coreboot-libre-fam15h-rdimm/3rdparty/chromeec/chip/lm4/lpc.c

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2024-03-04 11:14:53 +01:00
/* Copyright 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.
*/
/* LPC module for Chrome EC */
#include "acpi.h"
#include "clock.h"
#include "common.h"
#include "console.h"
#include "gpio.h"
#include "hooks.h"
#include "host_command.h"
#include "keyboard_protocol.h"
#include "lpc.h"
#include "port80.h"
#include "pwm.h"
#include "registers.h"
#include "system.h"
#include "task.h"
#include "timer.h"
#include "uart.h"
#include "util.h"
/* LPC channels */
#define LPC_CH_ACPI 0 /* ACPI commands */
#define LPC_CH_PORT80 1 /* Port 80 debug output */
#define LPC_CH_CMD_DATA 2 /* Data for host commands (args/params/response) */
#define LPC_CH_KEYBOARD 3 /* 8042 keyboard emulation */
#define LPC_CH_CMD 4 /* Host commands */
#define LPC_CH_MEMMAP 5 /* Memory-mapped data */
#define LPC_CH_COMX 7 /* UART emulation */
/* LPC pool offsets */
#define LPC_POOL_OFFS_ACPI 0 /* ACPI commands - 0=in, 1=out */
#define LPC_POOL_OFFS_PORT80 4 /* Port 80 - 4=in, 5=out */
#define LPC_POOL_OFFS_COMX 8 /* UART emulation range - 8-15 */
#define LPC_POOL_OFFS_KEYBOARD 16 /* Keyboard - 16=in, 17=out */
#define LPC_POOL_OFFS_CMD 20 /* Host commands - 20=in, 21=out */
#define LPC_POOL_OFFS_CMD_DATA 512 /* Data range for host commands - 512-767 */
#define LPC_POOL_OFFS_MEMMAP 768 /* Memory-mapped data - 768-1023 */
/* LPC pool data pointers */
#define LPC_POOL_ACPI (LM4_LPC_LPCPOOL + LPC_POOL_OFFS_ACPI)
#define LPC_POOL_PORT80 (LM4_LPC_LPCPOOL + LPC_POOL_OFFS_PORT80)
#define LPC_POOL_COMX (LM4_LPC_LPCPOOL + LPC_POOL_OFFS_COMX)
#define LPC_POOL_KEYBOARD (LM4_LPC_LPCPOOL + LPC_POOL_OFFS_KEYBOARD)
#define LPC_POOL_CMD (LM4_LPC_LPCPOOL + LPC_POOL_OFFS_CMD)
#define LPC_POOL_CMD_DATA (LM4_LPC_LPCPOOL + LPC_POOL_OFFS_CMD_DATA)
#define LPC_POOL_MEMMAP (LM4_LPC_LPCPOOL + LPC_POOL_OFFS_MEMMAP)
/* LPC COMx I/O address (in x86 I/O address space) */
#define LPC_COMX_ADDR 0x3f8 /* COM1 */
/* Console output macros */
#define CPUTS(outstr) cputs(CC_LPC, outstr)
#define CPRINTS(format, args...) cprints(CC_LPC, format, ## args)
static struct host_packet lpc_packet;
static struct host_cmd_handler_args host_cmd_args;
static uint8_t host_cmd_flags; /* Flags from host command */
/* Params must be 32-bit aligned */
static uint8_t params_copy[EC_LPC_HOST_PACKET_SIZE] __aligned(4);
static int init_done;
static uint8_t * const cmd_params = (uint8_t *)LPC_POOL_CMD_DATA +
EC_LPC_ADDR_HOST_PARAM - EC_LPC_ADDR_HOST_ARGS;
static struct ec_lpc_host_args * const lpc_host_args =
(struct ec_lpc_host_args *)LPC_POOL_CMD_DATA;
static void wait_irq_sent(void)
{
/*
* A hard-coded delay here isn't very elegant, but it's the best we can
* manage (and it's a short delay, so it's not that horrible). We need
* this because SIRQRIS isn't cleared in continuous mode, and the EC
* has trouble sending more than 1 frame in quiet mode. Waiting 4 us =
* 2 SERIRQ frames ensures the IRQ has been sent out.
*/
udelay(4);
}
#ifdef CONFIG_KEYBOARD_IRQ_GPIO
static void keyboard_irq_assert(void)
{
/*
* Enforce signal-high for long enough for the signal to be pulled high
* by the external pullup resistor. This ensures the host will see the
* following falling edge, regardless of the line state before this
* function call.
*/
uint64_t tstop = get_time().val + MSEC;
gpio_set_level(CONFIG_KEYBOARD_IRQ_GPIO, 1);
udelay(4);
/* Generate a falling edge */
gpio_set_level(CONFIG_KEYBOARD_IRQ_GPIO, 0);
/* Wait for host senses the interrupt and gets the char. */
do {
if (get_time().val > tstop)
break;
} while (lpc_keyboard_has_char());
/* Set signal high, now that we've generated the edge */
gpio_set_level(CONFIG_KEYBOARD_IRQ_GPIO, 1);
}
#else
static void wait_send_serirq(uint32_t lpcirqctl)
{
LM4_LPC_LPCIRQCTL = lpcirqctl;
wait_irq_sent();
}
/**
* Manually generate an IRQ to host (edge-trigger).
*
* @param irq_num IRQ number to generate. Pass 0 to set the AH
* (active high) bit.
*
* For SERIRQ quite mode, we need to set LM4_LPC_LPCIRQCTL twice.
* The first one is to assert IRQ (pull low), and then the second one is
* to de-assert it. This generates a pulse (high-low-high) for an IRQ.
*/
static void lpc_manual_irq(int irq_num)
{
uint32_t common_bits =
0x00000004 | /* PULSE */
0x00000002 | /* ONCHG - for quiet mode */
0x00000001; /* SND - send immediately */
/* Send out the IRQ first. */
wait_send_serirq((1 << (irq_num + 16)) | common_bits);
/* Generate a all-high frame to simulate a rising edge. */
wait_send_serirq(common_bits);
}
static inline void keyboard_irq_assert(void)
{
/* Use serirq method. */
lpc_manual_irq(1); /* IRQ#1 */
}
#endif
/**
* Generate SMI pulse to the host chipset via GPIO.
*
* If the x86 is in S0, SMI# is sampled at 33MHz, so minimum pulse length is
* 60ns. If the x86 is in S3, SMI# is sampled at 32.768KHz, so we need pulse
* length >61us. Both are short enough and events are infrequent, so just
* delay for 65us.
*/
static void lpc_generate_smi(void)
{
host_event_t smi;
/* Enforce signal-high for long enough to debounce high */
gpio_set_level(GPIO_PCH_SMI_L, 1);
udelay(65);
/* Generate a falling edge */
gpio_set_level(GPIO_PCH_SMI_L, 0);
udelay(65);
/* Set signal high, now that we've generated the edge */
gpio_set_level(GPIO_PCH_SMI_L, 1);
smi = lpc_get_host_events_by_type(LPC_HOST_EVENT_SMI);
if (smi)
HOST_EVENT_CPRINTS("smi", smi);
}
/**
* Generate SCI pulse to the host chipset via LPC0SCI.
*/
static void lpc_generate_sci(void)
{
host_event_t sci;
#ifdef CONFIG_SCI_GPIO
/* Enforce signal-high for long enough to debounce high */
gpio_set_level(CONFIG_SCI_GPIO, 1);
udelay(65);
/* Generate a falling edge */
gpio_set_level(CONFIG_SCI_GPIO, 0);
udelay(65);
/* Set signal high, now that we've generated the edge */
gpio_set_level(CONFIG_SCI_GPIO, 1);
#else
LM4_LPC_LPCCTL |= LM4_LPC_SCI_START;
#endif
sci = lpc_get_host_events_by_type(LPC_HOST_EVENT_SCI);
if (sci)
HOST_EVENT_CPRINTS("sci", sci);
}
/**
* Update the level-sensitive wake signal to the AP.
*
* @param wake_events Currently asserted wake events
*/
static void lpc_update_wake(uint64_t wake_events)
{
/*
* Mask off power button event, since the AP gets that through a
* separate dedicated GPIO.
*/
wake_events &= ~EC_HOST_EVENT_MASK(EC_HOST_EVENT_POWER_BUTTON);
/* Signal is asserted low when wake events is non-zero */
gpio_set_level(GPIO_PCH_WAKE_L, !wake_events);
}
uint8_t *lpc_get_memmap_range(void)
{
return (uint8_t *)LPC_POOL_MEMMAP;
}
static void lpc_send_response(struct host_cmd_handler_args *args)
{
uint8_t *out;
int size = args->response_size;
int csum;
int i;
/* Ignore in-progress on LPC since interface is synchronous anyway */
if (args->result == EC_RES_IN_PROGRESS)
return;
/* Handle negative size */
if (size < 0) {
args->result = EC_RES_INVALID_RESPONSE;
size = 0;
}
/* New-style response */
lpc_host_args->flags =
(host_cmd_flags & ~EC_HOST_ARGS_FLAG_FROM_HOST) |
EC_HOST_ARGS_FLAG_TO_HOST;
lpc_host_args->data_size = size;
csum = args->command + lpc_host_args->flags +
lpc_host_args->command_version +
lpc_host_args->data_size;
for (i = 0, out = (uint8_t *)args->response; i < size; i++, out++)
csum += *out;
lpc_host_args->checksum = (uint8_t)csum;
/* Fail if response doesn't fit in the param buffer */
if (size > EC_PROTO2_MAX_PARAM_SIZE)
args->result = EC_RES_INVALID_RESPONSE;
/* Write result to the data byte. This sets the TOH status bit. */
LPC_POOL_CMD[1] = args->result;
/* Clear the busy bit, so the host knows the EC is done. */
task_disable_irq(LM4_IRQ_LPC);
LM4_LPC_ST(LPC_CH_CMD) &= ~LM4_LPC_ST_BUSY;
task_enable_irq(LM4_IRQ_LPC);
}
static void lpc_send_response_packet(struct host_packet *pkt)
{
/* Ignore in-progress on LPC since interface is synchronous anyway */
if (pkt->driver_result == EC_RES_IN_PROGRESS)
return;
/* Write result to the data byte. This sets the TOH status bit. */
LPC_POOL_CMD[1] = pkt->driver_result;
/* Clear the busy bit, so the host knows the EC is done. */
task_disable_irq(LM4_IRQ_LPC);
LM4_LPC_ST(LPC_CH_CMD) &= ~LM4_LPC_ST_BUSY;
task_enable_irq(LM4_IRQ_LPC);
}
int lpc_keyboard_has_char(void)
{
return (LM4_LPC_ST(LPC_CH_KEYBOARD) & LM4_LPC_ST_TOH) ? 1 : 0;
}
/* Return true if the FRMH is set */
int lpc_keyboard_input_pending(void)
{
return (LM4_LPC_ST(LPC_CH_KEYBOARD) & LM4_LPC_ST_FRMH) ? 1 : 0;
}
/* Put a char to host buffer and send IRQ if specified. */
void lpc_keyboard_put_char(uint8_t chr, int send_irq)
{
LPC_POOL_KEYBOARD[1] = chr;
if (send_irq)
keyboard_irq_assert();
}
void lpc_keyboard_clear_buffer(void)
{
/* Make sure the previous TOH and IRQ has been sent out. */
wait_irq_sent();
LM4_LPC_ST(LPC_CH_KEYBOARD) &= ~LM4_LPC_ST_TOH;
/* Ensure there is no TOH set in this period. */
wait_irq_sent();
}
void lpc_keyboard_resume_irq(void)
{
if (lpc_keyboard_has_char())
keyboard_irq_assert();
}
#ifdef CONFIG_UART_HOST
int lpc_comx_has_char(void)
{
return LM4_LPC_ST(LPC_CH_COMX) & LM4_LPC_ST_FRMH;
}
int lpc_comx_get_char(void)
{
return LPC_POOL_COMX[0];
}
void lpc_comx_put_char(int c)
{
LPC_POOL_COMX[1] = c;
/*
* We could in theory manually trigger an IRQ, like we do for the 8042
* keyboard interface, but neither the kernel nor BIOS seems to require
* this.
*/
}
#endif /* CONFIG_UART_HOST */
/**
* Update the host event status.
*
* Sends a pulse if masked event status becomes non-zero:
* - SMI pulse via EC_SMI_L GPIO
* - SCI pulse via LPC0SCI
*/
void lpc_update_host_event_status(void)
{
int need_sci = 0;
int need_smi = 0;
if (!init_done)
return;
/* Disable LPC interrupt while updating status register */
task_disable_irq(LM4_IRQ_LPC);
if (lpc_get_host_events_by_type(LPC_HOST_EVENT_SMI)) {
/* Only generate SMI for first event */
if (!(LM4_LPC_ST(LPC_CH_ACPI) & LM4_LPC_ST_SMI))
need_smi = 1;
LM4_LPC_ST(LPC_CH_ACPI) |= LM4_LPC_ST_SMI;
} else
LM4_LPC_ST(LPC_CH_ACPI) &= ~LM4_LPC_ST_SMI;
if (lpc_get_host_events_by_type(LPC_HOST_EVENT_SCI)) {
/* Generate SCI for every event */
need_sci = 1;
LM4_LPC_ST(LPC_CH_ACPI) |= LM4_LPC_ST_SCI;
} else
LM4_LPC_ST(LPC_CH_ACPI) &= ~LM4_LPC_ST_SCI;
/* Copy host events to mapped memory */
*(host_event_t *)host_get_memmap(EC_MEMMAP_HOST_EVENTS) =
lpc_get_host_events();
task_enable_irq(LM4_IRQ_LPC);
/* Process the wake events. */
lpc_update_wake(lpc_get_host_events_by_type(LPC_HOST_EVENT_WAKE));
/* Send pulse on SMI signal if needed */
if (need_smi)
lpc_generate_smi();
/* ACPI 5.0-12.6.1: Generate SCI for SCI_EVT=1. */
if (need_sci)
lpc_generate_sci();
}
void lpc_set_acpi_status_mask(uint8_t mask)
{
uint32_t set_mask = 0;
if (mask & EC_LPC_STATUS_BURST_MODE)
set_mask |= LM4_LPC_ST_BURST;
LM4_LPC_ST(LPC_CH_ACPI) |= set_mask;
}
void lpc_clear_acpi_status_mask(uint8_t mask)
{
uint32_t clear_mask = 0;
if (mask & EC_LPC_STATUS_BURST_MODE)
clear_mask |= LM4_LPC_ST_BURST;
LM4_LPC_ST(LPC_CH_ACPI) &= ~clear_mask;
}
int lpc_get_pltrst_asserted(void)
{
return (LM4_LPC_LPCSTS & BIT(10)) ? 1 : 0;
}
/**
* Handle write to ACPI I/O port
*
* @param is_cmd Is write command (is_cmd=1) or data (is_cmd=0)
*/
static void handle_acpi_write(int is_cmd)
{
uint8_t value, result;
/* Set the busy bit */
LM4_LPC_ST(LPC_CH_ACPI) |= LM4_LPC_ST_BUSY;
/* Read command/data; this clears the FRMH status bit. */
value = LPC_POOL_ACPI[0];
/* Handle whatever this was. */
if (acpi_ap_to_ec(is_cmd, value, &result))
LPC_POOL_ACPI[1] = result;
/* Clear the busy bit */
LM4_LPC_ST(LPC_CH_ACPI) &= ~LM4_LPC_ST_BUSY;
/*
* ACPI 5.0-12.6.1: Generate SCI for Input Buffer Empty / Output Buffer
* Full condition on the kernel channel.
*/
lpc_generate_sci();
}
/**
* Handle write to host command I/O ports.
*
* @param is_cmd Is write command (1) or data (0)?
*/
static void handle_host_write(int is_cmd)
{
/* Ignore data writes or overlapping commands from host */
uint32_t is_overlapping = LM4_LPC_ST(LPC_CH_CMD) & LM4_LPC_ST_BUSY;
if (!is_cmd || is_overlapping) {
if (is_overlapping)
CPRINTS("LPC Ignoring overlapping HC");
LM4_LPC_ST(LPC_CH_CMD) &= ~LM4_LPC_ST_FRMH;
return;
}
/* Set the busy bit */
LM4_LPC_ST(LPC_CH_CMD) |= LM4_LPC_ST_BUSY;
/*
* Read the command byte. This clears the FRMH bit in
* the status byte.
*/
host_cmd_args.command = LPC_POOL_CMD[0];
host_cmd_args.result = EC_RES_SUCCESS;
host_cmd_args.send_response = lpc_send_response;
host_cmd_flags = lpc_host_args->flags;
/* See if we have an old or new style command */
if (host_cmd_args.command == EC_COMMAND_PROTOCOL_3) {
lpc_packet.send_response = lpc_send_response_packet;
lpc_packet.request = (const void *)LPC_POOL_CMD_DATA;
lpc_packet.request_temp = params_copy;
lpc_packet.request_max = sizeof(params_copy);
/* Don't know the request size so pass in the entire buffer */
lpc_packet.request_size = EC_LPC_HOST_PACKET_SIZE;
lpc_packet.response = (void *)LPC_POOL_CMD_DATA;
lpc_packet.response_max = EC_LPC_HOST_PACKET_SIZE;
lpc_packet.response_size = 0;
lpc_packet.driver_result = EC_RES_SUCCESS;
host_packet_receive(&lpc_packet);
return;
} else if (host_cmd_flags & EC_HOST_ARGS_FLAG_FROM_HOST) {
/* Version 2 (link) style command */
int size = lpc_host_args->data_size;
int csum, i;
host_cmd_args.version = lpc_host_args->command_version;
host_cmd_args.params = params_copy;
host_cmd_args.params_size = size;
host_cmd_args.response = cmd_params;
host_cmd_args.response_max = EC_PROTO2_MAX_PARAM_SIZE;
host_cmd_args.response_size = 0;
/* Verify params size */
if (size > EC_PROTO2_MAX_PARAM_SIZE) {
host_cmd_args.result = EC_RES_INVALID_PARAM;
} else {
const uint8_t *src = cmd_params;
uint8_t *copy = params_copy;
/*
* Verify checksum and copy params out of LPC space.
* This ensures the data acted on by the host command
* handler can't be changed by host writes after the
* checksum is verified.
*/
csum = host_cmd_args.command +
host_cmd_flags +
host_cmd_args.version +
host_cmd_args.params_size;
for (i = 0; i < size; i++) {
csum += *src;
*(copy++) = *(src++);
}
if ((uint8_t)csum != lpc_host_args->checksum)
host_cmd_args.result = EC_RES_INVALID_CHECKSUM;
}
} else {
/* Old style command, now unsupported */
host_cmd_args.result = EC_RES_INVALID_COMMAND;
}
/* Hand off to host command handler */
host_command_received(&host_cmd_args);
}
#ifdef CONFIG_CHIPSET_RESET_HOOK
static void lpc_chipset_reset(void)
{
hook_notify(HOOK_CHIPSET_RESET);
}
DECLARE_DEFERRED(lpc_chipset_reset);
#endif
/**
* LPC interrupt handler
*/
void lpc_interrupt(void)
{
uint32_t mis = LM4_LPC_LPCMIS;
uint32_t st;
/* Clear the interrupt bits we're handling */
LM4_LPC_LPCIC = mis;
#ifdef HAS_TASK_HOSTCMD
/* Handle ACPI command and data writes */
st = LM4_LPC_ST(LPC_CH_ACPI);
if (st & LM4_LPC_ST_FRMH)
handle_acpi_write(st & LM4_LPC_ST_CMD);
/* Handle user command writes */
st = LM4_LPC_ST(LPC_CH_CMD);
if (st & LM4_LPC_ST_FRMH)
handle_host_write(st & LM4_LPC_ST_CMD);
#endif
/*
* Handle port 80 writes (CH0MIS1). Due to crosbug.com/p/12349 the
* interrupt status (mis & LM4_LPC_INT_MASK(LPC_CH_PORT80, 2))
* apparently gets lost on back-to-back writes to port 80, so check the
* FRMH bit in the channel status register to see if a write is
* pending. Loop to handle bursts of back-to-back writes.
*/
while (LM4_LPC_ST(LPC_CH_PORT80) & LM4_LPC_ST_FRMH)
port_80_write(LPC_POOL_PORT80[0]);
#ifdef HAS_TASK_KEYPROTO
/* Handle keyboard interface writes */
st = LM4_LPC_ST(LPC_CH_KEYBOARD);
if (st & LM4_LPC_ST_FRMH)
keyboard_host_write(LPC_POOL_KEYBOARD[0], st & LM4_LPC_ST_CMD);
if (mis & LM4_LPC_INT_MASK(LPC_CH_KEYBOARD, 1)) {
/* Host read data; wake up task to send remaining bytes */
task_wake(TASK_ID_KEYPROTO);
}
#endif
#ifdef CONFIG_UART_HOST
/* Handle COMx */
if (lpc_comx_has_char()) {
/* Copy a character to the UART if there's space */
if (uart_comx_putc_ok())
uart_comx_putc(lpc_comx_get_char());
}
#endif
/* Debugging: print changes to LPC0RESET */
if (mis & BIT(31)) {
if (LM4_LPC_LPCSTS & BIT(10)) {
int i;
/* Store port 80 reset event */
port_80_write(PORT_80_EVENT_RESET);
/*
* Workaround for crosbug.com/p/12349; clear all FRMH
* bits so host writes will trigger interrupts.
*/
for (i = 0; i < 8; i++)
LM4_LPC_ST(i) &= ~LM4_LPC_ST_FRMH;
#ifdef CONFIG_CHIPSET_RESET_HOOK
/* Notify HOOK_CHIPSET_RESET */
hook_call_deferred(&lpc_chipset_reset_data, MSEC);
#endif
}
CPRINTS("LPC RESET# %sasserted",
lpc_get_pltrst_asserted() ? "" : "de");
}
}
DECLARE_IRQ(LM4_IRQ_LPC, lpc_interrupt, 2);
/* Enable LPC ACPI-EC interrupts */
void lpc_enable_acpi_interrupts(void)
{
LM4_LPC_LPCIM |= LM4_LPC_INT_MASK(LPC_CH_ACPI, 6);
}
/* Disable LPC ACPI-EC interrupts */
void lpc_disable_acpi_interrupts(void)
{
LM4_LPC_LPCIM &= ~(LM4_LPC_INT_MASK(LPC_CH_ACPI, 6));
}
static void lpc_init(void)
{
/* Enable LPC clock in run and sleep modes. */
clock_enable_peripheral(CGC_OFFSET_LPC, 0x1,
CGC_MODE_RUN | CGC_MODE_SLEEP);
LM4_LPC_LPCIM = 0;
LM4_LPC_LPCCTL = 0;
LM4_LPC_LPCIRQCTL = 0;
/* Configure GPIOs */
gpio_config_module(MODULE_LPC, 1);
/*
* Set LPC channel 0 to I/O address 0x62 (data) / 0x66 (command),
* single endpoint, offset 0 for host command/writes and 1 for EC
* data writes, pool bytes 0(data)/1(cmd)
*/
LM4_LPC_ADR(LPC_CH_ACPI) = EC_LPC_ADDR_ACPI_DATA;
LM4_LPC_CTL(LPC_CH_ACPI) = (LPC_POOL_OFFS_ACPI << (5 - 1));
LM4_LPC_ST(LPC_CH_ACPI) = 0;
/* Unmask interrupt for host command and data writes */
LM4_LPC_LPCIM |= LM4_LPC_INT_MASK(LPC_CH_ACPI, 6);
/*
* Set LPC channel 1 to I/O address 0x80 (data), single endpoint,
* pool bytes 4(data)/5(cmd).
*/
LM4_LPC_ADR(LPC_CH_PORT80) = 0x80;
LM4_LPC_CTL(LPC_CH_PORT80) = (LPC_POOL_OFFS_PORT80 << (5 - 1));
/* Unmask interrupt for host data writes */
LM4_LPC_LPCIM |= LM4_LPC_INT_MASK(LPC_CH_PORT80, 2);
/*
* Set LPC channel 2 to I/O address 0x880, range endpoint,
* arbitration disabled, pool bytes 512-639. To access this from
* x86, use the following command to set GEN_LPC2:
*
* pci_write32 0 0x1f 0 0x88 0x007c0801
*/
LM4_LPC_ADR(LPC_CH_CMD_DATA) = EC_LPC_ADDR_HOST_ARGS;
LM4_LPC_CTL(LPC_CH_CMD_DATA) = 0x8019 |
(LPC_POOL_OFFS_CMD_DATA << (5 - 1));
/*
* Set LPC channel 3 to I/O address 0x60 (data) / 0x64 (command),
* single endpoint, offset 0 for host command/writes and 1 for EC
* data writes, pool bytes 0(data)/1(cmd)
*/
LM4_LPC_ADR(LPC_CH_KEYBOARD) = 0x60;
LM4_LPC_CTL(LPC_CH_KEYBOARD) = (BIT(24)/* IRQSEL1 */) |
(0 << 18/* IRQEN1 */) | (LPC_POOL_OFFS_KEYBOARD << (5 - 1));
LM4_LPC_ST(LPC_CH_KEYBOARD) = 0;
/* Unmask interrupt for host command/data writes and data reads */
LM4_LPC_LPCIM |= LM4_LPC_INT_MASK(LPC_CH_KEYBOARD, 7);
/*
* Set LPC channel 4 to I/O address 0x200 (data) / 0x204 (command),
* single endpoint, offset 0 for host command/writes and 1 for EC
* data writes, pool bytes 0(data)/1(cmd)
*/
LM4_LPC_ADR(LPC_CH_CMD) = EC_LPC_ADDR_HOST_DATA;
LM4_LPC_CTL(LPC_CH_CMD) = (LPC_POOL_OFFS_CMD << (5 - 1));
/*
* Initialize status bits to 0. We never set the ACPI burst status bit,
* so this guarantees that at least one status bit will always be 0.
* This is used by comm_lpc.c to detect that the EC is present on the
* LPC bus. See crosbug.com/p/10963.
*/
LM4_LPC_ST(LPC_CH_CMD) = 0;
/* Unmask interrupt for host command writes */
LM4_LPC_LPCIM |= LM4_LPC_INT_MASK(LPC_CH_CMD, 4);
/*
* Set LPC channel 5 to I/O address 0x900, range endpoint,
* arbitration enabled, pool bytes 768-1023. To access this from
* x86, use the following command to set GEN_LPC3:
*
* pci_write32 0 0x1f 0 0x8c 0x007c0901
*/
LM4_LPC_ADR(LPC_CH_MEMMAP) = EC_LPC_ADDR_MEMMAP;
LM4_LPC_CTL(LPC_CH_MEMMAP) = 0x0019 | (LPC_POOL_OFFS_MEMMAP << (5 - 1));
#ifdef CONFIG_UART_HOST
/*
* Set LPC channel 7 to COM port I/O address. Note that channel 7
* ignores the TYPE bit and is always an 8-byte range.
*/
LM4_LPC_ADR(LPC_CH_COMX) = LPC_COMX_ADDR;
/*
* In theory we could configure IRQSELs and set IRQEN2/CX, and then the
* host could enable IRQs on its own. So far that hasn't been
* necessary, and due to the issues with IRQs (see wait_irq_sent()
* above) it might not work anyway.
*/
LM4_LPC_CTL(LPC_CH_COMX) = 0x0004 | (LPC_POOL_OFFS_COMX << (5 - 1));
/* Enable COMx emulation for reads and writes. */
LM4_LPC_LPCDMACX = 0x00310000;
/*
* Unmask interrupt for host data writes. We don't need interrupts for
* reads, because there's no flow control in that direction; LPC is
* much faster than the UART, and the UART doesn't have anywhere
* sensible to buffer input anyway.
*/
LM4_LPC_LPCIM |= LM4_LPC_INT_MASK(LPC_CH_COMX, 2);
#endif /* CONFIG_UART_HOST */
/*
* Unmask LPC bus reset interrupt. This lets us monitor the PCH
* PLTRST# signal for debugging.
*/
LM4_LPC_LPCIM |= BIT(31);
/* Enable LPC channels */
LM4_LPC_LPCCTL = LM4_LPC_SCI_CLK_1 |
BIT(LPC_CH_ACPI) |
BIT(LPC_CH_PORT80) |
BIT(LPC_CH_CMD_DATA) |
BIT(LPC_CH_KEYBOARD) |
BIT(LPC_CH_CMD) |
BIT(LPC_CH_MEMMAP);
#ifdef CONFIG_UART_HOST
LM4_LPC_LPCCTL |= 1 << LPC_CH_COMX;
#endif
/*
* Ensure the EC (slave) has control of the memory-mapped I/O space.
* Once the EC has won arbitration for the memory-mapped space, it will
* keep control of it until it writes the last byte in the space.
* (That never happens; we can't use the last byte in the space because
* ACPI can't see it anyway.)
*/
while (!(LM4_LPC_ST(LPC_CH_MEMMAP) & 0x10)) {
/* Clear HW1ST */
LM4_LPC_ST(LPC_CH_MEMMAP) &= ~0x40;
/* Do a dummy slave write; this should cause SW1ST to be set */
*LPC_POOL_MEMMAP = *LPC_POOL_MEMMAP;
}
/* Initialize host args and memory map to all zero */
memset(lpc_host_args, 0, sizeof(*lpc_host_args));
memset(lpc_get_memmap_range(), 0, EC_MEMMAP_SIZE);
/* We support LPC args and version 3 protocol */
*(lpc_get_memmap_range() + EC_MEMMAP_HOST_CMD_FLAGS) =
EC_HOST_CMD_FLAG_LPC_ARGS_SUPPORTED |
EC_HOST_CMD_FLAG_VERSION_3;
/* Enable LPC interrupt */
task_enable_irq(LM4_IRQ_LPC);
#ifdef CONFIG_UART_HOST
/* Enable COMx UART */
uart_comx_enable();
#endif
/* Sufficiently initialized */
init_done = 1;
/* Update host events now that we can copy them to memmap */
lpc_update_host_event_status();
}
/*
* Set prio to higher than default; this way LPC memory mapped data is ready
* before other inits try to initialize their memmap data.
*/
DECLARE_HOOK(HOOK_INIT, lpc_init, HOOK_PRIO_INIT_LPC);
static void lpc_tick(void)
{
/*
* Make sure pending LPC interrupts have been processed.
* This works around a LM4 bug where host writes sometimes
* don't trigger interrupts. See crosbug.com/p/13965.
*/
task_trigger_irq(LM4_IRQ_LPC);
}
DECLARE_HOOK(HOOK_TICK, lpc_tick, HOOK_PRIO_DEFAULT);
/**
* Get protocol information
*/
static enum ec_status lpc_get_protocol_info(struct host_cmd_handler_args *args)
{
struct ec_response_get_protocol_info *r = args->response;
memset(r, 0, sizeof(*r));
r->protocol_versions = BIT(2) | BIT(3);
r->max_request_packet_size = EC_LPC_HOST_PACKET_SIZE;
r->max_response_packet_size = EC_LPC_HOST_PACKET_SIZE;
r->flags = 0;
args->response_size = sizeof(*r);
return EC_SUCCESS;
}
DECLARE_HOST_COMMAND(EC_CMD_GET_PROTOCOL_INFO,
lpc_get_protocol_info,
EC_VER_MASK(0));