tests/qtest/stm32l4x5_usart-test.c - qemu - Git at Google

 /*
  * QTest testcase for STML4X5_USART
  *
  * Copyright (c) 2023 Arnaud Minier <arnaud.minier@telecom-paris.fr>
  * Copyright (c) 2023 Inès Varhol <ines.varhol@telecom-paris.fr>
  *
  * 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 "qemu/osdep.h"
 #include "libqtest.h"
 #include "hw/misc/stm32l4x5_rcc_internals.h"
 #include "hw/registerfields.h"

 #define RCC_BASE_ADDR 0x40021000
 /* Use USART 1 ADDR, assume the others work the same */
 #define USART1_BASE_ADDR 0x40013800

 /* See stm32l4x5_usart for definitions */
 REG32(CR1, 0x00)
     FIELD(CR1, M1, 28, 1)
     FIELD(CR1, OVER8, 15, 1)
     FIELD(CR1, M0, 12, 1)
     FIELD(CR1, PCE, 10, 1)
     FIELD(CR1, TXEIE, 7, 1)
     FIELD(CR1, RXNEIE, 5, 1)
     FIELD(CR1, TE, 3, 1)
     FIELD(CR1, RE, 2, 1)
     FIELD(CR1, UE, 0, 1)
 REG32(CR2, 0x04)
 REG32(CR3, 0x08)
     FIELD(CR3, OVRDIS, 12, 1)
 REG32(BRR, 0x0C)
 REG32(GTPR, 0x10)
 REG32(RTOR, 0x14)
 REG32(RQR, 0x18)
 REG32(ISR, 0x1C)
     FIELD(ISR, TXE, 7, 1)
     FIELD(ISR, RXNE, 5, 1)
     FIELD(ISR, ORE, 3, 1)
 REG32(ICR, 0x20)
 REG32(RDR, 0x24)
 REG32(TDR, 0x28)

 #define NVIC_ISPR1 0XE000E204
 #define NVIC_ICPR1 0xE000E284
 #define USART1_IRQ 37

 static bool check_nvic_pending(QTestState *qts, unsigned int n)
 {
     /* No USART interrupts are less than 32 */
     assert(n > 32);
     n -= 32;
     return qtest_readl(qts, NVIC_ISPR1) & (1 << n);
 }

 static bool clear_nvic_pending(QTestState *qts, unsigned int n)
 {
     /* No USART interrupts are less than 32 */
     assert(n > 32);
     n -= 32;
     qtest_writel(qts, NVIC_ICPR1, (1 << n));
     return true;
 }

 /*
  * Wait indefinitely for the flag to be updated.
  * If this is run on a slow CI runner,
  * the meson harness will timeout after 10 minutes for us.
  */
 static bool usart_wait_for_flag(QTestState *qts, uint32_t event_addr,
                                 uint32_t flag)
 {
     while (true) {
         if ((qtest_readl(qts, event_addr) & flag)) {
             return true;
         }
         g_usleep(1000);
     }

     return false;
 }

 static void usart_receive_string(QTestState *qts, int sock_fd, const char *in,
                                  char *out)
 {
     int i, in_len = strlen(in);

     g_assert_true(send(sock_fd, in, in_len, 0) == in_len);
     for (i = 0; i < in_len; i++) {
         g_assert_true(usart_wait_for_flag(qts,
             USART1_BASE_ADDR + A_ISR, R_ISR_RXNE_MASK));
         out[i] = qtest_readl(qts, USART1_BASE_ADDR + A_RDR);
     }
     out[i] = '\0';
 }

 static void usart_send_string(QTestState *qts, const char *in)
 {
     int i, in_len = strlen(in);

     for (i = 0; i < in_len; i++) {
         qtest_writel(qts, USART1_BASE_ADDR + A_TDR, in[i]);
         g_assert_true(usart_wait_for_flag(qts,
             USART1_BASE_ADDR + A_ISR, R_ISR_TXE_MASK));
     }
 }

 /* Init the RCC clocks to run at 80 MHz */
 static void init_clocks(QTestState *qts)
 {
     uint32_t value;

     /* MSIRANGE can be set only when MSI is OFF or READY */
     qtest_writel(qts, (RCC_BASE_ADDR + A_CR), R_CR_MSION_MASK);

     /* Clocking from MSI, in case MSI was not the default source */
     qtest_writel(qts, (RCC_BASE_ADDR + A_CFGR), 0);

     /*
      * Update PLL and set MSI as the source clock.
      * PLLM = 1 --> 000
      * PLLN = 40 --> 40
      * PPLLR = 2 --> 00
      * PLLDIV = unused, PLLP = unused (SAI3), PLLQ = unused (48M1)
      * SRC = MSI --> 01
      */
     qtest_writel(qts, (RCC_BASE_ADDR + A_PLLCFGR), R_PLLCFGR_PLLREN_MASK |
             (40 << R_PLLCFGR_PLLN_SHIFT) |
             (0b01 << R_PLLCFGR_PLLSRC_SHIFT));

     /* PLL activation */

     value = qtest_readl(qts, (RCC_BASE_ADDR + A_CR));
     qtest_writel(qts, (RCC_BASE_ADDR + A_CR), value | R_CR_PLLON_MASK);

     /* RCC_CFGR is OK by defaut */
     qtest_writel(qts, (RCC_BASE_ADDR + A_CFGR), 0);

     /* CCIPR : no periph clock by default */
     qtest_writel(qts, (RCC_BASE_ADDR + A_CCIPR), 0);

     /* Switches on the PLL clock source */
     value = qtest_readl(qts, (RCC_BASE_ADDR + A_CFGR));
     qtest_writel(qts, (RCC_BASE_ADDR + A_CFGR), (value & ~R_CFGR_SW_MASK) |
         (0b11 << R_CFGR_SW_SHIFT));

     /* Enable SYSCFG clock enabled */
     qtest_writel(qts, (RCC_BASE_ADDR + A_APB2ENR), R_APB2ENR_SYSCFGEN_MASK);

     /* Enable the IO port B clock (See p.252) */
     qtest_writel(qts, (RCC_BASE_ADDR + A_AHB2ENR), R_AHB2ENR_GPIOBEN_MASK);

     /* Enable the clock for USART1 (cf p.259) */
     /* We rewrite SYSCFGEN to not disable it */
     qtest_writel(qts, (RCC_BASE_ADDR + A_APB2ENR),
                  R_APB2ENR_SYSCFGEN_MASK | R_APB2ENR_USART1EN_MASK);

     /* TODO: Enable usart via gpio */

     /* Set PCLK as the clock for USART1(cf p.272) i.e. reset both bits */
     qtest_writel(qts, (RCC_BASE_ADDR + A_CCIPR), 0);

     /* Reset USART1 (see p.249) */
     qtest_writel(qts, (RCC_BASE_ADDR + A_APB2RSTR), 1 << 14);
     qtest_writel(qts, (RCC_BASE_ADDR + A_APB2RSTR), 0);
 }

 static void init_uart(QTestState *qts)
 {
     uint32_t cr1;

     init_clocks(qts);

     /*
      * For 115200 bauds, see p.1349.
      * The clock has a frequency of 80Mhz,
      * for 115200, we have to put a divider of 695 = 0x2B7.
      */
     qtest_writel(qts, (USART1_BASE_ADDR + A_BRR), 0x2B7);

     /*
      * Set the oversampling by 16,
      * disable the parity control and
      * set the word length to 8. (cf p.1377)
      */
     cr1 = qtest_readl(qts, (USART1_BASE_ADDR + A_CR1));
     cr1 &= ~(R_CR1_M1_MASK | R_CR1_M0_MASK | R_CR1_OVER8_MASK | R_CR1_PCE_MASK);
     qtest_writel(qts, (USART1_BASE_ADDR + A_CR1), cr1);

     /* Enable the transmitter, the receiver and the USART. */
     qtest_writel(qts, (USART1_BASE_ADDR + A_CR1),
         R_CR1_UE_MASK | R_CR1_RE_MASK | R_CR1_TE_MASK);
 }

 static void test_write_read(void)
 {
     QTestState *qts = qtest_init("-M b-l475e-iot01a");

     /* Test that we can write and retrieve a value from the device */
     qtest_writel(qts, USART1_BASE_ADDR + A_TDR, 0xFFFFFFFF);
     const uint32_t tdr = qtest_readl(qts, USART1_BASE_ADDR + A_TDR);
     g_assert_cmpuint(tdr, ==, 0x000001FF);
 }

 static void test_receive_char(void)
 {
     int sock_fd;
     uint32_t cr1;
     QTestState *qts = qtest_init_with_serial("-M b-l475e-iot01a", &sock_fd);

     init_uart(qts);

     /* Try without initializing IRQ */
     g_assert_true(send(sock_fd, "a", 1, 0) == 1);
     usart_wait_for_flag(qts, USART1_BASE_ADDR + A_ISR, R_ISR_RXNE_MASK);
     g_assert_cmphex(qtest_readl(qts, USART1_BASE_ADDR + A_RDR), ==, 'a');
     g_assert_false(check_nvic_pending(qts, USART1_IRQ));

     /* Now with the IRQ */
     cr1 = qtest_readl(qts, (USART1_BASE_ADDR + A_CR1));
     cr1 |= R_CR1_RXNEIE_MASK;
     qtest_writel(qts, USART1_BASE_ADDR + A_CR1, cr1);
     g_assert_true(send(sock_fd, "b", 1, 0) == 1);
     usart_wait_for_flag(qts, USART1_BASE_ADDR + A_ISR, R_ISR_RXNE_MASK);
     g_assert_cmphex(qtest_readl(qts, USART1_BASE_ADDR + A_RDR), ==, 'b');
     g_assert_true(check_nvic_pending(qts, USART1_IRQ));
     clear_nvic_pending(qts, USART1_IRQ);

     close(sock_fd);

     qtest_quit(qts);
 }

 static void test_send_char(void)
 {
     int sock_fd;
     char s[1];
     uint32_t cr1;
     QTestState *qts = qtest_init_with_serial("-M b-l475e-iot01a", &sock_fd);

     init_uart(qts);

     /* Try without initializing IRQ */
     qtest_writel(qts, USART1_BASE_ADDR + A_TDR, 'c');
     g_assert_true(recv(sock_fd, s, 1, 0) == 1);
     g_assert_cmphex(s[0], ==, 'c');
     g_assert_false(check_nvic_pending(qts, USART1_IRQ));

     /* Now with the IRQ */
     cr1 = qtest_readl(qts, (USART1_BASE_ADDR + A_CR1));
     cr1 |= R_CR1_TXEIE_MASK;
     qtest_writel(qts, USART1_BASE_ADDR + A_CR1, cr1);
     qtest_writel(qts, USART1_BASE_ADDR + A_TDR, 'd');
     g_assert_true(recv(sock_fd, s, 1, 0) == 1);
     g_assert_cmphex(s[0], ==, 'd');
     g_assert_true(check_nvic_pending(qts, USART1_IRQ));
     clear_nvic_pending(qts, USART1_IRQ);

     close(sock_fd);

     qtest_quit(qts);
 }

 static void test_receive_str(void)
 {
     int sock_fd;
     char s[10];
     QTestState *qts = qtest_init_with_serial("-M b-l475e-iot01a", &sock_fd);

     init_uart(qts);

     usart_receive_string(qts, sock_fd, "hello", s);
     g_assert_true(memcmp(s, "hello", 5) == 0);

     close(sock_fd);

     qtest_quit(qts);
 }

 static void test_send_str(void)
 {
     int sock_fd;
     char s[10];
     QTestState *qts = qtest_init_with_serial("-M b-l475e-iot01a", &sock_fd);

     init_uart(qts);

     usart_send_string(qts, "world");
     g_assert_true(recv(sock_fd, s, 10, 0) == 5);
     g_assert_true(memcmp(s, "world", 5) == 0);

     close(sock_fd);

     qtest_quit(qts);
 }

 int main(int argc, char **argv)
 {
     int ret;

     g_test_init(&argc, &argv, NULL);
     g_test_set_nonfatal_assertions();

     qtest_add_func("stm32l4x5/usart/write_read", test_write_read);
     qtest_add_func("stm32l4x5/usart/receive_char", test_receive_char);
     qtest_add_func("stm32l4x5/usart/send_char", test_send_char);
     qtest_add_func("stm32l4x5/usart/receive_str", test_receive_str);
     qtest_add_func("stm32l4x5/usart/send_str", test_send_str);
     ret = g_test_run();

     return ret;
 }
	/*
	* QTest testcase for STML4X5_USART
	*
	* Copyright (c) 2023 Arnaud Minier <arnaud.minier@telecom-paris.fr>
	* Copyright (c) 2023 Inès Varhol <ines.varhol@telecom-paris.fr>
	*
	* 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 "qemu/osdep.h"
	#include "libqtest.h"
	#include "hw/misc/stm32l4x5_rcc_internals.h"
	#include "hw/registerfields.h"

	#define RCC_BASE_ADDR 0x40021000
	/* Use USART 1 ADDR, assume the others work the same */
	#define USART1_BASE_ADDR 0x40013800

	/* See stm32l4x5_usart for definitions */
	REG32(CR1, 0x00)
	FIELD(CR1, M1, 28, 1)
	FIELD(CR1, OVER8, 15, 1)
	FIELD(CR1, M0, 12, 1)
	FIELD(CR1, PCE, 10, 1)
	FIELD(CR1, TXEIE, 7, 1)
	FIELD(CR1, RXNEIE, 5, 1)
	FIELD(CR1, TE, 3, 1)
	FIELD(CR1, RE, 2, 1)
	FIELD(CR1, UE, 0, 1)
	REG32(CR2, 0x04)
	REG32(CR3, 0x08)
	FIELD(CR3, OVRDIS, 12, 1)
	REG32(BRR, 0x0C)
	REG32(GTPR, 0x10)
	REG32(RTOR, 0x14)
	REG32(RQR, 0x18)
	REG32(ISR, 0x1C)
	FIELD(ISR, TXE, 7, 1)
	FIELD(ISR, RXNE, 5, 1)
	FIELD(ISR, ORE, 3, 1)
	REG32(ICR, 0x20)
	REG32(RDR, 0x24)
	REG32(TDR, 0x28)

	#define NVIC_ISPR1 0XE000E204
	#define NVIC_ICPR1 0xE000E284
	#define USART1_IRQ 37

	static bool check_nvic_pending(QTestState *qts, unsigned int n)
	{
	/* No USART interrupts are less than 32 */
	assert(n > 32);
	n -= 32;
	return qtest_readl(qts, NVIC_ISPR1) & (1 << n);
	}

	static bool clear_nvic_pending(QTestState *qts, unsigned int n)
	{
	/* No USART interrupts are less than 32 */
	assert(n > 32);
	n -= 32;
	qtest_writel(qts, NVIC_ICPR1, (1 << n));
	return true;
	}

	/*
	* Wait indefinitely for the flag to be updated.
	* If this is run on a slow CI runner,
	* the meson harness will timeout after 10 minutes for us.
	*/
	static bool usart_wait_for_flag(QTestState *qts, uint32_t event_addr,
	uint32_t flag)
	{
	while (true) {
	if ((qtest_readl(qts, event_addr) & flag)) {
	return true;
	}
	g_usleep(1000);
	}

	return false;
	}

	static void usart_receive_string(QTestState qts, int sock_fd, const char in,
	char *out)
	{
	int i, in_len = strlen(in);

	g_assert_true(send(sock_fd, in, in_len, 0) == in_len);
	for (i = 0; i < in_len; i++) {
	g_assert_true(usart_wait_for_flag(qts,
	USART1_BASE_ADDR + A_ISR, R_ISR_RXNE_MASK));
	out[i] = qtest_readl(qts, USART1_BASE_ADDR + A_RDR);
	}
	out[i] = '\0';
	}

	static void usart_send_string(QTestState qts, const char in)
	{
	int i, in_len = strlen(in);

	for (i = 0; i < in_len; i++) {
	qtest_writel(qts, USART1_BASE_ADDR + A_TDR, in[i]);
	g_assert_true(usart_wait_for_flag(qts,
	USART1_BASE_ADDR + A_ISR, R_ISR_TXE_MASK));
	}
	}

	/* Init the RCC clocks to run at 80 MHz */
	static void init_clocks(QTestState *qts)
	{
	uint32_t value;

	/* MSIRANGE can be set only when MSI is OFF or READY */
	qtest_writel(qts, (RCC_BASE_ADDR + A_CR), R_CR_MSION_MASK);

	/* Clocking from MSI, in case MSI was not the default source */
	qtest_writel(qts, (RCC_BASE_ADDR + A_CFGR), 0);

	/*
	* Update PLL and set MSI as the source clock.
	* PLLM = 1 --> 000
	* PLLN = 40 --> 40
	* PPLLR = 2 --> 00
	* PLLDIV = unused, PLLP = unused (SAI3), PLLQ = unused (48M1)
	* SRC = MSI --> 01
	*/
	qtest_writel(qts, (RCC_BASE_ADDR + A_PLLCFGR), R_PLLCFGR_PLLREN_MASK \|
	(40 << R_PLLCFGR_PLLN_SHIFT) \|
	(0b01 << R_PLLCFGR_PLLSRC_SHIFT));

	/* PLL activation */

	value = qtest_readl(qts, (RCC_BASE_ADDR + A_CR));
	qtest_writel(qts, (RCC_BASE_ADDR + A_CR), value \| R_CR_PLLON_MASK);

	/* RCC_CFGR is OK by defaut */
	qtest_writel(qts, (RCC_BASE_ADDR + A_CFGR), 0);

	/* CCIPR : no periph clock by default */
	qtest_writel(qts, (RCC_BASE_ADDR + A_CCIPR), 0);

	/* Switches on the PLL clock source */
	value = qtest_readl(qts, (RCC_BASE_ADDR + A_CFGR));
	qtest_writel(qts, (RCC_BASE_ADDR + A_CFGR), (value & ~R_CFGR_SW_MASK) \|
	(0b11 << R_CFGR_SW_SHIFT));

	/* Enable SYSCFG clock enabled */
	qtest_writel(qts, (RCC_BASE_ADDR + A_APB2ENR), R_APB2ENR_SYSCFGEN_MASK);

	/* Enable the IO port B clock (See p.252) */
	qtest_writel(qts, (RCC_BASE_ADDR + A_AHB2ENR), R_AHB2ENR_GPIOBEN_MASK);

	/* Enable the clock for USART1 (cf p.259) */
	/* We rewrite SYSCFGEN to not disable it */
	qtest_writel(qts, (RCC_BASE_ADDR + A_APB2ENR),
	R_APB2ENR_SYSCFGEN_MASK \| R_APB2ENR_USART1EN_MASK);

	/* TODO: Enable usart via gpio */

	/* Set PCLK as the clock for USART1(cf p.272) i.e. reset both bits */
	qtest_writel(qts, (RCC_BASE_ADDR + A_CCIPR), 0);

	/* Reset USART1 (see p.249) */
	qtest_writel(qts, (RCC_BASE_ADDR + A_APB2RSTR), 1 << 14);
	qtest_writel(qts, (RCC_BASE_ADDR + A_APB2RSTR), 0);
	}

	static void init_uart(QTestState *qts)
	{
	uint32_t cr1;

	init_clocks(qts);

	/*
	* For 115200 bauds, see p.1349.
	* The clock has a frequency of 80Mhz,
	* for 115200, we have to put a divider of 695 = 0x2B7.
	*/
	qtest_writel(qts, (USART1_BASE_ADDR + A_BRR), 0x2B7);

	/*
	* Set the oversampling by 16,
	* disable the parity control and
	* set the word length to 8. (cf p.1377)
	*/
	cr1 = qtest_readl(qts, (USART1_BASE_ADDR + A_CR1));
	cr1 &= ~(R_CR1_M1_MASK \| R_CR1_M0_MASK \| R_CR1_OVER8_MASK \| R_CR1_PCE_MASK);
	qtest_writel(qts, (USART1_BASE_ADDR + A_CR1), cr1);

	/* Enable the transmitter, the receiver and the USART. */
	qtest_writel(qts, (USART1_BASE_ADDR + A_CR1),
	R_CR1_UE_MASK \| R_CR1_RE_MASK \| R_CR1_TE_MASK);
	}

	static void test_write_read(void)
	{
	QTestState *qts = qtest_init("-M b-l475e-iot01a");

	/* Test that we can write and retrieve a value from the device */
	qtest_writel(qts, USART1_BASE_ADDR + A_TDR, 0xFFFFFFFF);
	const uint32_t tdr = qtest_readl(qts, USART1_BASE_ADDR + A_TDR);
	g_assert_cmpuint(tdr, ==, 0x000001FF);
	}

	static void test_receive_char(void)
	{
	int sock_fd;
	uint32_t cr1;
	QTestState *qts = qtest_init_with_serial("-M b-l475e-iot01a", &sock_fd);

	init_uart(qts);

	/* Try without initializing IRQ */
	g_assert_true(send(sock_fd, "a", 1, 0) == 1);
	usart_wait_for_flag(qts, USART1_BASE_ADDR + A_ISR, R_ISR_RXNE_MASK);
	g_assert_cmphex(qtest_readl(qts, USART1_BASE_ADDR + A_RDR), ==, 'a');
	g_assert_false(check_nvic_pending(qts, USART1_IRQ));

	/* Now with the IRQ */
	cr1 = qtest_readl(qts, (USART1_BASE_ADDR + A_CR1));
	cr1 \|= R_CR1_RXNEIE_MASK;
	qtest_writel(qts, USART1_BASE_ADDR + A_CR1, cr1);
	g_assert_true(send(sock_fd, "b", 1, 0) == 1);
	usart_wait_for_flag(qts, USART1_BASE_ADDR + A_ISR, R_ISR_RXNE_MASK);
	g_assert_cmphex(qtest_readl(qts, USART1_BASE_ADDR + A_RDR), ==, 'b');
	g_assert_true(check_nvic_pending(qts, USART1_IRQ));
	clear_nvic_pending(qts, USART1_IRQ);

	close(sock_fd);

	qtest_quit(qts);
	}

	static void test_send_char(void)
	{
	int sock_fd;
	char s[1];
	uint32_t cr1;
	QTestState *qts = qtest_init_with_serial("-M b-l475e-iot01a", &sock_fd);

	init_uart(qts);

	/* Try without initializing IRQ */
	qtest_writel(qts, USART1_BASE_ADDR + A_TDR, 'c');
	g_assert_true(recv(sock_fd, s, 1, 0) == 1);
	g_assert_cmphex(s[0], ==, 'c');
	g_assert_false(check_nvic_pending(qts, USART1_IRQ));

	/* Now with the IRQ */
	cr1 = qtest_readl(qts, (USART1_BASE_ADDR + A_CR1));
	cr1 \|= R_CR1_TXEIE_MASK;
	qtest_writel(qts, USART1_BASE_ADDR + A_CR1, cr1);
	qtest_writel(qts, USART1_BASE_ADDR + A_TDR, 'd');
	g_assert_true(recv(sock_fd, s, 1, 0) == 1);
	g_assert_cmphex(s[0], ==, 'd');
	g_assert_true(check_nvic_pending(qts, USART1_IRQ));
	clear_nvic_pending(qts, USART1_IRQ);

	close(sock_fd);

	qtest_quit(qts);
	}

	static void test_receive_str(void)
	{
	int sock_fd;
	char s[10];
	QTestState *qts = qtest_init_with_serial("-M b-l475e-iot01a", &sock_fd);

	init_uart(qts);

	usart_receive_string(qts, sock_fd, "hello", s);
	g_assert_true(memcmp(s, "hello", 5) == 0);

	close(sock_fd);

	qtest_quit(qts);
	}

	static void test_send_str(void)
	{
	int sock_fd;
	char s[10];
	QTestState *qts = qtest_init_with_serial("-M b-l475e-iot01a", &sock_fd);

	init_uart(qts);

	usart_send_string(qts, "world");
	g_assert_true(recv(sock_fd, s, 10, 0) == 5);
	g_assert_true(memcmp(s, "world", 5) == 0);

	close(sock_fd);

	qtest_quit(qts);
	}

	int main(int argc, char **argv)
	{
	int ret;

	g_test_init(&argc, &argv, NULL);
	g_test_set_nonfatal_assertions();

	qtest_add_func("stm32l4x5/usart/write_read", test_write_read);
	qtest_add_func("stm32l4x5/usart/receive_char", test_receive_char);
	qtest_add_func("stm32l4x5/usart/send_char", test_send_char);
	qtest_add_func("stm32l4x5/usart/receive_str", test_receive_str);
	qtest_add_func("stm32l4x5/usart/send_str", test_send_str);
	ret = g_test_run();

	return ret;
	}