xemu/tests/qtest/npcm7xx_pwm-test.c
Peter Maydell 302585450c tests/qtest/npcm7xx_pwm-test.c: Avoid g_assert_true() for non-test assertions
In the glib API, the distinction between g_assert() and
g_assert_true() is that the former is for "bug, terminate the
application" and the latter is for "test check, on failure either
terminate or just mark the testcase as failed".  For QEMU, g_assert()
is always fatal, so code can assume that if the assertion fails
execution does not proceed, but this is not true of g_assert_true().

In npcm7xx_pwm-test, the pwm_index() and pwm_module_index() functions
include some assertions that are just guarding against possible bugs
in the test code that might lead us to out-of-bounds array accesses.
These should use g_assert() because they aren't part of what the test
is testing and the code does not correctly handle the case where the
condition was false.

This fixes some Coverity issues where Coverity knows that
g_assert_true() can continue when the condition is false and
complains about the possible array overrun at various callsites.

Fixes: Coverity CID 1442340, 1442341, 1442343, 1442344, 1442345, 1442346
Signed-off-by: Peter Maydell <peter.maydell@linaro.org>
Reviewed-by: Thomas Huth <thuth@redhat.com>
Reviewed-by: Hao Wu <wuhaotsh@google.com>
Reviewed-by: Havard Skinnemoen <hskinnemoen@google.com>
Message-Id: <20210505135516.21097-1-peter.maydell@linaro.org>
Signed-off-by: Thomas Huth <thuth@redhat.com>
2021-05-14 12:28:01 +02:00

687 lines
19 KiB
C

/*
* QTests for Nuvoton NPCM7xx PWM Modules.
*
* Copyright 2020 Google LLC
*
* 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.
*
* This program is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* for more details.
*/
#include "qemu/osdep.h"
#include "qemu/bitops.h"
#include "libqos/libqtest.h"
#include "qapi/qmp/qdict.h"
#include "qapi/qmp/qnum.h"
#define REF_HZ 25000000
/* Register field definitions. */
#define CH_EN BIT(0)
#define CH_INV BIT(2)
#define CH_MOD BIT(3)
/* Registers shared between all PWMs in a module */
#define PPR 0x00
#define CSR 0x04
#define PCR 0x08
#define PIER 0x3c
#define PIIR 0x40
/* CLK module related */
#define CLK_BA 0xf0801000
#define CLKSEL 0x04
#define CLKDIV1 0x08
#define CLKDIV2 0x2c
#define PLLCON0 0x0c
#define PLLCON1 0x10
#define PLL_INDV(rv) extract32((rv), 0, 6)
#define PLL_FBDV(rv) extract32((rv), 16, 12)
#define PLL_OTDV1(rv) extract32((rv), 8, 3)
#define PLL_OTDV2(rv) extract32((rv), 13, 3)
#define APB4CKDIV(rv) extract32((rv), 30, 2)
#define APB3CKDIV(rv) extract32((rv), 28, 2)
#define CLK2CKDIV(rv) extract32((rv), 0, 1)
#define CLK4CKDIV(rv) extract32((rv), 26, 2)
#define CPUCKSEL(rv) extract32((rv), 0, 2)
#define MAX_DUTY 1000000
/* MFT (PWM fan) related */
#define MFT_BA(n) (0xf0180000 + ((n) * 0x1000))
#define MFT_IRQ(n) (96 + (n))
#define MFT_CNT1 0x00
#define MFT_CRA 0x02
#define MFT_CRB 0x04
#define MFT_CNT2 0x06
#define MFT_PRSC 0x08
#define MFT_CKC 0x0a
#define MFT_MCTRL 0x0c
#define MFT_ICTRL 0x0e
#define MFT_ICLR 0x10
#define MFT_IEN 0x12
#define MFT_CPA 0x14
#define MFT_CPB 0x16
#define MFT_CPCFG 0x18
#define MFT_INASEL 0x1a
#define MFT_INBSEL 0x1c
#define MFT_MCTRL_ALL 0x64
#define MFT_ICLR_ALL 0x3f
#define MFT_IEN_ALL 0x3f
#define MFT_CPCFG_EQ_MODE 0x44
#define MFT_CKC_C2CSEL BIT(3)
#define MFT_CKC_C1CSEL BIT(0)
#define MFT_ICTRL_TFPND BIT(5)
#define MFT_ICTRL_TEPND BIT(4)
#define MFT_ICTRL_TDPND BIT(3)
#define MFT_ICTRL_TCPND BIT(2)
#define MFT_ICTRL_TBPND BIT(1)
#define MFT_ICTRL_TAPND BIT(0)
#define MFT_MAX_CNT 0xffff
#define MFT_TIMEOUT 0x5000
#define DEFAULT_RPM 19800
#define DEFAULT_PRSC 255
#define MFT_PULSE_PER_REVOLUTION 2
#define MAX_ERROR 1
typedef struct PWMModule {
int irq;
uint64_t base_addr;
} PWMModule;
typedef struct PWM {
uint32_t cnr_offset;
uint32_t cmr_offset;
uint32_t pdr_offset;
uint32_t pwdr_offset;
} PWM;
typedef struct TestData {
const PWMModule *module;
const PWM *pwm;
} TestData;
static const PWMModule pwm_module_list[] = {
{
.irq = 93,
.base_addr = 0xf0103000
},
{
.irq = 94,
.base_addr = 0xf0104000
}
};
static const PWM pwm_list[] = {
{
.cnr_offset = 0x0c,
.cmr_offset = 0x10,
.pdr_offset = 0x14,
.pwdr_offset = 0x44,
},
{
.cnr_offset = 0x18,
.cmr_offset = 0x1c,
.pdr_offset = 0x20,
.pwdr_offset = 0x48,
},
{
.cnr_offset = 0x24,
.cmr_offset = 0x28,
.pdr_offset = 0x2c,
.pwdr_offset = 0x4c,
},
{
.cnr_offset = 0x30,
.cmr_offset = 0x34,
.pdr_offset = 0x38,
.pwdr_offset = 0x50,
},
};
static const int ppr_base[] = { 0, 0, 8, 8 };
static const int csr_base[] = { 0, 4, 8, 12 };
static const int pcr_base[] = { 0, 8, 12, 16 };
static const uint32_t ppr_list[] = {
0,
1,
10,
100,
255, /* Max possible value. */
};
static const uint32_t csr_list[] = {
0,
1,
2,
3,
4, /* Max possible value. */
};
static const uint32_t cnr_list[] = {
0,
1,
50,
100,
150,
200,
1000,
10000,
65535, /* Max possible value. */
};
static const uint32_t cmr_list[] = {
0,
1,
10,
50,
100,
150,
200,
1000,
10000,
65535, /* Max possible value. */
};
/* Returns the index of the PWM module. */
static int pwm_module_index(const PWMModule *module)
{
ptrdiff_t diff = module - pwm_module_list;
g_assert(diff >= 0 && diff < ARRAY_SIZE(pwm_module_list));
return diff;
}
/* Returns the index of the PWM entry. */
static int pwm_index(const PWM *pwm)
{
ptrdiff_t diff = pwm - pwm_list;
g_assert(diff >= 0 && diff < ARRAY_SIZE(pwm_list));
return diff;
}
static uint64_t pwm_qom_get(QTestState *qts, const char *path, const char *name)
{
QDict *response;
uint64_t val;
g_test_message("Getting properties %s from %s", name, path);
response = qtest_qmp(qts, "{ 'execute': 'qom-get',"
" 'arguments': { 'path': %s, 'property': %s}}",
path, name);
/* The qom set message returns successfully. */
g_assert_true(qdict_haskey(response, "return"));
val = qnum_get_uint(qobject_to(QNum, qdict_get(response, "return")));
qobject_unref(response);
return val;
}
static uint64_t pwm_get_freq(QTestState *qts, int module_index, int pwm_index)
{
char path[100];
char name[100];
sprintf(path, "/machine/soc/pwm[%d]", module_index);
sprintf(name, "freq[%d]", pwm_index);
return pwm_qom_get(qts, path, name);
}
static uint64_t pwm_get_duty(QTestState *qts, int module_index, int pwm_index)
{
char path[100];
char name[100];
sprintf(path, "/machine/soc/pwm[%d]", module_index);
sprintf(name, "duty[%d]", pwm_index);
return pwm_qom_get(qts, path, name);
}
static void mft_qom_set(QTestState *qts, int index, const char *name,
uint32_t value)
{
QDict *response;
char *path = g_strdup_printf("/machine/soc/mft[%d]", index);
g_test_message("Setting properties %s of mft[%d] with value %u",
name, index, value);
response = qtest_qmp(qts, "{ 'execute': 'qom-set',"
" 'arguments': { 'path': %s, "
" 'property': %s, 'value': %u}}",
path, name, value);
/* The qom set message returns successfully. */
g_assert_true(qdict_haskey(response, "return"));
}
static uint32_t get_pll(uint32_t con)
{
return REF_HZ * PLL_FBDV(con) / (PLL_INDV(con) * PLL_OTDV1(con)
* PLL_OTDV2(con));
}
static uint64_t read_pclk(QTestState *qts, bool mft)
{
uint64_t freq = REF_HZ;
uint32_t clksel = qtest_readl(qts, CLK_BA + CLKSEL);
uint32_t pllcon;
uint32_t clkdiv1 = qtest_readl(qts, CLK_BA + CLKDIV1);
uint32_t clkdiv2 = qtest_readl(qts, CLK_BA + CLKDIV2);
uint32_t apbdiv = mft ? APB4CKDIV(clkdiv2) : APB3CKDIV(clkdiv2);
switch (CPUCKSEL(clksel)) {
case 0:
pllcon = qtest_readl(qts, CLK_BA + PLLCON0);
freq = get_pll(pllcon);
break;
case 1:
pllcon = qtest_readl(qts, CLK_BA + PLLCON1);
freq = get_pll(pllcon);
break;
case 2:
break;
case 3:
break;
default:
g_assert_not_reached();
}
freq >>= (CLK2CKDIV(clkdiv1) + CLK4CKDIV(clkdiv1) + apbdiv);
return freq;
}
static uint32_t pwm_selector(uint32_t csr)
{
switch (csr) {
case 0:
return 2;
case 1:
return 4;
case 2:
return 8;
case 3:
return 16;
case 4:
return 1;
default:
g_assert_not_reached();
}
}
static uint64_t pwm_compute_freq(QTestState *qts, uint32_t ppr, uint32_t csr,
uint32_t cnr)
{
return read_pclk(qts, false) / ((ppr + 1) * pwm_selector(csr) * (cnr + 1));
}
static uint64_t pwm_compute_duty(uint32_t cnr, uint32_t cmr, bool inverted)
{
uint32_t duty;
if (cnr == 0) {
/* PWM is stopped. */
duty = 0;
} else if (cmr >= cnr) {
duty = MAX_DUTY;
} else {
duty = (uint64_t)MAX_DUTY * (cmr + 1) / (cnr + 1);
}
if (inverted) {
duty = MAX_DUTY - duty;
}
return duty;
}
static uint32_t pwm_read(QTestState *qts, const TestData *td, unsigned offset)
{
return qtest_readl(qts, td->module->base_addr + offset);
}
static void pwm_write(QTestState *qts, const TestData *td, unsigned offset,
uint32_t value)
{
qtest_writel(qts, td->module->base_addr + offset, value);
}
static uint8_t mft_readb(QTestState *qts, int index, unsigned offset)
{
return qtest_readb(qts, MFT_BA(index) + offset);
}
static uint16_t mft_readw(QTestState *qts, int index, unsigned offset)
{
return qtest_readw(qts, MFT_BA(index) + offset);
}
static void mft_writeb(QTestState *qts, int index, unsigned offset,
uint8_t value)
{
qtest_writeb(qts, MFT_BA(index) + offset, value);
}
static void mft_writew(QTestState *qts, int index, unsigned offset,
uint16_t value)
{
return qtest_writew(qts, MFT_BA(index) + offset, value);
}
static uint32_t pwm_read_ppr(QTestState *qts, const TestData *td)
{
return extract32(pwm_read(qts, td, PPR), ppr_base[pwm_index(td->pwm)], 8);
}
static void pwm_write_ppr(QTestState *qts, const TestData *td, uint32_t value)
{
pwm_write(qts, td, PPR, value << ppr_base[pwm_index(td->pwm)]);
}
static uint32_t pwm_read_csr(QTestState *qts, const TestData *td)
{
return extract32(pwm_read(qts, td, CSR), csr_base[pwm_index(td->pwm)], 3);
}
static void pwm_write_csr(QTestState *qts, const TestData *td, uint32_t value)
{
pwm_write(qts, td, CSR, value << csr_base[pwm_index(td->pwm)]);
}
static uint32_t pwm_read_pcr(QTestState *qts, const TestData *td)
{
return extract32(pwm_read(qts, td, PCR), pcr_base[pwm_index(td->pwm)], 4);
}
static void pwm_write_pcr(QTestState *qts, const TestData *td, uint32_t value)
{
pwm_write(qts, td, PCR, value << pcr_base[pwm_index(td->pwm)]);
}
static uint32_t pwm_read_cnr(QTestState *qts, const TestData *td)
{
return pwm_read(qts, td, td->pwm->cnr_offset);
}
static void pwm_write_cnr(QTestState *qts, const TestData *td, uint32_t value)
{
pwm_write(qts, td, td->pwm->cnr_offset, value);
}
static uint32_t pwm_read_cmr(QTestState *qts, const TestData *td)
{
return pwm_read(qts, td, td->pwm->cmr_offset);
}
static void pwm_write_cmr(QTestState *qts, const TestData *td, uint32_t value)
{
pwm_write(qts, td, td->pwm->cmr_offset, value);
}
static int mft_compute_index(const TestData *td)
{
int index = pwm_module_index(td->module) * ARRAY_SIZE(pwm_list) +
pwm_index(td->pwm);
g_assert_cmpint(index, <,
ARRAY_SIZE(pwm_module_list) * ARRAY_SIZE(pwm_list));
return index;
}
static void mft_reset_counters(QTestState *qts, int index)
{
mft_writew(qts, index, MFT_CNT1, MFT_MAX_CNT);
mft_writew(qts, index, MFT_CNT2, MFT_MAX_CNT);
mft_writew(qts, index, MFT_CRA, MFT_MAX_CNT);
mft_writew(qts, index, MFT_CRB, MFT_MAX_CNT);
mft_writew(qts, index, MFT_CPA, MFT_MAX_CNT - MFT_TIMEOUT);
mft_writew(qts, index, MFT_CPB, MFT_MAX_CNT - MFT_TIMEOUT);
}
static void mft_init(QTestState *qts, const TestData *td)
{
int index = mft_compute_index(td);
/* Enable everything */
mft_writeb(qts, index, MFT_CKC, 0);
mft_writeb(qts, index, MFT_ICLR, MFT_ICLR_ALL);
mft_writeb(qts, index, MFT_MCTRL, MFT_MCTRL_ALL);
mft_writeb(qts, index, MFT_IEN, MFT_IEN_ALL);
mft_writeb(qts, index, MFT_INASEL, 0);
mft_writeb(qts, index, MFT_INBSEL, 0);
/* Set cpcfg to use EQ mode, same as kernel driver */
mft_writeb(qts, index, MFT_CPCFG, MFT_CPCFG_EQ_MODE);
/* Write default counters, timeout and prescaler */
mft_reset_counters(qts, index);
mft_writeb(qts, index, MFT_PRSC, DEFAULT_PRSC);
/* Write default max rpm via QMP */
mft_qom_set(qts, index, "max_rpm[0]", DEFAULT_RPM);
mft_qom_set(qts, index, "max_rpm[1]", DEFAULT_RPM);
}
static int32_t mft_compute_cnt(uint32_t rpm, uint64_t clk)
{
uint64_t cnt;
if (rpm == 0) {
return -1;
}
cnt = clk * 60 / ((DEFAULT_PRSC + 1) * rpm * MFT_PULSE_PER_REVOLUTION);
if (cnt >= MFT_TIMEOUT) {
return -1;
}
return MFT_MAX_CNT - cnt;
}
static void mft_verify_rpm(QTestState *qts, const TestData *td, uint64_t duty)
{
int index = mft_compute_index(td);
uint16_t cnt, cr;
uint32_t rpm = DEFAULT_RPM * duty / MAX_DUTY;
uint64_t clk = read_pclk(qts, true);
int32_t expected_cnt = mft_compute_cnt(rpm, clk);
qtest_irq_intercept_in(qts, "/machine/soc/a9mpcore/gic");
g_test_message(
"verifying rpm for mft[%d]: clk: %" PRIu64 ", duty: %" PRIu64 ", rpm: %u, cnt: %d",
index, clk, duty, rpm, expected_cnt);
/* Verify rpm for fan A */
/* Stop capture */
mft_writeb(qts, index, MFT_CKC, 0);
mft_writeb(qts, index, MFT_ICLR, MFT_ICLR_ALL);
mft_reset_counters(qts, index);
g_assert_cmphex(mft_readw(qts, index, MFT_CNT1), ==, MFT_MAX_CNT);
g_assert_cmphex(mft_readw(qts, index, MFT_CRA), ==, MFT_MAX_CNT);
g_assert_cmphex(mft_readw(qts, index, MFT_CPA), ==,
MFT_MAX_CNT - MFT_TIMEOUT);
/* Start capture */
mft_writeb(qts, index, MFT_CKC, MFT_CKC_C1CSEL);
g_assert_true(qtest_get_irq(qts, MFT_IRQ(index)));
if (expected_cnt == -1) {
g_assert_cmphex(mft_readb(qts, index, MFT_ICTRL), ==, MFT_ICTRL_TEPND);
} else {
g_assert_cmphex(mft_readb(qts, index, MFT_ICTRL), ==, MFT_ICTRL_TAPND);
cnt = mft_readw(qts, index, MFT_CNT1);
/*
* Due to error in clock measurement and rounding, we might have a small
* error in measuring RPM.
*/
g_assert_cmphex(cnt + MAX_ERROR, >=, expected_cnt);
g_assert_cmphex(cnt, <=, expected_cnt + MAX_ERROR);
cr = mft_readw(qts, index, MFT_CRA);
g_assert_cmphex(cnt, ==, cr);
}
/* Verify rpm for fan B */
qtest_irq_intercept_out(qts, "/machine/soc/a9mpcore/gic");
}
/* Check pwm registers can be reset to default value */
static void test_init(gconstpointer test_data)
{
const TestData *td = test_data;
QTestState *qts = qtest_init("-machine npcm750-evb");
int module = pwm_module_index(td->module);
int pwm = pwm_index(td->pwm);
g_assert_cmpuint(pwm_get_freq(qts, module, pwm), ==, 0);
g_assert_cmpuint(pwm_get_duty(qts, module, pwm), ==, 0);
qtest_quit(qts);
}
/* One-shot mode should not change frequency and duty cycle. */
static void test_oneshot(gconstpointer test_data)
{
const TestData *td = test_data;
QTestState *qts = qtest_init("-machine npcm750-evb");
int module = pwm_module_index(td->module);
int pwm = pwm_index(td->pwm);
uint32_t ppr, csr, pcr;
int i, j;
pcr = CH_EN;
for (i = 0; i < ARRAY_SIZE(ppr_list); ++i) {
ppr = ppr_list[i];
pwm_write_ppr(qts, td, ppr);
for (j = 0; j < ARRAY_SIZE(csr_list); ++j) {
csr = csr_list[j];
pwm_write_csr(qts, td, csr);
pwm_write_pcr(qts, td, pcr);
g_assert_cmpuint(pwm_read_ppr(qts, td), ==, ppr);
g_assert_cmpuint(pwm_read_csr(qts, td), ==, csr);
g_assert_cmpuint(pwm_read_pcr(qts, td), ==, pcr);
g_assert_cmpuint(pwm_get_freq(qts, module, pwm), ==, 0);
g_assert_cmpuint(pwm_get_duty(qts, module, pwm), ==, 0);
}
}
qtest_quit(qts);
}
/* In toggle mode, the PWM generates correct outputs. */
static void test_toggle(gconstpointer test_data)
{
const TestData *td = test_data;
QTestState *qts = qtest_init("-machine npcm750-evb");
int module = pwm_module_index(td->module);
int pwm = pwm_index(td->pwm);
uint32_t ppr, csr, pcr, cnr, cmr;
int i, j, k, l;
uint64_t expected_freq, expected_duty;
mft_init(qts, td);
pcr = CH_EN | CH_MOD;
for (i = 0; i < ARRAY_SIZE(ppr_list); ++i) {
ppr = ppr_list[i];
pwm_write_ppr(qts, td, ppr);
for (j = 0; j < ARRAY_SIZE(csr_list); ++j) {
csr = csr_list[j];
pwm_write_csr(qts, td, csr);
for (k = 0; k < ARRAY_SIZE(cnr_list); ++k) {
cnr = cnr_list[k];
pwm_write_cnr(qts, td, cnr);
for (l = 0; l < ARRAY_SIZE(cmr_list); ++l) {
cmr = cmr_list[l];
pwm_write_cmr(qts, td, cmr);
expected_freq = pwm_compute_freq(qts, ppr, csr, cnr);
expected_duty = pwm_compute_duty(cnr, cmr, false);
pwm_write_pcr(qts, td, pcr);
g_assert_cmpuint(pwm_read_ppr(qts, td), ==, ppr);
g_assert_cmpuint(pwm_read_csr(qts, td), ==, csr);
g_assert_cmpuint(pwm_read_pcr(qts, td), ==, pcr);
g_assert_cmpuint(pwm_read_cnr(qts, td), ==, cnr);
g_assert_cmpuint(pwm_read_cmr(qts, td), ==, cmr);
g_assert_cmpuint(pwm_get_duty(qts, module, pwm),
==, expected_duty);
if (expected_duty != 0 && expected_duty != 100) {
/* Duty cycle with 0 or 100 doesn't need frequency. */
g_assert_cmpuint(pwm_get_freq(qts, module, pwm),
==, expected_freq);
}
/* Test MFT's RPM is correct. */
mft_verify_rpm(qts, td, expected_duty);
/* Test inverted mode */
expected_duty = pwm_compute_duty(cnr, cmr, true);
pwm_write_pcr(qts, td, pcr | CH_INV);
g_assert_cmpuint(pwm_read_pcr(qts, td), ==, pcr | CH_INV);
g_assert_cmpuint(pwm_get_duty(qts, module, pwm),
==, expected_duty);
if (expected_duty != 0 && expected_duty != 100) {
/* Duty cycle with 0 or 100 doesn't need frequency. */
g_assert_cmpuint(pwm_get_freq(qts, module, pwm),
==, expected_freq);
}
}
}
}
}
qtest_quit(qts);
}
static void pwm_add_test(const char *name, const TestData* td,
GTestDataFunc fn)
{
g_autofree char *full_name = g_strdup_printf(
"npcm7xx_pwm/module[%d]/pwm[%d]/%s", pwm_module_index(td->module),
pwm_index(td->pwm), name);
qtest_add_data_func(full_name, td, fn);
}
#define add_test(name, td) pwm_add_test(#name, td, test_##name)
int main(int argc, char **argv)
{
TestData test_data_list[ARRAY_SIZE(pwm_module_list) * ARRAY_SIZE(pwm_list)];
g_test_init(&argc, &argv, NULL);
for (int i = 0; i < ARRAY_SIZE(pwm_module_list); ++i) {
for (int j = 0; j < ARRAY_SIZE(pwm_list); ++j) {
TestData *td = &test_data_list[i * ARRAY_SIZE(pwm_list) + j];
td->module = &pwm_module_list[i];
td->pwm = &pwm_list[j];
add_test(init, td);
add_test(oneshot, td);
add_test(toggle, td);
}
}
return g_test_run();
}