/* Copyright 2017 The Chromium OS Authors. All rights reserved. * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ /* Tigertail board configuration */ #include "adc.h" #include "common.h" #include "console.h" #include "ec_version.h" #include "gpio.h" #include "hooks.h" #include "i2c.h" #include "ina2xx.h" #include "queue_policies.h" #include "registers.h" #include "task.h" #include "timer.h" #include "update_fw.h" #include "usart-stm32f0.h" #include "usart_tx_dma.h" #include "usart_rx_dma.h" #include "usb_i2c.h" #include "usb-stream.h" #include "util.h" #include "gpio_list.h" #define CPRINTS(format, args...) cprints(CC_SYSTEM, format, ## args) /****************************************************************************** * Forward UARTs as a USB serial interface. */ #define USB_STREAM_RX_SIZE 16 #define USB_STREAM_TX_SIZE 16 /****************************************************************************** * Forward USART1 as a simple USB serial interface. */ static struct usart_config const usart1; struct usb_stream_config const usart1_usb; static struct queue const usart1_to_usb = QUEUE_DIRECT(64, uint8_t, usart1.producer, usart1_usb.consumer); static struct queue const usb_to_usart1 = QUEUE_DIRECT(64, uint8_t, usart1_usb.producer, usart1.consumer); static struct usart_config const usart1 = USART_CONFIG(usart1_hw, usart_rx_interrupt, usart_tx_interrupt, 115200, 0, usart1_to_usb, usb_to_usart1); USB_STREAM_CONFIG(usart1_usb, USB_IFACE_USART1_STREAM, USB_STR_USART1_STREAM_NAME, USB_EP_USART1_STREAM, USB_STREAM_RX_SIZE, USB_STREAM_TX_SIZE, usb_to_usart1, usart1_to_usb) /****************************************************************************** * Define the strings used in our USB descriptors. */ const void *const usb_strings[] = { [USB_STR_DESC] = usb_string_desc, [USB_STR_VENDOR] = USB_STRING_DESC("Google Inc."), [USB_STR_PRODUCT] = USB_STRING_DESC("Tigertail"), [USB_STR_SERIALNO] = 0, [USB_STR_VERSION] = USB_STRING_DESC(CROS_EC_VERSION32), [USB_STR_I2C_NAME] = USB_STRING_DESC("I2C"), [USB_STR_USART1_STREAM_NAME] = USB_STRING_DESC("DUT UART"), [USB_STR_CONSOLE_NAME] = USB_STRING_DESC("Tigertail Console"), [USB_STR_UPDATE_NAME] = USB_STRING_DESC("Firmware update"), }; BUILD_ASSERT(ARRAY_SIZE(usb_strings) == USB_STR_COUNT); /****************************************************************************** * ADC support for SBU flip detect. */ /* ADC channels */ const struct adc_t adc_channels[] = { [ADC_SBU1] = {"SBU1", 3300, 4096, 0, STM32_AIN(6)}, [ADC_SBU2] = {"SBU2", 3300, 4096, 0, STM32_AIN(7)}, }; BUILD_ASSERT(ARRAY_SIZE(adc_channels) == ADC_CH_COUNT); /****************************************************************************** * Support I2C bridging over USB. */ /* I2C ports */ const struct i2c_port_t i2c_ports[] = { {"master", I2C_PORT_MASTER, 100, GPIO_MASTER_I2C_SCL, GPIO_MASTER_I2C_SDA}, }; const unsigned int i2c_ports_used = ARRAY_SIZE(i2c_ports); int usb_i2c_board_is_enabled(void) { return 1; } /****************************************************************************** * Console commands. */ /* State to indicate current GPIO config. */ static int uart_state = UART_OFF; /* State to indicate current autodetect mode. */ static int uart_detect = UART_DETECT_AUTO; const char *const uart_state_names[] = { [UART_OFF] = "off", [UART_ON_PP1800] = "on @ 1.8v", [UART_FLIP_PP1800] = "flip @ 1.8v", [UART_ON_PP3300] = "on @ 3.3v", [UART_FLIP_PP3300] = "flip @ 3.3v", [UART_AUTO] = "auto", }; /* Set GPIOs to configure UART mode. */ static void set_uart_gpios(int state) { int uart = GPIO_INPUT; int dir = 0; int voltage = 1; /* 1: 1.8v, 0: 3.3v */ int enabled = 0; gpio_set_level(GPIO_ST_UART_LVL_DIS, 1); switch (state) { case UART_ON_PP1800: uart = GPIO_ALTERNATE; dir = 1; voltage = 1; enabled = 1; break; case UART_FLIP_PP1800: uart = GPIO_ALTERNATE; dir = 0; voltage = 1; enabled = 1; break; case UART_ON_PP3300: uart = GPIO_ALTERNATE; dir = 1; voltage = 0; enabled = 1; break; case UART_FLIP_PP3300: uart = GPIO_ALTERNATE; dir = 0; voltage = 0; enabled = 1; break; default: /* Default to UART_OFF. */ uart = GPIO_INPUT; dir = 0; enabled = 0; } /* Set level shifter direction and voltage. */ gpio_set_level(GPIO_ST_UART_VREF, voltage); gpio_set_level(GPIO_ST_UART_TX_DIR, dir); gpio_set_level(GPIO_ST_UART_TX_DIR_N, !dir); /* Enable STM pinmux */ gpio_set_flags(GPIO_USART1_TX, uart); gpio_set_flags(GPIO_USART1_RX, uart); /* Flip uart orientation if necessary. */ STM32_USART_CR1(STM32_USART1_BASE) &= ~(STM32_USART_CR1_UE); if (dir) STM32_USART_CR2(STM32_USART1_BASE) &= ~(STM32_USART_CR2_SWAP); else STM32_USART_CR2(STM32_USART1_BASE) |= (STM32_USART_CR2_SWAP); STM32_USART_CR1(STM32_USART1_BASE) |= STM32_USART_CR1_UE; /* Enable level shifter. */ usleep(1000); gpio_set_level(GPIO_ST_UART_LVL_DIS, !enabled); } /* * Detect if a UART is plugged into SBU. Tigertail UART must be off * for this to return useful info. */ static int is_low(int mv) { return (mv < 190); } static int is_3300(int mv) { return ((mv > 3000) && (mv < 3400)); } static int is_1800(int mv) { return ((mv > 1600) && (mv < 1900)); } static int detect_uart_orientation(void) { int sbu1 = adc_read_channel(ADC_SBU1); int sbu2 = adc_read_channel(ADC_SBU2); int state = UART_OFF; /* * Here we check if one or the other SBU is 1.8v, as DUT * TX should idle high. */ if (is_low(sbu1) && is_1800(sbu2)) state = UART_ON_PP1800; else if (is_low(sbu2) && is_1800(sbu1)) state = UART_FLIP_PP1800; else if (is_low(sbu1) && is_3300(sbu2)) state = UART_ON_PP3300; else if (is_low(sbu2) && is_3300(sbu1)) state = UART_FLIP_PP3300; else state = UART_OFF; return state; } /* * Detect if UART has been unplugged. Normal UARTs should * have both lines idling high at 1.8v. */ static int detect_uart_idle(void) { int sbu1 = adc_read_channel(ADC_SBU1); int sbu2 = adc_read_channel(ADC_SBU2); int enabled = 0; if (is_1800(sbu1) && is_1800(sbu2)) enabled = 1; if (is_3300(sbu1) && is_3300(sbu2)) enabled = 1; return enabled; } /* Set the UART state and gpios, and autodetect if necessary. */ void set_uart_state(int state) { if (state == UART_AUTO) { set_uart_gpios(UART_OFF); msleep(10); uart_detect = UART_DETECT_AUTO; state = detect_uart_orientation(); } else { uart_detect = UART_DETECT_OFF; } uart_state = state; set_uart_gpios(state); } /* * Autodetect UART state: * We will check every 250ms, and change state if 1 second has passed * in the new state. */ void uart_sbu_tick(void) { static int debounce; /* = 0 */ if (uart_detect != UART_DETECT_AUTO) return; if (uart_state == UART_OFF) { int state = detect_uart_orientation(); if (state != UART_OFF) { debounce++; if (debounce > 4) { debounce = 0; CPRINTS("UART autoenable %s", uart_state_names[state]); uart_state = state; set_uart_gpios(state); } return; } } else { int enabled = detect_uart_idle(); if (!enabled) { debounce++; if (debounce > 4) { debounce = 0; CPRINTS("UART autodisable"); uart_state = UART_OFF; set_uart_gpios(UART_OFF); } return; } } debounce = 0; } DECLARE_HOOK(HOOK_TICK, uart_sbu_tick, HOOK_PRIO_DEFAULT); static int command_uart(int argc, char **argv) { const char *uart_state_str = "off"; const char *uart_detect_str = "manual"; if (argc > 1) { if (!strcasecmp("off", argv[1])) set_uart_state(UART_OFF); else if (!strcasecmp("on18", argv[1])) set_uart_state(UART_ON_PP1800); else if (!strcasecmp("on33", argv[1])) set_uart_state(UART_ON_PP3300); else if (!strcasecmp("flip18", argv[1])) set_uart_state(UART_FLIP_PP1800); else if (!strcasecmp("flip33", argv[1])) set_uart_state(UART_FLIP_PP3300); else if (!strcasecmp("auto", argv[1])) set_uart_state(UART_AUTO); else return EC_ERROR_PARAM1; } uart_state_str = uart_state_names[uart_state]; if (uart_detect == UART_DETECT_AUTO) uart_detect_str = "auto"; ccprintf("UART mux is: %s, setting: %s\n", uart_state_str, uart_detect_str); return EC_SUCCESS; } DECLARE_CONSOLE_COMMAND(uart, command_uart, "[off|on18|on33|flip18|flip33|auto]", "Set the sbu uart state\n" "WARNING: 3.3v may damage 1.8v devices.\n"); static void set_led_a(int r, int g, int b) { /* LEDs are active low */ gpio_set_level(GPIO_LED_R_L, !r); gpio_set_level(GPIO_LED_G_L, !g); gpio_set_level(GPIO_LED_B_L, !b); } static void set_led_b(int r, int g, int b) { gpio_set_level(GPIO_LED2_R_L, !r); gpio_set_level(GPIO_LED2_G_L, !g); gpio_set_level(GPIO_LED2_B_L, !b); } /* State we intend the mux GPIOs to be set. */ static int mux_state = MUX_OFF; static int last_mux_state = MUX_OFF; /* Set the state variable and GPIO configs to mux as requested. */ void set_mux_state(int state) { int enabled = (state == MUX_A) || (state == MUX_B); /* dir: 0 -> A, dir: 1 -> B */ int dir = (state == MUX_B); if (mux_state != state) last_mux_state = mux_state; /* Disconnect first. */ gpio_set_level(GPIO_USB_C_OE_N, 1); gpio_set_level(GPIO_SEL_RELAY_A, 0); gpio_set_level(GPIO_SEL_RELAY_B, 0); /* Let USB disconnect. */ msleep(100); /* Reconnect VBUS/CC in the requested direction. */ gpio_set_level(GPIO_SEL_RELAY_A, !dir && enabled); gpio_set_level(GPIO_SEL_RELAY_B, dir && enabled); /* Reconnect data. */ msleep(10); gpio_set_level(GPIO_USB_C_SEL_B, dir); gpio_set_level(GPIO_USB_C_OE_N, !enabled); if (!enabled) mux_state = MUX_OFF; else mux_state = state; if (state == MUX_A) set_led_a(0, 1, 0); else set_led_a(1, 0, 0); if (state == MUX_B) set_led_b(0, 1, 0); else set_led_b(1, 0, 0); } /* On button press, toggle between mux A, B, off. */ static int button_ready = 1; void button_interrupt_deferred(void) { switch (mux_state) { case MUX_OFF: if (last_mux_state == MUX_A) set_mux_state(MUX_B); else set_mux_state(MUX_A); break; case MUX_A: case MUX_B: default: set_mux_state(MUX_OFF); break; } button_ready = 1; } DECLARE_DEFERRED(button_interrupt_deferred); /* On button press, toggle between mux A, B, off. */ void button_interrupt(enum gpio_signal signal) { if (!button_ready) return; button_ready = 0; /* * button_ready is not set until set_mux_state completes, * which has ~100ms settle time for the mux, which also * provides for debouncing. */ hook_call_deferred(&button_interrupt_deferred_data, 0); } static int command_mux(int argc, char **argv) { char *mux_state_str = "off"; if (argc > 1) { if (!strcasecmp("off", argv[1])) set_mux_state(MUX_OFF); else if (!strcasecmp("a", argv[1])) set_mux_state(MUX_A); else if (!strcasecmp("b", argv[1])) set_mux_state(MUX_B); else return EC_ERROR_PARAM1; } if (mux_state == MUX_A) mux_state_str = "A"; if (mux_state == MUX_B) mux_state_str = "B"; ccprintf("TYPE-C mux is %s\n", mux_state_str); return EC_SUCCESS; } DECLARE_CONSOLE_COMMAND(mux, command_mux, "[off|A|B]", "Get/set the mux and enable state of the TYPE-C mux"); /****************************************************************************** * Initialize board. */ static void board_init(void) { /* USB to serial queues */ queue_init(&usart1_to_usb); queue_init(&usb_to_usart1); /* UART init */ usart_init(&usart1); /* * Default to port A, to allow easier charging and * detection of unconfigured devices. */ set_mux_state(MUX_A); /* Note that we can't enable AUTO until after init. */ set_uart_gpios(UART_OFF); /* Calibrate INA0 (VBUS) with 1mA/LSB scale */ ina2xx_init(0, 0x8000, INA2XX_CALIB_1MA(15 /*mOhm*/)); ina2xx_init(1, 0x8000, INA2XX_CALIB_1MA(15 /*mOhm*/)); ina2xx_init(4, 0x8000, INA2XX_CALIB_1MA(15 /*mOhm*/)); gpio_enable_interrupt(GPIO_BUTTON_L); } DECLARE_HOOK(HOOK_INIT, board_init, HOOK_PRIO_DEFAULT);