#include #include #include #include #include #include #include #include "hardware.h" #include "ili9341.h" #include "ice40.h" #include "rp2040.h" #include "fpga_test.h" #include "pax_gfx.h" #include "test_common.h" extern const uint8_t fpga_selftest_bin_start[] asm("_binary_fpga_selftest_bin_start"); extern const uint8_t fpga_selftest_bin_end[] asm("_binary_fpga_selftest_bin_end"); static const char *TAG = "fpga_test"; /* SPI commands */ #define SPI_CMD_NOP1 0x00 #define SPI_CMD_SOC_MSG 0x10 #define SPI_CMD_REG_ACCESS 0xf0 #define SPI_CMD_LOOPBACK 0xf1 #define SPI_CMD_LCD_PASSTHROUGH 0xf2 #define SPI_CMD_BUTTON_REPORT 0xf4 #define SPI_CMD_IRQ_ACK 0xfd #define SPI_CMD_RESP_ACK 0xfe #define SPI_CMD_NOP2 0xff /* Messages to self-test SoC */ #define SOC_CMD_PING 0x00 #define SOC_CMD_PING_PARAM 0xc0ffee #define SOC_CMD_PING_RESP 0xcafebabe #define SOC_CMD_RGB_STATE_SET 0x10 #define SOC_CMD_IRQN_SET 0x11 #define SOC_CMD_LCD_RGB_CYCLE_SET 0x12 #define SOC_CMD_PMOD_CYCLE_SET 0x13 #define SOC_CMD_LCD_PASSTHROUGH_SET 0x14 #define SOC_CMD_PSRAM_TEST 0x20 #define SOC_CMD_UART_LOOPBACK_TEST 0x21 #define SOC_CMD_PMOD_OPEN_TEST 0x22 #define SOC_CMD_PMOD_PLUG_TEST 0x23 #define SOC_CMD_LCD_INIT_TEST 0x24 #define SOC_CMD_LCD_CHECK_MODE 0x30 #define SOC_RESP_OK 0x00000000 /* SoC commands */ static bool soc_message(ICE40* ice40, uint8_t cmd, uint32_t param, uint32_t *resp, TickType_t ticks_to_wait) { esp_err_t res; uint8_t data_tx[6]; uint8_t data_rx[6]; /* Default delay */ ticks_to_wait /= 10; /* We do 10 retries */ if (!ticks_to_wait) ticks_to_wait = pdMS_TO_TICKS(50); /* Prepare message */ data_tx[0] = SPI_CMD_SOC_MSG; data_tx[1] = cmd; data_tx[2] = (param >> 16) & 0xff; data_tx[3] = (param >> 8) & 0xff; data_tx[4] = (param ) & 0xff; /* Send message to PicoRV */ res = ice40_send_turbo(ice40, data_tx, 5); if (res != ESP_OK) { ESP_LOGE(TAG, "SoC message TX failed"); return false; } /* Poll until we get a response */ data_tx[0] = SPI_CMD_RESP_ACK; for (int i=0; i<10; i++) { /* Poll */ res = ice40_transaction(ice40, data_tx, 6, data_rx, 6); if (res != ESP_OK) { ESP_LOGE(TAG, "SoC response RX failed"); return false; } /* Was response valid ? */ if (data_rx[1] & 0x80) break; /* Wait before retry */ vTaskDelay(ticks_to_wait); } if (!(data_rx[1] & 0x80)) { ESP_LOGE(TAG, "SoC response RX timeout"); return false; } /* Report response */ if (resp) { *resp = 0; for (int i=0; i<4; i++) *resp = (*resp << 8) | data_rx[2+i]; } return true; } /* Test routines */ static bool test_bitstream_load(uint32_t *rc) { ICE40* ice40 = get_ice40(); esp_err_t res; res = ice40_load_bitstream(ice40, fpga_selftest_bin_start, fpga_selftest_bin_end - fpga_selftest_bin_start); if (res != ESP_OK) { *rc = res; return false; } *rc = 0; return true; } static bool _test_spi_loopback_one(ICE40* ice40) { esp_err_t res; uint8_t data_tx[257]; uint8_t data_rx[258]; /* Generate pseudo random sequence */ data_tx[1] = 1; for (int i = 2; i < 257; i++) data_tx[i] = (data_tx[i-1] << 1) ^ ((data_tx[i-1] & 0x80) ? 0x1d : 0x00); /* Send 256 bytes at high speed with echo command */ data_tx[0] = SPI_CMD_LOOPBACK; res = ice40_send_turbo(ice40, data_tx, 257); if (res != ESP_OK) { ESP_LOGE(TAG, "SPI loopback transaction 1 failed (Turbo TX)"); return false; } /* Execute full duplex transaction with next 128 bytes */ res = ice40_transaction(ice40, data_tx, 257, data_rx, 257); if (res != ESP_OK) { ESP_LOGE(TAG, "SPI loopback transaction 2 failed (Full Duplex)"); return false; } /* Validate response present */ if ((data_rx[1] & 0x80) == 0) { ESP_LOGE(TAG, "SPI loopback transaction 2 reports no response available\n"); return false; } /* Validate RX data (only 254 byte got read) */ if (memcmp(&data_rx[2], &data_tx[1], 254)) { ESP_LOGE(TAG, "SPI loopback transaction 1->2 integrity fail:\n"); for (int i = 0; i < 254; i++) printf("%02X%c", data_rx[i], ((i&0xf)==0xf) ? '\n' : ' '); printf("\n"); return false; } /* Read two responses and ack them */ for (int t = 0; t < 2; t++) { /* Receive half duplex */ res = ice40_receive(ice40, data_rx, 258); if (res != ESP_OK) { ESP_LOGE(TAG, "SPI loopback transaction 3.%d failed (Half Duplex RX)", t); return false; } /* Short acknowledge command */ data_tx[0] = SPI_CMD_RESP_ACK; res = ice40_send_turbo(ice40, data_tx, 1); if (res != ESP_OK) { ESP_LOGE(TAG, "SPI loopback transaction 4.%d failed (Turbo ACK)", t); return false; } /* Validate response present */ if ((data_rx[1] & 0x80) == 0) { ESP_LOGE(TAG, "SPI loopback transaction 3.%d reports no response available\n", t); return false; } /* Validate RX data (only 254 byte got read) */ if (memcmp(&data_rx[2], &data_tx[1], 254)) { ESP_LOGE(TAG, "SPI loopback transaction %d->3.%d integrity fail:\n", 1+t, t); for (int i = 0; i < 254; i++) printf("%02X%c", data_rx[i], ((i&0xf)==0xf) ? '\n' : ' '); printf("\n"); return false; } } /* Check there is no more responses pending */ data_tx[0] = SPI_CMD_NOP2; res = ice40_transaction(ice40, data_tx, 2, data_rx, 2); if (res != ESP_OK) { ESP_LOGE(TAG, "SPI loopback transaction 5 failed (Full Duplex)"); return false; } if ((data_rx[1] & 0x80) != 0) { ESP_LOGE(TAG, "SPI loopback transaction 5 reports response available\n"); return false; } return true; } static bool test_spi_loopback(uint32_t *rc) { int i; ICE40* ice40 = get_ice40(); /* Run test 256 times */ for (i=0; i<256; i++) { if (!_test_spi_loopback_one(ice40)) break; } /* Failure ? */ if (i != 256) { *rc = i + 1; return false; } /* OK ! */ *rc = 0; return true; } static bool test_soc_loopback(uint32_t *rc) { ICE40* ice40 = get_ice40(); /* Execute command */ if (!soc_message(ice40, SOC_CMD_PING, SOC_CMD_PING_PARAM, rc, 0)) { *rc = -1; return false; } /* Check response */ if (*rc != SOC_CMD_PING_RESP) return false; /* Success */ *rc = 0; return true; } static bool test_uart_loopback(uint32_t *rc) { ICE40* ice40 = get_ice40(); /* Enable loopback mode of RP2040 */ rp2040_set_fpga_loopback(get_rp2040(), true, true); vTaskDelay(pdMS_TO_TICKS(10)); /* Execute command */ if (!soc_message(ice40, SOC_CMD_UART_LOOPBACK_TEST, 0, rc, 0)) { *rc = -1; return false; } /* Disable loopback mode of RP2040 */ rp2040_set_fpga_loopback(get_rp2040(), true, false); /* Check response */ return *rc == SOC_RESP_OK; } static bool test_psram(uint32_t *rc) { ICE40* ice40 = get_ice40(); /* Execute command */ if (!soc_message(ice40, SOC_CMD_PSRAM_TEST, 0, rc, pdMS_TO_TICKS(1000))) { *rc = -1; return false; } /* Check response */ return *rc == SOC_RESP_OK; } static bool test_irq_n(uint32_t *rc) { ICE40* ice40 = get_ice40(); esp_err_t res; /* Set pin as input */ res = gpio_set_direction(GPIO_INT_FPGA, GPIO_MODE_INPUT); if (res != ESP_OK) { *rc = 32; return false; } /* Assert interrupt line */ if (!soc_message(ice40, SOC_CMD_IRQN_SET, 1, rc, 0)) { *rc = -1; return false; } if (*rc != SOC_RESP_OK) return false; /* Check level is 0 */ if (gpio_get_level(GPIO_INT_FPGA) != 0) { *rc = 16; return false; } /* Release interrupt line */ if (!soc_message(ice40, SOC_CMD_IRQN_SET, 0, rc, 0)) { *rc = -1; return false; } if (*rc != SOC_RESP_OK) return false; /* Check level is 1 */ if (gpio_get_level(GPIO_INT_FPGA) != 1) { *rc = 16; return false; } return true; } static bool test_lcd_mode(uint32_t *rc) { ICE40* ice40 = get_ice40(); esp_err_t res; bool ok; /* Defaults */ ok = true; *rc = 0; /* Check state is 0 */ if (!soc_message(ice40, SOC_CMD_LCD_CHECK_MODE, 0, rc, 0)) { *rc = 16; return false; } if (*rc != SOC_RESP_OK) return false; /* Set LCD mode to 1 */ res = gpio_set_level(GPIO_LCD_MODE, 1); if (res != ESP_OK) { *rc = 32; return false; } /* Check state is 1 */ if (!soc_message(ice40, SOC_CMD_LCD_CHECK_MODE, 1, rc, 0)) { *rc = 17; ok = false; } if (*rc != SOC_RESP_OK) ok = false; /* Set LCD mode back to 0 */ res = gpio_set_level(GPIO_LCD_MODE, 0); if (res != ESP_OK) { *rc = 33; return false; } /* All good */ return ok; } static bool test_pmod_open(uint32_t *rc) { ICE40* ice40 = get_ice40(); /* Execute command */ if (!soc_message(ice40, SOC_CMD_PMOD_OPEN_TEST, 0, rc, 0)) { *rc = -1; return false; } /* Check response */ return *rc == SOC_RESP_OK; } static bool test_pmod_plug(uint32_t *rc) { ICE40* ice40 = get_ice40(); /* Execute command */ if (!soc_message(ice40, SOC_CMD_PMOD_PLUG_TEST, 0, rc, 0)) { *rc = -1; return false; } /* Check response */ return *rc == SOC_RESP_OK; } static bool test_lcd_init(uint32_t *rc) { ICE40* ice40 = get_ice40(); /* Execute command */ if (!soc_message(ice40, SOC_CMD_LCD_INIT_TEST, 0, rc, 0)) { *rc = -1; return false; } /* Check response */ return *rc == SOC_RESP_OK; } bool run_fpga_tests(xQueueHandle buttonQueue, pax_buf_t* pax_buffer, ILI9341* ili9341) { ICE40* ice40 = get_ice40(); const pax_font_t *font; int line = 0; bool ok = true; /* Screen init */ font = pax_get_font("sky mono"); pax_noclip(pax_buffer); pax_background(pax_buffer, 0x8060f0); ili9341_write(ili9341, pax_buffer->buf); /* Run mandatory tests */ RUN_TEST_MANDATORY("Bitstream load", test_bitstream_load); RUN_TEST_MANDATORY("SPI loopback", test_spi_loopback); RUN_TEST_MANDATORY("SoC loopback", test_soc_loopback); /* Set indicator to "in-progress" */ soc_message(ice40, SOC_CMD_RGB_STATE_SET, 1, NULL, 0); /* Run non-interactive tests */ RUN_TEST("UART loopback", test_uart_loopback); RUN_TEST("PSRAM", test_psram); RUN_TEST("IRQ_n signal", test_irq_n); RUN_TEST("LCD_MODE signal", test_lcd_mode); RUN_TEST("PMOD open", test_pmod_open); /* Show instructions for interactive test */ /*pax_draw_text(pax_buffer, 0xffc0c0c0, font, 9, 25, 20*line+ 0, "Insert PMOD plug"); pax_draw_text(pax_buffer, 0xffc0c0c0, font, 9, 25, 20*line+10, "Then press button for interactive test"); pax_draw_text(pax_buffer, 0xffc0c0c0, font, 9, 25, 20*line+20, " - Check LCD color bars"); pax_draw_text(pax_buffer, 0xffc0c0c0, font, 9, 25, 20*line+30, " - Then LCD & RGB led color cycling"); ili9341_write(ili9341, pax_buffer->buf);*/ /* Wait for button */ //wait_button(buttonQueue); /* Clear the instructions from buffer */ //pax_draw_rect(pax_buffer, 0xff8060f0, 0, 20*line, 320, 240-20*line); /* Handover LCD to FPGA */ ili9341_deinit(ili9341); /* Run interactive tests */ //RUN_TEST("PMOD plug", test_pmod_plug); RUN_TEST("LCD init", test_lcd_init); /* Wait a second (for user to see color bars) */ vTaskDelay(pdMS_TO_TICKS(1000)); /* Start LCD / RGB cycling */ soc_message(ice40, SOC_CMD_LCD_RGB_CYCLE_SET, 1, NULL, 0); /* Wait for button */ RUN_TEST("LCD control", test_wait_for_response); /* Stop LCD / RGB cycling */ soc_message(ice40, SOC_CMD_LCD_RGB_CYCLE_SET, 0, NULL, 0); /* Take control of the LCD back and refresh screen */ ili9341_init(ili9341); error: /* Update indicator */ soc_message(ice40, SOC_CMD_RGB_STATE_SET, ok ? 2 : 3, NULL, 0); /* Pass / Fail result on screen */ if (ok) pax_draw_text(pax_buffer, 0xff00ff00, font, 36, 0, 20*line, "PASS"); else pax_draw_text(pax_buffer, 0xffff0000, font, 36, 0, 20*line, "FAIL"); ili9341_write(ili9341, pax_buffer->buf); /* Cleanup */ ice40_disable(ice40); return ok; } void fpga_test(xQueueHandle buttonQueue, pax_buf_t* pax_buffer, ILI9341* ili9341) { run_fpga_tests(buttonQueue, pax_buffer, ili9341); test_wait_for_response(NULL); }