qemu-e2k/hw/char/cadence_uart.c
Michael S. Tsirkin 5eb0b194e9 cadence_uart: bounds check write offset
cadence_uart_init() initializes an I/O memory region of size 0x1000
bytes.  However in uart_write(), the 'offset' parameter (offset within
region) is divided by 4 and then used to index the array 'r' of size
CADENCE_UART_R_MAX which is much smaller: (0x48/4).  If 'offset>>=2'
exceeds CADENCE_UART_R_MAX, this will cause an out-of-bounds memory
write where the offset and the value are controlled by guest.

This will corrupt QEMU memory, in most situations this causes the vm to
crash.

Fix by checking the offset against the array size.

Cc: qemu-stable@nongnu.org
Reported-by: 李强 <liqiang6-s@360.cn>
Signed-off-by: Michael S. Tsirkin <mst@redhat.com>
Reviewed-by: Alistair Francis <alistair.francis@xilinx.com>
Message-id: 20160418100735.GA517@redhat.com
Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
2016-04-19 11:13:59 +01:00

541 lines
15 KiB
C

/*
* Device model for Cadence UART
*
* Copyright (c) 2010 Xilinx Inc.
* Copyright (c) 2012 Peter A.G. Crosthwaite (peter.crosthwaite@petalogix.com)
* Copyright (c) 2012 PetaLogix Pty Ltd.
* Written by Haibing Ma
* M.Habib
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation; either version
* 2 of the License, or (at your option) any later version.
*
* You should have received a copy of the GNU General Public License along
* with this program; if not, see <http://www.gnu.org/licenses/>.
*/
#include "qemu/osdep.h"
#include "hw/char/cadence_uart.h"
#ifdef CADENCE_UART_ERR_DEBUG
#define DB_PRINT(...) do { \
fprintf(stderr, ": %s: ", __func__); \
fprintf(stderr, ## __VA_ARGS__); \
} while (0);
#else
#define DB_PRINT(...)
#endif
#define UART_SR_INTR_RTRIG 0x00000001
#define UART_SR_INTR_REMPTY 0x00000002
#define UART_SR_INTR_RFUL 0x00000004
#define UART_SR_INTR_TEMPTY 0x00000008
#define UART_SR_INTR_TFUL 0x00000010
/* somewhat awkwardly, TTRIG is misaligned between SR and ISR */
#define UART_SR_TTRIG 0x00002000
#define UART_INTR_TTRIG 0x00000400
/* bits fields in CSR that correlate to CISR. If any of these bits are set in
* SR, then the same bit in CISR is set high too */
#define UART_SR_TO_CISR_MASK 0x0000001F
#define UART_INTR_ROVR 0x00000020
#define UART_INTR_FRAME 0x00000040
#define UART_INTR_PARE 0x00000080
#define UART_INTR_TIMEOUT 0x00000100
#define UART_INTR_DMSI 0x00000200
#define UART_INTR_TOVR 0x00001000
#define UART_SR_RACTIVE 0x00000400
#define UART_SR_TACTIVE 0x00000800
#define UART_SR_FDELT 0x00001000
#define UART_CR_RXRST 0x00000001
#define UART_CR_TXRST 0x00000002
#define UART_CR_RX_EN 0x00000004
#define UART_CR_RX_DIS 0x00000008
#define UART_CR_TX_EN 0x00000010
#define UART_CR_TX_DIS 0x00000020
#define UART_CR_RST_TO 0x00000040
#define UART_CR_STARTBRK 0x00000080
#define UART_CR_STOPBRK 0x00000100
#define UART_MR_CLKS 0x00000001
#define UART_MR_CHRL 0x00000006
#define UART_MR_CHRL_SH 1
#define UART_MR_PAR 0x00000038
#define UART_MR_PAR_SH 3
#define UART_MR_NBSTOP 0x000000C0
#define UART_MR_NBSTOP_SH 6
#define UART_MR_CHMODE 0x00000300
#define UART_MR_CHMODE_SH 8
#define UART_MR_UCLKEN 0x00000400
#define UART_MR_IRMODE 0x00000800
#define UART_DATA_BITS_6 (0x3 << UART_MR_CHRL_SH)
#define UART_DATA_BITS_7 (0x2 << UART_MR_CHRL_SH)
#define UART_PARITY_ODD (0x1 << UART_MR_PAR_SH)
#define UART_PARITY_EVEN (0x0 << UART_MR_PAR_SH)
#define UART_STOP_BITS_1 (0x3 << UART_MR_NBSTOP_SH)
#define UART_STOP_BITS_2 (0x2 << UART_MR_NBSTOP_SH)
#define NORMAL_MODE (0x0 << UART_MR_CHMODE_SH)
#define ECHO_MODE (0x1 << UART_MR_CHMODE_SH)
#define LOCAL_LOOPBACK (0x2 << UART_MR_CHMODE_SH)
#define REMOTE_LOOPBACK (0x3 << UART_MR_CHMODE_SH)
#define UART_INPUT_CLK 50000000
#define R_CR (0x00/4)
#define R_MR (0x04/4)
#define R_IER (0x08/4)
#define R_IDR (0x0C/4)
#define R_IMR (0x10/4)
#define R_CISR (0x14/4)
#define R_BRGR (0x18/4)
#define R_RTOR (0x1C/4)
#define R_RTRIG (0x20/4)
#define R_MCR (0x24/4)
#define R_MSR (0x28/4)
#define R_SR (0x2C/4)
#define R_TX_RX (0x30/4)
#define R_BDIV (0x34/4)
#define R_FDEL (0x38/4)
#define R_PMIN (0x3C/4)
#define R_PWID (0x40/4)
#define R_TTRIG (0x44/4)
static void uart_update_status(CadenceUARTState *s)
{
s->r[R_SR] = 0;
s->r[R_SR] |= s->rx_count == CADENCE_UART_RX_FIFO_SIZE ? UART_SR_INTR_RFUL
: 0;
s->r[R_SR] |= !s->rx_count ? UART_SR_INTR_REMPTY : 0;
s->r[R_SR] |= s->rx_count >= s->r[R_RTRIG] ? UART_SR_INTR_RTRIG : 0;
s->r[R_SR] |= s->tx_count == CADENCE_UART_TX_FIFO_SIZE ? UART_SR_INTR_TFUL
: 0;
s->r[R_SR] |= !s->tx_count ? UART_SR_INTR_TEMPTY : 0;
s->r[R_SR] |= s->tx_count >= s->r[R_TTRIG] ? UART_SR_TTRIG : 0;
s->r[R_CISR] |= s->r[R_SR] & UART_SR_TO_CISR_MASK;
s->r[R_CISR] |= s->r[R_SR] & UART_SR_TTRIG ? UART_INTR_TTRIG : 0;
qemu_set_irq(s->irq, !!(s->r[R_IMR] & s->r[R_CISR]));
}
static void fifo_trigger_update(void *opaque)
{
CadenceUARTState *s = opaque;
s->r[R_CISR] |= UART_INTR_TIMEOUT;
uart_update_status(s);
}
static void uart_rx_reset(CadenceUARTState *s)
{
s->rx_wpos = 0;
s->rx_count = 0;
if (s->chr) {
qemu_chr_accept_input(s->chr);
}
}
static void uart_tx_reset(CadenceUARTState *s)
{
s->tx_count = 0;
}
static void uart_send_breaks(CadenceUARTState *s)
{
int break_enabled = 1;
if (s->chr) {
qemu_chr_fe_ioctl(s->chr, CHR_IOCTL_SERIAL_SET_BREAK,
&break_enabled);
}
}
static void uart_parameters_setup(CadenceUARTState *s)
{
QEMUSerialSetParams ssp;
unsigned int baud_rate, packet_size;
baud_rate = (s->r[R_MR] & UART_MR_CLKS) ?
UART_INPUT_CLK / 8 : UART_INPUT_CLK;
ssp.speed = baud_rate / (s->r[R_BRGR] * (s->r[R_BDIV] + 1));
packet_size = 1;
switch (s->r[R_MR] & UART_MR_PAR) {
case UART_PARITY_EVEN:
ssp.parity = 'E';
packet_size++;
break;
case UART_PARITY_ODD:
ssp.parity = 'O';
packet_size++;
break;
default:
ssp.parity = 'N';
break;
}
switch (s->r[R_MR] & UART_MR_CHRL) {
case UART_DATA_BITS_6:
ssp.data_bits = 6;
break;
case UART_DATA_BITS_7:
ssp.data_bits = 7;
break;
default:
ssp.data_bits = 8;
break;
}
switch (s->r[R_MR] & UART_MR_NBSTOP) {
case UART_STOP_BITS_1:
ssp.stop_bits = 1;
break;
default:
ssp.stop_bits = 2;
break;
}
packet_size += ssp.data_bits + ssp.stop_bits;
s->char_tx_time = (NANOSECONDS_PER_SECOND / ssp.speed) * packet_size;
if (s->chr) {
qemu_chr_fe_ioctl(s->chr, CHR_IOCTL_SERIAL_SET_PARAMS, &ssp);
}
}
static int uart_can_receive(void *opaque)
{
CadenceUARTState *s = opaque;
int ret = MAX(CADENCE_UART_RX_FIFO_SIZE, CADENCE_UART_TX_FIFO_SIZE);
uint32_t ch_mode = s->r[R_MR] & UART_MR_CHMODE;
if (ch_mode == NORMAL_MODE || ch_mode == ECHO_MODE) {
ret = MIN(ret, CADENCE_UART_RX_FIFO_SIZE - s->rx_count);
}
if (ch_mode == REMOTE_LOOPBACK || ch_mode == ECHO_MODE) {
ret = MIN(ret, CADENCE_UART_TX_FIFO_SIZE - s->tx_count);
}
return ret;
}
static void uart_ctrl_update(CadenceUARTState *s)
{
if (s->r[R_CR] & UART_CR_TXRST) {
uart_tx_reset(s);
}
if (s->r[R_CR] & UART_CR_RXRST) {
uart_rx_reset(s);
}
s->r[R_CR] &= ~(UART_CR_TXRST | UART_CR_RXRST);
if (s->r[R_CR] & UART_CR_STARTBRK && !(s->r[R_CR] & UART_CR_STOPBRK)) {
uart_send_breaks(s);
}
}
static void uart_write_rx_fifo(void *opaque, const uint8_t *buf, int size)
{
CadenceUARTState *s = opaque;
uint64_t new_rx_time = qemu_clock_get_ns(QEMU_CLOCK_VIRTUAL);
int i;
if ((s->r[R_CR] & UART_CR_RX_DIS) || !(s->r[R_CR] & UART_CR_RX_EN)) {
return;
}
if (s->rx_count == CADENCE_UART_RX_FIFO_SIZE) {
s->r[R_CISR] |= UART_INTR_ROVR;
} else {
for (i = 0; i < size; i++) {
s->rx_fifo[s->rx_wpos] = buf[i];
s->rx_wpos = (s->rx_wpos + 1) % CADENCE_UART_RX_FIFO_SIZE;
s->rx_count++;
}
timer_mod(s->fifo_trigger_handle, new_rx_time +
(s->char_tx_time * 4));
}
uart_update_status(s);
}
static gboolean cadence_uart_xmit(GIOChannel *chan, GIOCondition cond,
void *opaque)
{
CadenceUARTState *s = opaque;
int ret;
/* instant drain the fifo when there's no back-end */
if (!s->chr) {
s->tx_count = 0;
return FALSE;
}
if (!s->tx_count) {
return FALSE;
}
ret = qemu_chr_fe_write(s->chr, s->tx_fifo, s->tx_count);
s->tx_count -= ret;
memmove(s->tx_fifo, s->tx_fifo + ret, s->tx_count);
if (s->tx_count) {
int r = qemu_chr_fe_add_watch(s->chr, G_IO_OUT|G_IO_HUP,
cadence_uart_xmit, s);
assert(r);
}
uart_update_status(s);
return FALSE;
}
static void uart_write_tx_fifo(CadenceUARTState *s, const uint8_t *buf,
int size)
{
if ((s->r[R_CR] & UART_CR_TX_DIS) || !(s->r[R_CR] & UART_CR_TX_EN)) {
return;
}
if (size > CADENCE_UART_TX_FIFO_SIZE - s->tx_count) {
size = CADENCE_UART_TX_FIFO_SIZE - s->tx_count;
/*
* This can only be a guest error via a bad tx fifo register push,
* as can_receive() should stop remote loop and echo modes ever getting
* us to here.
*/
qemu_log_mask(LOG_GUEST_ERROR, "cadence_uart: TxFIFO overflow");
s->r[R_CISR] |= UART_INTR_ROVR;
}
memcpy(s->tx_fifo + s->tx_count, buf, size);
s->tx_count += size;
cadence_uart_xmit(NULL, G_IO_OUT, s);
}
static void uart_receive(void *opaque, const uint8_t *buf, int size)
{
CadenceUARTState *s = opaque;
uint32_t ch_mode = s->r[R_MR] & UART_MR_CHMODE;
if (ch_mode == NORMAL_MODE || ch_mode == ECHO_MODE) {
uart_write_rx_fifo(opaque, buf, size);
}
if (ch_mode == REMOTE_LOOPBACK || ch_mode == ECHO_MODE) {
uart_write_tx_fifo(s, buf, size);
}
}
static void uart_event(void *opaque, int event)
{
CadenceUARTState *s = opaque;
uint8_t buf = '\0';
if (event == CHR_EVENT_BREAK) {
uart_write_rx_fifo(opaque, &buf, 1);
}
uart_update_status(s);
}
static void uart_read_rx_fifo(CadenceUARTState *s, uint32_t *c)
{
if ((s->r[R_CR] & UART_CR_RX_DIS) || !(s->r[R_CR] & UART_CR_RX_EN)) {
return;
}
if (s->rx_count) {
uint32_t rx_rpos = (CADENCE_UART_RX_FIFO_SIZE + s->rx_wpos -
s->rx_count) % CADENCE_UART_RX_FIFO_SIZE;
*c = s->rx_fifo[rx_rpos];
s->rx_count--;
if (s->chr) {
qemu_chr_accept_input(s->chr);
}
} else {
*c = 0;
}
uart_update_status(s);
}
static void uart_write(void *opaque, hwaddr offset,
uint64_t value, unsigned size)
{
CadenceUARTState *s = opaque;
DB_PRINT(" offset:%x data:%08x\n", (unsigned)offset, (unsigned)value);
offset >>= 2;
if (offset >= CADENCE_UART_R_MAX) {
return;
}
switch (offset) {
case R_IER: /* ier (wts imr) */
s->r[R_IMR] |= value;
break;
case R_IDR: /* idr (wtc imr) */
s->r[R_IMR] &= ~value;
break;
case R_IMR: /* imr (read only) */
break;
case R_CISR: /* cisr (wtc) */
s->r[R_CISR] &= ~value;
break;
case R_TX_RX: /* UARTDR */
switch (s->r[R_MR] & UART_MR_CHMODE) {
case NORMAL_MODE:
uart_write_tx_fifo(s, (uint8_t *) &value, 1);
break;
case LOCAL_LOOPBACK:
uart_write_rx_fifo(opaque, (uint8_t *) &value, 1);
break;
}
break;
default:
s->r[offset] = value;
}
switch (offset) {
case R_CR:
uart_ctrl_update(s);
break;
case R_MR:
uart_parameters_setup(s);
break;
}
uart_update_status(s);
}
static uint64_t uart_read(void *opaque, hwaddr offset,
unsigned size)
{
CadenceUARTState *s = opaque;
uint32_t c = 0;
offset >>= 2;
if (offset >= CADENCE_UART_R_MAX) {
c = 0;
} else if (offset == R_TX_RX) {
uart_read_rx_fifo(s, &c);
} else {
c = s->r[offset];
}
DB_PRINT(" offset:%x data:%08x\n", (unsigned)(offset << 2), (unsigned)c);
return c;
}
static const MemoryRegionOps uart_ops = {
.read = uart_read,
.write = uart_write,
.endianness = DEVICE_NATIVE_ENDIAN,
};
static void cadence_uart_reset(DeviceState *dev)
{
CadenceUARTState *s = CADENCE_UART(dev);
s->r[R_CR] = 0x00000128;
s->r[R_IMR] = 0;
s->r[R_CISR] = 0;
s->r[R_RTRIG] = 0x00000020;
s->r[R_BRGR] = 0x0000000F;
s->r[R_TTRIG] = 0x00000020;
uart_rx_reset(s);
uart_tx_reset(s);
uart_update_status(s);
}
static void cadence_uart_realize(DeviceState *dev, Error **errp)
{
CadenceUARTState *s = CADENCE_UART(dev);
s->fifo_trigger_handle = timer_new_ns(QEMU_CLOCK_VIRTUAL,
fifo_trigger_update, s);
/* FIXME use a qdev chardev prop instead of qemu_char_get_next_serial() */
s->chr = qemu_char_get_next_serial();
if (s->chr) {
qemu_chr_add_handlers(s->chr, uart_can_receive, uart_receive,
uart_event, s);
}
}
static void cadence_uart_init(Object *obj)
{
SysBusDevice *sbd = SYS_BUS_DEVICE(obj);
CadenceUARTState *s = CADENCE_UART(obj);
memory_region_init_io(&s->iomem, obj, &uart_ops, s, "uart", 0x1000);
sysbus_init_mmio(sbd, &s->iomem);
sysbus_init_irq(sbd, &s->irq);
s->char_tx_time = (NANOSECONDS_PER_SECOND / 9600) * 10;
}
static int cadence_uart_post_load(void *opaque, int version_id)
{
CadenceUARTState *s = opaque;
uart_parameters_setup(s);
uart_update_status(s);
return 0;
}
static const VMStateDescription vmstate_cadence_uart = {
.name = "cadence_uart",
.version_id = 2,
.minimum_version_id = 2,
.post_load = cadence_uart_post_load,
.fields = (VMStateField[]) {
VMSTATE_UINT32_ARRAY(r, CadenceUARTState, CADENCE_UART_R_MAX),
VMSTATE_UINT8_ARRAY(rx_fifo, CadenceUARTState,
CADENCE_UART_RX_FIFO_SIZE),
VMSTATE_UINT8_ARRAY(tx_fifo, CadenceUARTState,
CADENCE_UART_TX_FIFO_SIZE),
VMSTATE_UINT32(rx_count, CadenceUARTState),
VMSTATE_UINT32(tx_count, CadenceUARTState),
VMSTATE_UINT32(rx_wpos, CadenceUARTState),
VMSTATE_TIMER_PTR(fifo_trigger_handle, CadenceUARTState),
VMSTATE_END_OF_LIST()
}
};
static void cadence_uart_class_init(ObjectClass *klass, void *data)
{
DeviceClass *dc = DEVICE_CLASS(klass);
dc->realize = cadence_uart_realize;
dc->vmsd = &vmstate_cadence_uart;
dc->reset = cadence_uart_reset;
/* Reason: realize() method uses qemu_char_get_next_serial() */
dc->cannot_instantiate_with_device_add_yet = true;
}
static const TypeInfo cadence_uart_info = {
.name = TYPE_CADENCE_UART,
.parent = TYPE_SYS_BUS_DEVICE,
.instance_size = sizeof(CadenceUARTState),
.instance_init = cadence_uart_init,
.class_init = cadence_uart_class_init,
};
static void cadence_uart_register_types(void)
{
type_register_static(&cadence_uart_info);
}
type_init(cadence_uart_register_types)