/* SPDX-License-Identifier: GPL-2.0-or-later */ #define __SIMPLE_DEVICE__ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define GPIO_DWx_SIZE(x) (sizeof(uint32_t) * (x)) #define PAD_CFG_OFFSET(x, dw_num) ((x) + GPIO_DWx_SIZE(dw_num)) #define PAD_CFG0_OFFSET(x) PAD_CFG_OFFSET(x, 0) #define PAD_CFG1_OFFSET(x) PAD_CFG_OFFSET(x, 1) #define PAD_CFG2_OFFSET(x) PAD_CFG_OFFSET(x, 2) #define PAD_CFG3_OFFSET(x) PAD_CFG_OFFSET(x, 3) #define PAD_DW0_MASK (PAD_CFG0_TX_STATE | \ PAD_CFG0_TX_DISABLE | PAD_CFG0_RX_DISABLE | PAD_CFG0_MODE_MASK |\ PAD_CFG0_ROUTE_MASK | PAD_CFG0_RXTENCFG_MASK | \ PAD_CFG0_RXINV_MASK | PAD_CFG0_PREGFRXSEL | \ PAD_CFG0_TRIG_MASK | PAD_CFG0_RXRAW1_MASK | PAD_CFG0_NAFVWE_ENABLE |\ PAD_CFG0_RXPADSTSEL_MASK | PAD_CFG0_RESET_MASK) #if CONFIG(SOC_INTEL_COMMON_BLOCK_GPIO_PADCFG_PADTOL) #define PAD_DW1_MASK (PAD_CFG1_IOSTERM_MASK | \ PAD_CFG1_PULL_MASK | \ PAD_CFG1_TOL_MASK | \ PAD_CFG1_IOSSTATE_MASK) #else #define PAD_DW1_MASK (PAD_CFG1_IOSTERM_MASK | \ PAD_CFG1_PULL_MASK | \ PAD_CFG1_IOSSTATE_MASK) #endif #define PAD_DW2_MASK (PAD_CFG2_DEBOUNCE_MASK) #define PAD_DW3_MASK (0) #define MISCCFG_GPE0_DW0_SHIFT 8 #define MISCCFG_GPE0_DW0_MASK (0xf << MISCCFG_GPE0_DW0_SHIFT) #define MISCCFG_GPE0_DW1_SHIFT 12 #define MISCCFG_GPE0_DW1_MASK (0xf << MISCCFG_GPE0_DW1_SHIFT) #define MISCCFG_GPE0_DW2_SHIFT 16 #define MISCCFG_GPE0_DW2_MASK (0xf << MISCCFG_GPE0_DW2_SHIFT) #define GPI_SMI_STS_OFFSET(comm, group) ((comm)->gpi_smi_sts_reg_0 + \ ((group) * sizeof(uint32_t))) #define GPI_SMI_EN_OFFSET(comm, group) ((comm)->gpi_smi_en_reg_0 + \ ((group) * sizeof(uint32_t))) #define GPI_NMI_STS_OFFSET(comm, group) ((comm)->gpi_nmi_sts_reg_0 + \ ((group) * sizeof(uint32_t))) #define GPI_NMI_EN_OFFSET(comm, group) ((comm)->gpi_nmi_en_reg_0 + \ ((group) * sizeof(uint32_t))) #define GPI_IS_OFFSET(comm, group) ((comm)->gpi_int_sts_reg_0 + \ ((group) * sizeof(uint32_t))) #define GPI_IE_OFFSET(comm, group) ((comm)->gpi_int_en_reg_0 + \ ((group) * sizeof(uint32_t))) #define GPI_GPE_STS_OFFSET(comm, group) ((comm)->gpi_gpe_sts_reg_0 + \ ((group) * sizeof(uint32_t))) #define GPI_GPE_EN_OFFSET(comm, group) ((comm)->gpi_gpe_en_reg_0 + \ ((group) * sizeof(uint32_t))) static inline size_t relative_pad_in_comm(const struct pad_community *comm, gpio_t gpio) { return gpio - comm->first_pad; } /* find the group within the community that the pad is a part of */ static inline size_t gpio_group_index(const struct pad_community *comm, unsigned int relative_pad) { size_t i; if (!comm->groups) die("Failed to get comm->groups."); /* find the base pad number for this pad's group */ for (i = 0; i < comm->num_groups; i++) { if (relative_pad >= comm->groups[i].first_pad && relative_pad < comm->groups[i].first_pad + comm->groups[i].size) { return i; } } printk(BIOS_ERR, "%s: pad %d is not found in community %s!\n", __func__, relative_pad, comm->name); BUG(); return i; } static inline size_t gpio_group_index_scaled(const struct pad_community *comm, unsigned int relative_pad, size_t scale) { return gpio_group_index(comm, relative_pad) * scale; } static inline size_t gpio_within_group(const struct pad_community *comm, unsigned int relative_pad) { size_t i; i = gpio_group_index(comm, relative_pad); return relative_pad - comm->groups[i].first_pad; } static inline uint32_t gpio_bitmask_within_group( const struct pad_community *comm, unsigned int relative_pad) { return 1U << gpio_within_group(comm, relative_pad); } static const struct pad_community *gpio_get_community(gpio_t pad) { size_t gpio_communities; size_t i; const struct pad_community *comm; comm = soc_gpio_get_community(&gpio_communities); for (i = 0; i < gpio_communities; i++, comm++) { if (pad >= comm->first_pad && pad <= comm->last_pad) return comm; } printk(BIOS_ERR, "%s pad %d not found\n", __func__, pad); die("Invalid GPIO pad number\n"); return NULL; } static void gpio_configure_owner(const struct pad_config *cfg, const struct pad_community *comm) { uint32_t hostsw_own; uint16_t hostsw_own_offset; int pin; pin = relative_pad_in_comm(comm, cfg->pad); /* Based on the gpio pin number configure the corresponding bit in * HOSTSW_OWN register. Value of 0x1 indicates GPIO Driver onwership. */ hostsw_own_offset = comm->host_own_reg_0; hostsw_own_offset += gpio_group_index_scaled(comm, pin, sizeof(uint32_t)); hostsw_own = pcr_read32(comm->port, hostsw_own_offset); /* The 4th bit in pad_config 1 (RO) is used to indicate if the pad * needs GPIO driver ownership. Set the bit if GPIO driver ownership * requested, otherwise clear the bit. */ if (cfg->pad_config[1] & PAD_CFG_OWN_GPIO_DRIVER) hostsw_own |= gpio_bitmask_within_group(comm, pin); else hostsw_own &= ~gpio_bitmask_within_group(comm, pin); pcr_write32(comm->port, hostsw_own_offset, hostsw_own); } static void gpi_enable_gpe(const struct pad_config *cfg, const struct pad_community *comm, int group, int pin) { uint16_t en_reg; uint32_t en_value; /* Do not configure GPE_EN if PAD is not configured for SCI/wake */ if (((cfg->pad_config[0]) & PAD_CFG0_ROUTE_SCI) != PAD_CFG0_ROUTE_SCI) return; /* Get comm offset and bit mask to be set as per pin */ en_reg = GPI_GPE_EN_OFFSET(comm, group); en_value = gpio_bitmask_within_group(comm, pin); /* Set enable bits */ pcr_or32(comm->port, en_reg, en_value); if (CONFIG(DEBUG_GPIO)) { printk(BIOS_DEBUG, "GPE_EN[0x%02x, %02zd]: Reg: 0x%x, Value = 0x%x\n", comm->port, relative_pad_in_comm(comm, cfg->pad), en_reg, pcr_read32(comm->port, en_reg)); } } static void gpi_enable_smi(const struct pad_config *cfg, const struct pad_community *comm, int group, int pin) { uint16_t sts_reg; uint16_t en_reg; uint32_t en_value; if (((cfg->pad_config[0]) & PAD_CFG0_ROUTE_SMI) != PAD_CFG0_ROUTE_SMI) return; sts_reg = GPI_SMI_STS_OFFSET(comm, group); en_reg = GPI_SMI_EN_OFFSET(comm, group); en_value = gpio_bitmask_within_group(comm, pin); /* Write back 1 to reset the sts bit */ pcr_rmw32(comm->port, sts_reg, en_value, 0); /* Set enable bits */ pcr_or32(comm->port, en_reg, en_value); } static void gpi_enable_nmi(const struct pad_config *cfg, const struct pad_community *comm, int group, int pin) { uint16_t sts_reg; uint16_t en_reg; uint32_t en_value; if (((cfg->pad_config[0]) & PAD_CFG0_ROUTE_NMI) != PAD_CFG0_ROUTE_NMI) return; /* Do not configure NMI if the platform doesn't support it */ if (!comm->gpi_nmi_sts_reg_0 || !comm->gpi_nmi_en_reg_0) return; sts_reg = GPI_NMI_STS_OFFSET(comm, group); en_reg = GPI_NMI_EN_OFFSET(comm, group); en_value = gpio_bitmask_within_group(comm, pin); /* Write back 1 to reset the sts bit */ pcr_rmw32(comm->port, sts_reg, en_value, 0); /* Set enable bits */ pcr_or32(comm->port, en_reg, en_value); } /* 120 GSIs is the default for IOxAPIC */ static uint32_t gpio_ioapic_irqs_used[120 / (sizeof(uint32_t) * BITS_PER_BYTE) + 1]; static void set_ioapic_used(uint32_t irq) { size_t word_offset = irq / 32; size_t bit_offset = irq % 32; assert(word_offset < ARRAY_SIZE(gpio_ioapic_irqs_used)); gpio_ioapic_irqs_used[word_offset] |= BIT(bit_offset); } bool gpio_routes_ioapic_irq(uint32_t irq) { size_t word_offset = irq / 32; size_t bit_offset = irq % 32; assert(word_offset < ARRAY_SIZE(gpio_ioapic_irqs_used)); return (gpio_ioapic_irqs_used[word_offset] & BIT(bit_offset)) != 0; } static void gpio_configure_itss(const struct pad_config *cfg, uint16_t port, uint16_t pad_cfg_offset) { /* No ITSS configuration in SMM. */ if (ENV_SMM) return; int irq; /* Set up ITSS polarity if pad is routed to APIC. * * The ITSS takes only active high interrupt signals. Therefore, * if the pad configuration indicates an inversion assume the * intent is for the ITSS polarity. Before forwarding on the * request to the APIC there's an inversion setting for how the * signal is forwarded to the APIC. Honor the inversion setting * in the GPIO pad configuration so that a hardware active low * signal looks that way to the APIC (double inversion). */ if (!(cfg->pad_config[0] & PAD_CFG0_ROUTE_IOAPIC)) return; irq = pcr_read32(port, PAD_CFG1_OFFSET(pad_cfg_offset)); irq &= PAD_CFG1_IRQ_MASK; if (!irq) { printk(BIOS_ERR, "GPIO %u doesn't support APIC routing,\n", cfg->pad); return; } if (CONFIG(SOC_INTEL_COMMON_BLOCK_GPIO_ITSS_POL_CFG)) itss_set_irq_polarity(irq, !!(cfg->pad_config[0] & PAD_CFG0_RX_POL_INVERT)); set_ioapic_used(irq); } /* Number of DWx config registers can be different for different SOCs */ static uint16_t pad_config_offset(const struct pad_community *comm, gpio_t pad) { size_t offset; offset = relative_pad_in_comm(comm, pad); offset *= GPIO_DWx_SIZE(GPIO_NUM_PAD_CFG_REGS); return offset + comm->pad_cfg_base; } static uint32_t gpio_pad_reset_config_override(const struct pad_community *comm, uint32_t config_value) { const struct reset_mapping *rst_map = comm->reset_map; int i; if (rst_map == NULL || comm->num_reset_vals == 0) return config_value;/* Logical reset values equal chipset values */ for (i = 0; i < comm->num_reset_vals; i++, rst_map++) { if ((config_value & PAD_CFG0_RESET_MASK) == rst_map->logical) { config_value &= ~PAD_CFG0_RESET_MASK; config_value |= rst_map->chipset; return config_value; } } printk(BIOS_ERR, "%s: Logical to Chipset mapping not found\n", __func__); return config_value; } static const int mask[4] = { PAD_DW0_MASK, PAD_DW1_MASK, PAD_DW2_MASK, PAD_DW3_MASK }; static void gpio_configure_pad(const struct pad_config *cfg) { const struct pad_community *comm; uint16_t config_offset; uint32_t pad_conf, soc_pad_conf; int i, pin, group; if (!cfg) { printk(BIOS_ERR, "%s: cfg value is NULL\n", __func__); return; } comm = gpio_get_community(cfg->pad); if (!comm) { printk(BIOS_ERR, "%s: Could not find community for pad: 0x%x\n", __func__, cfg->pad); return; } config_offset = pad_config_offset(comm, cfg->pad); pin = relative_pad_in_comm(comm, cfg->pad); group = gpio_group_index(comm, pin); for (i = 0; i < GPIO_NUM_PAD_CFG_REGS; i++) { pad_conf = pcr_read32(comm->port, PAD_CFG_OFFSET(config_offset, i)); soc_pad_conf = cfg->pad_config[i]; if (i == 0) soc_pad_conf = gpio_pad_reset_config_override(comm, soc_pad_conf); soc_pad_conf &= mask[i]; soc_pad_conf |= pad_conf & ~mask[i]; /* Patch GPIO settings for SoC specifically */ soc_pad_conf = soc_gpio_pad_config_fixup(cfg, i, soc_pad_conf); if (CONFIG(DEBUG_GPIO)) printk(BIOS_DEBUG, "gpio_padcfg [0x%02x, %02d] DW%d [0x%08x : 0x%08x" " : 0x%08x]\n", comm->port, pin, i, pad_conf,/* old value */ cfg->pad_config[i],/* value passed from gpio table */ soc_pad_conf);/*new value*/ pcr_write32(comm->port, PAD_CFG_OFFSET(config_offset, i), soc_pad_conf); } gpio_configure_itss(cfg, comm->port, config_offset); gpio_configure_owner(cfg, comm); gpi_enable_smi(cfg, comm, group, pin); gpi_enable_nmi(cfg, comm, group, pin); gpi_enable_gpe(cfg, comm, group, pin); if (cfg->lock_action) gpio_lock_pad(cfg->pad, cfg->lock_action); } void gpio_configure_pads(const struct pad_config *cfg, size_t num_pads) { size_t i; for (i = 0; i < num_pads; i++) gpio_configure_pad(cfg + i); } /* * This functions checks to see if there is an override config present for the * provided pad_config. If no override config is present, then the input config * is returned. Else, it returns the override config. */ static const struct pad_config *gpio_get_config(const struct pad_config *c, const struct pad_config *override_cfg_table, size_t num) { size_t i; if (override_cfg_table == NULL) return c; for (i = 0; i < num; i++) { if (c->pad == override_cfg_table[i].pad) return override_cfg_table + i; } return c; } void gpio_configure_pads_with_override(const struct pad_config *base_cfg, size_t base_num_pads, const struct pad_config *override_cfg, size_t override_num_pads) { size_t i; const struct pad_config *c; for (i = 0; i < base_num_pads; i++) { c = gpio_get_config(base_cfg + i, override_cfg, override_num_pads); gpio_configure_pad(c); } } struct pad_config *new_padbased_table(void) { struct pad_config *padbased_table; padbased_table = malloc(sizeof(struct pad_config) * TOTAL_PADS); memset(padbased_table, 0, sizeof(struct pad_config) * TOTAL_PADS); return padbased_table; } void gpio_padbased_override(struct pad_config *padbased_table, const struct pad_config *override_cfg, size_t override_num_pads) { for (size_t i = 0; i < override_num_pads; i++) { /* Prevent overflow hack */ ASSERT(override_cfg[i].pad < TOTAL_PADS); padbased_table[override_cfg[i].pad] = override_cfg[i]; } } void gpio_configure_pads_with_padbased(struct pad_config *padbased_table) { size_t i; const struct pad_config *cfg = padbased_table; for (i = 0; i < TOTAL_PADS; i++) { /* Consider unmapped pin as default setting, skip */ if (cfg[i].pad == 0 && cfg[i].pad_config[0] == 0) continue; gpio_configure_pad(&cfg[i]); } } void *gpio_dwx_address(const gpio_t pad) { /* Calculate Address of DW0 register for given GPIO * pad - GPIO number * returns - address of GPIO */ const struct pad_community *comm = gpio_get_community(pad); uint16_t config_offset; config_offset = pad_config_offset(comm, pad); return pcr_reg_address(comm->port, config_offset); } uint8_t gpio_get_pad_portid(const gpio_t pad) { /* Get the port id of given pad * pad - GPIO number * returns - given pad port id */ const struct pad_community *comm = gpio_get_community(pad); return comm->port; } void gpio_input_pulldown(gpio_t gpio) { struct pad_config cfg = PAD_CFG_GPI(gpio, DN_20K, DEEP); gpio_configure_pad(&cfg); } void gpio_input_pullup(gpio_t gpio) { struct pad_config cfg = PAD_CFG_GPI(gpio, UP_20K, DEEP); gpio_configure_pad(&cfg); } void gpio_input(gpio_t gpio) { struct pad_config cfg = PAD_CFG_GPI(gpio, NONE, DEEP); gpio_configure_pad(&cfg); } void gpio_output(gpio_t gpio, int value) { struct pad_config cfg = PAD_CFG_GPO(gpio, value, DEEP); gpio_configure_pad(&cfg); } int gpio_get(gpio_t gpio_num) { const struct pad_community *comm = gpio_get_community(gpio_num); uint16_t config_offset; uint32_t reg; config_offset = pad_config_offset(comm, gpio_num); reg = pcr_read32(comm->port, config_offset); return !!(reg & PAD_CFG0_RX_STATE); } int gpio_tx_get(gpio_t gpio_num) { const struct pad_community *comm = gpio_get_community(gpio_num); uint16_t config_offset; uint32_t reg; config_offset = pad_config_offset(comm, gpio_num); reg = pcr_read32(comm->port, config_offset); return !!(reg & PAD_CFG0_TX_STATE); } static void gpio_pad_config_lock_using_sbi(const struct gpio_lock_config *pad_info, uint8_t pid, uint16_t offset, const uint32_t bit_mask) { int status; uint8_t response; uint32_t data; struct pcr_sbi_msg msg = { .pid = pid, .offset = offset, .opcode = GPIO_LOCK_UNLOCK, .is_posted = false, .fast_byte_enable = 0xf, .bar = 0, .fid = 0, }; if (!(pad_info->lock_action & GPIO_LOCK_FULL)) { printk(BIOS_ERR, "%s: Error: no lock_action specified for pad %d!\n", __func__, pad_info->pad); return; } if ((pad_info->lock_action & GPIO_LOCK_CONFIG) == GPIO_LOCK_CONFIG) { if (CONFIG(DEBUG_GPIO)) printk(BIOS_INFO, "%s: Locking pad %d configuration\n", __func__, pad_info->pad); data = pcr_read32(pid, offset) | bit_mask; status = pcr_execute_sideband_msg(PCH_DEV_P2SB, &msg, &data, &response); if (status || response) printk(BIOS_ERR, "Failed to lock GPIO PAD, response = %d\n", response); } if ((pad_info->lock_action & GPIO_LOCK_TX) == GPIO_LOCK_TX) { if (CONFIG(DEBUG_GPIO)) printk(BIOS_INFO, "%s: Locking pad %d Tx state\n", __func__, pad_info->pad); offset += sizeof(uint32_t); data = pcr_read32(pid, offset) | bit_mask; msg.offset = offset; status = pcr_execute_sideband_msg(PCH_DEV_P2SB, &msg, &data, &response); if (status || response) printk(BIOS_ERR, "Failed to lock GPIO PAD Tx state, response = %d\n", response); } } int gpio_lock_pads(const struct gpio_lock_config *pad_list, const size_t count) { const struct pad_community *comm; uint16_t offset; size_t rel_pad; gpio_t pad; if (!CONFIG(SOC_INTEL_COMMON_BLOCK_SMM_LOCK_GPIO_PADS)) return -1; /* * FSP-S will unlock all the GPIO pads and hide the P2SB device. With * the device hidden, we will not be able to send the sideband interface * message to lock the GPIO configuration. Therefore, we need to unhide * the P2SB device which can only be done in SMM requiring that this * function is called from SMM. */ if (!ENV_SMM) { printk(BIOS_ERR, "%s: Error: must be called from SMM!\n", __func__); return -1; } if ((pad_list == NULL) || (count == 0)) { printk(BIOS_ERR, "%s: Error: pad_list null or count = 0!\n", __func__); return -1; } p2sb_unhide(); for (int x = 0; x < count; x++) { pad = pad_list[x].pad; comm = gpio_get_community(pad); rel_pad = relative_pad_in_comm(comm, pad); offset = comm->pad_cfg_lock_offset; if (!offset) { printk(BIOS_ERR, "%s: Error: offset not defined for pad %d!\n", __func__, pad); continue; } /* PADCFGLOCK and PADCFGLOCKTX registers for each community are contiguous */ offset += gpio_group_index_scaled(comm, rel_pad, 2 * sizeof(uint32_t)); const uint32_t bit_mask = gpio_bitmask_within_group(comm, rel_pad); gpio_pad_config_lock_using_sbi(&pad_list[x], comm->port, offset, bit_mask); } p2sb_hide(); } static void gpio_pad_config_lock_using_pcr(const struct gpio_lock_config *pad_info, uint8_t pid, uint16_t offset, const uint32_t bit_mask) { if ((pad_info->lock_action & GPIO_LOCK_CONFIG) == GPIO_LOCK_CONFIG) { if (CONFIG(DEBUG_GPIO)) printk(BIOS_INFO, "%s: Locking pad %d configuration\n", __func__, pad_info->pad); pcr_or32(pid, offset, bit_mask); } if ((pad_info->lock_action & GPIO_LOCK_TX) == GPIO_LOCK_TX) { if (CONFIG(DEBUG_GPIO)) printk(BIOS_INFO, "%s: Locking pad %d TX state\n", __func__, pad_info->pad); pcr_or32(pid, offset + sizeof(uint32_t), bit_mask); } } static int gpio_non_smm_lock_pad(const struct gpio_lock_config *pad_info) { const struct pad_community *comm = gpio_get_community(pad_info->pad); uint16_t offset; size_t rel_pad; if (!pad_info) { printk(BIOS_ERR, "%s: Error: pad_info is null!\n", __func__); return -1; } if (cpu_soc_is_in_untrusted_mode()) { printk(BIOS_ERR, "%s: Error: IA Untrusted Mode enabled, can't lock pad!\n", __func__); return -1; } rel_pad = relative_pad_in_comm(comm, pad_info->pad); offset = comm->pad_cfg_lock_offset; if (!offset) { printk(BIOS_ERR, "%s: Error: offset not defined for pad %d!\n", __func__, pad_info->pad); return -1; } /* PADCFGLOCK and PADCFGLOCKTX registers for each community are contiguous */ offset += gpio_group_index_scaled(comm, rel_pad, 2 * sizeof(uint32_t)); const uint32_t bit_mask = gpio_bitmask_within_group(comm, rel_pad); if (CONFIG(SOC_INTEL_COMMON_BLOCK_GPIO_LOCK_USING_PCR)) { if (CONFIG(DEBUG_GPIO)) printk(BIOS_INFO, "Locking pad configuration using PCR\n"); gpio_pad_config_lock_using_pcr(pad_info, comm->port, offset, bit_mask); } else if (CONFIG(SOC_INTEL_COMMON_BLOCK_GPIO_LOCK_USING_SBI)) { if (CONFIG(DEBUG_GPIO)) printk(BIOS_INFO, "Locking pad configuration using SBI\n"); gpio_pad_config_lock_using_sbi(pad_info, comm->port, offset, bit_mask); } else { printk(BIOS_ERR, "%s: Error: No pad configuration lock method is selected!\n", __func__); } return 0; } int gpio_lock_pad(const gpio_t pad, enum gpio_lock_action lock_action) { /* Skip locking GPIO PAD in early stages or in recovery mode */ if (ENV_ROMSTAGE_OR_BEFORE || vboot_recovery_mode_enabled()) return -1; const struct gpio_lock_config pads = { .pad = pad, .lock_action = lock_action }; if (!ENV_SMM && !CONFIG(SOC_INTEL_COMMON_BLOCK_SMM_LOCK_GPIO_PADS)) return gpio_non_smm_lock_pad(&pads); return gpio_lock_pads(&pads, 1); } void gpio_set(gpio_t gpio_num, int value) { const struct pad_community *comm = gpio_get_community(gpio_num); uint16_t config_offset; config_offset = pad_config_offset(comm, gpio_num); pcr_rmw32(comm->port, config_offset, ~PAD_CFG0_TX_STATE, (!!value & PAD_CFG0_TX_STATE)); } uint16_t gpio_acpi_pin(gpio_t gpio_num) { const struct pad_community *comm; size_t group, pin; if (CONFIG(SOC_INTEL_COMMON_BLOCK_GPIO_MULTI_ACPI_DEVICES)) return relative_pad_in_comm(gpio_get_community(gpio_num), gpio_num); comm = gpio_get_community(gpio_num); pin = relative_pad_in_comm(comm, gpio_num); group = gpio_group_index(comm, pin); /* If pad base is not set then use GPIO number as ACPI pin number. */ if (comm->groups[group].acpi_pad_base == PAD_BASE_NONE) return gpio_num; /* * If this group has a non-zero pad base then compute the ACPI pin * number from the pad base and the relative pad in the group. */ return comm->groups[group].acpi_pad_base + gpio_within_group(comm, pin); } static void print_gpi_status(const struct gpi_status *sts) { int i; int group; int index; int bit_set; int num_groups; int abs_bit; size_t gpio_communities; const struct pad_community *comm; comm = soc_gpio_get_community(&gpio_communities); for (i = 0; i < gpio_communities; i++) { num_groups = comm->num_gpi_regs; index = comm->gpi_status_offset; for (group = 0; group < num_groups; group++, index++) { for (bit_set = comm->max_pads_per_group - 1; bit_set >= 0; bit_set--) { if (!(sts->grp[index] & (1 << bit_set))) continue; abs_bit = bit_set; abs_bit += group * comm->max_pads_per_group; printk(BIOS_DEBUG, "%s %d\n", comm->name, abs_bit); } } comm++; } } void gpi_clear_get_smi_status(struct gpi_status *sts) { int i; int group; int index; uint32_t sts_value; uint32_t en_value; size_t gpio_communities; int num_groups; const struct pad_community *comm; comm = soc_gpio_get_community(&gpio_communities); for (i = 0; i < gpio_communities; i++) { num_groups = comm->num_gpi_regs; index = comm->gpi_status_offset; for (group = 0; group < num_groups; group++, index++) { sts_value = pcr_read32(comm->port, GPI_SMI_STS_OFFSET(comm, group)); en_value = pcr_read32(comm->port, GPI_SMI_EN_OFFSET(comm, group)); sts->grp[index] = sts_value & en_value; /* Clear the set status bits. */ pcr_write32(comm->port, GPI_SMI_STS_OFFSET(comm, group), sts->grp[index]); } comm++; } if (CONFIG(DEBUG_SMI)) print_gpi_status(sts); } int gpi_status_get(const struct gpi_status *sts, gpio_t pad) { uint8_t sts_index; const struct pad_community *comm = gpio_get_community(pad); pad = relative_pad_in_comm(comm, pad); sts_index = comm->gpi_status_offset; sts_index += gpio_group_index(comm, pad); return !!(sts->grp[sts_index] & gpio_bitmask_within_group(comm, pad)); } static int gpio_route_pmc_gpio_gpe(int pmc_gpe_num) { size_t num_routes; const struct pmc_to_gpio_route *routes; int i; routes = soc_pmc_gpio_routes(&num_routes); assert(routes != NULL); for (i = 0; i < num_routes; i++, routes++) { if (pmc_gpe_num == routes->pmc) return routes->gpio; } return -1; } void gpio_route_gpe(uint8_t gpe0b, uint8_t gpe0c, uint8_t gpe0d) { int i; uint32_t misccfg_mask; uint32_t misccfg_value; int ret; size_t gpio_communities; const struct pad_community *comm; /* Get the group here for community specific MISCCFG register. * If any of these returns -1 then there is some error in devicetree * where the group is probably hardcoded and does not comply with the * PMC group defines. So we return from here and MISCFG is set to * default. */ ret = gpio_route_pmc_gpio_gpe(gpe0b); if (ret == -1) return; gpe0b = ret; ret = gpio_route_pmc_gpio_gpe(gpe0c); if (ret == -1) return; gpe0c = ret; ret = gpio_route_pmc_gpio_gpe(gpe0d); if (ret == -1) return; gpe0d = ret; misccfg_value = gpe0b << MISCCFG_GPE0_DW0_SHIFT; misccfg_value |= gpe0c << MISCCFG_GPE0_DW1_SHIFT; misccfg_value |= gpe0d << MISCCFG_GPE0_DW2_SHIFT; /* Program GPIO_MISCCFG */ misccfg_mask = ~(MISCCFG_GPE0_DW2_MASK | MISCCFG_GPE0_DW1_MASK | MISCCFG_GPE0_DW0_MASK); if (CONFIG(DEBUG_GPIO)) printk(BIOS_DEBUG, "misccfg_mask:%x misccfg_value:%x\n", misccfg_mask, misccfg_value); comm = soc_gpio_get_community(&gpio_communities); for (i = 0; i < gpio_communities; i++, comm++) pcr_rmw32(comm->port, GPIO_MISCCFG, misccfg_mask, misccfg_value); } const char *gpio_acpi_path(gpio_t gpio_num) { const struct pad_community *comm = gpio_get_community(gpio_num); return comm->acpi_path; } uint32_t __weak soc_gpio_pad_config_fixup(const struct pad_config *cfg, int dw_reg, uint32_t reg_val) { return reg_val; } void gpi_clear_int_cfg(void) { int i, group, num_groups; uint32_t sts_value; size_t gpio_communities; const struct pad_community *comm; comm = soc_gpio_get_community(&gpio_communities); for (i = 0; i < gpio_communities; i++, comm++) { num_groups = comm->num_gpi_regs; for (group = 0; group < num_groups; group++) { /* Clear the enable register */ pcr_write32(comm->port, GPI_IE_OFFSET(comm, group), 0); /* Read and clear the set status register bits*/ sts_value = pcr_read32(comm->port, GPI_IS_OFFSET(comm, group)); pcr_write32(comm->port, GPI_IS_OFFSET(comm, group), sts_value); } } } /* The function performs GPIO Power Management programming. */ void gpio_pm_configure(const uint8_t *misccfg_pm_values, size_t num) { int i; size_t gpio_communities; const uint8_t misccfg_pm_mask = (uint8_t)~MISCCFG_GPIO_PM_CONFIG_BITS; const struct pad_community *comm; comm = soc_gpio_get_community(&gpio_communities); if (gpio_communities != num) die("Incorrect GPIO community count!\n"); /* Program GPIO_MISCCFG */ for (i = 0; i < num; i++, comm++) pcr_rmw8(comm->port, GPIO_MISCCFG, misccfg_pm_mask, misccfg_pm_values[i]); } size_t gpio_get_index_in_group(gpio_t pad) { const struct pad_community *comm; size_t pin; comm = gpio_get_community(pad); pin = relative_pad_in_comm(comm, pad); return gpio_within_group(comm, pin); } static uint32_t *snapshot; static void *allocate_snapshot_space(void) { size_t gpio_communities, total = 0, i; const struct pad_community *comm; comm = soc_gpio_get_community(&gpio_communities); for (i = 0; i < gpio_communities; i++, comm++) total += comm->last_pad - comm->first_pad + 1; if (total == 0) return NULL; return malloc(total * GPIO_NUM_PAD_CFG_REGS * sizeof(uint32_t)); } void gpio_snapshot(void) { size_t gpio_communities, index, i, pad, reg; const struct pad_community *comm; uint16_t config_offset; if (snapshot == NULL) { snapshot = allocate_snapshot_space(); if (snapshot == NULL) return; } comm = soc_gpio_get_community(&gpio_communities); for (i = 0, index = 0; i < gpio_communities; i++, comm++) { for (pad = comm->first_pad; pad <= comm->last_pad; pad++) { config_offset = pad_config_offset(comm, pad); for (reg = 0; reg < GPIO_NUM_PAD_CFG_REGS; reg++) { snapshot[index] = pcr_read32(comm->port, PAD_CFG_OFFSET(config_offset, reg)); index++; } } } } size_t gpio_verify_snapshot(void) { size_t gpio_communities, index, i, pad, reg; const struct pad_community *comm; uint32_t curr_val; uint16_t config_offset; size_t changes = 0; if (snapshot == NULL) return 0; comm = soc_gpio_get_community(&gpio_communities); for (i = 0, index = 0; i < gpio_communities; i++, comm++) { for (pad = comm->first_pad; pad <= comm->last_pad; pad++) { config_offset = pad_config_offset(comm, pad); for (reg = 0; reg < GPIO_NUM_PAD_CFG_REGS; reg++) { curr_val = pcr_read32(comm->port, PAD_CFG_OFFSET(config_offset, reg)); if (curr_val != snapshot[index]) { printk(BIOS_SPEW, "%zd(DW%zd): Changed from 0x%x to 0x%x\n", pad, reg, snapshot[index], curr_val); changes++; } index++; } } } return changes; } static void snapshot_cleanup(void *unused) { free(snapshot); } BOOT_STATE_INIT_ENTRY(BS_OS_RESUME, BS_ON_ENTRY, snapshot_cleanup, NULL); BOOT_STATE_INIT_ENTRY(BS_PAYLOAD_LOAD, BS_ON_EXIT, snapshot_cleanup, NULL); bool gpio_get_vw_info(gpio_t pad, unsigned int *vw_index, unsigned int *vw_bit) { const struct pad_community *comm; unsigned int offset = 0; size_t i; comm = gpio_get_community(pad); for (i = 0; i < comm->num_vw_entries; i++) { if (pad >= comm->vw_entries[i].first_pad && pad <= comm->vw_entries[i].last_pad) break; offset += 1 + comm->vw_entries[i].last_pad - comm->vw_entries[i].first_pad; } if (i == comm->num_vw_entries) return false; offset += pad - comm->vw_entries[i].first_pad; *vw_index = comm->vw_base + offset / 8; *vw_bit = offset % 8; return true; } unsigned int gpio_get_pad_cpu_portid(gpio_t pad) { const struct pad_community *comm = gpio_get_community(pad); return comm->cpu_port; }