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OpenCellular/common/usb_pd_policy.c
Nicolas Boichat 87e8cd6103 usb_pd_policy: Automatically swap vconn if adapter requests it 
During discovery, if adapter requests vconn power in the AMA flags,
make sure that we provide vconn.

This, for example, is necessary for the Apple HDMI adapter to work
on boot, when connected in S5. In that case, adapter does request
vconn swap, but we reject that as the system is off, and, therefore
5V supply is off. On boot, we send another discovery request, which
will detect this case and swap the power.

BRANCH=none
BUG=chromium:644663
TEST=On elm, S5. Plug adapter with power+HDMI. Switch on elm,
     type "pd 0 vdm ident" in console, display works.

Change-Id: I55b6658c2bc0574b8427ae086f61daf03730a725
Reviewed-on: https://chromium-review.googlesource.com/415697
Commit-Ready: Nicolas Boichat <drinkcat@chromium.org>
Tested-by: Nicolas Boichat <drinkcat@chromium.org>
Reviewed-by: Vincent Palatin <vpalatin@chromium.org>
2016-12-14 06:02:54 -08:00

1008 lines
25 KiB
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/* Copyright (c) 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 "flash.h"
#include "gpio.h"
#include "hooks.h"
#include "host_command.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_pd.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;
int pd_check_requested_voltage(uint32_t rdo)
{
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);
#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;
}
static int stub_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;
}
int pd_board_check_request(uint32_t, int)
__attribute__((weak, alias("stub_pd_board_check_request")));
#ifdef CONFIG_USB_PD_DUAL_ROLE
/* Cap on the max voltage requested as a sink (in millivolts) */
static unsigned max_request_mv = PD_MAX_VOLTAGE_MV; /* no cap */
/**
* Find PDO index that offers the most amount of power and stays within
* max_mv voltage.
*
* @param cnt the number of Power Data Objects.
* @param src_caps Power Data Objects representing the source capabilities.
* @param max_mv maximum voltage (or -1 if no limit)
* @return index of PDO within source cap packet
*/
static int pd_find_pdo_index(int cnt, uint32_t *src_caps, int max_mv)
{
int i, uw, mv, ma;
int ret = -1;
int __attribute__((unused)) cur_mv = 0;
int cur_uw = 0;
int prefer_cur;
/* max voltage is always limited by this boards max request */
max_mv = MIN(max_mv, PD_MAX_VOLTAGE_MV);
/* Get max power that is under our max voltage input */
for (i = 0; i < cnt; i++) {
mv = ((src_caps[i] >> 10) & 0x3FF) * 50;
/* Skip invalid voltage */
if (!mv)
continue;
/* Skip any voltage not supported by this board */
if (!pd_is_valid_input_voltage(mv))
continue;
if ((src_caps[i] & PDO_TYPE_MASK) == PDO_TYPE_BATTERY) {
uw = 250000 * (src_caps[i] & 0x3FF);
} else {
ma = (src_caps[i] & 0x3FF) * 10;
ma = MIN(ma, PD_MAX_CURRENT_MA);
uw = ma * mv;
}
if (mv > max_mv)
continue;
uw = MIN(uw, PD_MAX_POWER_MW * 1000);
prefer_cur = 0;
/* Apply special rules in case of 'tie' */
#ifdef PD_PREFER_LOW_VOLTAGE
if (uw == cur_uw && mv < cur_mv)
prefer_cur = 1;
#elif defined(PD_PREFER_HIGH_VOLTAGE)
if (uw == cur_uw && mv > cur_mv)
prefer_cur = 1;
#endif
/* Prefer higher power, except for tiebreaker */
if (uw > cur_uw || prefer_cur) {
ret = i;
cur_uw = uw;
cur_mv = mv;
}
}
return ret;
}
/**
* Extract power information out of a Power Data Object (PDO)
*
* @pdo Power data object
* @ma Current we can request from that PDO
* @mv Voltage of the PDO
*/
static void pd_extract_pdo_power(uint32_t pdo, uint32_t *ma, uint32_t *mv)
{
int max_ma, uw;
*mv = ((pdo >> 10) & 0x3FF) * 50;
if (*mv == 0) {
CPRINTF("ERR:PDO mv=0\n");
*ma = 0;
return;
}
if ((pdo & PDO_TYPE_MASK) == PDO_TYPE_BATTERY) {
uw = 250000 * (pdo & 0x3FF);
max_ma = 1000 * MIN(1000 * uw, PD_MAX_POWER_MW) / *mv;
} else {
max_ma = 10 * (pdo & 0x3FF);
max_ma = MIN(max_ma, PD_MAX_POWER_MW * 1000 / *mv);
}
*ma = MIN(max_ma, PD_MAX_CURRENT_MA);
}
int pd_build_request(int cnt, uint32_t *src_caps, uint32_t *rdo,
uint32_t *ma, uint32_t *mv, enum pd_request_type req_type)
{
int pdo_index, flags = 0;
int uw;
if (req_type == PD_REQUEST_VSAFE5V)
/* src cap 0 should be vSafe5V */
pdo_index = 0;
else
/* find pdo index for max voltage we can request */
pdo_index = pd_find_pdo_index(cnt, src_caps, max_request_mv);
/* If could not find desired pdo_index, then return error */
if (pdo_index == -1)
return -EC_ERROR_UNKNOWN;
pd_extract_pdo_power(src_caps[pdo_index], ma, mv);
uw = *ma * *mv;
/* Mismatch bit set if less power offered than the operating power */
if (uw < (1000 * PD_OPERATING_POWER_MW))
flags |= RDO_CAP_MISMATCH;
if ((src_caps[pdo_index] & PDO_TYPE_MASK) == PDO_TYPE_BATTERY) {
int mw = uw / 1000;
*rdo = RDO_BATT(pdo_index + 1, mw, mw, flags);
} else {
*rdo = RDO_FIXED(pdo_index + 1, *ma, *ma, flags);
}
return EC_SUCCESS;
}
void pd_process_source_cap(int port, int cnt, uint32_t *src_caps)
{
#ifdef CONFIG_CHARGE_MANAGER
uint32_t ma, mv;
int pdo_index;
/* Get max power info that we could request */
pdo_index = pd_find_pdo_index(cnt, src_caps, PD_MAX_VOLTAGE_MV);
if (pdo_index < 0)
pdo_index = 0;
pd_extract_pdo_power(src_caps[pdo_index], &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 */
#ifdef CONFIG_USB_PD_ALT_MODE
#ifdef CONFIG_USB_PD_ALT_MODE_DFP
static struct pd_policy pe[CONFIG_USB_PD_PORT_COUNT];
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:
/* TODO(tbroch) do I disable VBUS here if power contract
* requested it
*/
if (!PD_VDO_AMA_VBUS_REQ(payload[VDO_I(AMA)]))
pd_power_supply_reset(port);
#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);
#endif
break;
default:
break;
}
}
static int dfp_discover_svids(int port, uint32_t *payload)
{
payload[0] = VDO(USB_SID_PD, 1, CMD_DISCOVER_SVID);
return 1;
}
static void dfp_consume_svids(int port, uint32_t *payload)
{
int i;
uint32_t *ptr = payload + 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;
}
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++;
}
/* 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++) {
if (!&supported_modes[i])
continue;
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. Pin
* configs are organized in pairs with the following breakdown.
*
* 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 someone creates a multi-output dongle presumably they would need
* to either offer different mode capabilities depending upon connection type or
* the DFP would need additional system policy to expose those options.
*/
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;
/* 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:
func = svdm_rsp.amode->status;
break;
case CMD_DP_CONFIG:
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;
}
} 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:
dfp_consume_identity(port, cnt, payload);
rsize = dfp_discover_svids(port, 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, 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);
#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) {
/* nothing to do */
rsize = 0;
#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 */
#ifndef CONFIG_USB_PD_CUSTOM_VDM
int pd_vdm(int port, int cnt, uint32_t *payload, uint32_t **rpayload)
{
return 0;
}
#endif /* !CONFIG_USB_PD_CUSTOM_VDM */
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 int 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 int 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_numcommits(),
(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, &version_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
gpio_set_level(port ? GPIO_USB_C1_DISCHARGE :
GPIO_USB_C0_DISCHARGE, enable);
#elif defined(CONFIG_USB_PD_DISCHARGE_TCPC)
tcpc_discharge_vbus(port, enable);
#else
#error "PD discharge implementation not defined"
#endif
mutex_unlock(&discharge_lock[port]);
}
#endif /* CONFIG_USB_PD_DISCHARGE */
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