/* 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. */ /* 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) { uint32_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) CPRINTS("smi 0x%08x", smi); } /** * Generate SCI pulse to the host chipset via LPC0SCI. */ static void lpc_generate_sci(void) { uint32_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) CPRINTS("sci 0x%08x", sci); } /** * Update the level-sensitive wake signal to the AP. * * @param wake_events Currently asserted wake events */ static void lpc_update_wake(uint32_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 */ *(uint32_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 & (1<<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 & (1 << 31)) { if (LM4_LPC_LPCSTS & (1 << 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) = (1 << 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 |= (1 << 31); /* Enable LPC channels */ LM4_LPC_LPCCTL = LM4_LPC_SCI_CLK_1 | (1 << LPC_CH_ACPI) | (1 << LPC_CH_PORT80) | (1 << LPC_CH_CMD_DATA) | (1 << LPC_CH_KEYBOARD) | (1 << LPC_CH_CMD) | (1 << 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_resume(void) { /* Store port 80 event so we know where resume happened */ port_80_write(PORT_80_EVENT_RESUME); } DECLARE_HOOK(HOOK_CHIPSET_RESUME, lpc_resume, HOOK_PRIO_DEFAULT); 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 int 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 = (1 << 2) | (1 << 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));