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/* Copyright (c) 2013 The Chromium OS Authors. All rights reserved.
* Use of this source code is governed by a BSD-style license that can be
* found in the LICENSE file.
*/
#include "acpi.h"
#include "common.h"
#include "console.h"
#include "dptf.h"
#include "hooks.h"
#include "host_command.h"
#include "lpc.h"
#include "ec_commands.h"
#include "tablet_mode.h"
#include "pwm.h"
#include "timer.h"
#include "util.h"
/* Console output macros */
#define CPUTS(outstr) cputs(CC_LPC, outstr)
#define CPRINTF(format, args...) cprintf(CC_LPC, format, ## args)
#define CPRINTS(format, args...) cprints(CC_LPC, format, ## args)
/* Last received ACPI command */
static uint8_t __bss_slow acpi_cmd;
/* First byte of data after ACPI command */
static uint8_t __bss_slow acpi_addr;
/* Number of data writes after command */
static int __bss_slow acpi_data_count;
/* Test byte in ACPI memory space */
static uint8_t __bss_slow acpi_mem_test;
#ifdef CONFIG_DPTF
static int __bss_slow dptf_temp_sensor_id; /* last sensor ID written */
static int __bss_slow dptf_temp_threshold; /* last threshold written */
#endif
/*
* Keep a read cache of four bytes when burst mode is enabled, which is the
* size of the largest non-string memmap data type.
*/
#define ACPI_READ_CACHE_SIZE 4
/* Start address that indicates read cache is flushed. */
#define ACPI_READ_CACHE_FLUSHED (EC_ACPI_MEM_MAPPED_BEGIN - 1)
/* Calculate size of valid cache based upon end of memmap data. */
#define ACPI_VALID_CACHE_SIZE(addr) (MIN( \
EC_ACPI_MEM_MAPPED_SIZE + EC_ACPI_MEM_MAPPED_BEGIN - (addr), \
ACPI_READ_CACHE_SIZE))
/*
* In burst mode, read the requested memmap data and the data immediately
* following it into a cache. For future reads in burst mode, try to grab
* data from the cache. This ensures the continuity of multi-byte reads,
* which is important when dealing with data types > 8 bits.
*/
static struct {
int enabled;
uint8_t start_addr;
uint8_t data[ACPI_READ_CACHE_SIZE];
} acpi_read_cache;
/*
* Deferred function to ensure that ACPI burst mode doesn't remain enabled
* indefinitely.
*/
static void acpi_disable_burst_deferred(void)
{
acpi_read_cache.enabled = 0;
lpc_clear_acpi_status_mask(EC_LPC_STATUS_BURST_MODE);
CPUTS("ACPI missed burst disable?");
}
DECLARE_DEFERRED(acpi_disable_burst_deferred);
/* Read memmapped data, returns read data or 0xff on error. */
static int acpi_read(uint8_t addr)
{
uint8_t *memmap_addr = (uint8_t *)(lpc_get_memmap_range() + addr -
EC_ACPI_MEM_MAPPED_BEGIN);
/* Check for out-of-range read. */
if (addr < EC_ACPI_MEM_MAPPED_BEGIN ||
addr >= EC_ACPI_MEM_MAPPED_BEGIN + EC_ACPI_MEM_MAPPED_SIZE) {
CPRINTS("ACPI read 0x%02x (ignored)",
acpi_addr);
return 0xff;
}
/* Read from cache if enabled (burst mode). */
if (acpi_read_cache.enabled) {
/* Fetch to cache on miss. */
if (acpi_read_cache.start_addr == ACPI_READ_CACHE_FLUSHED ||
acpi_read_cache.start_addr > addr ||
addr - acpi_read_cache.start_addr >=
ACPI_READ_CACHE_SIZE) {
memcpy(acpi_read_cache.data,
memmap_addr,
ACPI_VALID_CACHE_SIZE(addr));
acpi_read_cache.start_addr = addr;
}
/* Return data from cache. */
return acpi_read_cache.data[addr - acpi_read_cache.start_addr];
} else {
/* Read directly from memmap data. */
return *memmap_addr;
}
}
/*
* This handles AP writes to the EC via the ACPI I/O port. There are only a few
* ACPI commands (EC_CMD_ACPI_*), but they are all handled here.
*/
int acpi_ap_to_ec(int is_cmd, uint8_t value, uint8_t *resultptr)
{
int data = 0;
int retval = 0;
int result = 0xff; /* value for bogus read */
/* Read command/data; this clears the FRMH status bit. */
if (is_cmd) {
acpi_cmd = value;
acpi_data_count = 0;
} else {
data = value;
/*
* The first data byte is the ACPI memory address for
* read/write commands.
*/
if (!acpi_data_count++)
acpi_addr = data;
}
/* Process complete commands */
if (acpi_cmd == EC_CMD_ACPI_READ && acpi_data_count == 1) {
/* ACPI read cmd + addr */
switch (acpi_addr) {
case EC_ACPI_MEM_VERSION:
result = EC_ACPI_MEM_VERSION_CURRENT;
break;
case EC_ACPI_MEM_TEST:
result = acpi_mem_test;
break;
case EC_ACPI_MEM_TEST_COMPLIMENT:
result = 0xff - acpi_mem_test;
break;
#ifdef CONFIG_PWM_KBLIGHT
case EC_ACPI_MEM_KEYBOARD_BACKLIGHT:
result = pwm_get_duty(PWM_CH_KBLIGHT);
break;
#endif
#ifdef CONFIG_FANS
case EC_ACPI_MEM_FAN_DUTY:
result = dptf_get_fan_duty_target();
break;
#endif
#ifdef CONFIG_DPTF
case EC_ACPI_MEM_TEMP_ID:
result = dptf_query_next_sensor_event();
break;
#endif
#ifdef CONFIG_CHARGER
case EC_ACPI_MEM_CHARGING_LIMIT:
result = dptf_get_charging_current_limit();
if (result >= 0)
result /= EC_ACPI_MEM_CHARGING_LIMIT_STEP_MA;
else
result = EC_ACPI_MEM_CHARGING_LIMIT_DISABLED;
break;
#endif
#ifdef CONFIG_DPTF_DEVICE_ORIENTATION
case EC_ACPI_MEM_DEVICE_ORIENTATION:
result = tablet_get_mode();
break;
#endif
case EC_ACPI_MEM_DEVICE_FEATURES0:
case EC_ACPI_MEM_DEVICE_FEATURES1:
case EC_ACPI_MEM_DEVICE_FEATURES2:
case EC_ACPI_MEM_DEVICE_FEATURES3: {
int off = acpi_addr - EC_ACPI_MEM_DEVICE_FEATURES0;
uint32_t val = get_feature_flags0();
/* Flush EC_FEATURE_LIMITED bit. Having it reset to 0
* means that FEATURES[0-3] are supported in the first
* place, and the other bits are valid.
*/
val &= ~1;
result = val >> (8 * off);
break;
}
case EC_ACPI_MEM_DEVICE_FEATURES4:
case EC_ACPI_MEM_DEVICE_FEATURES5:
case EC_ACPI_MEM_DEVICE_FEATURES6:
case EC_ACPI_MEM_DEVICE_FEATURES7: {
int off = acpi_addr - EC_ACPI_MEM_DEVICE_FEATURES4;
uint32_t val = get_feature_flags1();
result = val >> (8 * off);
break;
}
default:
result = acpi_read(acpi_addr);
break;
}
/* Send the result byte */
*resultptr = result;
retval = 1;
} else if (acpi_cmd == EC_CMD_ACPI_WRITE && acpi_data_count == 2) {
/* ACPI write cmd + addr + data */
switch (acpi_addr) {
case EC_ACPI_MEM_TEST:
acpi_mem_test = data;
break;
#ifdef CONFIG_PWM_KBLIGHT
case EC_ACPI_MEM_KEYBOARD_BACKLIGHT:
/*
* Debug output with CR not newline, because the host
* does a lot of keyboard backlights and it scrolls the
* debug console.
*/
CPRINTF("\r[%T ACPI kblight %d]", data);
pwm_set_duty(PWM_CH_KBLIGHT, data);
break;
#endif
#ifdef CONFIG_FANS
case EC_ACPI_MEM_FAN_DUTY:
dptf_set_fan_duty_target(data);
break;
#endif
#ifdef CONFIG_DPTF
case EC_ACPI_MEM_TEMP_ID:
dptf_temp_sensor_id = data;
break;
case EC_ACPI_MEM_TEMP_THRESHOLD:
dptf_temp_threshold = data + EC_TEMP_SENSOR_OFFSET;
break;
case EC_ACPI_MEM_TEMP_COMMIT:
{
int idx = data & EC_ACPI_MEM_TEMP_COMMIT_SELECT_MASK;
int enable = data & EC_ACPI_MEM_TEMP_COMMIT_ENABLE_MASK;
dptf_set_temp_threshold(dptf_temp_sensor_id,
dptf_temp_threshold,
idx, enable);
break;
}
#endif
#ifdef CONFIG_CHARGER
case EC_ACPI_MEM_CHARGING_LIMIT:
if (data == EC_ACPI_MEM_CHARGING_LIMIT_DISABLED) {
dptf_set_charging_current_limit(-1);
} else {
data *= EC_ACPI_MEM_CHARGING_LIMIT_STEP_MA;
dptf_set_charging_current_limit(data);
}
break;
#endif
default:
CPRINTS("ACPI write 0x%02x = 0x%02x (ignored)",
acpi_addr, data);
break;
}
} else if (acpi_cmd == EC_CMD_ACPI_QUERY_EVENT && !acpi_data_count) {
/* Clear and return the lowest host event */
int evt_index = lpc_query_host_event_state();
CPRINTS("ACPI query = %d", evt_index);
*resultptr = evt_index;
retval = 1;
} else if (acpi_cmd == EC_CMD_ACPI_BURST_ENABLE && !acpi_data_count) {
/*
* TODO: The kernel only enables BURST when doing multi-byte
* value reads over the ACPI port. We don't do such reads
* when our memmap data can be accessed directly over LPC,
* so on LM4, for example, this is dead code. We might want
* to add a config to skip this code for certain chips.
*/
acpi_read_cache.enabled = 1;
acpi_read_cache.start_addr = ACPI_READ_CACHE_FLUSHED;
/* Enter burst mode */
lpc_set_acpi_status_mask(EC_LPC_STATUS_BURST_MODE);
/*
* Disable from deferred function in case burst mode is enabled
* for an extremely long time (ex. kernel bug / crash).
*/
hook_call_deferred(&acpi_disable_burst_deferred_data, 1*SECOND);
/* ACPI 5.0-12.3.3: Burst ACK */
*resultptr = 0x90;
retval = 1;
} else if (acpi_cmd == EC_CMD_ACPI_BURST_DISABLE && !acpi_data_count) {
acpi_read_cache.enabled = 0;
/* Leave burst mode */
hook_call_deferred(&acpi_disable_burst_deferred_data, -1);
lpc_clear_acpi_status_mask(EC_LPC_STATUS_BURST_MODE);
}
return retval;
}
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