coreboot-libre-fam15h-rdimm/3rdparty/chromeec/common/usb_pd_policy.c

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/* Copyright 2014 The Chromium OS Authors. All rights reserved.
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "atomic.h"
#include "charge_manager.h"
#include "common.h"
#include "console.h"
#include "ec_commands.h"
#include "flash.h"
#include "gpio.h"
#include "hooks.h"
#include "host_command.h"
#include "mkbp_event.h"
#include "registers.h"
#include "rsa.h"
#include "sha256.h"
#include "system.h"
#include "task.h"
#include "tcpm.h"
#include "timer.h"
#include "util.h"
#include "usb_api.h"
#include "usb_common.h"
#include "usb_pd.h"
#include "usbc_ppc.h"
#include "version.h"
#ifdef CONFIG_COMMON_RUNTIME
#define CPRINTS(format, args...) cprints(CC_USBPD, format, ## args)
#define CPRINTF(format, args...) cprintf(CC_USBPD, format, ## args)
#else
#define CPRINTS(format, args...)
#define CPRINTF(format, args...)
#endif
static int rw_flash_changed = 1;
#ifdef CONFIG_MKBP_EVENT
static int dp_alt_mode_entry_get_next_event(uint8_t *data)
{
return EC_SUCCESS;
}
DECLARE_EVENT_SOURCE(EC_MKBP_EVENT_DP_ALT_MODE_ENTERED,
dp_alt_mode_entry_get_next_event);
void pd_notify_dp_alt_mode_entry(void)
{
CPRINTS("Notifying AP of DP Alt Mode Entry...");
mkbp_send_event(EC_MKBP_EVENT_DP_ALT_MODE_ENTERED);
}
#endif /* CONFIG_MKBP_EVENT */
int pd_check_requested_voltage(uint32_t rdo, const int port)
{
int max_ma = rdo & 0x3FF;
int op_ma = (rdo >> 10) & 0x3FF;
int idx = RDO_POS(rdo);
uint32_t pdo;
uint32_t pdo_ma;
#if defined(CONFIG_USB_PD_DYNAMIC_SRC_CAP) || \
defined(CONFIG_USB_PD_MAX_SINGLE_SOURCE_CURRENT)
const uint32_t *src_pdo;
const int pdo_cnt = charge_manager_get_source_pdo(&src_pdo, port);
#else
const uint32_t *src_pdo = pd_src_pdo;
const int pdo_cnt = pd_src_pdo_cnt;
#endif
/* Board specific check for this request */
if (pd_board_check_request(rdo, pdo_cnt))
return EC_ERROR_INVAL;
/* check current ... */
pdo = src_pdo[idx - 1];
pdo_ma = (pdo & 0x3ff);
if (op_ma > pdo_ma)
return EC_ERROR_INVAL; /* too much op current */
if (max_ma > pdo_ma && !(rdo & RDO_CAP_MISMATCH))
return EC_ERROR_INVAL; /* too much max current */
CPRINTF("Requested %d V %d mA (for %d/%d mA)\n",
((pdo >> 10) & 0x3ff) * 50, (pdo & 0x3ff) * 10,
op_ma * 10, max_ma * 10);
/* Accept the requested voltage */
return EC_SUCCESS;
}
__attribute__((weak)) int pd_board_check_request(uint32_t rdo, int pdo_cnt)
{
int idx = RDO_POS(rdo);
/* Check for invalid index */
return (!idx || idx > pdo_cnt) ?
EC_ERROR_INVAL : EC_SUCCESS;
}
#ifdef CONFIG_USB_PD_DUAL_ROLE
/* Last received source cap */
static uint32_t pd_src_caps[CONFIG_USB_PD_PORT_COUNT][PDO_MAX_OBJECTS];
static uint8_t pd_src_cap_cnt[CONFIG_USB_PD_PORT_COUNT];
/* Cap on the max voltage requested as a sink (in millivolts) */
static unsigned max_request_mv = PD_MAX_VOLTAGE_MV; /* no cap */
const uint32_t * const pd_get_src_caps(int port)
{
ASSERT(port < CONFIG_USB_PD_PORT_COUNT);
return pd_src_caps[port];
}
uint8_t pd_get_src_cap_cnt(int port)
{
ASSERT(port < CONFIG_USB_PD_PORT_COUNT);
return pd_src_cap_cnt[port];
}
uint32_t get_max_request_mv(void)
{
return max_request_mv;
}
void pd_process_source_cap(int port, int cnt, uint32_t *src_caps)
{
#ifdef CONFIG_CHARGE_MANAGER
uint32_t ma, mv, pdo;
#endif
int i;
pd_src_cap_cnt[port] = cnt;
for (i = 0; i < cnt; i++)
pd_src_caps[port][i] = *src_caps++;
#ifdef CONFIG_CHARGE_MANAGER
/* Get max power info that we could request */
pd_find_pdo_index(pd_get_src_cap_cnt(port), pd_get_src_caps(port),
PD_MAX_VOLTAGE_MV, &pdo);
pd_extract_pdo_power(pdo, &ma, &mv);
/* Set max. limit, but apply 500mA ceiling */
charge_manager_set_ceil(port, CEIL_REQUESTOR_PD, PD_MIN_MA);
pd_set_input_current_limit(port, ma, mv);
#endif
}
void pd_set_max_voltage(unsigned mv)
{
max_request_mv = mv;
}
unsigned pd_get_max_voltage(void)
{
return max_request_mv;
}
int pd_charge_from_device(uint16_t vid, uint16_t pid)
{
/* TODO: rewrite into table if we get more of these */
/*
* White-list Apple charge-through accessory since it doesn't set
* externally powered bit, but we still need to charge from it when
* we are a sink.
*/
return (vid == USB_VID_APPLE && (pid == 0x1012 || pid == 0x1013));
}
#endif /* CONFIG_USB_PD_DUAL_ROLE */
static struct pd_cable cable[CONFIG_USB_PD_PORT_COUNT];
static uint8_t is_transmit_msg_sop_prime(int port)
{
if (IS_ENABLED(CONFIG_USB_PD_DECODE_SOP))
return !!(cable[port].flags & CABLE_FLAGS_SOP_PRIME_ENABLE);
return 0;
}
uint8_t is_sop_prime_ready(int port, uint8_t data_role, uint32_t pd_flags)
{
/*
* Ref: USB PD 3.0 sec 2.5.4: When an Explicit Contract is in place the
* VCONN Source (either the DFP or the UFP) can communicate with the
* Cable Plug(s) using SOP/SOP Packets
*
* Ref: USB PD 2.0 sec 2.4.4: When an Explicit Contract is in place the
* DFP (either the Source or the Sink) can communicate with the
* Cable Plug(s) using SOP/SOP” Packets.
* Sec 3.6.11 : Before communicating with a Cable Plug a Port Should
* ensure that it is the Vconn Source
*/
if (pd_flags & PD_FLAGS_VCONN_ON && (IS_ENABLED(CONFIG_USB_PD_REV30) ||
data_role == PD_ROLE_DFP))
return is_transmit_msg_sop_prime(port);
return 0;
}
void reset_pd_cable(int port)
{
if (IS_ENABLED(CONFIG_USB_PD_DECODE_SOP))
memset(&cable[port], 0, sizeof(cable[port]));
}
uint8_t get_usb_pd_mux_cable_type(int port)
{
return cable[port].type;
}
#ifdef CONFIG_USB_PD_ALT_MODE
#ifdef CONFIG_USB_PD_ALT_MODE_DFP
static struct pd_policy pe[CONFIG_USB_PD_PORT_COUNT];
static int is_vdo_present(int cnt, int index)
{
return cnt > index;
}
static void enable_transmit_sop_prime(int port)
{
cable[port].flags |= CABLE_FLAGS_SOP_PRIME_ENABLE;
}
static void disable_transmit_sop_prime(int port)
{
cable[port].flags &= ~CABLE_FLAGS_SOP_PRIME_ENABLE;
}
void pd_dfp_pe_init(int port)
{
memset(&pe[port], 0, sizeof(struct pd_policy));
}
static void dfp_consume_identity(int port, int cnt, uint32_t *payload)
{
int ptype = PD_IDH_PTYPE(payload[VDO_I(IDH)]);
size_t identity_size = MIN(sizeof(pe[port].identity),
(cnt - 1) * sizeof(uint32_t));
pd_dfp_pe_init(port);
memcpy(&pe[port].identity, payload + 1, identity_size);
switch (ptype) {
case IDH_PTYPE_AMA:
/* Leave vbus ON if the following macro is false */
#if defined(CONFIG_USB_PD_DUAL_ROLE) && defined(CONFIG_USBC_VCONN_SWAP)
/* Adapter is requesting vconn, try to supply it */
if (PD_VDO_AMA_VCONN_REQ(payload[VDO_I(AMA)]))
pd_try_vconn_src(port);
/* Only disable vbus if vconn was requested */
if (PD_VDO_AMA_VCONN_REQ(payload[VDO_I(AMA)]) &&
!PD_VDO_AMA_VBUS_REQ(payload[VDO_I(AMA)]))
pd_power_supply_reset(port);
#endif
break;
default:
break;
}
}
static void dfp_consume_cable_response(int port, int cnt, uint32_t *payload)
{
if (cable[port].is_identified)
return;
if (is_vdo_present(cnt, VDO_INDEX_IDH)) {
cable[port].type = PD_IDH_PTYPE(payload[VDO_INDEX_IDH]);
if (is_vdo_present(cnt, VDO_INDEX_PTYPE_CABLE1))
cable[port].attr.raw_value =
payload[VDO_INDEX_PTYPE_CABLE1];
}
/*
* Ref USB PD Spec 3.0 Pg 145. For active cable there are two VDOs.
* Hence storing the second VDO.
*/
if (IS_ENABLED(CONFIG_USB_PD_REV30) &&
is_vdo_present(cnt, VDO_INDEX_PTYPE_CABLE2) &&
cable[port].type == IDH_PTYPE_ACABLE) {
cable[port].rev = PD_REV30;
cable[port].attr2.raw_value = payload[VDO_INDEX_PTYPE_CABLE2];
}
cable[port].is_identified = 1;
}
static int dfp_discover_ident(uint32_t *payload)
{
payload[0] = VDO(USB_SID_PD, 1, CMD_DISCOVER_IDENT);
return 1;
}
static int dfp_discover_svids(uint32_t *payload)
{
payload[0] = VDO(USB_SID_PD, 1, CMD_DISCOVER_SVID);
return 1;
}
static void dfp_consume_svids(int port, int cnt, uint32_t *payload)
{
int i;
uint32_t *ptr = payload + 1;
int vdo = 1;
uint16_t svid0, svid1;
for (i = pe[port].svid_cnt; i < pe[port].svid_cnt + 12; i += 2) {
if (i == SVID_DISCOVERY_MAX) {
CPRINTF("ERR:SVIDCNT\n");
break;
}
/*
* Verify we're still within the valid packet (count will be one
* for the VDM header + xVDOs)
*/
if (vdo >= cnt)
break;
svid0 = PD_VDO_SVID_SVID0(*ptr);
if (!svid0)
break;
pe[port].svids[i].svid = svid0;
pe[port].svid_cnt++;
svid1 = PD_VDO_SVID_SVID1(*ptr);
if (!svid1)
break;
pe[port].svids[i + 1].svid = svid1;
pe[port].svid_cnt++;
ptr++;
vdo++;
}
/* TODO(tbroch) need to re-issue discover svids if > 12 */
if (i && ((i % 12) == 0))
CPRINTF("ERR:SVID+12\n");
}
static int dfp_discover_modes(int port, uint32_t *payload)
{
uint16_t svid = pe[port].svids[pe[port].svid_idx].svid;
if (pe[port].svid_idx >= pe[port].svid_cnt)
return 0;
payload[0] = VDO(svid, 1, CMD_DISCOVER_MODES);
return 1;
}
static void dfp_consume_modes(int port, int cnt, uint32_t *payload)
{
int idx = pe[port].svid_idx;
pe[port].svids[idx].mode_cnt = cnt - 1;
if (pe[port].svids[idx].mode_cnt < 0) {
CPRINTF("ERR:NOMODE\n");
} else {
memcpy(pe[port].svids[pe[port].svid_idx].mode_vdo, &payload[1],
sizeof(uint32_t) * pe[port].svids[idx].mode_cnt);
}
pe[port].svid_idx++;
}
static int get_mode_idx(int port, uint16_t svid)
{
int i;
for (i = 0; i < PD_AMODE_COUNT; i++) {
if (pe[port].amodes[i].fx->svid == svid)
return i;
}
return -1;
}
static struct svdm_amode_data *get_modep(int port, uint16_t svid)
{
int idx = get_mode_idx(port, svid);
return (idx == -1) ? NULL : &pe[port].amodes[idx];
}
int pd_alt_mode(int port, uint16_t svid)
{
struct svdm_amode_data *modep = get_modep(port, svid);
return (modep) ? modep->opos : -1;
}
int allocate_mode(int port, uint16_t svid)
{
int i, j;
struct svdm_amode_data *modep;
int mode_idx = get_mode_idx(port, svid);
if (mode_idx != -1)
return mode_idx;
/* There's no space to enter another mode */
if (pe[port].amode_idx == PD_AMODE_COUNT) {
CPRINTF("ERR:NO AMODE SPACE\n");
return -1;
}
/* Allocate ... if SVID == 0 enter default supported policy */
for (i = 0; i < supported_modes_cnt; i++) {
for (j = 0; j < pe[port].svid_cnt; j++) {
struct svdm_svid_data *svidp = &pe[port].svids[j];
if ((svidp->svid != supported_modes[i].svid) ||
(svid && (svidp->svid != svid)))
continue;
modep = &pe[port].amodes[pe[port].amode_idx];
modep->fx = &supported_modes[i];
modep->data = &pe[port].svids[j];
pe[port].amode_idx++;
return pe[port].amode_idx - 1;
}
}
return -1;
}
/*
* Enter default mode ( payload[0] == 0 ) or attempt to enter mode via svid &
* opos
*/
uint32_t pd_dfp_enter_mode(int port, uint16_t svid, int opos)
{
int mode_idx = allocate_mode(port, svid);
struct svdm_amode_data *modep;
uint32_t mode_caps;
if (mode_idx == -1)
return 0;
modep = &pe[port].amodes[mode_idx];
if (!opos) {
/* choose the lowest as default */
modep->opos = 1;
} else if (opos <= modep->data->mode_cnt) {
modep->opos = opos;
} else {
CPRINTF("opos error\n");
return 0;
}
mode_caps = modep->data->mode_vdo[modep->opos - 1];
if (modep->fx->enter(port, mode_caps) == -1)
return 0;
/* SVDM to send to UFP for mode entry */
return VDO(modep->fx->svid, 1, CMD_ENTER_MODE | VDO_OPOS(modep->opos));
}
static int validate_mode_request(struct svdm_amode_data *modep,
uint16_t svid, int opos)
{
if (!modep->fx)
return 0;
if (svid != modep->fx->svid) {
CPRINTF("ERR:svid r:0x%04x != c:0x%04x\n",
svid, modep->fx->svid);
return 0;
}
if (opos != modep->opos) {
CPRINTF("ERR:opos r:%d != c:%d\n",
opos, modep->opos);
return 0;
}
return 1;
}
static void dfp_consume_attention(int port, uint32_t *payload)
{
uint16_t svid = PD_VDO_VID(payload[0]);
int opos = PD_VDO_OPOS(payload[0]);
struct svdm_amode_data *modep = get_modep(port, svid);
if (!modep || !validate_mode_request(modep, svid, opos))
return;
if (modep->fx->attention)
modep->fx->attention(port, payload);
}
/*
* This algorithm defaults to choosing higher pin config over lower ones in
* order to prefer multi-function if desired.
*
* NAME | SIGNALING | OUTPUT TYPE | MULTI-FUNCTION | PIN CONFIG
* -------------------------------------------------------------
* A | USB G2 | ? | no | 00_0001
* B | USB G2 | ? | yes | 00_0010
* C | DP | CONVERTED | no | 00_0100
* D | PD | CONVERTED | yes | 00_1000
* E | DP | DP | no | 01_0000
* F | PD | DP | yes | 10_0000
*
* if UFP has NOT asserted multi-function preferred code masks away B/D/F
* leaving only A/C/E. For single-output dongles that should leave only one
* possible pin config depending on whether its a converter DP->(VGA|HDMI) or DP
* output. If UFP is a USB-C receptacle it may assert C/D/E/F. The DFP USB-C
* receptacle must always choose C/D in those cases.
*/
int pd_dfp_dp_get_pin_mode(int port, uint32_t status)
{
struct svdm_amode_data *modep = get_modep(port, USB_SID_DISPLAYPORT);
uint32_t mode_caps;
uint32_t pin_caps;
if (!modep)
return 0;
mode_caps = modep->data->mode_vdo[modep->opos - 1];
/* TODO(crosbug.com/p/39656) revisit with DFP that can be a sink */
pin_caps = PD_DP_PIN_CAPS(mode_caps);
/* if don't want multi-function then ignore those pin configs */
if (!PD_VDO_DPSTS_MF_PREF(status))
pin_caps &= ~MODE_DP_PIN_MF_MASK;
/* TODO(crosbug.com/p/39656) revisit if DFP drives USB Gen 2 signals */
pin_caps &= ~MODE_DP_PIN_BR2_MASK;
/* if C/D present they have precedence over E/F for USB-C->USB-C */
if (pin_caps & (MODE_DP_PIN_C | MODE_DP_PIN_D))
pin_caps &= ~(MODE_DP_PIN_E | MODE_DP_PIN_F);
/* get_next_bit returns undefined for zero */
if (!pin_caps)
return 0;
return 1 << get_next_bit(&pin_caps);
}
int pd_dfp_exit_mode(int port, uint16_t svid, int opos)
{
struct svdm_amode_data *modep;
int idx;
/*
* Empty svid signals we should reset DFP VDM state by exiting all
* entered modes then clearing state. This occurs when we've
* disconnected or for hard reset.
*/
if (!svid) {
for (idx = 0; idx < PD_AMODE_COUNT; idx++)
if (pe[port].amodes[idx].fx)
pe[port].amodes[idx].fx->exit(port);
pd_dfp_pe_init(port);
return 0;
}
/*
* TODO(crosbug.com/p/33946) : below needs revisited to allow multiple
* mode exit. Additionally it should honor OPOS == 7 as DFP's request
* to exit all modes. We currently don't have any UFPs that support
* multiple modes on one SVID.
*/
modep = get_modep(port, svid);
if (!modep || !validate_mode_request(modep, svid, opos))
return 0;
/* call DFPs exit function */
modep->fx->exit(port);
/* exit the mode */
modep->opos = 0;
return 1;
}
uint16_t pd_get_identity_vid(int port)
{
return PD_IDH_VID(pe[port].identity[0]);
}
uint16_t pd_get_identity_pid(int port)
{
return PD_PRODUCT_PID(pe[port].identity[2]);
}
#ifdef CONFIG_CMD_USB_PD_PE
static void dump_pe(int port)
{
const char * const idh_ptype_names[] = {
"UNDEF", "Hub", "Periph", "PCable", "ACable", "AMA",
"RSV6", "RSV7"};
int i, j, idh_ptype;
struct svdm_amode_data *modep;
uint32_t mode_caps;
if (pe[port].identity[0] == 0) {
ccprintf("No identity discovered yet.\n");
return;
}
idh_ptype = PD_IDH_PTYPE(pe[port].identity[0]);
ccprintf("IDENT:\n");
ccprintf("\t[ID Header] %08x :: %s, VID:%04x\n", pe[port].identity[0],
idh_ptype_names[idh_ptype], pd_get_identity_vid(port));
ccprintf("\t[Cert Stat] %08x\n", pe[port].identity[1]);
for (i = 2; i < ARRAY_SIZE(pe[port].identity); i++) {
ccprintf("\t");
if (pe[port].identity[i])
ccprintf("[%d] %08x ", i, pe[port].identity[i]);
}
ccprintf("\n");
if (pe[port].svid_cnt < 1) {
ccprintf("No SVIDS discovered yet.\n");
return;
}
for (i = 0; i < pe[port].svid_cnt; i++) {
ccprintf("SVID[%d]: %04x MODES:", i, pe[port].svids[i].svid);
for (j = 0; j < pe[port].svids[j].mode_cnt; j++)
ccprintf(" [%d] %08x", j + 1,
pe[port].svids[i].mode_vdo[j]);
ccprintf("\n");
modep = get_modep(port, pe[port].svids[i].svid);
if (modep) {
mode_caps = modep->data->mode_vdo[modep->opos - 1];
ccprintf("MODE[%d]: svid:%04x caps:%08x\n", modep->opos,
modep->fx->svid, mode_caps);
}
}
}
static int command_pe(int argc, char **argv)
{
int port;
char *e;
if (argc < 3)
return EC_ERROR_PARAM_COUNT;
/* command: pe <port> <subcmd> <args> */
port = strtoi(argv[1], &e, 10);
if (*e || port >= CONFIG_USB_PD_PORT_COUNT)
return EC_ERROR_PARAM2;
if (!strncasecmp(argv[2], "dump", 4))
dump_pe(port);
return EC_SUCCESS;
}
DECLARE_CONSOLE_COMMAND(pe, command_pe,
"<port> dump",
"USB PE");
#endif /* CONFIG_CMD_USB_PD_PE */
#endif /* CONFIG_USB_PD_ALT_MODE_DFP */
int pd_svdm(int port, int cnt, uint32_t *payload, uint32_t **rpayload)
{
int cmd = PD_VDO_CMD(payload[0]);
int cmd_type = PD_VDO_CMDT(payload[0]);
int (*func)(int port, uint32_t *payload) = NULL;
int rsize = 1; /* VDM header at a minimum */
payload[0] &= ~VDO_CMDT_MASK;
*rpayload = payload;
if (cmd_type == CMDT_INIT) {
switch (cmd) {
case CMD_DISCOVER_IDENT:
func = svdm_rsp.identity;
break;
case CMD_DISCOVER_SVID:
func = svdm_rsp.svids;
break;
case CMD_DISCOVER_MODES:
func = svdm_rsp.modes;
break;
case CMD_ENTER_MODE:
func = svdm_rsp.enter_mode;
break;
case CMD_DP_STATUS:
if (svdm_rsp.amode)
func = svdm_rsp.amode->status;
break;
case CMD_DP_CONFIG:
if (svdm_rsp.amode)
func = svdm_rsp.amode->config;
break;
case CMD_EXIT_MODE:
func = svdm_rsp.exit_mode;
break;
#ifdef CONFIG_USB_PD_ALT_MODE_DFP
case CMD_ATTENTION:
/*
* attention is only SVDM with no response
* (just goodCRC) return zero here.
*/
dfp_consume_attention(port, payload);
return 0;
#endif
default:
CPRINTF("ERR:CMD:%d\n", cmd);
rsize = 0;
}
if (func)
rsize = func(port, payload);
else /* not supported : NACK it */
rsize = 0;
if (rsize >= 1)
payload[0] |= VDO_CMDT(CMDT_RSP_ACK);
else if (!rsize) {
payload[0] |= VDO_CMDT(CMDT_RSP_NAK);
rsize = 1;
} else {
payload[0] |= VDO_CMDT(CMDT_RSP_BUSY);
rsize = 1;
}
payload[0] |= VDO_SVDM_VERS(pd_get_vdo_ver(port));
} else if (cmd_type == CMDT_RSP_ACK) {
#ifdef CONFIG_USB_PD_ALT_MODE_DFP
struct svdm_amode_data *modep;
modep = get_modep(port, PD_VDO_VID(payload[0]));
#endif
switch (cmd) {
#ifdef CONFIG_USB_PD_ALT_MODE_DFP
case CMD_DISCOVER_IDENT:
/* Received a SOP Prime Discover Ident msg */
if (is_transmit_msg_sop_prime(port)) {
/* Store cable type */
dfp_consume_cable_response(port, cnt, payload);
disable_transmit_sop_prime(port);
rsize = dfp_discover_svids(payload);
/* Received a SOP Discover Ident Message */
} else if (IS_ENABLED(CONFIG_USB_PD_DECODE_SOP)) {
dfp_consume_identity(port, cnt, payload);
/* Send SOP' Discover Ident message */
if (!cable[port].is_identified) {
rsize = dfp_discover_ident(payload);
enable_transmit_sop_prime(port);
}
} else {
dfp_consume_identity(port, cnt, payload);
rsize = dfp_discover_svids(payload);
}
#ifdef CONFIG_CHARGE_MANAGER
if (pd_charge_from_device(pd_get_identity_vid(port),
pd_get_identity_pid(port)))
charge_manager_update_dualrole(port,
CAP_DEDICATED);
#endif
break;
case CMD_DISCOVER_SVID:
dfp_consume_svids(port, cnt, payload);
rsize = dfp_discover_modes(port, payload);
break;
case CMD_DISCOVER_MODES:
dfp_consume_modes(port, cnt, payload);
rsize = dfp_discover_modes(port, payload);
/* enter the default mode for DFP */
if (!rsize) {
payload[0] = pd_dfp_enter_mode(port, 0, 0);
if (payload[0])
rsize = 1;
}
break;
case CMD_ENTER_MODE:
if (!modep) {
rsize = 0;
} else {
if (!modep->opos)
pd_dfp_enter_mode(port, 0, 0);
if (modep->opos) {
rsize = modep->fx->status(port,
payload);
payload[0] |= PD_VDO_OPOS(modep->opos);
}
}
break;
case CMD_DP_STATUS:
/* DP status response & UFP's DP attention have same
payload */
dfp_consume_attention(port, payload);
if (modep && modep->opos)
rsize = modep->fx->config(port, payload);
else
rsize = 0;
break;
case CMD_DP_CONFIG:
if (modep && modep->opos && modep->fx->post_config)
modep->fx->post_config(port);
/* no response after DFPs ack */
rsize = 0;
break;
case CMD_EXIT_MODE:
/* no response after DFPs ack */
rsize = 0;
break;
#endif
case CMD_ATTENTION:
/* no response after DFPs ack */
rsize = 0;
break;
default:
CPRINTF("ERR:CMD:%d\n", cmd);
rsize = 0;
}
payload[0] |= VDO_CMDT(CMDT_INIT);
payload[0] |= VDO_SVDM_VERS(pd_get_vdo_ver(port));
#ifdef CONFIG_USB_PD_ALT_MODE_DFP
} else if (cmd_type == CMDT_RSP_BUSY) {
switch (cmd) {
case CMD_DISCOVER_IDENT:
case CMD_DISCOVER_SVID:
case CMD_DISCOVER_MODES:
/* resend if its discovery */
rsize = 1;
break;
case CMD_ENTER_MODE:
/* Error */
CPRINTF("ERR:ENTBUSY\n");
rsize = 0;
break;
case CMD_EXIT_MODE:
rsize = 0;
break;
default:
rsize = 0;
}
} else if (cmd_type == CMDT_RSP_NAK) {
rsize = 0;
/* Send SOP' Discover Ident message, if not already received. */
if (IS_ENABLED(CONFIG_USB_PD_DECODE_SOP) &&
!cable[port].is_identified && (cmd == CMD_DISCOVER_IDENT)) {
rsize = dfp_discover_ident(payload);
enable_transmit_sop_prime(port);
}
#endif /* CONFIG_USB_PD_ALT_MODE_DFP */
} else {
CPRINTF("ERR:CMDT:%d\n", cmd);
/* do not answer */
rsize = 0;
}
return rsize;
}
#else
int pd_svdm(int port, int cnt, uint32_t *payload, uint32_t **rpayload)
{
return 0;
}
#endif /* CONFIG_USB_PD_ALT_MODE */
#ifdef CONFIG_CMD_USB_PD_CABLE
static const char * const cable_type[] = {
[IDH_PTYPE_PCABLE] = "Passive",
[IDH_PTYPE_ACABLE] = "Active",
};
static const char * const cable_curr[] = {
[CABLE_CURRENT_3A] = "3A",
[CABLE_CURRENT_5A] = "5A",
};
static const char * const cable_ss_support[] = {
[USB_SS_U2_ONLY] = "Not supported",
[USB_SS_U31_GEN1] = "Gen 1",
[USB_SS_U31_GEN2] = "Gen 1 and Gen 2",
};
static const char * const vbus_max[] = {
[CABLE_VBUS_20V] = "20V",
[CABLE_VBUS_30V] = "30V",
[CABLE_VBUS_40V] = "40V",
[CABLE_VBUS_50V] = "50V",
};
static const char * const conn_type[] = {
[CONNECTOR_ATYPE] = "Type A",
[CONNECTOR_BTYPE] = "Type B",
[CONNECTOR_CTYPE] = "Type C",
[CONNECTOR_CAPTIVE] = "Captive",
};
static int command_cable(int argc, char **argv)
{
int port;
char *e;
if (argc < 2)
return EC_ERROR_PARAM_COUNT;
port = strtoi(argv[1], &e, 0);
if (*e || port >= CONFIG_USB_PD_PORT_COUNT)
return EC_ERROR_PARAM2;
if (!cable[port].is_identified) {
ccprintf("Cable not identified.\n");
return EC_SUCCESS;
}
ccprintf("Cable Type: ");
if (cable[port].type != IDH_PTYPE_PCABLE &&
cable[port].type != IDH_PTYPE_ACABLE) {
ccprintf("Not Emark Cable\n");
return EC_SUCCESS;
}
ccprintf("%s\n", cable_type[cable[port].type]);
/*
* For rev 2.0, rev 3.0 active and passive cables have same bits for
* connector type (Bit 19:18) and current handling capability bit 6:5
*/
ccprintf("Connector Type: %s\n",
cable[port].attr.rev20.connector > ARRAY_SIZE(conn_type) ?
"Invalid" : conn_type[cable[port].attr.rev20.connector]);
if (cable[port].attr.rev20.current) {
ccprintf("Cable Current: %s\n",
cable[port].attr.rev20.current > ARRAY_SIZE(cable_curr) ?
"Invalid" : cable_curr[cable[port].attr.rev20.current]);
} else
ccprintf("Cable Current: Invalid\n");
/*
* For Rev 3.0 passive cables and Rev 2.0 active and passive cables,
* USB Superspeed Signaling support have same bits 2:0
*/
if (cable[port].type == IDH_PTYPE_PCABLE) {
ccprintf("USB Superspeed Signaling support: %s\n",
cable[port].attr.rev20.ss >
ARRAY_SIZE(cable_ss_support) ? "Invalid" :
cable_ss_support[cable[port].attr.p_rev30.ss]);
}
/*
* For Rev 3.0 active cables and Rev 2.0 active and passive cables,
* SOP" controller preset have same bit 3
*/
if (cable[port].type == IDH_PTYPE_ACABLE) {
ccprintf("SOP' ' Controller: %s present\n",
cable[port].attr.rev20.controller ? "" : "Not");
}
if (cable[port].rev == PD_REV30) {
/*
* For Rev 3.0 active and passive cables, Max Vbus vtg have
* same bits 10:9.
*/
ccprintf("Max vbus voltage: %s\n",
cable[port].attr.p_rev30.vbus_max >
ARRAY_SIZE(vbus_max) ? "Invaild" :
vbus_max[cable[port].attr.p_rev30.vbus_max]);
/* For Rev 3.0 Active cables */
if (cable[port].type == IDH_PTYPE_ACABLE) {
ccprintf("SS signaling: USB_SS_GEN%u\n",
cable[port].attr2.a2_rev30.sss ? 2 : 1);
ccprintf("Number of SS lanes supported: %u\n",
cable[port].attr2.a2_rev30.lanes);
}
}
return EC_SUCCESS;
}
DECLARE_CONSOLE_COMMAND(pdcable, command_cable,
"<port>",
"Cable Characteristics");
#endif /* CONFIG_CMD_USB_PD_CABLE */
static void pd_usb_billboard_deferred(void)
{
#if defined(CONFIG_USB_PD_ALT_MODE) && !defined(CONFIG_USB_PD_ALT_MODE_DFP) \
&& !defined(CONFIG_USB_PD_SIMPLE_DFP) && defined(CONFIG_USB_BOS)
/*
* TODO(tbroch)
* 1. Will we have multiple type-C port UFPs
* 2. Will there be other modes applicable to DFPs besides DP
*/
if (!pd_alt_mode(0, USB_SID_DISPLAYPORT))
usb_connect();
#endif
}
DECLARE_DEFERRED(pd_usb_billboard_deferred);
#ifdef CONFIG_USB_PD_ALT_MODE_DFP
static enum ec_status hc_remote_pd_discovery(struct host_cmd_handler_args *args)
{
const uint8_t *port = args->params;
struct ec_params_usb_pd_discovery_entry *r = args->response;
if (*port >= CONFIG_USB_PD_PORT_COUNT)
return EC_RES_INVALID_PARAM;
r->vid = pd_get_identity_vid(*port);
r->ptype = PD_IDH_PTYPE(pe[*port].identity[0]);
/* pid only included if vid is assigned */
if (r->vid)
r->pid = PD_PRODUCT_PID(pe[*port].identity[2]);
args->response_size = sizeof(*r);
return EC_RES_SUCCESS;
}
DECLARE_HOST_COMMAND(EC_CMD_USB_PD_DISCOVERY,
hc_remote_pd_discovery,
EC_VER_MASK(0));
static enum ec_status hc_remote_pd_get_amode(struct host_cmd_handler_args *args)
{
struct svdm_amode_data *modep;
const struct ec_params_usb_pd_get_mode_request *p = args->params;
struct ec_params_usb_pd_get_mode_response *r = args->response;
if (p->port >= CONFIG_USB_PD_PORT_COUNT)
return EC_RES_INVALID_PARAM;
/* no more to send */
if (p->svid_idx >= pe[p->port].svid_cnt) {
r->svid = 0;
args->response_size = sizeof(r->svid);
return EC_RES_SUCCESS;
}
r->svid = pe[p->port].svids[p->svid_idx].svid;
r->opos = 0;
memcpy(r->vdo, pe[p->port].svids[p->svid_idx].mode_vdo, 24);
modep = get_modep(p->port, r->svid);
if (modep)
r->opos = pd_alt_mode(p->port, r->svid);
args->response_size = sizeof(*r);
return EC_RES_SUCCESS;
}
DECLARE_HOST_COMMAND(EC_CMD_USB_PD_GET_AMODE,
hc_remote_pd_get_amode,
EC_VER_MASK(0));
#endif
#define FW_RW_END (CONFIG_EC_WRITABLE_STORAGE_OFF + \
CONFIG_RW_STORAGE_OFF + CONFIG_RW_SIZE)
uint8_t *flash_hash_rw(void)
{
static struct sha256_ctx ctx;
/* re-calculate RW hash when changed as its time consuming */
if (rw_flash_changed) {
rw_flash_changed = 0;
SHA256_init(&ctx);
SHA256_update(&ctx, (void *)CONFIG_PROGRAM_MEMORY_BASE +
CONFIG_RW_MEM_OFF,
CONFIG_RW_SIZE - RSANUMBYTES);
return SHA256_final(&ctx);
} else {
return ctx.buf;
}
}
void pd_get_info(uint32_t *info_data)
{
void *rw_hash = flash_hash_rw();
/* copy first 20 bytes of RW hash */
memcpy(info_data, rw_hash, 5 * sizeof(uint32_t));
/* copy other info into data msg */
#if defined(CONFIG_USB_PD_HW_DEV_ID_BOARD_MAJOR) && \
defined(CONFIG_USB_PD_HW_DEV_ID_BOARD_MINOR)
info_data[5] = VDO_INFO(CONFIG_USB_PD_HW_DEV_ID_BOARD_MAJOR,
CONFIG_USB_PD_HW_DEV_ID_BOARD_MINOR,
ver_get_num_commits(system_get_image_copy()),
(system_get_image_copy() != SYSTEM_IMAGE_RO));
#else
info_data[5] = 0;
#endif
}
int pd_custom_flash_vdm(int port, int cnt, uint32_t *payload)
{
static int flash_offset;
int rsize = 1; /* default is just VDM header returned */
switch (PD_VDO_CMD(payload[0])) {
case VDO_CMD_VERSION:
memcpy(payload + 1, &current_image_data.version, 24);
rsize = 7;
break;
case VDO_CMD_REBOOT:
/* ensure the power supply is in a safe state */
pd_power_supply_reset(0);
system_reset(0);
break;
case VDO_CMD_READ_INFO:
/* copy info into response */
pd_get_info(payload + 1);
rsize = 7;
break;
case VDO_CMD_FLASH_ERASE:
/* do not kill the code under our feet */
if (system_get_image_copy() != SYSTEM_IMAGE_RO)
break;
pd_log_event(PD_EVENT_ACC_RW_ERASE, 0, 0, NULL);
flash_offset = CONFIG_EC_WRITABLE_STORAGE_OFF +
CONFIG_RW_STORAGE_OFF;
flash_physical_erase(CONFIG_EC_WRITABLE_STORAGE_OFF +
CONFIG_RW_STORAGE_OFF, CONFIG_RW_SIZE);
rw_flash_changed = 1;
break;
case VDO_CMD_FLASH_WRITE:
/* do not kill the code under our feet */
if ((system_get_image_copy() != SYSTEM_IMAGE_RO) ||
(flash_offset < CONFIG_EC_WRITABLE_STORAGE_OFF +
CONFIG_RW_STORAGE_OFF))
break;
flash_physical_write(flash_offset, 4*(cnt - 1),
(const char *)(payload+1));
flash_offset += 4*(cnt - 1);
rw_flash_changed = 1;
break;
case VDO_CMD_ERASE_SIG:
/* this is not touching the code area */
{
uint32_t zero = 0;
int offset;
/* zeroes the area containing the RSA signature */
for (offset = FW_RW_END - RSANUMBYTES;
offset < FW_RW_END; offset += 4)
flash_physical_write(offset, 4,
(const char *)&zero);
}
break;
default:
/* Unknown : do not answer */
return 0;
}
return rsize;
}
#ifdef CONFIG_USB_PD_DISCHARGE
void pd_set_vbus_discharge(int port, int enable)
{
static struct mutex discharge_lock[CONFIG_USB_PD_PORT_COUNT];
mutex_lock(&discharge_lock[port]);
enable &= !board_vbus_source_enabled(port);
#ifdef CONFIG_USB_PD_DISCHARGE_GPIO
if (!port)
gpio_set_level(GPIO_USB_C0_DISCHARGE, enable);
#if CONFIG_USB_PD_PORT_COUNT > 1
else
gpio_set_level(GPIO_USB_C1_DISCHARGE, enable);
#endif /* CONFIG_USB_PD_PORT_COUNT */
#elif defined(CONFIG_USB_PD_DISCHARGE_TCPC)
tcpc_discharge_vbus(port, enable);
#elif defined(CONFIG_USB_PD_DISCHARGE_PPC)
ppc_discharge_vbus(port, enable);
#else
#error "PD discharge implementation not defined"
#endif
mutex_unlock(&discharge_lock[port]);
}
#endif /* CONFIG_USB_PD_DISCHARGE */