xemu/tests/tco-test.c
Paulo Alcantara 5add35bec1 ich9: implement strap SPKR pin logic
If the signal is sampled high, this indicates that the system is
strapped to the "No Reboot" mode (ICH9 will disable the TCO Timer system
reboot feature). The status of this strap is readable via the NO_REBOOT
bit (CC: offset 0x3410:bit 5).

The NO_REBOOT bit is set when SPKR pin on ICH9 is sampled high. This bit
may be set or cleared by software if the strap is sampled low but may
not override the strap when it indicates "No Reboot".

This patch implements the logic where hardware has ability to set SPKR
pin through a property named "noreboot" and it's sampled high by
default.

Signed-off-by: Paulo Alcantara <pcacjr@zytor.com>
Reviewed-by: Michael S. Tsirkin <mst@redhat.com>
Signed-off-by: Michael S. Tsirkin <mst@redhat.com>
2015-07-08 10:09:55 +03:00

475 lines
12 KiB
C

/*
* QEMU ICH9 TCO emulation tests
*
* Copyright (c) 2015 Paulo Alcantara <pcacjr@zytor.com>
*
* This work is licensed under the terms of the GNU GPL, version 2 or later.
* See the COPYING file in the top-level directory.
*/
#include <glib.h>
#include <string.h>
#include <stdio.h>
#include <stdlib.h>
#include "libqtest.h"
#include "libqos/pci.h"
#include "libqos/pci-pc.h"
#include "hw/pci/pci_regs.h"
#include "hw/i386/ich9.h"
#include "hw/acpi/ich9.h"
#include "hw/acpi/tco.h"
#define RCBA_BASE_ADDR 0xfed1c000
#define PM_IO_BASE_ADDR 0xb000
enum {
TCO_RLD_DEFAULT = 0x0000,
TCO_DAT_IN_DEFAULT = 0x00,
TCO_DAT_OUT_DEFAULT = 0x00,
TCO1_STS_DEFAULT = 0x0000,
TCO2_STS_DEFAULT = 0x0000,
TCO1_CNT_DEFAULT = 0x0000,
TCO2_CNT_DEFAULT = 0x0008,
TCO_MESSAGE1_DEFAULT = 0x00,
TCO_MESSAGE2_DEFAULT = 0x00,
TCO_WDCNT_DEFAULT = 0x00,
TCO_TMR_DEFAULT = 0x0004,
SW_IRQ_GEN_DEFAULT = 0x03,
};
#define TCO_SECS_TO_TICKS(secs) (((secs) * 10) / 6)
#define TCO_TICKS_TO_SECS(ticks) (((ticks) * 6) / 10)
typedef struct {
const char *args;
bool noreboot;
QPCIDevice *dev;
void *lpc_base;
void *tco_io_base;
} TestData;
static void test_init(TestData *d)
{
QPCIBus *bus;
QTestState *qs;
char *s;
s = g_strdup_printf("-machine q35 %s %s",
d->noreboot ? "" : "-global ICH9-LPC.noreboot=false",
!d->args ? "" : d->args);
qs = qtest_start(s);
qtest_irq_intercept_in(qs, "ioapic");
g_free(s);
bus = qpci_init_pc();
d->dev = qpci_device_find(bus, QPCI_DEVFN(0x1f, 0x00));
g_assert(d->dev != NULL);
/* map PCI-to-LPC bridge interface BAR */
d->lpc_base = qpci_iomap(d->dev, 0, NULL);
qpci_device_enable(d->dev);
g_assert(d->lpc_base != NULL);
/* set ACPI PM I/O space base address */
qpci_config_writel(d->dev, (uintptr_t)d->lpc_base + ICH9_LPC_PMBASE,
PM_IO_BASE_ADDR | 0x1);
/* enable ACPI I/O */
qpci_config_writeb(d->dev, (uintptr_t)d->lpc_base + ICH9_LPC_ACPI_CTRL,
0x80);
/* set Root Complex BAR */
qpci_config_writel(d->dev, (uintptr_t)d->lpc_base + ICH9_LPC_RCBA,
RCBA_BASE_ADDR | 0x1);
d->tco_io_base = (void *)((uintptr_t)PM_IO_BASE_ADDR + 0x60);
}
static void stop_tco(const TestData *d)
{
uint32_t val;
val = qpci_io_readw(d->dev, d->tco_io_base + TCO1_CNT);
val |= TCO_TMR_HLT;
qpci_io_writew(d->dev, d->tco_io_base + TCO1_CNT, val);
}
static void start_tco(const TestData *d)
{
uint32_t val;
val = qpci_io_readw(d->dev, d->tco_io_base + TCO1_CNT);
val &= ~TCO_TMR_HLT;
qpci_io_writew(d->dev, d->tco_io_base + TCO1_CNT, val);
}
static void load_tco(const TestData *d)
{
qpci_io_writew(d->dev, d->tco_io_base + TCO_RLD, 4);
}
static void set_tco_timeout(const TestData *d, uint16_t ticks)
{
qpci_io_writew(d->dev, d->tco_io_base + TCO_TMR, ticks);
}
static void clear_tco_status(const TestData *d)
{
qpci_io_writew(d->dev, d->tco_io_base + TCO1_STS, 0x0008);
qpci_io_writew(d->dev, d->tco_io_base + TCO2_STS, 0x0002);
qpci_io_writew(d->dev, d->tco_io_base + TCO2_STS, 0x0004);
}
static void reset_on_second_timeout(bool enable)
{
uint32_t val;
val = readl(RCBA_BASE_ADDR + ICH9_CC_GCS);
if (enable) {
val &= ~ICH9_CC_GCS_NO_REBOOT;
} else {
val |= ICH9_CC_GCS_NO_REBOOT;
}
writel(RCBA_BASE_ADDR + ICH9_CC_GCS, val);
}
static void test_tco_defaults(void)
{
TestData d;
d.args = NULL;
d.noreboot = true;
test_init(&d);
g_assert_cmpint(qpci_io_readw(d.dev, d.tco_io_base + TCO_RLD), ==,
TCO_RLD_DEFAULT);
/* TCO_DAT_IN & TCO_DAT_OUT */
g_assert_cmpint(qpci_io_readw(d.dev, d.tco_io_base + TCO_DAT_IN), ==,
(TCO_DAT_OUT_DEFAULT << 8) | TCO_DAT_IN_DEFAULT);
/* TCO1_STS & TCO2_STS */
g_assert_cmpint(qpci_io_readl(d.dev, d.tco_io_base + TCO1_STS), ==,
(TCO2_STS_DEFAULT << 16) | TCO1_STS_DEFAULT);
/* TCO1_CNT & TCO2_CNT */
g_assert_cmpint(qpci_io_readl(d.dev, d.tco_io_base + TCO1_CNT), ==,
(TCO2_CNT_DEFAULT << 16) | TCO1_CNT_DEFAULT);
/* TCO_MESSAGE1 & TCO_MESSAGE2 */
g_assert_cmpint(qpci_io_readw(d.dev, d.tco_io_base + TCO_MESSAGE1), ==,
(TCO_MESSAGE2_DEFAULT << 8) | TCO_MESSAGE1_DEFAULT);
g_assert_cmpint(qpci_io_readb(d.dev, d.tco_io_base + TCO_WDCNT), ==,
TCO_WDCNT_DEFAULT);
g_assert_cmpint(qpci_io_readb(d.dev, d.tco_io_base + SW_IRQ_GEN), ==,
SW_IRQ_GEN_DEFAULT);
g_assert_cmpint(qpci_io_readw(d.dev, d.tco_io_base + TCO_TMR), ==,
TCO_TMR_DEFAULT);
qtest_end();
}
static void test_tco_timeout(void)
{
TestData d;
const uint16_t ticks = TCO_SECS_TO_TICKS(4);
uint32_t val;
int ret;
d.args = NULL;
d.noreboot = true;
test_init(&d);
stop_tco(&d);
clear_tco_status(&d);
reset_on_second_timeout(false);
set_tco_timeout(&d, ticks);
load_tco(&d);
start_tco(&d);
clock_step(ticks * TCO_TICK_NSEC);
/* test first timeout */
val = qpci_io_readw(d.dev, d.tco_io_base + TCO1_STS);
ret = val & TCO_TIMEOUT ? 1 : 0;
g_assert(ret == 1);
/* test clearing timeout bit */
val |= TCO_TIMEOUT;
qpci_io_writew(d.dev, d.tco_io_base + TCO1_STS, val);
val = qpci_io_readw(d.dev, d.tco_io_base + TCO1_STS);
ret = val & TCO_TIMEOUT ? 1 : 0;
g_assert(ret == 0);
/* test second timeout */
clock_step(ticks * TCO_TICK_NSEC);
val = qpci_io_readw(d.dev, d.tco_io_base + TCO1_STS);
ret = val & TCO_TIMEOUT ? 1 : 0;
g_assert(ret == 1);
val = qpci_io_readw(d.dev, d.tco_io_base + TCO2_STS);
ret = val & TCO_SECOND_TO_STS ? 1 : 0;
g_assert(ret == 1);
stop_tco(&d);
qtest_end();
}
static void test_tco_max_timeout(void)
{
TestData d;
const uint16_t ticks = 0xffff;
uint32_t val;
int ret;
d.args = NULL;
d.noreboot = true;
test_init(&d);
stop_tco(&d);
clear_tco_status(&d);
reset_on_second_timeout(false);
set_tco_timeout(&d, ticks);
load_tco(&d);
start_tco(&d);
clock_step(((ticks & TCO_TMR_MASK) - 1) * TCO_TICK_NSEC);
val = qpci_io_readw(d.dev, d.tco_io_base + TCO_RLD);
g_assert_cmpint(val & TCO_RLD_MASK, ==, 1);
val = qpci_io_readw(d.dev, d.tco_io_base + TCO1_STS);
ret = val & TCO_TIMEOUT ? 1 : 0;
g_assert(ret == 0);
clock_step(TCO_TICK_NSEC);
val = qpci_io_readw(d.dev, d.tco_io_base + TCO1_STS);
ret = val & TCO_TIMEOUT ? 1 : 0;
g_assert(ret == 1);
stop_tco(&d);
qtest_end();
}
static QDict *get_watchdog_action(void)
{
QDict *ev = qmp("");
QDict *data;
g_assert(!strcmp(qdict_get_str(ev, "event"), "WATCHDOG"));
data = qdict_get_qdict(ev, "data");
QINCREF(data);
QDECREF(ev);
return data;
}
static void test_tco_second_timeout_pause(void)
{
TestData td;
const uint16_t ticks = TCO_SECS_TO_TICKS(32);
QDict *ad;
td.args = "-watchdog-action pause";
td.noreboot = false;
test_init(&td);
stop_tco(&td);
clear_tco_status(&td);
reset_on_second_timeout(true);
set_tco_timeout(&td, TCO_SECS_TO_TICKS(16));
load_tco(&td);
start_tco(&td);
clock_step(ticks * TCO_TICK_NSEC * 2);
ad = get_watchdog_action();
g_assert(!strcmp(qdict_get_str(ad, "action"), "pause"));
QDECREF(ad);
stop_tco(&td);
qtest_end();
}
static void test_tco_second_timeout_reset(void)
{
TestData td;
const uint16_t ticks = TCO_SECS_TO_TICKS(16);
QDict *ad;
td.args = "-watchdog-action reset";
td.noreboot = false;
test_init(&td);
stop_tco(&td);
clear_tco_status(&td);
reset_on_second_timeout(true);
set_tco_timeout(&td, TCO_SECS_TO_TICKS(16));
load_tco(&td);
start_tco(&td);
clock_step(ticks * TCO_TICK_NSEC * 2);
ad = get_watchdog_action();
g_assert(!strcmp(qdict_get_str(ad, "action"), "reset"));
QDECREF(ad);
stop_tco(&td);
qtest_end();
}
static void test_tco_second_timeout_shutdown(void)
{
TestData td;
const uint16_t ticks = TCO_SECS_TO_TICKS(128);
QDict *ad;
td.args = "-watchdog-action shutdown";
td.noreboot = false;
test_init(&td);
stop_tco(&td);
clear_tco_status(&td);
reset_on_second_timeout(true);
set_tco_timeout(&td, ticks);
load_tco(&td);
start_tco(&td);
clock_step(ticks * TCO_TICK_NSEC * 2);
ad = get_watchdog_action();
g_assert(!strcmp(qdict_get_str(ad, "action"), "shutdown"));
QDECREF(ad);
stop_tco(&td);
qtest_end();
}
static void test_tco_second_timeout_none(void)
{
TestData td;
const uint16_t ticks = TCO_SECS_TO_TICKS(256);
QDict *ad;
td.args = "-watchdog-action none";
td.noreboot = false;
test_init(&td);
stop_tco(&td);
clear_tco_status(&td);
reset_on_second_timeout(true);
set_tco_timeout(&td, ticks);
load_tco(&td);
start_tco(&td);
clock_step(ticks * TCO_TICK_NSEC * 2);
ad = get_watchdog_action();
g_assert(!strcmp(qdict_get_str(ad, "action"), "none"));
QDECREF(ad);
stop_tco(&td);
qtest_end();
}
static void test_tco_ticks_counter(void)
{
TestData d;
uint16_t ticks = TCO_SECS_TO_TICKS(8);
uint16_t rld;
d.args = NULL;
d.noreboot = true;
test_init(&d);
stop_tco(&d);
clear_tco_status(&d);
reset_on_second_timeout(false);
set_tco_timeout(&d, ticks);
load_tco(&d);
start_tco(&d);
do {
rld = qpci_io_readw(d.dev, d.tco_io_base + TCO_RLD) & TCO_RLD_MASK;
g_assert_cmpint(rld, ==, ticks);
clock_step(TCO_TICK_NSEC);
ticks--;
} while (!(qpci_io_readw(d.dev, d.tco_io_base + TCO1_STS) & TCO_TIMEOUT));
stop_tco(&d);
qtest_end();
}
static void test_tco1_control_bits(void)
{
TestData d;
uint16_t val;
d.args = NULL;
d.noreboot = true;
test_init(&d);
val = TCO_LOCK;
qpci_io_writew(d.dev, d.tco_io_base + TCO1_CNT, val);
val &= ~TCO_LOCK;
qpci_io_writew(d.dev, d.tco_io_base + TCO1_CNT, val);
g_assert_cmpint(qpci_io_readw(d.dev, d.tco_io_base + TCO1_CNT), ==,
TCO_LOCK);
qtest_end();
}
static void test_tco1_status_bits(void)
{
TestData d;
uint16_t ticks = 8;
uint16_t val;
int ret;
d.args = NULL;
d.noreboot = true;
test_init(&d);
stop_tco(&d);
clear_tco_status(&d);
reset_on_second_timeout(false);
set_tco_timeout(&d, ticks);
load_tco(&d);
start_tco(&d);
clock_step(ticks * TCO_TICK_NSEC);
qpci_io_writeb(d.dev, d.tco_io_base + TCO_DAT_IN, 0);
qpci_io_writeb(d.dev, d.tco_io_base + TCO_DAT_OUT, 0);
val = qpci_io_readw(d.dev, d.tco_io_base + TCO1_STS);
ret = val & (TCO_TIMEOUT | SW_TCO_SMI | TCO_INT_STS) ? 1 : 0;
g_assert(ret == 1);
qpci_io_writew(d.dev, d.tco_io_base + TCO1_STS, val);
g_assert_cmpint(qpci_io_readw(d.dev, d.tco_io_base + TCO1_STS), ==, 0);
qtest_end();
}
static void test_tco2_status_bits(void)
{
TestData d;
uint16_t ticks = 8;
uint16_t val;
int ret;
d.args = NULL;
d.noreboot = true;
test_init(&d);
stop_tco(&d);
clear_tco_status(&d);
reset_on_second_timeout(true);
set_tco_timeout(&d, ticks);
load_tco(&d);
start_tco(&d);
clock_step(ticks * TCO_TICK_NSEC * 2);
val = qpci_io_readw(d.dev, d.tco_io_base + TCO2_STS);
ret = val & (TCO_SECOND_TO_STS | TCO_BOOT_STS) ? 1 : 0;
g_assert(ret == 1);
qpci_io_writew(d.dev, d.tco_io_base + TCO2_STS, val);
g_assert_cmpint(qpci_io_readw(d.dev, d.tco_io_base + TCO2_STS), ==, 0);
qtest_end();
}
int main(int argc, char **argv)
{
g_test_init(&argc, &argv, NULL);
qtest_add_func("tco/defaults", test_tco_defaults);
qtest_add_func("tco/timeout/no_action", test_tco_timeout);
qtest_add_func("tco/timeout/no_action/max", test_tco_max_timeout);
qtest_add_func("tco/second_timeout/pause", test_tco_second_timeout_pause);
qtest_add_func("tco/second_timeout/reset", test_tco_second_timeout_reset);
qtest_add_func("tco/second_timeout/shutdown",
test_tco_second_timeout_shutdown);
qtest_add_func("tco/second_timeout/none", test_tco_second_timeout_none);
qtest_add_func("tco/counter", test_tco_ticks_counter);
qtest_add_func("tco/tco1_control/bits", test_tco1_control_bits);
qtest_add_func("tco/tco1_status/bits", test_tco1_status_bits);
qtest_add_func("tco/tco2_status/bits", test_tco2_status_bits);
return g_test_run();
}