/* SPDX-License-Identifier: GPL-2.0-or-later */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "drivers/intel/pmc_mux/conn/chip.h" WEAK_DEV_PTR(conn1); static void typec_orientation_fixup(void) { const struct device *conn = DEV_PTR(conn1); if (!is_dev_enabled(conn)) return; if (fw_config_probe(FW_CONFIG(DB_USB, USB4_GEN2)) || fw_config_probe(FW_CONFIG(DB_USB, USB3_ACTIVE)) || fw_config_probe(FW_CONFIG(DB_USB, USB4_GEN3)) || fw_config_probe(FW_CONFIG(DB_USB, USB3_NO_A))) { struct drivers_intel_pmc_mux_conn_config *config = conn->chip_info; if (config) { printk(BIOS_INFO, "Configure Right Type-C port orientation for retimer\n"); config->sbu_orientation = TYPEC_ORIENTATION_NORMAL; } } } static void mainboard_init(struct device *dev) { mainboard_ec_init(); typec_orientation_fixup(); variant_devtree_update(); } void __weak variant_devtree_update(void) { } void __weak variant_ramstage_init(void) { /* Default weak implementation */ } static void add_fw_config_oem_string(const struct fw_config *config, void *arg) { struct smbios_type11 *t; char buffer[64]; t = (struct smbios_type11 *)arg; snprintf(buffer, sizeof(buffer), "%s-%s", config->field_name, config->option_name); t->count = smbios_add_string(t->eos, buffer); } static void mainboard_smbios_strings(struct device *dev, struct smbios_type11 *t) { fw_config_for_each_found(add_fw_config_oem_string, t); } static void mainboard_enable(struct device *dev) { dev->ops->init = mainboard_init; dev->ops->get_smbios_strings = mainboard_smbios_strings; variant_ramstage_init(); } void mainboard_update_soc_chip_config(struct soc_intel_tigerlake_config *cfg) { int ret; if (!CONFIG(MAINBOARD_HAS_SPI_TPM_CR50)) { /* * Negotiation of long interrupt pulses is only supported via SPI. I2C is only * used on reworked prototypes on which the TPM is replaced with Dauntless under * development, it will use long pulses by default, or use the interrupt line in * a different way altogether. */ return; } ret = tlcl_lib_init(); if (ret != VB2_SUCCESS) { printk(BIOS_ERR, "tlcl_lib_init() failed: 0x%x\n", ret); return; } if (cr50_is_long_interrupt_pulse_enabled()) { printk(BIOS_INFO, "Enabling S0i3.4\n"); } else { /* * Disable S0i3.4, preventing the GPIO block from switching to * slow clock. */ printk(BIOS_INFO, "Not enabling S0i3.4\n"); cfg->LpmStateDisableMask |= LPM_S0i3_4; cfg->gpio_override_pm = 1; memset(cfg->gpio_pm, 0, sizeof(cfg->gpio_pm)); } } static void mainboard_chip_init(void *chip_info) { const struct pad_config *base_pads; const struct pad_config *override_pads; size_t base_num, override_num; base_pads = variant_base_gpio_table(&base_num); override_pads = variant_override_gpio_table(&override_num); gpio_configure_pads_with_override(base_pads, base_num, override_pads, override_num); /* * Check SATAXPCIE1 (GPP_A12) RX status to determine if SSD is NVMe or SATA and set * the IOSSTATE RX field to drive 0 or 1 back to the internal controller to ensure * the attached device is not mis-detected on resume from S0ix. */ if (gpio_get(GPP_A12)) { const struct pad_config gpio_pedet_nvme[] = { PAD_CFG_NF_IOSSTATE(GPP_A12, NONE, DEEP, NF1, HIZCRx1), }; gpio_configure_pads(gpio_pedet_nvme, ARRAY_SIZE(gpio_pedet_nvme)); printk(BIOS_INFO, "SATAXPCIE1 indicates PCIe NVMe is present\n"); } else { const struct pad_config gpio_pedet_sata[] = { PAD_CFG_NF_IOSSTATE(GPP_A12, NONE, DEEP, NF1, HIZCRx0), }; gpio_configure_pads(gpio_pedet_sata, ARRAY_SIZE(gpio_pedet_sata)); printk(BIOS_INFO, "SATAXPCIE1 indicates SATA SSD is present\n"); } } struct chip_operations mainboard_ops = { .init = mainboard_chip_init, .enable_dev = mainboard_enable, };