/* SPDX-License-Identifier: GPL-2.0-or-later */
/*
* Copyright 2015-2017 Google, Inc
*/
#ifndef __LINUX_USB_TCPM_H
#define __LINUX_USB_TCPM_H
#include <linux/bitops.h>
#include <linux/usb/typec.h>
#include "pd.h"
enum typec_cc_status {
TYPEC_CC_OPEN,
TYPEC_CC_RA,
TYPEC_CC_RD,
TYPEC_CC_RP_DEF,
TYPEC_CC_RP_1_5,
TYPEC_CC_RP_3_0,
};
/* Collision Avoidance */
#define SINK_TX_NG TYPEC_CC_RP_1_5
#define SINK_TX_OK TYPEC_CC_RP_3_0
enum typec_cc_polarity {
TYPEC_POLARITY_CC1,
TYPEC_POLARITY_CC2,
};
/* Time to wait for TCPC to complete transmit */
#define PD_T_TCPC_TX_TIMEOUT 100 /* in ms */
#define PD_ROLE_SWAP_TIMEOUT (MSEC_PER_SEC * 10)
#define PD_PPS_CTRL_TIMEOUT (MSEC_PER_SEC * 10)
enum tcpm_transmit_status {
TCPC_TX_SUCCESS = 0,
TCPC_TX_DISCARDED = 1,
TCPC_TX_FAILED = 2,
};
enum tcpm_transmit_type {
TCPC_TX_SOP = 0,
TCPC_TX_SOP_PRIME = 1,
TCPC_TX_SOP_PRIME_PRIME = 2,
TCPC_TX_SOP_DEBUG_PRIME = 3,
TCPC_TX_SOP_DEBUG_PRIME_PRIME = 4,
TCPC_TX_HARD_RESET = 5,
TCPC_TX_CABLE_RESET = 6,
TCPC_TX_BIST_MODE_2 = 7
};
/* Mux state attributes */
#define TCPC_MUX_USB_ENABLED BIT(0) /* USB enabled */
#define TCPC_MUX_DP_ENABLED BIT(1) /* DP enabled */
#define TCPC_MUX_POLARITY_INVERTED BIT(2) /* Polarity inverted */
/**
* struct tcpc_dev - Port configuration and callback functions
* @fwnode: Pointer to port fwnode
* @get_vbus: Called to read current VBUS state
* @get_current_limit:
* Optional; called by the tcpm core when configured as a snk
* and cc=Rp-def. This allows the tcpm to provide a fallback
* current-limit detection method for the cc=Rp-def case.
* For example, some tcpcs may include BC1.2 charger detection
* and use that in this case.
* @set_cc: Called to set value of CC pins
* @apply_rc: Optional; Needed to move TCPCI based chipset to APPLY_RC state
* as stated by the TCPCI specification.
* @get_cc: Called to read current CC pin values
* @set_polarity:
* Called to set polarity
* @set_vconn: Called to enable or disable VCONN
* @set_vbus: Called to enable or disable VBUS
* @set_current_limit:
* Optional; called to set current limit as negotiated
* with partner.
* @set_pd_rx: Called to enable or disable reception of PD messages
* @set_roles: Called to set power and data roles
* @start_toggling:
* Optional; if supported by hardware, called to start dual-role
* toggling or single-role connection detection. Toggling stops
* automatically if a connection is established.
* @try_role: Optional; called to set a preferred role
* @pd_transmit:Called to transmit PD message
* @set_bist_data: Turn on/off bist data mode for compliance testing
* @enable_frs:
* Optional; Called to enable/disable PD 3.0 fast role swap.
* Enabling frs is accessory dependent as not all PD3.0
* accessories support fast role swap.
* @frs_sourcing_vbus:
* Optional; Called to notify that vbus is now being sourced.
* Low level drivers can perform chip specific operations, if any.
* @enable_auto_vbus_discharge:
* Optional; TCPCI spec based TCPC implementations can optionally
* support hardware to autonomously dischrge vbus upon disconnecting
* as sink or source. TCPM signals TCPC to enable the mechanism upon
* entering connected state and signals disabling upon disconnect.
* @set_auto_vbus_discharge_threshold:
* Mandatory when enable_auto_vbus_discharge is implemented. TCPM
* calls this function to allow lower levels drivers to program the
* vbus threshold voltage below which the vbus discharge circuit
* will be turned on. requested_vbus_voltage is set to 0 when vbus
* is going to disappear knowingly i.e. during PR_SWAP and
* HARD_RESET etc.
* @is_vbus_vsafe0v:
* Optional; TCPCI spec based TCPC implementations are expected to
* detect VSAFE0V voltage level at vbus. When detection of VSAFE0V
* is supported by TCPC, set this callback for TCPM to query
* whether vbus is at VSAFE0V when needed.
* Returns true when vbus is at VSAFE0V, false otherwise.
* @set_partner_usb_comm_capable:
* Optional; The USB Communications Capable bit indicates if port
* partner is capable of communication over the USB data lines
* (e.g. D+/- or SS Tx/Rx). Called to notify the status of the bit.
* @check_contaminant:
* Optional; The callback is called when CC pins report open status
* at the end of the deboumce period or when the port is still
* toggling. Chip level drivers are expected to check for contaminant
* and call tcpm_clean_port when the port is clean.
* @cable_comm_capable
* Optional; Returns whether cable communication over SOP' is supported
* by the tcpc
* @attempt_vconn_swap_discovery:
* Optional; The callback is called by the TCPM when the result of
* a Discover Identity request indicates that the port partner is
* a receptacle capable of modal operation. Chip level TCPCI drivers
* can implement their own policy to determine if and when a Vconn
* swap following Discover Identity on SOP' occurs.
* Return true when the TCPM is allowed to request a Vconn swap
* after Discovery Identity on SOP.
*/
struct tcpc_dev {
struct fwnode_handle *fwnode;
int (*init)(struct tcpc_dev *dev);
int (*get_vbus)(struct tcpc_dev *dev);
int (*get_current_limit)(struct tcpc_dev *dev);
int (*set_cc)(struct tcpc_dev *dev, enum typec_cc_status cc);
int (*apply_rc)(struct tcpc_dev *dev, enum typec_cc_status cc,
enum typec_cc_polarity polarity);
int (*get_cc)(struct tcpc_dev *dev, enum typec_cc_status *cc1,
enum typec_cc_status *cc2);
int (*set_polarity)(struct tcpc_dev *dev,
enum typec_cc_polarity polarity);
int (*set_orientation)(struct tcpc_dev *dev,
enum typec_orientation orientation);
int (*set_vconn)(struct tcpc_dev *dev, bool on);
int (*set_vbus)(struct tcpc_dev *dev, bool on, bool charge);
int (*set_current_limit)(struct tcpc_dev *dev, u32 max_ma, u32 mv);
int (*set_pd_rx)(struct tcpc_dev *dev, bool on);
int (*set_roles)(struct tcpc_dev *dev, bool attached,
enum typec_role role, enum typec_data_role data);
int (*start_toggling)(struct tcpc_dev *dev,
enum typec_port_type port_type,
enum typec_cc_status cc);
int (*try_role)(struct tcpc_dev *dev, int role);
int (*pd_transmit)(struct tcpc_dev *dev, enum tcpm_transmit_type type,
const struct pd_message *msg, unsigned int negotiated_rev);
int (*set_bist_data)(struct tcpc_dev *dev, bool on);
int (*enable_frs)(struct tcpc_dev *dev, bool enable);
void (*frs_sourcing_vbus)(struct tcpc_dev *dev);
int (*enable_auto_vbus_discharge)(struct tcpc_dev *dev, bool enable);
int (*set_auto_vbus_discharge_threshold)(struct tcpc_dev *dev, enum typec_pwr_opmode mode,
bool pps_active, u32 requested_vbus_voltage);
bool (*is_vbus_vsafe0v)(struct tcpc_dev *dev);
void (*set_partner_usb_comm_capable)(struct tcpc_dev *dev, bool enable);
void (*check_contaminant)(struct tcpc_dev *dev);
bool (*cable_comm_capable)(struct tcpc_dev *dev);
bool (*attempt_vconn_swap_discovery)(struct tcpc_dev *dev);
};
struct tcpm_port;
struct tcpm_port *tcpm_register_port(struct device *dev, struct tcpc_dev *tcpc);
void tcpm_unregister_port(struct tcpm_port *port);
void tcpm_vbus_change(struct tcpm_port *port);
void tcpm_cc_change(struct tcpm_port *port);
void tcpm_sink_frs(struct tcpm_port *port);
void tcpm_sourcing_vbus(struct tcpm_port *port);
void tcpm_pd_receive(struct tcpm_port *port,
const struct pd_message *msg,
enum tcpm_transmit_type rx_sop_type);
void tcpm_pd_transmit_complete(struct tcpm_port *port,
enum tcpm_transmit_status status);
void tcpm_pd_hard_reset(struct tcpm_port *port);
void tcpm_tcpc_reset(struct tcpm_port *port);
void tcpm_port_clean(struct tcpm_port *port);
bool tcpm_port_is_toggling(struct tcpm_port *port);
void tcpm_port_error_recovery(struct tcpm_port *port);
#endif /* __LINUX_USB_TCPM_H */