coreboot-libre-fam15h-rdimm/3rdparty/chromeec/driver/tcpm/tcpm.h

400 lines
9.6 KiB
C

/* Copyright 2015 The Chromium OS Authors. All rights reserved.
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
/* USB Power delivery port management - common header for TCPM drivers */
#ifndef __CROS_EC_USB_PD_TCPM_TCPM_H
#define __CROS_EC_USB_PD_TCPM_TCPM_H
#include "common.h"
#include "ec_commands.h"
#include "gpio.h"
#include "i2c.h"
#include "usb_pd_tcpm.h"
#include "util.h"
#if defined(CONFIG_USB_PD_DUAL_ROLE_AUTO_TOGGLE) && \
!defined(CONFIG_USB_PD_DUAL_ROLE)
#error "DRP auto toggle requires board to have DRP support"
#error "Please upgrade your board configuration"
#endif
#ifndef CONFIG_USB_PD_TCPC
/* I2C wrapper functions - get I2C port / slave addr from config struct. */
#ifndef CONFIG_USB_PD_TCPC_LOW_POWER
static inline int tcpc_addr_write(int port, int i2c_addr, int reg, int val)
{
return i2c_write8(tcpc_config[port].i2c_info.port,
i2c_addr, reg, val);
}
static inline int tcpc_write16(int port, int reg, int val)
{
return i2c_write16(tcpc_config[port].i2c_info.port,
tcpc_config[port].i2c_info.addr_flags,
reg, val);
}
static inline int tcpc_addr_read(int port, int i2c_addr, int reg, int *val)
{
return i2c_read8(tcpc_config[port].i2c_info.port,
i2c_addr, reg, val);
}
static inline int tcpc_read16(int port, int reg, int *val)
{
return i2c_read16(tcpc_config[port].i2c_info.port,
tcpc_config[port].i2c_info.addr_flags,
reg, val);
}
static inline int tcpc_xfer(int port, const uint8_t *out, int out_size,
uint8_t *in, int in_size)
{
return i2c_xfer(tcpc_config[port].i2c_info.port,
tcpc_config[port].i2c_info.addr_flags,
out, out_size, in, in_size);
}
static inline int tcpc_xfer_unlocked(int port, const uint8_t *out, int out_size,
uint8_t *in, int in_size, int flags)
{
return i2c_xfer_unlocked(tcpc_config[port].i2c_info.port,
tcpc_config[port].i2c_info.addr_flags,
out, out_size, in, in_size, flags);
}
static inline int tcpc_read_block(int port, int reg, uint8_t *in, int size)
{
return i2c_read_block(tcpc_config[port].i2c_info.port,
tcpc_config[port].i2c_info.addr_flags,
reg, in, size);
}
static inline int tcpc_write_block(int port, int reg,
const uint8_t *out, int size)
{
return i2c_write_block(tcpc_config[port].i2c_info.port,
tcpc_config[port].i2c_info.addr_flags,
reg, out, size);
}
#else /* !CONFIG_USB_PD_TCPC_LOW_POWER */
int tcpc_addr_write(int port, int i2c_addr, int reg, int val);
int tcpc_write16(int port, int reg, int val);
int tcpc_addr_read(int port, int i2c_addr, int reg, int *val);
int tcpc_read16(int port, int reg, int *val);
int tcpc_read_block(int port, int reg, uint8_t *in, int size);
int tcpc_write_block(int port, int reg, const uint8_t *out, int size);
int tcpc_xfer(int port, const uint8_t *out, int out_size,
uint8_t *in, int in_size);
int tcpc_xfer_unlocked(int port, const uint8_t *out, int out_size,
uint8_t *in, int in_size, int flags);
#endif /* CONFIG_USB_PD_TCPC_LOW_POWER */
static inline int tcpc_write(int port, int reg, int val)
{
return tcpc_addr_write(port,
tcpc_config[port].i2c_info.addr_flags, reg, val);
}
static inline int tcpc_read(int port, int reg, int *val)
{
return tcpc_addr_read(port,
tcpc_config[port].i2c_info.addr_flags, reg, val);
}
static inline void tcpc_lock(int port, int lock)
{
i2c_lock(tcpc_config[port].i2c_info.port, lock);
}
/* TCPM driver wrapper function */
static inline int tcpm_init(int port)
{
int rv;
rv = tcpc_config[port].drv->init(port);
if (rv)
return rv;
/* Board specific post TCPC init */
if (board_tcpc_post_init)
rv = board_tcpc_post_init(port);
return rv;
}
static inline int tcpm_release(int port)
{
return tcpc_config[port].drv->release(port);
}
static inline int tcpm_get_cc(int port, enum tcpc_cc_voltage_status *cc1,
enum tcpc_cc_voltage_status *cc2)
{
return tcpc_config[port].drv->get_cc(port, cc1, cc2);
}
static inline int tcpm_get_vbus_level(int port)
{
return tcpc_config[port].drv->get_vbus_level(port);
}
static inline int tcpm_select_rp_value(int port, int rp)
{
return tcpc_config[port].drv->select_rp_value(port, rp);
}
static inline int tcpm_set_cc(int port, int pull)
{
return tcpc_config[port].drv->set_cc(port, pull);
}
static inline int tcpm_set_polarity(int port, int polarity)
{
return tcpc_config[port].drv->set_polarity(port, polarity);
}
static inline int tcpm_set_vconn(int port, int enable)
{
return tcpc_config[port].drv->set_vconn(port, enable);
}
static inline int tcpm_set_msg_header(int port, int power_role, int data_role)
{
return tcpc_config[port].drv->set_msg_header(port, power_role,
data_role);
}
static inline int tcpm_set_rx_enable(int port, int enable)
{
return tcpc_config[port].drv->set_rx_enable(port, enable);
}
/**
* Reads a message using get_message_raw driver method and puts it into EC's
* cache.
*/
int tcpm_enqueue_message(int port);
static inline int tcpm_transmit(int port, enum tcpm_transmit_type type,
uint16_t header, const uint32_t *data)
{
return tcpc_config[port].drv->transmit(port, type, header, data);
}
#ifdef CONFIG_USBC_PPC
static inline int tcpm_set_snk_ctrl(int port, int enable)
{
if (tcpc_config[port].drv->set_snk_ctrl != NULL)
return tcpc_config[port].drv->set_snk_ctrl(port, enable);
else
return EC_ERROR_UNIMPLEMENTED;
}
static inline int tcpm_set_src_ctrl(int port, int enable)
{
if (tcpc_config[port].drv->set_src_ctrl != NULL)
return tcpc_config[port].drv->set_src_ctrl(port, enable);
else
return EC_ERROR_UNIMPLEMENTED;
}
#endif
static inline void tcpc_alert(int port)
{
tcpc_config[port].drv->tcpc_alert(port);
}
static inline void tcpc_discharge_vbus(int port, int enable)
{
tcpc_config[port].drv->tcpc_discharge_vbus(port, enable);
}
#ifdef CONFIG_USB_PD_DUAL_ROLE_AUTO_TOGGLE
static inline int tcpm_auto_toggle_supported(int port)
{
return !!tcpc_config[port].drv->drp_toggle;
}
static inline int tcpm_enable_drp_toggle(int port)
{
return tcpc_config[port].drv->drp_toggle(port);
}
#endif
#ifdef CONFIG_USB_PD_TCPC_LOW_POWER
static inline int tcpm_enter_low_power_mode(int port)
{
return tcpc_config[port].drv->enter_low_power_mode(port);
}
#endif
#ifdef CONFIG_CMD_I2C_STRESS_TEST_TCPC
static inline int tcpc_i2c_read(const int port, const uint16_t addr_flags,
const int reg, int *data)
{
return tcpc_read(port, reg, data);
}
static inline int tcpc_i2c_write(const int port, const uint16_t addr_flags,
const int reg, int data)
{
return tcpc_write(port, reg, data);
}
#endif
static inline int tcpm_get_chip_info(int port, int live,
struct ec_response_pd_chip_info_v1 **info)
{
if (tcpc_config[port].drv->get_chip_info)
return tcpc_config[port].drv->get_chip_info(port, live, info);
return EC_ERROR_UNIMPLEMENTED;
}
#else
/**
* Initialize TCPM driver and wait for TCPC readiness.
*
* @param port Type-C port number
*
* @return EC_SUCCESS or error
*/
int tcpm_init(int port);
/**
* Read the CC line status.
*
* @param port Type-C port number
* @param cc1 pointer to CC status for CC1
* @param cc2 pointer to CC status for CC2
*
* @return EC_SUCCESS or error
*/
int tcpm_get_cc(int port, enum tcpc_cc_voltage_status *cc1,
enum tcpc_cc_voltage_status *cc2);
/**
* Read VBUS
*
* @param port Type-C port number
*
* @return 0 => VBUS not detected, 1 => VBUS detected
*/
int tcpm_get_vbus_level(int port);
/**
* Set the value of the CC pull-up used when we are a source.
*
* @param port Type-C port number
* @param rp One of enum tcpc_rp_value
*
* @return EC_SUCCESS or error
*/
int tcpm_select_rp_value(int port, int rp);
/**
* Set the CC pull resistor. This sets our role as either source or sink.
*
* @param port Type-C port number
* @param pull One of enum tcpc_cc_pull
*
* @return EC_SUCCESS or error
*/
int tcpm_set_cc(int port, int pull);
/**
* Set polarity
*
* @param port Type-C port number
* @param polarity 0=> transmit on CC1, 1=> transmit on CC2
*
* @return EC_SUCCESS or error
*/
int tcpm_set_polarity(int port, int polarity);
/**
* Set Vconn.
*
* @param port Type-C port number
* @param polarity Polarity of the CC line to read
*
* @return EC_SUCCESS or error
*/
int tcpm_set_vconn(int port, int enable);
/**
* Set PD message header to use for goodCRC
*
* @param port Type-C port number
* @param power_role Power role to use in header
* @param data_role Data role to use in header
*
* @return EC_SUCCESS or error
*/
int tcpm_set_msg_header(int port, int power_role, int data_role);
/**
* Set RX enable flag
*
* @param port Type-C port number
* @enable true for enable, false for disable
*
* @return EC_SUCCESS or error
*/
int tcpm_set_rx_enable(int port, int enable);
/**
* Transmit PD message
*
* @param port Type-C port number
* @param type Transmit type
* @param header Packet header
* @param cnt Number of bytes in payload
* @param data Payload
*
* @return EC_SUCCESS or error
*/
int tcpm_transmit(int port, enum tcpm_transmit_type type, uint16_t header,
const uint32_t *data);
/**
* TCPC is asserting alert
*
* @param port Type-C port number
*/
void tcpc_alert(int port);
#endif
/**
* Gets the next waiting RX message.
*
* @param port Type-C port number
* @param payload Pointer to location to copy payload of PD message
* @param header The header of PD message
*
* @return EC_SUCCESS or error
*/
int tcpm_dequeue_message(int port, uint32_t *payload, int *header);
/**
* Returns true if the tcpm has RX messages waiting to be consumed.
*/
int tcpm_has_pending_message(int port);
/**
* Clear any pending messages in the RX queue. This function must be
* called from the same context as the caller of tcpm_dequeue_message to avoid
* race conditions.
*/
void tcpm_clear_pending_messages(int port);
#endif