blob: 56b2a6d5623b65f0ac8bdfb0fe113783c8e7e67f [file] [log] [blame]
/* Copyright (c) 2016-2017, Linux Foundation. All rights reserved.
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 and
* only version 2 as published by the Free Software Foundation.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*/
#include <linux/completion.h>
#include <linux/delay.h>
#include <linux/hrtimer.h>
#include <linux/ipc_logging.h>
#include <linux/kernel.h>
#include <linux/list.h>
#include <linux/module.h>
#include <linux/of.h>
#include <linux/of_platform.h>
#include <linux/power_supply.h>
#include <linux/regulator/consumer.h>
#include <linux/slab.h>
#include <linux/spinlock.h>
#include <linux/workqueue.h>
#include <linux/extcon.h>
#include <linux/usb/class-dual-role.h>
#include <linux/usb/usbpd.h>
#include "usbpd.h"
/* To start USB stack for USB3.1 complaince testing */
static bool usb_compliance_mode;
module_param(usb_compliance_mode, bool, 0644);
MODULE_PARM_DESC(usb_compliance_mode, "Start USB stack for USB3.1 compliance testing");
static bool disable_usb_pd;
module_param(disable_usb_pd, bool, 0644);
MODULE_PARM_DESC(disable_usb_pd, "Disable USB PD for USB3.1 compliance testing");
static bool rev3_sink_only;
module_param(rev3_sink_only, bool, 0644);
MODULE_PARM_DESC(rev3_sink_only, "Enable power delivery rev3.0 sink only mode");
enum usbpd_state {
PE_UNKNOWN,
PE_ERROR_RECOVERY,
PE_SRC_DISABLED,
PE_SRC_STARTUP,
PE_SRC_SEND_CAPABILITIES,
PE_SRC_SEND_CAPABILITIES_WAIT, /* substate to wait for Request */
PE_SRC_NEGOTIATE_CAPABILITY,
PE_SRC_TRANSITION_SUPPLY,
PE_SRC_READY,
PE_SRC_HARD_RESET,
PE_SRC_SOFT_RESET,
PE_SRC_SEND_SOFT_RESET,
PE_SRC_DISCOVERY,
PE_SRC_TRANSITION_TO_DEFAULT,
PE_SNK_STARTUP,
PE_SNK_DISCOVERY,
PE_SNK_WAIT_FOR_CAPABILITIES,
PE_SNK_EVALUATE_CAPABILITY,
PE_SNK_SELECT_CAPABILITY,
PE_SNK_TRANSITION_SINK,
PE_SNK_READY,
PE_SNK_HARD_RESET,
PE_SNK_SOFT_RESET,
PE_SNK_SEND_SOFT_RESET,
PE_SNK_TRANSITION_TO_DEFAULT,
PE_DRS_SEND_DR_SWAP,
PE_PRS_SNK_SRC_SEND_SWAP,
PE_PRS_SNK_SRC_TRANSITION_TO_OFF,
PE_PRS_SNK_SRC_SOURCE_ON,
PE_PRS_SRC_SNK_SEND_SWAP,
PE_PRS_SRC_SNK_TRANSITION_TO_OFF,
PE_PRS_SRC_SNK_WAIT_SOURCE_ON,
PE_VCS_WAIT_FOR_VCONN,
};
static const char * const usbpd_state_strings[] = {
"UNKNOWN",
"ERROR_RECOVERY",
"SRC_Disabled",
"SRC_Startup",
"SRC_Send_Capabilities",
"SRC_Send_Capabilities (Wait for Request)",
"SRC_Negotiate_Capability",
"SRC_Transition_Supply",
"SRC_Ready",
"SRC_Hard_Reset",
"SRC_Soft_Reset",
"SRC_Send_Soft_Reset",
"SRC_Discovery",
"SRC_Transition_to_default",
"SNK_Startup",
"SNK_Discovery",
"SNK_Wait_for_Capabilities",
"SNK_Evaluate_Capability",
"SNK_Select_Capability",
"SNK_Transition_Sink",
"SNK_Ready",
"SNK_Hard_Reset",
"SNK_Soft_Reset",
"SNK_Send_Soft_Reset",
"SNK_Transition_to_default",
"DRS_Send_DR_Swap",
"PRS_SNK_SRC_Send_Swap",
"PRS_SNK_SRC_Transition_to_off",
"PRS_SNK_SRC_Source_on",
"PRS_SRC_SNK_Send_Swap",
"PRS_SRC_SNK_Transition_to_off",
"PRS_SRC_SNK_Wait_Source_on",
"VCS_Wait_for_VCONN",
};
enum usbpd_control_msg_type {
MSG_RESERVED = 0,
MSG_GOODCRC,
MSG_GOTOMIN,
MSG_ACCEPT,
MSG_REJECT,
MSG_PING,
MSG_PS_RDY,
MSG_GET_SOURCE_CAP,
MSG_GET_SINK_CAP,
MSG_DR_SWAP,
MSG_PR_SWAP,
MSG_VCONN_SWAP,
MSG_WAIT,
MSG_SOFT_RESET,
MSG_NOT_SUPPORTED = 0x10,
MSG_GET_SOURCE_CAP_EXTENDED,
MSG_GET_STATUS,
MSG_FR_SWAP,
MSG_GET_PPS_STATUS,
MSG_GET_COUNTRY_CODES,
};
enum usbpd_data_msg_type {
MSG_SOURCE_CAPABILITIES = 1,
MSG_REQUEST,
MSG_BIST,
MSG_SINK_CAPABILITIES,
MSG_BATTERY_STATUS,
MSG_ALERT,
MSG_GET_COUNTRY_INFO,
MSG_VDM = 0xF,
};
enum usbpd_ext_msg_type {
MSG_SOURCE_CAPABILITIES_EXTENDED = 1,
MSG_STATUS,
MSG_GET_BATTERY_CAP,
MSG_GET_BATTERY_STATUS,
MSG_BATTERY_CAPABILITIES,
MSG_GET_MANUFACTURER_INFO,
MSG_MANUFACTURER_INFO,
MSG_SECURITY_REQUEST,
MSG_SECURITY_RESPONSE,
MSG_FIRMWARE_UPDATE_REQUEST,
MSG_FIRMWARE_UPDATE_RESPONSE,
MSG_PPS_STATUS,
MSG_COUNTRY_INFO,
MSG_COUNTRY_CODES,
};
enum vdm_state {
VDM_NONE,
DISCOVERED_ID,
DISCOVERED_SVIDS,
DISCOVERED_MODES,
MODE_ENTERED,
MODE_EXITED,
};
static void *usbpd_ipc_log;
#define usbpd_dbg(dev, fmt, ...) do { \
ipc_log_string(usbpd_ipc_log, "%s: %s: " fmt, dev_name(dev), __func__, \
##__VA_ARGS__); \
dev_dbg(dev, fmt, ##__VA_ARGS__); \
} while (0)
#define usbpd_info(dev, fmt, ...) do { \
ipc_log_string(usbpd_ipc_log, "%s: %s: " fmt, dev_name(dev), __func__, \
##__VA_ARGS__); \
dev_info(dev, fmt, ##__VA_ARGS__); \
} while (0)
#define usbpd_warn(dev, fmt, ...) do { \
ipc_log_string(usbpd_ipc_log, "%s: %s: " fmt, dev_name(dev), __func__, \
##__VA_ARGS__); \
dev_warn(dev, fmt, ##__VA_ARGS__); \
} while (0)
#define usbpd_err(dev, fmt, ...) do { \
ipc_log_string(usbpd_ipc_log, "%s: %s: " fmt, dev_name(dev), __func__, \
##__VA_ARGS__); \
dev_err(dev, fmt, ##__VA_ARGS__); \
} while (0)
#define NUM_LOG_PAGES 10
/* Timeouts (in ms) */
#define ERROR_RECOVERY_TIME 25
#define SENDER_RESPONSE_TIME 26
#define SINK_WAIT_CAP_TIME 500
#define PS_TRANSITION_TIME 450
#define SRC_CAP_TIME 120
#define SRC_TRANSITION_TIME 25
#define SRC_RECOVER_TIME 750
#define PS_HARD_RESET_TIME 25
#define PS_SOURCE_ON 400
#define PS_SOURCE_OFF 750
#define FIRST_SOURCE_CAP_TIME 200
#define VDM_BUSY_TIME 50
#define VCONN_ON_TIME 100
/* tPSHardReset + tSafe0V */
#define SNK_HARD_RESET_VBUS_OFF_TIME (35 + 650)
/* tSrcRecover + tSrcTurnOn */
#define SNK_HARD_RESET_VBUS_ON_TIME (1000 + 275)
#define PD_CAPS_COUNT 50
#define PD_MAX_MSG_ID 7
#define PD_MAX_DATA_OBJ 7
#define PD_SRC_CAP_EXT_DB_LEN 24
#define PD_STATUS_DB_LEN 5
#define PD_BATTERY_CAP_DB_LEN 9
#define PD_MAX_EXT_MSG_LEN 260
#define PD_MAX_EXT_MSG_LEGACY_LEN 26
#define PD_MSG_HDR(type, dr, pr, id, cnt, rev) \
(((type) & 0x1F) | ((dr) << 5) | (rev << 6) | \
((pr) << 8) | ((id) << 9) | ((cnt) << 12))
#define PD_MSG_HDR_COUNT(hdr) (((hdr) >> 12) & 7)
#define PD_MSG_HDR_TYPE(hdr) ((hdr) & 0x1F)
#define PD_MSG_HDR_ID(hdr) (((hdr) >> 9) & 7)
#define PD_MSG_HDR_REV(hdr) (((hdr) >> 6) & 3)
#define PD_MSG_HDR_EXTENDED BIT(15)
#define PD_MSG_HDR_IS_EXTENDED(hdr) ((hdr) & PD_MSG_HDR_EXTENDED)
#define PD_MSG_EXT_HDR(chunked, num, req, size) \
(((chunked) << 15) | (((num) & 0xF) << 11) | \
((req) << 10) | ((size) & 0x1FF))
#define PD_MSG_EXT_HDR_IS_CHUNKED(ehdr) ((ehdr) & 0x8000)
#define PD_MSG_EXT_HDR_CHUNK_NUM(ehdr) (((ehdr) >> 11) & 0xF)
#define PD_MSG_EXT_HDR_REQ_CHUNK(ehdr) ((ehdr) & 0x400)
#define PD_MSG_EXT_HDR_DATA_SIZE(ehdr) ((ehdr) & 0x1FF)
#define PD_RDO_FIXED(obj, gb, mismatch, usb_comm, no_usb_susp, curr1, curr2) \
(((obj) << 28) | ((gb) << 27) | ((mismatch) << 26) | \
((usb_comm) << 25) | ((no_usb_susp) << 24) | \
((curr1) << 10) | (curr2))
#define PD_RDO_AUGMENTED(obj, mismatch, usb_comm, no_usb_susp, volt, curr) \
(((obj) << 28) | ((mismatch) << 26) | ((usb_comm) << 25) | \
((no_usb_susp) << 24) | ((volt) << 9) | (curr))
#define PD_RDO_OBJ_POS(rdo) ((rdo) >> 28 & 7)
#define PD_RDO_GIVEBACK(rdo) ((rdo) >> 27 & 1)
#define PD_RDO_MISMATCH(rdo) ((rdo) >> 26 & 1)
#define PD_RDO_USB_COMM(rdo) ((rdo) >> 25 & 1)
#define PD_RDO_NO_USB_SUSP(rdo) ((rdo) >> 24 & 1)
#define PD_RDO_FIXED_CURR(rdo) ((rdo) >> 10 & 0x3FF)
#define PD_RDO_FIXED_CURR_MINMAX(rdo) ((rdo) & 0x3FF)
#define PD_RDO_PROG_VOLTAGE(rdo) ((rdo) >> 9 & 0x7FF)
#define PD_RDO_PROG_CURR(rdo) ((rdo) & 0x7F)
#define PD_SRC_PDO_TYPE(pdo) (((pdo) >> 30) & 3)
#define PD_SRC_PDO_TYPE_FIXED 0
#define PD_SRC_PDO_TYPE_BATTERY 1
#define PD_SRC_PDO_TYPE_VARIABLE 2
#define PD_SRC_PDO_TYPE_AUGMENTED 3
#define PD_SRC_PDO_FIXED_PR_SWAP(pdo) (((pdo) >> 29) & 1)
#define PD_SRC_PDO_FIXED_USB_SUSP(pdo) (((pdo) >> 28) & 1)
#define PD_SRC_PDO_FIXED_EXT_POWERED(pdo) (((pdo) >> 27) & 1)
#define PD_SRC_PDO_FIXED_USB_COMM(pdo) (((pdo) >> 26) & 1)
#define PD_SRC_PDO_FIXED_DR_SWAP(pdo) (((pdo) >> 25) & 1)
#define PD_SRC_PDO_FIXED_PEAK_CURR(pdo) (((pdo) >> 20) & 3)
#define PD_SRC_PDO_FIXED_VOLTAGE(pdo) (((pdo) >> 10) & 0x3FF)
#define PD_SRC_PDO_FIXED_MAX_CURR(pdo) ((pdo) & 0x3FF)
#define PD_SRC_PDO_VAR_BATT_MAX_VOLT(pdo) (((pdo) >> 20) & 0x3FF)
#define PD_SRC_PDO_VAR_BATT_MIN_VOLT(pdo) (((pdo) >> 10) & 0x3FF)
#define PD_SRC_PDO_VAR_BATT_MAX(pdo) ((pdo) & 0x3FF)
#define PD_APDO_PPS(pdo) (((pdo) >> 28) & 3)
#define PD_APDO_MAX_VOLT(pdo) (((pdo) >> 17) & 0xFF)
#define PD_APDO_MIN_VOLT(pdo) (((pdo) >> 8) & 0xFF)
#define PD_APDO_MAX_CURR(pdo) ((pdo) & 0x7F)
/* Vendor Defined Messages */
#define MAX_CRC_RECEIVE_TIME 9 /* ~(2 * tReceive_max(1.1ms) * # retry 4) */
#define MAX_VDM_RESPONSE_TIME 60 /* 2 * tVDMSenderResponse_max(30ms) */
#define MAX_VDM_BUSY_TIME 100 /* 2 * tVDMBusy (50ms) */
#define PD_SNK_PDO_FIXED(prs, hc, uc, usb_comm, drs, volt, curr) \
(((prs) << 29) | ((hc) << 28) | ((uc) << 27) | ((usb_comm) << 26) | \
((drs) << 25) | ((volt) << 10) | (curr))
/* VDM header is the first 32-bit object following the 16-bit PD header */
#define VDM_HDR_SVID(hdr) ((hdr) >> 16)
#define VDM_IS_SVDM(hdr) ((hdr) & 0x8000)
#define SVDM_HDR_OBJ_POS(hdr) (((hdr) >> 8) & 0x7)
#define SVDM_HDR_CMD_TYPE(hdr) (((hdr) >> 6) & 0x3)
#define SVDM_HDR_CMD(hdr) ((hdr) & 0x1f)
#define SVDM_HDR(svid, ver, obj, cmd_type, cmd) \
(((svid) << 16) | (1 << 15) | ((ver) << 13) \
| ((obj) << 8) | ((cmd_type) << 6) | (cmd))
/* discover id response vdo bit fields */
#define ID_HDR_USB_HOST BIT(31)
#define ID_HDR_USB_DEVICE BIT(30)
#define ID_HDR_MODAL_OPR BIT(26)
#define ID_HDR_PRODUCT_TYPE(n) ((n) >> 27)
#define ID_HDR_PRODUCT_PER_MASK (2 << 27)
#define ID_HDR_PRODUCT_HUB 1
#define ID_HDR_PRODUCT_PER 2
#define ID_HDR_PRODUCT_AMA 5
#define ID_HDR_VID 0x05c6 /* qcom */
#define PROD_VDO_PID 0x0a00 /* TBD */
static bool check_vsafe0v = true;
module_param(check_vsafe0v, bool, 0600);
static int min_sink_current = 900;
module_param(min_sink_current, int, 0600);
static const u32 default_src_caps[] = { 0x36019096 }; /* VSafe5V @ 1.5A */
static const u32 default_snk_caps[] = { 0x2601912C }; /* VSafe5V @ 3A */
struct vdm_tx {
u32 data[PD_MAX_DATA_OBJ];
int size;
};
struct rx_msg {
u16 hdr;
u16 data_len; /* size of payload in bytes */
struct list_head entry;
u8 payload[];
};
#define IS_DATA(m, t) ((m) && !PD_MSG_HDR_IS_EXTENDED((m)->hdr) && \
PD_MSG_HDR_COUNT((m)->hdr) && \
(PD_MSG_HDR_TYPE((m)->hdr) == (t)))
#define IS_CTRL(m, t) ((m) && !PD_MSG_HDR_COUNT((m)->hdr) && \
(PD_MSG_HDR_TYPE((m)->hdr) == (t)))
#define IS_EXT(m, t) ((m) && PD_MSG_HDR_IS_EXTENDED((m)->hdr) && \
(PD_MSG_HDR_TYPE((m)->hdr) == (t)))
struct usbpd {
struct device dev;
struct workqueue_struct *wq;
struct work_struct sm_work;
struct hrtimer timer;
bool sm_queued;
struct extcon_dev *extcon;
enum usbpd_state current_state;
bool hard_reset_recvd;
ktime_t hard_reset_recvd_time;
struct list_head rx_q;
spinlock_t rx_lock;
struct rx_msg *rx_ext_msg;
u32 received_pdos[PD_MAX_DATA_OBJ];
u32 received_ado;
u16 src_cap_id;
u8 selected_pdo;
u8 requested_pdo;
u32 rdo; /* can be either source or sink */
int current_voltage; /* uV */
int requested_voltage; /* uV */
int requested_current; /* mA */
bool pd_connected;
bool in_explicit_contract;
bool peer_usb_comm;
bool peer_pr_swap;
bool peer_dr_swap;
u32 sink_caps[7];
int num_sink_caps;
struct power_supply *usb_psy;
struct notifier_block psy_nb;
enum power_supply_typec_mode typec_mode;
enum power_supply_type psy_type;
enum power_supply_typec_power_role forced_pr;
bool vbus_present;
enum pd_spec_rev spec_rev;
enum data_role current_dr;
enum power_role current_pr;
bool in_pr_swap;
bool pd_phy_opened;
bool send_request;
struct completion is_ready;
struct completion tx_chunk_request;
u8 next_tx_chunk;
struct mutex swap_lock;
struct dual_role_phy_instance *dual_role;
struct dual_role_phy_desc dr_desc;
bool send_pr_swap;
bool send_dr_swap;
struct regulator *vbus;
struct regulator *vconn;
bool vbus_enabled;
bool vconn_enabled;
bool vconn_is_external;
u8 tx_msgid;
u8 rx_msgid;
int caps_count;
int hard_reset_count;
enum vdm_state vdm_state;
u16 *discovered_svids;
int num_svids;
struct vdm_tx *vdm_tx;
struct vdm_tx *vdm_tx_retry;
struct mutex svid_handler_lock;
struct list_head svid_handlers;
struct list_head instance;
u16 ss_lane_svid;
/* ext msg support */
bool send_get_src_cap_ext;
u8 src_cap_ext_db[PD_SRC_CAP_EXT_DB_LEN];
bool send_get_pps_status;
u32 pps_status_db;
u8 status_db[PD_STATUS_DB_LEN];
bool send_get_battery_cap;
u8 get_battery_cap_db;
u8 battery_cap_db[PD_BATTERY_CAP_DB_LEN];
u8 get_battery_status_db;
bool send_get_battery_status;
u32 battery_sts_dobj;
};
static LIST_HEAD(_usbpd); /* useful for debugging */
static const unsigned int usbpd_extcon_cable[] = {
EXTCON_USB,
EXTCON_USB_HOST,
EXTCON_NONE,
};
/* EXTCON_USB and EXTCON_USB_HOST are mutually exclusive */
static const u32 usbpd_extcon_exclusive[] = {0x3, 0};
enum plug_orientation usbpd_get_plug_orientation(struct usbpd *pd)
{
int ret;
union power_supply_propval val;
ret = power_supply_get_property(pd->usb_psy,
POWER_SUPPLY_PROP_TYPEC_CC_ORIENTATION, &val);
if (ret)
return ORIENTATION_NONE;
return val.intval;
}
EXPORT_SYMBOL(usbpd_get_plug_orientation);
static unsigned int get_connector_type(struct usbpd *pd)
{
int ret;
union power_supply_propval val;
ret = power_supply_get_property(pd->usb_psy,
POWER_SUPPLY_PROP_CONNECTOR_TYPE, &val);
if (ret) {
dev_err(&pd->dev, "Unable to read CONNECTOR TYPE: %d\n", ret);
return ret;
}
return val.intval;
}
static inline void stop_usb_host(struct usbpd *pd)
{
extcon_set_state_sync(pd->extcon, EXTCON_USB_HOST, 0);
}
static inline void start_usb_host(struct usbpd *pd, bool ss)
{
enum plug_orientation cc = usbpd_get_plug_orientation(pd);
union extcon_property_value val;
val.intval = (cc == ORIENTATION_CC2);
extcon_set_property(pd->extcon, EXTCON_USB_HOST,
EXTCON_PROP_USB_TYPEC_POLARITY, val);
val.intval = ss;
extcon_set_property(pd->extcon, EXTCON_USB_HOST,
EXTCON_PROP_USB_SS, val);
extcon_set_state_sync(pd->extcon, EXTCON_USB_HOST, 1);
}
static inline void stop_usb_peripheral(struct usbpd *pd)
{
extcon_set_state_sync(pd->extcon, EXTCON_USB, 0);
}
static inline void start_usb_peripheral(struct usbpd *pd)
{
enum plug_orientation cc = usbpd_get_plug_orientation(pd);
union extcon_property_value val;
val.intval = (cc == ORIENTATION_CC2);
extcon_set_property(pd->extcon, EXTCON_USB,
EXTCON_PROP_USB_TYPEC_POLARITY, val);
val.intval = 1;
extcon_set_property(pd->extcon, EXTCON_USB, EXTCON_PROP_USB_SS, val);
extcon_set_state_sync(pd->extcon, EXTCON_USB, 1);
}
/**
* This API allows client driver to request for releasing SS lanes. It should
* not be called from atomic context.
*
* @pd - USBPD handler
* @hdlr - client's handler
*
* @returns int - Success - 0, else negative error code
*/
static int usbpd_release_ss_lane(struct usbpd *pd,
struct usbpd_svid_handler *hdlr)
{
int ret = 0;
if (!hdlr || !pd)
return -EINVAL;
usbpd_dbg(&pd->dev, "hdlr:%pK svid:%d", hdlr, hdlr->svid);
/*
* If USB SS lanes are already used by one client, and other client is
* requesting for same or same client requesting again, return -EBUSY.
*/
if (pd->ss_lane_svid) {
usbpd_dbg(&pd->dev, "-EBUSY: ss_lanes are already used by(%d)",
pd->ss_lane_svid);
ret = -EBUSY;
goto err_exit;
}
ret = extcon_blocking_sync(pd->extcon, EXTCON_USB_HOST, 0);
if (ret) {
usbpd_err(&pd->dev, "err(%d) for releasing ss lane", ret);
goto err_exit;
}
pd->ss_lane_svid = hdlr->svid;
err_exit:
return ret;
}
static int set_power_role(struct usbpd *pd, enum power_role pr)
{
union power_supply_propval val = {0};
switch (pr) {
case PR_NONE:
val.intval = POWER_SUPPLY_TYPEC_PR_NONE;
break;
case PR_SINK:
val.intval = POWER_SUPPLY_TYPEC_PR_SINK;
break;
case PR_SRC:
val.intval = POWER_SUPPLY_TYPEC_PR_SOURCE;
break;
}
return power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_TYPEC_POWER_ROLE, &val);
}
static struct usbpd_svid_handler *find_svid_handler(struct usbpd *pd, u16 svid)
{
struct usbpd_svid_handler *handler;
mutex_lock(&pd->svid_handler_lock);
list_for_each_entry(handler, &pd->svid_handlers, entry) {
if (svid == handler->svid) {
mutex_unlock(&pd->svid_handler_lock);
return handler;
}
}
mutex_unlock(&pd->svid_handler_lock);
return NULL;
}
/* Reset protocol layer */
static inline void pd_reset_protocol(struct usbpd *pd)
{
/*
* first Rx ID should be 0; set this to a sentinel of -1 so that in
* phy_msg_received() we can check if we had seen it before.
*/
pd->rx_msgid = -1;
pd->tx_msgid = 0;
pd->send_request = false;
pd->send_pr_swap = false;
pd->send_dr_swap = false;
}
static int pd_send_msg(struct usbpd *pd, u8 msg_type, const u32 *data,
size_t num_data, enum pd_sop_type sop)
{
int ret;
u16 hdr;
if (pd->hard_reset_recvd)
return -EBUSY;
hdr = PD_MSG_HDR(msg_type, pd->current_dr, pd->current_pr,
pd->tx_msgid, num_data, pd->spec_rev);
ret = pd_phy_write(hdr, (u8 *)data, num_data * sizeof(u32), sop);
if (ret)
return ret;
pd->tx_msgid = (pd->tx_msgid + 1) & PD_MAX_MSG_ID;
return 0;
}
static int pd_send_ext_msg(struct usbpd *pd, u8 msg_type,
const u8 *data, size_t data_len, enum pd_sop_type sop)
{
int ret;
size_t len_remain, chunk_len;
u8 chunked_payload[PD_MAX_DATA_OBJ * sizeof(u32)] = {0};
u16 hdr;
u16 ext_hdr;
u8 num_objs;
if (data_len > PD_MAX_EXT_MSG_LEN) {
usbpd_warn(&pd->dev, "Extended message length exceeds max, truncating...\n");
data_len = PD_MAX_EXT_MSG_LEN;
}
pd->next_tx_chunk = 0;
len_remain = data_len;
do {
ext_hdr = PD_MSG_EXT_HDR(1, pd->next_tx_chunk++, 0, data_len);
memcpy(chunked_payload, &ext_hdr, sizeof(ext_hdr));
chunk_len = min_t(size_t, len_remain,
PD_MAX_EXT_MSG_LEGACY_LEN);
memcpy(chunked_payload + sizeof(ext_hdr), data, chunk_len);
num_objs = DIV_ROUND_UP(chunk_len + sizeof(u16), sizeof(u32));
len_remain -= chunk_len;
reinit_completion(&pd->tx_chunk_request);
hdr = PD_MSG_HDR(msg_type, pd->current_dr, pd->current_pr,
pd->tx_msgid, num_objs, pd->spec_rev) |
PD_MSG_HDR_EXTENDED;
ret = pd_phy_write(hdr, chunked_payload,
num_objs * sizeof(u32), sop);
if (ret)
return ret;
pd->tx_msgid = (pd->tx_msgid + 1) & PD_MAX_MSG_ID;
/* Wait for request chunk */
if (len_remain &&
!wait_for_completion_timeout(&pd->tx_chunk_request,
msecs_to_jiffies(SENDER_RESPONSE_TIME))) {
usbpd_err(&pd->dev, "Timed out waiting for chunk request\n");
return -EPROTO;
}
} while (len_remain);
return 0;
}
static int pd_select_pdo(struct usbpd *pd, int pdo_pos, int uv, int ua)
{
int curr;
int max_current;
bool mismatch = false;
u8 type;
u32 pdo = pd->received_pdos[pdo_pos - 1];
type = PD_SRC_PDO_TYPE(pdo);
if (type == PD_SRC_PDO_TYPE_FIXED) {
curr = max_current = PD_SRC_PDO_FIXED_MAX_CURR(pdo) * 10;
/*
* Check if the PDO has enough current, otherwise set the
* Capability Mismatch flag
*/
if (curr < min_sink_current) {
mismatch = true;
max_current = min_sink_current;
}
pd->requested_voltage =
PD_SRC_PDO_FIXED_VOLTAGE(pdo) * 50 * 1000;
pd->rdo = PD_RDO_FIXED(pdo_pos, 0, mismatch, 1, 1, curr / 10,
max_current / 10);
} else if (type == PD_SRC_PDO_TYPE_AUGMENTED) {
if ((uv / 100000) > PD_APDO_MAX_VOLT(pdo) ||
(uv / 100000) < PD_APDO_MIN_VOLT(pdo) ||
(ua / 50000) > PD_APDO_MAX_CURR(pdo) || (ua < 0)) {
usbpd_err(&pd->dev, "uv (%d) and ua (%d) out of range of APDO\n",
uv, ua);
return -EINVAL;
}
curr = ua / 1000;
pd->requested_voltage = uv;
pd->rdo = PD_RDO_AUGMENTED(pdo_pos, mismatch, 1, 1,
uv / 20000, ua / 50000);
} else {
usbpd_err(&pd->dev, "Only Fixed or Programmable PDOs supported\n");
return -ENOTSUPP;
}
/* Can't sink more than 5V if VCONN is sourced from the VBUS input */
if (pd->vconn_enabled && !pd->vconn_is_external &&
pd->requested_voltage > 5000000)
return -ENOTSUPP;
pd->requested_current = curr;
pd->requested_pdo = pdo_pos;
return 0;
}
static int pd_eval_src_caps(struct usbpd *pd)
{
int i;
union power_supply_propval val;
u32 first_pdo = pd->received_pdos[0];
if (PD_SRC_PDO_TYPE(first_pdo) != PD_SRC_PDO_TYPE_FIXED) {
usbpd_err(&pd->dev, "First src_cap invalid! %08x\n", first_pdo);
return -EINVAL;
}
pd->peer_usb_comm = PD_SRC_PDO_FIXED_USB_COMM(first_pdo);
pd->peer_pr_swap = PD_SRC_PDO_FIXED_PR_SWAP(first_pdo);
pd->peer_dr_swap = PD_SRC_PDO_FIXED_DR_SWAP(first_pdo);
val.intval = PD_SRC_PDO_FIXED_USB_SUSP(first_pdo);
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_USB_SUSPEND_SUPPORTED, &val);
if (pd->spec_rev == USBPD_REV_30 && !rev3_sink_only) {
bool pps_found = false;
/* downgrade to 2.0 if no PPS */
for (i = 1; i < PD_MAX_DATA_OBJ; i++) {
if ((PD_SRC_PDO_TYPE(pd->received_pdos[i]) ==
PD_SRC_PDO_TYPE_AUGMENTED) &&
!PD_APDO_PPS(pd->received_pdos[i])) {
pps_found = true;
break;
}
}
if (!pps_found)
pd->spec_rev = USBPD_REV_20;
}
/* Select the first PDO (vSafe5V) immediately. */
pd_select_pdo(pd, 1, 0, 0);
return 0;
}
static void pd_send_hard_reset(struct usbpd *pd)
{
union power_supply_propval val = {0};
usbpd_dbg(&pd->dev, "send hard reset");
/* Force CC logic to source/sink to keep Rp/Rd unchanged */
set_power_role(pd, pd->current_pr);
pd->hard_reset_count++;
pd_phy_signal(HARD_RESET_SIG);
pd->in_pr_swap = false;
power_supply_set_property(pd->usb_psy, POWER_SUPPLY_PROP_PR_SWAP, &val);
}
static void kick_sm(struct usbpd *pd, int ms)
{
pm_stay_awake(&pd->dev);
pd->sm_queued = true;
if (ms)
hrtimer_start(&pd->timer, ms_to_ktime(ms), HRTIMER_MODE_REL);
else
queue_work(pd->wq, &pd->sm_work);
}
static void phy_sig_received(struct usbpd *pd, enum pd_sig_type sig)
{
union power_supply_propval val = {1};
if (sig != HARD_RESET_SIG) {
usbpd_err(&pd->dev, "invalid signal (%d) received\n", sig);
return;
}
pd->hard_reset_recvd = true;
pd->hard_reset_recvd_time = ktime_get();
usbpd_err(&pd->dev, "hard reset received\n");
/* Force CC logic to source/sink to keep Rp/Rd unchanged */
set_power_role(pd, pd->current_pr);
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_IN_HARD_RESET, &val);
kick_sm(pd, 0);
}
struct pd_request_chunk {
struct work_struct w;
struct usbpd *pd;
u8 msg_type;
u8 chunk_num;
enum pd_sop_type sop;
};
static void pd_request_chunk_work(struct work_struct *w)
{
struct pd_request_chunk *req =
container_of(w, struct pd_request_chunk, w);
struct usbpd *pd = req->pd;
unsigned long flags;
int ret;
u8 payload[4] = {0}; /* ext_hdr + padding */
u16 hdr = PD_MSG_HDR(req->msg_type, pd->current_dr, pd->current_pr,
pd->tx_msgid, 1, pd->spec_rev) | PD_MSG_HDR_EXTENDED;
*(u16 *)payload = PD_MSG_EXT_HDR(1, req->chunk_num, 1, 0);
ret = pd_phy_write(hdr, payload, sizeof(payload), req->sop);
if (!ret) {
pd->tx_msgid = (pd->tx_msgid + 1) & PD_MAX_MSG_ID;
} else {
usbpd_err(&pd->dev, "could not send chunk request\n");
/* queue what we have anyway */
spin_lock_irqsave(&pd->rx_lock, flags);
list_add_tail(&pd->rx_ext_msg->entry, &pd->rx_q);
spin_unlock_irqrestore(&pd->rx_lock, flags);
pd->rx_ext_msg = NULL;
}
kfree(req);
}
static struct rx_msg *pd_ext_msg_received(struct usbpd *pd, u16 header, u8 *buf,
size_t len, enum pd_sop_type sop)
{
struct rx_msg *rx_msg;
u16 bytes_to_copy;
u16 ext_hdr = *(u16 *)buf;
u8 chunk_num;
if (!PD_MSG_EXT_HDR_IS_CHUNKED(ext_hdr)) {
usbpd_err(&pd->dev, "unchunked extended messages unsupported\n");
return NULL;
}
/* request for next Tx chunk */
if (PD_MSG_EXT_HDR_REQ_CHUNK(ext_hdr)) {
if (PD_MSG_EXT_HDR_DATA_SIZE(ext_hdr) ||
PD_MSG_EXT_HDR_CHUNK_NUM(ext_hdr) !=
pd->next_tx_chunk) {
usbpd_err(&pd->dev, "invalid request chunk ext header 0x%02x\n",
ext_hdr);
return NULL;
}
if (!completion_done(&pd->tx_chunk_request))
complete(&pd->tx_chunk_request);
return NULL;
}
chunk_num = PD_MSG_EXT_HDR_CHUNK_NUM(ext_hdr);
if (!chunk_num) {
/* allocate new message if first chunk */
rx_msg = kzalloc(sizeof(*rx_msg) +
PD_MSG_EXT_HDR_DATA_SIZE(ext_hdr),
GFP_ATOMIC);
if (!rx_msg)
return NULL;
rx_msg->hdr = header;
rx_msg->data_len = PD_MSG_EXT_HDR_DATA_SIZE(ext_hdr);
if (rx_msg->data_len > PD_MAX_EXT_MSG_LEN) {
usbpd_warn(&pd->dev, "Extended message length exceeds max, truncating...\n");
rx_msg->data_len = PD_MAX_EXT_MSG_LEN;
}
} else {
if (!pd->rx_ext_msg) {
usbpd_err(&pd->dev, "missing first rx_ext_msg chunk\n");
return NULL;
}
rx_msg = pd->rx_ext_msg;
}
/*
* The amount to copy is derived as follows:
*
* - if extended data_len < 26, then copy data_len bytes
* - for chunks 0..N-2, copy 26 bytes
* - for the last chunk (N-1), copy the remainder
*/
bytes_to_copy =
min((rx_msg->data_len - chunk_num * PD_MAX_EXT_MSG_LEGACY_LEN),
PD_MAX_EXT_MSG_LEGACY_LEN);
/* check against received length to avoid overrun */
if (bytes_to_copy > len - sizeof(ext_hdr)) {
usbpd_warn(&pd->dev, "not enough bytes in chunk, expected:%u received:%lu\n",
bytes_to_copy, len - sizeof(ext_hdr));
bytes_to_copy = len - sizeof(ext_hdr);
}
memcpy(rx_msg->payload + chunk_num * PD_MAX_EXT_MSG_LEGACY_LEN, buf + 2,
bytes_to_copy);
/* request next chunk? */
if ((rx_msg->data_len - chunk_num * PD_MAX_EXT_MSG_LEGACY_LEN) >
PD_MAX_EXT_MSG_LEGACY_LEN) {
struct pd_request_chunk *req;
if (pd->rx_ext_msg && pd->rx_ext_msg != rx_msg) {
usbpd_dbg(&pd->dev, "stale previous rx_ext_msg?\n");
kfree(pd->rx_ext_msg);
}
pd->rx_ext_msg = rx_msg;
req = kzalloc(sizeof(*req), GFP_ATOMIC);
if (!req)
goto queue_rx; /* return what we have anyway */
INIT_WORK(&req->w, pd_request_chunk_work);
req->pd = pd;
req->msg_type = PD_MSG_HDR_TYPE(header);
req->chunk_num = chunk_num + 1;
req->sop = sop;
queue_work(pd->wq, &req->w);
return NULL;
}
queue_rx:
pd->rx_ext_msg = NULL;
return rx_msg; /* queue it for usbpd_sm */
}
static void phy_msg_received(struct usbpd *pd, enum pd_sop_type sop,
u8 *buf, size_t len)
{
struct rx_msg *rx_msg;
unsigned long flags;
u16 header;
if (sop != SOP_MSG) {
usbpd_err(&pd->dev, "invalid msg type (%d) received; only SOP supported\n",
sop);
return;
}
if (len < 2) {
usbpd_err(&pd->dev, "invalid message received, len=%zd\n", len);
return;
}
header = *((u16 *)buf);
buf += sizeof(u16);
len -= sizeof(u16);
if (len % 4 != 0) {
usbpd_err(&pd->dev, "len=%zd not multiple of 4\n", len);
return;
}
/* if MSGID already seen, discard */
if (PD_MSG_HDR_ID(header) == pd->rx_msgid &&
PD_MSG_HDR_TYPE(header) != MSG_SOFT_RESET) {
usbpd_dbg(&pd->dev, "MessageID already seen, discarding\n");
return;
}
pd->rx_msgid = PD_MSG_HDR_ID(header);
/* discard Pings */
if (PD_MSG_HDR_TYPE(header) == MSG_PING && !len)
return;
/* check header's count field to see if it matches len */
if (PD_MSG_HDR_COUNT(header) != (len / 4)) {
usbpd_err(&pd->dev, "header count (%d) mismatch, len=%zd\n",
PD_MSG_HDR_COUNT(header), len);
return;
}
/* if spec rev differs (i.e. is older), update PHY */
if (PD_MSG_HDR_REV(header) < pd->spec_rev)
pd->spec_rev = PD_MSG_HDR_REV(header);
usbpd_dbg(&pd->dev, "received message: type(%d) num_objs(%d)\n",
PD_MSG_HDR_TYPE(header), PD_MSG_HDR_COUNT(header));
if (!PD_MSG_HDR_IS_EXTENDED(header)) {
rx_msg = kzalloc(sizeof(*rx_msg) + len, GFP_ATOMIC);
if (!rx_msg)
return;
rx_msg->hdr = header;
rx_msg->data_len = len;
memcpy(rx_msg->payload, buf, len);
} else {
rx_msg = pd_ext_msg_received(pd, header, buf, len, sop);
if (!rx_msg)
return;
}
spin_lock_irqsave(&pd->rx_lock, flags);
list_add_tail(&rx_msg->entry, &pd->rx_q);
spin_unlock_irqrestore(&pd->rx_lock, flags);
kick_sm(pd, 0);
}
static void phy_shutdown(struct usbpd *pd)
{
usbpd_dbg(&pd->dev, "shutdown");
if (pd->vconn_enabled) {
regulator_disable(pd->vconn);
pd->vconn_enabled = false;
}
if (pd->vbus_enabled) {
regulator_disable(pd->vbus);
pd->vbus_enabled = false;
}
}
static enum hrtimer_restart pd_timeout(struct hrtimer *timer)
{
struct usbpd *pd = container_of(timer, struct usbpd, timer);
usbpd_dbg(&pd->dev, "timeout");
queue_work(pd->wq, &pd->sm_work);
return HRTIMER_NORESTART;
}
/* Enters new state and executes actions on entry */
static void usbpd_set_state(struct usbpd *pd, enum usbpd_state next_state)
{
struct pd_phy_params phy_params = {
.signal_cb = phy_sig_received,
.msg_rx_cb = phy_msg_received,
.shutdown_cb = phy_shutdown,
.frame_filter_val = FRAME_FILTER_EN_SOP |
FRAME_FILTER_EN_HARD_RESET,
};
union power_supply_propval val = {0};
unsigned long flags;
int ret;
if (pd->hard_reset_recvd) /* let usbpd_sm handle it */
return;
usbpd_dbg(&pd->dev, "%s -> %s\n",
usbpd_state_strings[pd->current_state],
usbpd_state_strings[next_state]);
pd->current_state = next_state;
switch (next_state) {
case PE_ERROR_RECOVERY: /* perform hard disconnect/reconnect */
pd->in_pr_swap = false;
pd->current_pr = PR_NONE;
set_power_role(pd, PR_NONE);
pd->typec_mode = POWER_SUPPLY_TYPEC_NONE;
kick_sm(pd, 0);
break;
/* Source states */
case PE_SRC_DISABLED:
/* are we still connected? */
if (pd->typec_mode == POWER_SUPPLY_TYPEC_NONE) {
pd->current_pr = PR_NONE;
kick_sm(pd, 0);
}
break;
case PE_SRC_STARTUP:
if (pd->current_dr == DR_NONE) {
pd->current_dr = DR_DFP;
start_usb_host(pd, true);
pd->ss_lane_svid = 0x0;
}
dual_role_instance_changed(pd->dual_role);
/* Set CC back to DRP toggle for the next disconnect */
val.intval = POWER_SUPPLY_TYPEC_PR_DUAL;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_TYPEC_POWER_ROLE, &val);
/* support only PD 2.0 as a source */
pd->spec_rev = USBPD_REV_20;
pd_reset_protocol(pd);
if (!pd->in_pr_swap) {
if (pd->pd_phy_opened) {
pd_phy_close();
pd->pd_phy_opened = false;
}
phy_params.data_role = pd->current_dr;
phy_params.power_role = pd->current_pr;
ret = pd_phy_open(&phy_params);
if (ret) {
WARN_ON_ONCE(1);
usbpd_err(&pd->dev, "error opening PD PHY %d\n",
ret);
pd->current_state = PE_UNKNOWN;
return;
}
pd->pd_phy_opened = true;
}
if (pd->in_pr_swap) {
pd->in_pr_swap = false;
val.intval = 0;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PR_SWAP, &val);
}
/*
* A sink might remove its terminations (during some Type-C
* compliance tests or a sink attempting to do Try.SRC)
* at this point just after we enabled VBUS. Sending PD
* messages now would delay detecting the detach beyond the
* required timing. Instead, delay sending out the first
* source capabilities to allow for the other side to
* completely settle CC debounce and allow HW to detect detach
* sooner in the meantime. PD spec allows up to
* tFirstSourceCap (250ms).
*/
pd->current_state = PE_SRC_SEND_CAPABILITIES;
kick_sm(pd, FIRST_SOURCE_CAP_TIME);
break;
case PE_SRC_SEND_CAPABILITIES:
kick_sm(pd, 0);
break;
case PE_SRC_NEGOTIATE_CAPABILITY:
if (PD_RDO_OBJ_POS(pd->rdo) != 1 ||
PD_RDO_FIXED_CURR(pd->rdo) >
PD_SRC_PDO_FIXED_MAX_CURR(*default_src_caps) ||
PD_RDO_FIXED_CURR_MINMAX(pd->rdo) >
PD_SRC_PDO_FIXED_MAX_CURR(*default_src_caps)) {
/* send Reject */
ret = pd_send_msg(pd, MSG_REJECT, NULL, 0, SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending Reject\n");
usbpd_set_state(pd, PE_SRC_SEND_SOFT_RESET);
break;
}
usbpd_err(&pd->dev, "Invalid request: %08x\n", pd->rdo);
if (pd->in_explicit_contract)
usbpd_set_state(pd, PE_SRC_READY);
else
/*
* bypass PE_SRC_Capability_Response and
* PE_SRC_Wait_New_Capabilities in this
* implementation for simplicity.
*/
usbpd_set_state(pd, PE_SRC_SEND_CAPABILITIES);
break;
}
/* PE_SRC_TRANSITION_SUPPLY pseudo-state */
ret = pd_send_msg(pd, MSG_ACCEPT, NULL, 0, SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending Accept\n");
usbpd_set_state(pd, PE_SRC_SEND_SOFT_RESET);
break;
}
/* tSrcTransition required after ACCEPT */
usleep_range(SRC_TRANSITION_TIME * USEC_PER_MSEC,
(SRC_TRANSITION_TIME + 5) * USEC_PER_MSEC);
/*
* Normally a voltage change should occur within tSrcReady
* but since we only support VSafe5V there is nothing more to
* prepare from the power supply so send PS_RDY right away.
*/
ret = pd_send_msg(pd, MSG_PS_RDY, NULL, 0, SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending PS_RDY\n");
usbpd_set_state(pd, PE_SRC_SEND_SOFT_RESET);
break;
}
usbpd_set_state(pd, PE_SRC_READY);
break;
case PE_SRC_READY:
pd->in_explicit_contract = true;
if (pd->vdm_tx)
kick_sm(pd, 0);
else if (pd->current_dr == DR_DFP && pd->vdm_state == VDM_NONE)
usbpd_send_svdm(pd, USBPD_SID,
USBPD_SVDM_DISCOVER_IDENTITY,
SVDM_CMD_TYPE_INITIATOR, 0, NULL, 0);
kobject_uevent(&pd->dev.kobj, KOBJ_CHANGE);
complete(&pd->is_ready);
dual_role_instance_changed(pd->dual_role);
break;
case PE_SRC_HARD_RESET:
case PE_SNK_HARD_RESET:
/* are we still connected? */
if (pd->typec_mode == POWER_SUPPLY_TYPEC_NONE)
pd->current_pr = PR_NONE;
/* hard reset may sleep; handle it in the workqueue */
kick_sm(pd, 0);
break;
case PE_SRC_SEND_SOFT_RESET:
case PE_SNK_SEND_SOFT_RESET:
pd_reset_protocol(pd);
ret = pd_send_msg(pd, MSG_SOFT_RESET, NULL, 0, SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending Soft Reset, do Hard Reset\n");
usbpd_set_state(pd, pd->current_pr == PR_SRC ?
PE_SRC_HARD_RESET : PE_SNK_HARD_RESET);
break;
}
/* wait for ACCEPT */
kick_sm(pd, SENDER_RESPONSE_TIME);
break;
/* Sink states */
case PE_SNK_STARTUP:
if (pd->current_dr == DR_NONE || pd->current_dr == DR_UFP) {
pd->current_dr = DR_UFP;
if (pd->psy_type == POWER_SUPPLY_TYPE_USB ||
pd->psy_type == POWER_SUPPLY_TYPE_USB_CDP ||
pd->psy_type == POWER_SUPPLY_TYPE_USB_FLOAT ||
usb_compliance_mode)
start_usb_peripheral(pd);
}
dual_role_instance_changed(pd->dual_role);
ret = power_supply_get_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_ALLOWED, &val);
if (ret) {
usbpd_err(&pd->dev, "Unable to read USB PROP_PD_ALLOWED: %d\n",
ret);
break;
}
if (!val.intval || disable_usb_pd)
break;
/*
* support up to PD 3.0 as a sink; if source is 2.0
* phy_msg_received() will handle the downgrade.
*/
pd->spec_rev = USBPD_REV_30;
pd_reset_protocol(pd);
if (!pd->in_pr_swap) {
if (pd->pd_phy_opened) {
pd_phy_close();
pd->pd_phy_opened = false;
}
phy_params.data_role = pd->current_dr;
phy_params.power_role = pd->current_pr;
ret = pd_phy_open(&phy_params);
if (ret) {
WARN_ON_ONCE(1);
usbpd_err(&pd->dev, "error opening PD PHY %d\n",
ret);
pd->current_state = PE_UNKNOWN;
return;
}
pd->pd_phy_opened = true;
}
pd->current_voltage = pd->requested_voltage = 5000000;
val.intval = pd->requested_voltage; /* set max range to 5V */
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_VOLTAGE_MAX, &val);
if (!pd->vbus_present) {
pd->current_state = PE_SNK_DISCOVERY;
/* max time for hard reset to turn vbus back on */
kick_sm(pd, SNK_HARD_RESET_VBUS_ON_TIME);
break;
}
pd->current_state = PE_SNK_WAIT_FOR_CAPABILITIES;
/* fall-through */
case PE_SNK_WAIT_FOR_CAPABILITIES:
spin_lock_irqsave(&pd->rx_lock, flags);
if (list_empty(&pd->rx_q))
kick_sm(pd, SINK_WAIT_CAP_TIME);
spin_unlock_irqrestore(&pd->rx_lock, flags);
break;
case PE_SNK_EVALUATE_CAPABILITY:
pd->pd_connected = true; /* we know peer is PD capable */
pd->hard_reset_count = 0;
/* evaluate PDOs and select one */
ret = pd_eval_src_caps(pd);
if (ret < 0) {
usbpd_err(&pd->dev, "Invalid src_caps received. Skipping request\n");
break;
}
pd->current_state = PE_SNK_SELECT_CAPABILITY;
/* fall-through */
case PE_SNK_SELECT_CAPABILITY:
ret = pd_send_msg(pd, MSG_REQUEST, &pd->rdo, 1, SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending Request\n");
usbpd_set_state(pd, PE_SNK_SEND_SOFT_RESET);
break;
}
/* wait for ACCEPT */
kick_sm(pd, SENDER_RESPONSE_TIME);
break;
case PE_SNK_TRANSITION_SINK:
/* wait for PS_RDY */
kick_sm(pd, PS_TRANSITION_TIME);
break;
case PE_SNK_READY:
pd->in_explicit_contract = true;
if (pd->vdm_tx)
kick_sm(pd, 0);
else if (pd->current_dr == DR_DFP && pd->vdm_state == VDM_NONE)
usbpd_send_svdm(pd, USBPD_SID,
USBPD_SVDM_DISCOVER_IDENTITY,
SVDM_CMD_TYPE_INITIATOR, 0, NULL, 0);
kobject_uevent(&pd->dev.kobj, KOBJ_CHANGE);
complete(&pd->is_ready);
dual_role_instance_changed(pd->dual_role);
break;
case PE_SNK_TRANSITION_TO_DEFAULT:
if (pd->current_dr != DR_UFP) {
stop_usb_host(pd);
start_usb_peripheral(pd);
pd->current_dr = DR_UFP;
pd_phy_update_roles(pd->current_dr, pd->current_pr);
}
if (pd->vconn_enabled) {
regulator_disable(pd->vconn);
pd->vconn_enabled = false;
}
/* max time for hard reset to turn vbus off */
kick_sm(pd, SNK_HARD_RESET_VBUS_OFF_TIME);
break;
case PE_PRS_SNK_SRC_TRANSITION_TO_OFF:
val.intval = pd->requested_current = 0; /* suspend charging */
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_CURRENT_MAX, &val);
pd->in_explicit_contract = false;
/*
* need to update PR bit in message header so that
* proper GoodCRC is sent when receiving next PS_RDY
*/
pd_phy_update_roles(pd->current_dr, PR_SRC);
/* wait for PS_RDY */
kick_sm(pd, PS_SOURCE_OFF);
break;
default:
usbpd_dbg(&pd->dev, "No action for state %s\n",
usbpd_state_strings[pd->current_state]);
break;
}
}
int usbpd_register_svid(struct usbpd *pd, struct usbpd_svid_handler *hdlr)
{
if (find_svid_handler(pd, hdlr->svid)) {
usbpd_err(&pd->dev, "SVID 0x%04x already registered\n",
hdlr->svid);
return -EINVAL;
}
/* require connect/disconnect callbacks be implemented */
if (!hdlr->connect || !hdlr->disconnect) {
usbpd_err(&pd->dev, "SVID 0x%04x connect/disconnect must be non-NULL\n",
hdlr->svid);
return -EINVAL;
}
usbpd_dbg(&pd->dev, "registered handler(%pK) for SVID 0x%04x\n",
hdlr, hdlr->svid);
mutex_lock(&pd->svid_handler_lock);
list_add_tail(&hdlr->entry, &pd->svid_handlers);
mutex_unlock(&pd->svid_handler_lock);
hdlr->request_usb_ss_lane = usbpd_release_ss_lane;
/* already connected with this SVID discovered? */
if (pd->vdm_state >= DISCOVERED_SVIDS) {
int i;
for (i = 0; i < pd->num_svids; i++) {
if (pd->discovered_svids[i] == hdlr->svid) {
hdlr->connect(hdlr);
hdlr->discovered = true;
break;
}
}
}
return 0;
}
EXPORT_SYMBOL(usbpd_register_svid);
void usbpd_unregister_svid(struct usbpd *pd, struct usbpd_svid_handler *hdlr)
{
usbpd_dbg(&pd->dev, "unregistered handler(%pK) for SVID 0x%04x\n",
hdlr, hdlr->svid);
mutex_lock(&pd->svid_handler_lock);
list_del_init(&hdlr->entry);
mutex_unlock(&pd->svid_handler_lock);
}
EXPORT_SYMBOL(usbpd_unregister_svid);
int usbpd_send_vdm(struct usbpd *pd, u32 vdm_hdr, const u32 *vdos, int num_vdos)
{
struct vdm_tx *vdm_tx;
if (!pd->in_explicit_contract || pd->vdm_tx)
return -EBUSY;
vdm_tx = kzalloc(sizeof(*vdm_tx), GFP_KERNEL);
if (!vdm_tx)
return -ENOMEM;
vdm_tx->data[0] = vdm_hdr;
if (vdos && num_vdos)
memcpy(&vdm_tx->data[1], vdos, num_vdos * sizeof(u32));
vdm_tx->size = num_vdos + 1; /* include the header */
/* VDM will get sent in PE_SRC/SNK_READY state handling */
pd->vdm_tx = vdm_tx;
/* slight delay before queuing to prioritize handling of incoming VDM */
kick_sm(pd, 2);
return 0;
}
EXPORT_SYMBOL(usbpd_send_vdm);
int usbpd_send_svdm(struct usbpd *pd, u16 svid, u8 cmd,
enum usbpd_svdm_cmd_type cmd_type, int obj_pos,
const u32 *vdos, int num_vdos)
{
u32 svdm_hdr = SVDM_HDR(svid, 0, obj_pos, cmd_type, cmd);
usbpd_dbg(&pd->dev, "VDM tx: svid:%x cmd:%x cmd_type:%x svdm_hdr:%x\n",
svid, cmd, cmd_type, svdm_hdr);
return usbpd_send_vdm(pd, svdm_hdr, vdos, num_vdos);
}
EXPORT_SYMBOL(usbpd_send_svdm);
static void handle_vdm_rx(struct usbpd *pd, struct rx_msg *rx_msg)
{
u32 vdm_hdr =
rx_msg->data_len >= sizeof(u32) ? ((u32 *)rx_msg->payload)[0] : 0;
u32 *vdos = (u32 *)&rx_msg->payload[sizeof(u32)];
u16 svid = VDM_HDR_SVID(vdm_hdr);
u16 *psvid;
u8 i, num_vdos = PD_MSG_HDR_COUNT(rx_msg->hdr) - 1;
u8 cmd = SVDM_HDR_CMD(vdm_hdr);
u8 cmd_type = SVDM_HDR_CMD_TYPE(vdm_hdr);
bool has_dp = false;
struct usbpd_svid_handler *handler;
usbpd_dbg(&pd->dev, "VDM rx: svid:%x cmd:%x cmd_type:%x vdm_hdr:%x\n",
svid, cmd, cmd_type, vdm_hdr);
/* if it's a supported SVID, pass the message to the handler */
handler = find_svid_handler(pd, svid);
/* Unstructured VDM */
if (!VDM_IS_SVDM(vdm_hdr)) {
if (handler && handler->vdm_received)
handler->vdm_received(handler, vdm_hdr, vdos, num_vdos);
return;
}
/* if this interrupts a previous exchange, abort queued response */
if (cmd_type == SVDM_CMD_TYPE_INITIATOR && pd->vdm_tx) {
usbpd_dbg(&pd->dev, "Discarding previously queued SVDM tx (SVID:0x%04x)\n",
VDM_HDR_SVID(pd->vdm_tx->data[0]));
kfree(pd->vdm_tx);
pd->vdm_tx = NULL;
}
if (handler && handler->svdm_received) {
handler->svdm_received(handler, cmd, cmd_type, vdos, num_vdos);
return;
}
/* Standard Discovery or unhandled messages go here */
switch (cmd_type) {
case SVDM_CMD_TYPE_INITIATOR:
if (svid == USBPD_SID && cmd == USBPD_SVDM_DISCOVER_IDENTITY) {
u32 tx_vdos[3] = {
ID_HDR_USB_HOST | ID_HDR_USB_DEVICE |
ID_HDR_PRODUCT_PER_MASK | ID_HDR_VID,
0x0, /* TBD: Cert Stat VDO */
(PROD_VDO_PID << 16),
/* TBD: Get these from gadget */
};
usbpd_send_svdm(pd, USBPD_SID, cmd,
SVDM_CMD_TYPE_RESP_ACK, 0, tx_vdos, 3);
} else if (cmd != USBPD_SVDM_ATTENTION) {
usbpd_send_svdm(pd, svid, cmd, SVDM_CMD_TYPE_RESP_NAK,
SVDM_HDR_OBJ_POS(vdm_hdr), NULL, 0);
}
break;
case SVDM_CMD_TYPE_RESP_ACK:
if (svid != USBPD_SID) {
usbpd_err(&pd->dev, "unhandled ACK for SVID:0x%x\n",
svid);
break;
}
switch (cmd) {
case USBPD_SVDM_DISCOVER_IDENTITY:
kfree(pd->vdm_tx_retry);
pd->vdm_tx_retry = NULL;
pd->vdm_state = DISCOVERED_ID;
usbpd_send_svdm(pd, USBPD_SID,
USBPD_SVDM_DISCOVER_SVIDS,
SVDM_CMD_TYPE_INITIATOR, 0, NULL, 0);
break;
case USBPD_SVDM_DISCOVER_SVIDS:
pd->vdm_state = DISCOVERED_SVIDS;
kfree(pd->vdm_tx_retry);
pd->vdm_tx_retry = NULL;
if (!pd->discovered_svids) {
pd->num_svids = 2 * num_vdos;
pd->discovered_svids = kcalloc(pd->num_svids,
sizeof(u16),
GFP_KERNEL);
if (!pd->discovered_svids) {
usbpd_err(&pd->dev, "unable to allocate SVIDs\n");
break;
}
psvid = pd->discovered_svids;
} else { /* handle > 12 SVIDs */
void *ptr;
size_t oldsize = pd->num_svids * sizeof(u16);
size_t newsize = oldsize +
(2 * num_vdos * sizeof(u16));
ptr = krealloc(pd->discovered_svids, newsize,
GFP_KERNEL);
if (!ptr) {
usbpd_err(&pd->dev, "unable to realloc SVIDs\n");
break;
}
pd->discovered_svids = ptr;
psvid = pd->discovered_svids + pd->num_svids;
memset(psvid, 0, (2 * num_vdos));
pd->num_svids += 2 * num_vdos;
}
/* convert 32-bit VDOs to list of 16-bit SVIDs */
for (i = 0; i < num_vdos * 2; i++) {
/*
* Within each 32-bit VDO,
* SVID[i]: upper 16-bits
* SVID[i+1]: lower 16-bits
* where i is even.
*/
if (!(i & 1))
svid = vdos[i >> 1] >> 16;
else
svid = vdos[i >> 1] & 0xFFFF;
/*
* There are some devices that incorrectly
* swap the order of SVIDs within a VDO. So in
* case of an odd-number of SVIDs it could end
* up with SVID[i] as 0 while SVID[i+1] is
* non-zero. Just skip over the zero ones.
*/
if (svid) {
usbpd_dbg(&pd->dev, "Discovered SVID: 0x%04x\n",
svid);
*psvid++ = svid;
}
}
/* if more than 12 SVIDs, resend the request */
if (num_vdos == 6 && vdos[5] != 0) {
usbpd_send_svdm(pd, USBPD_SID,
USBPD_SVDM_DISCOVER_SVIDS,
SVDM_CMD_TYPE_INITIATOR, 0,
NULL, 0);
break;
}
/* now that all SVIDs are discovered, notify handlers */
for (i = 0; i < pd->num_svids; i++) {
svid = pd->discovered_svids[i];
if (svid) {
handler = find_svid_handler(pd, svid);
if (handler) {
handler->connect(handler);
handler->discovered = true;
}
}
if (svid == 0xFF01)
has_dp = true;
}
break;
default:
usbpd_dbg(&pd->dev, "unhandled ACK for command:0x%x\n",
cmd);
break;
}
break;
case SVDM_CMD_TYPE_RESP_NAK:
usbpd_info(&pd->dev, "VDM NAK received for SVID:0x%04x command:0x%x\n",
svid, cmd);
switch (cmd) {
case USBPD_SVDM_DISCOVER_IDENTITY:
case USBPD_SVDM_DISCOVER_SVIDS:
break;
default:
break;
}
break;
case SVDM_CMD_TYPE_RESP_BUSY:
switch (cmd) {
case USBPD_SVDM_DISCOVER_IDENTITY:
case USBPD_SVDM_DISCOVER_SVIDS:
if (!pd->vdm_tx_retry) {
usbpd_err(&pd->dev, "Discover command %d VDM was unexpectedly freed\n",
cmd);
break;
}
/* wait tVDMBusy, then retry */
pd->vdm_tx = pd->vdm_tx_retry;
pd->vdm_tx_retry = NULL;
kick_sm(pd, VDM_BUSY_TIME);
break;
default:
break;
}
break;
}
}
static void handle_vdm_tx(struct usbpd *pd)
{
int ret;
unsigned long flags;
/* only send one VDM at a time */
if (pd->vdm_tx) {
u32 vdm_hdr = pd->vdm_tx->data[0];
/* bail out and try again later if a message just arrived */
spin_lock_irqsave(&pd->rx_lock, flags);
if (!list_empty(&pd->rx_q)) {
spin_unlock_irqrestore(&pd->rx_lock, flags);
return;
}
spin_unlock_irqrestore(&pd->rx_lock, flags);
ret = pd_send_msg(pd, MSG_VDM, pd->vdm_tx->data,
pd->vdm_tx->size, SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error (%d) sending VDM command %d\n",
ret, SVDM_HDR_CMD(pd->vdm_tx->data[0]));
/* retry when hitting PE_SRC/SNK_Ready again */
if (ret != -EBUSY)
usbpd_set_state(pd, pd->current_pr == PR_SRC ?
PE_SRC_SEND_SOFT_RESET :
PE_SNK_SEND_SOFT_RESET);
return;
}
/*
* special case: keep initiated Discover ID/SVIDs
* around in case we need to re-try when receiving BUSY
*/
if (VDM_IS_SVDM(vdm_hdr) &&
SVDM_HDR_CMD_TYPE(vdm_hdr) == SVDM_CMD_TYPE_INITIATOR &&
SVDM_HDR_CMD(vdm_hdr) <= USBPD_SVDM_DISCOVER_SVIDS) {
if (pd->vdm_tx_retry) {
usbpd_dbg(&pd->dev, "Previous Discover VDM command %d not ACKed/NAKed\n",
SVDM_HDR_CMD(
pd->vdm_tx_retry->data[0]));
kfree(pd->vdm_tx_retry);
}
pd->vdm_tx_retry = pd->vdm_tx;
} else {
kfree(pd->vdm_tx);
}
pd->vdm_tx = NULL;
}
}
static void reset_vdm_state(struct usbpd *pd)
{
struct usbpd_svid_handler *handler;
mutex_lock(&pd->svid_handler_lock);
list_for_each_entry(handler, &pd->svid_handlers, entry) {
if (handler->discovered) {
handler->disconnect(handler);
handler->discovered = false;
}
}
mutex_unlock(&pd->svid_handler_lock);
pd->vdm_state = VDM_NONE;
kfree(pd->vdm_tx_retry);
pd->vdm_tx_retry = NULL;
kfree(pd->discovered_svids);
pd->discovered_svids = NULL;
pd->num_svids = 0;
kfree(pd->vdm_tx);
pd->vdm_tx = NULL;
}
static void dr_swap(struct usbpd *pd)
{
reset_vdm_state(pd);
usbpd_dbg(&pd->dev, "dr_swap: current_dr(%d)\n", pd->current_dr);
if (pd->current_dr == DR_DFP) {
stop_usb_host(pd);
start_usb_peripheral(pd);
pd->current_dr = DR_UFP;
} else if (pd->current_dr == DR_UFP) {
stop_usb_peripheral(pd);
start_usb_host(pd, true);
pd->current_dr = DR_DFP;
usbpd_send_svdm(pd, USBPD_SID, USBPD_SVDM_DISCOVER_IDENTITY,
SVDM_CMD_TYPE_INITIATOR, 0, NULL, 0);
}
pd_phy_update_roles(pd->current_dr, pd->current_pr);
dual_role_instance_changed(pd->dual_role);
}
static void vconn_swap(struct usbpd *pd)
{
int ret;
if (pd->vconn_enabled) {
pd->current_state = PE_VCS_WAIT_FOR_VCONN;
kick_sm(pd, VCONN_ON_TIME);
} else {
ret = regulator_enable(pd->vconn);
if (ret) {
usbpd_err(&pd->dev, "Unable to enable vconn\n");
return;
}
pd->vconn_enabled = true;
/*
* Small delay to ensure Vconn has ramped up. This is well
* below tVCONNSourceOn (100ms) so we still send PS_RDY within
* the allowed time.
*/
usleep_range(5000, 10000);
ret = pd_send_msg(pd, MSG_PS_RDY, NULL, 0, SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending PS_RDY\n");
usbpd_set_state(pd, pd->current_pr == PR_SRC ?
PE_SRC_SEND_SOFT_RESET :
PE_SNK_SEND_SOFT_RESET);
return;
}
}
}
static int enable_vbus(struct usbpd *pd)
{
union power_supply_propval val = {0};
int count = 100;
int ret;
if (!check_vsafe0v)
goto enable_reg;
/*
* Check to make sure there's no lingering charge on
* VBUS before enabling it as a source. If so poll here
* until it goes below VSafe0V (0.8V) before proceeding.
*/
while (count--) {
ret = power_supply_get_property(pd->usb_psy,
POWER_SUPPLY_PROP_VOLTAGE_NOW, &val);
if (ret || val.intval <= 800000)
break;
usleep_range(20000, 30000);
}
if (count < 99)
msleep(100); /* need to wait an additional tCCDebounce */
enable_reg:
ret = regulator_enable(pd->vbus);
if (ret)
usbpd_err(&pd->dev, "Unable to enable vbus (%d)\n", ret);
else
pd->vbus_enabled = true;
return ret;
}
static inline void rx_msg_cleanup(struct usbpd *pd)
{
struct rx_msg *msg, *tmp;
unsigned long flags;
spin_lock_irqsave(&pd->rx_lock, flags);
list_for_each_entry_safe(msg, tmp, &pd->rx_q, entry) {
list_del(&msg->entry);
kfree(msg);
}
spin_unlock_irqrestore(&pd->rx_lock, flags);
}
/* For PD 3.0, check SinkTxOk before allowing initiating AMS */
static inline bool is_sink_tx_ok(struct usbpd *pd)
{
if (pd->spec_rev == USBPD_REV_30)
return pd->typec_mode == POWER_SUPPLY_TYPEC_SOURCE_HIGH;
return true;
}
/* Handles current state and determines transitions */
static void usbpd_sm(struct work_struct *w)
{
struct usbpd *pd = container_of(w, struct usbpd, sm_work);
union power_supply_propval val = {0};
int ret;
struct rx_msg *rx_msg = NULL;
unsigned long flags;
usbpd_dbg(&pd->dev, "handle state %s\n",
usbpd_state_strings[pd->current_state]);
hrtimer_cancel(&pd->timer);
pd->sm_queued = false;
spin_lock_irqsave(&pd->rx_lock, flags);
if (!list_empty(&pd->rx_q)) {
rx_msg = list_first_entry(&pd->rx_q, struct rx_msg, entry);
list_del(&rx_msg->entry);
}
spin_unlock_irqrestore(&pd->rx_lock, flags);
/* Disconnect? */
if (pd->current_pr == PR_NONE) {
if (pd->current_state == PE_UNKNOWN)
goto sm_done;
if (pd->vconn_enabled) {
regulator_disable(pd->vconn);
pd->vconn_enabled = false;
}
usbpd_info(&pd->dev, "USB Type-C disconnect\n");
if (pd->pd_phy_opened) {
pd_phy_close();
pd->pd_phy_opened = false;
}
pd->in_pr_swap = false;
pd->pd_connected = false;
pd->in_explicit_contract = false;
pd->hard_reset_recvd = false;
pd->caps_count = 0;
pd->hard_reset_count = 0;
pd->requested_voltage = 0;
pd->requested_current = 0;
pd->selected_pdo = pd->requested_pdo = 0;
memset(&pd->received_pdos, 0, sizeof(pd->received_pdos));
rx_msg_cleanup(pd);
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_IN_HARD_RESET, &val);
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_USB_SUSPEND_SUPPORTED,
&val);
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_ACTIVE, &val);
if (pd->vbus_enabled) {
regulator_disable(pd->vbus);
pd->vbus_enabled = false;
}
reset_vdm_state(pd);
if (pd->current_dr == DR_UFP)
stop_usb_peripheral(pd);
else if (pd->current_dr == DR_DFP)
stop_usb_host(pd);
pd->current_dr = DR_NONE;
if (pd->current_state == PE_ERROR_RECOVERY)
/* forced disconnect, wait before resetting to DRP */
usleep_range(ERROR_RECOVERY_TIME * USEC_PER_MSEC,
(ERROR_RECOVERY_TIME + 5) * USEC_PER_MSEC);
val.intval = 0;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PR_SWAP, &val);
/* set due to dual_role class "mode" change */
if (pd->forced_pr != POWER_SUPPLY_TYPEC_PR_NONE)
val.intval = pd->forced_pr;
else if (rev3_sink_only)
val.intval = POWER_SUPPLY_TYPEC_PR_SINK;
else
/* Set CC back to DRP toggle */
val.intval = POWER_SUPPLY_TYPEC_PR_DUAL;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_TYPEC_POWER_ROLE, &val);
pd->forced_pr = POWER_SUPPLY_TYPEC_PR_NONE;
pd->current_state = PE_UNKNOWN;
kobject_uevent(&pd->dev.kobj, KOBJ_CHANGE);
dual_role_instance_changed(pd->dual_role);
goto sm_done;
}
/* Hard reset? */
if (pd->hard_reset_recvd) {
pd->hard_reset_recvd = false;
if (pd->requested_current) {
val.intval = pd->requested_current = 0;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_CURRENT_MAX, &val);
}
pd->requested_voltage = 5000000;
val.intval = pd->requested_voltage;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_VOLTAGE_MIN, &val);
pd->in_pr_swap = false;
val.intval = 0;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PR_SWAP, &val);
pd->in_explicit_contract = false;
pd->selected_pdo = pd->requested_pdo = 0;
pd->rdo = 0;
rx_msg_cleanup(pd);
reset_vdm_state(pd);
kobject_uevent(&pd->dev.kobj, KOBJ_CHANGE);
if (pd->current_pr == PR_SINK) {
usbpd_set_state(pd, PE_SNK_TRANSITION_TO_DEFAULT);
} else {
s64 delta = ktime_ms_delta(ktime_get(),
pd->hard_reset_recvd_time);
pd->current_state = PE_SRC_TRANSITION_TO_DEFAULT;
if (delta >= PS_HARD_RESET_TIME)
kick_sm(pd, 0);
else
kick_sm(pd, PS_HARD_RESET_TIME - (int)delta);
}
goto sm_done;
}
/* Soft reset? */
if (IS_CTRL(rx_msg, MSG_SOFT_RESET)) {
usbpd_dbg(&pd->dev, "Handle soft reset\n");
if (pd->current_pr == PR_SRC)
pd->current_state = PE_SRC_SOFT_RESET;
else if (pd->current_pr == PR_SINK)
pd->current_state = PE_SNK_SOFT_RESET;
}
switch (pd->current_state) {
case PE_UNKNOWN:
val.intval = 0;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_IN_HARD_RESET, &val);
if (pd->current_pr == PR_SINK) {
usbpd_set_state(pd, PE_SNK_STARTUP);
} else if (pd->current_pr == PR_SRC) {
if (!pd->vconn_enabled &&
pd->typec_mode ==
POWER_SUPPLY_TYPEC_SINK_POWERED_CABLE) {
ret = regulator_enable(pd->vconn);
if (ret)
usbpd_err(&pd->dev, "Unable to enable vconn\n");
else
pd->vconn_enabled = true;
}
enable_vbus(pd);
usbpd_set_state(pd, PE_SRC_STARTUP);
}
break;
case PE_SRC_STARTUP:
usbpd_set_state(pd, PE_SRC_STARTUP);
break;
case PE_SRC_SEND_CAPABILITIES:
ret = pd_send_msg(pd, MSG_SOURCE_CAPABILITIES, default_src_caps,
ARRAY_SIZE(default_src_caps), SOP_MSG);
if (ret) {
pd->caps_count++;
if (pd->caps_count >= PD_CAPS_COUNT) {
usbpd_dbg(&pd->dev, "Src CapsCounter exceeded, disabling PD\n");
usbpd_set_state(pd, PE_SRC_DISABLED);
val.intval = 0;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_ACTIVE,
&val);
break;
}
kick_sm(pd, SRC_CAP_TIME);
break;
}
/* transmit was successful if GoodCRC was received */
pd->caps_count = 0;
pd->hard_reset_count = 0;
pd->pd_connected = true; /* we know peer is PD capable */
/* wait for REQUEST */
pd->current_state = PE_SRC_SEND_CAPABILITIES_WAIT;
kick_sm(pd, SENDER_RESPONSE_TIME);
val.intval = 1;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_ACTIVE, &val);
break;
case PE_SRC_SEND_CAPABILITIES_WAIT:
if (IS_DATA(rx_msg, MSG_REQUEST)) {
pd->rdo = *(u32 *)rx_msg->payload;
usbpd_set_state(pd, PE_SRC_NEGOTIATE_CAPABILITY);
} else if (rx_msg) {
usbpd_err(&pd->dev, "Unexpected message received\n");
usbpd_set_state(pd, PE_SRC_SEND_SOFT_RESET);
} else {
usbpd_set_state(pd, PE_SRC_HARD_RESET);
}
break;
case PE_SRC_READY:
if (IS_CTRL(rx_msg, MSG_GET_SOURCE_CAP)) {
pd->current_state = PE_SRC_SEND_CAPABILITIES;
kick_sm(pd, 0);
} else if (IS_CTRL(rx_msg, MSG_GET_SINK_CAP)) {
ret = pd_send_msg(pd, MSG_SINK_CAPABILITIES,
pd->sink_caps, pd->num_sink_caps,
SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending Sink Caps\n");
usbpd_set_state(pd, PE_SRC_SEND_SOFT_RESET);
}
} else if (IS_DATA(rx_msg, MSG_REQUEST)) {
pd->rdo = *(u32 *)rx_msg->payload;
usbpd_set_state(pd, PE_SRC_NEGOTIATE_CAPABILITY);
} else if (IS_CTRL(rx_msg, MSG_DR_SWAP)) {
if (pd->vdm_state == MODE_ENTERED) {
usbpd_set_state(pd, PE_SRC_HARD_RESET);
break;
}
ret = pd_send_msg(pd, MSG_ACCEPT, NULL, 0, SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending Accept\n");
usbpd_set_state(pd, PE_SRC_SEND_SOFT_RESET);
break;
}
dr_swap(pd);
} else if (IS_CTRL(rx_msg, MSG_PR_SWAP)) {
/* lock in current mode */
set_power_role(pd, pd->current_pr);
/* we'll happily accept Src->Sink requests anytime */
ret = pd_send_msg(pd, MSG_ACCEPT, NULL, 0, SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending Accept\n");
usbpd_set_state(pd, PE_SRC_SEND_SOFT_RESET);
break;
}
pd->current_state = PE_PRS_SRC_SNK_TRANSITION_TO_OFF;
kick_sm(pd, SRC_TRANSITION_TIME);
break;
} else if (IS_CTRL(rx_msg, MSG_VCONN_SWAP)) {
ret = pd_send_msg(pd, MSG_ACCEPT, NULL, 0, SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending Accept\n");
usbpd_set_state(pd, PE_SRC_SEND_SOFT_RESET);
break;
}
vconn_swap(pd);
} else if (IS_DATA(rx_msg, MSG_VDM)) {
handle_vdm_rx(pd, rx_msg);
} else if (rx_msg && pd->spec_rev == USBPD_REV_30) {
/* unhandled messages */
ret = pd_send_msg(pd, MSG_NOT_SUPPORTED, NULL, 0,
SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending Not supported\n");
usbpd_set_state(pd, PE_SRC_SEND_SOFT_RESET);
}
break;
} else if (pd->send_pr_swap) {
pd->send_pr_swap = false;
ret = pd_send_msg(pd, MSG_PR_SWAP, NULL, 0, SOP_MSG);
if (ret) {
dev_err(&pd->dev, "Error sending PR Swap\n");
usbpd_set_state(pd, PE_SRC_SEND_SOFT_RESET);
break;
}
pd->current_state = PE_PRS_SRC_SNK_SEND_SWAP;
kick_sm(pd, SENDER_RESPONSE_TIME);
} else if (pd->send_dr_swap) {
pd->send_dr_swap = false;
ret = pd_send_msg(pd, MSG_DR_SWAP, NULL, 0, SOP_MSG);
if (ret) {
dev_err(&pd->dev, "Error sending DR Swap\n");
usbpd_set_state(pd, PE_SRC_SEND_SOFT_RESET);
break;
}
pd->current_state = PE_DRS_SEND_DR_SWAP;
kick_sm(pd, SENDER_RESPONSE_TIME);
} else {
handle_vdm_tx(pd);
}
break;
case PE_SRC_TRANSITION_TO_DEFAULT:
if (pd->vconn_enabled)
regulator_disable(pd->vconn);
pd->vconn_enabled = false;
if (pd->vbus_enabled)
regulator_disable(pd->vbus);
pd->vbus_enabled = false;
if (pd->current_dr != DR_DFP) {
extcon_set_state_sync(pd->extcon, EXTCON_USB, 0);
pd->current_dr = DR_DFP;
pd_phy_update_roles(pd->current_dr, pd->current_pr);
}
/* PE_UNKNOWN will turn on VBUS and go back to PE_SRC_STARTUP */
pd->current_state = PE_UNKNOWN;
kick_sm(pd, SRC_RECOVER_TIME);
break;
case PE_SRC_HARD_RESET:
val.intval = 1;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_IN_HARD_RESET, &val);
pd_send_hard_reset(pd);
pd->in_explicit_contract = false;
pd->rdo = 0;
rx_msg_cleanup(pd);
reset_vdm_state(pd);
kobject_uevent(&pd->dev.kobj, KOBJ_CHANGE);
pd->current_state = PE_SRC_TRANSITION_TO_DEFAULT;
kick_sm(pd, PS_HARD_RESET_TIME);
break;
case PE_SNK_STARTUP:
usbpd_set_state(pd, PE_SNK_STARTUP);
break;
case PE_SNK_DISCOVERY:
if (!rx_msg) {
if (pd->vbus_present)
usbpd_set_state(pd,
PE_SNK_WAIT_FOR_CAPABILITIES);
/*
* Handle disconnection in the middle of PR_Swap.
* Since in psy_changed() if pd->in_pr_swap is true
* we ignore the typec_mode==NONE change since that is
* expected to happen. However if the cable really did
* get disconnected we need to check for it here after
* waiting for VBUS presence times out.
*/
if (!pd->typec_mode) {
pd->current_pr = PR_NONE;
kick_sm(pd, 0);
}
break;
}
/* else fall-through */
case PE_SNK_WAIT_FOR_CAPABILITIES:
pd->in_pr_swap = false;
val.intval = 0;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PR_SWAP, &val);
if (IS_DATA(rx_msg, MSG_SOURCE_CAPABILITIES)) {
val.intval = 0;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_IN_HARD_RESET,
&val);
/* save the PDOs so userspace can further evaluate */
memset(&pd->received_pdos, 0,
sizeof(pd->received_pdos));
memcpy(&pd->received_pdos, rx_msg->payload,
min_t(size_t, rx_msg->data_len,
sizeof(pd->received_pdos)));
pd->src_cap_id++;
usbpd_set_state(pd, PE_SNK_EVALUATE_CAPABILITY);
val.intval = 1;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_ACTIVE, &val);
} else if (pd->hard_reset_count < 3) {
usbpd_set_state(pd, PE_SNK_HARD_RESET);
} else {
usbpd_dbg(&pd->dev, "Sink hard reset count exceeded, disabling PD\n");
val.intval = 0;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_IN_HARD_RESET,
&val);
val.intval = 0;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_ACTIVE, &val);
}
break;
case PE_SNK_SELECT_CAPABILITY:
if (IS_CTRL(rx_msg, MSG_ACCEPT)) {
u32 pdo = pd->received_pdos[pd->requested_pdo - 1];
bool same_pps = (pd->selected_pdo == pd->requested_pdo)
&& (PD_SRC_PDO_TYPE(pdo) ==
PD_SRC_PDO_TYPE_AUGMENTED);
usbpd_set_state(pd, PE_SNK_TRANSITION_SINK);
/* prepare for voltage increase/decrease */
val.intval = pd->requested_voltage;
power_supply_set_property(pd->usb_psy,
pd->requested_voltage >= pd->current_voltage ?
POWER_SUPPLY_PROP_PD_VOLTAGE_MAX :
POWER_SUPPLY_PROP_PD_VOLTAGE_MIN,
&val);
/*
* if changing voltages (not within the same PPS PDO),
* we must lower input current to pSnkStdby (2.5W).
* Calculate it and set PD_CURRENT_MAX accordingly.
*/
if (!same_pps &&
pd->requested_voltage != pd->current_voltage) {
int mv = max(pd->requested_voltage,
pd->current_voltage) / 1000;
val.intval = (2500000 / mv) * 1000;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_CURRENT_MAX, &val);
} else {
/* decreasing current? */
ret = power_supply_get_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_CURRENT_MAX, &val);
if (!ret &&
pd->requested_current < val.intval) {
val.intval =
pd->requested_current * 1000;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_CURRENT_MAX,
&val);
}
}
pd->selected_pdo = pd->requested_pdo;
} else if (IS_CTRL(rx_msg, MSG_REJECT) ||
IS_CTRL(rx_msg, MSG_WAIT)) {
if (pd->in_explicit_contract)
usbpd_set_state(pd, PE_SNK_READY);
else
usbpd_set_state(pd,
PE_SNK_WAIT_FOR_CAPABILITIES);
} else if (rx_msg) {
usbpd_err(&pd->dev, "Invalid response to sink request\n");
usbpd_set_state(pd, PE_SNK_SEND_SOFT_RESET);
} else {
/* timed out; go to hard reset */
usbpd_set_state(pd, PE_SNK_HARD_RESET);
}
break;
case PE_SNK_TRANSITION_SINK:
if (IS_CTRL(rx_msg, MSG_PS_RDY)) {
val.intval = pd->requested_voltage;
power_supply_set_property(pd->usb_psy,
pd->requested_voltage >= pd->current_voltage ?
POWER_SUPPLY_PROP_PD_VOLTAGE_MIN :
POWER_SUPPLY_PROP_PD_VOLTAGE_MAX, &val);
pd->current_voltage = pd->requested_voltage;
/* resume charging */
val.intval = pd->requested_current * 1000; /* mA->uA */
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_CURRENT_MAX, &val);
usbpd_set_state(pd, PE_SNK_READY);
} else {
/* timed out; go to hard reset */
usbpd_set_state(pd, PE_SNK_HARD_RESET);
}
break;
case PE_SNK_READY:
if (IS_DATA(rx_msg, MSG_SOURCE_CAPABILITIES)) {
/* save the PDOs so userspace can further evaluate */
memset(&pd->received_pdos, 0,
sizeof(pd->received_pdos));
memcpy(&pd->received_pdos, rx_msg->payload,
min_t(size_t, rx_msg->data_len,
sizeof(pd->received_pdos)));
pd->src_cap_id++;
usbpd_set_state(pd, PE_SNK_EVALUATE_CAPABILITY);
} else if (IS_CTRL(rx_msg, MSG_GET_SINK_CAP)) {
ret = pd_send_msg(pd, MSG_SINK_CAPABILITIES,
pd->sink_caps, pd->num_sink_caps,
SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending Sink Caps\n");
usbpd_set_state(pd, PE_SNK_SEND_SOFT_RESET);
}
} else if (IS_CTRL(rx_msg, MSG_GET_SOURCE_CAP) &&
pd->spec_rev == USBPD_REV_20) {
ret = pd_send_msg(pd, MSG_SOURCE_CAPABILITIES,
default_src_caps,
ARRAY_SIZE(default_src_caps), SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending SRC CAPs\n");
usbpd_set_state(pd, PE_SNK_SEND_SOFT_RESET);
break;
}
} else if (IS_CTRL(rx_msg, MSG_DR_SWAP)) {
if (pd->vdm_state == MODE_ENTERED) {
usbpd_set_state(pd, PE_SNK_HARD_RESET);
break;
}
ret = pd_send_msg(pd, MSG_ACCEPT, NULL, 0, SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending Accept\n");
usbpd_set_state(pd, PE_SRC_SEND_SOFT_RESET);
break;
}
dr_swap(pd);
} else if (IS_CTRL(rx_msg, MSG_PR_SWAP) &&
pd->spec_rev == USBPD_REV_20) {
/* lock in current mode */
set_power_role(pd, pd->current_pr);
/* TODO: should we Reject in certain circumstances? */
ret = pd_send_msg(pd, MSG_ACCEPT, NULL, 0, SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending Accept\n");
usbpd_set_state(pd, PE_SNK_SEND_SOFT_RESET);
break;
}
pd->in_pr_swap = true;
val.intval = 1;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PR_SWAP, &val);
usbpd_set_state(pd, PE_PRS_SNK_SRC_TRANSITION_TO_OFF);
break;
} else if (IS_CTRL(rx_msg, MSG_VCONN_SWAP) &&
pd->spec_rev == USBPD_REV_20) {
/*
* if VCONN is connected to VBUS, make sure we are
* not in high voltage contract, otherwise reject.
*/
if (!pd->vconn_is_external &&
(pd->requested_voltage > 5000000)) {
ret = pd_send_msg(pd, MSG_REJECT, NULL, 0,
SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending Reject\n");
usbpd_set_state(pd,
PE_SNK_SEND_SOFT_RESET);
}
break;
}
ret = pd_send_msg(pd, MSG_ACCEPT, NULL, 0, SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending Accept\n");
usbpd_set_state(pd, PE_SNK_SEND_SOFT_RESET);
break;
}
vconn_swap(pd);
} else if (IS_DATA(rx_msg, MSG_VDM)) {
handle_vdm_rx(pd, rx_msg);
} else if (pd->send_get_src_cap_ext && is_sink_tx_ok(pd)) {
pd->send_get_src_cap_ext = false;
ret = pd_send_msg(pd, MSG_GET_SOURCE_CAP_EXTENDED, NULL,
0, SOP_MSG);
if (ret) {
dev_err(&pd->dev,
"Error sending get_src_cap_ext\n");
usbpd_set_state(pd, PE_SNK_SEND_SOFT_RESET);
break;
}
kick_sm(pd, SENDER_RESPONSE_TIME);
} else if (rx_msg &&
IS_EXT(rx_msg, MSG_SOURCE_CAPABILITIES_EXTENDED)) {
if (rx_msg->data_len != PD_SRC_CAP_EXT_DB_LEN) {
usbpd_err(&pd->dev, "Invalid src cap ext db\n");
break;
}
memcpy(&pd->src_cap_ext_db, rx_msg->payload,
sizeof(pd->src_cap_ext_db));
complete(&pd->is_ready);
} else if (pd->send_get_pps_status && is_sink_tx_ok(pd)) {
pd->send_get_pps_status = false;
ret = pd_send_msg(pd, MSG_GET_PPS_STATUS, NULL,
0, SOP_MSG);
if (ret) {
dev_err(&pd->dev,
"Error sending get_pps_status\n");
usbpd_set_state(pd, PE_SNK_SEND_SOFT_RESET);
break;
}
kick_sm(pd, SENDER_RESPONSE_TIME);
} else if (rx_msg &&
IS_EXT(rx_msg, MSG_PPS_STATUS)) {
if (rx_msg->data_len != sizeof(pd->pps_status_db)) {
usbpd_err(&pd->dev, "Invalid pps status db\n");
break;
}
memcpy(&pd->pps_status_db, rx_msg->payload,
sizeof(pd->pps_status_db));
complete(&pd->is_ready);
} else if (IS_DATA(rx_msg, MSG_ALERT)) {
if (rx_msg->data_len != sizeof(pd->received_ado)) {
usbpd_err(&pd->dev, "Invalid ado\n");
break;
}
memcpy(&pd->received_ado, rx_msg->payload,
sizeof(pd->received_ado));
ret = pd_send_msg(pd, MSG_GET_STATUS, NULL,
0, SOP_MSG);
if (ret) {
dev_err(&pd->dev,
"Error sending get_status\n");
usbpd_set_state(pd, PE_SNK_SEND_SOFT_RESET);
break;
}
kick_sm(pd, SENDER_RESPONSE_TIME);
} else if (rx_msg &&
IS_EXT(rx_msg, MSG_STATUS)) {
if (rx_msg->data_len != PD_STATUS_DB_LEN) {
usbpd_err(&pd->dev, "Invalid status db\n");
break;
}
memcpy(&pd->status_db, rx_msg->payload,
sizeof(pd->status_db));
kobject_uevent(&pd->dev.kobj, KOBJ_CHANGE);
} else if (pd->send_get_battery_cap && is_sink_tx_ok(pd)) {
pd->send_get_battery_cap = false;
ret = pd_send_ext_msg(pd, MSG_GET_BATTERY_CAP,
&pd->get_battery_cap_db, 1, SOP_MSG);
if (ret) {
dev_err(&pd->dev,
"Error sending get_battery_cap\n");
usbpd_set_state(pd, PE_SNK_SEND_SOFT_RESET);
break;
}
kick_sm(pd, SENDER_RESPONSE_TIME);
} else if (rx_msg &&
IS_EXT(rx_msg, MSG_BATTERY_CAPABILITIES)) {
if (rx_msg->data_len != PD_BATTERY_CAP_DB_LEN) {
usbpd_err(&pd->dev, "Invalid battery cap db\n");
break;
}
memcpy(&pd->battery_cap_db, rx_msg->payload,
sizeof(pd->battery_cap_db));
complete(&pd->is_ready);
} else if (pd->send_get_battery_status && is_sink_tx_ok(pd)) {
pd->send_get_battery_status = false;
ret = pd_send_ext_msg(pd, MSG_GET_BATTERY_STATUS,
&pd->get_battery_status_db, 1, SOP_MSG);
if (ret) {
dev_err(&pd->dev,
"Error sending get_battery_status\n");
usbpd_set_state(pd, PE_SNK_SEND_SOFT_RESET);
break;
}
kick_sm(pd, SENDER_RESPONSE_TIME);
} else if (rx_msg &&
IS_EXT(rx_msg, MSG_BATTERY_STATUS)) {
if (rx_msg->data_len != sizeof(pd->battery_sts_dobj)) {
usbpd_err(&pd->dev, "Invalid bat sts dobj\n");
break;
}
memcpy(&pd->battery_sts_dobj, rx_msg->payload,
sizeof(pd->battery_sts_dobj));
complete(&pd->is_ready);
} else if (rx_msg && pd->spec_rev == USBPD_REV_30) {
/* unhandled messages */
ret = pd_send_msg(pd, MSG_NOT_SUPPORTED, NULL, 0,
SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending Not supported\n");
usbpd_set_state(pd, PE_SNK_SEND_SOFT_RESET);
}
break;
} else if (pd->send_request) {
pd->send_request = false;
usbpd_set_state(pd, PE_SNK_SELECT_CAPABILITY);
} else if (pd->send_pr_swap && is_sink_tx_ok(pd)) {
pd->send_pr_swap = false;
ret = pd_send_msg(pd, MSG_PR_SWAP, NULL, 0, SOP_MSG);
if (ret) {
dev_err(&pd->dev, "Error sending PR Swap\n");
usbpd_set_state(pd, PE_SNK_SEND_SOFT_RESET);
break;
}
pd->current_state = PE_PRS_SNK_SRC_SEND_SWAP;
kick_sm(pd, SENDER_RESPONSE_TIME);
} else if (pd->send_dr_swap && is_sink_tx_ok(pd)) {
pd->send_dr_swap = false;
ret = pd_send_msg(pd, MSG_DR_SWAP, NULL, 0, SOP_MSG);
if (ret) {
dev_err(&pd->dev, "Error sending DR Swap\n");
usbpd_set_state(pd, PE_SNK_SEND_SOFT_RESET);
break;
}
pd->current_state = PE_DRS_SEND_DR_SWAP;
kick_sm(pd, SENDER_RESPONSE_TIME);
} else if (is_sink_tx_ok(pd)) {
handle_vdm_tx(pd);
}
break;
case PE_SNK_TRANSITION_TO_DEFAULT:
usbpd_set_state(pd, PE_SNK_STARTUP);
break;
case PE_SRC_SOFT_RESET:
case PE_SNK_SOFT_RESET:
pd_reset_protocol(pd);
ret = pd_send_msg(pd, MSG_ACCEPT, NULL, 0, SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "%s: Error sending Accept, do Hard Reset\n",
usbpd_state_strings[pd->current_state]);
usbpd_set_state(pd, pd->current_pr == PR_SRC ?
PE_SRC_HARD_RESET : PE_SNK_HARD_RESET);
break;
}
usbpd_set_state(pd, pd->current_pr == PR_SRC ?
PE_SRC_SEND_CAPABILITIES :
PE_SNK_WAIT_FOR_CAPABILITIES);
break;
case PE_SRC_SEND_SOFT_RESET:
case PE_SNK_SEND_SOFT_RESET:
if (IS_CTRL(rx_msg, MSG_ACCEPT)) {
usbpd_set_state(pd, pd->current_pr == PR_SRC ?
PE_SRC_SEND_CAPABILITIES :
PE_SNK_WAIT_FOR_CAPABILITIES);
} else {
usbpd_err(&pd->dev, "%s: Did not see Accept, do Hard Reset\n",
usbpd_state_strings[pd->current_state]);
usbpd_set_state(pd, pd->current_pr == PR_SRC ?
PE_SRC_HARD_RESET : PE_SNK_HARD_RESET);
}
break;
case PE_SNK_HARD_RESET:
/* prepare charger for VBUS change */
val.intval = 1;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_IN_HARD_RESET, &val);
pd->requested_voltage = 5000000;
if (pd->requested_current) {
val.intval = pd->requested_current = 0;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_CURRENT_MAX, &val);
}
val.intval = pd->requested_voltage;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PD_VOLTAGE_MIN, &val);
pd_send_hard_reset(pd);
pd->in_explicit_contract = false;
pd->selected_pdo = pd->requested_pdo = 0;
pd->rdo = 0;
reset_vdm_state(pd);
kobject_uevent(&pd->dev.kobj, KOBJ_CHANGE);
usbpd_set_state(pd, PE_SNK_TRANSITION_TO_DEFAULT);
break;
case PE_DRS_SEND_DR_SWAP:
if (IS_CTRL(rx_msg, MSG_ACCEPT))
dr_swap(pd);
usbpd_set_state(pd, pd->current_pr == PR_SRC ?
PE_SRC_READY : PE_SNK_READY);
break;
case PE_PRS_SRC_SNK_SEND_SWAP:
if (!IS_CTRL(rx_msg, MSG_ACCEPT)) {
pd->current_state = PE_SRC_READY;
break;
}
pd->current_state = PE_PRS_SRC_SNK_TRANSITION_TO_OFF;
kick_sm(pd, SRC_TRANSITION_TIME);
break;
case PE_PRS_SRC_SNK_TRANSITION_TO_OFF:
pd->in_pr_swap = true;
val.intval = 1;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PR_SWAP, &val);
pd->in_explicit_contract = false;
if (pd->vbus_enabled) {
regulator_disable(pd->vbus);
pd->vbus_enabled = false;
}
/* PE_PRS_SRC_SNK_Assert_Rd */
pd->current_pr = PR_SINK;
set_power_role(pd, pd->current_pr);
pd_phy_update_roles(pd->current_dr, pd->current_pr);
/* allow time for Vbus discharge, must be < tSrcSwapStdby */
msleep(500);
ret = pd_send_msg(pd, MSG_PS_RDY, NULL, 0, SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending PS_RDY\n");
usbpd_set_state(pd, PE_ERROR_RECOVERY);
break;
}
pd->current_state = PE_PRS_SRC_SNK_WAIT_SOURCE_ON;
kick_sm(pd, PS_SOURCE_ON);
break;
case PE_PRS_SRC_SNK_WAIT_SOURCE_ON:
if (IS_CTRL(rx_msg, MSG_PS_RDY))
usbpd_set_state(pd, PE_SNK_STARTUP);
else
usbpd_set_state(pd, PE_ERROR_RECOVERY);
break;
case PE_PRS_SNK_SRC_SEND_SWAP:
if (!IS_CTRL(rx_msg, MSG_ACCEPT)) {
pd->current_state = PE_SNK_READY;
break;
}
pd->in_pr_swap = true;
val.intval = 1;
power_supply_set_property(pd->usb_psy,
POWER_SUPPLY_PROP_PR_SWAP, &val);
usbpd_set_state(pd, PE_PRS_SNK_SRC_TRANSITION_TO_OFF);
break;
case PE_PRS_SNK_SRC_TRANSITION_TO_OFF:
if (!IS_CTRL(rx_msg, MSG_PS_RDY)) {
usbpd_set_state(pd, PE_ERROR_RECOVERY);
break;
}
/* PE_PRS_SNK_SRC_Assert_Rp */
pd->current_pr = PR_SRC;
set_power_role(pd, pd->current_pr);
pd->current_state = PE_PRS_SNK_SRC_SOURCE_ON;
/* fall-through */
case PE_PRS_SNK_SRC_SOURCE_ON:
enable_vbus(pd);
msleep(200); /* allow time VBUS ramp-up, must be < tNewSrc */
ret = pd_send_msg(pd, MSG_PS_RDY, NULL, 0, SOP_MSG);
if (ret) {
usbpd_err(&pd->dev, "Error sending PS_RDY\n");
usbpd_set_state(pd, PE_ERROR_RECOVERY);
break;
}
usbpd_set_state(pd, PE_SRC_STARTUP);
break;
case PE_VCS_WAIT_FOR_VCONN:
if (IS_CTRL(rx_msg, MSG_PS_RDY)) {
/*
* hopefully redundant check but in case not enabled
* avoids unbalanced regulator disable count
*/
if (pd->vconn_enabled)
regulator_disable(pd->vconn);
pd->vconn_enabled = false;
pd->current_state = pd->current_pr == PR_SRC ?
PE_SRC_READY : PE_SNK_READY;
} else {
/* timed out; go to hard reset */
usbpd_set_state(pd, pd->current_pr == PR_SRC ?
PE_SRC_HARD_RESET : PE_SNK_HARD_RESET);
}
break;
default:
usbpd_err(&pd->dev, "Unhandled state %s\n",
usbpd_state_strings[pd->current_state]);
break;
}
sm_done:
kfree(rx_msg);
spin_lock_irqsave(&pd->rx_lock, flags);
ret = list_empty(&pd->rx_q);
spin_unlock_irqrestore(&pd->rx_lock, flags);
/* requeue if there are any new/pending RX messages */
if (!ret)
kick_sm(pd, 0);
if (!pd->sm_queued)
pm_relax(&pd->dev);
}
static inline const char *src_current(enum power_supply_typec_mode typec_mode)
{
switch (typec_mode) {
case POWER_SUPPLY_TYPEC_SOURCE_DEFAULT:
return "default";
case POWER_SUPPLY_TYPEC_SOURCE_MEDIUM:
return "medium - 1.5A";
case POWER_SUPPLY_TYPEC_SOURCE_HIGH:
return "high - 3.0A";
default:
return "";
}
}
static int psy_changed(struct notifier_block *nb, unsigned long evt, void *ptr)
{
struct usbpd *pd = container_of(nb, struct usbpd, psy_nb);
union power_supply_propval val;
enum power_supply_typec_mode typec_mode;
int ret;
if (ptr != pd->usb_psy || evt != PSY_EVENT_PROP_CHANGED)
return 0;
ret = power_supply_get_property(pd->usb_psy,
POWER_SUPPLY_PROP_TYPEC_MODE, &val);
if (ret) {
usbpd_err(&pd->dev, "Unable to read USB TYPEC_MODE: %d\n", ret);
return ret;
}
typec_mode = val.intval;
ret = power_supply_get_property(pd->usb_psy,
POWER_SUPPLY_PROP_PE_START, &val);
if (ret) {
usbpd_err(&pd->dev, "Unable to read USB PROP_PE_START: %d\n",
ret);
return ret;
}
/* Don't proceed if PE_START=0 as other props may still change */
if (!val.intval && !pd->pd_connected &&
typec_mode != POWER_SUPPLY_TYPEC_NONE)
return 0;
ret = power_supply_get_property(pd->usb_psy,
POWER_SUPPLY_PROP_PRESENT, &val);
if (ret) {
usbpd_err(&pd->dev, "Unable to read USB PRESENT: %d\n", ret);
return ret;
}
pd->vbus_present = val.intval;
ret = power_supply_get_property(pd->usb_psy,
POWER_SUPPLY_PROP_REAL_TYPE, &val);
if (ret) {
usbpd_err(&pd->dev, "Unable to read USB TYPE: %d\n", ret);
return ret;
}
pd->psy_type = val.intval;
/*
* For sink hard reset, state machine needs to know when VBUS changes
* - when in PE_SNK_TRANSITION_TO_DEFAULT, notify when VBUS falls
* - when in PE_SNK_DISCOVERY, notify when VBUS rises
*/
if (typec_mode && ((!pd->vbus_present &&
pd->current_state == PE_SNK_TRANSITION_TO_DEFAULT) ||
(pd->vbus_present && pd->current_state == PE_SNK_DISCOVERY))) {
usbpd_dbg(&pd->dev, "hard reset: typec mode:%d present:%d\n",
typec_mode, pd->vbus_present);
pd->typec_mode = typec_mode;
kick_sm(pd, 0);
return 0;
}
if (pd->typec_mode == typec_mode)
return 0;
pd->typec_mode = typec_mode;
usbpd_dbg(&pd->dev, "typec mode:%d present:%d type:%d orientation:%d\n",
typec_mode, pd->vbus_present, pd->psy_type,
usbpd_get_plug_orientation(pd));
switch (typec_mode) {
/* Disconnect */
case POWER_SUPPLY_TYPEC_NONE:
if (pd->in_pr_swap) {
usbpd_dbg(&pd->dev, "Ignoring disconnect due to PR swap\n");
return 0;
}
pd->current_pr = PR_NONE;
break;
/* Sink states */
case POWER_SUPPLY_TYPEC_SOURCE_DEFAULT:
case POWER_SUPPLY_TYPEC_SOURCE_MEDIUM:
case POWER_SUPPLY_TYPEC_SOURCE_HIGH:
usbpd_info(&pd->dev, "Type-C Source (%s) connected\n",
src_current(typec_mode));
/* if waiting for SinkTxOk to start an AMS */
if (pd->spec_rev == USBPD_REV_30 &&
typec_mode == POWER_SUPPLY_TYPEC_SOURCE_HIGH &&
(pd->send_pr_swap || pd->send_dr_swap || pd->vdm_tx))
break;
if (pd->current_pr == PR_SINK)
return 0;
/*
* Unexpected if not in PR swap; need to force disconnect from
* source so we can turn off VBUS, Vconn, PD PHY etc.
*/
if (pd->current_pr == PR_SRC) {
usbpd_info(&pd->dev, "Forcing disconnect from source mode\n");
pd->current_pr = PR_NONE;
break;
}
pd->current_pr = PR_SINK;
break;
/* Source states */
case POWER_SUPPLY_TYPEC_SINK_POWERED_CABLE:
case POWER_SUPPLY_TYPEC_SINK:
usbpd_info(&pd->dev, "Type-C Sink%s connected\n",
typec_mode == POWER_SUPPLY_TYPEC_SINK ?
"" : " (powered)");
if (pd->current_pr == PR_SRC)
return 0;
pd->current_pr = PR_SRC;
break;
case POWER_SUPPLY_TYPEC_SINK_DEBUG_ACCESSORY:
usbpd_info(&pd->dev, "Type-C Debug Accessory connected\n");
break;
case POWER_SUPPLY_TYPEC_SINK_AUDIO_ADAPTER:
usbpd_info(&pd->dev, "Type-C Analog Audio Adapter connected\n");
break;
default:
usbpd_warn(&pd->dev, "Unsupported typec mode:%d\n",
typec_mode);
break;
}
/* queue state machine due to CC state change */
kick_sm(pd, 0);
return 0;
}
static enum dual_role_property usbpd_dr_properties[] = {
DUAL_ROLE_PROP_SUPPORTED_MODES,
DUAL_ROLE_PROP_MODE,
DUAL_ROLE_PROP_PR,
DUAL_ROLE_PROP_DR,
};
static int usbpd_dr_get_property(struct dual_role_phy_instance *dual_role,
enum dual_role_property prop, unsigned int *val)
{
struct usbpd *pd = dual_role_get_drvdata(dual_role);
if (!pd)
return -ENODEV;
switch (prop) {
case DUAL_ROLE_PROP_MODE:
/* For now associate UFP/DFP with data role only */
if (pd->current_dr == DR_UFP)
*val = DUAL_ROLE_PROP_MODE_UFP;
else if (pd->current_dr == DR_DFP)
*val = DUAL_ROLE_PROP_MODE_DFP;
else
*val = DUAL_ROLE_PROP_MODE_NONE;
break;
case DUAL_ROLE_PROP_PR:
if (pd->current_pr == PR_SRC)
*val = DUAL_ROLE_PROP_PR_SRC;
else if (pd->current_pr == PR_SINK)
*val = DUAL_ROLE_PROP_PR_SNK;
else
*val = DUAL_ROLE_PROP_PR_NONE;
break;
case DUAL_ROLE_PROP_DR:
if (pd->current_dr == DR_UFP)
*val = DUAL_ROLE_PROP_DR_DEVICE;
else if (pd->current_dr == DR_DFP)
*val = DUAL_ROLE_PROP_DR_HOST;
else
*val = DUAL_ROLE_PROP_DR_NONE;
break;
default:
usbpd_warn(&pd->dev, "unsupported property %d\n", prop);
return -ENODATA;
}
return 0;
}
static int usbpd_dr_set_property(struct dual_role_phy_instance *dual_role,
enum dual_role_property prop, const unsigned int *val)
{
struct usbpd *pd = dual_role_get_drvdata(dual_role);
bool do_swap = false;
if (!pd)
return -ENODEV;
switch (prop) {
case DUAL_ROLE_PROP_MODE:
usbpd_dbg(&pd->dev, "Setting mode to %d\n", *val);
/*
* Forces disconnect on CC and re-establishes connection.
* This does not use PD-based PR/DR swap
*/
if (*val == DUAL_ROLE_PROP_MODE_UFP)
pd->forced_pr = POWER_SUPPLY_TYPEC_PR_SINK;
else if (*val == DUAL_ROLE_PROP_MODE_DFP)
pd->forced_pr = POWER_SUPPLY_TYPEC_PR_SOURCE;
/* new mode will be applied in disconnect handler */
set_power_role(pd, PR_NONE);
/* wait until it takes effect */
while (pd->forced_pr != POWER_SUPPLY_TYPEC_PR_NONE)
msleep(20);
break;
case DUAL_ROLE_PROP_DR:
usbpd_dbg(&pd->dev, "Setting data_role to %d\n", *val);
if (*val == DUAL_ROLE_PROP_DR_HOST) {
if (pd->current_dr == DR_UFP)
do_swap = true;
} else if (*val == DUAL_ROLE_PROP_DR_DEVICE) {
if (pd->current_dr == DR_DFP)
do_swap = true;
} else {
usbpd_warn(&pd->dev, "setting data_role to 'none' unsupported\n");
return -ENOTSUPP;
}
if (do_swap) {
if (pd->current_state != PE_SRC_READY &&
pd->current_state != PE_SNK_READY) {
usbpd_err(&pd->dev, "data_role swap not allowed: PD not in Ready state\n");
return -EAGAIN;
}
if (pd->current_state == PE_SNK_READY &&
!is_sink_tx_ok(pd)) {
usbpd_err(&pd->dev, "Rp indicates SinkTxNG\n");
return -EAGAIN;
}
mutex_lock(&pd->swap_lock);
reinit_completion(&pd->is_ready);
pd->send_dr_swap = true;
kick_sm(pd, 0);
/* wait for operation to complete */
if (!wait_for_completion_timeout(&pd->is_ready,
msecs_to_jiffies(100))) {
usbpd_err(&pd->dev, "data_role swap timed out\n");
mutex_unlock(&pd->swap_lock);
return -ETIMEDOUT;
}
mutex_unlock(&pd->swap_lock);
if ((*val == DUAL_ROLE_PROP_DR_HOST &&
pd->current_dr != DR_DFP) ||
(*val == DUAL_ROLE_PROP_DR_DEVICE &&
pd->current_dr != DR_UFP)) {
usbpd_err(&pd->dev, "incorrect state (%s) after data_role swap\n",
pd->current_dr == DR_DFP ?
"dfp" : "ufp");
return -EPROTO;
}
}
break;
case DUAL_ROLE_PROP_PR:
usbpd_dbg(&pd->dev, "Setting power_role to %d\n", *val);
if (*val == DUAL_ROLE_PROP_PR_SRC) {
if (pd->current_pr == PR_SINK)
do_swap = true;
} else if (*val == DUAL_ROLE_PROP_PR_SNK) {
if (pd->current_pr == PR_SRC)
do_swap = true;
} else {
usbpd_warn(&pd->dev, "setting power_role to 'none' unsupported\n");
return -ENOTSUPP;
}
if (do_swap) {
if (pd->current_state != PE_SRC_READY &&
pd->current_state != PE_SNK_READY) {
usbpd_err(&pd->dev, "power_role swap not allowed: PD not in Ready state\n");
return -EAGAIN;
}
if (pd->current_state == PE_SNK_READY &&
!is_sink_tx_ok(pd)) {
usbpd_err(&pd->dev, "Rp indicates SinkTxNG\n");
return -EAGAIN;
}
mutex_lock(&pd->swap_lock);
reinit_completion(&pd->is_ready);
pd->send_pr_swap = true;
kick_sm(pd, 0);
/* wait for operation to complete */
if (!wait_for_completion_timeout(&pd->is_ready,
msecs_to_jiffies(2000))) {
usbpd_err(&pd->dev, "power_role swap timed out\n");
mutex_unlock(&pd->swap_lock);
return -ETIMEDOUT;
}
mutex_unlock(&pd->swap_lock);
if ((*val == DUAL_ROLE_PROP_PR_SRC &&
pd->current_pr != PR_SRC) ||
(*val == DUAL_ROLE_PROP_PR_SNK &&
pd->current_pr != PR_SINK)) {
usbpd_err(&pd->dev, "incorrect state (%s) after power_role swap\n",
pd->current_pr == PR_SRC ?
"source" : "sink");
return -EPROTO;
}
}
break;
default:
usbpd_warn(&pd->dev, "unsupported property %d\n", prop);
return -ENOTSUPP;
}
return 0;
}
static int usbpd_dr_prop_writeable(struct dual_role_phy_instance *dual_role,
enum dual_role_property prop)
{
struct usbpd *pd = dual_role_get_drvdata(dual_role);
switch (prop) {
case DUAL_ROLE_PROP_MODE:
return 1;
case DUAL_ROLE_PROP_DR:
case DUAL_ROLE_PROP_PR:
if (pd)
return pd->current_state == PE_SNK_READY ||
pd->current_state == PE_SRC_READY;
break;
default:
break;
}
return 0;
}
static int usbpd_uevent(struct device *dev, struct kobj_uevent_env *env)
{
struct usbpd *pd = dev_get_drvdata(dev);
int i;
add_uevent_var(env, "DATA_ROLE=%s", pd->current_dr == DR_DFP ?
"dfp" : "ufp");
if (pd->current_pr == PR_SINK) {
add_uevent_var(env, "POWER_ROLE=sink");
add_uevent_var(env, "SRC_CAP_ID=%d", pd->src_cap_id);
for (i = 0; i < ARRAY_SIZE(pd->received_pdos); i++)
add_uevent_var(env, "PDO%d=%08x", i,
pd->received_pdos[i]);
add_uevent_var(env, "REQUESTED_PDO=%d", pd->requested_pdo);
add_uevent_var(env, "SELECTED_PDO=%d", pd->selected_pdo);
} else {
add_uevent_var(env, "POWER_ROLE=source");
for (i = 0; i < ARRAY_SIZE(default_src_caps); i++)
add_uevent_var(env, "PDO%d=%08x", i,
default_src_caps[i]);
}
add_uevent_var(env, "RDO=%08x", pd->rdo);
add_uevent_var(env, "CONTRACT=%s", pd->in_explicit_contract ?
"explicit" : "implicit");
add_uevent_var(env, "ALT_MODE=%d", pd->vdm_state == MODE_ENTERED);
add_uevent_var(env, "ADO=%08x", pd->received_ado);
for (i = 0; i < PD_STATUS_DB_LEN; i++)
add_uevent_var(env, "SDB%d=%08x", i, pd->status_db[i]);
return 0;
}
static ssize_t contract_show(struct device *dev, struct device_attribute *attr,
char *buf)
{
struct usbpd *pd = dev_get_drvdata(dev);
return snprintf(buf, PAGE_SIZE, "%s\n",
pd->in_explicit_contract ? "explicit" : "implicit");
}
static DEVICE_ATTR_RO(contract);
static ssize_t current_pr_show(struct device *dev,
struct device_attribute *attr, char *buf)
{
struct usbpd *pd = dev_get_drvdata(dev);
const char *pr = "none";
if (pd->current_pr == PR_SINK)
pr = "sink";
else if (pd->current_pr == PR_SRC)
pr = "source";
return snprintf(buf, PAGE_SIZE, "%s\n", pr);
}
static DEVICE_ATTR_RO(current_pr);
static ssize_t initial_pr_show(struct device *dev,
struct device_attribute *attr, char *buf)
{
struct usbpd *pd = dev_get_drvdata(dev);
const char *pr = "none";
if (pd->typec_mode >= POWER_SUPPLY_TYPEC_SOURCE_DEFAULT)
pr = "sink";
else if (pd->typec_mode >= POWER_SUPPLY_TYPEC_SINK)
pr = "source";
return snprintf(buf, PAGE_SIZE, "%s\n", pr);
}
static DEVICE_ATTR_RO(initial_pr);
static ssize_t current_dr_show(struct device *dev,
struct device_attribute *attr, char *buf)
{
struct usbpd *pd = dev_get_drvdata(dev);
const char *dr = "none";
if (pd->current_dr == DR_UFP)
dr = "ufp";
else if (pd->current_dr == DR_DFP)
dr = "dfp";
return snprintf(buf, PAGE_SIZE, "%s\n", dr);
}
static DEVICE_ATTR_RO(current_dr);
static ssize_t initial_dr_show(struct device *dev,
struct device_attribute *attr, char *buf)
{
struct usbpd *pd = dev_get_drvdata(dev);
const char *dr = "none";
if (pd->typec_mode >= POWER_SUPPLY_TYPEC_SOURCE_DEFAULT)
dr = "ufp";
else if (pd->typec_mode >= POWER_SUPPLY_TYPEC_SINK)
dr = "dfp";
return snprintf(buf, PAGE_SIZE, "%s\n", dr);
}
static DEVICE_ATTR_RO(initial_dr);
static ssize_t src_cap_id_show(struct device *dev,
struct device_attribute *attr, char *buf)
{
struct usbpd *pd = dev_get_drvdata(dev);
return snprintf(buf, PAGE_SIZE, "%d\n", pd->src_cap_id);
}
static DEVICE_ATTR_RO(src_cap_id);
/* Dump received source PDOs in human-readable format */
static ssize_t pdo_h_show(struct device *dev, struct device_attribute *attr,
char *buf)
{
struct usbpd *pd = dev_get_drvdata(dev);
int i;
ssize_t cnt = 0;
for (i = 0; i < ARRAY_SIZE(pd->received_pdos); i++) {
u32 pdo = pd->received_pdos[i];
if (pdo == 0)
break;
cnt += scnprintf(&buf[cnt], PAGE_SIZE - cnt, "PDO %d\n", i + 1);
if (PD_SRC_PDO_TYPE(pdo) == PD_SRC_PDO_TYPE_FIXED) {
cnt += scnprintf(&buf[cnt], PAGE_SIZE - cnt,
"\tFixed supply\n"
"\tDual-Role Power:%d\n"
"\tUSB Suspend Supported:%d\n"
"\tExternally Powered:%d\n"
"\tUSB Communications Capable:%d\n"
"\tData Role Swap:%d\n"
"\tPeak Current:%d\n"
"\tVoltage:%d (mV)\n"
"\tMax Current:%d (mA)\n",
PD_SRC_PDO_FIXED_PR_SWAP(pdo),
PD_SRC_PDO_FIXED_USB_SUSP(pdo),
PD_SRC_PDO_FIXED_EXT_POWERED(pdo),
PD_SRC_PDO_FIXED_USB_COMM(pdo),
PD_SRC_PDO_FIXED_DR_SWAP(pdo),
PD_SRC_PDO_FIXED_PEAK_CURR(pdo),
PD_SRC_PDO_FIXED_VOLTAGE(pdo) * 50,
PD_SRC_PDO_FIXED_MAX_CURR(pdo) * 10);
} else if (PD_SRC_PDO_TYPE(pdo) == PD_SRC_PDO_TYPE_BATTERY) {
cnt += scnprintf(&buf[cnt], PAGE_SIZE - cnt,
"\tBattery supply\n"
"\tMax Voltage:%d (mV)\n"
"\tMin Voltage:%d (mV)\n"
"\tMax Power:%d (mW)\n",
PD_SRC_PDO_VAR_BATT_MAX_VOLT(pdo) * 50,
PD_SRC_PDO_VAR_BATT_MIN_VOLT(pdo) * 50,
PD_SRC_PDO_VAR_BATT_MAX(pdo) * 250);
} else if (PD_SRC_PDO_TYPE(pdo) == PD_SRC_PDO_TYPE_VARIABLE) {
cnt += scnprintf(&buf[cnt], PAGE_SIZE - cnt,
"\tVariable supply\n"
"\tMax Voltage:%d (mV)\n"
"\tMin Voltage:%d (mV)\n"
"\tMax Current:%d (mA)\n",
PD_SRC_PDO_VAR_BATT_MAX_VOLT(pdo) * 50,
PD_SRC_PDO_VAR_BATT_MIN_VOLT(pdo) * 50,
PD_SRC_PDO_VAR_BATT_MAX(pdo) * 10);
} else if (PD_SRC_PDO_TYPE(pdo) == PD_SRC_PDO_TYPE_AUGMENTED) {
cnt += scnprintf(&buf[cnt], PAGE_SIZE - cnt,
"\tProgrammable Power supply\n"
"\tMax Voltage:%d (mV)\n"
"\tMin Voltage:%d (mV)\n"
"\tMax Current:%d (mA)\n",
PD_APDO_MAX_VOLT(pdo) * 100,
PD_APDO_MIN_VOLT(pdo) * 100,
PD_APDO_MAX_CURR(pdo) * 50);
} else {
cnt += scnprintf(&buf[cnt], PAGE_SIZE - cnt,
"Invalid PDO\n");
}
buf[cnt++] = '\n';
}
return cnt;
}
static DEVICE_ATTR_RO(pdo_h);
static ssize_t pdo_n_show(struct device *dev, struct device_attribute *attr,
char *buf);
#define PDO_ATTR(n) { \
.attr = { .name = __stringify(pdo##n), .mode = 0444 }, \
.show = pdo_n_show, \
}
static struct device_attribute dev_attr_pdos[] = {
PDO_ATTR(1),
PDO_ATTR(2),
PDO_ATTR(3),
PDO_ATTR(4),
PDO_ATTR(5),
PDO_ATTR(6),
PDO_ATTR(7),
};
static ssize_t pdo_n_show(struct device *dev, struct device_attribute *attr,
char *buf)
{
struct usbpd *pd = dev_get_drvdata(dev);
int i;
for (i = 0; i < ARRAY_SIZE(dev_attr_pdos); i++)
if (attr == &dev_attr_pdos[i])
/* dump the PDO as a hex string */
return snprintf(buf, PAGE_SIZE, "%08x\n",
pd->received_pdos[i]);
usbpd_err(&pd->dev, "Invalid PDO index\n");
return -EINVAL;
}
static ssize_t select_pdo_store(struct device *dev,
struct device_attribute *attr, const char *buf, size_t size)
{
struct usbpd *pd = dev_get_drvdata(dev);
int src_cap_id;
int pdo, uv = 0, ua = 0;
int ret;
mutex_lock(&pd->swap_lock);
/* Only allowed if we are already in explicit sink contract */
if (pd->current_state != PE_SNK_READY || !is_sink_tx_ok(pd)) {
usbpd_err(&pd->dev, "select_pdo: Cannot select new PDO yet\n");
ret = -EBUSY;
goto out;
}
ret = sscanf(buf, "%d %d %d %d", &src_cap_id, &pdo, &uv, &ua);
if (ret != 2 && ret != 4) {
usbpd_err(&pd->dev, "select_pdo: Must specify <src cap id> <PDO> [<uV> <uA>]\n");
ret = -EINVAL;
goto out;
}
if (src_cap_id != pd->src_cap_id) {
usbpd_err(&pd->dev, "select_pdo: src_cap_id mismatch. Requested:%d, current:%d\n",
src_cap_id, pd->src_cap_id);
ret = -EINVAL;
goto out;
}
if (pdo < 1 || pdo > 7) {
usbpd_err(&pd->dev, "select_pdo: invalid PDO:%d\n", pdo);
ret = -EINVAL;
goto out;
}
ret = pd_select_pdo(pd, pdo, uv, ua);
if (ret)
goto out;
reinit_completion(&pd->is_ready);
pd->send_request = true;
kick_sm(pd, 0);
/* wait for operation to complete */
if (!wait_for_completion_timeout(&pd->is_ready,
msecs_to_jiffies(1000))) {
usbpd_err(&pd->dev, "select_pdo: request timed out\n");
ret = -ETIMEDOUT;
goto out;
}
/* determine if request was accepted/rejected */
if (pd->selected_pdo != pd->requested_pdo ||
pd->current_voltage != pd->requested_voltage) {
usbpd_err(&pd->dev, "select_pdo: request rejected\n");
ret = -EINVAL;
}
out:
pd->send_request = false;
mutex_unlock(&pd->swap_lock);
return ret ? ret : size;
}
static ssize_t select_pdo_show(struct device *dev,
struct device_attribute *attr, char *buf)
{
struct usbpd *pd = dev_get_drvdata(dev);
return snprintf(buf, PAGE_SIZE, "%d\n", pd->selected_pdo);
}
static DEVICE_ATTR_RW(select_pdo);
static ssize_t rdo_show(struct device *dev, struct device_attribute *attr,
char *buf)
{
struct usbpd *pd = dev_get_drvdata(dev);
/* dump the RDO as a hex string */
return snprintf(buf, PAGE_SIZE, "%08x\n", pd->rdo);
}
static DEVICE_ATTR_RO(rdo);
static ssize_t rdo_h_show(struct device *dev, struct device_attribute *attr,
char *buf)
{
struct usbpd *pd = dev_get_drvdata(dev);
int pos = PD_RDO_OBJ_POS(pd->rdo);
int type = PD_SRC_PDO_TYPE(pd->received_pdos[pos]);
int len;
len = scnprintf(buf, PAGE_SIZE, "Request Data Object\n"
"\tObj Pos:%d\n"
"\tGiveback:%d\n"
"\tCapability Mismatch:%d\n"
"\tUSB Communications Capable:%d\n"
"\tNo USB Suspend:%d\n",
PD_RDO_OBJ_POS(pd->rdo),
PD_RDO_GIVEBACK(pd->rdo),
PD_RDO_MISMATCH(pd->rdo),
PD_RDO_USB_COMM(pd->rdo),
PD_RDO_NO_USB_SUSP(pd->rdo));
switch (type) {
case PD_SRC_PDO_TYPE_FIXED:
case PD_SRC_PDO_TYPE_VARIABLE:
len += scnprintf(buf + len, PAGE_SIZE - len,
"(Fixed/Variable)\n"
"\tOperating Current:%d (mA)\n"
"\t%s Current:%d (mA)\n",
PD_RDO_FIXED_CURR(pd->rdo) * 10,
PD_RDO_GIVEBACK(pd->rdo) ? "Min" : "Max",
PD_RDO_FIXED_CURR_MINMAX(pd->rdo) * 10);
break;
case PD_SRC_PDO_TYPE_BATTERY:
len += scnprintf(buf + len, PAGE_SIZE - len,
"(Battery)\n"
"\tOperating Power:%d (mW)\n"
"\t%s Power:%d (mW)\n",
PD_RDO_FIXED_CURR(pd->rdo) * 250,
PD_RDO_GIVEBACK(pd->rdo) ? "Min" : "Max",
PD_RDO_FIXED_CURR_MINMAX(pd->rdo) * 250);
break;
case PD_SRC_PDO_TYPE_AUGMENTED:
len += scnprintf(buf + len, PAGE_SIZE - len,
"(Programmable)\n"
"\tOutput Voltage:%d (mV)\n"
"\tOperating Current:%d (mA)\n",
PD_RDO_PROG_VOLTAGE(pd->rdo) * 20,
PD_RDO_PROG_CURR(pd->rdo) * 50);
break;
}
return len;
}
static DEVICE_ATTR_RO(rdo_h);
static ssize_t hard_reset_store(struct device *dev,
struct device_attribute *attr, const char *buf, size_t size)
{
struct usbpd *pd = dev_get_drvdata(dev);
int val = 0;
if (sscanf(buf, "%d\n", &val) != 1)
return -EINVAL;
if (val)
usbpd_set_state(pd, pd->current_pr == PR_SRC ?
PE_SRC_HARD_RESET : PE_SNK_HARD_RESET);
return size;
}
static DEVICE_ATTR_WO(hard_reset);
static int trigger_tx_msg(struct usbpd *pd, bool *msg_tx_flag)
{
int ret = 0;
/* Only allowed if we are already in explicit sink contract */
if (pd->current_state != PE_SNK_READY || !is_sink_tx_ok(pd)) {
usbpd_err(&pd->dev, "%s: Cannot send msg\n", __func__);
ret = -EBUSY;
goto out;
}
reinit_completion(&pd->is_ready);
*msg_tx_flag = true;
kick_sm(pd, 0);
/* wait for operation to complete */
if (!wait_for_completion_timeout(&pd->is_ready,
msecs_to_jiffies(1000))) {
usbpd_err(&pd->dev, "%s: request timed out\n", __func__);
ret = -ETIMEDOUT;
}
out:
*msg_tx_flag = false;
return ret;
}
static ssize_t get_src_cap_ext_show(struct device *dev,
struct device_attribute *attr, char *buf)
{
int i, ret, len = 0;
struct usbpd *pd = dev_get_drvdata(dev);
if (pd->spec_rev == USBPD_REV_20)
return -EINVAL;
ret = trigger_tx_msg(pd, &pd->send_get_src_cap_ext);
if (ret)
return ret;
for (i = 0; i < PD_SRC_CAP_EXT_DB_LEN; i++)
len += snprintf(buf + len, PAGE_SIZE - len, "%d\n",
pd->src_cap_ext_db[i]);
return len;
}
static DEVICE_ATTR_RO(get_src_cap_ext);
static ssize_t get_pps_status_show(struct device *dev,
struct device_attribute *attr, char *buf)
{
int ret;
struct usbpd *pd = dev_get_drvdata(dev);
if (pd->spec_rev == USBPD_REV_20)
return -EINVAL;
ret = trigger_tx_msg(pd, &pd->send_get_pps_status);
if (ret)
return ret;
return snprintf(buf, PAGE_SIZE, "%d\n", pd->pps_status_db);
}
static DEVICE_ATTR_RO(get_pps_status);
static ssize_t rx_ado_show(struct device *dev, struct device_attribute *attr,
char *buf)
{
struct usbpd *pd = dev_get_drvdata(dev);
/* dump the ADO as a hex string */
return snprintf(buf, PAGE_SIZE, "%08x\n", pd->received_ado);
}
static DEVICE_ATTR_RO(rx_ado);
static ssize_t get_battery_cap_store(struct device *dev,
struct device_attribute *attr, const char *buf, size_t size)
{
struct usbpd *pd = dev_get_drvdata(dev);
int val, ret;
if (pd->spec_rev == USBPD_REV_20 || sscanf(buf, "%d\n", &val) != 1) {
pd->get_battery_cap_db = -EINVAL;
return -EINVAL;
}
pd->get_battery_cap_db = val;
ret = trigger_tx_msg(pd, &pd->send_get_battery_cap);
return ret ? ret : size;
}
static ssize_t get_battery_cap_show(struct device *dev,
struct device_attribute *attr, char *buf)
{
int i, len = 0;
struct usbpd *pd = dev_get_drvdata(dev);
if (pd->get_battery_cap_db == -EINVAL)
return -EINVAL;
for (i = 0; i < PD_BATTERY_CAP_DB_LEN; i++)
len += snprintf(buf + len, PAGE_SIZE - len, "%d\n",
pd->battery_cap_db[i]);
return len;
}
static DEVICE_ATTR_RW(get_battery_cap);
static ssize_t get_battery_status_store(struct device *dev,
struct device_attribute *attr, const char *buf, size_t size)
{
struct usbpd *pd = dev_get_drvdata(dev);
int val, ret;
if (pd->spec_rev == USBPD_REV_20 || sscanf(buf, "%d\n", &val) != 1) {
pd->get_battery_status_db = -EINVAL;
return -EINVAL;
}
pd->get_battery_status_db = val;
ret = trigger_tx_msg(pd, &pd->send_get_battery_status);
return ret ? ret : size;
}
static ssize_t get_battery_status_show(struct device *dev,
struct device_attribute *attr, char *buf)
{
struct usbpd *pd = dev_get_drvdata(dev);
if (pd->get_battery_status_db == -EINVAL)
return -EINVAL;
return snprintf(buf, PAGE_SIZE, "%d\n", pd->battery_sts_dobj);
}
static DEVICE_ATTR_RW(get_battery_status);
static struct attribute *usbpd_attrs[] = {
&dev_attr_contract.attr,
&dev_attr_initial_pr.attr,
&dev_attr_current_pr.attr,
&dev_attr_initial_dr.attr,
&dev_attr_current_dr.attr,
&dev_attr_src_cap_id.attr,
&dev_attr_pdo_h.attr,
&dev_attr_pdos[0].attr,
&dev_attr_pdos[1].attr,
&dev_attr_pdos[2].attr,
&dev_attr_pdos[3].attr,
&dev_attr_pdos[4].attr,
&dev_attr_pdos[5].attr,
&dev_attr_pdos[6].attr,
&dev_attr_select_pdo.attr,
&dev_attr_rdo.attr,
&dev_attr_rdo_h.attr,
&dev_attr_hard_reset.attr,
&dev_attr_get_src_cap_ext.attr,
&dev_attr_get_pps_status.attr,
&dev_attr_rx_ado.attr,
&dev_attr_get_battery_cap.attr,
&dev_attr_get_battery_status.attr,
NULL,
};
ATTRIBUTE_GROUPS(usbpd);
static struct class usbpd_class = {
.name = "usbpd",
.owner = THIS_MODULE,
.dev_uevent = usbpd_uevent,
.dev_groups = usbpd_groups,
};
static int match_usbpd_device(struct device *dev, const void *data)
{
return dev->parent == data;
}
static void devm_usbpd_put(struct device *dev, void *res)
{
struct usbpd **ppd = res;
put_device(&(*ppd)->dev);
}
struct usbpd *devm_usbpd_get_by_phandle(struct device *dev, const char *phandle)
{
struct usbpd **ptr, *pd = NULL;
struct device_node *pd_np;
struct platform_device *pdev;
struct device *pd_dev;
if (!usbpd_class.p) /* usbpd_init() not yet called */
return ERR_PTR(-EAGAIN);
if (!dev->of_node)
return ERR_PTR(-EINVAL);
pd_np = of_parse_phandle(dev->of_node, phandle, 0);
if (!pd_np)
return ERR_PTR(-ENXIO);
pdev = of_find_device_by_node(pd_np);
if (!pdev)
return ERR_PTR(-ENODEV);
pd_dev = class_find_device(&usbpd_class, NULL, &pdev->dev,
match_usbpd_device);
if (!pd_dev) {
platform_device_put(pdev);
/* device was found but maybe hadn't probed yet, so defer */
return ERR_PTR(-EPROBE_DEFER);
}
ptr = devres_alloc(devm_usbpd_put, sizeof(*ptr), GFP_KERNEL);
if (!ptr) {
put_device(pd_dev);
platform_device_put(pdev);
return ERR_PTR(-ENOMEM);
}
pd = dev_get_drvdata(pd_dev);
if (!pd)
return ERR_PTR(-EPROBE_DEFER);
*ptr = pd;
devres_add(dev, ptr);
return pd;
}
EXPORT_SYMBOL(devm_usbpd_get_by_phandle);
static int num_pd_instances;
/**
* usbpd_create - Create a new instance of USB PD protocol/policy engine
* @parent - parent device to associate with
*
* This creates a new usbpd class device which manages the state of a
* USB PD-capable port. The parent device that is passed in should be
* associated with the physical device port, e.g. a PD PHY.
*
* Return: struct usbpd pointer, or an ERR_PTR value
*/
struct usbpd *usbpd_create(struct device *parent)
{
int ret;
struct usbpd *pd;
pd = kzalloc(sizeof(*pd), GFP_KERNEL);
if (!pd)
return ERR_PTR(-ENOMEM);
device_initialize(&pd->dev);
pd->dev.class = &usbpd_class;
pd->dev.parent = parent;
dev_set_drvdata(&pd->dev, pd);
ret = dev_set_name(&pd->dev, "usbpd%d", num_pd_instances++);
if (ret)
goto free_pd;
ret = device_init_wakeup(&pd->dev, true);
if (ret)
goto free_pd;
ret = device_add(&pd->dev);
if (ret)
goto free_pd;
pd->wq = alloc_ordered_workqueue("usbpd_wq", WQ_FREEZABLE | WQ_HIGHPRI);
if (!pd->wq) {
ret = -ENOMEM;
goto del_pd;
}
INIT_WORK(&pd->sm_work, usbpd_sm);
hrtimer_init(&pd->timer, CLOCK_MONOTONIC, HRTIMER_MODE_REL);
pd->timer.function = pd_timeout;
mutex_init(&pd->swap_lock);
mutex_init(&pd->svid_handler_lock);
pd->usb_psy = power_supply_get_by_name("usb");
if (!pd->usb_psy) {
usbpd_dbg(&pd->dev, "Could not get USB power_supply, deferring probe\n");
ret = -EPROBE_DEFER;
goto destroy_wq;
}
if (get_connector_type(pd) == POWER_SUPPLY_CONNECTOR_MICRO_USB) {
usbpd_dbg(&pd->dev, "USB connector is microAB hence failing pdphy_probe\n");
ret = -EINVAL;
goto put_psy;
}
/*
* associate extcon with the parent dev as it could have a DT
* node which will be useful for extcon_get_edev_by_phandle()
*/
pd->extcon = devm_extcon_dev_allocate(parent, usbpd_extcon_cable);
if (IS_ERR(pd->extcon)) {
usbpd_err(&pd->dev, "failed to allocate extcon device\n");
ret = PTR_ERR(pd->extcon);
goto put_psy;
}
pd->extcon->mutually_exclusive = usbpd_extcon_exclusive;
ret = devm_extcon_dev_register(parent, pd->extcon);
if (ret) {
usbpd_err(&pd->dev, "failed to register extcon device\n");
goto put_psy;
}
/* Support reporting polarity and speed via properties */
extcon_set_property_capability(pd->extcon, EXTCON_USB,
EXTCON_PROP_USB_TYPEC_POLARITY);
extcon_set_property_capability(pd->extcon, EXTCON_USB,
EXTCON_PROP_USB_SS);
extcon_set_property_capability(pd->extcon, EXTCON_USB_HOST,
EXTCON_PROP_USB_TYPEC_POLARITY);
extcon_set_property_capability(pd->extcon, EXTCON_USB_HOST,
EXTCON_PROP_USB_SS);
pd->vbus = devm_regulator_get(parent, "vbus");
if (IS_ERR(pd->vbus)) {
ret = PTR_ERR(pd->vbus);
goto put_psy;
}
pd->vconn = devm_regulator_get(parent, "vconn");
if (IS_ERR(pd->vconn)) {
ret = PTR_ERR(pd->vconn);
goto put_psy;
}
pd->vconn_is_external = device_property_present(parent,
"qcom,vconn-uses-external-source");
pd->num_sink_caps = device_property_read_u32_array(parent,
"qcom,default-sink-caps", NULL, 0);
if (pd->num_sink_caps > 0) {
int i;
u32 sink_caps[14];
if (pd->num_sink_caps % 2 || pd->num_sink_caps > 14) {
ret = -EINVAL;
usbpd_err(&pd->dev, "default-sink-caps must be be specified as voltage/current, max 7 pairs\n");
goto put_psy;
}
ret = device_property_read_u32_array(parent,
"qcom,default-sink-caps", sink_caps,
pd->num_sink_caps);
if (ret) {
usbpd_err(&pd->dev, "Error reading default-sink-caps\n");
goto put_psy;
}
pd->num_sink_caps /= 2;
for (i = 0; i < pd->num_sink_caps; i++) {
int v = sink_caps[i * 2] / 50;
int c = sink_caps[i * 2 + 1] / 10;
pd->sink_caps[i] =
PD_SNK_PDO_FIXED(0, 0, 0, 0, 0, v, c);
}
/* First PDO includes additional capabilities */
pd->sink_caps[0] |= PD_SNK_PDO_FIXED(1, 0, 0, 1, 1, 0, 0);
} else {
memcpy(pd->sink_caps, default_snk_caps,
sizeof(default_snk_caps));
pd->num_sink_caps = ARRAY_SIZE(default_snk_caps);
}
/*
* Register the Android dual-role class (/sys/class/dual_role_usb/).
* The first instance should be named "otg_default" as that's what
* Android expects.
* Note this is different than the /sys/class/usbpd/ created above.
*/
pd->dr_desc.name = (num_pd_instances == 1) ?
"otg_default" : dev_name(&pd->dev);
pd->dr_desc.supported_modes = DUAL_ROLE_SUPPORTED_MODES_DFP_AND_UFP;
pd->dr_desc.properties = usbpd_dr_properties;
pd->dr_desc.num_properties = ARRAY_SIZE(usbpd_dr_properties);
pd->dr_desc.get_property = usbpd_dr_get_property;
pd->dr_desc.set_property = usbpd_dr_set_property;
pd->dr_desc.property_is_writeable = usbpd_dr_prop_writeable;
pd->dual_role = devm_dual_role_instance_register(&pd->dev,
&pd->dr_desc);
if (IS_ERR(pd->dual_role)) {
usbpd_err(&pd->dev, "could not register dual_role instance\n");
goto put_psy;
} else {
pd->dual_role->drv_data = pd;
}
pd->current_pr = PR_NONE;
pd->current_dr = DR_NONE;
list_add_tail(&pd->instance, &_usbpd);
spin_lock_init(&pd->rx_lock);
INIT_LIST_HEAD(&pd->rx_q);
INIT_LIST_HEAD(&pd->svid_handlers);
init_completion(&pd->is_ready);
init_completion(&pd->tx_chunk_request);
pd->psy_nb.notifier_call = psy_changed;
ret = power_supply_reg_notifier(&pd->psy_nb);
if (ret)
goto del_inst;
/* force read initial power_supply values */
psy_changed(&pd->psy_nb, PSY_EVENT_PROP_CHANGED, pd->usb_psy);
return pd;
del_inst:
list_del(&pd->instance);
put_psy:
power_supply_put(pd->usb_psy);
destroy_wq:
destroy_workqueue(pd->wq);
del_pd:
device_del(&pd->dev);
free_pd:
num_pd_instances--;
kfree(pd);
return ERR_PTR(ret);
}
EXPORT_SYMBOL(usbpd_create);
/**
* usbpd_destroy - Removes and frees a usbpd instance
* @pd: the instance to destroy
*/
void usbpd_destroy(struct usbpd *pd)
{
if (!pd)
return;
list_del(&pd->instance);
power_supply_unreg_notifier(&pd->psy_nb);
power_supply_put(pd->usb_psy);
destroy_workqueue(pd->wq);
device_del(&pd->dev);
kfree(pd);
}
EXPORT_SYMBOL(usbpd_destroy);
static int __init usbpd_init(void)
{
usbpd_ipc_log = ipc_log_context_create(NUM_LOG_PAGES, "usb_pd", 0);
return class_register(&usbpd_class);
}
module_init(usbpd_init);
static void __exit usbpd_exit(void)
{
class_unregister(&usbpd_class);
}
module_exit(usbpd_exit);
MODULE_DESCRIPTION("USB Power Delivery Policy Engine");
MODULE_LICENSE("GPL v2");