/* * Copyright (c) 2019, Arm Limited and affiliates. * SPDX-License-Identifier: Apache-2.0 * * Licensed under the Apache License, Version 2.0 (the "License"); * you may not use this file except in compliance with the License. * You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ #include "UARTTester.h" #include "fpga_config.h" void UARTTester::set_baud(uint32_t baudrate) { uint32_t divisor = TESTER_CLOCK_FREQUENCY_HZ / baudrate; // Baud divisor is only 16 bits MBED_ASSERT((divisor & 0xFFFF0000) == 0); write(TESTER_UART_BAUD_DIVISOR, (uint8_t *)&divisor, TESTER_UART_BAUD_DIVISOR_SIZE); } void UARTTester::set_bits(uint8_t data_bits) { // Check for supported range MBED_ASSERT((data_bits >= 1) && (data_bits <= 16)); write(TESTER_UART_BIT_COUNT, &data_bits, sizeof(data_bits)); } void UARTTester::set_stops(uint8_t stop_bits) { // Check for supported range MBED_ASSERT((stop_bits >= 1) && (stop_bits <= 16)); write(TESTER_UART_STOP_COUNT, &stop_bits, sizeof(stop_bits)); } void UARTTester::set_parity(bool enable, bool odd_n_even) { uint8_t parity = (enable ? TESTER_UART_PARITY_ENABLE : 0) | (odd_n_even ? TESTER_UART_PARITY_ODD_N_EVEN : 0); write(TESTER_UART_PARITY, &parity, sizeof(parity)); } void UARTTester::rx_start() { uint8_t data = TESTER_UART_RX_CONTROL_ENABLE; write(TESTER_UART_RX_CONTROL, &data, sizeof(data)); } void UARTTester::rx_stop() { uint8_t data = 0; write(TESTER_UART_RX_CONTROL, &data, sizeof(data)); } uint32_t UARTTester::rx_get_checksum() { uint32_t checksum = 0; read(TESTER_UART_RX_CHECKSUM, (uint8_t *)&checksum, sizeof(checksum)); return checksum; } uint32_t UARTTester::rx_get_count() { uint32_t count = 0; read(TESTER_UART_RX_COUNT, (uint8_t *)&count, sizeof(count)); return count; } uint16_t UARTTester::rx_get_data(int prev) { MBED_ASSERT((prev >= 1) && (prev <= 4)); uint16_t data = 0; read(TESTER_UART_RX_PREV_1 - (prev - 1) * 2, (uint8_t *)&data, sizeof(data)); return data; } uint32_t UARTTester::rx_get_parity_errors() { uint32_t errors = 0; read(TESTER_UART_RX_PARITY_ERRORS, (uint8_t *)&errors, sizeof(errors)); return errors; } uint32_t UARTTester::rx_get_stop_errors() { uint32_t errors = 0; read(TESTER_UART_RX_STOP_ERRORS, (uint8_t *)&errors, sizeof(errors)); return errors; } uint32_t UARTTester::rx_get_framing_errors() { uint32_t errors = 0; read(TESTER_UART_RX_FRAMING_ERRORS, (uint8_t *)&errors, sizeof(errors)); return errors; } void UARTTester::tx_start(bool cts_enabled) { uint32_t control = TESTER_UART_TX_CONTROL_ENABLE | (cts_enabled ? TESTER_UART_TX_CONTROL_ENABLE_CTS : 0); write(TESTER_UART_TX_CONTROL, (uint8_t *)&control, sizeof(control)); } void UARTTester::tx_stop() { uint32_t control = 0; write(TESTER_UART_TX_CONTROL, (uint8_t *)&control, sizeof(control)); } void UARTTester::tx_set_delay(uint32_t delay_ns) { uint32_t delay_clks = (delay_ns + TESTER_CLOCK_PERIOD_NS - 1) / TESTER_CLOCK_PERIOD_NS; write(TESTER_UART_TX_DELAY, (uint8_t *)&delay_clks, sizeof(delay_clks)); } void UARTTester::tx_set_count(uint32_t count) { write(TESTER_UART_TX_COUNT, (uint8_t *)&count, sizeof(count)); } void UARTTester::tx_set_next(uint16_t value) { write(TESTER_UART_TX_NEXT, (uint8_t *)&value, sizeof(value)); } void UARTTester::cts_deassert_delay(uint32_t delay_ns) { uint32_t delay_clks = delay_ns / TESTER_CLOCK_PERIOD_NS; write(TESTER_UART_CTS_DEACTIVATE_DELAY, (uint8_t *)&delay_clks, sizeof(delay_clks)); }