sw/device/tests/rv_plic_smoketest.c - 3p/lowrisc/opentitan - Git at Google

 // Copyright lowRISC contributors.
 // Licensed under the Apache License, Version 2.0, see LICENSE for details.
 // SPDX-License-Identifier: Apache-2.0

 #include "sw/device/lib/base/mmio.h"
 #include "sw/device/lib/dif/dif_rv_plic.h"
 #include "sw/device/lib/dif/dif_uart.h"
 #include "sw/device/lib/runtime/hart.h"
 #include "sw/device/lib/runtime/irq.h"
 #include "sw/device/lib/runtime/log.h"
 #include "sw/device/lib/testing/test_framework/check.h"
 #include "sw/device/lib/testing/test_framework/ottf_main.h"
 #include "sw/device/lib/testing/test_framework/status.h"

 #include "hw/top_earlgrey/sw/autogen/top_earlgrey.h"

 static const uint32_t kPlicTarget = kTopEarlgreyPlicTargetIbex0;

 static dif_rv_plic_t plic0;
 static dif_uart_t uart0;

 // These flags are used in the test routine to verify that a corresponding
 // interrupt has elapsed, and has been serviced. These are declared as volatile
 // since they are referenced in the ISR routine as well as in the main program
 // flow.
 static volatile bool uart_rx_overflow_handled;
 static volatile bool uart_tx_empty_handled;

 /**
  * UART ISR.
  *
  * Services UART interrupts, sets the appropriate flags that are used to
  * determine success or failure of the test.
  */
 static void handle_uart_isr(const dif_rv_plic_irq_id_t interrupt_id) {
   // NOTE: This initialization is superfluous, since the `default` case below
   // is effectively noreturn, but the compiler is unable to prove this.
   dif_uart_irq_t uart_irq = 0;

   switch (interrupt_id) {
     case kTopEarlgreyPlicIrqIdUart0RxOverflow:
       CHECK(!uart_rx_overflow_handled,
             "UART RX overflow IRQ asserted more than once");

       uart_irq = kDifUartIrqRxOverflow;
       uart_rx_overflow_handled = true;
       break;
     case kTopEarlgreyPlicIrqIdUart0TxEmpty:
       CHECK(!uart_tx_empty_handled,
             "UART TX empty IRQ asserted more than once");

       uart_irq = kDifUartIrqTxEmpty;
       uart_tx_empty_handled = true;
       break;
     default:
       LOG_FATAL("ISR is not implemented!");
       test_status_set(kTestStatusFailed);
   }

   CHECK_DIF_OK(dif_uart_irq_acknowledge(&uart0, uart_irq));
 }

 /**
  * External ISR.
  *
  * Handles all peripheral interrupts on Ibex. PLIC asserts an external interrupt
  * line to the CPU, which results in a call to this OTTF ISR. This ISR
  * overrides the default OTTF implementation.
  */
 void ottf_external_isr(void) {
   // Claim the IRQ by reading the Ibex specific CC register.
   dif_rv_plic_irq_id_t interrupt_id;
   CHECK_DIF_OK(dif_rv_plic_irq_claim(&plic0, kPlicTarget, &interrupt_id));

   // Check if the interrupted peripheral is UART.
   top_earlgrey_plic_peripheral_t peripheral_id =
       top_earlgrey_plic_interrupt_for_peripheral[interrupt_id];
   CHECK(peripheral_id == kTopEarlgreyPlicPeripheralUart0,
         "ISR interrupted peripheral is not UART!");
   handle_uart_isr(interrupt_id);

   // Complete the IRQ by writing the IRQ source to the Ibex specific CC
   // register.
   CHECK_DIF_OK(dif_rv_plic_irq_complete(&plic0, kPlicTarget, interrupt_id));
 }

 static void uart_initialise(mmio_region_t base_addr, dif_uart_t *uart) {
   CHECK_DIF_OK(dif_uart_init(base_addr, uart));
   CHECK_DIF_OK(
       dif_uart_configure(uart, (dif_uart_config_t){
                                    .baudrate = kUartBaudrate,
                                    .clk_freq_hz = kClockFreqPeripheralHz,
                                    .parity_enable = kDifToggleDisabled,
                                    .parity = kDifUartParityEven,
                                    .tx_enable = kDifToggleEnabled,
                                    .rx_enable = kDifToggleEnabled,
                                }));
 }

 /**
  * Configures all the relevant interrupts in UART.
  */
 static void uart_configure_irqs(dif_uart_t *uart) {
   CHECK_DIF_OK(dif_uart_irq_set_enabled(&uart0, kDifUartIrqRxOverflow,
                                         kDifToggleEnabled));
   CHECK_DIF_OK(
       dif_uart_irq_set_enabled(&uart0, kDifUartIrqTxEmpty, kDifToggleEnabled));
 }

 /**
  * Configures all the relevant interrupts in PLIC.
  */
 static void plic_configure_irqs(dif_rv_plic_t *plic) {
   // Set IRQ priorities to MAX
   CHECK_DIF_OK(dif_rv_plic_irq_set_priority(
       plic, kTopEarlgreyPlicIrqIdUart0RxOverflow, kDifRvPlicMaxPriority));

   CHECK_DIF_OK(dif_rv_plic_irq_set_priority(
       plic, kTopEarlgreyPlicIrqIdUart0TxEmpty, kDifRvPlicMaxPriority));

   // Set Ibex IRQ priority threshold level
   CHECK_DIF_OK(dif_rv_plic_target_set_threshold(&plic0, kPlicTarget,
                                                 kDifRvPlicMinPriority));

   // Enable IRQs in PLIC
   CHECK_DIF_OK(dif_rv_plic_irq_set_enabled(plic,
                                            kTopEarlgreyPlicIrqIdUart0RxOverflow,
                                            kPlicTarget, kDifToggleEnabled));

   CHECK_DIF_OK(dif_rv_plic_irq_set_enabled(
       plic, kTopEarlgreyPlicIrqIdUart0TxEmpty, kPlicTarget, kDifToggleEnabled));
 }

 static void execute_test(dif_uart_t *uart) {
   // Force UART RX overflow interrupt.
   uart_rx_overflow_handled = false;
   CHECK_DIF_OK(dif_uart_irq_force(uart, kDifUartIrqRxOverflow, true));
   // Check if the IRQ has occured and has been handled appropriately.
   if (!uart_rx_overflow_handled) {
     busy_spin_micros(10);
   }
   CHECK(uart_rx_overflow_handled, "RX overflow IRQ has not been handled!");

   // Force UART TX empty interrupt.
   uart_tx_empty_handled = false;
   CHECK_DIF_OK(dif_uart_irq_force(uart, kDifUartIrqTxEmpty, true));
   // Check if the IRQ has occured and has been handled appropriately.
   if (!uart_tx_empty_handled) {
     busy_spin_micros(10);
   }
   CHECK(uart_tx_empty_handled, "TX empty IRQ has not been handled!");
 }

 OTTF_DEFINE_TEST_CONFIG(.enable_concurrency = false,
                         .can_clobber_uart = true, );

 bool test_main(void) {
   // Enable IRQs on Ibex
   irq_global_ctrl(true);
   irq_external_ctrl(true);

   // No debug output in case of UART initialisation failure.
   mmio_region_t uart_base_addr =
       mmio_region_from_addr(TOP_EARLGREY_UART0_BASE_ADDR);
   uart_initialise(uart_base_addr, &uart0);

   mmio_region_t plic_base_addr =
       mmio_region_from_addr(TOP_EARLGREY_RV_PLIC_BASE_ADDR);
   CHECK_DIF_OK(dif_rv_plic_init(plic_base_addr, &plic0));

   uart_configure_irqs(&uart0);
   plic_configure_irqs(&plic0);
   execute_test(&uart0);

   return true;
 }
	// Copyright lowRISC contributors.
	// Licensed under the Apache License, Version 2.0, see LICENSE for details.
	// SPDX-License-Identifier: Apache-2.0

	#include "sw/device/lib/base/mmio.h"
	#include "sw/device/lib/dif/dif_rv_plic.h"
	#include "sw/device/lib/dif/dif_uart.h"
	#include "sw/device/lib/runtime/hart.h"
	#include "sw/device/lib/runtime/irq.h"
	#include "sw/device/lib/runtime/log.h"
	#include "sw/device/lib/testing/test_framework/check.h"
	#include "sw/device/lib/testing/test_framework/ottf_main.h"
	#include "sw/device/lib/testing/test_framework/status.h"

	#include "hw/top_earlgrey/sw/autogen/top_earlgrey.h"

	static const uint32_t kPlicTarget = kTopEarlgreyPlicTargetIbex0;

	static dif_rv_plic_t plic0;
	static dif_uart_t uart0;

	// These flags are used in the test routine to verify that a corresponding
	// interrupt has elapsed, and has been serviced. These are declared as volatile
	// since they are referenced in the ISR routine as well as in the main program
	// flow.
	static volatile bool uart_rx_overflow_handled;
	static volatile bool uart_tx_empty_handled;

	/**
	* UART ISR.
	*
	* Services UART interrupts, sets the appropriate flags that are used to
	* determine success or failure of the test.
	*/
	static void handle_uart_isr(const dif_rv_plic_irq_id_t interrupt_id) {
	// NOTE: This initialization is superfluous, since the `default` case below
	// is effectively noreturn, but the compiler is unable to prove this.
	dif_uart_irq_t uart_irq = 0;

	switch (interrupt_id) {
	case kTopEarlgreyPlicIrqIdUart0RxOverflow:
	CHECK(!uart_rx_overflow_handled,
	"UART RX overflow IRQ asserted more than once");

	uart_irq = kDifUartIrqRxOverflow;
	uart_rx_overflow_handled = true;
	break;
	case kTopEarlgreyPlicIrqIdUart0TxEmpty:
	CHECK(!uart_tx_empty_handled,
	"UART TX empty IRQ asserted more than once");

	uart_irq = kDifUartIrqTxEmpty;
	uart_tx_empty_handled = true;
	break;
	default:
	LOG_FATAL("ISR is not implemented!");
	test_status_set(kTestStatusFailed);
	}

	CHECK_DIF_OK(dif_uart_irq_acknowledge(&uart0, uart_irq));
	}

	/**
	* External ISR.
	*
	* Handles all peripheral interrupts on Ibex. PLIC asserts an external interrupt
	* line to the CPU, which results in a call to this OTTF ISR. This ISR
	* overrides the default OTTF implementation.
	*/
	void ottf_external_isr(void) {
	// Claim the IRQ by reading the Ibex specific CC register.
	dif_rv_plic_irq_id_t interrupt_id;
	CHECK_DIF_OK(dif_rv_plic_irq_claim(&plic0, kPlicTarget, &interrupt_id));

	// Check if the interrupted peripheral is UART.
	top_earlgrey_plic_peripheral_t peripheral_id =
	top_earlgrey_plic_interrupt_for_peripheral[interrupt_id];
	CHECK(peripheral_id == kTopEarlgreyPlicPeripheralUart0,
	"ISR interrupted peripheral is not UART!");
	handle_uart_isr(interrupt_id);

	// Complete the IRQ by writing the IRQ source to the Ibex specific CC
	// register.
	CHECK_DIF_OK(dif_rv_plic_irq_complete(&plic0, kPlicTarget, interrupt_id));
	}

	static void uart_initialise(mmio_region_t base_addr, dif_uart_t *uart) {
	CHECK_DIF_OK(dif_uart_init(base_addr, uart));
	CHECK_DIF_OK(
	dif_uart_configure(uart, (dif_uart_config_t){
	.baudrate = kUartBaudrate,
	.clk_freq_hz = kClockFreqPeripheralHz,
	.parity_enable = kDifToggleDisabled,
	.parity = kDifUartParityEven,
	.tx_enable = kDifToggleEnabled,
	.rx_enable = kDifToggleEnabled,
	}));
	}

	/**
	* Configures all the relevant interrupts in UART.
	*/
	static void uart_configure_irqs(dif_uart_t *uart) {
	CHECK_DIF_OK(dif_uart_irq_set_enabled(&uart0, kDifUartIrqRxOverflow,
	kDifToggleEnabled));
	CHECK_DIF_OK(
	dif_uart_irq_set_enabled(&uart0, kDifUartIrqTxEmpty, kDifToggleEnabled));
	}

	/**
	* Configures all the relevant interrupts in PLIC.
	*/
	static void plic_configure_irqs(dif_rv_plic_t *plic) {
	// Set IRQ priorities to MAX
	CHECK_DIF_OK(dif_rv_plic_irq_set_priority(
	plic, kTopEarlgreyPlicIrqIdUart0RxOverflow, kDifRvPlicMaxPriority));

	CHECK_DIF_OK(dif_rv_plic_irq_set_priority(
	plic, kTopEarlgreyPlicIrqIdUart0TxEmpty, kDifRvPlicMaxPriority));

	// Set Ibex IRQ priority threshold level
	CHECK_DIF_OK(dif_rv_plic_target_set_threshold(&plic0, kPlicTarget,
	kDifRvPlicMinPriority));

	// Enable IRQs in PLIC
	CHECK_DIF_OK(dif_rv_plic_irq_set_enabled(plic,
	kTopEarlgreyPlicIrqIdUart0RxOverflow,
	kPlicTarget, kDifToggleEnabled));

	CHECK_DIF_OK(dif_rv_plic_irq_set_enabled(
	plic, kTopEarlgreyPlicIrqIdUart0TxEmpty, kPlicTarget, kDifToggleEnabled));
	}

	static void execute_test(dif_uart_t *uart) {
	// Force UART RX overflow interrupt.
	uart_rx_overflow_handled = false;
	CHECK_DIF_OK(dif_uart_irq_force(uart, kDifUartIrqRxOverflow, true));
	// Check if the IRQ has occured and has been handled appropriately.
	if (!uart_rx_overflow_handled) {
	busy_spin_micros(10);
	}
	CHECK(uart_rx_overflow_handled, "RX overflow IRQ has not been handled!");

	// Force UART TX empty interrupt.
	uart_tx_empty_handled = false;
	CHECK_DIF_OK(dif_uart_irq_force(uart, kDifUartIrqTxEmpty, true));
	// Check if the IRQ has occured and has been handled appropriately.
	if (!uart_tx_empty_handled) {
	busy_spin_micros(10);
	}
	CHECK(uart_tx_empty_handled, "TX empty IRQ has not been handled!");
	}

	OTTF_DEFINE_TEST_CONFIG(.enable_concurrency = false,
	.can_clobber_uart = true, );

	bool test_main(void) {
	// Enable IRQs on Ibex
	irq_global_ctrl(true);
	irq_external_ctrl(true);

	// No debug output in case of UART initialisation failure.
	mmio_region_t uart_base_addr =
	mmio_region_from_addr(TOP_EARLGREY_UART0_BASE_ADDR);
	uart_initialise(uart_base_addr, &uart0);

	mmio_region_t plic_base_addr =
	mmio_region_from_addr(TOP_EARLGREY_RV_PLIC_BASE_ADDR);
	CHECK_DIF_OK(dif_rv_plic_init(plic_base_addr, &plic0));

	uart_configure_irqs(&uart0);
	plic_configure_irqs(&plic0);
	execute_test(&uart0);

	return true;
	}