0x10
#define STATUS_CTS 0x20
#define STATUS_TXUNDRN 0x40
#define STATUS_BRK 0x80
#define R_SPEC 1
#define SPEC_ALLSENT 0x01
#define SPEC_BITS8 0x06
#define R_IVEC 2
#define IVEC_TXINTB 0x00
#define IVEC_LONOINT 0x06
#define IVEC_LORXINTA 0x0c
#define IVEC_LORXINTB 0x04
#define IVEC_LOTXINTA 0x08
#define IVEC_HINOINT 0x60
#define IVEC_HIRXINTA 0x30
#define IVEC_HIRXINTB 0x20
#define IVEC_HITXINTA 0x10
#define R_INTR 3
#define INTR_EXTINTB 0x01
#define INTR_TXINTB 0x02
#define INTR_RXINTB 0x04
#define INTR_EXTINTA 0x08
#define INTR_TXINTA 0x10
#define INTR_RXINTA 0x20
#define R_IPEN 4
#define R_TXCTRL1 5
#define R_TXCTRL2 6
#define R_BC 7
#define R_RXBUF 8
#define R_RXCTRL 9
#define R_MISC 10
#define MISC_2CLKMISS 0x40
#define R_MISC1 11
#define R_BRGLO 12
#define R_BRGHI 13
#define R_MISC1I 14
#define R_EXTINT 15
static void handle_kbd_command(ESCCChannelState *s, int val);
static int serial_can_receive(void *opaque);
static void serial_receive_byte(ESCCChannelState *s, int ch);
static int reg_shift(ESCCState *s)
{
return s->bit_swap ? s->it_shift + 1 : s->it_shift;
}
static int chn_shift(ESCCState *s)
{
return s->bit_swap ? s->it_shift : s->it_shift + 1;
}
static void clear_queue(void *opaque)
{
ESCCChannelState *s = opaque;
ESCCSERIOQueue *q = &s->queue;
q->rptr = q->wptr = q->count = 0;
}
static void put_queue(void *opaque, int b)
{
ESCCChannelState *s = opaque;
ESCCSERIOQueue *q = &s->queue;
trace_escc_put_queue(CHN_C(s), b);
if (q->count >= ESCC_SERIO_QUEUE_SIZE) {
return;
}
q->data[q->wptr] = b;
if (++q->wptr == ESCC_SERIO_QUEUE_SIZE) {
q->wptr = 0;
}
q->count++;
serial_receive_byte(s, 0);
}
static uint32_t get_queue(void *opaque)
{
ESCCChannelState *s = opaque;
ESCCSERIOQueue *q = &s->queue;
int val;
if (q->count == 0) {
return 0;
} else {
val = q->data[q->rptr];
if (++q->rptr == ESCC_SERIO_QUEUE_SIZE) {
q->rptr = 0;
}
q->count--;
}
trace_escc_get_queue(CHN_C(s), val);
if (q->count > 0) {
serial_receive_byte(s, 0);
}
return val;
}
static int escc_update_irq_chn(ESCCChannelState *s)
{
if ((((s->wregs[W_INTR] & INTR_TXINT) && (s->txint == 1)) ||
/* tx ints enabled, pending */
((((s->wregs[W_INTR] & INTR_RXMODEMSK) == INTR_RXINT1ST) ||
((s->wregs[W_INTR] & INTR_RXMODEMSK) == INTR_RXINTALL)) &&
s->rxint == 1) ||
/* rx ints enabled, pending */
((s->wregs[W_EXTINT] & EXTINT_BRKINT) &&
(s->rregs[R_STATUS] & STATUS_BRK)))) {
/* break int e&p */
return 1;
}
return 0;
}
static void escc_update_irq(ESCCChannelState *s)
{
int irq;
irq = escc_update_irq_chn(s);
irq |= escc_update_irq_chn(s->otherchn);
trace_escc_update_irq(irq);
qemu_set_irq(s->irq, irq);
}
static void escc_reset_chn(ESCCChannelState *s)
{
s->reg = 0;
s->rx = s->tx = 0;
s->rxint = s->txint = 0;
s->rxint_under_svc = s->txint_under_svc = 0;
s->e0_mode = s->led_mode = s->caps_lock_mode = s->num_lock_mode = 0;
clear_queue(s);
}
static void escc_soft_reset_chn(ESCCChannelState *s)
{
escc_reset_chn(s);
s->wregs[W_CMD] = 0;
s->wregs[W_INTR] &= INTR_PAR_SPEC | INTR_WTRQ_TXRX;
s->wregs[W_RXCTRL] &= ~RXCTRL_RXEN;
/* 1 stop bit */
s->wregs[W_TXCTRL1] |= TXCTRL1_1STOP;
s->wregs[W_TXCTRL2] &= TXCTRL2_TXCRC | TXCTRL2_8BITS;
s->wregs[W_MINTR] &= ~MINTR_SOFTIACK;
s->wregs[W_MISC1] &= MISC1_ENC_MASK;
/* PLL disabled */
s->wregs[W_MISC2] &= MISC2_BRG_EN | MISC2_BRG_SRC |
MISC2_PLLCMD1 | MISC2_PLLCMD2;
s->wregs[W_MISC2] |= MISC2_PLLCMD0;
/* Enable most interrupts */
s->wregs[W_EXTINT] = EXTINT_DCD | EXTINT_SYNCINT | EXTINT_CTSINT |
EXTINT_TXUNDRN | EXTINT_BRKINT;
s->rregs[R_STATUS] &= STATUS_DCD | STATUS_SYNC | STATUS_CTS | STATUS_BRK;
s->rregs[R_STATUS] |= STATUS_TXEMPTY | STATUS_TXUNDRN;
if (s->disabled) {
s->rregs[R_STATUS] |= STATUS_DCD | STATUS_SYNC | STATUS_CTS;
}
s->rregs[R_SPEC] &= SPEC_ALLSENT;
s->rregs[R_SPEC] |= SPEC_BITS8;
s->rregs[R_INTR] = 0;
s->rregs[R_MISC] &= MISC_2CLKMISS;
}
static void escc_hard_reset_chn(ESCCChannelState *s)
{
escc_soft_reset_chn(s);
/*
* Hard reset is almost identical to soft reset above, except that the
* values of WR9 (W_MINTR), WR10 (W_MISC1), WR11 (W_CLOCK) and WR14
* (W_MISC2) have extra bits forced to 0/1
*/
s->wregs[W_MINTR] &= MINTR_VIS | MINTR_NV;
s->wregs[W_MINTR] |= MINTR_RST_B | MINTR_RST_A;
s->wregs[W_MISC1] = 0;
s->wregs[W_CLOCK] = CLOCK_TRXC;
s->wregs[W_MISC2] &= MISC2_PLLCMD1 | MISC2_PLLCMD2;
s->wregs[W_MISC2] |= MISC2_LCL_LOOP | MISC2_PLLCMD0;
}
static void escc_reset(DeviceState *d)
{
ESCCState *s = ESCC(d);
int i, j;
for (i = 0; i < 2; i++) {
ESCCChannelState *cs = &s->chn[i];
/*
* According to the ESCC datasheet "Miscellaneous Questions" section
* on page 384, the values of the ESCC registers are not guaranteed on
* power-on until an explicit hardware or software reset has been
* issued. For now we zero the registers so that a device reset always
* returns the emulated device to a fixed state.
*/
for (j = 0; j < ESCC_SERIAL_REGS; j++) {
cs->rregs[j] = 0;
cs->wregs[j] = 0;
}
/*
* ...but there is an exception. The "Transmit Interrupts and Transmit
* Buffer Empty Bit" section on page 50 of the ESCC datasheet says of
* the STATUS_TXEMPTY bit in R_STATUS: "After a hardware reset
* (including a hardware reset by software), or a channel reset, this
* bit is set to 1". The Sun PROM checks this bit early on startup and
* gets stuck in an infinite loop if it is not set.
*/
cs->rregs[R_STATUS] |= STATUS_TXEMPTY;
escc_reset_chn(cs);
}
}
static inline void set_rxint(ESCCChannelState *s)
{
s->rxint = 1;
/*
* XXX: missing daisy chaining: escc_chn_b rx should have a lower priority
* than chn_a rx/tx/special_condition service
*/
s->rxint_under_svc = 1;
if (s->chn == escc_chn_a) {
s->rregs[R_INTR] |= INTR_RXINTA;
if (s->wregs[W_MINTR] & MINTR_STATUSHI) {
s->otherchn->rregs[R_IVEC] = IVEC_HIRXINTA;
} else {
s->otherchn->rregs[R_IVEC] = IVEC_LORXINTA;
}
} else {
s->otherchn->rregs[R_INTR] |= INTR_RXINTB;
if (s->wregs[W_MINTR] & MINTR_STATUSHI) {
s->rregs[R_IVEC] = IVEC_HIRXINTB;
} else {
s->rregs[R_IVEC] = IVEC_LORXINTB;
}
}
escc_update_irq(s);
}
static inline void set_txint(ESCCChannelState *s)
{
s->txint = 1;
if (!s->rxint_under_svc) {
s->txint_under_svc = 1;
if (s->chn == escc_chn_a) {
if (s->wregs[W_INTR] & INTR_TXINT) {
s->rregs[R_INTR] |= INTR_TXINTA;
}
if (s->wregs[W_MINTR] & MINTR_STATUSHI) {
s->otherchn->rregs[R_IVEC] = IVEC_HITXINTA;
} else {
s->otherchn->rregs[R_IVEC] = IVEC_LOTXINTA;
}
} else {
s->rregs[R_IVEC] = IVEC_TXINTB;
if (s->wregs[W_INTR] & INTR_TXINT) {
s->otherchn->rregs[R_INTR] |= INTR_TXINTB;
}
}
escc_update_irq(s);
}
}
static inline void clr_rxint(ESCCChannelState *s)
{
s->rxint = 0;
s->rxint_under_svc = 0;
if (s->chn == escc_chn_a) {
if (s->wregs[W_MINTR] & MINTR_STATUSHI) {
s->otherchn->rregs[R_IVEC] = IVEC_HINOINT;
} else {
s->otherchn->rregs[R_IVEC] = IVEC_LONOINT;
}
s->rregs[R_INTR] &= ~INTR_RXINTA;
} else {
if (s->wregs[W_MINTR] & MINTR_STATUSHI) {
s->rregs[R_IVEC] = IVEC_HINOINT;
} else {
s->rregs[R_IVEC] = IVEC_LONOINT;
}
s->otherchn->rregs[R_INTR] &= ~INTR_RXINTB;
}
if (s->txint) {
set_txint(s);
}
escc_update_irq(s);
}
static inline void clr_txint(ESCCChannelState *s)
{
s->txint = 0;
s->txint_under_svc = 0;
if (s->chn == escc_chn_a) {
if (s->wregs[W_MINTR] & MINTR_STATUSHI) {
s->otherchn->rregs[R_IVEC] = IVEC_HINOINT;
} else {
s->otherchn->rregs[R_IVEC] = IVEC_LONOINT;
}
s->rregs[R_INTR] &= ~INTR_TXINTA;
} else {
s->otherchn->rregs[R_INTR] &= ~INTR_TXINTB;
if (s->wregs[W_MINTR] & MINTR_STATUSHI) {
s->rregs[R_IVEC] = IVEC_HINOINT;
} else {
s->rregs[R_IVEC] = IVEC_LONOINT;
}
s->otherchn->rregs[R_INTR] &= ~INTR_TXINTB;
}
if (s->rxint) {
set_rxint(s);
}
escc_update_irq(s);
}
static void escc_update_parameters(ESCCChannelState *s)
{
int speed, parity, data_bits, stop_bits;
QEMUSerialSetParams ssp;
if (!qemu_chr_fe_backend_connected(&s->chr) || s->type != escc_serial) {
return;
}
if (s->wregs[W_TXCTRL1] & TXCTRL1_PAREN) {
if (s->wregs[W_TXCTRL1] & TXCTRL1_PAREV) {
parity = 'E';
} else {
parity = 'O';
}
} else {
parity = 'N';
}
if ((s->wregs[W_TXCTRL1] & TXCTRL1_STPMSK) == TXCTRL1_2STOP) {
stop_bits = 2;
} else {
stop_bits = 1;
}
switch (s->wregs[W_TXCTRL2] & TXCTRL2_BITMSK) {
case TXCTRL2_5BITS:
data_bits = 5;
break;
case TXCTRL2_7BITS:
data_bits = 7;
break;
case TXCTRL2_6BITS:
data_bits = 6;
break;
default:
case TXCTRL2_8BITS:
data_bits = 8;
break;
}
speed = s->clock / ((s->wregs[W_BRGLO] | (s->wregs[W_BRGHI] << 8)) + 2);
switch (s->wregs[W_TXCTRL1] & TXCTRL1_CLKMSK) {
case TXCTRL1_CLK1X:
break;
case TXCTRL1_CLK16X:
speed /= 16;
break;
case TXCTRL1_CLK32X:
speed /= 32;
break;
default:
case TXCTRL1_CLK64X:
speed /= 64;
break;
}
ssp.speed = speed;
ssp.parity = parity;
ssp.data_bits = data_bits;
ssp.stop_bits = stop_bits;
trace_escc_update_parameters(CHN_C(s), speed, parity, data_bits, stop_bits);
qemu_chr_fe_ioctl(&s->chr, CHR_IOCTL_SERIAL_SET_PARAMS, &ssp);
}
static void escc_mem_write(void *opaque, hwaddr addr,
uint64_t val, unsigned size)
{
ESCCState *serial = opaque;
ESCCChannelState *s;
uint32_t saddr;
int newreg, channel;
val &= 0xff;
saddr = (addr >> reg_shift(serial)) & 1;
channel = (addr >> chn_shift(serial)) & 1;
s = &serial->chn[channel];
switch (saddr) {
case SERIAL_CTRL:
trace_escc_mem_writeb_ctrl(CHN_C(s), s->reg, val & 0xff);
newreg = 0;
switch (s->reg) {
case W_CMD:
newreg = val & CMD_PTR_MASK;
val &= CMD_CMD_MASK;
switch (val) {
case CMD_HI:
newreg |= CMD_HI;
break;
case CMD_CLR_TXINT:
clr_txint(s);
break;
case CMD_CLR_IUS:
if (s->rxint_under_svc) {
s->rxint_under_svc = 0;
if (s->txint) {
set_txint(s);
}
} else if (s->txint_under_svc) {
s->txint_under_svc = 0;
}
escc_update_irq(s);
break;
default:
break;
}
break;
case W_RXCTRL:
s->wregs[s->reg] = val;
if (val & RXCTRL_HUNT) {
s->rregs[R_STATUS] |= STATUS_SYNC;
}
break;
case W_INTR ... W_IVEC:
case W_SYNC1 ... W_TXBUF:
case W_MISC1 ... W_CLOCK:
case W_MISC2 ... W_EXTINT:
s->wregs[s->reg] = val;
break;
case W_TXCTRL1:
s->wregs[s->reg] = val;
/*
* The ESCC datasheet states that SPEC_ALLSENT is always set in
* sync mode, and set in async mode when all characters have
* cleared the transmitter. Since writes to SERIAL_DATA use the
* blocking qemu_chr_fe_write_all() function to write each
* character, the guest can never see the state when async data
* is in the process of being transmitted so we can set this bit
* unconditionally regardless of the state of the W_TXCTRL1 mode
* bits.
*/
s->rregs[R_SPEC] |= SPEC_ALLSENT;
escc_update_parameters(s);
break;
case W_TXCTRL2:
s->wregs[s->reg] = val;
escc_update_parameters(s);
break;
case W_BRGLO:
case W_BRGHI:
s->wregs[s->reg] = val;
s->rregs[s->reg] = val;
escc_update_parameters(s);
break;
case W_MINTR:
switch (val & MINTR_RST_MASK) {
case 0:
default:
break;
case MINTR_RST_B:
trace_escc_soft_reset_chn(CHN_C(&serial->chn[0]));
escc_soft_reset_chn(&serial->chn[0]);
return;
case MINTR_RST_A:
trace_escc_soft_reset_chn(CHN_C(&serial->chn[1]));
escc_soft_reset_chn(&serial->chn[1]);
return;
case MINTR_RST_ALL:
trace_escc_hard_reset();
escc_hard_reset_chn(&serial->chn[0]);
escc_hard_reset_chn(&serial->chn[1]);
return;
}
break;
default:
break;
}
if (s->reg == 0) {
s->reg = newreg;
} else {
s->reg = 0;
}
break;
case SERIAL_DATA:
trace_escc_mem_writeb_data(CHN_C(s), val);
/*
* Lower the irq when data is written to the Tx buffer and no other
* interrupts are currently pending. The irq will be raised again once
* the Tx buffer becomes empty below.
*/
s->txint = 0;
escc_update_irq(s);
s->tx = val;
if (s->wregs[W_TXCTRL2] & TXCTRL2_TXEN) { /* tx enabled */
if (qemu_chr_fe_backend_connected(&s->chr)) {
/*
* XXX this blocks entire thread. Rewrite to use
* qemu_chr_fe_write and background I/O callbacks
*/
qemu_chr_fe_write_all(&s->chr, &s->tx, 1);
} else if (s->type == escc_kbd && !s->disabled) {
handle_kbd_command(s, val);
}
}
s->rregs[R_STATUS] |= STATUS_TXEMPTY; /* Tx buffer empty */
s->rregs[R_SPEC] |= SPEC_ALLSENT; /* All sent */
set_txint(s);
break;
default:
break;
}
}
static uint64_t escc_mem_read(void *opaque, hwaddr addr,
unsigned size)
{
ESCCState *serial = opaque;
ESCCChannelState *s;
uint32_t saddr;
uint32_t ret;
int channel;
saddr = (addr >> reg_shift(serial)) & 1;
channel = (addr >> chn_shift(serial)) & 1;
s = &serial->chn[channel];
switch (saddr) {
case SERIAL_CTRL:
trace_escc_mem_readb_ctrl(CHN_C(s), s->reg, s->rregs[s->reg]);
ret = s->rregs[s->reg];
s->reg = 0;
return ret;
case SERIAL_DATA:
s->rregs[R_STATUS] &= ~STATUS_RXAV;
clr_rxint(s);
if (s->type == escc_kbd || s->type == escc_mouse) {
ret = get_queue(s);
} else {
ret = s->rx;
}
trace_escc_mem_readb_data(CHN_C(s), ret);
qemu_chr_fe_accept_input(&s->chr);
return ret;
default:
break;
}
return 0;
}
static const MemoryRegionOps escc_mem_ops = {
.read = escc_mem_read,
.write = escc_mem_write,
.endianness = DEVICE_NATIVE_ENDIAN,
.valid = {
.min_access_size = 1,
.max_access_size = 1,
},
};
static int serial_can_receive(void *opaque)
{
ESCCChannelState *s = opaque;
int ret;
if (((s->wregs[W_RXCTRL] & RXCTRL_RXEN) == 0) /* Rx not enabled */
|| ((s->rregs[R_STATUS] & STATUS_RXAV) == STATUS_RXAV)) {
/* char already available */
ret = 0;
} else {
ret = 1;
}
return ret;
}
static void serial_receive_byte(ESCCChannelState *s, int ch)
{
trace_escc_serial_receive_byte(CHN_C(s), ch);
s->rregs[R_STATUS] |= STATUS_RXAV;
s->rx = ch;
set_rxint(s);
}
static void serial_receive_break(ESCCChannelState *s)
{
s->rregs[R_STATUS] |= STATUS_BRK;
escc_update_irq(s);
}
static void serial_receive1(void *opaque, const uint8_t *buf, int size)
{
ESCCChannelState *s = opaque;
serial_receive_byte(s, buf[0]);
}
static void serial_event(void *opaque, QEMUChrEvent event)
{
ESCCChannelState *s = opaque;
if (event == CHR_EVENT_BREAK) {
serial_receive_break(s);
}
}
static const VMStateDescription vmstate_escc_chn = {
.name = "escc_chn",
.version_id = 2,
.minimum_version_id = 1,
.fields = (VMStateField[]) {
VMSTATE_UINT32(vmstate_dummy, ESCCChannelState),
VMSTATE_UINT32(reg, ESCCChannelState),
VMSTATE_UINT32(rxint, ESCCChannelState),
VMSTATE_UINT32(txint, ESCCChannelState),
VMSTATE_UINT32(rxint_under_svc, ESCCChannelState),
VMSTATE_UINT32(txint_under_svc, ESCCChannelState),
VMSTATE_UINT8(rx, ESCCChannelState),
VMSTATE_UINT8(tx, ESCCChannelState),
VMSTATE_BUFFER(wregs, ESCCChannelState),
VMSTATE_BUFFER(rregs, ESCCChannelState),
VMSTATE_END_OF_LIST()
}
};
static const VMStateDescription vmstate_escc = {
.name = "escc",
.version_id = 2,
.minimum_version_id = 1,
.fields = (VMStateField[]) {
VMSTATE_STRUCT_ARRAY(chn, ESCCState, 2, 2, vmstate_escc_chn,
ESCCChannelState),
VMSTATE_END_OF_LIST()
}
};
static void sunkbd_handle_event(DeviceState *dev, QemuConsole *src,
InputEvent *evt)
{
ESCCChannelState *s = (ESCCChannelState *)dev;
int qcode, keycode;
InputKeyEvent *key;
assert(evt->type == INPUT_EVENT_KIND_KEY);
qapi: Don't special-case simple union wrappers Simple unions were carrying a special case that hid their 'data' QMP member from the resulting C struct, via the hack method QAPISchemaObjectTypeVariant.simple_union_type(). But by using the work we started by unboxing flat union and alternate branches, coupled with the ability to visit the members of an implicit type, we can now expose the simple union's implicit type in qapi-types.h: | struct q_obj_ImageInfoSpecificQCow2_wrapper { | ImageInfoSpecificQCow2 *data; | }; | | struct q_obj_ImageInfoSpecificVmdk_wrapper { | ImageInfoSpecificVmdk *data; | }; ... | struct ImageInfoSpecific { | ImageInfoSpecificKind type; | union { /* union tag is @type */ | void *data; |- ImageInfoSpecificQCow2 *qcow2; |- ImageInfoSpecificVmdk *vmdk; |+ q_obj_ImageInfoSpecificQCow2_wrapper qcow2; |+ q_obj_ImageInfoSpecificVmdk_wrapper vmdk; | } u; | }; Doing this removes asymmetry between QAPI's QMP side and its C side (both sides now expose 'data'), and means that the treatment of a simple union as sugar for a flat union is now equivalent in both languages (previously the two approaches used a different layer of dereferencing, where the simple union could be converted to a flat union with equivalent C layout but different {} on the wire, or to an equivalent QMP wire form but with different C representation). Using the implicit type also lets us get rid of the simple_union_type() hack. Of course, now all clients of simple unions have to adjust from using su->u.member to using su->u.member.data; while this touches a number of files in the tree, some earlier cleanup patches helped minimize the change to the initialization of a temporary variable rather than every single member access. The generated qapi-visit.c code is also affected by the layout change: |@@ -7393,10 +7393,10 @@ void visit_type_ImageInfoSpecific_member | } | switch (obj->type) { | case IMAGE_INFO_SPECIFIC_KIND_QCOW2: |- visit_type_ImageInfoSpecificQCow2(v, "data", &obj->u.qcow2, &err); |+ visit_type_q_obj_ImageInfoSpecificQCow2_wrapper_members(v, &obj->u.qcow2, &err); | break; | case IMAGE_INFO_SPECIFIC_KIND_VMDK: |- visit_type_ImageInfoSpecificVmdk(v, "data", &obj->u.vmdk, &err); |+ visit_type_q_obj_ImageInfoSpecificVmdk_wrapper_members(v, &obj->u.vmdk, &err); | break; | default: | abort(); Signed-off-by: Eric Blake <eblake@redhat.com> Message-Id: <1458254921-17042-13-git-send-email-eblake@redhat.com> Signed-off-by: Markus Armbruster <armbru@redhat.com>
2016-03-17 23:48:37 +01:00
key = evt->u.key.data;
qcode = qemu_input_key_value_to_qcode(key->key);
trace_escc_sunkbd_event_in(qcode, QKeyCode_str(qcode),
key->down);
if (qcode == Q_KEY_CODE_CAPS_LOCK) {
if (key->down) {
s->caps_lock_mode ^= 1;
if (s->caps_lock_mode == 2) {
return; /* Drop second press */
}
} else {
s->caps_lock_mode ^= 2;
if (s->caps_lock_mode == 3) {
return; /* Drop first release */
}
}
}
if (qcode == Q_KEY_CODE_NUM_LOCK) {
if (key->down) {
s->num_lock_mode ^= 1;
if (s->num_lock_mode == 2) {
return; /* Drop second press */
}
} else {
s->num_lock_mode ^= 2;
if (s->num_lock_mode == 3) {
return; /* Drop first release */
}
}
}
if (qcode >= qemu_input_map_qcode_to_sun_len) {
return;
}
keycode = qemu_input_map_qcode_to_sun[qcode];
if (!key->down) {
keycode |= 0x80;
}
trace_escc_sunkbd_event_out(keycode);
put_queue(s, keycode);
}
static QemuInputHandler sunkbd_handler = {
.name = "sun keyboard",
.mask = INPUT_EVENT_MASK_KEY,
.event = sunkbd_handle_event,
};
static void handle_kbd_command(ESCCChannelState *s, int val)
{
trace_escc_kbd_command(val);
if (s->led_mode) { /* Ignore led byte */
s->led_mode = 0;
return;
}
switch (val) {
case 1: /* Reset, return type code */
clear_queue(s);
put_queue(s, 0xff);
put_queue(s, 4); /* Type 4 */
put_queue(s, 0x7f);
break;
case 0xe: /* Set leds */
s->led_mode = 1;
break;
case 7: /* Query layout */
case 0xf:
clear_queue(s);
put_queue(s, 0xfe);
put_queue(s, 0x21); /* en-us layout */
break;
default:
break;
}
}
static void sunmouse_event(void *opaque,
int dx, int dy, int dz, int buttons_state)
{
ESCCChannelState *s = opaque;
int ch;
trace_escc_sunmouse_event(dx, dy, buttons_state);
ch = 0x80 | 0x7; /* protocol start byte, no buttons pressed */
if (buttons_state & MOUSE_EVENT_LBUTTON) {
ch ^= 0x4;
}
if (buttons_state & MOUSE_EVENT_MBUTTON) {
ch ^= 0x2;
}
if (buttons_state & MOUSE_EVENT_RBUTTON) {
ch ^= 0x1;
}
put_queue(s, ch);
ch = dx;
if (ch > 127) {
ch = 127;
} else if (ch < -127) {
ch = -127;
}
put_queue(s, ch & 0xff);
ch = -dy;
if (ch > 127) {
ch = 127;
} else if (ch < -127) {
ch = -127;
}
put_queue(s, ch & 0xff);
/* MSC protocol specifies two extra motion bytes */
put_queue(s, 0);
put_queue(s, 0);
}
static void escc_init1(Object *obj)
{
ESCCState *s = ESCC(obj);
SysBusDevice *dev = SYS_BUS_DEVICE(obj);
unsigned int i;
for (i = 0; i < 2; i++) {
sysbus_init_irq(dev, &s->chn[i].irq);
s->chn[i].chn = 1 - i;
}
s->chn[0].otherchn = &s->chn[1];
s->chn[1].otherchn = &s->chn[0];
sysbus_init_mmio(dev, &s->mmio);
}
static void escc_realize(DeviceState *dev, Error **errp)
{
ESCCState *s = ESCC(dev);
unsigned int i;
s->chn[0].disabled = s->disabled;
s->chn[1].disabled = s->disabled;
memory_region_init_io(&s->mmio, OBJECT(dev), &escc_mem_ops, s, "escc",
ESCC_SIZE << s->it_shift);
for (i = 0; i < 2; i++) {
if (qemu_chr_fe_backend_connected(&s->chn[i].chr)) {
s->chn[i].clock = s->frequency / 2;
qemu_chr_fe_set_handlers(&s->chn[i].chr, serial_can_receive,
serial_receive1, serial_event, NULL,
&s->chn[i], NULL, true);
}
}
if (s->chn[0].type == escc_mouse) {
qemu_add_mouse_event_handler(sunmouse_event, &s->chn[0], 0,
"QEMU Sun Mouse");
}
if (s->chn[1].type == escc_kbd) {
s->chn[1].hs = qemu_input_handler_register((DeviceState *)(&s->chn[1]),
&sunkbd_handler);
}
}
static Property escc_properties[] = {
DEFINE_PROP_UINT32("frequency", ESCCState, frequency, 0),
DEFINE_PROP_UINT32("it_shift", ESCCState, it_shift, 0),
DEFINE_PROP_BOOL("bit_swap", ESCCState, bit_swap, false),
DEFINE_PROP_UINT32("disabled", ESCCState, disabled, 0),
DEFINE_PROP_UINT32("chnBtype", ESCCState, chn[0].type, 0),
DEFINE_PROP_UINT32("chnAtype", ESCCState, chn[1].type, 0),
DEFINE_PROP_CHR("chrB", ESCCState, chn[0].chr),
DEFINE_PROP_CHR("chrA", ESCCState, chn[1].chr),
DEFINE_PROP_END_OF_LIST(),
};
static void escc_class_init(ObjectClass *klass, void *data)
{
DeviceClass *dc = DEVICE_CLASS(klass);
dc->reset = escc_reset;
dc->realize = escc_realize;
dc->vmsd = &vmstate_escc;
device_class_set_props(dc, escc_properties);
set_bit(DEVICE_CATEGORY_INPUT, dc->categories);
}
static const TypeInfo escc_info = {
.name = TYPE_ESCC,
.parent = TYPE_SYS_BUS_DEVICE,
.instance_size = sizeof(ESCCState),
.instance_init = escc_init1,
.class_init = escc_class_init,
};
static void escc_register_types(void)
{
type_register_static(&escc_info);
}
type_init(escc_register_types)