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f369797617
According to the glib function requirements, we need initialise the variable. Otherwise there will be compilation warnings: glib-autocleanups.h:28:3: warning: ‘full_name’ may be used uninitialized in this function [-Wmaybe-uninitialized] 28 | g_free (*pp); | ^~~~~~~~~~~~ Reported-by: Euler Robot <euler.robot@huawei.com> Signed-off-by: Chen Qun <kuhn.chenqun@huawei.com> Reviewed-by: Thomas Huth <thuth@redhat.com> Reviewed-by: Havard Skinnemoen <hskinnemoen@google.com> Message-Id: <20201118115646.2461726-2-kuhn.chenqun@huawei.com> Signed-off-by: Thomas Huth <thuth@redhat.com>
561 lines
17 KiB
C
561 lines
17 KiB
C
/*
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* QTest testcase for the Nuvoton NPCM7xx Timer
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*
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* Copyright 2020 Google LLC
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*
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* This program is free software; you can redistribute it and/or modify it
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* under the terms of the GNU General Public License as published by the
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* Free Software Foundation; either version 2 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful, but WITHOUT
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* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
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* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
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* for more details.
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*/
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#include "qemu/osdep.h"
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#include "qemu/timer.h"
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#include "libqtest-single.h"
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#define TIM_REF_HZ (25000000)
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/* Bits in TCSRx */
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#define CEN BIT(30)
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#define IE BIT(29)
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#define MODE_ONESHOT (0 << 27)
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#define MODE_PERIODIC (1 << 27)
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#define CRST BIT(26)
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#define CACT BIT(25)
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#define PRESCALE(x) (x)
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/* Registers shared between all timers in a module. */
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#define TISR 0x18
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#define WTCR 0x1c
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# define WTCLK(x) ((x) << 10)
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/* Power-on default; used to re-initialize timers before each test. */
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#define TCSR_DEFAULT PRESCALE(5)
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/* Register offsets for a timer within a timer block. */
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typedef struct Timer {
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unsigned int tcsr_offset;
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unsigned int ticr_offset;
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unsigned int tdr_offset;
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} Timer;
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/* A timer block containing 5 timers. */
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typedef struct TimerBlock {
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int irq_base;
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uint64_t base_addr;
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} TimerBlock;
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/* Testdata for testing a particular timer within a timer block. */
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typedef struct TestData {
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const TimerBlock *tim;
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const Timer *timer;
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} TestData;
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const TimerBlock timer_block[] = {
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{
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.irq_base = 32,
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.base_addr = 0xf0008000,
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},
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{
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.irq_base = 37,
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.base_addr = 0xf0009000,
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},
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{
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.irq_base = 42,
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.base_addr = 0xf000a000,
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},
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};
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const Timer timer[] = {
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{
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.tcsr_offset = 0x00,
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.ticr_offset = 0x08,
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.tdr_offset = 0x10,
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}, {
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.tcsr_offset = 0x04,
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.ticr_offset = 0x0c,
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.tdr_offset = 0x14,
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}, {
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.tcsr_offset = 0x20,
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.ticr_offset = 0x28,
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.tdr_offset = 0x30,
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}, {
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.tcsr_offset = 0x24,
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.ticr_offset = 0x2c,
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.tdr_offset = 0x34,
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}, {
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.tcsr_offset = 0x40,
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.ticr_offset = 0x48,
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.tdr_offset = 0x50,
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},
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};
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/* Returns the index of the timer block. */
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static int tim_index(const TimerBlock *tim)
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{
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ptrdiff_t diff = tim - timer_block;
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g_assert(diff >= 0 && diff < ARRAY_SIZE(timer_block));
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return diff;
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}
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/* Returns the index of a timer within a timer block. */
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static int timer_index(const Timer *t)
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{
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ptrdiff_t diff = t - timer;
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g_assert(diff >= 0 && diff < ARRAY_SIZE(timer));
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return diff;
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}
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/* Returns the irq line for a given timer. */
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static int tim_timer_irq(const TestData *td)
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{
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return td->tim->irq_base + timer_index(td->timer);
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}
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/* Register read/write accessors. */
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static void tim_write(const TestData *td,
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unsigned int offset, uint32_t value)
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{
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writel(td->tim->base_addr + offset, value);
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}
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static uint32_t tim_read(const TestData *td, unsigned int offset)
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{
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return readl(td->tim->base_addr + offset);
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}
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static void tim_write_tcsr(const TestData *td, uint32_t value)
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{
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tim_write(td, td->timer->tcsr_offset, value);
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}
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static uint32_t tim_read_tcsr(const TestData *td)
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{
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return tim_read(td, td->timer->tcsr_offset);
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}
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static void tim_write_ticr(const TestData *td, uint32_t value)
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{
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tim_write(td, td->timer->ticr_offset, value);
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}
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static uint32_t tim_read_ticr(const TestData *td)
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{
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return tim_read(td, td->timer->ticr_offset);
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}
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static uint32_t tim_read_tdr(const TestData *td)
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{
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return tim_read(td, td->timer->tdr_offset);
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}
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/* Returns the number of nanoseconds to count the given number of cycles. */
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static int64_t tim_calculate_step(uint32_t count, uint32_t prescale)
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{
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return (1000000000LL / TIM_REF_HZ) * count * (prescale + 1);
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}
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/* Returns a bitmask corresponding to the timer under test. */
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static uint32_t tim_timer_bit(const TestData *td)
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{
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return BIT(timer_index(td->timer));
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}
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/* Resets all timers to power-on defaults. */
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static void tim_reset(const TestData *td)
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{
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int i, j;
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/* Reset all the timers, in case a previous test left a timer running. */
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for (i = 0; i < ARRAY_SIZE(timer_block); i++) {
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for (j = 0; j < ARRAY_SIZE(timer); j++) {
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writel(timer_block[i].base_addr + timer[j].tcsr_offset,
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CRST | TCSR_DEFAULT);
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}
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writel(timer_block[i].base_addr + TISR, -1);
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}
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}
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/* Verifies the reset state of a timer. */
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static void test_reset(gconstpointer test_data)
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{
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const TestData *td = test_data;
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tim_reset(td);
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g_assert_cmphex(tim_read_tcsr(td), ==, TCSR_DEFAULT);
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g_assert_cmphex(tim_read_ticr(td), ==, 0);
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g_assert_cmphex(tim_read_tdr(td), ==, 0);
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g_assert_cmphex(tim_read(td, TISR), ==, 0);
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g_assert_cmphex(tim_read(td, WTCR), ==, WTCLK(1));
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}
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/* Verifies that CRST wins if both CEN and CRST are set. */
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static void test_reset_overrides_enable(gconstpointer test_data)
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{
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const TestData *td = test_data;
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tim_reset(td);
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/* CRST should force CEN to 0 */
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tim_write_tcsr(td, CEN | CRST | TCSR_DEFAULT);
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g_assert_cmphex(tim_read_tcsr(td), ==, TCSR_DEFAULT);
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g_assert_cmphex(tim_read_tdr(td), ==, 0);
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g_assert_cmphex(tim_read(td, TISR), ==, 0);
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}
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/* Verifies the behavior when CEN is set and then cleared. */
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static void test_oneshot_enable_then_disable(gconstpointer test_data)
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{
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const TestData *td = test_data;
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tim_reset(td);
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/* Enable the timer with zero initial count, then disable it again. */
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tim_write_tcsr(td, CEN | TCSR_DEFAULT);
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tim_write_tcsr(td, TCSR_DEFAULT);
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g_assert_cmphex(tim_read_tcsr(td), ==, TCSR_DEFAULT);
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g_assert_cmphex(tim_read_tdr(td), ==, 0);
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/* Timer interrupt flag should be set, but interrupts are not enabled. */
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g_assert_cmphex(tim_read(td, TISR), ==, tim_timer_bit(td));
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g_assert_false(qtest_get_irq(global_qtest, tim_timer_irq(td)));
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}
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/* Verifies that a one-shot timer fires when expected with prescaler 5. */
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static void test_oneshot_ps5(gconstpointer test_data)
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{
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const TestData *td = test_data;
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unsigned int count = 256;
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unsigned int ps = 5;
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tim_reset(td);
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tim_write_ticr(td, count);
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tim_write_tcsr(td, CEN | PRESCALE(ps));
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g_assert_cmphex(tim_read_tcsr(td), ==, CEN | CACT | PRESCALE(ps));
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g_assert_cmpuint(tim_read_tdr(td), ==, count);
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clock_step(tim_calculate_step(count, ps) - 1);
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g_assert_cmphex(tim_read_tcsr(td), ==, CEN | CACT | PRESCALE(ps));
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g_assert_cmpuint(tim_read_tdr(td), <, count);
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g_assert_cmphex(tim_read(td, TISR), ==, 0);
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clock_step(1);
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g_assert_cmphex(tim_read_tcsr(td), ==, PRESCALE(ps));
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g_assert_cmpuint(tim_read_tdr(td), ==, count);
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g_assert_cmphex(tim_read(td, TISR), ==, tim_timer_bit(td));
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g_assert_false(qtest_get_irq(global_qtest, tim_timer_irq(td)));
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/* Clear the interrupt flag. */
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tim_write(td, TISR, tim_timer_bit(td));
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g_assert_cmphex(tim_read(td, TISR), ==, 0);
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g_assert_false(qtest_get_irq(global_qtest, tim_timer_irq(td)));
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/* Verify that this isn't a periodic timer. */
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clock_step(2 * tim_calculate_step(count, ps));
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g_assert_cmphex(tim_read(td, TISR), ==, 0);
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g_assert_false(qtest_get_irq(global_qtest, tim_timer_irq(td)));
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}
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/* Verifies that a one-shot timer fires when expected with prescaler 0. */
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static void test_oneshot_ps0(gconstpointer test_data)
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{
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const TestData *td = test_data;
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unsigned int count = 1;
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unsigned int ps = 0;
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tim_reset(td);
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tim_write_ticr(td, count);
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tim_write_tcsr(td, CEN | PRESCALE(ps));
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g_assert_cmphex(tim_read_tcsr(td), ==, CEN | CACT | PRESCALE(ps));
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g_assert_cmpuint(tim_read_tdr(td), ==, count);
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clock_step(tim_calculate_step(count, ps) - 1);
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g_assert_cmphex(tim_read_tcsr(td), ==, CEN | CACT | PRESCALE(ps));
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g_assert_cmpuint(tim_read_tdr(td), <, count);
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g_assert_cmphex(tim_read(td, TISR), ==, 0);
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clock_step(1);
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g_assert_cmphex(tim_read_tcsr(td), ==, PRESCALE(ps));
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g_assert_cmpuint(tim_read_tdr(td), ==, count);
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g_assert_cmphex(tim_read(td, TISR), ==, tim_timer_bit(td));
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g_assert_false(qtest_get_irq(global_qtest, tim_timer_irq(td)));
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}
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/* Verifies that a one-shot timer fires when expected with highest prescaler. */
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static void test_oneshot_ps255(gconstpointer test_data)
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{
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const TestData *td = test_data;
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unsigned int count = (1U << 24) - 1;
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unsigned int ps = 255;
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tim_reset(td);
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tim_write_ticr(td, count);
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tim_write_tcsr(td, CEN | PRESCALE(ps));
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g_assert_cmphex(tim_read_tcsr(td), ==, CEN | CACT | PRESCALE(ps));
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g_assert_cmpuint(tim_read_tdr(td), ==, count);
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clock_step(tim_calculate_step(count, ps) - 1);
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g_assert_cmphex(tim_read_tcsr(td), ==, CEN | CACT | PRESCALE(ps));
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g_assert_cmpuint(tim_read_tdr(td), <, count);
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g_assert_cmphex(tim_read(td, TISR), ==, 0);
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clock_step(1);
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g_assert_cmphex(tim_read_tcsr(td), ==, PRESCALE(ps));
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g_assert_cmpuint(tim_read_tdr(td), ==, count);
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g_assert_cmphex(tim_read(td, TISR), ==, tim_timer_bit(td));
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g_assert_false(qtest_get_irq(global_qtest, tim_timer_irq(td)));
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}
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/* Verifies that a oneshot timer fires an interrupt when expected. */
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static void test_oneshot_interrupt(gconstpointer test_data)
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{
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const TestData *td = test_data;
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unsigned int count = 256;
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unsigned int ps = 7;
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tim_reset(td);
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tim_write_ticr(td, count);
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tim_write_tcsr(td, IE | CEN | MODE_ONESHOT | PRESCALE(ps));
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clock_step_next();
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g_assert_cmphex(tim_read(td, TISR), ==, tim_timer_bit(td));
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g_assert_true(qtest_get_irq(global_qtest, tim_timer_irq(td)));
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}
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/*
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* Verifies that the timer can be paused and later resumed, and it still fires
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* at the right moment.
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*/
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static void test_pause_resume(gconstpointer test_data)
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{
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const TestData *td = test_data;
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unsigned int count = 256;
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unsigned int ps = 1;
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tim_reset(td);
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tim_write_ticr(td, count);
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tim_write_tcsr(td, IE | CEN | MODE_ONESHOT | PRESCALE(ps));
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/* Pause the timer halfway to expiration. */
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clock_step(tim_calculate_step(count / 2, ps));
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tim_write_tcsr(td, IE | MODE_ONESHOT | PRESCALE(ps));
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g_assert_cmpuint(tim_read_tdr(td), ==, count / 2);
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/* Counter should not advance during the following step. */
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clock_step(2 * tim_calculate_step(count, ps));
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g_assert_cmpuint(tim_read_tdr(td), ==, count / 2);
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g_assert_cmphex(tim_read(td, TISR), ==, 0);
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g_assert_false(qtest_get_irq(global_qtest, tim_timer_irq(td)));
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/* Resume the timer and run _almost_ to expiration. */
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tim_write_tcsr(td, IE | CEN | MODE_ONESHOT | PRESCALE(ps));
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clock_step(tim_calculate_step(count / 2, ps) - 1);
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g_assert_cmpuint(tim_read_tdr(td), <, count);
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g_assert_cmphex(tim_read(td, TISR), ==, 0);
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g_assert_false(qtest_get_irq(global_qtest, tim_timer_irq(td)));
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/* Now, run the rest of the way and verify that the interrupt fires. */
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clock_step(1);
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g_assert_cmphex(tim_read(td, TISR), ==, tim_timer_bit(td));
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g_assert_true(qtest_get_irq(global_qtest, tim_timer_irq(td)));
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}
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/* Verifies that the prescaler can be changed while the timer is runnin. */
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static void test_prescaler_change(gconstpointer test_data)
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{
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const TestData *td = test_data;
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unsigned int count = 256;
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unsigned int ps = 5;
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tim_reset(td);
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tim_write_ticr(td, count);
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tim_write_tcsr(td, CEN | MODE_ONESHOT | PRESCALE(ps));
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/* Run a quarter of the way, and change the prescaler. */
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clock_step(tim_calculate_step(count / 4, ps));
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g_assert_cmpuint(tim_read_tdr(td), ==, 3 * count / 4);
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ps = 2;
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tim_write_tcsr(td, CEN | MODE_ONESHOT | PRESCALE(ps));
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/* The counter must not change. */
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g_assert_cmpuint(tim_read_tdr(td), ==, 3 * count / 4);
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/* Run another quarter of the way, and change the prescaler again. */
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clock_step(tim_calculate_step(count / 4, ps));
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g_assert_cmpuint(tim_read_tdr(td), ==, count / 2);
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ps = 8;
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tim_write_tcsr(td, CEN | MODE_ONESHOT | PRESCALE(ps));
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/* The counter must not change. */
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g_assert_cmpuint(tim_read_tdr(td), ==, count / 2);
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/* Run another quarter of the way, and change the prescaler again. */
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clock_step(tim_calculate_step(count / 4, ps));
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g_assert_cmpuint(tim_read_tdr(td), ==, count / 4);
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ps = 0;
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tim_write_tcsr(td, CEN | MODE_ONESHOT | PRESCALE(ps));
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/* The counter must not change. */
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g_assert_cmpuint(tim_read_tdr(td), ==, count / 4);
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/* Run almost to expiration, and verify the timer didn't fire yet. */
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clock_step(tim_calculate_step(count / 4, ps) - 1);
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g_assert_cmpuint(tim_read_tdr(td), <, count);
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g_assert_cmphex(tim_read(td, TISR), ==, 0);
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/* Now, run the rest of the way and verify that the timer fires. */
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clock_step(1);
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g_assert_cmphex(tim_read(td, TISR), ==, tim_timer_bit(td));
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}
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/* Verifies that a periodic timer automatically restarts after expiration. */
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static void test_periodic_no_interrupt(gconstpointer test_data)
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{
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const TestData *td = test_data;
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unsigned int count = 2;
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unsigned int ps = 3;
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int i;
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tim_reset(td);
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tim_write_ticr(td, count);
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tim_write_tcsr(td, CEN | MODE_PERIODIC | PRESCALE(ps));
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for (i = 0; i < 4; i++) {
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clock_step_next();
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g_assert_cmphex(tim_read(td, TISR), ==, tim_timer_bit(td));
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g_assert_false(qtest_get_irq(global_qtest, tim_timer_irq(td)));
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tim_write(td, TISR, tim_timer_bit(td));
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|
|
g_assert_cmphex(tim_read(td, TISR), ==, 0);
|
|
g_assert_false(qtest_get_irq(global_qtest, tim_timer_irq(td)));
|
|
}
|
|
}
|
|
|
|
/* Verifies that a periodict timer fires an interrupt every time it expires. */
|
|
static void test_periodic_interrupt(gconstpointer test_data)
|
|
{
|
|
const TestData *td = test_data;
|
|
unsigned int count = 65535;
|
|
unsigned int ps = 2;
|
|
int i;
|
|
|
|
tim_reset(td);
|
|
|
|
tim_write_ticr(td, count);
|
|
tim_write_tcsr(td, CEN | IE | MODE_PERIODIC | PRESCALE(ps));
|
|
|
|
for (i = 0; i < 4; i++) {
|
|
clock_step_next();
|
|
|
|
g_assert_cmphex(tim_read(td, TISR), ==, tim_timer_bit(td));
|
|
g_assert_true(qtest_get_irq(global_qtest, tim_timer_irq(td)));
|
|
|
|
tim_write(td, TISR, tim_timer_bit(td));
|
|
|
|
g_assert_cmphex(tim_read(td, TISR), ==, 0);
|
|
g_assert_false(qtest_get_irq(global_qtest, tim_timer_irq(td)));
|
|
}
|
|
}
|
|
|
|
/*
|
|
* Verifies that the timer behaves correctly when disabled right before and
|
|
* exactly when it's supposed to expire.
|
|
*/
|
|
static void test_disable_on_expiration(gconstpointer test_data)
|
|
{
|
|
const TestData *td = test_data;
|
|
unsigned int count = 8;
|
|
unsigned int ps = 255;
|
|
|
|
tim_reset(td);
|
|
|
|
tim_write_ticr(td, count);
|
|
tim_write_tcsr(td, CEN | MODE_ONESHOT | PRESCALE(ps));
|
|
|
|
clock_step(tim_calculate_step(count, ps) - 1);
|
|
|
|
tim_write_tcsr(td, MODE_ONESHOT | PRESCALE(ps));
|
|
tim_write_tcsr(td, CEN | MODE_ONESHOT | PRESCALE(ps));
|
|
clock_step(1);
|
|
tim_write_tcsr(td, MODE_ONESHOT | PRESCALE(ps));
|
|
g_assert_cmphex(tim_read(td, TISR), ==, tim_timer_bit(td));
|
|
}
|
|
|
|
/*
|
|
* Constructs a name that includes the timer block, timer and testcase name,
|
|
* and adds the test to the test suite.
|
|
*/
|
|
static void tim_add_test(const char *name, const TestData *td, GTestDataFunc fn)
|
|
{
|
|
g_autofree char *full_name = g_strdup_printf(
|
|
"npcm7xx_timer/tim[%d]/timer[%d]/%s", tim_index(td->tim),
|
|
timer_index(td->timer), name);
|
|
qtest_add_data_func(full_name, td, fn);
|
|
}
|
|
|
|
/* Convenience macro for adding a test with a predictable function name. */
|
|
#define add_test(name, td) tim_add_test(#name, td, test_##name)
|
|
|
|
int main(int argc, char **argv)
|
|
{
|
|
TestData testdata[ARRAY_SIZE(timer_block) * ARRAY_SIZE(timer)];
|
|
int ret;
|
|
int i, j;
|
|
|
|
g_test_init(&argc, &argv, NULL);
|
|
g_test_set_nonfatal_assertions();
|
|
|
|
for (i = 0; i < ARRAY_SIZE(timer_block); i++) {
|
|
for (j = 0; j < ARRAY_SIZE(timer); j++) {
|
|
TestData *td = &testdata[i * ARRAY_SIZE(timer) + j];
|
|
td->tim = &timer_block[i];
|
|
td->timer = &timer[j];
|
|
|
|
add_test(reset, td);
|
|
add_test(reset_overrides_enable, td);
|
|
add_test(oneshot_enable_then_disable, td);
|
|
add_test(oneshot_ps5, td);
|
|
add_test(oneshot_ps0, td);
|
|
add_test(oneshot_ps255, td);
|
|
add_test(oneshot_interrupt, td);
|
|
add_test(pause_resume, td);
|
|
add_test(prescaler_change, td);
|
|
add_test(periodic_no_interrupt, td);
|
|
add_test(periodic_interrupt, td);
|
|
add_test(disable_on_expiration, td);
|
|
}
|
|
}
|
|
|
|
qtest_start("-machine npcm750-evb");
|
|
qtest_irq_intercept_in(global_qtest, "/machine/soc/a9mpcore/gic");
|
|
ret = g_test_run();
|
|
qtest_end();
|
|
|
|
return ret;
|
|
}
|