/* 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. */ #include "atomic.h" #include "extpower.h" #include "charge_manager.h" #include "common.h" #include "console.h" #include "driver/charger/bd9995x.h" #include "driver/tcpm/anx74xx.h" #include "driver/tcpm/ps8xxx.h" #include "gpio.h" #include "hooks.h" #include "host_command.h" #include "registers.h" #include "system.h" #include "task.h" #include "timer.h" #include "util.h" #include "usb_mux.h" #include "usb_pd.h" #include "usb_pd_tcpm.h" #define CPRINTF(format, args...) cprintf(CC_USBPD, format, ## args) #define CPRINTS(format, args...) cprints(CC_USBPD, format, ## args) #define PDO_FIXED_FLAGS (PDO_FIXED_DUAL_ROLE | PDO_FIXED_DATA_SWAP |\ PDO_FIXED_COMM_CAP) /* TODO: fill in correct source and sink capabilities */ const uint32_t pd_src_pdo[] = { PDO_FIXED(5000, 1500, PDO_FIXED_FLAGS), }; const int pd_src_pdo_cnt = ARRAY_SIZE(pd_src_pdo); const uint32_t pd_src_pdo_max[] = { PDO_FIXED(5000, 3000, PDO_FIXED_FLAGS), }; const int pd_src_pdo_max_cnt = ARRAY_SIZE(pd_src_pdo_max); const uint32_t pd_snk_pdo[] = { PDO_FIXED(5000, 500, PDO_FIXED_FLAGS), PDO_BATT(4750, 21000, 15000), PDO_VAR(4750, 21000, 3000), }; const int pd_snk_pdo_cnt = ARRAY_SIZE(pd_snk_pdo); int pd_is_valid_input_voltage(int mv) { return 1; } void pd_transition_voltage(int idx) { /* No-operation: we are always 5V */ } static uint8_t vbus_en[CONFIG_USB_PD_PORT_COUNT]; static uint8_t vbus_rp[CONFIG_USB_PD_PORT_COUNT] = {TYPEC_RP_1A5, TYPEC_RP_1A5}; int board_vbus_source_enabled(int port) { return vbus_en[port]; } static void board_vbus_update_source_current(int port) { enum gpio_signal gpio = port ? GPIO_USB_C1_5V_EN : GPIO_USB_C0_5V_EN; enum gpio_signal gpio_3a_en = port ? GPIO_EN_USB_C1_3A : GPIO_EN_USB_C0_3A; gpio_set_level(gpio_3a_en, vbus_rp[port] == TYPEC_RP_3A0 ? 1 : 0); gpio_set_level(gpio, vbus_en[port]); } void typec_set_source_current_limit(int port, int rp) { vbus_rp[port] = rp; /* change the GPIO driving the load switch if needed */ board_vbus_update_source_current(port); } int pd_set_power_supply_ready(int port) { /* Ensure we're not charging from this port */ bd9995x_select_input_port(port, 0); /* Ensure we advertise the proper available current quota */ charge_manager_source_port(port, 1); pd_set_vbus_discharge(port, 0); /* Provide VBUS */ vbus_en[port] = 1; board_vbus_update_source_current(port); /* notify host of power info change */ pd_send_host_event(PD_EVENT_POWER_CHANGE); return EC_SUCCESS; /* we are ready */ } void pd_power_supply_reset(int port) { int prev_en; prev_en = vbus_en[port]; /* Disable VBUS */ vbus_en[port] = 0; board_vbus_update_source_current(port); /* Enable discharge if we were previously sourcing 5V */ if (prev_en) pd_set_vbus_discharge(port, 1); /* Give back the current quota we are no longer using */ charge_manager_source_port(port, 0); /* notify host of power info change */ pd_send_host_event(PD_EVENT_POWER_CHANGE); } int pd_board_checks(void) { return EC_SUCCESS; } int pd_check_power_swap(int port) { /* * Allow power swap as long as we are acting as a dual role device, * otherwise assume our role is fixed (not in S0 or console command * to fix our role). */ return pd_get_dual_role() == PD_DRP_TOGGLE_ON ? 1 : 0; } int pd_check_data_swap(int port, int data_role) { /* * Allow data swap if we are a UFP, otherwise don't allow. * * When we are still in the Read-Only firmware, avoid swapping roles * so we don't jump in RW as a SNK/DFP and potentially confuse the * power supply by sending a soft-reset with wrong data role. */ return (data_role == PD_ROLE_UFP) && (system_get_image_copy() != SYSTEM_IMAGE_RO) ? 1 : 0; } int pd_check_vconn_swap(int port) { /* in G3, do not allow vconn swap since pp5000_A rail is off */ return gpio_get_level(GPIO_EN_PP5000); } void pd_execute_data_swap(int port, int data_role) { /* Do nothing */ } void pd_check_pr_role(int port, int pr_role, int flags) { /* * If partner is dual-role power and dualrole toggling is on, consider * if a power swap is necessary. */ if ((flags & PD_FLAGS_PARTNER_DR_POWER) && pd_get_dual_role() == PD_DRP_TOGGLE_ON) { /* * If we are a sink and partner is not externally powered, then * swap to become a source. If we are source and partner is * externally powered, swap to become a sink. */ int partner_extpower = flags & PD_FLAGS_PARTNER_EXTPOWER; if ((!partner_extpower && pr_role == PD_ROLE_SINK) || (partner_extpower && pr_role == PD_ROLE_SOURCE)) pd_request_power_swap(port); } } void pd_check_dr_role(int port, int dr_role, int flags) { /* If UFP, try to switch to DFP */ if ((flags & PD_FLAGS_PARTNER_DR_DATA) && dr_role == PD_ROLE_UFP && system_get_image_copy() != SYSTEM_IMAGE_RO) pd_request_data_swap(port); } /* ----------------- Vendor Defined Messages ------------------ */ const struct svdm_response svdm_rsp = { .identity = NULL, .svids = NULL, .modes = NULL, }; int pd_custom_vdm(int port, int cnt, uint32_t *payload, uint32_t **rpayload) { int cmd = PD_VDO_CMD(payload[0]); uint16_t dev_id = 0; int is_rw, is_latest; /* make sure we have some payload */ if (cnt == 0) return 0; switch (cmd) { case VDO_CMD_VERSION: /* guarantee last byte of payload is null character */ *(payload + cnt - 1) = 0; CPRINTF("version: %s\n", (char *)(payload+1)); break; case VDO_CMD_READ_INFO: case VDO_CMD_SEND_INFO: /* copy hash */ if (cnt == 7) { dev_id = VDO_INFO_HW_DEV_ID(payload[6]); is_rw = VDO_INFO_IS_RW(payload[6]); is_latest = pd_dev_store_rw_hash(port, dev_id, payload + 1, is_rw ? SYSTEM_IMAGE_RW : SYSTEM_IMAGE_RO); /* * Send update host event unless our RW hash is * already known to be the latest update RW. */ if (!is_rw || !is_latest) pd_send_host_event(PD_EVENT_UPDATE_DEVICE); CPRINTF("DevId:%d.%d SW:%d RW:%d\n", HW_DEV_ID_MAJ(dev_id), HW_DEV_ID_MIN(dev_id), VDO_INFO_SW_DBG_VER(payload[6]), is_rw); } else if (cnt == 6) { /* really old devices don't have last byte */ pd_dev_store_rw_hash(port, dev_id, payload + 1, SYSTEM_IMAGE_UNKNOWN); } break; case VDO_CMD_CURRENT: CPRINTF("Current: %dmA\n", payload[1]); break; case VDO_CMD_FLIP: usb_mux_flip(port); break; #ifdef CONFIG_USB_PD_LOGGING case VDO_CMD_GET_LOG: pd_log_recv_vdm(port, cnt, payload); break; #endif /* CONFIG_USB_PD_LOGGING */ } return 0; } #ifdef CONFIG_USB_PD_ALT_MODE_DFP static int dp_flags[CONFIG_USB_PD_PORT_COUNT]; static uint32_t dp_status[CONFIG_USB_PD_PORT_COUNT]; static void svdm_safe_dp_mode(int port) { /* make DP interface safe until configure */ dp_flags[port] = 0; dp_status[port] = 0; usb_mux_set(port, TYPEC_MUX_NONE, USB_SWITCH_CONNECT, pd_get_polarity(port)); } static int svdm_enter_dp_mode(int port, uint32_t mode_caps) { /* Only enter mode if device is DFP_D capable */ if (mode_caps & MODE_DP_SNK) { svdm_safe_dp_mode(port); return 0; } return -1; } static int svdm_dp_status(int port, uint32_t *payload) { int opos = pd_alt_mode(port, USB_SID_DISPLAYPORT); payload[0] = VDO(USB_SID_DISPLAYPORT, 1, CMD_DP_STATUS | VDO_OPOS(opos)); payload[1] = VDO_DP_STATUS(0, /* HPD IRQ ... not applicable */ 0, /* HPD level ... not applicable */ 0, /* exit DP? ... no */ 0, /* usb mode? ... no */ 0, /* multi-function ... no */ (!!(dp_flags[port] & DP_FLAGS_DP_ON)), 0, /* power low? ... no */ (!!(dp_flags[port] & DP_FLAGS_DP_ON))); return 2; }; static int svdm_dp_config(int port, uint32_t *payload) { int opos = pd_alt_mode(port, USB_SID_DISPLAYPORT); int mf_pref = PD_VDO_DPSTS_MF_PREF(dp_status[port]); int pin_mode = pd_dfp_dp_get_pin_mode(port, dp_status[port]); if (!pin_mode) return 0; usb_mux_set(port, mf_pref ? TYPEC_MUX_DOCK : TYPEC_MUX_DP, USB_SWITCH_CONNECT, pd_get_polarity(port)); payload[0] = VDO(USB_SID_DISPLAYPORT, 1, CMD_DP_CONFIG | VDO_OPOS(opos)); payload[1] = VDO_DP_CFG(pin_mode, /* pin mode */ 1, /* DPv1.3 signaling */ 2); /* UFP connected */ return 2; }; static void svdm_dp_post_config(int port) { const struct usb_mux *mux = &usb_muxes[port]; dp_flags[port] |= DP_FLAGS_DP_ON; if (!(dp_flags[port] & DP_FLAGS_HPD_HI_PENDING)) return; mux->hpd_update(port, 1, 0); } static int svdm_dp_attention(int port, uint32_t *payload) { int lvl = PD_VDO_DPSTS_HPD_LVL(payload[1]); int irq = PD_VDO_DPSTS_HPD_IRQ(payload[1]); const struct usb_mux *mux = &usb_muxes[port]; dp_status[port] = payload[1]; if (!(dp_flags[port] & DP_FLAGS_DP_ON)) { if (lvl) dp_flags[port] |= DP_FLAGS_HPD_HI_PENDING; return 1; } mux->hpd_update(port, lvl, irq); /* ack */ return 1; } static void svdm_exit_dp_mode(int port) { const struct usb_mux *mux = &usb_muxes[port]; svdm_safe_dp_mode(port); mux->hpd_update(port, 0, 0); } static int svdm_enter_gfu_mode(int port, uint32_t mode_caps) { /* Always enter GFU mode */ return 0; } static void svdm_exit_gfu_mode(int port) { } static int svdm_gfu_status(int port, uint32_t *payload) { /* * This is called after enter mode is successful, send unstructured * VDM to read info. */ pd_send_vdm(port, USB_VID_GOOGLE, VDO_CMD_READ_INFO, NULL, 0); return 0; } static int svdm_gfu_config(int port, uint32_t *payload) { return 0; } static int svdm_gfu_attention(int port, uint32_t *payload) { return 0; } const struct svdm_amode_fx supported_modes[] = { { .svid = USB_SID_DISPLAYPORT, .enter = &svdm_enter_dp_mode, .status = &svdm_dp_status, .config = &svdm_dp_config, .post_config = &svdm_dp_post_config, .attention = &svdm_dp_attention, .exit = &svdm_exit_dp_mode, }, { .svid = USB_VID_GOOGLE, .enter = &svdm_enter_gfu_mode, .status = &svdm_gfu_status, .config = &svdm_gfu_config, .attention = &svdm_gfu_attention, .exit = &svdm_exit_gfu_mode, } }; const int supported_modes_cnt = ARRAY_SIZE(supported_modes); #endif /* CONFIG_USB_PD_ALT_MODE_DFP */