include/linux/platform_data/cros_ec_commands.h at v5.18-rc1

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kernel / include / linux / platform_data / cros_ec_commands.h
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   1/* SPDX-License-Identifier: GPL-2.0-only */
   2/*
   3 * Host communication command constants for ChromeOS EC
   4 *
   5 * Copyright (C) 2012 Google, Inc
   6 *
   7 * NOTE: This file is auto-generated from ChromeOS EC Open Source code from
   8 * https://chromium.googlesource.com/chromiumos/platform/ec/+/master/include/ec_commands.h
   9 */
  10
  11/* Host communication command constants for Chrome EC */
  12
  13#ifndef __CROS_EC_COMMANDS_H
  14#define __CROS_EC_COMMANDS_H
  15
  16
  17
  18
  19#define BUILD_ASSERT(_cond)
  20
  21/*
  22 * Current version of this protocol
  23 *
  24 * TODO(crosbug.com/p/11223): This is effectively useless; protocol is
  25 * determined in other ways.  Remove this once the kernel code no longer
  26 * depends on it.
  27 */
  28#define EC_PROTO_VERSION          0x00000002
  29
  30/* Command version mask */
  31#define EC_VER_MASK(version) BIT(version)
  32
  33/* I/O addresses for ACPI commands */
  34#define EC_LPC_ADDR_ACPI_DATA  0x62
  35#define EC_LPC_ADDR_ACPI_CMD   0x66
  36
  37/* I/O addresses for host command */
  38#define EC_LPC_ADDR_HOST_DATA  0x200
  39#define EC_LPC_ADDR_HOST_CMD   0x204
  40
  41/* I/O addresses for host command args and params */
  42/* Protocol version 2 */
  43#define EC_LPC_ADDR_HOST_ARGS    0x800  /* And 0x801, 0x802, 0x803 */
  44#define EC_LPC_ADDR_HOST_PARAM   0x804  /* For version 2 params; size is
  45					 * EC_PROTO2_MAX_PARAM_SIZE
  46					 */
  47/* Protocol version 3 */
  48#define EC_LPC_ADDR_HOST_PACKET  0x800  /* Offset of version 3 packet */
  49#define EC_LPC_HOST_PACKET_SIZE  0x100  /* Max size of version 3 packet */
  50
  51/*
  52 * The actual block is 0x800-0x8ff, but some BIOSes think it's 0x880-0x8ff
  53 * and they tell the kernel that so we have to think of it as two parts.
  54 */
  55#define EC_HOST_CMD_REGION0    0x800
  56#define EC_HOST_CMD_REGION1    0x880
  57#define EC_HOST_CMD_REGION_SIZE 0x80
  58
  59/* EC command register bit functions */
  60#define EC_LPC_CMDR_DATA	BIT(0)  /* Data ready for host to read */
  61#define EC_LPC_CMDR_PENDING	BIT(1)  /* Write pending to EC */
  62#define EC_LPC_CMDR_BUSY	BIT(2)  /* EC is busy processing a command */
  63#define EC_LPC_CMDR_CMD		BIT(3)  /* Last host write was a command */
  64#define EC_LPC_CMDR_ACPI_BRST	BIT(4)  /* Burst mode (not used) */
  65#define EC_LPC_CMDR_SCI		BIT(5)  /* SCI event is pending */
  66#define EC_LPC_CMDR_SMI		BIT(6)  /* SMI event is pending */
  67
  68#define EC_LPC_ADDR_MEMMAP       0x900
  69#define EC_MEMMAP_SIZE         255 /* ACPI IO buffer max is 255 bytes */
  70#define EC_MEMMAP_TEXT_MAX     8   /* Size of a string in the memory map */
  71
  72/* The offset address of each type of data in mapped memory. */
  73#define EC_MEMMAP_TEMP_SENSOR      0x00 /* Temp sensors 0x00 - 0x0f */
  74#define EC_MEMMAP_FAN              0x10 /* Fan speeds 0x10 - 0x17 */
  75#define EC_MEMMAP_TEMP_SENSOR_B    0x18 /* More temp sensors 0x18 - 0x1f */
  76#define EC_MEMMAP_ID               0x20 /* 0x20 == 'E', 0x21 == 'C' */
  77#define EC_MEMMAP_ID_VERSION       0x22 /* Version of data in 0x20 - 0x2f */
  78#define EC_MEMMAP_THERMAL_VERSION  0x23 /* Version of data in 0x00 - 0x1f */
  79#define EC_MEMMAP_BATTERY_VERSION  0x24 /* Version of data in 0x40 - 0x7f */
  80#define EC_MEMMAP_SWITCHES_VERSION 0x25 /* Version of data in 0x30 - 0x33 */
  81#define EC_MEMMAP_EVENTS_VERSION   0x26 /* Version of data in 0x34 - 0x3f */
  82#define EC_MEMMAP_HOST_CMD_FLAGS   0x27 /* Host cmd interface flags (8 bits) */
  83/* Unused 0x28 - 0x2f */
  84#define EC_MEMMAP_SWITCHES         0x30	/* 8 bits */
  85/* Unused 0x31 - 0x33 */
  86#define EC_MEMMAP_HOST_EVENTS      0x34 /* 64 bits */
  87/* Battery values are all 32 bits, unless otherwise noted. */
  88#define EC_MEMMAP_BATT_VOLT        0x40 /* Battery Present Voltage */
  89#define EC_MEMMAP_BATT_RATE        0x44 /* Battery Present Rate */
  90#define EC_MEMMAP_BATT_CAP         0x48 /* Battery Remaining Capacity */
  91#define EC_MEMMAP_BATT_FLAG        0x4c /* Battery State, see below (8-bit) */
  92#define EC_MEMMAP_BATT_COUNT       0x4d /* Battery Count (8-bit) */
  93#define EC_MEMMAP_BATT_INDEX       0x4e /* Current Battery Data Index (8-bit) */
  94/* Unused 0x4f */
  95#define EC_MEMMAP_BATT_DCAP        0x50 /* Battery Design Capacity */
  96#define EC_MEMMAP_BATT_DVLT        0x54 /* Battery Design Voltage */
  97#define EC_MEMMAP_BATT_LFCC        0x58 /* Battery Last Full Charge Capacity */
  98#define EC_MEMMAP_BATT_CCNT        0x5c /* Battery Cycle Count */
  99/* Strings are all 8 bytes (EC_MEMMAP_TEXT_MAX) */
 100#define EC_MEMMAP_BATT_MFGR        0x60 /* Battery Manufacturer String */
 101#define EC_MEMMAP_BATT_MODEL       0x68 /* Battery Model Number String */
 102#define EC_MEMMAP_BATT_SERIAL      0x70 /* Battery Serial Number String */
 103#define EC_MEMMAP_BATT_TYPE        0x78 /* Battery Type String */
 104#define EC_MEMMAP_ALS              0x80 /* ALS readings in lux (2 X 16 bits) */
 105/* Unused 0x84 - 0x8f */
 106#define EC_MEMMAP_ACC_STATUS       0x90 /* Accelerometer status (8 bits )*/
 107/* Unused 0x91 */
 108#define EC_MEMMAP_ACC_DATA         0x92 /* Accelerometers data 0x92 - 0x9f */
 109/* 0x92: Lid Angle if available, LID_ANGLE_UNRELIABLE otherwise */
 110/* 0x94 - 0x99: 1st Accelerometer */
 111/* 0x9a - 0x9f: 2nd Accelerometer */
 112#define EC_MEMMAP_GYRO_DATA        0xa0 /* Gyroscope data 0xa0 - 0xa5 */
 113/* Unused 0xa6 - 0xdf */
 114
 115/*
 116 * ACPI is unable to access memory mapped data at or above this offset due to
 117 * limitations of the ACPI protocol. Do not place data in the range 0xe0 - 0xfe
 118 * which might be needed by ACPI.
 119 */
 120#define EC_MEMMAP_NO_ACPI 0xe0
 121
 122/* Define the format of the accelerometer mapped memory status byte. */
 123#define EC_MEMMAP_ACC_STATUS_SAMPLE_ID_MASK  0x0f
 124#define EC_MEMMAP_ACC_STATUS_BUSY_BIT        BIT(4)
 125#define EC_MEMMAP_ACC_STATUS_PRESENCE_BIT    BIT(7)
 126
 127/* Number of temp sensors at EC_MEMMAP_TEMP_SENSOR */
 128#define EC_TEMP_SENSOR_ENTRIES     16
 129/*
 130 * Number of temp sensors at EC_MEMMAP_TEMP_SENSOR_B.
 131 *
 132 * Valid only if EC_MEMMAP_THERMAL_VERSION returns >= 2.
 133 */
 134#define EC_TEMP_SENSOR_B_ENTRIES      8
 135
 136/* Special values for mapped temperature sensors */
 137#define EC_TEMP_SENSOR_NOT_PRESENT    0xff
 138#define EC_TEMP_SENSOR_ERROR          0xfe
 139#define EC_TEMP_SENSOR_NOT_POWERED    0xfd
 140#define EC_TEMP_SENSOR_NOT_CALIBRATED 0xfc
 141/*
 142 * The offset of temperature value stored in mapped memory.  This allows
 143 * reporting a temperature range of 200K to 454K = -73C to 181C.
 144 */
 145#define EC_TEMP_SENSOR_OFFSET      200
 146
 147/*
 148 * Number of ALS readings at EC_MEMMAP_ALS
 149 */
 150#define EC_ALS_ENTRIES             2
 151
 152/*
 153 * The default value a temperature sensor will return when it is present but
 154 * has not been read this boot.  This is a reasonable number to avoid
 155 * triggering alarms on the host.
 156 */
 157#define EC_TEMP_SENSOR_DEFAULT     (296 - EC_TEMP_SENSOR_OFFSET)
 158
 159#define EC_FAN_SPEED_ENTRIES       4       /* Number of fans at EC_MEMMAP_FAN */
 160#define EC_FAN_SPEED_NOT_PRESENT   0xffff  /* Entry not present */
 161#define EC_FAN_SPEED_STALLED       0xfffe  /* Fan stalled */
 162
 163/* Battery bit flags at EC_MEMMAP_BATT_FLAG. */
 164#define EC_BATT_FLAG_AC_PRESENT   0x01
 165#define EC_BATT_FLAG_BATT_PRESENT 0x02
 166#define EC_BATT_FLAG_DISCHARGING  0x04
 167#define EC_BATT_FLAG_CHARGING     0x08
 168#define EC_BATT_FLAG_LEVEL_CRITICAL 0x10
 169/* Set if some of the static/dynamic data is invalid (or outdated). */
 170#define EC_BATT_FLAG_INVALID_DATA 0x20
 171
 172/* Switch flags at EC_MEMMAP_SWITCHES */
 173#define EC_SWITCH_LID_OPEN               0x01
 174#define EC_SWITCH_POWER_BUTTON_PRESSED   0x02
 175#define EC_SWITCH_WRITE_PROTECT_DISABLED 0x04
 176/* Was recovery requested via keyboard; now unused. */
 177#define EC_SWITCH_IGNORE1		 0x08
 178/* Recovery requested via dedicated signal (from servo board) */
 179#define EC_SWITCH_DEDICATED_RECOVERY     0x10
 180/* Was fake developer mode switch; now unused.  Remove in next refactor. */
 181#define EC_SWITCH_IGNORE0                0x20
 182
 183/* Host command interface flags */
 184/* Host command interface supports LPC args (LPC interface only) */
 185#define EC_HOST_CMD_FLAG_LPC_ARGS_SUPPORTED  0x01
 186/* Host command interface supports version 3 protocol */
 187#define EC_HOST_CMD_FLAG_VERSION_3   0x02
 188
 189/* Wireless switch flags */
 190#define EC_WIRELESS_SWITCH_ALL       ~0x00  /* All flags */
 191#define EC_WIRELESS_SWITCH_WLAN       0x01  /* WLAN radio */
 192#define EC_WIRELESS_SWITCH_BLUETOOTH  0x02  /* Bluetooth radio */
 193#define EC_WIRELESS_SWITCH_WWAN       0x04  /* WWAN power */
 194#define EC_WIRELESS_SWITCH_WLAN_POWER 0x08  /* WLAN power */
 195
 196/*****************************************************************************/
 197/*
 198 * ACPI commands
 199 *
 200 * These are valid ONLY on the ACPI command/data port.
 201 */
 202
 203/*
 204 * ACPI Read Embedded Controller
 205 *
 206 * This reads from ACPI memory space on the EC (EC_ACPI_MEM_*).
 207 *
 208 * Use the following sequence:
 209 *
 210 *    - Write EC_CMD_ACPI_READ to EC_LPC_ADDR_ACPI_CMD
 211 *    - Wait for EC_LPC_CMDR_PENDING bit to clear
 212 *    - Write address to EC_LPC_ADDR_ACPI_DATA
 213 *    - Wait for EC_LPC_CMDR_DATA bit to set
 214 *    - Read value from EC_LPC_ADDR_ACPI_DATA
 215 */
 216#define EC_CMD_ACPI_READ 0x0080
 217
 218/*
 219 * ACPI Write Embedded Controller
 220 *
 221 * This reads from ACPI memory space on the EC (EC_ACPI_MEM_*).
 222 *
 223 * Use the following sequence:
 224 *
 225 *    - Write EC_CMD_ACPI_WRITE to EC_LPC_ADDR_ACPI_CMD
 226 *    - Wait for EC_LPC_CMDR_PENDING bit to clear
 227 *    - Write address to EC_LPC_ADDR_ACPI_DATA
 228 *    - Wait for EC_LPC_CMDR_PENDING bit to clear
 229 *    - Write value to EC_LPC_ADDR_ACPI_DATA
 230 */
 231#define EC_CMD_ACPI_WRITE 0x0081
 232
 233/*
 234 * ACPI Burst Enable Embedded Controller
 235 *
 236 * This enables burst mode on the EC to allow the host to issue several
 237 * commands back-to-back. While in this mode, writes to mapped multi-byte
 238 * data are locked out to ensure data consistency.
 239 */
 240#define EC_CMD_ACPI_BURST_ENABLE 0x0082
 241
 242/*
 243 * ACPI Burst Disable Embedded Controller
 244 *
 245 * This disables burst mode on the EC and stops preventing EC writes to mapped
 246 * multi-byte data.
 247 */
 248#define EC_CMD_ACPI_BURST_DISABLE 0x0083
 249
 250/*
 251 * ACPI Query Embedded Controller
 252 *
 253 * This clears the lowest-order bit in the currently pending host events, and
 254 * sets the result code to the 1-based index of the bit (event 0x00000001 = 1,
 255 * event 0x80000000 = 32), or 0 if no event was pending.
 256 */
 257#define EC_CMD_ACPI_QUERY_EVENT 0x0084
 258
 259/* Valid addresses in ACPI memory space, for read/write commands */
 260
 261/* Memory space version; set to EC_ACPI_MEM_VERSION_CURRENT */
 262#define EC_ACPI_MEM_VERSION            0x00
 263/*
 264 * Test location; writing value here updates test compliment byte to (0xff -
 265 * value).
 266 */
 267#define EC_ACPI_MEM_TEST               0x01
 268/* Test compliment; writes here are ignored. */
 269#define EC_ACPI_MEM_TEST_COMPLIMENT    0x02
 270
 271/* Keyboard backlight brightness percent (0 - 100) */
 272#define EC_ACPI_MEM_KEYBOARD_BACKLIGHT 0x03
 273/* DPTF Target Fan Duty (0-100, 0xff for auto/none) */
 274#define EC_ACPI_MEM_FAN_DUTY           0x04
 275
 276/*
 277 * DPTF temp thresholds. Any of the EC's temp sensors can have up to two
 278 * independent thresholds attached to them. The current value of the ID
 279 * register determines which sensor is affected by the THRESHOLD and COMMIT
 280 * registers. The THRESHOLD register uses the same EC_TEMP_SENSOR_OFFSET scheme
 281 * as the memory-mapped sensors. The COMMIT register applies those settings.
 282 *
 283 * The spec does not mandate any way to read back the threshold settings
 284 * themselves, but when a threshold is crossed the AP needs a way to determine
 285 * which sensor(s) are responsible. Each reading of the ID register clears and
 286 * returns one sensor ID that has crossed one of its threshold (in either
 287 * direction) since the last read. A value of 0xFF means "no new thresholds
 288 * have tripped". Setting or enabling the thresholds for a sensor will clear
 289 * the unread event count for that sensor.
 290 */
 291#define EC_ACPI_MEM_TEMP_ID            0x05
 292#define EC_ACPI_MEM_TEMP_THRESHOLD     0x06
 293#define EC_ACPI_MEM_TEMP_COMMIT        0x07
 294/*
 295 * Here are the bits for the COMMIT register:
 296 *   bit 0 selects the threshold index for the chosen sensor (0/1)
 297 *   bit 1 enables/disables the selected threshold (0 = off, 1 = on)
 298 * Each write to the commit register affects one threshold.
 299 */
 300#define EC_ACPI_MEM_TEMP_COMMIT_SELECT_MASK BIT(0)
 301#define EC_ACPI_MEM_TEMP_COMMIT_ENABLE_MASK BIT(1)
 302/*
 303 * Example:
 304 *
 305 * Set the thresholds for sensor 2 to 50 C and 60 C:
 306 *   write 2 to [0x05]      --  select temp sensor 2
 307 *   write 0x7b to [0x06]   --  C_TO_K(50) - EC_TEMP_SENSOR_OFFSET
 308 *   write 0x2 to [0x07]    --  enable threshold 0 with this value
 309 *   write 0x85 to [0x06]   --  C_TO_K(60) - EC_TEMP_SENSOR_OFFSET
 310 *   write 0x3 to [0x07]    --  enable threshold 1 with this value
 311 *
 312 * Disable the 60 C threshold, leaving the 50 C threshold unchanged:
 313 *   write 2 to [0x05]      --  select temp sensor 2
 314 *   write 0x1 to [0x07]    --  disable threshold 1
 315 */
 316
 317/* DPTF battery charging current limit */
 318#define EC_ACPI_MEM_CHARGING_LIMIT     0x08
 319
 320/* Charging limit is specified in 64 mA steps */
 321#define EC_ACPI_MEM_CHARGING_LIMIT_STEP_MA   64
 322/* Value to disable DPTF battery charging limit */
 323#define EC_ACPI_MEM_CHARGING_LIMIT_DISABLED  0xff
 324
 325/*
 326 * Report device orientation
 327 *  Bits       Definition
 328 *  3:1        Device DPTF Profile Number (DDPN)
 329 *               0   = Reserved for backward compatibility (indicates no valid
 330 *                     profile number. Host should fall back to using TBMD).
 331 *              1..7 = DPTF Profile number to indicate to host which table needs
 332 *                     to be loaded.
 333 *   0         Tablet Mode Device Indicator (TBMD)
 334 */
 335#define EC_ACPI_MEM_DEVICE_ORIENTATION 0x09
 336#define EC_ACPI_MEM_TBMD_SHIFT         0
 337#define EC_ACPI_MEM_TBMD_MASK          0x1
 338#define EC_ACPI_MEM_DDPN_SHIFT         1
 339#define EC_ACPI_MEM_DDPN_MASK          0x7
 340
 341/*
 342 * Report device features. Uses the same format as the host command, except:
 343 *
 344 * bit 0 (EC_FEATURE_LIMITED) changes meaning from "EC code has a limited set
 345 * of features", which is of limited interest when the system is already
 346 * interpreting ACPI bytecode, to "EC_FEATURES[0-7] is not supported". Since
 347 * these are supported, it defaults to 0.
 348 * This allows detecting the presence of this field since older versions of
 349 * the EC codebase would simply return 0xff to that unknown address. Check
 350 * FEATURES0 != 0xff (or FEATURES0[0] == 0) to make sure that the other bits
 351 * are valid.
 352 */
 353#define EC_ACPI_MEM_DEVICE_FEATURES0 0x0a
 354#define EC_ACPI_MEM_DEVICE_FEATURES1 0x0b
 355#define EC_ACPI_MEM_DEVICE_FEATURES2 0x0c
 356#define EC_ACPI_MEM_DEVICE_FEATURES3 0x0d
 357#define EC_ACPI_MEM_DEVICE_FEATURES4 0x0e
 358#define EC_ACPI_MEM_DEVICE_FEATURES5 0x0f
 359#define EC_ACPI_MEM_DEVICE_FEATURES6 0x10
 360#define EC_ACPI_MEM_DEVICE_FEATURES7 0x11
 361
 362#define EC_ACPI_MEM_BATTERY_INDEX    0x12
 363
 364/*
 365 * USB Port Power. Each bit indicates whether the corresponding USB ports' power
 366 * is enabled (1) or disabled (0).
 367 *   bit 0 USB port ID 0
 368 *   ...
 369 *   bit 7 USB port ID 7
 370 */
 371#define EC_ACPI_MEM_USB_PORT_POWER 0x13
 372
 373/*
 374 * ACPI addresses 0x20 - 0xff map to EC_MEMMAP offset 0x00 - 0xdf.  This data
 375 * is read-only from the AP.  Added in EC_ACPI_MEM_VERSION 2.
 376 */
 377#define EC_ACPI_MEM_MAPPED_BEGIN   0x20
 378#define EC_ACPI_MEM_MAPPED_SIZE    0xe0
 379
 380/* Current version of ACPI memory address space */
 381#define EC_ACPI_MEM_VERSION_CURRENT 2
 382
 383
 384/*
 385 * This header file is used in coreboot both in C and ACPI code.  The ACPI code
 386 * is pre-processed to handle constants but the ASL compiler is unable to
 387 * handle actual C code so keep it separate.
 388 */
 389
 390
 391/*
 392 * Attributes for EC request and response packets.  Just defining __packed
 393 * results in inefficient assembly code on ARM, if the structure is actually
 394 * 32-bit aligned, as it should be for all buffers.
 395 *
 396 * Be very careful when adding these to existing structures.  They will round
 397 * up the structure size to the specified boundary.
 398 *
 399 * Also be very careful to make that if a structure is included in some other
 400 * parent structure that the alignment will still be true given the packing of
 401 * the parent structure.  This is particularly important if the sub-structure
 402 * will be passed as a pointer to another function, since that function will
 403 * not know about the misaligment caused by the parent structure's packing.
 404 *
 405 * Also be very careful using __packed - particularly when nesting non-packed
 406 * structures inside packed ones.  In fact, DO NOT use __packed directly;
 407 * always use one of these attributes.
 408 *
 409 * Once everything is annotated properly, the following search strings should
 410 * not return ANY matches in this file other than right here:
 411 *
 412 * "__packed" - generates inefficient code; all sub-structs must also be packed
 413 *
 414 * "struct [^_]" - all structs should be annotated, except for structs that are
 415 * members of other structs/unions (and their original declarations should be
 416 * annotated).
 417 */
 418
 419/*
 420 * Packed structures make no assumption about alignment, so they do inefficient
 421 * byte-wise reads.
 422 */
 423#define __ec_align1 __packed
 424#define __ec_align2 __packed
 425#define __ec_align4 __packed
 426#define __ec_align_size1 __packed
 427#define __ec_align_offset1 __packed
 428#define __ec_align_offset2 __packed
 429#define __ec_todo_packed __packed
 430#define __ec_todo_unpacked
 431
 432
 433/* LPC command status byte masks */
 434/* EC has written a byte in the data register and host hasn't read it yet */
 435#define EC_LPC_STATUS_TO_HOST     0x01
 436/* Host has written a command/data byte and the EC hasn't read it yet */
 437#define EC_LPC_STATUS_FROM_HOST   0x02
 438/* EC is processing a command */
 439#define EC_LPC_STATUS_PROCESSING  0x04
 440/* Last write to EC was a command, not data */
 441#define EC_LPC_STATUS_LAST_CMD    0x08
 442/* EC is in burst mode */
 443#define EC_LPC_STATUS_BURST_MODE  0x10
 444/* SCI event is pending (requesting SCI query) */
 445#define EC_LPC_STATUS_SCI_PENDING 0x20
 446/* SMI event is pending (requesting SMI query) */
 447#define EC_LPC_STATUS_SMI_PENDING 0x40
 448/* (reserved) */
 449#define EC_LPC_STATUS_RESERVED    0x80
 450
 451/*
 452 * EC is busy.  This covers both the EC processing a command, and the host has
 453 * written a new command but the EC hasn't picked it up yet.
 454 */
 455#define EC_LPC_STATUS_BUSY_MASK \
 456	(EC_LPC_STATUS_FROM_HOST | EC_LPC_STATUS_PROCESSING)
 457
 458/*
 459 * Host command response codes (16-bit).  Note that response codes should be
 460 * stored in a uint16_t rather than directly in a value of this type.
 461 */
 462enum ec_status {
 463	EC_RES_SUCCESS = 0,
 464	EC_RES_INVALID_COMMAND = 1,
 465	EC_RES_ERROR = 2,
 466	EC_RES_INVALID_PARAM = 3,
 467	EC_RES_ACCESS_DENIED = 4,
 468	EC_RES_INVALID_RESPONSE = 5,
 469	EC_RES_INVALID_VERSION = 6,
 470	EC_RES_INVALID_CHECKSUM = 7,
 471	EC_RES_IN_PROGRESS = 8,		/* Accepted, command in progress */
 472	EC_RES_UNAVAILABLE = 9,		/* No response available */
 473	EC_RES_TIMEOUT = 10,		/* We got a timeout */
 474	EC_RES_OVERFLOW = 11,		/* Table / data overflow */
 475	EC_RES_INVALID_HEADER = 12,     /* Header contains invalid data */
 476	EC_RES_REQUEST_TRUNCATED = 13,  /* Didn't get the entire request */
 477	EC_RES_RESPONSE_TOO_BIG = 14,   /* Response was too big to handle */
 478	EC_RES_BUS_ERROR = 15,		/* Communications bus error */
 479	EC_RES_BUSY = 16,		/* Up but too busy.  Should retry */
 480	EC_RES_INVALID_HEADER_VERSION = 17,  /* Header version invalid */
 481	EC_RES_INVALID_HEADER_CRC = 18,      /* Header CRC invalid */
 482	EC_RES_INVALID_DATA_CRC = 19,        /* Data CRC invalid */
 483	EC_RES_DUP_UNAVAILABLE = 20,         /* Can't resend response */
 484};
 485
 486/*
 487 * Host event codes.  Note these are 1-based, not 0-based, because ACPI query
 488 * EC command uses code 0 to mean "no event pending".  We explicitly specify
 489 * each value in the enum listing so they won't change if we delete/insert an
 490 * item or rearrange the list (it needs to be stable across platforms, not
 491 * just within a single compiled instance).
 492 */
 493enum host_event_code {
 494	EC_HOST_EVENT_LID_CLOSED = 1,
 495	EC_HOST_EVENT_LID_OPEN = 2,
 496	EC_HOST_EVENT_POWER_BUTTON = 3,
 497	EC_HOST_EVENT_AC_CONNECTED = 4,
 498	EC_HOST_EVENT_AC_DISCONNECTED = 5,
 499	EC_HOST_EVENT_BATTERY_LOW = 6,
 500	EC_HOST_EVENT_BATTERY_CRITICAL = 7,
 501	EC_HOST_EVENT_BATTERY = 8,
 502	EC_HOST_EVENT_THERMAL_THRESHOLD = 9,
 503	/* Event generated by a device attached to the EC */
 504	EC_HOST_EVENT_DEVICE = 10,
 505	EC_HOST_EVENT_THERMAL = 11,
 506	EC_HOST_EVENT_USB_CHARGER = 12,
 507	EC_HOST_EVENT_KEY_PRESSED = 13,
 508	/*
 509	 * EC has finished initializing the host interface.  The host can check
 510	 * for this event following sending a EC_CMD_REBOOT_EC command to
 511	 * determine when the EC is ready to accept subsequent commands.
 512	 */
 513	EC_HOST_EVENT_INTERFACE_READY = 14,
 514	/* Keyboard recovery combo has been pressed */
 515	EC_HOST_EVENT_KEYBOARD_RECOVERY = 15,
 516
 517	/* Shutdown due to thermal overload */
 518	EC_HOST_EVENT_THERMAL_SHUTDOWN = 16,
 519	/* Shutdown due to battery level too low */
 520	EC_HOST_EVENT_BATTERY_SHUTDOWN = 17,
 521
 522	/* Suggest that the AP throttle itself */
 523	EC_HOST_EVENT_THROTTLE_START = 18,
 524	/* Suggest that the AP resume normal speed */
 525	EC_HOST_EVENT_THROTTLE_STOP = 19,
 526
 527	/* Hang detect logic detected a hang and host event timeout expired */
 528	EC_HOST_EVENT_HANG_DETECT = 20,
 529	/* Hang detect logic detected a hang and warm rebooted the AP */
 530	EC_HOST_EVENT_HANG_REBOOT = 21,
 531
 532	/* PD MCU triggering host event */
 533	EC_HOST_EVENT_PD_MCU = 22,
 534
 535	/* Battery Status flags have changed */
 536	EC_HOST_EVENT_BATTERY_STATUS = 23,
 537
 538	/* EC encountered a panic, triggering a reset */
 539	EC_HOST_EVENT_PANIC = 24,
 540
 541	/* Keyboard fastboot combo has been pressed */
 542	EC_HOST_EVENT_KEYBOARD_FASTBOOT = 25,
 543
 544	/* EC RTC event occurred */
 545	EC_HOST_EVENT_RTC = 26,
 546
 547	/* Emulate MKBP event */
 548	EC_HOST_EVENT_MKBP = 27,
 549
 550	/* EC desires to change state of host-controlled USB mux */
 551	EC_HOST_EVENT_USB_MUX = 28,
 552
 553	/* TABLET/LAPTOP mode or detachable base attach/detach event */
 554	EC_HOST_EVENT_MODE_CHANGE = 29,
 555
 556	/* Keyboard recovery combo with hardware reinitialization */
 557	EC_HOST_EVENT_KEYBOARD_RECOVERY_HW_REINIT = 30,
 558
 559	/* WoV */
 560	EC_HOST_EVENT_WOV = 31,
 561
 562	/*
 563	 * The high bit of the event mask is not used as a host event code.  If
 564	 * it reads back as set, then the entire event mask should be
 565	 * considered invalid by the host.  This can happen when reading the
 566	 * raw event status via EC_MEMMAP_HOST_EVENTS but the LPC interface is
 567	 * not initialized on the EC, or improperly configured on the host.
 568	 */
 569	EC_HOST_EVENT_INVALID = 32
 570};
 571/* Host event mask */
 572#define EC_HOST_EVENT_MASK(event_code) BIT_ULL((event_code) - 1)
 573
 574/**
 575 * struct ec_lpc_host_args - Arguments at EC_LPC_ADDR_HOST_ARGS
 576 * @flags: The host argument flags.
 577 * @command_version: Command version.
 578 * @data_size: The length of data.
 579 * @checksum: Checksum; sum of command + flags + command_version + data_size +
 580 *            all params/response data bytes.
 581 */
 582struct ec_lpc_host_args {
 583	uint8_t flags;
 584	uint8_t command_version;
 585	uint8_t data_size;
 586	uint8_t checksum;
 587} __ec_align4;
 588
 589/* Flags for ec_lpc_host_args.flags */
 590/*
 591 * Args are from host.  Data area at EC_LPC_ADDR_HOST_PARAM contains command
 592 * params.
 593 *
 594 * If EC gets a command and this flag is not set, this is an old-style command.
 595 * Command version is 0 and params from host are at EC_LPC_ADDR_OLD_PARAM with
 596 * unknown length.  EC must respond with an old-style response (that is,
 597 * without setting EC_HOST_ARGS_FLAG_TO_HOST).
 598 */
 599#define EC_HOST_ARGS_FLAG_FROM_HOST 0x01
 600/*
 601 * Args are from EC.  Data area at EC_LPC_ADDR_HOST_PARAM contains response.
 602 *
 603 * If EC responds to a command and this flag is not set, this is an old-style
 604 * response.  Command version is 0 and response data from EC is at
 605 * EC_LPC_ADDR_OLD_PARAM with unknown length.
 606 */
 607#define EC_HOST_ARGS_FLAG_TO_HOST   0x02
 608
 609/*****************************************************************************/
 610/*
 611 * Byte codes returned by EC over SPI interface.
 612 *
 613 * These can be used by the AP to debug the EC interface, and to determine
 614 * when the EC is not in a state where it will ever get around to responding
 615 * to the AP.
 616 *
 617 * Example of sequence of bytes read from EC for a current good transfer:
 618 *   1. -                  - AP asserts chip select (CS#)
 619 *   2. EC_SPI_OLD_READY   - AP sends first byte(s) of request
 620 *   3. -                  - EC starts handling CS# interrupt
 621 *   4. EC_SPI_RECEIVING   - AP sends remaining byte(s) of request
 622 *   5. EC_SPI_PROCESSING  - EC starts processing request; AP is clocking in
 623 *                           bytes looking for EC_SPI_FRAME_START
 624 *   6. -                  - EC finishes processing and sets up response
 625 *   7. EC_SPI_FRAME_START - AP reads frame byte
 626 *   8. (response packet)  - AP reads response packet
 627 *   9. EC_SPI_PAST_END    - Any additional bytes read by AP
 628 *   10 -                  - AP deasserts chip select
 629 *   11 -                  - EC processes CS# interrupt and sets up DMA for
 630 *                           next request
 631 *
 632 * If the AP is waiting for EC_SPI_FRAME_START and sees any value other than
 633 * the following byte values:
 634 *   EC_SPI_OLD_READY
 635 *   EC_SPI_RX_READY
 636 *   EC_SPI_RECEIVING
 637 *   EC_SPI_PROCESSING
 638 *
 639 * Then the EC found an error in the request, or was not ready for the request
 640 * and lost data.  The AP should give up waiting for EC_SPI_FRAME_START,
 641 * because the EC is unable to tell when the AP is done sending its request.
 642 */
 643
 644/*
 645 * Framing byte which precedes a response packet from the EC.  After sending a
 646 * request, the AP will clock in bytes until it sees the framing byte, then
 647 * clock in the response packet.
 648 */
 649#define EC_SPI_FRAME_START    0xec
 650
 651/*
 652 * Padding bytes which are clocked out after the end of a response packet.
 653 */
 654#define EC_SPI_PAST_END       0xed
 655
 656/*
 657 * EC is ready to receive, and has ignored the byte sent by the AP.  EC expects
 658 * that the AP will send a valid packet header (starting with
 659 * EC_COMMAND_PROTOCOL_3) in the next 32 bytes.
 660 */
 661#define EC_SPI_RX_READY       0xf8
 662
 663/*
 664 * EC has started receiving the request from the AP, but hasn't started
 665 * processing it yet.
 666 */
 667#define EC_SPI_RECEIVING      0xf9
 668
 669/* EC has received the entire request from the AP and is processing it. */
 670#define EC_SPI_PROCESSING     0xfa
 671
 672/*
 673 * EC received bad data from the AP, such as a packet header with an invalid
 674 * length.  EC will ignore all data until chip select deasserts.
 675 */
 676#define EC_SPI_RX_BAD_DATA    0xfb
 677
 678/*
 679 * EC received data from the AP before it was ready.  That is, the AP asserted
 680 * chip select and started clocking data before the EC was ready to receive it.
 681 * EC will ignore all data until chip select deasserts.
 682 */
 683#define EC_SPI_NOT_READY      0xfc
 684
 685/*
 686 * EC was ready to receive a request from the AP.  EC has treated the byte sent
 687 * by the AP as part of a request packet, or (for old-style ECs) is processing
 688 * a fully received packet but is not ready to respond yet.
 689 */
 690#define EC_SPI_OLD_READY      0xfd
 691
 692/*****************************************************************************/
 693
 694/*
 695 * Protocol version 2 for I2C and SPI send a request this way:
 696 *
 697 *	0	EC_CMD_VERSION0 + (command version)
 698 *	1	Command number
 699 *	2	Length of params = N
 700 *	3..N+2	Params, if any
 701 *	N+3	8-bit checksum of bytes 0..N+2
 702 *
 703 * The corresponding response is:
 704 *
 705 *	0	Result code (EC_RES_*)
 706 *	1	Length of params = M
 707 *	2..M+1	Params, if any
 708 *	M+2	8-bit checksum of bytes 0..M+1
 709 */
 710#define EC_PROTO2_REQUEST_HEADER_BYTES 3
 711#define EC_PROTO2_REQUEST_TRAILER_BYTES 1
 712#define EC_PROTO2_REQUEST_OVERHEAD (EC_PROTO2_REQUEST_HEADER_BYTES +	\
 713				    EC_PROTO2_REQUEST_TRAILER_BYTES)
 714
 715#define EC_PROTO2_RESPONSE_HEADER_BYTES 2
 716#define EC_PROTO2_RESPONSE_TRAILER_BYTES 1
 717#define EC_PROTO2_RESPONSE_OVERHEAD (EC_PROTO2_RESPONSE_HEADER_BYTES +	\
 718				     EC_PROTO2_RESPONSE_TRAILER_BYTES)
 719
 720/* Parameter length was limited by the LPC interface */
 721#define EC_PROTO2_MAX_PARAM_SIZE 0xfc
 722
 723/* Maximum request and response packet sizes for protocol version 2 */
 724#define EC_PROTO2_MAX_REQUEST_SIZE (EC_PROTO2_REQUEST_OVERHEAD +	\
 725				    EC_PROTO2_MAX_PARAM_SIZE)
 726#define EC_PROTO2_MAX_RESPONSE_SIZE (EC_PROTO2_RESPONSE_OVERHEAD +	\
 727				     EC_PROTO2_MAX_PARAM_SIZE)
 728
 729/*****************************************************************************/
 730
 731/*
 732 * Value written to legacy command port / prefix byte to indicate protocol
 733 * 3+ structs are being used.  Usage is bus-dependent.
 734 */
 735#define EC_COMMAND_PROTOCOL_3 0xda
 736
 737#define EC_HOST_REQUEST_VERSION 3
 738
 739/**
 740 * struct ec_host_request - Version 3 request from host.
 741 * @struct_version: Should be 3. The EC will return EC_RES_INVALID_HEADER if it
 742 *                  receives a header with a version it doesn't know how to
 743 *                  parse.
 744 * @checksum: Checksum of request and data; sum of all bytes including checksum
 745 *            should total to 0.
 746 * @command: Command to send (EC_CMD_...)
 747 * @command_version: Command version.
 748 * @reserved: Unused byte in current protocol version; set to 0.
 749 * @data_len: Length of data which follows this header.
 750 */
 751struct ec_host_request {
 752	uint8_t struct_version;
 753	uint8_t checksum;
 754	uint16_t command;
 755	uint8_t command_version;
 756	uint8_t reserved;
 757	uint16_t data_len;
 758} __ec_align4;
 759
 760#define EC_HOST_RESPONSE_VERSION 3
 761
 762/**
 763 * struct ec_host_response - Version 3 response from EC.
 764 * @struct_version: Struct version (=3).
 765 * @checksum: Checksum of response and data; sum of all bytes including
 766 *            checksum should total to 0.
 767 * @result: EC's response to the command (separate from communication failure)
 768 * @data_len: Length of data which follows this header.
 769 * @reserved: Unused bytes in current protocol version; set to 0.
 770 */
 771struct ec_host_response {
 772	uint8_t struct_version;
 773	uint8_t checksum;
 774	uint16_t result;
 775	uint16_t data_len;
 776	uint16_t reserved;
 777} __ec_align4;
 778
 779/*****************************************************************************/
 780
 781/*
 782 * Host command protocol V4.
 783 *
 784 * Packets always start with a request or response header.  They are followed
 785 * by data_len bytes of data.  If the data_crc_present flag is set, the data
 786 * bytes are followed by a CRC-8 of that data, using using x^8 + x^2 + x + 1
 787 * polynomial.
 788 *
 789 * Host algorithm when sending a request q:
 790 *
 791 * 101) tries_left=(some value, e.g. 3);
 792 * 102) q.seq_num++
 793 * 103) q.seq_dup=0
 794 * 104) Calculate q.header_crc.
 795 * 105) Send request q to EC.
 796 * 106) Wait for response r.  Go to 201 if received or 301 if timeout.
 797 *
 798 * 201) If r.struct_version != 4, go to 301.
 799 * 202) If r.header_crc mismatches calculated CRC for r header, go to 301.
 800 * 203) If r.data_crc_present and r.data_crc mismatches, go to 301.
 801 * 204) If r.seq_num != q.seq_num, go to 301.
 802 * 205) If r.seq_dup == q.seq_dup, return success.
 803 * 207) If r.seq_dup == 1, go to 301.
 804 * 208) Return error.
 805 *
 806 * 301) If --tries_left <= 0, return error.
 807 * 302) If q.seq_dup == 1, go to 105.
 808 * 303) q.seq_dup = 1
 809 * 304) Go to 104.
 810 *
 811 * EC algorithm when receiving a request q.
 812 * EC has response buffer r, error buffer e.
 813 *
 814 * 101) If q.struct_version != 4, set e.result = EC_RES_INVALID_HEADER_VERSION
 815 *      and go to 301
 816 * 102) If q.header_crc mismatches calculated CRC, set e.result =
 817 *      EC_RES_INVALID_HEADER_CRC and go to 301
 818 * 103) If q.data_crc_present, calculate data CRC.  If that mismatches the CRC
 819 *      byte at the end of the packet, set e.result = EC_RES_INVALID_DATA_CRC
 820 *      and go to 301.
 821 * 104) If q.seq_dup == 0, go to 201.
 822 * 105) If q.seq_num != r.seq_num, go to 201.
 823 * 106) If q.seq_dup == r.seq_dup, go to 205, else go to 203.
 824 *
 825 * 201) Process request q into response r.
 826 * 202) r.seq_num = q.seq_num
 827 * 203) r.seq_dup = q.seq_dup
 828 * 204) Calculate r.header_crc
 829 * 205) If r.data_len > 0 and data is no longer available, set e.result =
 830 *      EC_RES_DUP_UNAVAILABLE and go to 301.
 831 * 206) Send response r.
 832 *
 833 * 301) e.seq_num = q.seq_num
 834 * 302) e.seq_dup = q.seq_dup
 835 * 303) Calculate e.header_crc.
 836 * 304) Send error response e.
 837 */
 838
 839/* Version 4 request from host */
 840struct ec_host_request4 {
 841	/*
 842	 * bits 0-3: struct_version: Structure version (=4)
 843	 * bit    4: is_response: Is response (=0)
 844	 * bits 5-6: seq_num: Sequence number
 845	 * bit    7: seq_dup: Sequence duplicate flag
 846	 */
 847	uint8_t fields0;
 848
 849	/*
 850	 * bits 0-4: command_version: Command version
 851	 * bits 5-6: Reserved (set 0, ignore on read)
 852	 * bit    7: data_crc_present: Is data CRC present after data
 853	 */
 854	uint8_t fields1;
 855
 856	/* Command code (EC_CMD_*) */
 857	uint16_t command;
 858
 859	/* Length of data which follows this header (not including data CRC) */
 860	uint16_t data_len;
 861
 862	/* Reserved (set 0, ignore on read) */
 863	uint8_t reserved;
 864
 865	/* CRC-8 of above fields, using x^8 + x^2 + x + 1 polynomial */
 866	uint8_t header_crc;
 867} __ec_align4;
 868
 869/* Version 4 response from EC */
 870struct ec_host_response4 {
 871	/*
 872	 * bits 0-3: struct_version: Structure version (=4)
 873	 * bit    4: is_response: Is response (=1)
 874	 * bits 5-6: seq_num: Sequence number
 875	 * bit    7: seq_dup: Sequence duplicate flag
 876	 */
 877	uint8_t fields0;
 878
 879	/*
 880	 * bits 0-6: Reserved (set 0, ignore on read)
 881	 * bit    7: data_crc_present: Is data CRC present after data
 882	 */
 883	uint8_t fields1;
 884
 885	/* Result code (EC_RES_*) */
 886	uint16_t result;
 887
 888	/* Length of data which follows this header (not including data CRC) */
 889	uint16_t data_len;
 890
 891	/* Reserved (set 0, ignore on read) */
 892	uint8_t reserved;
 893
 894	/* CRC-8 of above fields, using x^8 + x^2 + x + 1 polynomial */
 895	uint8_t header_crc;
 896} __ec_align4;
 897
 898/* Fields in fields0 byte */
 899#define EC_PACKET4_0_STRUCT_VERSION_MASK	0x0f
 900#define EC_PACKET4_0_IS_RESPONSE_MASK		0x10
 901#define EC_PACKET4_0_SEQ_NUM_SHIFT		5
 902#define EC_PACKET4_0_SEQ_NUM_MASK		0x60
 903#define EC_PACKET4_0_SEQ_DUP_MASK		0x80
 904
 905/* Fields in fields1 byte */
 906#define EC_PACKET4_1_COMMAND_VERSION_MASK	0x1f  /* (request only) */
 907#define EC_PACKET4_1_DATA_CRC_PRESENT_MASK	0x80
 908
 909/*****************************************************************************/
 910/*
 911 * Notes on commands:
 912 *
 913 * Each command is an 16-bit command value.  Commands which take params or
 914 * return response data specify structures for that data.  If no structure is
 915 * specified, the command does not input or output data, respectively.
 916 * Parameter/response length is implicit in the structs.  Some underlying
 917 * communication protocols (I2C, SPI) may add length or checksum headers, but
 918 * those are implementation-dependent and not defined here.
 919 *
 920 * All commands MUST be #defined to be 4-digit UPPER CASE hex values
 921 * (e.g., 0x00AB, not 0xab) for CONFIG_HOSTCMD_SECTION_SORTED to work.
 922 */
 923
 924/*****************************************************************************/
 925/* General / test commands */
 926
 927/*
 928 * Get protocol version, used to deal with non-backward compatible protocol
 929 * changes.
 930 */
 931#define EC_CMD_PROTO_VERSION 0x0000
 932
 933/**
 934 * struct ec_response_proto_version - Response to the proto version command.
 935 * @version: The protocol version.
 936 */
 937struct ec_response_proto_version {
 938	uint32_t version;
 939} __ec_align4;
 940
 941/*
 942 * Hello.  This is a simple command to test the EC is responsive to
 943 * commands.
 944 */
 945#define EC_CMD_HELLO 0x0001
 946
 947/**
 948 * struct ec_params_hello - Parameters to the hello command.
 949 * @in_data: Pass anything here.
 950 */
 951struct ec_params_hello {
 952	uint32_t in_data;
 953} __ec_align4;
 954
 955/**
 956 * struct ec_response_hello - Response to the hello command.
 957 * @out_data: Output will be in_data + 0x01020304.
 958 */
 959struct ec_response_hello {
 960	uint32_t out_data;
 961} __ec_align4;
 962
 963/* Get version number */
 964#define EC_CMD_GET_VERSION 0x0002
 965
 966enum ec_current_image {
 967	EC_IMAGE_UNKNOWN = 0,
 968	EC_IMAGE_RO,
 969	EC_IMAGE_RW
 970};
 971
 972/**
 973 * struct ec_response_get_version - Response to the get version command.
 974 * @version_string_ro: Null-terminated RO firmware version string.
 975 * @version_string_rw: Null-terminated RW firmware version string.
 976 * @reserved: Unused bytes; was previously RW-B firmware version string.
 977 * @current_image: One of ec_current_image.
 978 */
 979struct ec_response_get_version {
 980	char version_string_ro[32];
 981	char version_string_rw[32];
 982	char reserved[32];
 983	uint32_t current_image;
 984} __ec_align4;
 985
 986/* Read test */
 987#define EC_CMD_READ_TEST 0x0003
 988
 989/**
 990 * struct ec_params_read_test - Parameters for the read test command.
 991 * @offset: Starting value for read buffer.
 992 * @size: Size to read in bytes.
 993 */
 994struct ec_params_read_test {
 995	uint32_t offset;
 996	uint32_t size;
 997} __ec_align4;
 998
 999/**
1000 * struct ec_response_read_test - Response to the read test command.
1001 * @data: Data returned by the read test command.
1002 */
1003struct ec_response_read_test {
1004	uint32_t data[32];
1005} __ec_align4;
1006
1007/*
1008 * Get build information
1009 *
1010 * Response is null-terminated string.
1011 */
1012#define EC_CMD_GET_BUILD_INFO 0x0004
1013
1014/* Get chip info */
1015#define EC_CMD_GET_CHIP_INFO 0x0005
1016
1017/**
1018 * struct ec_response_get_chip_info - Response to the get chip info command.
1019 * @vendor: Null-terminated string for chip vendor.
1020 * @name: Null-terminated string for chip name.
1021 * @revision: Null-terminated string for chip mask version.
1022 */
1023struct ec_response_get_chip_info {
1024	char vendor[32];
1025	char name[32];
1026	char revision[32];
1027} __ec_align4;
1028
1029/* Get board HW version */
1030#define EC_CMD_GET_BOARD_VERSION 0x0006
1031
1032/**
1033 * struct ec_response_board_version - Response to the board version command.
1034 * @board_version: A monotonously incrementing number.
1035 */
1036struct ec_response_board_version {
1037	uint16_t board_version;
1038} __ec_align2;
1039
1040/*
1041 * Read memory-mapped data.
1042 *
1043 * This is an alternate interface to memory-mapped data for bus protocols
1044 * which don't support direct-mapped memory - I2C, SPI, etc.
1045 *
1046 * Response is params.size bytes of data.
1047 */
1048#define EC_CMD_READ_MEMMAP 0x0007
1049
1050/**
1051 * struct ec_params_read_memmap - Parameters for the read memory map command.
1052 * @offset: Offset in memmap (EC_MEMMAP_*).
1053 * @size: Size to read in bytes.
1054 */
1055struct ec_params_read_memmap {
1056	uint8_t offset;
1057	uint8_t size;
1058} __ec_align1;
1059
1060/* Read versions supported for a command */
1061#define EC_CMD_GET_CMD_VERSIONS 0x0008
1062
1063/**
1064 * struct ec_params_get_cmd_versions - Parameters for the get command versions.
1065 * @cmd: Command to check.
1066 */
1067struct ec_params_get_cmd_versions {
1068	uint8_t cmd;
1069} __ec_align1;
1070
1071/**
1072 * struct ec_params_get_cmd_versions_v1 - Parameters for the get command
1073 *         versions (v1)
1074 * @cmd: Command to check.
1075 */
1076struct ec_params_get_cmd_versions_v1 {
1077	uint16_t cmd;
1078} __ec_align2;
1079
1080/**
1081 * struct ec_response_get_cmd_version - Response to the get command versions.
1082 * @version_mask: Mask of supported versions; use EC_VER_MASK() to compare with
1083 *                a desired version.
1084 */
1085struct ec_response_get_cmd_versions {
1086	uint32_t version_mask;
1087} __ec_align4;
1088
1089/*
1090 * Check EC communications status (busy). This is needed on i2c/spi but not
1091 * on lpc since it has its own out-of-band busy indicator.
1092 *
1093 * lpc must read the status from the command register. Attempting this on
1094 * lpc will overwrite the args/parameter space and corrupt its data.
1095 */
1096#define EC_CMD_GET_COMMS_STATUS		0x0009
1097
1098/* Avoid using ec_status which is for return values */
1099enum ec_comms_status {
1100	EC_COMMS_STATUS_PROCESSING	= BIT(0),	/* Processing cmd */
1101};
1102
1103/**
1104 * struct ec_response_get_comms_status - Response to the get comms status
1105 *         command.
1106 * @flags: Mask of enum ec_comms_status.
1107 */
1108struct ec_response_get_comms_status {
1109	uint32_t flags;		/* Mask of enum ec_comms_status */
1110} __ec_align4;
1111
1112/* Fake a variety of responses, purely for testing purposes. */
1113#define EC_CMD_TEST_PROTOCOL		0x000A
1114
1115/* Tell the EC what to send back to us. */
1116struct ec_params_test_protocol {
1117	uint32_t ec_result;
1118	uint32_t ret_len;
1119	uint8_t buf[32];
1120} __ec_align4;
1121
1122/* Here it comes... */
1123struct ec_response_test_protocol {
1124	uint8_t buf[32];
1125} __ec_align4;
1126
1127/* Get protocol information */
1128#define EC_CMD_GET_PROTOCOL_INFO	0x000B
1129
1130/* Flags for ec_response_get_protocol_info.flags */
1131/* EC_RES_IN_PROGRESS may be returned if a command is slow */
1132#define EC_PROTOCOL_INFO_IN_PROGRESS_SUPPORTED BIT(0)
1133
1134/**
1135 * struct ec_response_get_protocol_info - Response to the get protocol info.
1136 * @protocol_versions: Bitmask of protocol versions supported (1 << n means
1137 *                     version n).
1138 * @max_request_packet_size: Maximum request packet size in bytes.
1139 * @max_response_packet_size: Maximum response packet size in bytes.
1140 * @flags: see EC_PROTOCOL_INFO_*
1141 */
1142struct ec_response_get_protocol_info {
1143	/* Fields which exist if at least protocol version 3 supported */
1144	uint32_t protocol_versions;
1145	uint16_t max_request_packet_size;
1146	uint16_t max_response_packet_size;
1147	uint32_t flags;
1148} __ec_align4;
1149
1150
1151/*****************************************************************************/
1152/* Get/Set miscellaneous values */
1153
1154/* The upper byte of .flags tells what to do (nothing means "get") */
1155#define EC_GSV_SET        0x80000000
1156
1157/*
1158 * The lower three bytes of .flags identifies the parameter, if that has
1159 * meaning for an individual command.
1160 */
1161#define EC_GSV_PARAM_MASK 0x00ffffff
1162
1163struct ec_params_get_set_value {
1164	uint32_t flags;
1165	uint32_t value;
1166} __ec_align4;
1167
1168struct ec_response_get_set_value {
1169	uint32_t flags;
1170	uint32_t value;
1171} __ec_align4;
1172
1173/* More than one command can use these structs to get/set parameters. */
1174#define EC_CMD_GSV_PAUSE_IN_S5	0x000C
1175
1176/*****************************************************************************/
1177/* List the features supported by the firmware */
1178#define EC_CMD_GET_FEATURES  0x000D
1179
1180/* Supported features */
1181enum ec_feature_code {
1182	/*
1183	 * This image contains a limited set of features. Another image
1184	 * in RW partition may support more features.
1185	 */
1186	EC_FEATURE_LIMITED = 0,
1187	/*
1188	 * Commands for probing/reading/writing/erasing the flash in the
1189	 * EC are present.
1190	 */
1191	EC_FEATURE_FLASH = 1,
1192	/*
1193	 * Can control the fan speed directly.
1194	 */
1195	EC_FEATURE_PWM_FAN = 2,
1196	/*
1197	 * Can control the intensity of the keyboard backlight.
1198	 */
1199	EC_FEATURE_PWM_KEYB = 3,
1200	/*
1201	 * Support Google lightbar, introduced on Pixel.
1202	 */
1203	EC_FEATURE_LIGHTBAR = 4,
1204	/* Control of LEDs  */
1205	EC_FEATURE_LED = 5,
1206	/* Exposes an interface to control gyro and sensors.
1207	 * The host goes through the EC to access these sensors.
1208	 * In addition, the EC may provide composite sensors, like lid angle.
1209	 */
1210	EC_FEATURE_MOTION_SENSE = 6,
1211	/* The keyboard is controlled by the EC */
1212	EC_FEATURE_KEYB = 7,
1213	/* The AP can use part of the EC flash as persistent storage. */
1214	EC_FEATURE_PSTORE = 8,
1215	/* The EC monitors BIOS port 80h, and can return POST codes. */
1216	EC_FEATURE_PORT80 = 9,
1217	/*
1218	 * Thermal management: include TMP specific commands.
1219	 * Higher level than direct fan control.
1220	 */
1221	EC_FEATURE_THERMAL = 10,
1222	/* Can switch the screen backlight on/off */
1223	EC_FEATURE_BKLIGHT_SWITCH = 11,
1224	/* Can switch the wifi module on/off */
1225	EC_FEATURE_WIFI_SWITCH = 12,
1226	/* Monitor host events, through for example SMI or SCI */
1227	EC_FEATURE_HOST_EVENTS = 13,
1228	/* The EC exposes GPIO commands to control/monitor connected devices. */
1229	EC_FEATURE_GPIO = 14,
1230	/* The EC can send i2c messages to downstream devices. */
1231	EC_FEATURE_I2C = 15,
1232	/* Command to control charger are included */
1233	EC_FEATURE_CHARGER = 16,
1234	/* Simple battery support. */
1235	EC_FEATURE_BATTERY = 17,
1236	/*
1237	 * Support Smart battery protocol
1238	 * (Common Smart Battery System Interface Specification)
1239	 */
1240	EC_FEATURE_SMART_BATTERY = 18,
1241	/* EC can detect when the host hangs. */
1242	EC_FEATURE_HANG_DETECT = 19,
1243	/* Report power information, for pit only */
1244	EC_FEATURE_PMU = 20,
1245	/* Another Cros EC device is present downstream of this one */
1246	EC_FEATURE_SUB_MCU = 21,
1247	/* Support USB Power delivery (PD) commands */
1248	EC_FEATURE_USB_PD = 22,
1249	/* Control USB multiplexer, for audio through USB port for instance. */
1250	EC_FEATURE_USB_MUX = 23,
1251	/* Motion Sensor code has an internal software FIFO */
1252	EC_FEATURE_MOTION_SENSE_FIFO = 24,
1253	/* Support temporary secure vstore */
1254	EC_FEATURE_VSTORE = 25,
1255	/* EC decides on USB-C SS mux state, muxes configured by host */
1256	EC_FEATURE_USBC_SS_MUX_VIRTUAL = 26,
1257	/* EC has RTC feature that can be controlled by host commands */
1258	EC_FEATURE_RTC = 27,
1259	/* The MCU exposes a Fingerprint sensor */
1260	EC_FEATURE_FINGERPRINT = 28,
1261	/* The MCU exposes a Touchpad */
1262	EC_FEATURE_TOUCHPAD = 29,
1263	/* The MCU has RWSIG task enabled */
1264	EC_FEATURE_RWSIG = 30,
1265	/* EC has device events support */
1266	EC_FEATURE_DEVICE_EVENT = 31,
1267	/* EC supports the unified wake masks for LPC/eSPI systems */
1268	EC_FEATURE_UNIFIED_WAKE_MASKS = 32,
1269	/* EC supports 64-bit host events */
1270	EC_FEATURE_HOST_EVENT64 = 33,
1271	/* EC runs code in RAM (not in place, a.k.a. XIP) */
1272	EC_FEATURE_EXEC_IN_RAM = 34,
1273	/* EC supports CEC commands */
1274	EC_FEATURE_CEC = 35,
1275	/* EC supports tight sensor timestamping. */
1276	EC_FEATURE_MOTION_SENSE_TIGHT_TIMESTAMPS = 36,
1277	/*
1278	 * EC supports tablet mode detection aligned to Chrome and allows
1279	 * setting of threshold by host command using
1280	 * MOTIONSENSE_CMD_TABLET_MODE_LID_ANGLE.
1281	 */
1282	EC_FEATURE_REFINED_TABLET_MODE_HYSTERESIS = 37,
1283	/* The MCU is a System Companion Processor (SCP). */
1284	EC_FEATURE_SCP = 39,
1285	/* The MCU is an Integrated Sensor Hub */
1286	EC_FEATURE_ISH = 40,
1287	/* New TCPMv2 TYPEC_ prefaced commands supported */
1288	EC_FEATURE_TYPEC_CMD = 41,
1289	/*
1290	 * The EC will wait for direction from the AP to enter Type-C alternate
1291	 * modes or USB4.
1292	 */
1293	EC_FEATURE_TYPEC_REQUIRE_AP_MODE_ENTRY = 42,
1294	/*
1295	 * The EC will wait for an acknowledge from the AP after setting the
1296	 * mux.
1297	 */
1298	EC_FEATURE_TYPEC_MUX_REQUIRE_AP_ACK = 43,
1299};
1300
1301#define EC_FEATURE_MASK_0(event_code) BIT(event_code % 32)
1302#define EC_FEATURE_MASK_1(event_code) BIT(event_code - 32)
1303
1304struct ec_response_get_features {
1305	uint32_t flags[2];
1306} __ec_align4;
1307
1308/*****************************************************************************/
1309/* Get the board's SKU ID from EC */
1310#define EC_CMD_GET_SKU_ID 0x000E
1311
1312/* Set SKU ID from AP */
1313#define EC_CMD_SET_SKU_ID 0x000F
1314
1315struct ec_sku_id_info {
1316	uint32_t sku_id;
1317} __ec_align4;
1318
1319/*****************************************************************************/
1320/* Flash commands */
1321
1322/* Get flash info */
1323#define EC_CMD_FLASH_INFO 0x0010
1324#define EC_VER_FLASH_INFO 2
1325
1326/**
1327 * struct ec_response_flash_info - Response to the flash info command.
1328 * @flash_size: Usable flash size in bytes.
1329 * @write_block_size: Write block size. Write offset and size must be a
1330 *                    multiple of this.
1331 * @erase_block_size: Erase block size. Erase offset and size must be a
1332 *                    multiple of this.
1333 * @protect_block_size: Protection block size. Protection offset and size
1334 *                      must be a multiple of this.
1335 *
1336 * Version 0 returns these fields.
1337 */
1338struct ec_response_flash_info {
1339	uint32_t flash_size;
1340	uint32_t write_block_size;
1341	uint32_t erase_block_size;
1342	uint32_t protect_block_size;
1343} __ec_align4;
1344
1345/*
1346 * Flags for version 1+ flash info command
1347 * EC flash erases bits to 0 instead of 1.
1348 */
1349#define EC_FLASH_INFO_ERASE_TO_0 BIT(0)
1350
1351/*
1352 * Flash must be selected for read/write/erase operations to succeed.  This may
1353 * be necessary on a chip where write/erase can be corrupted by other board
1354 * activity, or where the chip needs to enable some sort of programming voltage,
1355 * or where the read/write/erase operations require cleanly suspending other
1356 * chip functionality.
1357 */
1358#define EC_FLASH_INFO_SELECT_REQUIRED BIT(1)
1359
1360/**
1361 * struct ec_response_flash_info_1 - Response to the flash info v1 command.
1362 * @flash_size: Usable flash size in bytes.
1363 * @write_block_size: Write block size. Write offset and size must be a
1364 *                    multiple of this.
1365 * @erase_block_size: Erase block size. Erase offset and size must be a
1366 *                    multiple of this.
1367 * @protect_block_size: Protection block size. Protection offset and size
1368 *                      must be a multiple of this.
1369 * @write_ideal_size: Ideal write size in bytes.  Writes will be fastest if
1370 *                    size is exactly this and offset is a multiple of this.
1371 *                    For example, an EC may have a write buffer which can do
1372 *                    half-page operations if data is aligned, and a slower
1373 *                    word-at-a-time write mode.
1374 * @flags: Flags; see EC_FLASH_INFO_*
1375 *
1376 * Version 1 returns the same initial fields as version 0, with additional
1377 * fields following.
1378 *
1379 * gcc anonymous structs don't seem to get along with the __packed directive;
1380 * if they did we'd define the version 0 structure as a sub-structure of this
1381 * one.
1382 *
1383 * Version 2 supports flash banks of different sizes:
1384 * The caller specified the number of banks it has preallocated
1385 * (num_banks_desc)
1386 * The EC returns the number of banks describing the flash memory.
1387 * It adds banks descriptions up to num_banks_desc.
1388 */
1389struct ec_response_flash_info_1 {
1390	/* Version 0 fields; see above for description */
1391	uint32_t flash_size;
1392	uint32_t write_block_size;
1393	uint32_t erase_block_size;
1394	uint32_t protect_block_size;
1395
1396	/* Version 1 adds these fields: */
1397	uint32_t write_ideal_size;
1398	uint32_t flags;
1399} __ec_align4;
1400
1401struct ec_params_flash_info_2 {
1402	/* Number of banks to describe */
1403	uint16_t num_banks_desc;
1404	/* Reserved; set 0; ignore on read */
1405	uint8_t reserved[2];
1406} __ec_align4;
1407
1408struct ec_flash_bank {
1409	/* Number of sector is in this bank. */
1410	uint16_t count;
1411	/* Size in power of 2 of each sector (8 --> 256 bytes) */
1412	uint8_t size_exp;
1413	/* Minimal write size for the sectors in this bank */
1414	uint8_t write_size_exp;
1415	/* Erase size for the sectors in this bank */
1416	uint8_t erase_size_exp;
1417	/* Size for write protection, usually identical to erase size. */
1418	uint8_t protect_size_exp;
1419	/* Reserved; set 0; ignore on read */
1420	uint8_t reserved[2];
1421};
1422
1423struct ec_response_flash_info_2 {
1424	/* Total flash in the EC. */
1425	uint32_t flash_size;
1426	/* Flags; see EC_FLASH_INFO_* */
1427	uint32_t flags;
1428	/* Maximum size to use to send data to write to the EC. */
1429	uint32_t write_ideal_size;
1430	/* Number of banks present in the EC. */
1431	uint16_t num_banks_total;
1432	/* Number of banks described in banks array. */
1433	uint16_t num_banks_desc;
1434	struct ec_flash_bank banks[];
1435} __ec_align4;
1436
1437/*
1438 * Read flash
1439 *
1440 * Response is params.size bytes of data.
1441 */
1442#define EC_CMD_FLASH_READ 0x0011
1443
1444/**
1445 * struct ec_params_flash_read - Parameters for the flash read command.
1446 * @offset: Byte offset to read.
1447 * @size: Size to read in bytes.
1448 */
1449struct ec_params_flash_read {
1450	uint32_t offset;
1451	uint32_t size;
1452} __ec_align4;
1453
1454/* Write flash */
1455#define EC_CMD_FLASH_WRITE 0x0012
1456#define EC_VER_FLASH_WRITE 1
1457
1458/* Version 0 of the flash command supported only 64 bytes of data */
1459#define EC_FLASH_WRITE_VER0_SIZE 64
1460
1461/**
1462 * struct ec_params_flash_write - Parameters for the flash write command.
1463 * @offset: Byte offset to write.
1464 * @size: Size to write in bytes.
1465 */
1466struct ec_params_flash_write {
1467	uint32_t offset;
1468	uint32_t size;
1469	/* Followed by data to write */
1470} __ec_align4;
1471
1472/* Erase flash */
1473#define EC_CMD_FLASH_ERASE 0x0013
1474
1475/**
1476 * struct ec_params_flash_erase - Parameters for the flash erase command, v0.
1477 * @offset: Byte offset to erase.
1478 * @size: Size to erase in bytes.
1479 */
1480struct ec_params_flash_erase {
1481	uint32_t offset;
1482	uint32_t size;
1483} __ec_align4;
1484
1485/*
1486 * v1 add async erase:
1487 * subcommands can returns:
1488 * EC_RES_SUCCESS : erased (see ERASE_SECTOR_ASYNC case below).
1489 * EC_RES_INVALID_PARAM : offset/size are not aligned on a erase boundary.
1490 * EC_RES_ERROR : other errors.
1491 * EC_RES_BUSY : an existing erase operation is in progress.
1492 * EC_RES_ACCESS_DENIED: Trying to erase running image.
1493 *
1494 * When ERASE_SECTOR_ASYNC returns EC_RES_SUCCESS, the operation is just
1495 * properly queued. The user must call ERASE_GET_RESULT subcommand to get
1496 * the proper result.
1497 * When ERASE_GET_RESULT returns EC_RES_BUSY, the caller must wait and send
1498 * ERASE_GET_RESULT again to get the result of ERASE_SECTOR_ASYNC.
1499 * ERASE_GET_RESULT command may timeout on EC where flash access is not
1500 * permitted while erasing. (For instance, STM32F4).
1501 */
1502enum ec_flash_erase_cmd {
1503	FLASH_ERASE_SECTOR,     /* Erase and wait for result */
1504	FLASH_ERASE_SECTOR_ASYNC,  /* Erase and return immediately. */
1505	FLASH_ERASE_GET_RESULT,  /* Ask for last erase result */
1506};
1507
1508/**
1509 * struct ec_params_flash_erase_v1 - Parameters for the flash erase command, v1.
1510 * @cmd: One of ec_flash_erase_cmd.
1511 * @reserved: Pad byte; currently always contains 0.
1512 * @flag: No flags defined yet; set to 0.
1513 * @params: Same as v0 parameters.
1514 */
1515struct ec_params_flash_erase_v1 {
1516	uint8_t  cmd;
1517	uint8_t  reserved;
1518	uint16_t flag;
1519	struct ec_params_flash_erase params;
1520} __ec_align4;
1521
1522/*
1523 * Get/set flash protection.
1524 *
1525 * If mask!=0, sets/clear the requested bits of flags.  Depending on the
1526 * firmware write protect GPIO, not all flags will take effect immediately;
1527 * some flags require a subsequent hard reset to take effect.  Check the
1528 * returned flags bits to see what actually happened.
1529 *
1530 * If mask=0, simply returns the current flags state.
1531 */
1532#define EC_CMD_FLASH_PROTECT 0x0015
1533#define EC_VER_FLASH_PROTECT 1  /* Command version 1 */
1534
1535/* Flags for flash protection */
1536/* RO flash code protected when the EC boots */
1537#define EC_FLASH_PROTECT_RO_AT_BOOT         BIT(0)
1538/*
1539 * RO flash code protected now.  If this bit is set, at-boot status cannot
1540 * be changed.
1541 */
1542#define EC_FLASH_PROTECT_RO_NOW             BIT(1)
1543/* Entire flash code protected now, until reboot. */
1544#define EC_FLASH_PROTECT_ALL_NOW            BIT(2)
1545/* Flash write protect GPIO is asserted now */
1546#define EC_FLASH_PROTECT_GPIO_ASSERTED      BIT(3)
1547/* Error - at least one bank of flash is stuck locked, and cannot be unlocked */
1548#define EC_FLASH_PROTECT_ERROR_STUCK        BIT(4)
1549/*
1550 * Error - flash protection is in inconsistent state.  At least one bank of
1551 * flash which should be protected is not protected.  Usually fixed by
1552 * re-requesting the desired flags, or by a hard reset if that fails.
1553 */
1554#define EC_FLASH_PROTECT_ERROR_INCONSISTENT BIT(5)
1555/* Entire flash code protected when the EC boots */
1556#define EC_FLASH_PROTECT_ALL_AT_BOOT        BIT(6)
1557/* RW flash code protected when the EC boots */
1558#define EC_FLASH_PROTECT_RW_AT_BOOT         BIT(7)
1559/* RW flash code protected now. */
1560#define EC_FLASH_PROTECT_RW_NOW             BIT(8)
1561/* Rollback information flash region protected when the EC boots */
1562#define EC_FLASH_PROTECT_ROLLBACK_AT_BOOT   BIT(9)
1563/* Rollback information flash region protected now */
1564#define EC_FLASH_PROTECT_ROLLBACK_NOW       BIT(10)
1565
1566
1567/**
1568 * struct ec_params_flash_protect - Parameters for the flash protect command.
1569 * @mask: Bits in flags to apply.
1570 * @flags: New flags to apply.
1571 */
1572struct ec_params_flash_protect {
1573	uint32_t mask;
1574	uint32_t flags;
1575} __ec_align4;
1576
1577/**
1578 * struct ec_response_flash_protect - Response to the flash protect command.
1579 * @flags: Current value of flash protect flags.
1580 * @valid_flags: Flags which are valid on this platform. This allows the
1581 *               caller to distinguish between flags which aren't set vs. flags
1582 *               which can't be set on this platform.
1583 * @writable_flags: Flags which can be changed given the current protection
1584 *                  state.
1585 */
1586struct ec_response_flash_protect {
1587	uint32_t flags;
1588	uint32_t valid_flags;
1589	uint32_t writable_flags;
1590} __ec_align4;
1591
1592/*
1593 * Note: commands 0x14 - 0x19 version 0 were old commands to get/set flash
1594 * write protect.  These commands may be reused with version > 0.
1595 */
1596
1597/* Get the region offset/size */
1598#define EC_CMD_FLASH_REGION_INFO 0x0016
1599#define EC_VER_FLASH_REGION_INFO 1
1600
1601enum ec_flash_region {
1602	/* Region which holds read-only EC image */
1603	EC_FLASH_REGION_RO = 0,
1604	/*
1605	 * Region which holds active RW image. 'Active' is different from
1606	 * 'running'. Active means 'scheduled-to-run'. Since RO image always
1607	 * scheduled to run, active/non-active applies only to RW images (for
1608	 * the same reason 'update' applies only to RW images. It's a state of
1609	 * an image on a flash. Running image can be RO, RW_A, RW_B but active
1610	 * image can only be RW_A or RW_B. In recovery mode, an active RW image
1611	 * doesn't enter 'running' state but it's still active on a flash.
1612	 */
1613	EC_FLASH_REGION_ACTIVE,
1614	/*
1615	 * Region which should be write-protected in the factory (a superset of
1616	 * EC_FLASH_REGION_RO)
1617	 */
1618	EC_FLASH_REGION_WP_RO,
1619	/* Region which holds updatable (non-active) RW image */
1620	EC_FLASH_REGION_UPDATE,
1621	/* Number of regions */
1622	EC_FLASH_REGION_COUNT,
1623};
1624/*
1625 * 'RW' is vague if there are multiple RW images; we mean the active one,
1626 * so the old constant is deprecated.
1627 */
1628#define EC_FLASH_REGION_RW EC_FLASH_REGION_ACTIVE
1629
1630/**
1631 * struct ec_params_flash_region_info - Parameters for the flash region info
1632 *         command.
1633 * @region: Flash region; see EC_FLASH_REGION_*
1634 */
1635struct ec_params_flash_region_info {
1636	uint32_t region;
1637} __ec_align4;
1638
1639struct ec_response_flash_region_info {
1640	uint32_t offset;
1641	uint32_t size;
1642} __ec_align4;
1643
1644/* Read/write VbNvContext */
1645#define EC_CMD_VBNV_CONTEXT 0x0017
1646#define EC_VER_VBNV_CONTEXT 1
1647#define EC_VBNV_BLOCK_SIZE 16
1648
1649enum ec_vbnvcontext_op {
1650	EC_VBNV_CONTEXT_OP_READ,
1651	EC_VBNV_CONTEXT_OP_WRITE,
1652};
1653
1654struct ec_params_vbnvcontext {
1655	uint32_t op;
1656	uint8_t block[EC_VBNV_BLOCK_SIZE];
1657} __ec_align4;
1658
1659struct ec_response_vbnvcontext {
1660	uint8_t block[EC_VBNV_BLOCK_SIZE];
1661} __ec_align4;
1662
1663
1664/* Get SPI flash information */
1665#define EC_CMD_FLASH_SPI_INFO 0x0018
1666
1667struct ec_response_flash_spi_info {
1668	/* JEDEC info from command 0x9F (manufacturer, memory type, size) */
1669	uint8_t jedec[3];
1670
1671	/* Pad byte; currently always contains 0 */
1672	uint8_t reserved0;
1673
1674	/* Manufacturer / device ID from command 0x90 */
1675	uint8_t mfr_dev_id[2];
1676
1677	/* Status registers from command 0x05 and 0x35 */
1678	uint8_t sr1, sr2;
1679} __ec_align1;
1680
1681
1682/* Select flash during flash operations */
1683#define EC_CMD_FLASH_SELECT 0x0019
1684
1685/**
1686 * struct ec_params_flash_select - Parameters for the flash select command.
1687 * @select: 1 to select flash, 0 to deselect flash
1688 */
1689struct ec_params_flash_select {
1690	uint8_t select;
1691} __ec_align4;
1692
1693
1694/*****************************************************************************/
1695/* PWM commands */
1696
1697/* Get fan target RPM */
1698#define EC_CMD_PWM_GET_FAN_TARGET_RPM 0x0020
1699
1700struct ec_response_pwm_get_fan_rpm {
1701	uint32_t rpm;
1702} __ec_align4;
1703
1704/* Set target fan RPM */
1705#define EC_CMD_PWM_SET_FAN_TARGET_RPM 0x0021
1706
1707/* Version 0 of input params */
1708struct ec_params_pwm_set_fan_target_rpm_v0 {
1709	uint32_t rpm;
1710} __ec_align4;
1711
1712/* Version 1 of input params */
1713struct ec_params_pwm_set_fan_target_rpm_v1 {
1714	uint32_t rpm;
1715	uint8_t fan_idx;
1716} __ec_align_size1;
1717
1718/* Get keyboard backlight */
1719/* OBSOLETE - Use EC_CMD_PWM_SET_DUTY */
1720#define EC_CMD_PWM_GET_KEYBOARD_BACKLIGHT 0x0022
1721
1722struct ec_response_pwm_get_keyboard_backlight {
1723	uint8_t percent;
1724	uint8_t enabled;
1725} __ec_align1;
1726
1727/* Set keyboard backlight */
1728/* OBSOLETE - Use EC_CMD_PWM_SET_DUTY */
1729#define EC_CMD_PWM_SET_KEYBOARD_BACKLIGHT 0x0023
1730
1731struct ec_params_pwm_set_keyboard_backlight {
1732	uint8_t percent;
1733} __ec_align1;
1734
1735/* Set target fan PWM duty cycle */
1736#define EC_CMD_PWM_SET_FAN_DUTY 0x0024
1737
1738/* Version 0 of input params */
1739struct ec_params_pwm_set_fan_duty_v0 {
1740	uint32_t percent;
1741} __ec_align4;
1742
1743/* Version 1 of input params */
1744struct ec_params_pwm_set_fan_duty_v1 {
1745	uint32_t percent;
1746	uint8_t fan_idx;
1747} __ec_align_size1;
1748
1749#define EC_CMD_PWM_SET_DUTY 0x0025
1750/* 16 bit duty cycle, 0xffff = 100% */
1751#define EC_PWM_MAX_DUTY 0xffff
1752
1753enum ec_pwm_type {
1754	/* All types, indexed by board-specific enum pwm_channel */
1755	EC_PWM_TYPE_GENERIC = 0,
1756	/* Keyboard backlight */
1757	EC_PWM_TYPE_KB_LIGHT,
1758	/* Display backlight */
1759	EC_PWM_TYPE_DISPLAY_LIGHT,
1760	EC_PWM_TYPE_COUNT,
1761};
1762
1763struct ec_params_pwm_set_duty {
1764	uint16_t duty;     /* Duty cycle, EC_PWM_MAX_DUTY = 100% */
1765	uint8_t pwm_type;  /* ec_pwm_type */
1766	uint8_t index;     /* Type-specific index, or 0 if unique */
1767} __ec_align4;
1768
1769#define EC_CMD_PWM_GET_DUTY 0x0026
1770
1771struct ec_params_pwm_get_duty {
1772	uint8_t pwm_type;  /* ec_pwm_type */
1773	uint8_t index;     /* Type-specific index, or 0 if unique */
1774} __ec_align1;
1775
1776struct ec_response_pwm_get_duty {
1777	uint16_t duty;     /* Duty cycle, EC_PWM_MAX_DUTY = 100% */
1778} __ec_align2;
1779
1780/*****************************************************************************/
1781/*
1782 * Lightbar commands. This looks worse than it is. Since we only use one HOST
1783 * command to say "talk to the lightbar", we put the "and tell it to do X" part
1784 * into a subcommand. We'll make separate structs for subcommands with
1785 * different input args, so that we know how much to expect.
1786 */
1787#define EC_CMD_LIGHTBAR_CMD 0x0028
1788
1789struct rgb_s {
1790	uint8_t r, g, b;
1791} __ec_todo_unpacked;
1792
1793#define LB_BATTERY_LEVELS 4
1794
1795/*
1796 * List of tweakable parameters. NOTE: It's __packed so it can be sent in a
1797 * host command, but the alignment is the same regardless. Keep it that way.
1798 */
1799struct lightbar_params_v0 {
1800	/* Timing */
1801	int32_t google_ramp_up;
1802	int32_t google_ramp_down;
1803	int32_t s3s0_ramp_up;
1804	int32_t s0_tick_delay[2];		/* AC=0/1 */
1805	int32_t s0a_tick_delay[2];		/* AC=0/1 */
1806	int32_t s0s3_ramp_down;
1807	int32_t s3_sleep_for;
1808	int32_t s3_ramp_up;
1809	int32_t s3_ramp_down;
1810
1811	/* Oscillation */
1812	uint8_t new_s0;
1813	uint8_t osc_min[2];			/* AC=0/1 */
1814	uint8_t osc_max[2];			/* AC=0/1 */
1815	uint8_t w_ofs[2];			/* AC=0/1 */
1816
1817	/* Brightness limits based on the backlight and AC. */
1818	uint8_t bright_bl_off_fixed[2];		/* AC=0/1 */
1819	uint8_t bright_bl_on_min[2];		/* AC=0/1 */
1820	uint8_t bright_bl_on_max[2];		/* AC=0/1 */
1821
1822	/* Battery level thresholds */
1823	uint8_t battery_threshold[LB_BATTERY_LEVELS - 1];
1824
1825	/* Map [AC][battery_level] to color index */
1826	uint8_t s0_idx[2][LB_BATTERY_LEVELS];	/* AP is running */
1827	uint8_t s3_idx[2][LB_BATTERY_LEVELS];	/* AP is sleeping */
1828
1829	/* Color palette */
1830	struct rgb_s color[8];			/* 0-3 are Google colors */
1831} __ec_todo_packed;
1832
1833struct lightbar_params_v1 {
1834	/* Timing */
1835	int32_t google_ramp_up;
1836	int32_t google_ramp_down;
1837	int32_t s3s0_ramp_up;
1838	int32_t s0_tick_delay[2];		/* AC=0/1 */
1839	int32_t s0a_tick_delay[2];		/* AC=0/1 */
1840	int32_t s0s3_ramp_down;
1841	int32_t s3_sleep_for;
1842	int32_t s3_ramp_up;
1843	int32_t s3_ramp_down;
1844	int32_t s5_ramp_up;
1845	int32_t s5_ramp_down;
1846	int32_t tap_tick_delay;
1847	int32_t tap_gate_delay;
1848	int32_t tap_display_time;
1849
1850	/* Tap-for-battery params */
1851	uint8_t tap_pct_red;
1852	uint8_t tap_pct_green;
1853	uint8_t tap_seg_min_on;
1854	uint8_t tap_seg_max_on;
1855	uint8_t tap_seg_osc;
1856	uint8_t tap_idx[3];
1857
1858	/* Oscillation */
1859	uint8_t osc_min[2];			/* AC=0/1 */
1860	uint8_t osc_max[2];			/* AC=0/1 */
1861	uint8_t w_ofs[2];			/* AC=0/1 */
1862
1863	/* Brightness limits based on the backlight and AC. */
1864	uint8_t bright_bl_off_fixed[2];		/* AC=0/1 */
1865	uint8_t bright_bl_on_min[2];		/* AC=0/1 */
1866	uint8_t bright_bl_on_max[2];		/* AC=0/1 */
1867
1868	/* Battery level thresholds */
1869	uint8_t battery_threshold[LB_BATTERY_LEVELS - 1];
1870
1871	/* Map [AC][battery_level] to color index */
1872	uint8_t s0_idx[2][LB_BATTERY_LEVELS];	/* AP is running */
1873	uint8_t s3_idx[2][LB_BATTERY_LEVELS];	/* AP is sleeping */
1874
1875	/* s5: single color pulse on inhibited power-up */
1876	uint8_t s5_idx;
1877
1878	/* Color palette */
1879	struct rgb_s color[8];			/* 0-3 are Google colors */
1880} __ec_todo_packed;
1881
1882/* Lightbar command params v2
1883 * crbug.com/467716
1884 *
1885 * lightbar_parms_v1 was too big for i2c, therefore in v2, we split them up by
1886 * logical groups to make it more manageable ( < 120 bytes).
1887 *
1888 * NOTE: Each of these groups must be less than 120 bytes.
1889 */
1890
1891struct lightbar_params_v2_timing {
1892	/* Timing */
1893	int32_t google_ramp_up;
1894	int32_t google_ramp_down;
1895	int32_t s3s0_ramp_up;
1896	int32_t s0_tick_delay[2];		/* AC=0/1 */
1897	int32_t s0a_tick_delay[2];		/* AC=0/1 */
1898	int32_t s0s3_ramp_down;
1899	int32_t s3_sleep_for;
1900	int32_t s3_ramp_up;
1901	int32_t s3_ramp_down;
1902	int32_t s5_ramp_up;
1903	int32_t s5_ramp_down;
1904	int32_t tap_tick_delay;
1905	int32_t tap_gate_delay;
1906	int32_t tap_display_time;
1907} __ec_todo_packed;
1908
1909struct lightbar_params_v2_tap {
1910	/* Tap-for-battery params */
1911	uint8_t tap_pct_red;
1912	uint8_t tap_pct_green;
1913	uint8_t tap_seg_min_on;
1914	uint8_t tap_seg_max_on;
1915	uint8_t tap_seg_osc;
1916	uint8_t tap_idx[3];
1917} __ec_todo_packed;
1918
1919struct lightbar_params_v2_oscillation {
1920	/* Oscillation */
1921	uint8_t osc_min[2];			/* AC=0/1 */
1922	uint8_t osc_max[2];			/* AC=0/1 */
1923	uint8_t w_ofs[2];			/* AC=0/1 */
1924} __ec_todo_packed;
1925
1926struct lightbar_params_v2_brightness {
1927	/* Brightness limits based on the backlight and AC. */
1928	uint8_t bright_bl_off_fixed[2];		/* AC=0/1 */
1929	uint8_t bright_bl_on_min[2];		/* AC=0/1 */
1930	uint8_t bright_bl_on_max[2];		/* AC=0/1 */
1931} __ec_todo_packed;
1932
1933struct lightbar_params_v2_thresholds {
1934	/* Battery level thresholds */
1935	uint8_t battery_threshold[LB_BATTERY_LEVELS - 1];
1936} __ec_todo_packed;
1937
1938struct lightbar_params_v2_colors {
1939	/* Map [AC][battery_level] to color index */
1940	uint8_t s0_idx[2][LB_BATTERY_LEVELS];	/* AP is running */
1941	uint8_t s3_idx[2][LB_BATTERY_LEVELS];	/* AP is sleeping */
1942
1943	/* s5: single color pulse on inhibited power-up */
1944	uint8_t s5_idx;
1945
1946	/* Color palette */
1947	struct rgb_s color[8];			/* 0-3 are Google colors */
1948} __ec_todo_packed;
1949
1950/* Lightbar program. */
1951#define EC_LB_PROG_LEN 192
1952struct lightbar_program {
1953	uint8_t size;
1954	uint8_t data[EC_LB_PROG_LEN];
1955} __ec_todo_unpacked;
1956
1957struct ec_params_lightbar {
1958	uint8_t cmd;		      /* Command (see enum lightbar_command) */
1959	union {
1960		/*
1961		 * The following commands have no args:
1962		 *
1963		 * dump, off, on, init, get_seq, get_params_v0, get_params_v1,
1964		 * version, get_brightness, get_demo, suspend, resume,
1965		 * get_params_v2_timing, get_params_v2_tap, get_params_v2_osc,
1966		 * get_params_v2_bright, get_params_v2_thlds,
1967		 * get_params_v2_colors
1968		 *
1969		 * Don't use an empty struct, because C++ hates that.
1970		 */
1971
1972		struct __ec_todo_unpacked {
1973			uint8_t num;
1974		} set_brightness, seq, demo;
1975
1976		struct __ec_todo_unpacked {
1977			uint8_t ctrl, reg, value;
1978		} reg;
1979
1980		struct __ec_todo_unpacked {
1981			uint8_t led, red, green, blue;
1982		} set_rgb;
1983
1984		struct __ec_todo_unpacked {
1985			uint8_t led;
1986		} get_rgb;
1987
1988		struct __ec_todo_unpacked {
1989			uint8_t enable;
1990		} manual_suspend_ctrl;
1991
1992		struct lightbar_params_v0 set_params_v0;
1993		struct lightbar_params_v1 set_params_v1;
1994
1995		struct lightbar_params_v2_timing set_v2par_timing;
1996		struct lightbar_params_v2_tap set_v2par_tap;
1997		struct lightbar_params_v2_oscillation set_v2par_osc;
1998		struct lightbar_params_v2_brightness set_v2par_bright;
1999		struct lightbar_params_v2_thresholds set_v2par_thlds;
2000		struct lightbar_params_v2_colors set_v2par_colors;
2001
2002		struct lightbar_program set_program;
2003	};
2004} __ec_todo_packed;
2005
2006struct ec_response_lightbar {
2007	union {
2008		struct __ec_todo_unpacked {
2009			struct __ec_todo_unpacked {
2010				uint8_t reg;
2011				uint8_t ic0;
2012				uint8_t ic1;
2013			} vals[23];
2014		} dump;
2015
2016		struct __ec_todo_unpacked {
2017			uint8_t num;
2018		} get_seq, get_brightness, get_demo;
2019
2020		struct lightbar_params_v0 get_params_v0;
2021		struct lightbar_params_v1 get_params_v1;
2022
2023
2024		struct lightbar_params_v2_timing get_params_v2_timing;
2025		struct lightbar_params_v2_tap get_params_v2_tap;
2026		struct lightbar_params_v2_oscillation get_params_v2_osc;
2027		struct lightbar_params_v2_brightness get_params_v2_bright;
2028		struct lightbar_params_v2_thresholds get_params_v2_thlds;
2029		struct lightbar_params_v2_colors get_params_v2_colors;
2030
2031		struct __ec_todo_unpacked {
2032			uint32_t num;
2033			uint32_t flags;
2034		} version;
2035
2036		struct __ec_todo_unpacked {
2037			uint8_t red, green, blue;
2038		} get_rgb;
2039
2040		/*
2041		 * The following commands have no response:
2042		 *
2043		 * off, on, init, set_brightness, seq, reg, set_rgb, demo,
2044		 * set_params_v0, set_params_v1, set_program,
2045		 * manual_suspend_ctrl, suspend, resume, set_v2par_timing,
2046		 * set_v2par_tap, set_v2par_osc, set_v2par_bright,
2047		 * set_v2par_thlds, set_v2par_colors
2048		 */
2049	};
2050} __ec_todo_packed;
2051
2052/* Lightbar commands */
2053enum lightbar_command {
2054	LIGHTBAR_CMD_DUMP = 0,
2055	LIGHTBAR_CMD_OFF = 1,
2056	LIGHTBAR_CMD_ON = 2,
2057	LIGHTBAR_CMD_INIT = 3,
2058	LIGHTBAR_CMD_SET_BRIGHTNESS = 4,
2059	LIGHTBAR_CMD_SEQ = 5,
2060	LIGHTBAR_CMD_REG = 6,
2061	LIGHTBAR_CMD_SET_RGB = 7,
2062	LIGHTBAR_CMD_GET_SEQ = 8,
2063	LIGHTBAR_CMD_DEMO = 9,
2064	LIGHTBAR_CMD_GET_PARAMS_V0 = 10,
2065	LIGHTBAR_CMD_SET_PARAMS_V0 = 11,
2066	LIGHTBAR_CMD_VERSION = 12,
2067	LIGHTBAR_CMD_GET_BRIGHTNESS = 13,
2068	LIGHTBAR_CMD_GET_RGB = 14,
2069	LIGHTBAR_CMD_GET_DEMO = 15,
2070	LIGHTBAR_CMD_GET_PARAMS_V1 = 16,
2071	LIGHTBAR_CMD_SET_PARAMS_V1 = 17,
2072	LIGHTBAR_CMD_SET_PROGRAM = 18,
2073	LIGHTBAR_CMD_MANUAL_SUSPEND_CTRL = 19,
2074	LIGHTBAR_CMD_SUSPEND = 20,
2075	LIGHTBAR_CMD_RESUME = 21,
2076	LIGHTBAR_CMD_GET_PARAMS_V2_TIMING = 22,
2077	LIGHTBAR_CMD_SET_PARAMS_V2_TIMING = 23,
2078	LIGHTBAR_CMD_GET_PARAMS_V2_TAP = 24,
2079	LIGHTBAR_CMD_SET_PARAMS_V2_TAP = 25,
2080	LIGHTBAR_CMD_GET_PARAMS_V2_OSCILLATION = 26,
2081	LIGHTBAR_CMD_SET_PARAMS_V2_OSCILLATION = 27,
2082	LIGHTBAR_CMD_GET_PARAMS_V2_BRIGHTNESS = 28,
2083	LIGHTBAR_CMD_SET_PARAMS_V2_BRIGHTNESS = 29,
2084	LIGHTBAR_CMD_GET_PARAMS_V2_THRESHOLDS = 30,
2085	LIGHTBAR_CMD_SET_PARAMS_V2_THRESHOLDS = 31,
2086	LIGHTBAR_CMD_GET_PARAMS_V2_COLORS = 32,
2087	LIGHTBAR_CMD_SET_PARAMS_V2_COLORS = 33,
2088	LIGHTBAR_NUM_CMDS
2089};
2090
2091/*****************************************************************************/
2092/* LED control commands */
2093
2094#define EC_CMD_LED_CONTROL 0x0029
2095
2096enum ec_led_id {
2097	/* LED to indicate battery state of charge */
2098	EC_LED_ID_BATTERY_LED = 0,
2099	/*
2100	 * LED to indicate system power state (on or in suspend).
2101	 * May be on power button or on C-panel.
2102	 */
2103	EC_LED_ID_POWER_LED,
2104	/* LED on power adapter or its plug */
2105	EC_LED_ID_ADAPTER_LED,
2106	/* LED to indicate left side */
2107	EC_LED_ID_LEFT_LED,
2108	/* LED to indicate right side */
2109	EC_LED_ID_RIGHT_LED,
2110	/* LED to indicate recovery mode with HW_REINIT */
2111	EC_LED_ID_RECOVERY_HW_REINIT_LED,
2112	/* LED to indicate sysrq debug mode. */
2113	EC_LED_ID_SYSRQ_DEBUG_LED,
2114
2115	EC_LED_ID_COUNT
2116};
2117
2118/* LED control flags */
2119#define EC_LED_FLAGS_QUERY BIT(0) /* Query LED capability only */
2120#define EC_LED_FLAGS_AUTO  BIT(1) /* Switch LED back to automatic control */
2121
2122enum ec_led_colors {
2123	EC_LED_COLOR_RED = 0,
2124	EC_LED_COLOR_GREEN,
2125	EC_LED_COLOR_BLUE,
2126	EC_LED_COLOR_YELLOW,
2127	EC_LED_COLOR_WHITE,
2128	EC_LED_COLOR_AMBER,
2129
2130	EC_LED_COLOR_COUNT
2131};
2132
2133struct ec_params_led_control {
2134	uint8_t led_id;     /* Which LED to control */
2135	uint8_t flags;      /* Control flags */
2136
2137	uint8_t brightness[EC_LED_COLOR_COUNT];
2138} __ec_align1;
2139
2140struct ec_response_led_control {
2141	/*
2142	 * Available brightness value range.
2143	 *
2144	 * Range 0 means color channel not present.
2145	 * Range 1 means on/off control.
2146	 * Other values means the LED is control by PWM.
2147	 */
2148	uint8_t brightness_range[EC_LED_COLOR_COUNT];
2149} __ec_align1;
2150
2151/*****************************************************************************/
2152/* Verified boot commands */
2153
2154/*
2155 * Note: command code 0x29 version 0 was VBOOT_CMD in Link EVT; it may be
2156 * reused for other purposes with version > 0.
2157 */
2158
2159/* Verified boot hash command */
2160#define EC_CMD_VBOOT_HASH 0x002A
2161
2162struct ec_params_vboot_hash {
2163	uint8_t cmd;             /* enum ec_vboot_hash_cmd */
2164	uint8_t hash_type;       /* enum ec_vboot_hash_type */
2165	uint8_t nonce_size;      /* Nonce size; may be 0 */
2166	uint8_t reserved0;       /* Reserved; set 0 */
2167	uint32_t offset;         /* Offset in flash to hash */
2168	uint32_t size;           /* Number of bytes to hash */
2169	uint8_t nonce_data[64];  /* Nonce data; ignored if nonce_size=0 */
2170} __ec_align4;
2171
2172struct ec_response_vboot_hash {
2173	uint8_t status;          /* enum ec_vboot_hash_status */
2174	uint8_t hash_type;       /* enum ec_vboot_hash_type */
2175	uint8_t digest_size;     /* Size of hash digest in bytes */
2176	uint8_t reserved0;       /* Ignore; will be 0 */
2177	uint32_t offset;         /* Offset in flash which was hashed */
2178	uint32_t size;           /* Number of bytes hashed */
2179	uint8_t hash_digest[64]; /* Hash digest data */
2180} __ec_align4;
2181
2182enum ec_vboot_hash_cmd {
2183	EC_VBOOT_HASH_GET = 0,       /* Get current hash status */
2184	EC_VBOOT_HASH_ABORT = 1,     /* Abort calculating current hash */
2185	EC_VBOOT_HASH_START = 2,     /* Start computing a new hash */
2186	EC_VBOOT_HASH_RECALC = 3,    /* Synchronously compute a new hash */
2187};
2188
2189enum ec_vboot_hash_type {
2190	EC_VBOOT_HASH_TYPE_SHA256 = 0, /* SHA-256 */
2191};
2192
2193enum ec_vboot_hash_status {
2194	EC_VBOOT_HASH_STATUS_NONE = 0, /* No hash (not started, or aborted) */
2195	EC_VBOOT_HASH_STATUS_DONE = 1, /* Finished computing a hash */
2196	EC_VBOOT_HASH_STATUS_BUSY = 2, /* Busy computing a hash */
2197};
2198
2199/*
2200 * Special values for offset for EC_VBOOT_HASH_START and EC_VBOOT_HASH_RECALC.
2201 * If one of these is specified, the EC will automatically update offset and
2202 * size to the correct values for the specified image (RO or RW).
2203 */
2204#define EC_VBOOT_HASH_OFFSET_RO		0xfffffffe
2205#define EC_VBOOT_HASH_OFFSET_ACTIVE	0xfffffffd
2206#define EC_VBOOT_HASH_OFFSET_UPDATE	0xfffffffc
2207
2208/*
2209 * 'RW' is vague if there are multiple RW images; we mean the active one,
2210 * so the old constant is deprecated.
2211 */
2212#define EC_VBOOT_HASH_OFFSET_RW EC_VBOOT_HASH_OFFSET_ACTIVE
2213
2214/*****************************************************************************/
2215/*
2216 * Motion sense commands. We'll make separate structs for sub-commands with
2217 * different input args, so that we know how much to expect.
2218 */
2219#define EC_CMD_MOTION_SENSE_CMD 0x002B
2220
2221/* Motion sense commands */
2222enum motionsense_command {
2223	/*
2224	 * Dump command returns all motion sensor data including motion sense
2225	 * module flags and individual sensor flags.
2226	 */
2227	MOTIONSENSE_CMD_DUMP = 0,
2228
2229	/*
2230	 * Info command returns data describing the details of a given sensor,
2231	 * including enum motionsensor_type, enum motionsensor_location, and
2232	 * enum motionsensor_chip.
2233	 */
2234	MOTIONSENSE_CMD_INFO = 1,
2235
2236	/*
2237	 * EC Rate command is a setter/getter command for the EC sampling rate
2238	 * in milliseconds.
2239	 * It is per sensor, the EC run sample task  at the minimum of all
2240	 * sensors EC_RATE.
2241	 * For sensors without hardware FIFO, EC_RATE should be equals to 1/ODR
2242	 * to collect all the sensor samples.
2243	 * For sensor with hardware FIFO, EC_RATE is used as the maximal delay
2244	 * to process of all motion sensors in milliseconds.
2245	 */
2246	MOTIONSENSE_CMD_EC_RATE = 2,
2247
2248	/*
2249	 * Sensor ODR command is a setter/getter command for the output data
2250	 * rate of a specific motion sensor in millihertz.
2251	 */
2252	MOTIONSENSE_CMD_SENSOR_ODR = 3,
2253
2254	/*
2255	 * Sensor range command is a setter/getter command for the range of
2256	 * a specified motion sensor in +/-G's or +/- deg/s.
2257	 */
2258	MOTIONSENSE_CMD_SENSOR_RANGE = 4,
2259
2260	/*
2261	 * Setter/getter command for the keyboard wake angle. When the lid
2262	 * angle is greater than this value, keyboard wake is disabled in S3,
2263	 * and when the lid angle goes less than this value, keyboard wake is
2264	 * enabled. Note, the lid angle measurement is an approximate,
2265	 * un-calibrated value, hence the wake angle isn't exact.
2266	 */
2267	MOTIONSENSE_CMD_KB_WAKE_ANGLE = 5,
2268
2269	/*
2270	 * Returns a single sensor data.
2271	 */
2272	MOTIONSENSE_CMD_DATA = 6,
2273
2274	/*
2275	 * Return sensor fifo info.
2276	 */
2277	MOTIONSENSE_CMD_FIFO_INFO = 7,
2278
2279	/*
2280	 * Insert a flush element in the fifo and return sensor fifo info.
2281	 * The host can use that element to synchronize its operation.
2282	 */
2283	MOTIONSENSE_CMD_FIFO_FLUSH = 8,
2284
2285	/*
2286	 * Return a portion of the fifo.
2287	 */
2288	MOTIONSENSE_CMD_FIFO_READ = 9,
2289
2290	/*
2291	 * Perform low level calibration.
2292	 * On sensors that support it, ask to do offset calibration.
2293	 */
2294	MOTIONSENSE_CMD_PERFORM_CALIB = 10,
2295
2296	/*
2297	 * Sensor Offset command is a setter/getter command for the offset
2298	 * used for calibration.
2299	 * The offsets can be calculated by the host, or via
2300	 * PERFORM_CALIB command.
2301	 */
2302	MOTIONSENSE_CMD_SENSOR_OFFSET = 11,
2303
2304	/*
2305	 * List available activities for a MOTION sensor.
2306	 * Indicates if they are enabled or disabled.
2307	 */
2308	MOTIONSENSE_CMD_LIST_ACTIVITIES = 12,
2309
2310	/*
2311	 * Activity management
2312	 * Enable/Disable activity recognition.
2313	 */
2314	MOTIONSENSE_CMD_SET_ACTIVITY = 13,
2315
2316	/*
2317	 * Lid Angle
2318	 */
2319	MOTIONSENSE_CMD_LID_ANGLE = 14,
2320
2321	/*
2322	 * Allow the FIFO to trigger interrupt via MKBP events.
2323	 * By default the FIFO does not send interrupt to process the FIFO
2324	 * until the AP is ready or it is coming from a wakeup sensor.
2325	 */
2326	MOTIONSENSE_CMD_FIFO_INT_ENABLE = 15,
2327
2328	/*
2329	 * Spoof the readings of the sensors.  The spoofed readings can be set
2330	 * to arbitrary values, or will lock to the last read actual values.
2331	 */
2332	MOTIONSENSE_CMD_SPOOF = 16,
2333
2334	/* Set lid angle for tablet mode detection. */
2335	MOTIONSENSE_CMD_TABLET_MODE_LID_ANGLE = 17,
2336
2337	/*
2338	 * Sensor Scale command is a setter/getter command for the calibration
2339	 * scale.
2340	 */
2341	MOTIONSENSE_CMD_SENSOR_SCALE = 18,
2342
2343	/* Number of motionsense sub-commands. */
2344	MOTIONSENSE_NUM_CMDS
2345};
2346
2347/* List of motion sensor types. */
2348enum motionsensor_type {
2349	MOTIONSENSE_TYPE_ACCEL = 0,
2350	MOTIONSENSE_TYPE_GYRO = 1,
2351	MOTIONSENSE_TYPE_MAG = 2,
2352	MOTIONSENSE_TYPE_PROX = 3,
2353	MOTIONSENSE_TYPE_LIGHT = 4,
2354	MOTIONSENSE_TYPE_ACTIVITY = 5,
2355	MOTIONSENSE_TYPE_BARO = 6,
2356	MOTIONSENSE_TYPE_SYNC = 7,
2357	MOTIONSENSE_TYPE_MAX,
2358};
2359
2360/* List of motion sensor locations. */
2361enum motionsensor_location {
2362	MOTIONSENSE_LOC_BASE = 0,
2363	MOTIONSENSE_LOC_LID = 1,
2364	MOTIONSENSE_LOC_CAMERA = 2,
2365	MOTIONSENSE_LOC_MAX,
2366};
2367
2368/* List of motion sensor chips. */
2369enum motionsensor_chip {
2370	MOTIONSENSE_CHIP_KXCJ9 = 0,
2371	MOTIONSENSE_CHIP_LSM6DS0 = 1,
2372	MOTIONSENSE_CHIP_BMI160 = 2,
2373	MOTIONSENSE_CHIP_SI1141 = 3,
2374	MOTIONSENSE_CHIP_SI1142 = 4,
2375	MOTIONSENSE_CHIP_SI1143 = 5,
2376	MOTIONSENSE_CHIP_KX022 = 6,
2377	MOTIONSENSE_CHIP_L3GD20H = 7,
2378	MOTIONSENSE_CHIP_BMA255 = 8,
2379	MOTIONSENSE_CHIP_BMP280 = 9,
2380	MOTIONSENSE_CHIP_OPT3001 = 10,
2381	MOTIONSENSE_CHIP_BH1730 = 11,
2382	MOTIONSENSE_CHIP_GPIO = 12,
2383	MOTIONSENSE_CHIP_LIS2DH = 13,
2384	MOTIONSENSE_CHIP_LSM6DSM = 14,
2385	MOTIONSENSE_CHIP_LIS2DE = 15,
2386	MOTIONSENSE_CHIP_LIS2MDL = 16,
2387	MOTIONSENSE_CHIP_LSM6DS3 = 17,
2388	MOTIONSENSE_CHIP_LSM6DSO = 18,
2389	MOTIONSENSE_CHIP_LNG2DM = 19,
2390	MOTIONSENSE_CHIP_MAX,
2391};
2392
2393/* List of orientation positions */
2394enum motionsensor_orientation {
2395	MOTIONSENSE_ORIENTATION_LANDSCAPE = 0,
2396	MOTIONSENSE_ORIENTATION_PORTRAIT = 1,
2397	MOTIONSENSE_ORIENTATION_UPSIDE_DOWN_PORTRAIT = 2,
2398	MOTIONSENSE_ORIENTATION_UPSIDE_DOWN_LANDSCAPE = 3,
2399	MOTIONSENSE_ORIENTATION_UNKNOWN = 4,
2400};
2401
2402struct ec_response_motion_sensor_data {
2403	/* Flags for each sensor. */
2404	uint8_t flags;
2405	/* Sensor number the data comes from. */
2406	uint8_t sensor_num;
2407	/* Each sensor is up to 3-axis. */
2408	union {
2409		int16_t             data[3];
2410		struct __ec_todo_packed {
2411			uint16_t    reserved;
2412			uint32_t    timestamp;
2413		};
2414		struct __ec_todo_unpacked {
2415			uint8_t     activity; /* motionsensor_activity */
2416			uint8_t     state;
2417			int16_t     add_info[2];
2418		};
2419	};
2420} __ec_todo_packed;
2421
2422/* Note: used in ec_response_get_next_data */
2423struct ec_response_motion_sense_fifo_info {
2424	/* Size of the fifo */
2425	uint16_t size;
2426	/* Amount of space used in the fifo */
2427	uint16_t count;
2428	/* Timestamp recorded in us.
2429	 * aka accurate timestamp when host event was triggered.
2430	 */
2431	uint32_t timestamp;
2432	/* Total amount of vector lost */
2433	uint16_t total_lost;
2434	/* Lost events since the last fifo_info, per sensors */
2435	uint16_t lost[];
2436} __ec_todo_packed;
2437
2438struct ec_response_motion_sense_fifo_data {
2439	uint32_t number_data;
2440	struct ec_response_motion_sensor_data data[];
2441} __ec_todo_packed;
2442
2443/* List supported activity recognition */
2444enum motionsensor_activity {
2445	MOTIONSENSE_ACTIVITY_RESERVED = 0,
2446	MOTIONSENSE_ACTIVITY_SIG_MOTION = 1,
2447	MOTIONSENSE_ACTIVITY_DOUBLE_TAP = 2,
2448	MOTIONSENSE_ACTIVITY_ORIENTATION = 3,
2449};
2450
2451struct ec_motion_sense_activity {
2452	uint8_t sensor_num;
2453	uint8_t activity; /* one of enum motionsensor_activity */
2454	uint8_t enable;   /* 1: enable, 0: disable */
2455	uint8_t reserved;
2456	uint16_t parameters[3]; /* activity dependent parameters */
2457} __ec_todo_unpacked;
2458
2459/* Module flag masks used for the dump sub-command. */
2460#define MOTIONSENSE_MODULE_FLAG_ACTIVE BIT(0)
2461
2462/* Sensor flag masks used for the dump sub-command. */
2463#define MOTIONSENSE_SENSOR_FLAG_PRESENT BIT(0)
2464
2465/*
2466 * Flush entry for synchronization.
2467 * data contains time stamp
2468 */
2469#define MOTIONSENSE_SENSOR_FLAG_FLUSH BIT(0)
2470#define MOTIONSENSE_SENSOR_FLAG_TIMESTAMP BIT(1)
2471#define MOTIONSENSE_SENSOR_FLAG_WAKEUP BIT(2)
2472#define MOTIONSENSE_SENSOR_FLAG_TABLET_MODE BIT(3)
2473#define MOTIONSENSE_SENSOR_FLAG_ODR BIT(4)
2474
2475/*
2476 * Send this value for the data element to only perform a read. If you
2477 * send any other value, the EC will interpret it as data to set and will
2478 * return the actual value set.
2479 */
2480#define EC_MOTION_SENSE_NO_VALUE -1
2481
2482#define EC_MOTION_SENSE_INVALID_CALIB_TEMP 0x8000
2483
2484/* MOTIONSENSE_CMD_SENSOR_OFFSET subcommand flag */
2485/* Set Calibration information */
2486#define MOTION_SENSE_SET_OFFSET BIT(0)
2487
2488/* Default Scale value, factor 1. */
2489#define MOTION_SENSE_DEFAULT_SCALE BIT(15)
2490
2491#define LID_ANGLE_UNRELIABLE 500
2492
2493enum motionsense_spoof_mode {
2494	/* Disable spoof mode. */
2495	MOTIONSENSE_SPOOF_MODE_DISABLE = 0,
2496
2497	/* Enable spoof mode, but use provided component values. */
2498	MOTIONSENSE_SPOOF_MODE_CUSTOM,
2499
2500	/* Enable spoof mode, but use the current sensor values. */
2501	MOTIONSENSE_SPOOF_MODE_LOCK_CURRENT,
2502
2503	/* Query the current spoof mode status for the sensor. */
2504	MOTIONSENSE_SPOOF_MODE_QUERY,
2505};
2506
2507struct ec_params_motion_sense {
2508	uint8_t cmd;
2509	union {
2510		/* Used for MOTIONSENSE_CMD_DUMP. */
2511		struct __ec_todo_unpacked {
2512			/*
2513			 * Maximal number of sensor the host is expecting.
2514			 * 0 means the host is only interested in the number
2515			 * of sensors controlled by the EC.
2516			 */
2517			uint8_t max_sensor_count;
2518		} dump;
2519
2520		/*
2521		 * Used for MOTIONSENSE_CMD_KB_WAKE_ANGLE.
2522		 */
2523		struct __ec_todo_unpacked {
2524			/* Data to set or EC_MOTION_SENSE_NO_VALUE to read.
2525			 * kb_wake_angle: angle to wakup AP.
2526			 */
2527			int16_t data;
2528		} kb_wake_angle;
2529
2530		/*
2531		 * Used for MOTIONSENSE_CMD_INFO, MOTIONSENSE_CMD_DATA
2532		 * and MOTIONSENSE_CMD_PERFORM_CALIB.
2533		 */
2534		struct __ec_todo_unpacked {
2535			uint8_t sensor_num;
2536		} info, info_3, data, fifo_flush, perform_calib,
2537				list_activities;
2538
2539		/*
2540		 * Used for MOTIONSENSE_CMD_EC_RATE, MOTIONSENSE_CMD_SENSOR_ODR
2541		 * and MOTIONSENSE_CMD_SENSOR_RANGE.
2542		 */
2543		struct __ec_todo_unpacked {
2544			uint8_t sensor_num;
2545
2546			/* Rounding flag, true for round-up, false for down. */
2547			uint8_t roundup;
2548
2549			uint16_t reserved;
2550
2551			/* Data to set or EC_MOTION_SENSE_NO_VALUE to read. */
2552			int32_t data;
2553		} ec_rate, sensor_odr, sensor_range;
2554
2555		/* Used for MOTIONSENSE_CMD_SENSOR_OFFSET */
2556		struct __ec_todo_packed {
2557			uint8_t sensor_num;
2558
2559			/*
2560			 * bit 0: If set (MOTION_SENSE_SET_OFFSET), set
2561			 * the calibration information in the EC.
2562			 * If unset, just retrieve calibration information.
2563			 */
2564			uint16_t flags;
2565
2566			/*
2567			 * Temperature at calibration, in units of 0.01 C
2568			 * 0x8000: invalid / unknown.
2569			 * 0x0: 0C
2570			 * 0x7fff: +327.67C
2571			 */
2572			int16_t temp;
2573
2574			/*
2575			 * Offset for calibration.
2576			 * Unit:
2577			 * Accelerometer: 1/1024 g
2578			 * Gyro:          1/1024 deg/s
2579			 * Compass:       1/16 uT
2580			 */
2581			int16_t offset[3];
2582		} sensor_offset;
2583
2584		/* Used for MOTIONSENSE_CMD_SENSOR_SCALE */
2585		struct __ec_todo_packed {
2586			uint8_t sensor_num;
2587
2588			/*
2589			 * bit 0: If set (MOTION_SENSE_SET_OFFSET), set
2590			 * the calibration information in the EC.
2591			 * If unset, just retrieve calibration information.
2592			 */
2593			uint16_t flags;
2594
2595			/*
2596			 * Temperature at calibration, in units of 0.01 C
2597			 * 0x8000: invalid / unknown.
2598			 * 0x0: 0C
2599			 * 0x7fff: +327.67C
2600			 */
2601			int16_t temp;
2602
2603			/*
2604			 * Scale for calibration:
2605			 * By default scale is 1, it is encoded on 16bits:
2606			 * 1 = BIT(15)
2607			 * ~2 = 0xFFFF
2608			 * ~0 = 0.
2609			 */
2610			uint16_t scale[3];
2611		} sensor_scale;
2612
2613
2614		/* Used for MOTIONSENSE_CMD_FIFO_INFO */
2615		/* (no params) */
2616
2617		/* Used for MOTIONSENSE_CMD_FIFO_READ */
2618		struct __ec_todo_unpacked {
2619			/*
2620			 * Number of expected vector to return.
2621			 * EC may return less or 0 if none available.
2622			 */
2623			uint32_t max_data_vector;
2624		} fifo_read;
2625
2626		struct ec_motion_sense_activity set_activity;
2627
2628		/* Used for MOTIONSENSE_CMD_LID_ANGLE */
2629		/* (no params) */
2630
2631		/* Used for MOTIONSENSE_CMD_FIFO_INT_ENABLE */
2632		struct __ec_todo_unpacked {
2633			/*
2634			 * 1: enable, 0 disable fifo,
2635			 * EC_MOTION_SENSE_NO_VALUE return value.
2636			 */
2637			int8_t enable;
2638		} fifo_int_enable;
2639
2640		/* Used for MOTIONSENSE_CMD_SPOOF */
2641		struct __ec_todo_packed {
2642			uint8_t sensor_id;
2643
2644			/* See enum motionsense_spoof_mode. */
2645			uint8_t spoof_enable;
2646
2647			/* Ignored, used for alignment. */
2648			uint8_t reserved;
2649
2650			/* Individual component values to spoof. */
2651			int16_t components[3];
2652		} spoof;
2653
2654		/* Used for MOTIONSENSE_CMD_TABLET_MODE_LID_ANGLE. */
2655		struct __ec_todo_unpacked {
2656			/*
2657			 * Lid angle threshold for switching between tablet and
2658			 * clamshell mode.
2659			 */
2660			int16_t lid_angle;
2661
2662			/*
2663			 * Hysteresis degree to prevent fluctuations between
2664			 * clamshell and tablet mode if lid angle keeps
2665			 * changing around the threshold. Lid motion driver will
2666			 * use lid_angle + hys_degree to trigger tablet mode and
2667			 * lid_angle - hys_degree to trigger clamshell mode.
2668			 */
2669			int16_t hys_degree;
2670		} tablet_mode_threshold;
2671	};
2672} __ec_todo_packed;
2673
2674struct ec_response_motion_sense {
2675	union {
2676		/* Used for MOTIONSENSE_CMD_DUMP */
2677		struct __ec_todo_unpacked {
2678			/* Flags representing the motion sensor module. */
2679			uint8_t module_flags;
2680
2681			/* Number of sensors managed directly by the EC. */
2682			uint8_t sensor_count;
2683
2684			/*
2685			 * Sensor data is truncated if response_max is too small
2686			 * for holding all the data.
2687			 */
2688			struct ec_response_motion_sensor_data sensor[0];
2689		} dump;
2690
2691		/* Used for MOTIONSENSE_CMD_INFO. */
2692		struct __ec_todo_unpacked {
2693			/* Should be element of enum motionsensor_type. */
2694			uint8_t type;
2695
2696			/* Should be element of enum motionsensor_location. */
2697			uint8_t location;
2698
2699			/* Should be element of enum motionsensor_chip. */
2700			uint8_t chip;
2701		} info;
2702
2703		/* Used for MOTIONSENSE_CMD_INFO version 3 */
2704		struct __ec_todo_unpacked {
2705			/* Should be element of enum motionsensor_type. */
2706			uint8_t type;
2707
2708			/* Should be element of enum motionsensor_location. */
2709			uint8_t location;
2710
2711			/* Should be element of enum motionsensor_chip. */
2712			uint8_t chip;
2713
2714			/* Minimum sensor sampling frequency */
2715			uint32_t min_frequency;
2716
2717			/* Maximum sensor sampling frequency */
2718			uint32_t max_frequency;
2719
2720			/* Max number of sensor events that could be in fifo */
2721			uint32_t fifo_max_event_count;
2722		} info_3;
2723
2724		/* Used for MOTIONSENSE_CMD_DATA */
2725		struct ec_response_motion_sensor_data data;
2726
2727		/*
2728		 * Used for MOTIONSENSE_CMD_EC_RATE, MOTIONSENSE_CMD_SENSOR_ODR,
2729		 * MOTIONSENSE_CMD_SENSOR_RANGE,
2730		 * MOTIONSENSE_CMD_KB_WAKE_ANGLE,
2731		 * MOTIONSENSE_CMD_FIFO_INT_ENABLE and
2732		 * MOTIONSENSE_CMD_SPOOF.
2733		 */
2734		struct __ec_todo_unpacked {
2735			/* Current value of the parameter queried. */
2736			int32_t ret;
2737		} ec_rate, sensor_odr, sensor_range, kb_wake_angle,
2738		  fifo_int_enable, spoof;
2739
2740		/*
2741		 * Used for MOTIONSENSE_CMD_SENSOR_OFFSET,
2742		 * PERFORM_CALIB.
2743		 */
2744		struct __ec_todo_unpacked  {
2745			int16_t temp;
2746			int16_t offset[3];
2747		} sensor_offset, perform_calib;
2748
2749		/* Used for MOTIONSENSE_CMD_SENSOR_SCALE */
2750		struct __ec_todo_unpacked  {
2751			int16_t temp;
2752			uint16_t scale[3];
2753		} sensor_scale;
2754
2755		struct ec_response_motion_sense_fifo_info fifo_info, fifo_flush;
2756
2757		struct ec_response_motion_sense_fifo_data fifo_read;
2758
2759		struct __ec_todo_packed {
2760			uint16_t reserved;
2761			uint32_t enabled;
2762			uint32_t disabled;
2763		} list_activities;
2764
2765		/* No params for set activity */
2766
2767		/* Used for MOTIONSENSE_CMD_LID_ANGLE */
2768		struct __ec_todo_unpacked {
2769			/*
2770			 * Angle between 0 and 360 degree if available,
2771			 * LID_ANGLE_UNRELIABLE otherwise.
2772			 */
2773			uint16_t value;
2774		} lid_angle;
2775
2776		/* Used for MOTIONSENSE_CMD_TABLET_MODE_LID_ANGLE. */
2777		struct __ec_todo_unpacked {
2778			/*
2779			 * Lid angle threshold for switching between tablet and
2780			 * clamshell mode.
2781			 */
2782			uint16_t lid_angle;
2783
2784			/* Hysteresis degree. */
2785			uint16_t hys_degree;
2786		} tablet_mode_threshold;
2787
2788	};
2789} __ec_todo_packed;
2790
2791/*****************************************************************************/
2792/* Force lid open command */
2793
2794/* Make lid event always open */
2795#define EC_CMD_FORCE_LID_OPEN 0x002C
2796
2797struct ec_params_force_lid_open {
2798	uint8_t enabled;
2799} __ec_align1;
2800
2801/*****************************************************************************/
2802/* Configure the behavior of the power button */
2803#define EC_CMD_CONFIG_POWER_BUTTON 0x002D
2804
2805enum ec_config_power_button_flags {
2806	/* Enable/Disable power button pulses for x86 devices */
2807	EC_POWER_BUTTON_ENABLE_PULSE = BIT(0),
2808};
2809
2810struct ec_params_config_power_button {
2811	/* See enum ec_config_power_button_flags */
2812	uint8_t flags;
2813} __ec_align1;
2814
2815/*****************************************************************************/
2816/* USB charging control commands */
2817
2818/* Set USB port charging mode */
2819#define EC_CMD_USB_CHARGE_SET_MODE 0x0030
2820
2821struct ec_params_usb_charge_set_mode {
2822	uint8_t usb_port_id;
2823	uint8_t mode:7;
2824	uint8_t inhibit_charge:1;
2825} __ec_align1;
2826
2827/*****************************************************************************/
2828/* Persistent storage for host */
2829
2830/* Maximum bytes that can be read/written in a single command */
2831#define EC_PSTORE_SIZE_MAX 64
2832
2833/* Get persistent storage info */
2834#define EC_CMD_PSTORE_INFO 0x0040
2835
2836struct ec_response_pstore_info {
2837	/* Persistent storage size, in bytes */
2838	uint32_t pstore_size;
2839	/* Access size; read/write offset and size must be a multiple of this */
2840	uint32_t access_size;
2841} __ec_align4;
2842
2843/*
2844 * Read persistent storage
2845 *
2846 * Response is params.size bytes of data.
2847 */
2848#define EC_CMD_PSTORE_READ 0x0041
2849
2850struct ec_params_pstore_read {
2851	uint32_t offset;   /* Byte offset to read */
2852	uint32_t size;     /* Size to read in bytes */
2853} __ec_align4;
2854
2855/* Write persistent storage */
2856#define EC_CMD_PSTORE_WRITE 0x0042
2857
2858struct ec_params_pstore_write {
2859	uint32_t offset;   /* Byte offset to write */
2860	uint32_t size;     /* Size to write in bytes */
2861	uint8_t data[EC_PSTORE_SIZE_MAX];
2862} __ec_align4;
2863
2864/*****************************************************************************/
2865/* Real-time clock */
2866
2867/* RTC params and response structures */
2868struct ec_params_rtc {
2869	uint32_t time;
2870} __ec_align4;
2871
2872struct ec_response_rtc {
2873	uint32_t time;
2874} __ec_align4;
2875
2876/* These use ec_response_rtc */
2877#define EC_CMD_RTC_GET_VALUE 0x0044
2878#define EC_CMD_RTC_GET_ALARM 0x0045
2879
2880/* These all use ec_params_rtc */
2881#define EC_CMD_RTC_SET_VALUE 0x0046
2882#define EC_CMD_RTC_SET_ALARM 0x0047
2883
2884/* Pass as time param to SET_ALARM to clear the current alarm */
2885#define EC_RTC_ALARM_CLEAR 0
2886
2887/*****************************************************************************/
2888/* Port80 log access */
2889
2890/* Maximum entries that can be read/written in a single command */
2891#define EC_PORT80_SIZE_MAX 32
2892
2893/* Get last port80 code from previous boot */
2894#define EC_CMD_PORT80_LAST_BOOT 0x0048
2895#define EC_CMD_PORT80_READ 0x0048
2896
2897enum ec_port80_subcmd {
2898	EC_PORT80_GET_INFO = 0,
2899	EC_PORT80_READ_BUFFER,
2900};
2901
2902struct ec_params_port80_read {
2903	uint16_t subcmd;
2904	union {
2905		struct __ec_todo_unpacked {
2906			uint32_t offset;
2907			uint32_t num_entries;
2908		} read_buffer;
2909	};
2910} __ec_todo_packed;
2911
2912struct ec_response_port80_read {
2913	union {
2914		struct __ec_todo_unpacked {
2915			uint32_t writes;
2916			uint32_t history_size;
2917			uint32_t last_boot;
2918		} get_info;
2919		struct __ec_todo_unpacked {
2920			uint16_t codes[EC_PORT80_SIZE_MAX];
2921		} data;
2922	};
2923} __ec_todo_packed;
2924
2925struct ec_response_port80_last_boot {
2926	uint16_t code;
2927} __ec_align2;
2928
2929/*****************************************************************************/
2930/* Temporary secure storage for host verified boot use */
2931
2932/* Number of bytes in a vstore slot */
2933#define EC_VSTORE_SLOT_SIZE 64
2934
2935/* Maximum number of vstore slots */
2936#define EC_VSTORE_SLOT_MAX 32
2937
2938/* Get persistent storage info */
2939#define EC_CMD_VSTORE_INFO 0x0049
2940struct ec_response_vstore_info {
2941	/* Indicates which slots are locked */
2942	uint32_t slot_locked;
2943	/* Total number of slots available */
2944	uint8_t slot_count;
2945} __ec_align_size1;
2946
2947/*
2948 * Read temporary secure storage
2949 *
2950 * Response is EC_VSTORE_SLOT_SIZE bytes of data.
2951 */
2952#define EC_CMD_VSTORE_READ 0x004A
2953
2954struct ec_params_vstore_read {
2955	uint8_t slot; /* Slot to read from */
2956} __ec_align1;
2957
2958struct ec_response_vstore_read {
2959	uint8_t data[EC_VSTORE_SLOT_SIZE];
2960} __ec_align1;
2961
2962/*
2963 * Write temporary secure storage and lock it.
2964 */
2965#define EC_CMD_VSTORE_WRITE 0x004B
2966
2967struct ec_params_vstore_write {
2968	uint8_t slot; /* Slot to write to */
2969	uint8_t data[EC_VSTORE_SLOT_SIZE];
2970} __ec_align1;
2971
2972/*****************************************************************************/
2973/* Thermal engine commands. Note that there are two implementations. We'll
2974 * reuse the command number, but the data and behavior is incompatible.
2975 * Version 0 is what originally shipped on Link.
2976 * Version 1 separates the CPU thermal limits from the fan control.
2977 */
2978
2979#define EC_CMD_THERMAL_SET_THRESHOLD 0x0050
2980#define EC_CMD_THERMAL_GET_THRESHOLD 0x0051
2981
2982/* The version 0 structs are opaque. You have to know what they are for
2983 * the get/set commands to make any sense.
2984 */
2985
2986/* Version 0 - set */
2987struct ec_params_thermal_set_threshold {
2988	uint8_t sensor_type;
2989	uint8_t threshold_id;
2990	uint16_t value;
2991} __ec_align2;
2992
2993/* Version 0 - get */
2994struct ec_params_thermal_get_threshold {
2995	uint8_t sensor_type;
2996	uint8_t threshold_id;
2997} __ec_align1;
2998
2999struct ec_response_thermal_get_threshold {
3000	uint16_t value;
3001} __ec_align2;
3002
3003
3004/* The version 1 structs are visible. */
3005enum ec_temp_thresholds {
3006	EC_TEMP_THRESH_WARN = 0,
3007	EC_TEMP_THRESH_HIGH,
3008	EC_TEMP_THRESH_HALT,
3009
3010	EC_TEMP_THRESH_COUNT
3011};
3012
3013/*
3014 * Thermal configuration for one temperature sensor. Temps are in degrees K.
3015 * Zero values will be silently ignored by the thermal task.
3016 *
3017 * Set 'temp_host' value allows thermal task to trigger some event with 1 degree
3018 * hysteresis.
3019 * For example,
3020 *	temp_host[EC_TEMP_THRESH_HIGH] = 300 K
3021 *	temp_host_release[EC_TEMP_THRESH_HIGH] = 0 K
3022 * EC will throttle ap when temperature >= 301 K, and release throttling when
3023 * temperature <= 299 K.
3024 *
3025 * Set 'temp_host_release' value allows thermal task has a custom hysteresis.
3026 * For example,
3027 *	temp_host[EC_TEMP_THRESH_HIGH] = 300 K
3028 *	temp_host_release[EC_TEMP_THRESH_HIGH] = 295 K
3029 * EC will throttle ap when temperature >= 301 K, and release throttling when
3030 * temperature <= 294 K.
3031 *
3032 * Note that this structure is a sub-structure of
3033 * ec_params_thermal_set_threshold_v1, but maintains its alignment there.
3034 */
3035struct ec_thermal_config {
3036	uint32_t temp_host[EC_TEMP_THRESH_COUNT]; /* levels of hotness */
3037	uint32_t temp_host_release[EC_TEMP_THRESH_COUNT]; /* release levels */
3038	uint32_t temp_fan_off;		/* no active cooling needed */
3039	uint32_t temp_fan_max;		/* max active cooling needed */
3040} __ec_align4;
3041
3042/* Version 1 - get config for one sensor. */
3043struct ec_params_thermal_get_threshold_v1 {
3044	uint32_t sensor_num;
3045} __ec_align4;
3046/* This returns a struct ec_thermal_config */
3047
3048/*
3049 * Version 1 - set config for one sensor.
3050 * Use read-modify-write for best results!
3051 */
3052struct ec_params_thermal_set_threshold_v1 {
3053	uint32_t sensor_num;
3054	struct ec_thermal_config cfg;
3055} __ec_align4;
3056/* This returns no data */
3057
3058/****************************************************************************/
3059
3060/* Toggle automatic fan control */
3061#define EC_CMD_THERMAL_AUTO_FAN_CTRL 0x0052
3062
3063/* Version 1 of input params */
3064struct ec_params_auto_fan_ctrl_v1 {
3065	uint8_t fan_idx;
3066} __ec_align1;
3067
3068/* Get/Set TMP006 calibration data */
3069#define EC_CMD_TMP006_GET_CALIBRATION 0x0053
3070#define EC_CMD_TMP006_SET_CALIBRATION 0x0054
3071
3072/*
3073 * The original TMP006 calibration only needed four params, but now we need
3074 * more. Since the algorithm is nothing but magic numbers anyway, we'll leave
3075 * the params opaque. The v1 "get" response will include the algorithm number
3076 * and how many params it requires. That way we can change the EC code without
3077 * needing to update this file. We can also use a different algorithm on each
3078 * sensor.
3079 */
3080
3081/* This is the same struct for both v0 and v1. */
3082struct ec_params_tmp006_get_calibration {
3083	uint8_t index;
3084} __ec_align1;
3085
3086/* Version 0 */
3087struct ec_response_tmp006_get_calibration_v0 {
3088	float s0;
3089	float b0;
3090	float b1;
3091	float b2;
3092} __ec_align4;
3093
3094struct ec_params_tmp006_set_calibration_v0 {
3095	uint8_t index;
3096	uint8_t reserved[3];
3097	float s0;
3098	float b0;
3099	float b1;
3100	float b2;
3101} __ec_align4;
3102
3103/* Version 1 */
3104struct ec_response_tmp006_get_calibration_v1 {
3105	uint8_t algorithm;
3106	uint8_t num_params;
3107	uint8_t reserved[2];
3108	float val[];
3109} __ec_align4;
3110
3111struct ec_params_tmp006_set_calibration_v1 {
3112	uint8_t index;
3113	uint8_t algorithm;
3114	uint8_t num_params;
3115	uint8_t reserved;
3116	float val[];
3117} __ec_align4;
3118
3119
3120/* Read raw TMP006 data */
3121#define EC_CMD_TMP006_GET_RAW 0x0055
3122
3123struct ec_params_tmp006_get_raw {
3124	uint8_t index;
3125} __ec_align1;
3126
3127struct ec_response_tmp006_get_raw {
3128	int32_t t;  /* In 1/100 K */
3129	int32_t v;  /* In nV */
3130} __ec_align4;
3131
3132/*****************************************************************************/
3133/* MKBP - Matrix KeyBoard Protocol */
3134
3135/*
3136 * Read key state
3137 *
3138 * Returns raw data for keyboard cols; see ec_response_mkbp_info.cols for
3139 * expected response size.
3140 *
3141 * NOTE: This has been superseded by EC_CMD_MKBP_GET_NEXT_EVENT.  If you wish
3142 * to obtain the instantaneous state, use EC_CMD_MKBP_INFO with the type
3143 * EC_MKBP_INFO_CURRENT and event EC_MKBP_EVENT_KEY_MATRIX.
3144 */
3145#define EC_CMD_MKBP_STATE 0x0060
3146
3147/*
3148 * Provide information about various MKBP things.  See enum ec_mkbp_info_type.
3149 */
3150#define EC_CMD_MKBP_INFO 0x0061
3151
3152struct ec_response_mkbp_info {
3153	uint32_t rows;
3154	uint32_t cols;
3155	/* Formerly "switches", which was 0. */
3156	uint8_t reserved;
3157} __ec_align_size1;
3158
3159struct ec_params_mkbp_info {
3160	uint8_t info_type;
3161	uint8_t event_type;
3162} __ec_align1;
3163
3164enum ec_mkbp_info_type {
3165	/*
3166	 * Info about the keyboard matrix: number of rows and columns.
3167	 *
3168	 * Returns struct ec_response_mkbp_info.
3169	 */
3170	EC_MKBP_INFO_KBD = 0,
3171
3172	/*
3173	 * For buttons and switches, info about which specifically are
3174	 * supported.  event_type must be set to one of the values in enum
3175	 * ec_mkbp_event.
3176	 *
3177	 * For EC_MKBP_EVENT_BUTTON and EC_MKBP_EVENT_SWITCH, returns a 4 byte
3178	 * bitmask indicating which buttons or switches are present.  See the
3179	 * bit inidices below.
3180	 */
3181	EC_MKBP_INFO_SUPPORTED = 1,
3182
3183	/*
3184	 * Instantaneous state of buttons and switches.
3185	 *
3186	 * event_type must be set to one of the values in enum ec_mkbp_event.
3187	 *
3188	 * For EC_MKBP_EVENT_KEY_MATRIX, returns uint8_t key_matrix[13]
3189	 * indicating the current state of the keyboard matrix.
3190	 *
3191	 * For EC_MKBP_EVENT_HOST_EVENT, return uint32_t host_event, the raw
3192	 * event state.
3193	 *
3194	 * For EC_MKBP_EVENT_BUTTON, returns uint32_t buttons, indicating the
3195	 * state of supported buttons.
3196	 *
3197	 * For EC_MKBP_EVENT_SWITCH, returns uint32_t switches, indicating the
3198	 * state of supported switches.
3199	 */
3200	EC_MKBP_INFO_CURRENT = 2,
3201};
3202
3203/* Simulate key press */
3204#define EC_CMD_MKBP_SIMULATE_KEY 0x0062
3205
3206struct ec_params_mkbp_simulate_key {
3207	uint8_t col;
3208	uint8_t row;
3209	uint8_t pressed;
3210} __ec_align1;
3211
3212#define EC_CMD_GET_KEYBOARD_ID 0x0063
3213
3214struct ec_response_keyboard_id {
3215	uint32_t keyboard_id;
3216} __ec_align4;
3217
3218enum keyboard_id {
3219	KEYBOARD_ID_UNSUPPORTED = 0,
3220	KEYBOARD_ID_UNREADABLE = 0xffffffff,
3221};
3222
3223/* Configure keyboard scanning */
3224#define EC_CMD_MKBP_SET_CONFIG 0x0064
3225#define EC_CMD_MKBP_GET_CONFIG 0x0065
3226
3227/* flags */
3228enum mkbp_config_flags {
3229	EC_MKBP_FLAGS_ENABLE = 1,	/* Enable keyboard scanning */
3230};
3231
3232enum mkbp_config_valid {
3233	EC_MKBP_VALID_SCAN_PERIOD		= BIT(0),
3234	EC_MKBP_VALID_POLL_TIMEOUT		= BIT(1),
3235	EC_MKBP_VALID_MIN_POST_SCAN_DELAY	= BIT(3),
3236	EC_MKBP_VALID_OUTPUT_SETTLE		= BIT(4),
3237	EC_MKBP_VALID_DEBOUNCE_DOWN		= BIT(5),
3238	EC_MKBP_VALID_DEBOUNCE_UP		= BIT(6),
3239	EC_MKBP_VALID_FIFO_MAX_DEPTH		= BIT(7),
3240};
3241
3242/*
3243 * Configuration for our key scanning algorithm.
3244 *
3245 * Note that this is used as a sub-structure of
3246 * ec_{params/response}_mkbp_get_config.
3247 */
3248struct ec_mkbp_config {
3249	uint32_t valid_mask;		/* valid fields */
3250	uint8_t flags;		/* some flags (enum mkbp_config_flags) */
3251	uint8_t valid_flags;		/* which flags are valid */
3252	uint16_t scan_period_us;	/* period between start of scans */
3253	/* revert to interrupt mode after no activity for this long */
3254	uint32_t poll_timeout_us;
3255	/*
3256	 * minimum post-scan relax time. Once we finish a scan we check
3257	 * the time until we are due to start the next one. If this time is
3258	 * shorter this field, we use this instead.
3259	 */
3260	uint16_t min_post_scan_delay_us;
3261	/* delay between setting up output and waiting for it to settle */
3262	uint16_t output_settle_us;
3263	uint16_t debounce_down_us;	/* time for debounce on key down */
3264	uint16_t debounce_up_us;	/* time for debounce on key up */
3265	/* maximum depth to allow for fifo (0 = no keyscan output) */
3266	uint8_t fifo_max_depth;
3267} __ec_align_size1;
3268
3269struct ec_params_mkbp_set_config {
3270	struct ec_mkbp_config config;
3271} __ec_align_size1;
3272
3273struct ec_response_mkbp_get_config {
3274	struct ec_mkbp_config config;
3275} __ec_align_size1;
3276
3277/* Run the key scan emulation */
3278#define EC_CMD_KEYSCAN_SEQ_CTRL 0x0066
3279
3280enum ec_keyscan_seq_cmd {
3281	EC_KEYSCAN_SEQ_STATUS = 0,	/* Get status information */
3282	EC_KEYSCAN_SEQ_CLEAR = 1,	/* Clear sequence */
3283	EC_KEYSCAN_SEQ_ADD = 2,		/* Add item to sequence */
3284	EC_KEYSCAN_SEQ_START = 3,	/* Start running sequence */
3285	EC_KEYSCAN_SEQ_COLLECT = 4,	/* Collect sequence summary data */
3286};
3287
3288enum ec_collect_flags {
3289	/*
3290	 * Indicates this scan was processed by the EC. Due to timing, some
3291	 * scans may be skipped.
3292	 */
3293	EC_KEYSCAN_SEQ_FLAG_DONE	= BIT(0),
3294};
3295
3296struct ec_collect_item {
3297	uint8_t flags;		/* some flags (enum ec_collect_flags) */
3298} __ec_align1;
3299
3300struct ec_params_keyscan_seq_ctrl {
3301	uint8_t cmd;	/* Command to send (enum ec_keyscan_seq_cmd) */
3302	union {
3303		struct __ec_align1 {
3304			uint8_t active;		/* still active */
3305			uint8_t num_items;	/* number of items */
3306			/* Current item being presented */
3307			uint8_t cur_item;
3308		} status;
3309		struct __ec_todo_unpacked {
3310			/*
3311			 * Absolute time for this scan, measured from the
3312			 * start of the sequence.
3313			 */
3314			uint32_t time_us;
3315			uint8_t scan[0];	/* keyscan data */
3316		} add;
3317		struct __ec_align1 {
3318			uint8_t start_item;	/* First item to return */
3319			uint8_t num_items;	/* Number of items to return */
3320		} collect;
3321	};
3322} __ec_todo_packed;
3323
3324struct ec_result_keyscan_seq_ctrl {
3325	union {
3326		struct __ec_todo_unpacked {
3327			uint8_t num_items;	/* Number of items */
3328			/* Data for each item */
3329			struct ec_collect_item item[0];
3330		} collect;
3331	};
3332} __ec_todo_packed;
3333
3334/*
3335 * Get the next pending MKBP event.
3336 *
3337 * Returns EC_RES_UNAVAILABLE if there is no event pending.
3338 */
3339#define EC_CMD_GET_NEXT_EVENT 0x0067
3340
3341#define EC_MKBP_HAS_MORE_EVENTS_SHIFT 7
3342
3343/*
3344 * We use the most significant bit of the event type to indicate to the host
3345 * that the EC has more MKBP events available to provide.
3346 */
3347#define EC_MKBP_HAS_MORE_EVENTS BIT(EC_MKBP_HAS_MORE_EVENTS_SHIFT)
3348
3349/* The mask to apply to get the raw event type */
3350#define EC_MKBP_EVENT_TYPE_MASK (BIT(EC_MKBP_HAS_MORE_EVENTS_SHIFT) - 1)
3351
3352enum ec_mkbp_event {
3353	/* Keyboard matrix changed. The event data is the new matrix state. */
3354	EC_MKBP_EVENT_KEY_MATRIX = 0,
3355
3356	/* New host event. The event data is 4 bytes of host event flags. */
3357	EC_MKBP_EVENT_HOST_EVENT = 1,
3358
3359	/* New Sensor FIFO data. The event data is fifo_info structure. */
3360	EC_MKBP_EVENT_SENSOR_FIFO = 2,
3361
3362	/* The state of the non-matrixed buttons have changed. */
3363	EC_MKBP_EVENT_BUTTON = 3,
3364
3365	/* The state of the switches have changed. */
3366	EC_MKBP_EVENT_SWITCH = 4,
3367
3368	/* New Fingerprint sensor event, the event data is fp_events bitmap. */
3369	EC_MKBP_EVENT_FINGERPRINT = 5,
3370
3371	/*
3372	 * Sysrq event: send emulated sysrq. The event data is sysrq,
3373	 * corresponding to the key to be pressed.
3374	 */
3375	EC_MKBP_EVENT_SYSRQ = 6,
3376
3377	/*
3378	 * New 64-bit host event.
3379	 * The event data is 8 bytes of host event flags.
3380	 */
3381	EC_MKBP_EVENT_HOST_EVENT64 = 7,
3382
3383	/* Notify the AP that something happened on CEC */
3384	EC_MKBP_EVENT_CEC_EVENT = 8,
3385
3386	/* Send an incoming CEC message to the AP */
3387	EC_MKBP_EVENT_CEC_MESSAGE = 9,
3388
3389	/* Peripheral device charger event */
3390	EC_MKBP_EVENT_PCHG = 12,
3391
3392	/* Number of MKBP events */
3393	EC_MKBP_EVENT_COUNT,
3394};
3395BUILD_ASSERT(EC_MKBP_EVENT_COUNT <= EC_MKBP_EVENT_TYPE_MASK);
3396
3397union __ec_align_offset1 ec_response_get_next_data {
3398	uint8_t key_matrix[13];
3399
3400	/* Unaligned */
3401	uint32_t host_event;
3402	uint64_t host_event64;
3403
3404	struct __ec_todo_unpacked {
3405		/* For aligning the fifo_info */
3406		uint8_t reserved[3];
3407		struct ec_response_motion_sense_fifo_info info;
3408	} sensor_fifo;
3409
3410	uint32_t buttons;
3411
3412	uint32_t switches;
3413
3414	uint32_t fp_events;
3415
3416	uint32_t sysrq;
3417
3418	/* CEC events from enum mkbp_cec_event */
3419	uint32_t cec_events;
3420};
3421
3422union __ec_align_offset1 ec_response_get_next_data_v1 {
3423	uint8_t key_matrix[16];
3424
3425	/* Unaligned */
3426	uint32_t host_event;
3427	uint64_t host_event64;
3428
3429	struct __ec_todo_unpacked {
3430		/* For aligning the fifo_info */
3431		uint8_t reserved[3];
3432		struct ec_response_motion_sense_fifo_info info;
3433	} sensor_fifo;
3434
3435	uint32_t buttons;
3436
3437	uint32_t switches;
3438
3439	uint32_t fp_events;
3440
3441	uint32_t sysrq;
3442
3443	/* CEC events from enum mkbp_cec_event */
3444	uint32_t cec_events;
3445
3446	uint8_t cec_message[16];
3447};
3448BUILD_ASSERT(sizeof(union ec_response_get_next_data_v1) == 16);
3449
3450struct ec_response_get_next_event {
3451	uint8_t event_type;
3452	/* Followed by event data if any */
3453	union ec_response_get_next_data data;
3454} __ec_align1;
3455
3456struct ec_response_get_next_event_v1 {
3457	uint8_t event_type;
3458	/* Followed by event data if any */
3459	union ec_response_get_next_data_v1 data;
3460} __ec_align1;
3461
3462/* Bit indices for buttons and switches.*/
3463/* Buttons */
3464#define EC_MKBP_POWER_BUTTON	0
3465#define EC_MKBP_VOL_UP		1
3466#define EC_MKBP_VOL_DOWN	2
3467#define EC_MKBP_RECOVERY	3
3468
3469/* Switches */
3470#define EC_MKBP_LID_OPEN	0
3471#define EC_MKBP_TABLET_MODE	1
3472#define EC_MKBP_BASE_ATTACHED	2
3473#define EC_MKBP_FRONT_PROXIMITY	3
3474
3475/* Run keyboard factory test scanning */
3476#define EC_CMD_KEYBOARD_FACTORY_TEST 0x0068
3477
3478struct ec_response_keyboard_factory_test {
3479	uint16_t shorted;	/* Keyboard pins are shorted */
3480} __ec_align2;
3481
3482/* Fingerprint events in 'fp_events' for EC_MKBP_EVENT_FINGERPRINT */
3483#define EC_MKBP_FP_RAW_EVENT(fp_events) ((fp_events) & 0x00FFFFFF)
3484#define EC_MKBP_FP_ERRCODE(fp_events)   ((fp_events) & 0x0000000F)
3485#define EC_MKBP_FP_ENROLL_PROGRESS_OFFSET 4
3486#define EC_MKBP_FP_ENROLL_PROGRESS(fpe) (((fpe) & 0x00000FF0) \
3487					 >> EC_MKBP_FP_ENROLL_PROGRESS_OFFSET)
3488#define EC_MKBP_FP_MATCH_IDX_OFFSET 12
3489#define EC_MKBP_FP_MATCH_IDX_MASK 0x0000F000
3490#define EC_MKBP_FP_MATCH_IDX(fpe) (((fpe) & EC_MKBP_FP_MATCH_IDX_MASK) \
3491					 >> EC_MKBP_FP_MATCH_IDX_OFFSET)
3492#define EC_MKBP_FP_ENROLL               BIT(27)
3493#define EC_MKBP_FP_MATCH                BIT(28)
3494#define EC_MKBP_FP_FINGER_DOWN          BIT(29)
3495#define EC_MKBP_FP_FINGER_UP            BIT(30)
3496#define EC_MKBP_FP_IMAGE_READY          BIT(31)
3497/* code given by EC_MKBP_FP_ERRCODE() when EC_MKBP_FP_ENROLL is set */
3498#define EC_MKBP_FP_ERR_ENROLL_OK               0
3499#define EC_MKBP_FP_ERR_ENROLL_LOW_QUALITY      1
3500#define EC_MKBP_FP_ERR_ENROLL_IMMOBILE         2
3501#define EC_MKBP_FP_ERR_ENROLL_LOW_COVERAGE     3
3502#define EC_MKBP_FP_ERR_ENROLL_INTERNAL         5
3503/* Can be used to detect if image was usable for enrollment or not. */
3504#define EC_MKBP_FP_ERR_ENROLL_PROBLEM_MASK     1
3505/* code given by EC_MKBP_FP_ERRCODE() when EC_MKBP_FP_MATCH is set */
3506#define EC_MKBP_FP_ERR_MATCH_NO                0
3507#define EC_MKBP_FP_ERR_MATCH_NO_INTERNAL       6
3508#define EC_MKBP_FP_ERR_MATCH_NO_TEMPLATES      7
3509#define EC_MKBP_FP_ERR_MATCH_NO_LOW_QUALITY    2
3510#define EC_MKBP_FP_ERR_MATCH_NO_LOW_COVERAGE   4
3511#define EC_MKBP_FP_ERR_MATCH_YES               1
3512#define EC_MKBP_FP_ERR_MATCH_YES_UPDATED       3
3513#define EC_MKBP_FP_ERR_MATCH_YES_UPDATE_FAILED 5
3514
3515
3516/*****************************************************************************/
3517/* Temperature sensor commands */
3518
3519/* Read temperature sensor info */
3520#define EC_CMD_TEMP_SENSOR_GET_INFO 0x0070
3521
3522struct ec_params_temp_sensor_get_info {
3523	uint8_t id;
3524} __ec_align1;
3525
3526struct ec_response_temp_sensor_get_info {
3527	char sensor_name[32];
3528	uint8_t sensor_type;
3529} __ec_align1;
3530
3531/*****************************************************************************/
3532
3533/*
3534 * Note: host commands 0x80 - 0x87 are reserved to avoid conflict with ACPI
3535 * commands accidentally sent to the wrong interface.  See the ACPI section
3536 * below.
3537 */
3538
3539/*****************************************************************************/
3540/* Host event commands */
3541
3542
3543/* Obsolete. New implementation should use EC_CMD_HOST_EVENT instead */
3544/*
3545 * Host event mask params and response structures, shared by all of the host
3546 * event commands below.
3547 */
3548struct ec_params_host_event_mask {
3549	uint32_t mask;
3550} __ec_align4;
3551
3552struct ec_response_host_event_mask {
3553	uint32_t mask;
3554} __ec_align4;
3555
3556/* These all use ec_response_host_event_mask */
3557#define EC_CMD_HOST_EVENT_GET_B         0x0087
3558#define EC_CMD_HOST_EVENT_GET_SMI_MASK  0x0088
3559#define EC_CMD_HOST_EVENT_GET_SCI_MASK  0x0089
3560#define EC_CMD_HOST_EVENT_GET_WAKE_MASK 0x008D
3561
3562/* These all use ec_params_host_event_mask */
3563#define EC_CMD_HOST_EVENT_SET_SMI_MASK  0x008A
3564#define EC_CMD_HOST_EVENT_SET_SCI_MASK  0x008B
3565#define EC_CMD_HOST_EVENT_CLEAR         0x008C
3566#define EC_CMD_HOST_EVENT_SET_WAKE_MASK 0x008E
3567#define EC_CMD_HOST_EVENT_CLEAR_B       0x008F
3568
3569/*
3570 * Unified host event programming interface - Should be used by newer versions
3571 * of BIOS/OS to program host events and masks
3572 */
3573
3574struct ec_params_host_event {
3575
3576	/* Action requested by host - one of enum ec_host_event_action. */
3577	uint8_t action;
3578
3579	/*
3580	 * Mask type that the host requested the action on - one of
3581	 * enum ec_host_event_mask_type.
3582	 */
3583	uint8_t mask_type;
3584
3585	/* Set to 0, ignore on read */
3586	uint16_t reserved;
3587
3588	/* Value to be used in case of set operations. */
3589	uint64_t value;
3590} __ec_align4;
3591
3592/*
3593 * Response structure returned by EC_CMD_HOST_EVENT.
3594 * Update the value on a GET request. Set to 0 on GET/CLEAR
3595 */
3596
3597struct ec_response_host_event {
3598
3599	/* Mask value in case of get operation */
3600	uint64_t value;
3601} __ec_align4;
3602
3603enum ec_host_event_action {
3604	/*
3605	 * params.value is ignored. Value of mask_type populated
3606	 * in response.value
3607	 */
3608	EC_HOST_EVENT_GET,
3609
3610	/* Bits in params.value are set */
3611	EC_HOST_EVENT_SET,
3612
3613	/* Bits in params.value are cleared */
3614	EC_HOST_EVENT_CLEAR,
3615};
3616
3617enum ec_host_event_mask_type {
3618
3619	/* Main host event copy */
3620	EC_HOST_EVENT_MAIN,
3621
3622	/* Copy B of host events */
3623	EC_HOST_EVENT_B,
3624
3625	/* SCI Mask */
3626	EC_HOST_EVENT_SCI_MASK,
3627
3628	/* SMI Mask */
3629	EC_HOST_EVENT_SMI_MASK,
3630
3631	/* Mask of events that should be always reported in hostevents */
3632	EC_HOST_EVENT_ALWAYS_REPORT_MASK,
3633
3634	/* Active wake mask */
3635	EC_HOST_EVENT_ACTIVE_WAKE_MASK,
3636
3637	/* Lazy wake mask for S0ix */
3638	EC_HOST_EVENT_LAZY_WAKE_MASK_S0IX,
3639
3640	/* Lazy wake mask for S3 */
3641	EC_HOST_EVENT_LAZY_WAKE_MASK_S3,
3642
3643	/* Lazy wake mask for S5 */
3644	EC_HOST_EVENT_LAZY_WAKE_MASK_S5,
3645};
3646
3647#define EC_CMD_HOST_EVENT       0x00A4
3648
3649/*****************************************************************************/
3650/* Switch commands */
3651
3652/* Enable/disable LCD backlight */
3653#define EC_CMD_SWITCH_ENABLE_BKLIGHT 0x0090
3654
3655struct ec_params_switch_enable_backlight {
3656	uint8_t enabled;
3657} __ec_align1;
3658
3659/* Enable/disable WLAN/Bluetooth */
3660#define EC_CMD_SWITCH_ENABLE_WIRELESS 0x0091
3661#define EC_VER_SWITCH_ENABLE_WIRELESS 1
3662
3663/* Version 0 params; no response */
3664struct ec_params_switch_enable_wireless_v0 {
3665	uint8_t enabled;
3666} __ec_align1;
3667
3668/* Version 1 params */
3669struct ec_params_switch_enable_wireless_v1 {
3670	/* Flags to enable now */
3671	uint8_t now_flags;
3672
3673	/* Which flags to copy from now_flags */
3674	uint8_t now_mask;
3675
3676	/*
3677	 * Flags to leave enabled in S3, if they're on at the S0->S3
3678	 * transition.  (Other flags will be disabled by the S0->S3
3679	 * transition.)
3680	 */
3681	uint8_t suspend_flags;
3682
3683	/* Which flags to copy from suspend_flags */
3684	uint8_t suspend_mask;
3685} __ec_align1;
3686
3687/* Version 1 response */
3688struct ec_response_switch_enable_wireless_v1 {
3689	/* Flags to enable now */
3690	uint8_t now_flags;
3691
3692	/* Flags to leave enabled in S3 */
3693	uint8_t suspend_flags;
3694} __ec_align1;
3695
3696/*****************************************************************************/
3697/* GPIO commands. Only available on EC if write protect has been disabled. */
3698
3699/* Set GPIO output value */
3700#define EC_CMD_GPIO_SET 0x0092
3701
3702struct ec_params_gpio_set {
3703	char name[32];
3704	uint8_t val;
3705} __ec_align1;
3706
3707/* Get GPIO value */
3708#define EC_CMD_GPIO_GET 0x0093
3709
3710/* Version 0 of input params and response */
3711struct ec_params_gpio_get {
3712	char name[32];
3713} __ec_align1;
3714
3715struct ec_response_gpio_get {
3716	uint8_t val;
3717} __ec_align1;
3718
3719/* Version 1 of input params and response */
3720struct ec_params_gpio_get_v1 {
3721	uint8_t subcmd;
3722	union {
3723		struct __ec_align1 {
3724			char name[32];
3725		} get_value_by_name;
3726		struct __ec_align1 {
3727			uint8_t index;
3728		} get_info;
3729	};
3730} __ec_align1;
3731
3732struct ec_response_gpio_get_v1 {
3733	union {
3734		struct __ec_align1 {
3735			uint8_t val;
3736		} get_value_by_name, get_count;
3737		struct __ec_todo_unpacked {
3738			uint8_t val;
3739			char name[32];
3740			uint32_t flags;
3741		} get_info;
3742	};
3743} __ec_todo_packed;
3744
3745enum gpio_get_subcmd {
3746	EC_GPIO_GET_BY_NAME = 0,
3747	EC_GPIO_GET_COUNT = 1,
3748	EC_GPIO_GET_INFO = 2,
3749};
3750
3751/*****************************************************************************/
3752/* I2C commands. Only available when flash write protect is unlocked. */
3753
3754/*
3755 * CAUTION: These commands are deprecated, and are not supported anymore in EC
3756 * builds >= 8398.0.0 (see crosbug.com/p/23570).
3757 *
3758 * Use EC_CMD_I2C_PASSTHRU instead.
3759 */
3760
3761/* Read I2C bus */
3762#define EC_CMD_I2C_READ 0x0094
3763
3764struct ec_params_i2c_read {
3765	uint16_t addr; /* 8-bit address (7-bit shifted << 1) */
3766	uint8_t read_size; /* Either 8 or 16. */
3767	uint8_t port;
3768	uint8_t offset;
3769} __ec_align_size1;
3770
3771struct ec_response_i2c_read {
3772	uint16_t data;
3773} __ec_align2;
3774
3775/* Write I2C bus */
3776#define EC_CMD_I2C_WRITE 0x0095
3777
3778struct ec_params_i2c_write {
3779	uint16_t data;
3780	uint16_t addr; /* 8-bit address (7-bit shifted << 1) */
3781	uint8_t write_size; /* Either 8 or 16. */
3782	uint8_t port;
3783	uint8_t offset;
3784} __ec_align_size1;
3785
3786/*****************************************************************************/
3787/* Charge state commands. Only available when flash write protect unlocked. */
3788
3789/* Force charge state machine to stop charging the battery or force it to
3790 * discharge the battery.
3791 */
3792#define EC_CMD_CHARGE_CONTROL 0x0096
3793#define EC_VER_CHARGE_CONTROL 1
3794
3795enum ec_charge_control_mode {
3796	CHARGE_CONTROL_NORMAL = 0,
3797	CHARGE_CONTROL_IDLE,
3798	CHARGE_CONTROL_DISCHARGE,
3799};
3800
3801struct ec_params_charge_control {
3802	uint32_t mode;  /* enum charge_control_mode */
3803} __ec_align4;
3804
3805/*****************************************************************************/
3806
3807/* Snapshot console output buffer for use by EC_CMD_CONSOLE_READ. */
3808#define EC_CMD_CONSOLE_SNAPSHOT 0x0097
3809
3810/*
3811 * Read data from the saved snapshot. If the subcmd parameter is
3812 * CONSOLE_READ_NEXT, this will return data starting from the beginning of
3813 * the latest snapshot. If it is CONSOLE_READ_RECENT, it will start from the
3814 * end of the previous snapshot.
3815 *
3816 * The params are only looked at in version >= 1 of this command. Prior
3817 * versions will just default to CONSOLE_READ_NEXT behavior.
3818 *
3819 * Response is null-terminated string.  Empty string, if there is no more
3820 * remaining output.
3821 */
3822#define EC_CMD_CONSOLE_READ 0x0098
3823
3824enum ec_console_read_subcmd {
3825	CONSOLE_READ_NEXT = 0,
3826	CONSOLE_READ_RECENT
3827};
3828
3829struct ec_params_console_read_v1 {
3830	uint8_t subcmd; /* enum ec_console_read_subcmd */
3831} __ec_align1;
3832
3833/*****************************************************************************/
3834
3835/*
3836 * Cut off battery power immediately or after the host has shut down.
3837 *
3838 * return EC_RES_INVALID_COMMAND if unsupported by a board/battery.
3839 *	  EC_RES_SUCCESS if the command was successful.
3840 *	  EC_RES_ERROR if the cut off command failed.
3841 */
3842#define EC_CMD_BATTERY_CUT_OFF 0x0099
3843
3844#define EC_BATTERY_CUTOFF_FLAG_AT_SHUTDOWN	BIT(0)
3845
3846struct ec_params_battery_cutoff {
3847	uint8_t flags;
3848} __ec_align1;
3849
3850/*****************************************************************************/
3851/* USB port mux control. */
3852
3853/*
3854 * Switch USB mux or return to automatic switching.
3855 */
3856#define EC_CMD_USB_MUX 0x009A
3857
3858struct ec_params_usb_mux {
3859	uint8_t mux;
3860} __ec_align1;
3861
3862/*****************************************************************************/
3863/* LDOs / FETs control. */
3864
3865enum ec_ldo_state {
3866	EC_LDO_STATE_OFF = 0,	/* the LDO / FET is shut down */
3867	EC_LDO_STATE_ON = 1,	/* the LDO / FET is ON / providing power */
3868};
3869
3870/*
3871 * Switch on/off a LDO.
3872 */
3873#define EC_CMD_LDO_SET 0x009B
3874
3875struct ec_params_ldo_set {
3876	uint8_t index;
3877	uint8_t state;
3878} __ec_align1;
3879
3880/*
3881 * Get LDO state.
3882 */
3883#define EC_CMD_LDO_GET 0x009C
3884
3885struct ec_params_ldo_get {
3886	uint8_t index;
3887} __ec_align1;
3888
3889struct ec_response_ldo_get {
3890	uint8_t state;
3891} __ec_align1;
3892
3893/*****************************************************************************/
3894/* Power info. */
3895
3896/*
3897 * Get power info.
3898 */
3899#define EC_CMD_POWER_INFO 0x009D
3900
3901struct ec_response_power_info {
3902	uint32_t usb_dev_type;
3903	uint16_t voltage_ac;
3904	uint16_t voltage_system;
3905	uint16_t current_system;
3906	uint16_t usb_current_limit;
3907} __ec_align4;
3908
3909/*****************************************************************************/
3910/* I2C passthru command */
3911
3912#define EC_CMD_I2C_PASSTHRU 0x009E
3913
3914/* Read data; if not present, message is a write */
3915#define EC_I2C_FLAG_READ	BIT(15)
3916
3917/* Mask for address */
3918#define EC_I2C_ADDR_MASK	0x3ff
3919
3920#define EC_I2C_STATUS_NAK	BIT(0) /* Transfer was not acknowledged */
3921#define EC_I2C_STATUS_TIMEOUT	BIT(1) /* Timeout during transfer */
3922
3923/* Any error */
3924#define EC_I2C_STATUS_ERROR	(EC_I2C_STATUS_NAK | EC_I2C_STATUS_TIMEOUT)
3925
3926struct ec_params_i2c_passthru_msg {
3927	uint16_t addr_flags;	/* I2C slave address (7 or 10 bits) and flags */
3928	uint16_t len;		/* Number of bytes to read or write */
3929} __ec_align2;
3930
3931struct ec_params_i2c_passthru {
3932	uint8_t port;		/* I2C port number */
3933	uint8_t num_msgs;	/* Number of messages */
3934	struct ec_params_i2c_passthru_msg msg[];
3935	/* Data to write for all messages is concatenated here */
3936} __ec_align2;
3937
3938struct ec_response_i2c_passthru {
3939	uint8_t i2c_status;	/* Status flags (EC_I2C_STATUS_...) */
3940	uint8_t num_msgs;	/* Number of messages processed */
3941	uint8_t data[];		/* Data read by messages concatenated here */
3942} __ec_align1;
3943
3944/*****************************************************************************/
3945/* Power button hang detect */
3946
3947#define EC_CMD_HANG_DETECT 0x009F
3948
3949/* Reasons to start hang detection timer */
3950/* Power button pressed */
3951#define EC_HANG_START_ON_POWER_PRESS  BIT(0)
3952
3953/* Lid closed */
3954#define EC_HANG_START_ON_LID_CLOSE    BIT(1)
3955
3956 /* Lid opened */
3957#define EC_HANG_START_ON_LID_OPEN     BIT(2)
3958
3959/* Start of AP S3->S0 transition (booting or resuming from suspend) */
3960#define EC_HANG_START_ON_RESUME       BIT(3)
3961
3962/* Reasons to cancel hang detection */
3963
3964/* Power button released */
3965#define EC_HANG_STOP_ON_POWER_RELEASE BIT(8)
3966
3967/* Any host command from AP received */
3968#define EC_HANG_STOP_ON_HOST_COMMAND  BIT(9)
3969
3970/* Stop on end of AP S0->S3 transition (suspending or shutting down) */
3971#define EC_HANG_STOP_ON_SUSPEND       BIT(10)
3972
3973/*
3974 * If this flag is set, all the other fields are ignored, and the hang detect
3975 * timer is started.  This provides the AP a way to start the hang timer
3976 * without reconfiguring any of the other hang detect settings.  Note that
3977 * you must previously have configured the timeouts.
3978 */
3979#define EC_HANG_START_NOW             BIT(30)
3980
3981/*
3982 * If this flag is set, all the other fields are ignored (including
3983 * EC_HANG_START_NOW).  This provides the AP a way to stop the hang timer
3984 * without reconfiguring any of the other hang detect settings.
3985 */
3986#define EC_HANG_STOP_NOW              BIT(31)
3987
3988struct ec_params_hang_detect {
3989	/* Flags; see EC_HANG_* */
3990	uint32_t flags;
3991
3992	/* Timeout in msec before generating host event, if enabled */
3993	uint16_t host_event_timeout_msec;
3994
3995	/* Timeout in msec before generating warm reboot, if enabled */
3996	uint16_t warm_reboot_timeout_msec;
3997} __ec_align4;
3998
3999/*****************************************************************************/
4000/* Commands for battery charging */
4001
4002/*
4003 * This is the single catch-all host command to exchange data regarding the
4004 * charge state machine (v2 and up).
4005 */
4006#define EC_CMD_CHARGE_STATE 0x00A0
4007
4008/* Subcommands for this host command */
4009enum charge_state_command {
4010	CHARGE_STATE_CMD_GET_STATE,
4011	CHARGE_STATE_CMD_GET_PARAM,
4012	CHARGE_STATE_CMD_SET_PARAM,
4013	CHARGE_STATE_NUM_CMDS
4014};
4015
4016/*
4017 * Known param numbers are defined here. Ranges are reserved for board-specific
4018 * params, which are handled by the particular implementations.
4019 */
4020enum charge_state_params {
4021	CS_PARAM_CHG_VOLTAGE,	      /* charger voltage limit */
4022	CS_PARAM_CHG_CURRENT,	      /* charger current limit */
4023	CS_PARAM_CHG_INPUT_CURRENT,   /* charger input current limit */
4024	CS_PARAM_CHG_STATUS,	      /* charger-specific status */
4025	CS_PARAM_CHG_OPTION,	      /* charger-specific options */
4026	CS_PARAM_LIMIT_POWER,	      /*
4027				       * Check if power is limited due to
4028				       * low battery and / or a weak external
4029				       * charger. READ ONLY.
4030				       */
4031	/* How many so far? */
4032	CS_NUM_BASE_PARAMS,
4033
4034	/* Range for CONFIG_CHARGER_PROFILE_OVERRIDE params */
4035	CS_PARAM_CUSTOM_PROFILE_MIN = 0x10000,
4036	CS_PARAM_CUSTOM_PROFILE_MAX = 0x1ffff,
4037
4038	/* Range for CONFIG_CHARGE_STATE_DEBUG params */
4039	CS_PARAM_DEBUG_MIN = 0x20000,
4040	CS_PARAM_DEBUG_CTL_MODE = 0x20000,
4041	CS_PARAM_DEBUG_MANUAL_MODE,
4042	CS_PARAM_DEBUG_SEEMS_DEAD,
4043	CS_PARAM_DEBUG_SEEMS_DISCONNECTED,
4044	CS_PARAM_DEBUG_BATT_REMOVED,
4045	CS_PARAM_DEBUG_MANUAL_CURRENT,
4046	CS_PARAM_DEBUG_MANUAL_VOLTAGE,
4047	CS_PARAM_DEBUG_MAX = 0x2ffff,
4048
4049	/* Other custom param ranges go here... */
4050};
4051
4052struct ec_params_charge_state {
4053	uint8_t cmd;				/* enum charge_state_command */
4054	union {
4055		/* get_state has no args */
4056
4057		struct __ec_todo_unpacked {
4058			uint32_t param;		/* enum charge_state_param */
4059		} get_param;
4060
4061		struct __ec_todo_unpacked {
4062			uint32_t param;		/* param to set */
4063			uint32_t value;		/* value to set */
4064		} set_param;
4065	};
4066} __ec_todo_packed;
4067
4068struct ec_response_charge_state {
4069	union {
4070		struct __ec_align4 {
4071			int ac;
4072			int chg_voltage;
4073			int chg_current;
4074			int chg_input_current;
4075			int batt_state_of_charge;
4076		} get_state;
4077
4078		struct __ec_align4 {
4079			uint32_t value;
4080		} get_param;
4081
4082		/* set_param returns no args */
4083	};
4084} __ec_align4;
4085
4086
4087/*
4088 * Set maximum battery charging current.
4089 */
4090#define EC_CMD_CHARGE_CURRENT_LIMIT 0x00A1
4091
4092struct ec_params_current_limit {
4093	uint32_t limit; /* in mA */
4094} __ec_align4;
4095
4096/*
4097 * Set maximum external voltage / current.
4098 */
4099#define EC_CMD_EXTERNAL_POWER_LIMIT 0x00A2
4100
4101/* Command v0 is used only on Spring and is obsolete + unsupported */
4102struct ec_params_external_power_limit_v1 {
4103	uint16_t current_lim; /* in mA, or EC_POWER_LIMIT_NONE to clear limit */
4104	uint16_t voltage_lim; /* in mV, or EC_POWER_LIMIT_NONE to clear limit */
4105} __ec_align2;
4106
4107#define EC_POWER_LIMIT_NONE 0xffff
4108
4109/*
4110 * Set maximum voltage & current of a dedicated charge port
4111 */
4112#define EC_CMD_OVERRIDE_DEDICATED_CHARGER_LIMIT 0x00A3
4113
4114struct ec_params_dedicated_charger_limit {
4115	uint16_t current_lim; /* in mA */
4116	uint16_t voltage_lim; /* in mV */
4117} __ec_align2;
4118
4119/*****************************************************************************/
4120/* Hibernate/Deep Sleep Commands */
4121
4122/* Set the delay before going into hibernation. */
4123#define EC_CMD_HIBERNATION_DELAY 0x00A8
4124
4125struct ec_params_hibernation_delay {
4126	/*
4127	 * Seconds to wait in G3 before hibernate.  Pass in 0 to read the
4128	 * current settings without changing them.
4129	 */
4130	uint32_t seconds;
4131} __ec_align4;
4132
4133struct ec_response_hibernation_delay {
4134	/*
4135	 * The current time in seconds in which the system has been in the G3
4136	 * state.  This value is reset if the EC transitions out of G3.
4137	 */
4138	uint32_t time_g3;
4139
4140	/*
4141	 * The current time remaining in seconds until the EC should hibernate.
4142	 * This value is also reset if the EC transitions out of G3.
4143	 */
4144	uint32_t time_remaining;
4145
4146	/*
4147	 * The current time in seconds that the EC should wait in G3 before
4148	 * hibernating.
4149	 */
4150	uint32_t hibernate_delay;
4151} __ec_align4;
4152
4153/* Inform the EC when entering a sleep state */
4154#define EC_CMD_HOST_SLEEP_EVENT 0x00A9
4155
4156enum host_sleep_event {
4157	HOST_SLEEP_EVENT_S3_SUSPEND   = 1,
4158	HOST_SLEEP_EVENT_S3_RESUME    = 2,
4159	HOST_SLEEP_EVENT_S0IX_SUSPEND = 3,
4160	HOST_SLEEP_EVENT_S0IX_RESUME  = 4,
4161	/* S3 suspend with additional enabled wake sources */
4162	HOST_SLEEP_EVENT_S3_WAKEABLE_SUSPEND = 5,
4163};
4164
4165struct ec_params_host_sleep_event {
4166	uint8_t sleep_event;
4167} __ec_align1;
4168
4169/*
4170 * Use a default timeout value (CONFIG_SLEEP_TIMEOUT_MS) for detecting sleep
4171 * transition failures
4172 */
4173#define EC_HOST_SLEEP_TIMEOUT_DEFAULT 0
4174
4175/* Disable timeout detection for this sleep transition */
4176#define EC_HOST_SLEEP_TIMEOUT_INFINITE 0xFFFF
4177
4178struct ec_params_host_sleep_event_v1 {
4179	/* The type of sleep being entered or exited. */
4180	uint8_t sleep_event;
4181
4182	/* Padding */
4183	uint8_t reserved;
4184	union {
4185		/* Parameters that apply for suspend messages. */
4186		struct {
4187			/*
4188			 * The timeout in milliseconds between when this message
4189			 * is received and when the EC will declare sleep
4190			 * transition failure if the sleep signal is not
4191			 * asserted.
4192			 */
4193			uint16_t sleep_timeout_ms;
4194		} suspend_params;
4195
4196		/* No parameters for non-suspend messages. */
4197	};
4198} __ec_align2;
4199
4200/* A timeout occurred when this bit is set */
4201#define EC_HOST_RESUME_SLEEP_TIMEOUT 0x80000000
4202
4203/*
4204 * The mask defining which bits correspond to the number of sleep transitions,
4205 * as well as the maximum number of suspend line transitions that will be
4206 * reported back to the host.
4207 */
4208#define EC_HOST_RESUME_SLEEP_TRANSITIONS_MASK 0x7FFFFFFF
4209
4210struct ec_response_host_sleep_event_v1 {
4211	union {
4212		/* Response fields that apply for resume messages. */
4213		struct {
4214			/*
4215			 * The number of sleep power signal transitions that
4216			 * occurred since the suspend message. The high bit
4217			 * indicates a timeout occurred.
4218			 */
4219			uint32_t sleep_transitions;
4220		} resume_response;
4221
4222		/* No response fields for non-resume messages. */
4223	};
4224} __ec_align4;
4225
4226/*****************************************************************************/
4227/* Device events */
4228#define EC_CMD_DEVICE_EVENT 0x00AA
4229
4230enum ec_device_event {
4231	EC_DEVICE_EVENT_TRACKPAD,
4232	EC_DEVICE_EVENT_DSP,
4233	EC_DEVICE_EVENT_WIFI,
4234	EC_DEVICE_EVENT_WLC,
4235};
4236
4237enum ec_device_event_param {
4238	/* Get and clear pending device events */
4239	EC_DEVICE_EVENT_PARAM_GET_CURRENT_EVENTS,
4240	/* Get device event mask */
4241	EC_DEVICE_EVENT_PARAM_GET_ENABLED_EVENTS,
4242	/* Set device event mask */
4243	EC_DEVICE_EVENT_PARAM_SET_ENABLED_EVENTS,
4244};
4245
4246#define EC_DEVICE_EVENT_MASK(event_code) BIT(event_code % 32)
4247
4248struct ec_params_device_event {
4249	uint32_t event_mask;
4250	uint8_t param;
4251} __ec_align_size1;
4252
4253struct ec_response_device_event {
4254	uint32_t event_mask;
4255} __ec_align4;
4256
4257/*****************************************************************************/
4258/* Smart battery pass-through */
4259
4260/* Get / Set 16-bit smart battery registers */
4261#define EC_CMD_SB_READ_WORD   0x00B0
4262#define EC_CMD_SB_WRITE_WORD  0x00B1
4263
4264/* Get / Set string smart battery parameters
4265 * formatted as SMBUS "block".
4266 */
4267#define EC_CMD_SB_READ_BLOCK  0x00B2
4268#define EC_CMD_SB_WRITE_BLOCK 0x00B3
4269
4270struct ec_params_sb_rd {
4271	uint8_t reg;
4272} __ec_align1;
4273
4274struct ec_response_sb_rd_word {
4275	uint16_t value;
4276} __ec_align2;
4277
4278struct ec_params_sb_wr_word {
4279	uint8_t reg;
4280	uint16_t value;
4281} __ec_align1;
4282
4283struct ec_response_sb_rd_block {
4284	uint8_t data[32];
4285} __ec_align1;
4286
4287struct ec_params_sb_wr_block {
4288	uint8_t reg;
4289	uint16_t data[32];
4290} __ec_align1;
4291
4292/*****************************************************************************/
4293/* Battery vendor parameters
4294 *
4295 * Get or set vendor-specific parameters in the battery. Implementations may
4296 * differ between boards or batteries. On a set operation, the response
4297 * contains the actual value set, which may be rounded or clipped from the
4298 * requested value.
4299 */
4300
4301#define EC_CMD_BATTERY_VENDOR_PARAM 0x00B4
4302
4303enum ec_battery_vendor_param_mode {
4304	BATTERY_VENDOR_PARAM_MODE_GET = 0,
4305	BATTERY_VENDOR_PARAM_MODE_SET,
4306};
4307
4308struct ec_params_battery_vendor_param {
4309	uint32_t param;
4310	uint32_t value;
4311	uint8_t mode;
4312} __ec_align_size1;
4313
4314struct ec_response_battery_vendor_param {
4315	uint32_t value;
4316} __ec_align4;
4317
4318/*****************************************************************************/
4319/*
4320 * Smart Battery Firmware Update Commands
4321 */
4322#define EC_CMD_SB_FW_UPDATE 0x00B5
4323
4324enum ec_sb_fw_update_subcmd {
4325	EC_SB_FW_UPDATE_PREPARE  = 0x0,
4326	EC_SB_FW_UPDATE_INFO     = 0x1, /*query sb info */
4327	EC_SB_FW_UPDATE_BEGIN    = 0x2, /*check if protected */
4328	EC_SB_FW_UPDATE_WRITE    = 0x3, /*check if protected */
4329	EC_SB_FW_UPDATE_END      = 0x4,
4330	EC_SB_FW_UPDATE_STATUS   = 0x5,
4331	EC_SB_FW_UPDATE_PROTECT  = 0x6,
4332	EC_SB_FW_UPDATE_MAX      = 0x7,
4333};
4334
4335#define SB_FW_UPDATE_CMD_WRITE_BLOCK_SIZE 32
4336#define SB_FW_UPDATE_CMD_STATUS_SIZE 2
4337#define SB_FW_UPDATE_CMD_INFO_SIZE 8
4338
4339struct ec_sb_fw_update_header {
4340	uint16_t subcmd;  /* enum ec_sb_fw_update_subcmd */
4341	uint16_t fw_id;   /* firmware id */
4342} __ec_align4;
4343
4344struct ec_params_sb_fw_update {
4345	struct ec_sb_fw_update_header hdr;
4346	union {
4347		/* EC_SB_FW_UPDATE_PREPARE  = 0x0 */
4348		/* EC_SB_FW_UPDATE_INFO     = 0x1 */
4349		/* EC_SB_FW_UPDATE_BEGIN    = 0x2 */
4350		/* EC_SB_FW_UPDATE_END      = 0x4 */
4351		/* EC_SB_FW_UPDATE_STATUS   = 0x5 */
4352		/* EC_SB_FW_UPDATE_PROTECT  = 0x6 */
4353		/* Those have no args */
4354
4355		/* EC_SB_FW_UPDATE_WRITE    = 0x3 */
4356		struct __ec_align4 {
4357			uint8_t  data[SB_FW_UPDATE_CMD_WRITE_BLOCK_SIZE];
4358		} write;
4359	};
4360} __ec_align4;
4361
4362struct ec_response_sb_fw_update {
4363	union {
4364		/* EC_SB_FW_UPDATE_INFO     = 0x1 */
4365		struct __ec_align1 {
4366			uint8_t data[SB_FW_UPDATE_CMD_INFO_SIZE];
4367		} info;
4368
4369		/* EC_SB_FW_UPDATE_STATUS   = 0x5 */
4370		struct __ec_align1 {
4371			uint8_t data[SB_FW_UPDATE_CMD_STATUS_SIZE];
4372		} status;
4373	};
4374} __ec_align1;
4375
4376/*
4377 * Entering Verified Boot Mode Command
4378 * Default mode is VBOOT_MODE_NORMAL if EC did not receive this command.
4379 * Valid Modes are: normal, developer, and recovery.
4380 */
4381#define EC_CMD_ENTERING_MODE 0x00B6
4382
4383struct ec_params_entering_mode {
4384	int vboot_mode;
4385} __ec_align4;
4386
4387#define VBOOT_MODE_NORMAL    0
4388#define VBOOT_MODE_DEVELOPER 1
4389#define VBOOT_MODE_RECOVERY  2
4390
4391/*****************************************************************************/
4392/*
4393 * I2C passthru protection command: Protects I2C tunnels against access on
4394 * certain addresses (board-specific).
4395 */
4396#define EC_CMD_I2C_PASSTHRU_PROTECT 0x00B7
4397
4398enum ec_i2c_passthru_protect_subcmd {
4399	EC_CMD_I2C_PASSTHRU_PROTECT_STATUS = 0x0,
4400	EC_CMD_I2C_PASSTHRU_PROTECT_ENABLE = 0x1,
4401};
4402
4403struct ec_params_i2c_passthru_protect {
4404	uint8_t subcmd;
4405	uint8_t port;		/* I2C port number */
4406} __ec_align1;
4407
4408struct ec_response_i2c_passthru_protect {
4409	uint8_t status;		/* Status flags (0: unlocked, 1: locked) */
4410} __ec_align1;
4411
4412
4413/*****************************************************************************/
4414/*
4415 * HDMI CEC commands
4416 *
4417 * These commands are for sending and receiving message via HDMI CEC
4418 */
4419
4420#define MAX_CEC_MSG_LEN 16
4421
4422/* CEC message from the AP to be written on the CEC bus */
4423#define EC_CMD_CEC_WRITE_MSG 0x00B8
4424
4425/**
4426 * struct ec_params_cec_write - Message to write to the CEC bus
4427 * @msg: message content to write to the CEC bus
4428 */
4429struct ec_params_cec_write {
4430	uint8_t msg[MAX_CEC_MSG_LEN];
4431} __ec_align1;
4432
4433/* Set various CEC parameters */
4434#define EC_CMD_CEC_SET 0x00BA
4435
4436/**
4437 * struct ec_params_cec_set - CEC parameters set
4438 * @cmd: parameter type, can be CEC_CMD_ENABLE or CEC_CMD_LOGICAL_ADDRESS
4439 * @val: in case cmd is CEC_CMD_ENABLE, this field can be 0 to disable CEC
4440 *	or 1 to enable CEC functionality, in case cmd is
4441 *	CEC_CMD_LOGICAL_ADDRESS, this field encodes the requested logical
4442 *	address between 0 and 15 or 0xff to unregister
4443 */
4444struct ec_params_cec_set {
4445	uint8_t cmd; /* enum cec_command */
4446	uint8_t val;
4447} __ec_align1;
4448
4449/* Read various CEC parameters */
4450#define EC_CMD_CEC_GET 0x00BB
4451
4452/**
4453 * struct ec_params_cec_get - CEC parameters get
4454 * @cmd: parameter type, can be CEC_CMD_ENABLE or CEC_CMD_LOGICAL_ADDRESS
4455 */
4456struct ec_params_cec_get {
4457	uint8_t cmd; /* enum cec_command */
4458} __ec_align1;
4459
4460/**
4461 * struct ec_response_cec_get - CEC parameters get response
4462 * @val: in case cmd was CEC_CMD_ENABLE, this field will 0 if CEC is
4463 *	disabled or 1 if CEC functionality is enabled,
4464 *	in case cmd was CEC_CMD_LOGICAL_ADDRESS, this will encode the
4465 *	configured logical address between 0 and 15 or 0xff if unregistered
4466 */
4467struct ec_response_cec_get {
4468	uint8_t val;
4469} __ec_align1;
4470
4471/* CEC parameters command */
4472enum cec_command {
4473	/* CEC reading, writing and events enable */
4474	CEC_CMD_ENABLE,
4475	/* CEC logical address  */
4476	CEC_CMD_LOGICAL_ADDRESS,
4477};
4478
4479/* Events from CEC to AP */
4480enum mkbp_cec_event {
4481	/* Outgoing message was acknowledged by a follower */
4482	EC_MKBP_CEC_SEND_OK			= BIT(0),
4483	/* Outgoing message was not acknowledged */
4484	EC_MKBP_CEC_SEND_FAILED			= BIT(1),
4485};
4486
4487/*****************************************************************************/
4488
4489/* Commands for audio codec. */
4490#define EC_CMD_EC_CODEC 0x00BC
4491
4492enum ec_codec_subcmd {
4493	EC_CODEC_GET_CAPABILITIES = 0x0,
4494	EC_CODEC_GET_SHM_ADDR = 0x1,
4495	EC_CODEC_SET_SHM_ADDR = 0x2,
4496	EC_CODEC_SUBCMD_COUNT,
4497};
4498
4499enum ec_codec_cap {
4500	EC_CODEC_CAP_WOV_AUDIO_SHM = 0,
4501	EC_CODEC_CAP_WOV_LANG_SHM = 1,
4502	EC_CODEC_CAP_LAST = 32,
4503};
4504
4505enum ec_codec_shm_id {
4506	EC_CODEC_SHM_ID_WOV_AUDIO = 0x0,
4507	EC_CODEC_SHM_ID_WOV_LANG = 0x1,
4508	EC_CODEC_SHM_ID_LAST,
4509};
4510
4511enum ec_codec_shm_type {
4512	EC_CODEC_SHM_TYPE_EC_RAM = 0x0,
4513	EC_CODEC_SHM_TYPE_SYSTEM_RAM = 0x1,
4514};
4515
4516struct __ec_align1 ec_param_ec_codec_get_shm_addr {
4517	uint8_t shm_id;
4518	uint8_t reserved[3];
4519};
4520
4521struct __ec_align4 ec_param_ec_codec_set_shm_addr {
4522	uint64_t phys_addr;
4523	uint32_t len;
4524	uint8_t shm_id;
4525	uint8_t reserved[3];
4526};
4527
4528struct __ec_align4 ec_param_ec_codec {
4529	uint8_t cmd; /* enum ec_codec_subcmd */
4530	uint8_t reserved[3];
4531
4532	union {
4533		struct ec_param_ec_codec_get_shm_addr
4534				get_shm_addr_param;
4535		struct ec_param_ec_codec_set_shm_addr
4536				set_shm_addr_param;
4537	};
4538};
4539
4540struct __ec_align4 ec_response_ec_codec_get_capabilities {
4541	uint32_t capabilities;
4542};
4543
4544struct __ec_align4 ec_response_ec_codec_get_shm_addr {
4545	uint64_t phys_addr;
4546	uint32_t len;
4547	uint8_t type;
4548	uint8_t reserved[3];
4549};
4550
4551/*****************************************************************************/
4552
4553/* Commands for DMIC on audio codec. */
4554#define EC_CMD_EC_CODEC_DMIC 0x00BD
4555
4556enum ec_codec_dmic_subcmd {
4557	EC_CODEC_DMIC_GET_MAX_GAIN = 0x0,
4558	EC_CODEC_DMIC_SET_GAIN_IDX = 0x1,
4559	EC_CODEC_DMIC_GET_GAIN_IDX = 0x2,
4560	EC_CODEC_DMIC_SUBCMD_COUNT,
4561};
4562
4563enum ec_codec_dmic_channel {
4564	EC_CODEC_DMIC_CHANNEL_0 = 0x0,
4565	EC_CODEC_DMIC_CHANNEL_1 = 0x1,
4566	EC_CODEC_DMIC_CHANNEL_2 = 0x2,
4567	EC_CODEC_DMIC_CHANNEL_3 = 0x3,
4568	EC_CODEC_DMIC_CHANNEL_4 = 0x4,
4569	EC_CODEC_DMIC_CHANNEL_5 = 0x5,
4570	EC_CODEC_DMIC_CHANNEL_6 = 0x6,
4571	EC_CODEC_DMIC_CHANNEL_7 = 0x7,
4572	EC_CODEC_DMIC_CHANNEL_COUNT,
4573};
4574
4575struct __ec_align1 ec_param_ec_codec_dmic_set_gain_idx {
4576	uint8_t channel; /* enum ec_codec_dmic_channel */
4577	uint8_t gain;
4578	uint8_t reserved[2];
4579};
4580
4581struct __ec_align1 ec_param_ec_codec_dmic_get_gain_idx {
4582	uint8_t channel; /* enum ec_codec_dmic_channel */
4583	uint8_t reserved[3];
4584};
4585
4586struct __ec_align4 ec_param_ec_codec_dmic {
4587	uint8_t cmd; /* enum ec_codec_dmic_subcmd */
4588	uint8_t reserved[3];
4589
4590	union {
4591		struct ec_param_ec_codec_dmic_set_gain_idx
4592				set_gain_idx_param;
4593		struct ec_param_ec_codec_dmic_get_gain_idx
4594				get_gain_idx_param;
4595	};
4596};
4597
4598struct __ec_align1 ec_response_ec_codec_dmic_get_max_gain {
4599	uint8_t max_gain;
4600};
4601
4602struct __ec_align1 ec_response_ec_codec_dmic_get_gain_idx {
4603	uint8_t gain;
4604};
4605
4606/*****************************************************************************/
4607
4608/* Commands for I2S RX on audio codec. */
4609
4610#define EC_CMD_EC_CODEC_I2S_RX 0x00BE
4611
4612enum ec_codec_i2s_rx_subcmd {
4613	EC_CODEC_I2S_RX_ENABLE = 0x0,
4614	EC_CODEC_I2S_RX_DISABLE = 0x1,
4615	EC_CODEC_I2S_RX_SET_SAMPLE_DEPTH = 0x2,
4616	EC_CODEC_I2S_RX_SET_DAIFMT = 0x3,
4617	EC_CODEC_I2S_RX_SET_BCLK = 0x4,
4618	EC_CODEC_I2S_RX_RESET = 0x5,
4619	EC_CODEC_I2S_RX_SUBCMD_COUNT,
4620};
4621
4622enum ec_codec_i2s_rx_sample_depth {
4623	EC_CODEC_I2S_RX_SAMPLE_DEPTH_16 = 0x0,
4624	EC_CODEC_I2S_RX_SAMPLE_DEPTH_24 = 0x1,
4625	EC_CODEC_I2S_RX_SAMPLE_DEPTH_COUNT,
4626};
4627
4628enum ec_codec_i2s_rx_daifmt {
4629	EC_CODEC_I2S_RX_DAIFMT_I2S = 0x0,
4630	EC_CODEC_I2S_RX_DAIFMT_RIGHT_J = 0x1,
4631	EC_CODEC_I2S_RX_DAIFMT_LEFT_J = 0x2,
4632	EC_CODEC_I2S_RX_DAIFMT_COUNT,
4633};
4634
4635struct __ec_align1 ec_param_ec_codec_i2s_rx_set_sample_depth {
4636	uint8_t depth;
4637	uint8_t reserved[3];
4638};
4639
4640struct __ec_align1 ec_param_ec_codec_i2s_rx_set_gain {
4641	uint8_t left;
4642	uint8_t right;
4643	uint8_t reserved[2];
4644};
4645
4646struct __ec_align1 ec_param_ec_codec_i2s_rx_set_daifmt {
4647	uint8_t daifmt;
4648	uint8_t reserved[3];
4649};
4650
4651struct __ec_align4 ec_param_ec_codec_i2s_rx_set_bclk {
4652	uint32_t bclk;
4653};
4654
4655struct __ec_align4 ec_param_ec_codec_i2s_rx {
4656	uint8_t cmd; /* enum ec_codec_i2s_rx_subcmd */
4657	uint8_t reserved[3];
4658
4659	union {
4660		struct ec_param_ec_codec_i2s_rx_set_sample_depth
4661				set_sample_depth_param;
4662		struct ec_param_ec_codec_i2s_rx_set_daifmt
4663				set_daifmt_param;
4664		struct ec_param_ec_codec_i2s_rx_set_bclk
4665				set_bclk_param;
4666	};
4667};
4668
4669/*****************************************************************************/
4670/* Commands for WoV on audio codec. */
4671
4672#define EC_CMD_EC_CODEC_WOV 0x00BF
4673
4674enum ec_codec_wov_subcmd {
4675	EC_CODEC_WOV_SET_LANG = 0x0,
4676	EC_CODEC_WOV_SET_LANG_SHM = 0x1,
4677	EC_CODEC_WOV_GET_LANG = 0x2,
4678	EC_CODEC_WOV_ENABLE = 0x3,
4679	EC_CODEC_WOV_DISABLE = 0x4,
4680	EC_CODEC_WOV_READ_AUDIO = 0x5,
4681	EC_CODEC_WOV_READ_AUDIO_SHM = 0x6,
4682	EC_CODEC_WOV_SUBCMD_COUNT,
4683};
4684
4685/*
4686 * @hash is SHA256 of the whole language model.
4687 * @total_len indicates the length of whole language model.
4688 * @offset is the cursor from the beginning of the model.
4689 * @buf is the packet buffer.
4690 * @len denotes how many bytes in the buf.
4691 */
4692struct __ec_align4 ec_param_ec_codec_wov_set_lang {
4693	uint8_t hash[32];
4694	uint32_t total_len;
4695	uint32_t offset;
4696	uint8_t buf[128];
4697	uint32_t len;
4698};
4699
4700struct __ec_align4 ec_param_ec_codec_wov_set_lang_shm {
4701	uint8_t hash[32];
4702	uint32_t total_len;
4703};
4704
4705struct __ec_align4 ec_param_ec_codec_wov {
4706	uint8_t cmd; /* enum ec_codec_wov_subcmd */
4707	uint8_t reserved[3];
4708
4709	union {
4710		struct ec_param_ec_codec_wov_set_lang
4711				set_lang_param;
4712		struct ec_param_ec_codec_wov_set_lang_shm
4713				set_lang_shm_param;
4714	};
4715};
4716
4717struct __ec_align4 ec_response_ec_codec_wov_get_lang {
4718	uint8_t hash[32];
4719};
4720
4721struct __ec_align4 ec_response_ec_codec_wov_read_audio {
4722	uint8_t buf[128];
4723	uint32_t len;
4724};
4725
4726struct __ec_align4 ec_response_ec_codec_wov_read_audio_shm {
4727	uint32_t offset;
4728	uint32_t len;
4729};
4730
4731/*****************************************************************************/
4732/* System commands */
4733
4734/*
4735 * TODO(crosbug.com/p/23747): This is a confusing name, since it doesn't
4736 * necessarily reboot the EC.  Rename to "image" or something similar?
4737 */
4738#define EC_CMD_REBOOT_EC 0x00D2
4739
4740/* Command */
4741enum ec_reboot_cmd {
4742	EC_REBOOT_CANCEL = 0,        /* Cancel a pending reboot */
4743	EC_REBOOT_JUMP_RO = 1,       /* Jump to RO without rebooting */
4744	EC_REBOOT_JUMP_RW = 2,       /* Jump to active RW without rebooting */
4745	/* (command 3 was jump to RW-B) */
4746	EC_REBOOT_COLD = 4,          /* Cold-reboot */
4747	EC_REBOOT_DISABLE_JUMP = 5,  /* Disable jump until next reboot */
4748	EC_REBOOT_HIBERNATE = 6,     /* Hibernate EC */
4749	EC_REBOOT_HIBERNATE_CLEAR_AP_OFF = 7, /* and clears AP_OFF flag */
4750	EC_REBOOT_COLD_AP_OFF = 8,   /* Cold-reboot and don't boot AP */
4751};
4752
4753/* Flags for ec_params_reboot_ec.reboot_flags */
4754#define EC_REBOOT_FLAG_RESERVED0      BIT(0)  /* Was recovery request */
4755#define EC_REBOOT_FLAG_ON_AP_SHUTDOWN BIT(1)  /* Reboot after AP shutdown */
4756#define EC_REBOOT_FLAG_SWITCH_RW_SLOT BIT(2)  /* Switch RW slot */
4757
4758struct ec_params_reboot_ec {
4759	uint8_t cmd;           /* enum ec_reboot_cmd */
4760	uint8_t flags;         /* See EC_REBOOT_FLAG_* */
4761} __ec_align1;
4762
4763/*
4764 * Get information on last EC panic.
4765 *
4766 * Returns variable-length platform-dependent panic information.  See panic.h
4767 * for details.
4768 */
4769#define EC_CMD_GET_PANIC_INFO 0x00D3
4770
4771/*****************************************************************************/
4772/*
4773 * Special commands
4774 *
4775 * These do not follow the normal rules for commands.  See each command for
4776 * details.
4777 */
4778
4779/*
4780 * Reboot NOW
4781 *
4782 * This command will work even when the EC LPC interface is busy, because the
4783 * reboot command is processed at interrupt level.  Note that when the EC
4784 * reboots, the host will reboot too, so there is no response to this command.
4785 *
4786 * Use EC_CMD_REBOOT_EC to reboot the EC more politely.
4787 */
4788#define EC_CMD_REBOOT 0x00D1  /* Think "die" */
4789
4790/*
4791 * Resend last response (not supported on LPC).
4792 *
4793 * Returns EC_RES_UNAVAILABLE if there is no response available - for example,
4794 * there was no previous command, or the previous command's response was too
4795 * big to save.
4796 */
4797#define EC_CMD_RESEND_RESPONSE 0x00DB
4798
4799/*
4800 * This header byte on a command indicate version 0. Any header byte less
4801 * than this means that we are talking to an old EC which doesn't support
4802 * versioning. In that case, we assume version 0.
4803 *
4804 * Header bytes greater than this indicate a later version. For example,
4805 * EC_CMD_VERSION0 + 1 means we are using version 1.
4806 *
4807 * The old EC interface must not use commands 0xdc or higher.
4808 */
4809#define EC_CMD_VERSION0 0x00DC
4810
4811/*****************************************************************************/
4812/*
4813 * PD commands
4814 *
4815 * These commands are for PD MCU communication.
4816 */
4817
4818/* EC to PD MCU exchange status command */
4819#define EC_CMD_PD_EXCHANGE_STATUS 0x0100
4820#define EC_VER_PD_EXCHANGE_STATUS 2
4821
4822enum pd_charge_state {
4823	PD_CHARGE_NO_CHANGE = 0, /* Don't change charge state */
4824	PD_CHARGE_NONE,          /* No charging allowed */
4825	PD_CHARGE_5V,            /* 5V charging only */
4826	PD_CHARGE_MAX            /* Charge at max voltage */
4827};
4828
4829/* Status of EC being sent to PD */
4830#define EC_STATUS_HIBERNATING	BIT(0)
4831
4832struct ec_params_pd_status {
4833	uint8_t status;       /* EC status */
4834	int8_t batt_soc;      /* battery state of charge */
4835	uint8_t charge_state; /* charging state (from enum pd_charge_state) */
4836} __ec_align1;
4837
4838/* Status of PD being sent back to EC */
4839#define PD_STATUS_HOST_EVENT      BIT(0) /* Forward host event to AP */
4840#define PD_STATUS_IN_RW           BIT(1) /* Running RW image */
4841#define PD_STATUS_JUMPED_TO_IMAGE BIT(2) /* Current image was jumped to */
4842#define PD_STATUS_TCPC_ALERT_0    BIT(3) /* Alert active in port 0 TCPC */
4843#define PD_STATUS_TCPC_ALERT_1    BIT(4) /* Alert active in port 1 TCPC */
4844#define PD_STATUS_TCPC_ALERT_2    BIT(5) /* Alert active in port 2 TCPC */
4845#define PD_STATUS_TCPC_ALERT_3    BIT(6) /* Alert active in port 3 TCPC */
4846#define PD_STATUS_EC_INT_ACTIVE  (PD_STATUS_TCPC_ALERT_0 | \
4847				      PD_STATUS_TCPC_ALERT_1 | \
4848				      PD_STATUS_HOST_EVENT)
4849struct ec_response_pd_status {
4850	uint32_t curr_lim_ma;       /* input current limit */
4851	uint16_t status;            /* PD MCU status */
4852	int8_t active_charge_port;  /* active charging port */
4853} __ec_align_size1;
4854
4855/* AP to PD MCU host event status command, cleared on read */
4856#define EC_CMD_PD_HOST_EVENT_STATUS 0x0104
4857
4858/* PD MCU host event status bits */
4859#define PD_EVENT_UPDATE_DEVICE     BIT(0)
4860#define PD_EVENT_POWER_CHANGE      BIT(1)
4861#define PD_EVENT_IDENTITY_RECEIVED BIT(2)
4862#define PD_EVENT_DATA_SWAP         BIT(3)
4863struct ec_response_host_event_status {
4864	uint32_t status;      /* PD MCU host event status */
4865} __ec_align4;
4866
4867/* Set USB type-C port role and muxes */
4868#define EC_CMD_USB_PD_CONTROL 0x0101
4869
4870enum usb_pd_control_role {
4871	USB_PD_CTRL_ROLE_NO_CHANGE = 0,
4872	USB_PD_CTRL_ROLE_TOGGLE_ON = 1, /* == AUTO */
4873	USB_PD_CTRL_ROLE_TOGGLE_OFF = 2,
4874	USB_PD_CTRL_ROLE_FORCE_SINK = 3,
4875	USB_PD_CTRL_ROLE_FORCE_SOURCE = 4,
4876	USB_PD_CTRL_ROLE_FREEZE = 5,
4877	USB_PD_CTRL_ROLE_COUNT
4878};
4879
4880enum usb_pd_control_mux {
4881	USB_PD_CTRL_MUX_NO_CHANGE = 0,
4882	USB_PD_CTRL_MUX_NONE = 1,
4883	USB_PD_CTRL_MUX_USB = 2,
4884	USB_PD_CTRL_MUX_DP = 3,
4885	USB_PD_CTRL_MUX_DOCK = 4,
4886	USB_PD_CTRL_MUX_AUTO = 5,
4887	USB_PD_CTRL_MUX_COUNT
4888};
4889
4890enum usb_pd_control_swap {
4891	USB_PD_CTRL_SWAP_NONE = 0,
4892	USB_PD_CTRL_SWAP_DATA = 1,
4893	USB_PD_CTRL_SWAP_POWER = 2,
4894	USB_PD_CTRL_SWAP_VCONN = 3,
4895	USB_PD_CTRL_SWAP_COUNT
4896};
4897
4898struct ec_params_usb_pd_control {
4899	uint8_t port;
4900	uint8_t role;
4901	uint8_t mux;
4902	uint8_t swap;
4903} __ec_align1;
4904
4905#define PD_CTRL_RESP_ENABLED_COMMS      BIT(0) /* Communication enabled */
4906#define PD_CTRL_RESP_ENABLED_CONNECTED  BIT(1) /* Device connected */
4907#define PD_CTRL_RESP_ENABLED_PD_CAPABLE BIT(2) /* Partner is PD capable */
4908
4909#define PD_CTRL_RESP_ROLE_POWER         BIT(0) /* 0=SNK/1=SRC */
4910#define PD_CTRL_RESP_ROLE_DATA          BIT(1) /* 0=UFP/1=DFP */
4911#define PD_CTRL_RESP_ROLE_VCONN         BIT(2) /* Vconn status */
4912#define PD_CTRL_RESP_ROLE_DR_POWER      BIT(3) /* Partner is dualrole power */
4913#define PD_CTRL_RESP_ROLE_DR_DATA       BIT(4) /* Partner is dualrole data */
4914#define PD_CTRL_RESP_ROLE_USB_COMM      BIT(5) /* Partner USB comm capable */
4915#define PD_CTRL_RESP_ROLE_EXT_POWERED   BIT(6) /* Partner externally powerd */
4916
4917struct ec_response_usb_pd_control {
4918	uint8_t enabled;
4919	uint8_t role;
4920	uint8_t polarity;
4921	uint8_t state;
4922} __ec_align1;
4923
4924struct ec_response_usb_pd_control_v1 {
4925	uint8_t enabled;
4926	uint8_t role;
4927	uint8_t polarity;
4928	char state[32];
4929} __ec_align1;
4930
4931/* Values representing usbc PD CC state */
4932#define USBC_PD_CC_NONE		0 /* No accessory connected */
4933#define USBC_PD_CC_NO_UFP	1 /* No UFP accessory connected */
4934#define USBC_PD_CC_AUDIO_ACC	2 /* Audio accessory connected */
4935#define USBC_PD_CC_DEBUG_ACC	3 /* Debug accessory connected */
4936#define USBC_PD_CC_UFP_ATTACHED	4 /* UFP attached to usbc */
4937#define USBC_PD_CC_DFP_ATTACHED	5 /* DPF attached to usbc */
4938
4939/* Active/Passive Cable */
4940#define USB_PD_CTRL_ACTIVE_CABLE        BIT(0)
4941/* Optical/Non-optical cable */
4942#define USB_PD_CTRL_OPTICAL_CABLE       BIT(1)
4943/* 3rd Gen TBT device (or AMA)/2nd gen tbt Adapter */
4944#define USB_PD_CTRL_TBT_LEGACY_ADAPTER  BIT(2)
4945/* Active Link Uni-Direction */
4946#define USB_PD_CTRL_ACTIVE_LINK_UNIDIR  BIT(3)
4947
4948struct ec_response_usb_pd_control_v2 {
4949	uint8_t enabled;
4950	uint8_t role;
4951	uint8_t polarity;
4952	char state[32];
4953	uint8_t cc_state;	/* enum pd_cc_states representing cc state */
4954	uint8_t dp_mode;	/* Current DP pin mode (MODE_DP_PIN_[A-E]) */
4955	uint8_t reserved;	/* Reserved for future use */
4956	uint8_t control_flags;	/* USB_PD_CTRL_*flags */
4957	uint8_t cable_speed;	/* TBT_SS_* cable speed */
4958	uint8_t cable_gen;	/* TBT_GEN3_* cable rounded support */
4959} __ec_align1;
4960
4961#define EC_CMD_USB_PD_PORTS 0x0102
4962
4963/* Maximum number of PD ports on a device, num_ports will be <= this */
4964#define EC_USB_PD_MAX_PORTS 8
4965
4966struct ec_response_usb_pd_ports {
4967	uint8_t num_ports;
4968} __ec_align1;
4969
4970#define EC_CMD_USB_PD_POWER_INFO 0x0103
4971
4972#define PD_POWER_CHARGING_PORT 0xff
4973struct ec_params_usb_pd_power_info {
4974	uint8_t port;
4975} __ec_align1;
4976
4977enum usb_chg_type {
4978	USB_CHG_TYPE_NONE,
4979	USB_CHG_TYPE_PD,
4980	USB_CHG_TYPE_C,
4981	USB_CHG_TYPE_PROPRIETARY,
4982	USB_CHG_TYPE_BC12_DCP,
4983	USB_CHG_TYPE_BC12_CDP,
4984	USB_CHG_TYPE_BC12_SDP,
4985	USB_CHG_TYPE_OTHER,
4986	USB_CHG_TYPE_VBUS,
4987	USB_CHG_TYPE_UNKNOWN,
4988	USB_CHG_TYPE_DEDICATED,
4989};
4990enum usb_power_roles {
4991	USB_PD_PORT_POWER_DISCONNECTED,
4992	USB_PD_PORT_POWER_SOURCE,
4993	USB_PD_PORT_POWER_SINK,
4994	USB_PD_PORT_POWER_SINK_NOT_CHARGING,
4995};
4996
4997struct usb_chg_measures {
4998	uint16_t voltage_max;
4999	uint16_t voltage_now;
5000	uint16_t current_max;
5001	uint16_t current_lim;
5002} __ec_align2;
5003
5004struct ec_response_usb_pd_power_info {
5005	uint8_t role;
5006	uint8_t type;
5007	uint8_t dualrole;
5008	uint8_t reserved1;
5009	struct usb_chg_measures meas;
5010	uint32_t max_power;
5011} __ec_align4;
5012
5013
5014/*
5015 * This command will return the number of USB PD charge port + the number
5016 * of dedicated port present.
5017 * EC_CMD_USB_PD_PORTS does NOT include the dedicated ports
5018 */
5019#define EC_CMD_CHARGE_PORT_COUNT 0x0105
5020struct ec_response_charge_port_count {
5021	uint8_t port_count;
5022} __ec_align1;
5023
5024/* Write USB-PD device FW */
5025#define EC_CMD_USB_PD_FW_UPDATE 0x0110
5026
5027enum usb_pd_fw_update_cmds {
5028	USB_PD_FW_REBOOT,
5029	USB_PD_FW_FLASH_ERASE,
5030	USB_PD_FW_FLASH_WRITE,
5031	USB_PD_FW_ERASE_SIG,
5032};
5033
5034struct ec_params_usb_pd_fw_update {
5035	uint16_t dev_id;
5036	uint8_t cmd;
5037	uint8_t port;
5038	uint32_t size;     /* Size to write in bytes */
5039	/* Followed by data to write */
5040} __ec_align4;
5041
5042/* Write USB-PD Accessory RW_HASH table entry */
5043#define EC_CMD_USB_PD_RW_HASH_ENTRY 0x0111
5044/* RW hash is first 20 bytes of SHA-256 of RW section */
5045#define PD_RW_HASH_SIZE 20
5046struct ec_params_usb_pd_rw_hash_entry {
5047	uint16_t dev_id;
5048	uint8_t dev_rw_hash[PD_RW_HASH_SIZE];
5049	uint8_t reserved;        /*
5050				  * For alignment of current_image
5051				  * TODO(rspangler) but it's not aligned!
5052				  * Should have been reserved[2].
5053				  */
5054	uint32_t current_image;  /* One of ec_current_image */
5055} __ec_align1;
5056
5057/* Read USB-PD Accessory info */
5058#define EC_CMD_USB_PD_DEV_INFO 0x0112
5059
5060struct ec_params_usb_pd_info_request {
5061	uint8_t port;
5062} __ec_align1;
5063
5064/* Read USB-PD Device discovery info */
5065#define EC_CMD_USB_PD_DISCOVERY 0x0113
5066struct ec_params_usb_pd_discovery_entry {
5067	uint16_t vid;  /* USB-IF VID */
5068	uint16_t pid;  /* USB-IF PID */
5069	uint8_t ptype; /* product type (hub,periph,cable,ama) */
5070} __ec_align_size1;
5071
5072/* Override default charge behavior */
5073#define EC_CMD_PD_CHARGE_PORT_OVERRIDE 0x0114
5074
5075/* Negative port parameters have special meaning */
5076enum usb_pd_override_ports {
5077	OVERRIDE_DONT_CHARGE = -2,
5078	OVERRIDE_OFF = -1,
5079	/* [0, CONFIG_USB_PD_PORT_COUNT): Port# */
5080};
5081
5082struct ec_params_charge_port_override {
5083	int16_t override_port; /* Override port# */
5084} __ec_align2;
5085
5086/*
5087 * Read (and delete) one entry of PD event log.
5088 * TODO(crbug.com/751742): Make this host command more generic to accommodate
5089 * future non-PD logs that use the same internal EC event_log.
5090 */
5091#define EC_CMD_PD_GET_LOG_ENTRY 0x0115
5092
5093struct ec_response_pd_log {
5094	uint32_t timestamp; /* relative timestamp in milliseconds */
5095	uint8_t type;       /* event type : see PD_EVENT_xx below */
5096	uint8_t size_port;  /* [7:5] port number [4:0] payload size in bytes */
5097	uint16_t data;      /* type-defined data payload */
5098	uint8_t payload[];  /* optional additional data payload: 0..16 bytes */
5099} __ec_align4;
5100
5101/* The timestamp is the microsecond counter shifted to get about a ms. */
5102#define PD_LOG_TIMESTAMP_SHIFT 10 /* 1 LSB = 1024us */
5103
5104#define PD_LOG_SIZE_MASK  0x1f
5105#define PD_LOG_PORT_MASK  0xe0
5106#define PD_LOG_PORT_SHIFT    5
5107#define PD_LOG_PORT_SIZE(port, size) (((port) << PD_LOG_PORT_SHIFT) | \
5108				      ((size) & PD_LOG_SIZE_MASK))
5109#define PD_LOG_PORT(size_port) ((size_port) >> PD_LOG_PORT_SHIFT)
5110#define PD_LOG_SIZE(size_port) ((size_port) & PD_LOG_SIZE_MASK)
5111
5112/* PD event log : entry types */
5113/* PD MCU events */
5114#define PD_EVENT_MCU_BASE       0x00
5115#define PD_EVENT_MCU_CHARGE             (PD_EVENT_MCU_BASE+0)
5116#define PD_EVENT_MCU_CONNECT            (PD_EVENT_MCU_BASE+1)
5117/* Reserved for custom board event */
5118#define PD_EVENT_MCU_BOARD_CUSTOM       (PD_EVENT_MCU_BASE+2)
5119/* PD generic accessory events */
5120#define PD_EVENT_ACC_BASE       0x20
5121#define PD_EVENT_ACC_RW_FAIL   (PD_EVENT_ACC_BASE+0)
5122#define PD_EVENT_ACC_RW_ERASE  (PD_EVENT_ACC_BASE+1)
5123/* PD power supply events */
5124#define PD_EVENT_PS_BASE        0x40
5125#define PD_EVENT_PS_FAULT      (PD_EVENT_PS_BASE+0)
5126/* PD video dongles events */
5127#define PD_EVENT_VIDEO_BASE     0x60
5128#define PD_EVENT_VIDEO_DP_MODE (PD_EVENT_VIDEO_BASE+0)
5129#define PD_EVENT_VIDEO_CODEC   (PD_EVENT_VIDEO_BASE+1)
5130/* Returned in the "type" field, when there is no entry available */
5131#define PD_EVENT_NO_ENTRY       0xff
5132
5133/*
5134 * PD_EVENT_MCU_CHARGE event definition :
5135 * the payload is "struct usb_chg_measures"
5136 * the data field contains the port state flags as defined below :
5137 */
5138/* Port partner is a dual role device */
5139#define CHARGE_FLAGS_DUAL_ROLE         BIT(15)
5140/* Port is the pending override port */
5141#define CHARGE_FLAGS_DELAYED_OVERRIDE  BIT(14)
5142/* Port is the override port */
5143#define CHARGE_FLAGS_OVERRIDE          BIT(13)
5144/* Charger type */
5145#define CHARGE_FLAGS_TYPE_SHIFT               3
5146#define CHARGE_FLAGS_TYPE_MASK       (0xf << CHARGE_FLAGS_TYPE_SHIFT)
5147/* Power delivery role */
5148#define CHARGE_FLAGS_ROLE_MASK         (7 <<  0)
5149
5150/*
5151 * PD_EVENT_PS_FAULT data field flags definition :
5152 */
5153#define PS_FAULT_OCP                          1
5154#define PS_FAULT_FAST_OCP                     2
5155#define PS_FAULT_OVP                          3
5156#define PS_FAULT_DISCH                        4
5157
5158/*
5159 * PD_EVENT_VIDEO_CODEC payload is "struct mcdp_info".
5160 */
5161struct mcdp_version {
5162	uint8_t major;
5163	uint8_t minor;
5164	uint16_t build;
5165} __ec_align4;
5166
5167struct mcdp_info {
5168	uint8_t family[2];
5169	uint8_t chipid[2];
5170	struct mcdp_version irom;
5171	struct mcdp_version fw;
5172} __ec_align4;
5173
5174/* struct mcdp_info field decoding */
5175#define MCDP_CHIPID(chipid) ((chipid[0] << 8) | chipid[1])
5176#define MCDP_FAMILY(family) ((family[0] << 8) | family[1])
5177
5178/* Get/Set USB-PD Alternate mode info */
5179#define EC_CMD_USB_PD_GET_AMODE 0x0116
5180struct ec_params_usb_pd_get_mode_request {
5181	uint16_t svid_idx; /* SVID index to get */
5182	uint8_t port;      /* port */
5183} __ec_align_size1;
5184
5185struct ec_params_usb_pd_get_mode_response {
5186	uint16_t svid;   /* SVID */
5187	uint16_t opos;    /* Object Position */
5188	uint32_t vdo[6]; /* Mode VDOs */
5189} __ec_align4;
5190
5191#define EC_CMD_USB_PD_SET_AMODE 0x0117
5192
5193enum pd_mode_cmd {
5194	PD_EXIT_MODE = 0,
5195	PD_ENTER_MODE = 1,
5196	/* Not a command.  Do NOT remove. */
5197	PD_MODE_CMD_COUNT,
5198};
5199
5200struct ec_params_usb_pd_set_mode_request {
5201	uint32_t cmd;  /* enum pd_mode_cmd */
5202	uint16_t svid; /* SVID to set */
5203	uint8_t opos;  /* Object Position */
5204	uint8_t port;  /* port */
5205} __ec_align4;
5206
5207/* Ask the PD MCU to record a log of a requested type */
5208#define EC_CMD_PD_WRITE_LOG_ENTRY 0x0118
5209
5210struct ec_params_pd_write_log_entry {
5211	uint8_t type; /* event type : see PD_EVENT_xx above */
5212	uint8_t port; /* port#, or 0 for events unrelated to a given port */
5213} __ec_align1;
5214
5215
5216/* Control USB-PD chip */
5217#define EC_CMD_PD_CONTROL 0x0119
5218
5219enum ec_pd_control_cmd {
5220	PD_SUSPEND = 0,      /* Suspend the PD chip (EC: stop talking to PD) */
5221	PD_RESUME,           /* Resume the PD chip (EC: start talking to PD) */
5222	PD_RESET,            /* Force reset the PD chip */
5223	PD_CONTROL_DISABLE,  /* Disable further calls to this command */
5224	PD_CHIP_ON,          /* Power on the PD chip */
5225};
5226
5227struct ec_params_pd_control {
5228	uint8_t chip;         /* chip id */
5229	uint8_t subcmd;
5230} __ec_align1;
5231
5232/* Get info about USB-C SS muxes */
5233#define EC_CMD_USB_PD_MUX_INFO 0x011A
5234
5235struct ec_params_usb_pd_mux_info {
5236	uint8_t port; /* USB-C port number */
5237} __ec_align1;
5238
5239/* Flags representing mux state */
5240#define USB_PD_MUX_NONE               0      /* Open switch */
5241#define USB_PD_MUX_USB_ENABLED        BIT(0) /* USB connected */
5242#define USB_PD_MUX_DP_ENABLED         BIT(1) /* DP connected */
5243#define USB_PD_MUX_POLARITY_INVERTED  BIT(2) /* CC line Polarity inverted */
5244#define USB_PD_MUX_HPD_IRQ            BIT(3) /* HPD IRQ is asserted */
5245#define USB_PD_MUX_HPD_LVL            BIT(4) /* HPD level is asserted */
5246#define USB_PD_MUX_SAFE_MODE          BIT(5) /* DP is in safe mode */
5247#define USB_PD_MUX_TBT_COMPAT_ENABLED BIT(6) /* TBT compat enabled */
5248#define USB_PD_MUX_USB4_ENABLED       BIT(7) /* USB4 enabled */
5249
5250struct ec_response_usb_pd_mux_info {
5251	uint8_t flags; /* USB_PD_MUX_*-encoded USB mux state */
5252} __ec_align1;
5253
5254#define EC_CMD_PD_CHIP_INFO		0x011B
5255
5256struct ec_params_pd_chip_info {
5257	uint8_t port;	/* USB-C port number */
5258	uint8_t renew;	/* Force renewal */
5259} __ec_align1;
5260
5261struct ec_response_pd_chip_info {
5262	uint16_t vendor_id;
5263	uint16_t product_id;
5264	uint16_t device_id;
5265	union {
5266		uint8_t fw_version_string[8];
5267		uint64_t fw_version_number;
5268	};
5269} __ec_align2;
5270
5271struct ec_response_pd_chip_info_v1 {
5272	uint16_t vendor_id;
5273	uint16_t product_id;
5274	uint16_t device_id;
5275	union {
5276		uint8_t fw_version_string[8];
5277		uint64_t fw_version_number;
5278	};
5279	union {
5280		uint8_t min_req_fw_version_string[8];
5281		uint64_t min_req_fw_version_number;
5282	};
5283} __ec_align2;
5284
5285/* Run RW signature verification and get status */
5286#define EC_CMD_RWSIG_CHECK_STATUS	0x011C
5287
5288struct ec_response_rwsig_check_status {
5289	uint32_t status;
5290} __ec_align4;
5291
5292/* For controlling RWSIG task */
5293#define EC_CMD_RWSIG_ACTION	0x011D
5294
5295enum rwsig_action {
5296	RWSIG_ACTION_ABORT = 0,		/* Abort RWSIG and prevent jumping */
5297	RWSIG_ACTION_CONTINUE = 1,	/* Jump to RW immediately */
5298};
5299
5300struct ec_params_rwsig_action {
5301	uint32_t action;
5302} __ec_align4;
5303
5304/* Run verification on a slot */
5305#define EC_CMD_EFS_VERIFY	0x011E
5306
5307struct ec_params_efs_verify {
5308	uint8_t region;		/* enum ec_flash_region */
5309} __ec_align1;
5310
5311/*
5312 * Retrieve info from Cros Board Info store. Response is based on the data
5313 * type. Integers return a uint32. Strings return a string, using the response
5314 * size to determine how big it is.
5315 */
5316#define EC_CMD_GET_CROS_BOARD_INFO	0x011F
5317/*
5318 * Write info into Cros Board Info on EEPROM. Write fails if the board has
5319 * hardware write-protect enabled.
5320 */
5321#define EC_CMD_SET_CROS_BOARD_INFO	0x0120
5322
5323enum cbi_data_tag {
5324	CBI_TAG_BOARD_VERSION = 0, /* uint32_t or smaller */
5325	CBI_TAG_OEM_ID = 1,        /* uint32_t or smaller */
5326	CBI_TAG_SKU_ID = 2,        /* uint32_t or smaller */
5327	CBI_TAG_DRAM_PART_NUM = 3, /* variable length ascii, nul terminated. */
5328	CBI_TAG_OEM_NAME = 4,      /* variable length ascii, nul terminated. */
5329	CBI_TAG_MODEL_ID = 5,      /* uint32_t or smaller */
5330	CBI_TAG_COUNT,
5331};
5332
5333/*
5334 * Flags to control read operation
5335 *
5336 * RELOAD:  Invalidate cache and read data from EEPROM. Useful to verify
5337 *          write was successful without reboot.
5338 */
5339#define CBI_GET_RELOAD		BIT(0)
5340
5341struct ec_params_get_cbi {
5342	uint32_t tag;		/* enum cbi_data_tag */
5343	uint32_t flag;		/* CBI_GET_* */
5344} __ec_align4;
5345
5346/*
5347 * Flags to control write behavior.
5348 *
5349 * NO_SYNC: Makes EC update data in RAM but skip writing to EEPROM. It's
5350 *          useful when writing multiple fields in a row.
5351 * INIT:    Need to be set when creating a new CBI from scratch. All fields
5352 *          will be initialized to zero first.
5353 */
5354#define CBI_SET_NO_SYNC		BIT(0)
5355#define CBI_SET_INIT		BIT(1)
5356
5357struct ec_params_set_cbi {
5358	uint32_t tag;		/* enum cbi_data_tag */
5359	uint32_t flag;		/* CBI_SET_* */
5360	uint32_t size;		/* Data size */
5361	uint8_t data[];		/* For string and raw data */
5362} __ec_align1;
5363
5364/*
5365 * Information about resets of the AP by the EC and the EC's own uptime.
5366 */
5367#define EC_CMD_GET_UPTIME_INFO 0x0121
5368
5369struct ec_response_uptime_info {
5370	/*
5371	 * Number of milliseconds since the last EC boot. Sysjump resets
5372	 * typically do not restart the EC's time_since_boot epoch.
5373	 *
5374	 * WARNING: The EC's sense of time is much less accurate than the AP's
5375	 * sense of time, in both phase and frequency.  This timebase is similar
5376	 * to CLOCK_MONOTONIC_RAW, but with 1% or more frequency error.
5377	 */
5378	uint32_t time_since_ec_boot_ms;
5379
5380	/*
5381	 * Number of times the AP was reset by the EC since the last EC boot.
5382	 * Note that the AP may be held in reset by the EC during the initial
5383	 * boot sequence, such that the very first AP boot may count as more
5384	 * than one here.
5385	 */
5386	uint32_t ap_resets_since_ec_boot;
5387
5388	/*
5389	 * The set of flags which describe the EC's most recent reset.  See
5390	 * include/system.h RESET_FLAG_* for details.
5391	 */
5392	uint32_t ec_reset_flags;
5393
5394	/* Empty log entries have both the cause and timestamp set to zero. */
5395	struct ap_reset_log_entry {
5396		/*
5397		 * See include/chipset.h: enum chipset_{reset,shutdown}_reason
5398		 * for details.
5399		 */
5400		uint16_t reset_cause;
5401
5402		/* Reserved for protocol growth. */
5403		uint16_t reserved;
5404
5405		/*
5406		 * The time of the reset's assertion, in milliseconds since the
5407		 * last EC boot, in the same epoch as time_since_ec_boot_ms.
5408		 * Set to zero if the log entry is empty.
5409		 */
5410		uint32_t reset_time_ms;
5411	} recent_ap_reset[4];
5412} __ec_align4;
5413
5414/*
5415 * Add entropy to the device secret (stored in the rollback region).
5416 *
5417 * Depending on the chip, the operation may take a long time (e.g. to erase
5418 * flash), so the commands are asynchronous.
5419 */
5420#define EC_CMD_ADD_ENTROPY	0x0122
5421
5422enum add_entropy_action {
5423	/* Add entropy to the current secret. */
5424	ADD_ENTROPY_ASYNC = 0,
5425	/*
5426	 * Add entropy, and also make sure that the previous secret is erased.
5427	 * (this can be implemented by adding entropy multiple times until
5428	 * all rolback blocks have been overwritten).
5429	 */
5430	ADD_ENTROPY_RESET_ASYNC = 1,
5431	/* Read back result from the previous operation. */
5432	ADD_ENTROPY_GET_RESULT = 2,
5433};
5434
5435struct ec_params_rollback_add_entropy {
5436	uint8_t action;
5437} __ec_align1;
5438
5439/*
5440 * Perform a single read of a given ADC channel.
5441 */
5442#define EC_CMD_ADC_READ		0x0123
5443
5444struct ec_params_adc_read {
5445	uint8_t adc_channel;
5446} __ec_align1;
5447
5448struct ec_response_adc_read {
5449	int32_t adc_value;
5450} __ec_align4;
5451
5452/*
5453 * Read back rollback info
5454 */
5455#define EC_CMD_ROLLBACK_INFO		0x0124
5456
5457struct ec_response_rollback_info {
5458	int32_t id; /* Incrementing number to indicate which region to use. */
5459	int32_t rollback_min_version;
5460	int32_t rw_rollback_version;
5461} __ec_align4;
5462
5463
5464/* Issue AP reset */
5465#define EC_CMD_AP_RESET 0x0125
5466
5467/**
5468 * Get the number of peripheral charge ports
5469 */
5470#define EC_CMD_PCHG_COUNT 0x0134
5471
5472#define EC_PCHG_MAX_PORTS 8
5473
5474struct ec_response_pchg_count {
5475	uint8_t port_count;
5476} __ec_align1;
5477
5478/**
5479 * Get the status of a peripheral charge port
5480 */
5481#define EC_CMD_PCHG 0x0135
5482
5483struct ec_params_pchg {
5484	uint8_t port;
5485} __ec_align1;
5486
5487struct ec_response_pchg {
5488	uint32_t error;			/* enum pchg_error */
5489	uint8_t state;			/* enum pchg_state state */
5490	uint8_t battery_percentage;
5491	uint8_t unused0;
5492	uint8_t unused1;
5493	/* Fields added in version 1 */
5494	uint32_t fw_version;
5495	uint32_t dropped_event_count;
5496} __ec_align2;
5497
5498enum pchg_state {
5499	/* Charger is reset and not initialized. */
5500	PCHG_STATE_RESET = 0,
5501	/* Charger is initialized or disabled. */
5502	PCHG_STATE_INITIALIZED,
5503	/* Charger is enabled and ready to detect a device. */
5504	PCHG_STATE_ENABLED,
5505	/* Device is in proximity. */
5506	PCHG_STATE_DETECTED,
5507	/* Device is being charged. */
5508	PCHG_STATE_CHARGING,
5509	/* Device is fully charged. It implies DETECTED (& not charging). */
5510	PCHG_STATE_FULL,
5511	/* In download (a.k.a. firmware update) mode */
5512	PCHG_STATE_DOWNLOAD,
5513	/* In download mode. Ready for receiving data. */
5514	PCHG_STATE_DOWNLOADING,
5515	/* Device is ready for data communication. */
5516	PCHG_STATE_CONNECTED,
5517	/* Put no more entry below */
5518	PCHG_STATE_COUNT,
5519};
5520
5521#define EC_PCHG_STATE_TEXT { \
5522	[PCHG_STATE_RESET] = "RESET", \
5523	[PCHG_STATE_INITIALIZED] = "INITIALIZED", \
5524	[PCHG_STATE_ENABLED] = "ENABLED", \
5525	[PCHG_STATE_DETECTED] = "DETECTED", \
5526	[PCHG_STATE_CHARGING] = "CHARGING", \
5527	[PCHG_STATE_FULL] = "FULL", \
5528	[PCHG_STATE_DOWNLOAD] = "DOWNLOAD", \
5529	[PCHG_STATE_DOWNLOADING] = "DOWNLOADING", \
5530	[PCHG_STATE_CONNECTED] = "CONNECTED", \
5531	}
5532
5533/*
5534 * Update firmware of peripheral chip
5535 */
5536#define EC_CMD_PCHG_UPDATE 0x0136
5537
5538/* Port number is encoded in bit[28:31]. */
5539#define EC_MKBP_PCHG_PORT_SHIFT		28
5540/* Utility macro for converting MKBP event to port number. */
5541#define EC_MKBP_PCHG_EVENT_TO_PORT(e)	(((e) >> EC_MKBP_PCHG_PORT_SHIFT) & 0xf)
5542/* Utility macro for extracting event bits. */
5543#define EC_MKBP_PCHG_EVENT_MASK(e)	((e) \
5544					& GENMASK(EC_MKBP_PCHG_PORT_SHIFT-1, 0))
5545
5546#define EC_MKBP_PCHG_UPDATE_OPENED	BIT(0)
5547#define EC_MKBP_PCHG_WRITE_COMPLETE	BIT(1)
5548#define EC_MKBP_PCHG_UPDATE_CLOSED	BIT(2)
5549#define EC_MKBP_PCHG_UPDATE_ERROR	BIT(3)
5550#define EC_MKBP_PCHG_DEVICE_EVENT	BIT(4)
5551
5552enum ec_pchg_update_cmd {
5553	/* Reset chip to normal mode. */
5554	EC_PCHG_UPDATE_CMD_RESET_TO_NORMAL = 0,
5555	/* Reset and put a chip in update (a.k.a. download) mode. */
5556	EC_PCHG_UPDATE_CMD_OPEN,
5557	/* Write a block of data containing FW image. */
5558	EC_PCHG_UPDATE_CMD_WRITE,
5559	/* Close update session. */
5560	EC_PCHG_UPDATE_CMD_CLOSE,
5561	/* End of commands */
5562	EC_PCHG_UPDATE_CMD_COUNT,
5563};
5564
5565struct ec_params_pchg_update {
5566	/* PCHG port number */
5567	uint8_t port;
5568	/* enum ec_pchg_update_cmd */
5569	uint8_t cmd;
5570	/* Padding */
5571	uint8_t reserved0;
5572	uint8_t reserved1;
5573	/* Version of new firmware */
5574	uint32_t version;
5575	/* CRC32 of new firmware */
5576	uint32_t crc32;
5577	/* Address in chip memory where <data> is written to */
5578	uint32_t addr;
5579	/* Size of <data> */
5580	uint32_t size;
5581	/* Partial data of new firmware */
5582	uint8_t data[];
5583} __ec_align4;
5584
5585BUILD_ASSERT(EC_PCHG_UPDATE_CMD_COUNT
5586	     < BIT(sizeof(((struct ec_params_pchg_update *)0)->cmd)*8));
5587
5588struct ec_response_pchg_update {
5589	/* Block size */
5590	uint32_t block_size;
5591} __ec_align4;
5592
5593
5594/*****************************************************************************/
5595/* Voltage regulator controls */
5596
5597/*
5598 * Get basic info of voltage regulator for given index.
5599 *
5600 * Returns the regulator name and supported voltage list in mV.
5601 */
5602#define EC_CMD_REGULATOR_GET_INFO 0x012C
5603
5604/* Maximum length of regulator name */
5605#define EC_REGULATOR_NAME_MAX_LEN 16
5606
5607/* Maximum length of the supported voltage list. */
5608#define EC_REGULATOR_VOLTAGE_MAX_COUNT 16
5609
5610struct ec_params_regulator_get_info {
5611	uint32_t index;
5612} __ec_align4;
5613
5614struct ec_response_regulator_get_info {
5615	char name[EC_REGULATOR_NAME_MAX_LEN];
5616	uint16_t num_voltages;
5617	uint16_t voltages_mv[EC_REGULATOR_VOLTAGE_MAX_COUNT];
5618} __ec_align2;
5619
5620/*
5621 * Configure the regulator as enabled / disabled.
5622 */
5623#define EC_CMD_REGULATOR_ENABLE 0x012D
5624
5625struct ec_params_regulator_enable {
5626	uint32_t index;
5627	uint8_t enable;
5628} __ec_align4;
5629
5630/*
5631 * Query if the regulator is enabled.
5632 *
5633 * Returns 1 if the regulator is enabled, 0 if not.
5634 */
5635#define EC_CMD_REGULATOR_IS_ENABLED 0x012E
5636
5637struct ec_params_regulator_is_enabled {
5638	uint32_t index;
5639} __ec_align4;
5640
5641struct ec_response_regulator_is_enabled {
5642	uint8_t enabled;
5643} __ec_align1;
5644
5645/*
5646 * Set voltage for the voltage regulator within the range specified.
5647 *
5648 * The driver should select the voltage in range closest to min_mv.
5649 *
5650 * Also note that this might be called before the regulator is enabled, and the
5651 * setting should be in effect after the regulator is enabled.
5652 */
5653#define EC_CMD_REGULATOR_SET_VOLTAGE 0x012F
5654
5655struct ec_params_regulator_set_voltage {
5656	uint32_t index;
5657	uint32_t min_mv;
5658	uint32_t max_mv;
5659} __ec_align4;
5660
5661/*
5662 * Get the currently configured voltage for the voltage regulator.
5663 *
5664 * Note that this might be called before the regulator is enabled, and this
5665 * should return the configured output voltage if the regulator is enabled.
5666 */
5667#define EC_CMD_REGULATOR_GET_VOLTAGE 0x0130
5668
5669struct ec_params_regulator_get_voltage {
5670	uint32_t index;
5671} __ec_align4;
5672
5673struct ec_response_regulator_get_voltage {
5674	uint32_t voltage_mv;
5675} __ec_align4;
5676
5677/*
5678 * Gather all discovery information for the given port and partner type.
5679 *
5680 * Note that if discovery has not yet completed, only the currently completed
5681 * responses will be filled in.   If the discovery data structures are changed
5682 * in the process of the command running, BUSY will be returned.
5683 *
5684 * VDO field sizes are set to the maximum possible number of VDOs a VDM may
5685 * contain, while the number of SVIDs here is selected to fit within the PROTO2
5686 * maximum parameter size.
5687 */
5688#define EC_CMD_TYPEC_DISCOVERY 0x0131
5689
5690enum typec_partner_type {
5691	TYPEC_PARTNER_SOP = 0,
5692	TYPEC_PARTNER_SOP_PRIME = 1,
5693};
5694
5695struct ec_params_typec_discovery {
5696	uint8_t port;
5697	uint8_t partner_type; /* enum typec_partner_type */
5698} __ec_align1;
5699
5700struct svid_mode_info {
5701	uint16_t svid;
5702	uint16_t mode_count;  /* Number of modes partner sent */
5703	uint32_t mode_vdo[6]; /* Max VDOs allowed after VDM header is 6 */
5704};
5705
5706struct ec_response_typec_discovery {
5707	uint8_t identity_count;    /* Number of identity VDOs partner sent */
5708	uint8_t svid_count;	   /* Number of SVIDs partner sent */
5709	uint16_t reserved;
5710	uint32_t discovery_vdo[6]; /* Max VDOs allowed after VDM header is 6 */
5711	struct svid_mode_info svids[];
5712} __ec_align1;
5713
5714/* USB Type-C commands for AP-controlled device policy. */
5715#define EC_CMD_TYPEC_CONTROL 0x0132
5716
5717enum typec_control_command {
5718	TYPEC_CONTROL_COMMAND_EXIT_MODES,
5719	TYPEC_CONTROL_COMMAND_CLEAR_EVENTS,
5720	TYPEC_CONTROL_COMMAND_ENTER_MODE,
5721};
5722
5723struct ec_params_typec_control {
5724	uint8_t port;
5725	uint8_t command;	/* enum typec_control_command */
5726	uint16_t reserved;
5727
5728	/*
5729	 * This section will be interpreted based on |command|. Define a
5730	 * placeholder structure to avoid having to increase the size and bump
5731	 * the command version when adding new sub-commands.
5732	 */
5733	union {
5734		uint32_t clear_events_mask;
5735		uint8_t mode_to_enter;      /* enum typec_mode */
5736		uint8_t placeholder[128];
5737	};
5738} __ec_align1;
5739
5740/*
5741 * Gather all status information for a port.
5742 *
5743 * Note: this covers many of the return fields from the deprecated
5744 * EC_CMD_USB_PD_CONTROL command, except those that are redundant with the
5745 * discovery data.  The "enum pd_cc_states" is defined with the deprecated
5746 * EC_CMD_USB_PD_CONTROL command.
5747 *
5748 * This also combines in the EC_CMD_USB_PD_MUX_INFO flags.
5749 */
5750#define EC_CMD_TYPEC_STATUS 0x0133
5751
5752/*
5753 * Power role.
5754 *
5755 * Note this is also used for PD header creation, and values align to those in
5756 * the Power Delivery Specification Revision 3.0 (See
5757 * 6.2.1.1.4 Port Power Role).
5758 */
5759enum pd_power_role {
5760	PD_ROLE_SINK = 0,
5761	PD_ROLE_SOURCE = 1
5762};
5763
5764/*
5765 * Data role.
5766 *
5767 * Note this is also used for PD header creation, and the first two values
5768 * align to those in the Power Delivery Specification Revision 3.0 (See
5769 * 6.2.1.1.6 Port Data Role).
5770 */
5771enum pd_data_role {
5772	PD_ROLE_UFP = 0,
5773	PD_ROLE_DFP = 1,
5774	PD_ROLE_DISCONNECTED = 2,
5775};
5776
5777enum pd_vconn_role {
5778	PD_ROLE_VCONN_OFF = 0,
5779	PD_ROLE_VCONN_SRC = 1,
5780};
5781
5782/*
5783 * Note: BIT(0) may be used to determine whether the polarity is CC1 or CC2,
5784 * regardless of whether a debug accessory is connected.
5785 */
5786enum tcpc_cc_polarity {
5787	/*
5788	 * _CCx: is used to indicate the polarity while not connected to
5789	 * a Debug Accessory.  Only one CC line will assert a resistor and
5790	 * the other will be open.
5791	 */
5792	POLARITY_CC1 = 0,
5793	POLARITY_CC2 = 1,
5794
5795	/*
5796	 * _CCx_DTS is used to indicate the polarity while connected to a
5797	 * SRC Debug Accessory.  Assert resistors on both lines.
5798	 */
5799	POLARITY_CC1_DTS = 2,
5800	POLARITY_CC2_DTS = 3,
5801
5802	/*
5803	 * The current TCPC code relies on these specific POLARITY values.
5804	 * Adding in a check to verify if the list grows for any reason
5805	 * that this will give a hint that other places need to be
5806	 * adjusted.
5807	 */
5808	POLARITY_COUNT
5809};
5810
5811#define PD_STATUS_EVENT_SOP_DISC_DONE		BIT(0)
5812#define PD_STATUS_EVENT_SOP_PRIME_DISC_DONE	BIT(1)
5813#define PD_STATUS_EVENT_HARD_RESET		BIT(2)
5814
5815struct ec_params_typec_status {
5816	uint8_t port;
5817} __ec_align1;
5818
5819struct ec_response_typec_status {
5820	uint8_t pd_enabled;		/* PD communication enabled - bool */
5821	uint8_t dev_connected;		/* Device connected - bool */
5822	uint8_t sop_connected;		/* Device is SOP PD capable - bool */
5823	uint8_t source_cap_count;	/* Number of Source Cap PDOs */
5824
5825	uint8_t power_role;		/* enum pd_power_role */
5826	uint8_t data_role;		/* enum pd_data_role */
5827	uint8_t vconn_role;		/* enum pd_vconn_role */
5828	uint8_t sink_cap_count;		/* Number of Sink Cap PDOs */
5829
5830	uint8_t polarity;		/* enum tcpc_cc_polarity */
5831	uint8_t cc_state;		/* enum pd_cc_states */
5832	uint8_t dp_pin;			/* DP pin mode (MODE_DP_IN_[A-E]) */
5833	uint8_t mux_state;		/* USB_PD_MUX* - encoded mux state */
5834
5835	char tc_state[32];		/* TC state name */
5836
5837	uint32_t events;		/* PD_STATUS_EVENT bitmask */
5838
5839	/*
5840	 * BCD PD revisions for partners
5841	 *
5842	 * The format has the PD major reversion in the upper nibble, and PD
5843	 * minor version in the next nibble.  Following two nibbles are
5844	 * currently 0.
5845	 * ex. PD 3.2 would map to 0x3200
5846	 *
5847	 * PD major/minor will be 0 if no PD device is connected.
5848	 */
5849	uint16_t sop_revision;
5850	uint16_t sop_prime_revision;
5851
5852	uint32_t source_cap_pdos[7];	/* Max 7 PDOs can be present */
5853
5854	uint32_t sink_cap_pdos[7];	/* Max 7 PDOs can be present */
5855} __ec_align1;
5856
5857/*****************************************************************************/
5858/* The command range 0x200-0x2FF is reserved for Rotor. */
5859
5860/*****************************************************************************/
5861/*
5862 * Reserve a range of host commands for the CR51 firmware.
5863 */
5864#define EC_CMD_CR51_BASE 0x0300
5865#define EC_CMD_CR51_LAST 0x03FF
5866
5867/*****************************************************************************/
5868/* Fingerprint MCU commands: range 0x0400-0x040x */
5869
5870/* Fingerprint SPI sensor passthru command: prototyping ONLY */
5871#define EC_CMD_FP_PASSTHRU 0x0400
5872
5873#define EC_FP_FLAG_NOT_COMPLETE 0x1
5874
5875struct ec_params_fp_passthru {
5876	uint16_t len;		/* Number of bytes to write then read */
5877	uint16_t flags;		/* EC_FP_FLAG_xxx */
5878	uint8_t data[];		/* Data to send */
5879} __ec_align2;
5880
5881/* Configure the Fingerprint MCU behavior */
5882#define EC_CMD_FP_MODE 0x0402
5883
5884/* Put the sensor in its lowest power mode */
5885#define FP_MODE_DEEPSLEEP      BIT(0)
5886/* Wait to see a finger on the sensor */
5887#define FP_MODE_FINGER_DOWN    BIT(1)
5888/* Poll until the finger has left the sensor */
5889#define FP_MODE_FINGER_UP      BIT(2)
5890/* Capture the current finger image */
5891#define FP_MODE_CAPTURE        BIT(3)
5892/* Finger enrollment session on-going */
5893#define FP_MODE_ENROLL_SESSION BIT(4)
5894/* Enroll the current finger image */
5895#define FP_MODE_ENROLL_IMAGE   BIT(5)
5896/* Try to match the current finger image */
5897#define FP_MODE_MATCH          BIT(6)
5898/* Reset and re-initialize the sensor. */
5899#define FP_MODE_RESET_SENSOR   BIT(7)
5900/* special value: don't change anything just read back current mode */
5901#define FP_MODE_DONT_CHANGE    BIT(31)
5902
5903#define FP_VALID_MODES (FP_MODE_DEEPSLEEP      | \
5904			FP_MODE_FINGER_DOWN    | \
5905			FP_MODE_FINGER_UP      | \
5906			FP_MODE_CAPTURE        | \
5907			FP_MODE_ENROLL_SESSION | \
5908			FP_MODE_ENROLL_IMAGE   | \
5909			FP_MODE_MATCH          | \
5910			FP_MODE_RESET_SENSOR   | \
5911			FP_MODE_DONT_CHANGE)
5912
5913/* Capture types defined in bits [30..28] */
5914#define FP_MODE_CAPTURE_TYPE_SHIFT 28
5915#define FP_MODE_CAPTURE_TYPE_MASK  (0x7 << FP_MODE_CAPTURE_TYPE_SHIFT)
5916/*
5917 * This enum must remain ordered, if you add new values you must ensure that
5918 * FP_CAPTURE_TYPE_MAX is still the last one.
5919 */
5920enum fp_capture_type {
5921	/* Full blown vendor-defined capture (produces 'frame_size' bytes) */
5922	FP_CAPTURE_VENDOR_FORMAT = 0,
5923	/* Simple raw image capture (produces width x height x bpp bits) */
5924	FP_CAPTURE_SIMPLE_IMAGE = 1,
5925	/* Self test pattern (e.g. checkerboard) */
5926	FP_CAPTURE_PATTERN0 = 2,
5927	/* Self test pattern (e.g. inverted checkerboard) */
5928	FP_CAPTURE_PATTERN1 = 3,
5929	/* Capture for Quality test with fixed contrast */
5930	FP_CAPTURE_QUALITY_TEST = 4,
5931	/* Capture for pixel reset value test */
5932	FP_CAPTURE_RESET_TEST = 5,
5933	FP_CAPTURE_TYPE_MAX,
5934};
5935/* Extracts the capture type from the sensor 'mode' word */
5936#define FP_CAPTURE_TYPE(mode) (((mode) & FP_MODE_CAPTURE_TYPE_MASK) \
5937				       >> FP_MODE_CAPTURE_TYPE_SHIFT)
5938
5939struct ec_params_fp_mode {
5940	uint32_t mode; /* as defined by FP_MODE_ constants */
5941} __ec_align4;
5942
5943struct ec_response_fp_mode {
5944	uint32_t mode; /* as defined by FP_MODE_ constants */
5945} __ec_align4;
5946
5947/* Retrieve Fingerprint sensor information */
5948#define EC_CMD_FP_INFO 0x0403
5949
5950/* Number of dead pixels detected on the last maintenance */
5951#define FP_ERROR_DEAD_PIXELS(errors) ((errors) & 0x3FF)
5952/* Unknown number of dead pixels detected on the last maintenance */
5953#define FP_ERROR_DEAD_PIXELS_UNKNOWN (0x3FF)
5954/* No interrupt from the sensor */
5955#define FP_ERROR_NO_IRQ    BIT(12)
5956/* SPI communication error */
5957#define FP_ERROR_SPI_COMM  BIT(13)
5958/* Invalid sensor Hardware ID */
5959#define FP_ERROR_BAD_HWID  BIT(14)
5960/* Sensor initialization failed */
5961#define FP_ERROR_INIT_FAIL BIT(15)
5962
5963struct ec_response_fp_info_v0 {
5964	/* Sensor identification */
5965	uint32_t vendor_id;
5966	uint32_t product_id;
5967	uint32_t model_id;
5968	uint32_t version;
5969	/* Image frame characteristics */
5970	uint32_t frame_size;
5971	uint32_t pixel_format; /* using V4L2_PIX_FMT_ */
5972	uint16_t width;
5973	uint16_t height;
5974	uint16_t bpp;
5975	uint16_t errors; /* see FP_ERROR_ flags above */
5976} __ec_align4;
5977
5978struct ec_response_fp_info {
5979	/* Sensor identification */
5980	uint32_t vendor_id;
5981	uint32_t product_id;
5982	uint32_t model_id;
5983	uint32_t version;
5984	/* Image frame characteristics */
5985	uint32_t frame_size;
5986	uint32_t pixel_format; /* using V4L2_PIX_FMT_ */
5987	uint16_t width;
5988	uint16_t height;
5989	uint16_t bpp;
5990	uint16_t errors; /* see FP_ERROR_ flags above */
5991	/* Template/finger current information */
5992	uint32_t template_size;  /* max template size in bytes */
5993	uint16_t template_max;   /* maximum number of fingers/templates */
5994	uint16_t template_valid; /* number of valid fingers/templates */
5995	uint32_t template_dirty; /* bitmap of templates with MCU side changes */
5996	uint32_t template_version; /* version of the template format */
5997} __ec_align4;
5998
5999/* Get the last captured finger frame or a template content */
6000#define EC_CMD_FP_FRAME 0x0404
6001
6002/* constants defining the 'offset' field which also contains the frame index */
6003#define FP_FRAME_INDEX_SHIFT       28
6004/* Frame buffer where the captured image is stored */
6005#define FP_FRAME_INDEX_RAW_IMAGE    0
6006/* First frame buffer holding a template */
6007#define FP_FRAME_INDEX_TEMPLATE     1
6008#define FP_FRAME_GET_BUFFER_INDEX(offset) ((offset) >> FP_FRAME_INDEX_SHIFT)
6009#define FP_FRAME_OFFSET_MASK       0x0FFFFFFF
6010
6011/* Version of the format of the encrypted templates. */
6012#define FP_TEMPLATE_FORMAT_VERSION 3
6013
6014/* Constants for encryption parameters */
6015#define FP_CONTEXT_NONCE_BYTES 12
6016#define FP_CONTEXT_USERID_WORDS (32 / sizeof(uint32_t))
6017#define FP_CONTEXT_TAG_BYTES 16
6018#define FP_CONTEXT_SALT_BYTES 16
6019#define FP_CONTEXT_TPM_BYTES 32
6020
6021struct ec_fp_template_encryption_metadata {
6022	/*
6023	 * Version of the structure format (N=3).
6024	 */
6025	uint16_t struct_version;
6026	/* Reserved bytes, set to 0. */
6027	uint16_t reserved;
6028	/*
6029	 * The salt is *only* ever used for key derivation. The nonce is unique,
6030	 * a different one is used for every message.
6031	 */
6032	uint8_t nonce[FP_CONTEXT_NONCE_BYTES];
6033	uint8_t salt[FP_CONTEXT_SALT_BYTES];
6034	uint8_t tag[FP_CONTEXT_TAG_BYTES];
6035};
6036
6037struct ec_params_fp_frame {
6038	/*
6039	 * The offset contains the template index or FP_FRAME_INDEX_RAW_IMAGE
6040	 * in the high nibble, and the real offset within the frame in
6041	 * FP_FRAME_OFFSET_MASK.
6042	 */
6043	uint32_t offset;
6044	uint32_t size;
6045} __ec_align4;
6046
6047/* Load a template into the MCU */
6048#define EC_CMD_FP_TEMPLATE 0x0405
6049
6050/* Flag in the 'size' field indicating that the full template has been sent */
6051#define FP_TEMPLATE_COMMIT 0x80000000
6052
6053struct ec_params_fp_template {
6054	uint32_t offset;
6055	uint32_t size;
6056	uint8_t data[];
6057} __ec_align4;
6058
6059/* Clear the current fingerprint user context and set a new one */
6060#define EC_CMD_FP_CONTEXT 0x0406
6061
6062struct ec_params_fp_context {
6063	uint32_t userid[FP_CONTEXT_USERID_WORDS];
6064} __ec_align4;
6065
6066#define EC_CMD_FP_STATS 0x0407
6067
6068#define FPSTATS_CAPTURE_INV  BIT(0)
6069#define FPSTATS_MATCHING_INV BIT(1)
6070
6071struct ec_response_fp_stats {
6072	uint32_t capture_time_us;
6073	uint32_t matching_time_us;
6074	uint32_t overall_time_us;
6075	struct {
6076		uint32_t lo;
6077		uint32_t hi;
6078	} overall_t0;
6079	uint8_t timestamps_invalid;
6080	int8_t template_matched;
6081} __ec_align2;
6082
6083#define EC_CMD_FP_SEED 0x0408
6084struct ec_params_fp_seed {
6085	/*
6086	 * Version of the structure format (N=3).
6087	 */
6088	uint16_t struct_version;
6089	/* Reserved bytes, set to 0. */
6090	uint16_t reserved;
6091	/* Seed from the TPM. */
6092	uint8_t seed[FP_CONTEXT_TPM_BYTES];
6093} __ec_align4;
6094
6095#define EC_CMD_FP_ENC_STATUS 0x0409
6096
6097/* FP TPM seed has been set or not */
6098#define FP_ENC_STATUS_SEED_SET BIT(0)
6099
6100struct ec_response_fp_encryption_status {
6101	/* Used bits in encryption engine status */
6102	uint32_t valid_flags;
6103	/* Encryption engine status */
6104	uint32_t status;
6105} __ec_align4;
6106
6107/*****************************************************************************/
6108/* Touchpad MCU commands: range 0x0500-0x05FF */
6109
6110/* Perform touchpad self test */
6111#define EC_CMD_TP_SELF_TEST 0x0500
6112
6113/* Get number of frame types, and the size of each type */
6114#define EC_CMD_TP_FRAME_INFO 0x0501
6115
6116struct ec_response_tp_frame_info {
6117	uint32_t n_frames;
6118	uint32_t frame_sizes[];
6119} __ec_align4;
6120
6121/* Create a snapshot of current frame readings */
6122#define EC_CMD_TP_FRAME_SNAPSHOT 0x0502
6123
6124/* Read the frame */
6125#define EC_CMD_TP_FRAME_GET 0x0503
6126
6127struct ec_params_tp_frame_get {
6128	uint32_t frame_index;
6129	uint32_t offset;
6130	uint32_t size;
6131} __ec_align4;
6132
6133/*****************************************************************************/
6134/* EC-EC communication commands: range 0x0600-0x06FF */
6135
6136#define EC_COMM_TEXT_MAX 8
6137
6138/*
6139 * Get battery static information, i.e. information that never changes, or
6140 * very infrequently.
6141 */
6142#define EC_CMD_BATTERY_GET_STATIC 0x0600
6143
6144/**
6145 * struct ec_params_battery_static_info - Battery static info parameters
6146 * @index: Battery index.
6147 */
6148struct ec_params_battery_static_info {
6149	uint8_t index;
6150} __ec_align_size1;
6151
6152/**
6153 * struct ec_response_battery_static_info - Battery static info response
6154 * @design_capacity: Battery Design Capacity (mAh)
6155 * @design_voltage: Battery Design Voltage (mV)
6156 * @manufacturer: Battery Manufacturer String
6157 * @model: Battery Model Number String
6158 * @serial: Battery Serial Number String
6159 * @type: Battery Type String
6160 * @cycle_count: Battery Cycle Count
6161 */
6162struct ec_response_battery_static_info {
6163	uint16_t design_capacity;
6164	uint16_t design_voltage;
6165	char manufacturer[EC_COMM_TEXT_MAX];
6166	char model[EC_COMM_TEXT_MAX];
6167	char serial[EC_COMM_TEXT_MAX];
6168	char type[EC_COMM_TEXT_MAX];
6169	/* TODO(crbug.com/795991): Consider moving to dynamic structure. */
6170	uint32_t cycle_count;
6171} __ec_align4;
6172
6173/*
6174 * Get battery dynamic information, i.e. information that is likely to change
6175 * every time it is read.
6176 */
6177#define EC_CMD_BATTERY_GET_DYNAMIC 0x0601
6178
6179/**
6180 * struct ec_params_battery_dynamic_info - Battery dynamic info parameters
6181 * @index: Battery index.
6182 */
6183struct ec_params_battery_dynamic_info {
6184	uint8_t index;
6185} __ec_align_size1;
6186
6187/**
6188 * struct ec_response_battery_dynamic_info - Battery dynamic info response
6189 * @actual_voltage: Battery voltage (mV)
6190 * @actual_current: Battery current (mA); negative=discharging
6191 * @remaining_capacity: Remaining capacity (mAh)
6192 * @full_capacity: Capacity (mAh, might change occasionally)
6193 * @flags: Flags, see EC_BATT_FLAG_*
6194 * @desired_voltage: Charging voltage desired by battery (mV)
6195 * @desired_current: Charging current desired by battery (mA)
6196 */
6197struct ec_response_battery_dynamic_info {
6198	int16_t actual_voltage;
6199	int16_t actual_current;
6200	int16_t remaining_capacity;
6201	int16_t full_capacity;
6202	int16_t flags;
6203	int16_t desired_voltage;
6204	int16_t desired_current;
6205} __ec_align2;
6206
6207/*
6208 * Control charger chip. Used to control charger chip on the slave.
6209 */
6210#define EC_CMD_CHARGER_CONTROL 0x0602
6211
6212/**
6213 * struct ec_params_charger_control - Charger control parameters
6214 * @max_current: Charger current (mA). Positive to allow base to draw up to
6215 *     max_current and (possibly) charge battery, negative to request current
6216 *     from base (OTG).
6217 * @otg_voltage: Voltage (mV) to use in OTG mode, ignored if max_current is
6218 *     >= 0.
6219 * @allow_charging: Allow base battery charging (only makes sense if
6220 *     max_current > 0).
6221 */
6222struct ec_params_charger_control {
6223	int16_t max_current;
6224	uint16_t otg_voltage;
6225	uint8_t allow_charging;
6226} __ec_align_size1;
6227
6228/* Get ACK from the USB-C SS muxes */
6229#define EC_CMD_USB_PD_MUX_ACK 0x0603
6230
6231struct ec_params_usb_pd_mux_ack {
6232	uint8_t port; /* USB-C port number */
6233} __ec_align1;
6234
6235/*****************************************************************************/
6236/*
6237 * Reserve a range of host commands for board-specific, experimental, or
6238 * special purpose features. These can be (re)used without updating this file.
6239 *
6240 * CAUTION: Don't go nuts with this. Shipping products should document ALL
6241 * their EC commands for easier development, testing, debugging, and support.
6242 *
6243 * All commands MUST be #defined to be 4-digit UPPER CASE hex values
6244 * (e.g., 0x00AB, not 0xab) for CONFIG_HOSTCMD_SECTION_SORTED to work.
6245 *
6246 * In your experimental code, you may want to do something like this:
6247 *
6248 *   #define EC_CMD_MAGIC_FOO 0x0000
6249 *   #define EC_CMD_MAGIC_BAR 0x0001
6250 *   #define EC_CMD_MAGIC_HEY 0x0002
6251 *
6252 *   DECLARE_PRIVATE_HOST_COMMAND(EC_CMD_MAGIC_FOO, magic_foo_handler,
6253 *      EC_VER_MASK(0);
6254 *
6255 *   DECLARE_PRIVATE_HOST_COMMAND(EC_CMD_MAGIC_BAR, magic_bar_handler,
6256 *      EC_VER_MASK(0);
6257 *
6258 *   DECLARE_PRIVATE_HOST_COMMAND(EC_CMD_MAGIC_HEY, magic_hey_handler,
6259 *      EC_VER_MASK(0);
6260 */
6261#define EC_CMD_BOARD_SPECIFIC_BASE 0x3E00
6262#define EC_CMD_BOARD_SPECIFIC_LAST 0x3FFF
6263
6264/*
6265 * Given the private host command offset, calculate the true private host
6266 * command value.
6267 */
6268#define EC_PRIVATE_HOST_COMMAND_VALUE(command) \
6269	(EC_CMD_BOARD_SPECIFIC_BASE + (command))
6270
6271/*****************************************************************************/
6272/*
6273 * Passthru commands
6274 *
6275 * Some platforms have sub-processors chained to each other.  For example.
6276 *
6277 *     AP <--> EC <--> PD MCU
6278 *
6279 * The top 2 bits of the command number are used to indicate which device the
6280 * command is intended for.  Device 0 is always the device receiving the
6281 * command; other device mapping is board-specific.
6282 *
6283 * When a device receives a command to be passed to a sub-processor, it passes
6284 * it on with the device number set back to 0.  This allows the sub-processor
6285 * to remain blissfully unaware of whether the command originated on the next
6286 * device up the chain, or was passed through from the AP.
6287 *
6288 * In the above example, if the AP wants to send command 0x0002 to the PD MCU,
6289 *     AP sends command 0x4002 to the EC
6290 *     EC sends command 0x0002 to the PD MCU
6291 *     EC forwards PD MCU response back to the AP
6292 */
6293
6294/* Offset and max command number for sub-device n */
6295#define EC_CMD_PASSTHRU_OFFSET(n) (0x4000 * (n))
6296#define EC_CMD_PASSTHRU_MAX(n) (EC_CMD_PASSTHRU_OFFSET(n) + 0x3fff)
6297
6298/*****************************************************************************/
6299/*
6300 * Deprecated constants. These constants have been renamed for clarity. The
6301 * meaning and size has not changed. Programs that use the old names should
6302 * switch to the new names soon, as the old names may not be carried forward
6303 * forever.
6304 */
6305#define EC_HOST_PARAM_SIZE      EC_PROTO2_MAX_PARAM_SIZE
6306#define EC_LPC_ADDR_OLD_PARAM   EC_HOST_CMD_REGION1
6307#define EC_OLD_PARAM_SIZE       EC_HOST_CMD_REGION_SIZE
6308
6309
6310
6311#endif  /* __CROS_EC_COMMANDS_H */
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