/* SPDX-License-Identifier: GPL-2.0-only */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* THC assignment definition */ #define THC_NONE 0 #define THC_0 1 #define THC_1 2 /* SATA DEVSLP idle timeout default values */ #define DEF_DMVAL 15 #define DEF_DITOVAL 625 #define MAX_ONBOARD_PCIE_DEVICES 256 static const struct slot_irq_constraints irq_constraints[] = { { .slot = PCI_DEV_SLOT_PCIE_3, .fns = { FIXED_INT_PIRQ(PCI_DEVFN_PCIE12, PCI_INT_A, PIRQ_A), }, }, { .slot = PCI_DEV_SLOT_IGD, .fns = { /* INTERRUPT_PIN is RO/0x01 */ FIXED_INT_ANY_PIRQ(PCI_DEV_SLOT_IGD, PCI_INT_A), }, }, { .slot = PCI_DEV_SLOT_DPTF, .fns = { /* Dynamic Tuning Technology (DTT) device IRQ is not programmable and is INT_A/PIRQ_A (IRQ 16) */ FIXED_INT_PIRQ(PCI_DEVFN_DPTF, PCI_INT_A, PIRQ_A), }, }, { .slot = PCI_DEV_SLOT_IPU, .fns = { /* INTERRUPT_PIN is RO/0x01, and INTERRUPT_LINE is RW, but S0ix fails when not set to 16 (b/193434192) */ FIXED_INT_PIRQ(PCI_DEVFN_IPU, PCI_INT_A, PIRQ_A), }, }, { .slot = PCI_DEV_SLOT_PCIE_2, .fns = { FIXED_INT_PIRQ(PCI_DEVFN_PCIE9, PCI_INT_A, PIRQ_A), FIXED_INT_PIRQ(PCI_DEVFN_PCIE10, PCI_INT_B, PIRQ_B), FIXED_INT_PIRQ(PCI_DEVFN_PCIE11, PCI_INT_C, PIRQ_C), }, }, { .slot = PCI_DEV_SLOT_TBT, .fns = { ANY_PIRQ(PCI_DEVFN_TBT0), ANY_PIRQ(PCI_DEVFN_TBT1), ANY_PIRQ(PCI_DEVFN_TBT2), ANY_PIRQ(PCI_DEVFN_TBT3), }, }, { .slot = PCI_DEV_SLOT_GNA, .fns = { /* INTERRUPT_PIN is RO/0x01 */ FIXED_INT_ANY_PIRQ(PCI_DEVFN_GNA, PCI_INT_A), }, }, { .slot = PCI_DEV_SLOT_VPU, .fns = { /* INTERRUPT_PIN is RO/0x01 */ FIXED_INT_ANY_PIRQ(PCI_DEVFN_VPU, PCI_INT_A), }, }, { .slot = PCI_DEV_SLOT_TCSS, .fns = { ANY_PIRQ(PCI_DEVFN_TCSS_XHCI), ANY_PIRQ(PCI_DEVFN_TCSS_XDCI), }, }, { .slot = PCI_DEV_SLOT_THC, .fns = { ANY_PIRQ(PCI_DEVFN_THC0), ANY_PIRQ(PCI_DEVFN_THC1), }, }, { .slot = PCI_DEV_SLOT_ISH, .fns = { DIRECT_IRQ(PCI_DEVFN_ISH), DIRECT_IRQ(PCI_DEVFN_GSPI2), ANY_PIRQ(PCI_DEVFN_UFS), }, }, { .slot = PCI_DEV_SLOT_XHCI, .fns = { ANY_PIRQ(PCI_DEVFN_XHCI), DIRECT_IRQ(PCI_DEVFN_USBOTG), ANY_PIRQ(PCI_DEVFN_CNVI_WIFI), }, }, { .slot = PCI_DEV_SLOT_SIO0, .fns = { DIRECT_IRQ(PCI_DEVFN_I2C0), DIRECT_IRQ(PCI_DEVFN_I2C1), DIRECT_IRQ(PCI_DEVFN_I2C2), DIRECT_IRQ(PCI_DEVFN_I2C3), }, }, { .slot = PCI_DEV_SLOT_CSE, .fns = { ANY_PIRQ(PCI_DEVFN_CSE), ANY_PIRQ(PCI_DEVFN_CSE_2), ANY_PIRQ(PCI_DEVFN_CSE_IDER), ANY_PIRQ(PCI_DEVFN_CSE_KT), ANY_PIRQ(PCI_DEVFN_CSE_3), ANY_PIRQ(PCI_DEVFN_CSE_4), }, }, { .slot = PCI_DEV_SLOT_SATA, .fns = { ANY_PIRQ(PCI_DEVFN_SATA), }, }, { .slot = PCI_DEV_SLOT_SIO1, .fns = { DIRECT_IRQ(PCI_DEVFN_I2C4), DIRECT_IRQ(PCI_DEVFN_I2C5), DIRECT_IRQ(PCI_DEVFN_UART2), }, }, { .slot = PCI_DEV_SLOT_PCIE_1, .fns = { FIXED_INT_PIRQ(PCI_DEVFN_PCIE1, PCI_INT_A, PIRQ_A), FIXED_INT_PIRQ(PCI_DEVFN_PCIE2, PCI_INT_B, PIRQ_B), FIXED_INT_PIRQ(PCI_DEVFN_PCIE3, PCI_INT_C, PIRQ_C), FIXED_INT_PIRQ(PCI_DEVFN_PCIE4, PCI_INT_D, PIRQ_D), FIXED_INT_PIRQ(PCI_DEVFN_PCIE5, PCI_INT_A, PIRQ_A), FIXED_INT_PIRQ(PCI_DEVFN_PCIE6, PCI_INT_B, PIRQ_B), FIXED_INT_PIRQ(PCI_DEVFN_PCIE7, PCI_INT_C, PIRQ_C), FIXED_INT_PIRQ(PCI_DEVFN_PCIE8, PCI_INT_D, PIRQ_D), }, }, { .slot = PCI_DEV_SLOT_SIO2, .fns = { /* UART0 shares an interrupt line with TSN0, so must use a PIRQ */ FIXED_INT_ANY_PIRQ(PCI_DEVFN_UART0, PCI_INT_A), /* UART1 shares an interrupt line with TSN1, so must use a PIRQ */ FIXED_INT_ANY_PIRQ(PCI_DEVFN_UART1, PCI_INT_B), DIRECT_IRQ(PCI_DEVFN_GSPI0), DIRECT_IRQ(PCI_DEVFN_GSPI1), }, }, { .slot = PCI_DEV_SLOT_ESPI, .fns = { ANY_PIRQ(PCI_DEVFN_HDA), ANY_PIRQ(PCI_DEVFN_SMBUS), ANY_PIRQ(PCI_DEVFN_GBE), /* INTERRUPT_PIN is RO/0x01 */ FIXED_INT_ANY_PIRQ(PCI_DEVFN_NPK, PCI_INT_A), }, }, }; bool is_pch_slot(unsigned int devfn) { if (PCI_SLOT(devfn) >= MIN_PCH_SLOT) return true; const struct pcie_rp_group *group; for (group = get_pcie_rp_table(); group->count; ++group) { if (PCI_SLOT(devfn) == group->slot) return true; } return false; } static const SI_PCH_DEVICE_INTERRUPT_CONFIG *pci_irq_to_fsp(size_t *out_count) { const struct pci_irq_entry *entry = get_cached_pci_irqs(); SI_PCH_DEVICE_INTERRUPT_CONFIG *config; size_t pch_total = 0; size_t cfg_count = 0; if (!entry) return NULL; /* Count PCH devices */ while (entry) { if (is_pch_slot(entry->devfn)) ++pch_total; entry = entry->next; } /* Convert PCH device entries to FSP format */ config = calloc(pch_total, sizeof(*config)); entry = get_cached_pci_irqs(); while (entry) { if (!is_pch_slot(entry->devfn)) { entry = entry->next; continue; } config[cfg_count].Device = PCI_SLOT(entry->devfn); config[cfg_count].Function = PCI_FUNC(entry->devfn); config[cfg_count].IntX = (SI_PCH_INT_PIN)entry->pin; config[cfg_count].Irq = entry->irq; ++cfg_count; entry = entry->next; } *out_count = cfg_count; return config; } /* * ME End of Post configuration * 0 - Disable EOP. * 1 - Send in PEI (Applicable for FSP in API mode) * 2 - Send in DXE (Not applicable for FSP in API mode) */ enum fsp_end_of_post { EOP_DISABLE = 0, EOP_PEI = 1, EOP_DXE = 2, }; static const pci_devfn_t i2c_dev[] = { PCI_DEVFN_I2C0, PCI_DEVFN_I2C1, PCI_DEVFN_I2C2, PCI_DEVFN_I2C3, PCI_DEVFN_I2C4, PCI_DEVFN_I2C5, }; static const pci_devfn_t gspi_dev[] = { PCI_DEVFN_GSPI0, PCI_DEVFN_GSPI1, PCI_DEVFN_GSPI2, }; static const pci_devfn_t uart_dev[] = { PCI_DEVFN_UART0, PCI_DEVFN_UART1, PCI_DEVFN_UART2 }; /* * Chip config parameter PcieRpL1Substates uses (UPD value + 1) * because UPD value of 0 for PcieRpL1Substates means disabled for FSP. * In order to ensure that mainboard setting does not disable L1 substates * incorrectly, chip config parameter values are offset by 1 with 0 meaning * use FSP UPD default. get_l1_substate_control() ensures that the right UPD * value is set in fsp_params. * 0: Use FSP UPD default * 1: Disable L1 substates * 2: Use L1.1 * 3: Use L1.2 (FSP UPD default) */ static int get_l1_substate_control(enum L1_substates_control ctl) { if (CONFIG(SOC_INTEL_COMPLIANCE_TEST_MODE)) ctl = L1_SS_DISABLED; else if ((ctl > L1_SS_L1_2) || (ctl == L1_SS_FSP_DEFAULT)) ctl = L1_SS_L1_2; return ctl - 1; } /* * Chip config parameter pcie_rp_aspm uses (UPD value + 1) because * a UPD value of 0 for pcie_rp_aspm means disabled. In order to ensure * that the mainboard setting does not disable ASPM incorrectly, chip * config parameter values are offset by 1 with 0 meaning use FSP UPD default. * get_aspm_control() ensures that the right UPD value is set in fsp_params. * 0: Use FSP UPD default * 1: Disable ASPM * 2: L0s only * 3: L1 only * 4: L0s and L1 * 5: Auto configuration */ static unsigned int get_aspm_control(enum ASPM_control ctl) { if ((ctl > ASPM_AUTO) || (ctl == ASPM_DEFAULT)) ctl = ASPM_AUTO; return ctl - 1; } __weak void mainboard_update_soc_chip_config(struct soc_intel_meteorlake_config *config) { /* Override settings per board. */ } static void fill_fsps_lpss_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { int max_port, i; max_port = get_max_i2c_port(); for (i = 0; i < max_port; i++) { s_cfg->SerialIoI2cMode[i] = is_devfn_enabled(i2c_dev[i]) ? config->serial_io_i2c_mode[i] : 0; } max_port = get_max_gspi_port(); for (i = 0; i < max_port; i++) { s_cfg->SerialIoSpiCsMode[i] = config->serial_io_gspi_cs_mode[i]; s_cfg->SerialIoSpiCsState[i] = config->serial_io_gspi_cs_state[i]; s_cfg->SerialIoSpiMode[i] = is_devfn_enabled(gspi_dev[i]) ? config->serial_io_gspi_mode[i] : 0; } max_port = get_max_uart_port(); for (i = 0; i < max_port; i++) { s_cfg->SerialIoUartMode[i] = is_devfn_enabled(uart_dev[i]) ? config->serial_io_uart_mode[i] : 0; } } static void fill_fsps_microcode_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { const struct microcode *microcode_file; size_t microcode_len; /* Locate microcode and pass to FSP-S for 2nd microcode loading */ microcode_file = intel_microcode_find(); if (microcode_file != NULL) { microcode_len = get_microcode_size(microcode_file); if (microcode_len != 0) { /* Update CPU Microcode patch base address/size */ s_cfg->MicrocodeRegionBase = (uint32_t)(uintptr_t)microcode_file; s_cfg->MicrocodeRegionSize = (uint32_t)microcode_len; } } } static void fill_fsps_cpu_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { /* * FIXME: FSP assumes ownership of the APs (Application Processors) * upon passing `NULL` pointer to the CpuMpPpi FSP-S UPD. * Hence, pass a valid pointer to the CpuMpPpi UPD unconditionally. * This would avoid APs from getting hijacked by FSP while coreboot * decides to set SkipMpInit UPD. */ s_cfg->CpuMpPpi = (uintptr_t)mp_fill_ppi_services_data(); /* * Fill `2nd microcode loading FSP UPD` if FSP is running CPU feature * programming. */ if (CONFIG(USE_FSP_FEATURE_PROGRAM_ON_APS)) fill_fsps_microcode_params(s_cfg, config); } static void fill_fsps_igd_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { /* Load VBT before devicetree-specific config. */ s_cfg->GraphicsConfigPtr = (uintptr_t)vbt_get(); /* Check if IGD is present and fill Graphics init param accordingly */ s_cfg->PeiGraphicsPeimInit = CONFIG(RUN_FSP_GOP) && is_devfn_enabled(PCI_DEVFN_IGD); s_cfg->LidStatus = CONFIG(VBOOT_LID_SWITCH) ? get_lid_switch() : CONFIG(RUN_FSP_GOP); s_cfg->PavpEnable = CONFIG(PAVP); } static void fill_fsps_tcss_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { const struct device *tcss_port_arr[] = { DEV_PTR(tcss_usb3_port0), DEV_PTR(tcss_usb3_port1), DEV_PTR(tcss_usb3_port2), DEV_PTR(tcss_usb3_port3), }; s_cfg->TcssAuxOri = config->tcss_aux_ori; /* Explicitly clear this field to avoid using defaults */ memset(s_cfg->IomTypeCPortPadCfg, 0, sizeof(s_cfg->IomTypeCPortPadCfg)); /* D3Hot and D3Cold for TCSS */ s_cfg->D3HotEnable = !config->tcss_d3_hot_disable; s_cfg->D3ColdEnable = CONFIG(D3COLD_SUPPORT); s_cfg->UsbTcPortEn = 0; for (int i = 0; i < MAX_TYPE_C_PORTS; i++) { if (is_dev_enabled(tcss_port_arr[i])) s_cfg->UsbTcPortEn |= BIT(i); } } static void fill_fsps_chipset_lockdown_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { /* Chipset Lockdown */ const bool lockdown_by_fsp = get_lockdown_config() == CHIPSET_LOCKDOWN_FSP; s_cfg->PchLockDownGlobalSmi = lockdown_by_fsp; s_cfg->PchLockDownBiosInterface = lockdown_by_fsp; s_cfg->PchUnlockGpioPads = !lockdown_by_fsp; s_cfg->RtcMemoryLock = lockdown_by_fsp; s_cfg->SkipPamLock = !lockdown_by_fsp; /* coreboot will send EOP before loading payload */ s_cfg->EndOfPostMessage = EOP_DISABLE; } static void fill_fsps_xhci_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { int i, max_port; max_port = get_max_usb20_port(); for (i = 0; i < max_port; i++) { s_cfg->PortUsb20Enable[i] = config->usb2_ports[i].enable; s_cfg->Usb2PhyPetxiset[i] = config->usb2_ports[i].pre_emp_bias; s_cfg->Usb2PhyTxiset[i] = config->usb2_ports[i].tx_bias; s_cfg->Usb2PhyPredeemp[i] = config->usb2_ports[i].tx_emp_enable; s_cfg->Usb2PhyPehalfbit[i] = config->usb2_ports[i].pre_emp_bit; if (config->usb2_ports[i].enable) s_cfg->Usb2OverCurrentPin[i] = config->usb2_ports[i].ocpin; else s_cfg->Usb2OverCurrentPin[i] = OC_SKIP; s_cfg->PortResetMessageEnable[i] = config->usb2_ports[i].type_c; } max_port = get_max_usb30_port(); for (i = 0; i < max_port; i++) { s_cfg->PortUsb30Enable[i] = config->usb3_ports[i].enable; if (config->usb3_ports[i].enable) s_cfg->Usb3OverCurrentPin[i] = config->usb3_ports[i].ocpin; else s_cfg->Usb3OverCurrentPin[i] = OC_SKIP; if (config->usb3_ports[i].tx_de_emp) { s_cfg->Usb3HsioTxDeEmphEnable[i] = 1; s_cfg->Usb3HsioTxDeEmph[i] = config->usb3_ports[i].tx_de_emp; } if (config->usb3_ports[i].tx_downscale_amp) { s_cfg->Usb3HsioTxDownscaleAmpEnable[i] = 1; s_cfg->Usb3HsioTxDownscaleAmp[i] = config->usb3_ports[i].tx_downscale_amp; } } max_port = get_max_tcss_port(); for (i = 0; i < max_port; i++) { if (config->tcss_ports[i].enable) s_cfg->CpuUsb3OverCurrentPin[i] = config->tcss_ports[i].ocpin; } } static void fill_fsps_xdci_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { s_cfg->XdciEnable = xdci_can_enable(PCI_DEVFN_USBOTG); } static void fill_fsps_uart_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { ASSERT(ARRAY_SIZE(s_cfg->SerialIoUartAutoFlow) > CONFIG_UART_FOR_CONSOLE); s_cfg->SerialIoUartAutoFlow[CONFIG_UART_FOR_CONSOLE] = 0; } static void fill_fsps_sata_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { /* SATA */ s_cfg->SataEnable = is_devfn_enabled(PCI_DEVFN_SATA); if (s_cfg->SataEnable) { s_cfg->SataMode = config->sata_mode; s_cfg->SataSalpSupport = config->sata_salp_support; memcpy(s_cfg->SataPortsEnable, config->sata_ports_enable, sizeof(s_cfg->SataPortsEnable)); memcpy(s_cfg->SataPortsDevSlp, config->sata_ports_dev_slp, sizeof(s_cfg->SataPortsDevSlp)); } /* * Power Optimizer for SATA. * SataPwrOptimizeDisable is default to 0. * Boards not needing the optimizers explicitly disables them by setting * these disable variables to 1 in devicetree overrides. */ s_cfg->SataPwrOptEnable = !(config->sata_pwr_optimize_disable); /* * Enable DEVSLP Idle Timeout settings DmVal and DitoVal. * SataPortsDmVal is the DITO multiplier. Default is 15. * SataPortsDitoVal is the DEVSLP Idle Timeout (DITO), Default is 625ms. * The default values can be changed from devicetree. */ for (size_t i = 0; i < ARRAY_SIZE(config->sata_ports_enable_dito_config); i++) { if (config->sata_ports_enable_dito_config[i]) { s_cfg->SataPortsDmVal[i] = config->sata_ports_dm_val[i]; s_cfg->SataPortsDitoVal[i] = config->sata_ports_dito_val[i]; } } } static void fill_fsps_thermal_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { /* Enable TCPU for processor thermal control */ s_cfg->Device4Enable = is_devfn_enabled(PCI_DEVFN_DPTF); /* Set TccActivationOffset */ s_cfg->TccActivationOffset = config->tcc_offset; } static void fill_fsps_lan_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { /* LAN */ s_cfg->PchLanEnable = is_devfn_enabled(PCI_DEVFN_GBE); } static void fill_fsps_cnvi_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { /* CNVi */ s_cfg->CnviMode = is_devfn_enabled(PCI_DEVFN_CNVI_WIFI); s_cfg->CnviWifiCore = config->cnvi_wifi_core; s_cfg->CnviBtCore = config->cnvi_bt_core; s_cfg->CnviBtAudioOffload = config->cnvi_bt_audio_offload; if (!s_cfg->CnviMode && s_cfg->CnviWifiCore) { printk(BIOS_ERR, "CNVi WiFi is enabled without CNVi being enabled\n"); s_cfg->CnviWifiCore = 0; } if (!s_cfg->CnviBtCore && s_cfg->CnviBtAudioOffload) { printk(BIOS_ERR, "BT offload is enabled without CNVi BT being enabled\n"); s_cfg->CnviBtAudioOffload = 0; } if (!s_cfg->CnviMode && s_cfg->CnviBtCore) { printk(BIOS_ERR, "CNVi BT is enabled without CNVi being enabled\n"); s_cfg->CnviBtCore = 0; s_cfg->CnviBtAudioOffload = 0; } } static void fill_fsps_vmd_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { /* VMD */ s_cfg->VmdEnable = is_devfn_enabled(PCI_DEVFN_VMD); } static void fill_fsps_tbt_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { for (int i = 0; i < ARRAY_SIZE(s_cfg->ITbtPcieRootPortEn); i++) s_cfg->ITbtPcieRootPortEn[i] = is_devfn_enabled(PCI_DEVFN_TBT(i)); } static void fill_fsps_8254_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { /* Legacy 8254 timer support */ bool use_8254 = get_uint_option("legacy_8254_timer", CONFIG(USE_LEGACY_8254_TIMER)); s_cfg->Enable8254ClockGating = !use_8254; s_cfg->Enable8254ClockGatingOnS3 = !use_8254; } static void fill_fsps_pm_timer_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { /* * Legacy PM ACPI Timer (and TCO Timer) * This *must* be 1 in any case to keep FSP from * 1) enabling PM ACPI Timer emulation in uCode. * 2) disabling the PM ACPI Timer. * We handle both by ourself! */ s_cfg->EnableTcoTimer = 1; } static void fill_fsps_pcie_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { int max_port = get_max_pcie_port(); uint32_t enable_mask = pcie_rp_enable_mask(get_pcie_rp_table()); for (int i = 0; i < max_port; i++) { if (!(enable_mask & BIT(i))) continue; const struct pcie_rp_config *rp_cfg = &config->pcie_rp[i]; s_cfg->PcieRpL1Substates[i] = get_l1_substate_control(rp_cfg->PcieRpL1Substates); s_cfg->PcieRpLtrEnable[i] = !!(rp_cfg->flags & PCIE_RP_LTR); s_cfg->PcieRpAdvancedErrorReporting[i] = !!(rp_cfg->flags & PCIE_RP_AER); s_cfg->PcieRpHotPlug[i] = !!(rp_cfg->flags & PCIE_RP_HOTPLUG) || CONFIG(SOC_INTEL_COMPLIANCE_TEST_MODE); s_cfg->PcieRpClkReqDetect[i] = !!(rp_cfg->flags & PCIE_RP_CLK_REQ_DETECT); if (rp_cfg->pcie_rp_aspm) s_cfg->PcieRpAspm[i] = get_aspm_control(rp_cfg->pcie_rp_aspm); } s_cfg->PcieComplianceTestMode = CONFIG(SOC_INTEL_COMPLIANCE_TEST_MODE); } static void fill_fsps_misc_power_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { /* Skip setting D0I3 bit for all HECI devices */ s_cfg->DisableD0I3SettingForHeci = 1; s_cfg->Hwp = 1; s_cfg->Cx = 1; s_cfg->PsOnEnable = 1; s_cfg->PkgCStateLimit = LIMIT_AUTO; /* Enable the energy efficient turbo mode */ s_cfg->EnergyEfficientTurbo = 1; s_cfg->PmcLpmS0ixSubStateEnableMask = get_supported_lpm_mask(); /* Un-Demotion from Demoted C1 need to be disable when * C1 auto demotion is disabled */ s_cfg->C1StateUnDemotion = !config->disable_c1_state_auto_demotion; s_cfg->C1StateAutoDemotion = !config->disable_c1_state_auto_demotion; s_cfg->PkgCStateDemotion = !config->disable_package_c_state_demotion; s_cfg->PkgCStateUnDemotion = !config->disable_package_c_state_demotion; s_cfg->PmcV1p05PhyExtFetControlEn = 1; /* Enable PCH to CPU energy report feature. */ s_cfg->PchPmDisableEnergyReport = !config->pch_pm_energy_report_enable; } static void fill_fsps_ufs_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { s_cfg->UfsEnable[0] = is_devfn_enabled(PCI_DEVFN_UFS); } static void fill_fsps_ai_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { s_cfg->GnaEnable = is_devfn_enabled(PCI_DEVFN_GNA); s_cfg->VpuEnable = is_devfn_enabled(PCI_DEVFN_VPU); } static void fill_fsps_irq_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { if (!assign_pci_irqs(irq_constraints, ARRAY_SIZE(irq_constraints))) die("ERROR: Unable to assign PCI IRQs, and no _PRT table available\n"); size_t pch_count = 0; const SI_PCH_DEVICE_INTERRUPT_CONFIG *upd_irqs = pci_irq_to_fsp(&pch_count); s_cfg->DevIntConfigPtr = (UINT32)((uintptr_t)upd_irqs); s_cfg->NumOfDevIntConfig = pch_count; printk(BIOS_INFO, "IRQ: Using dynamically assigned PCI IO-APIC IRQs\n"); } static void arch_silicon_init_params(FSPS_ARCHx_UPD *s_arch_cfg) { #if !CONFIG(PLATFORM_USES_FSP2_4) /* * EnableMultiPhaseSiliconInit for running MultiPhaseSiInit */ s_arch_cfg->EnableMultiPhaseSiliconInit = 1; #endif /* Assign FspEventHandler arch Upd to use coreboot debug event handler */ if (CONFIG(FSP_USES_CB_DEBUG_EVENT_HANDLER) && CONFIG(CONSOLE_SERIAL) && CONFIG(FSP_ENABLE_SERIAL_DEBUG)) #if CONFIG(PLATFORM_USES_FSP2_X86_32) s_arch_cfg->FspEventHandler = (FSP_EVENT_HANDLER) fsp_debug_event_handler; #else s_arch_cfg->FspEventHandler = (EFI_PHYSICAL_ADDRESS) fsp_debug_event_handler; #endif } static void evaluate_ssid(const struct device *dev, uint16_t *svid, uint16_t *ssid) { if (!(dev && svid && ssid)) return; *svid = CONFIG_SUBSYSTEM_VENDOR_ID ? : (dev->subsystem_vendor ? : 0x8086); *ssid = CONFIG_SUBSYSTEM_DEVICE_ID ? : (dev->subsystem_device ? : 0xfffe); } /* * Programming SSID before FSP-S is important because SSID registers of a few PCIE * devices (e.g. IPU, Crashlog, XHCI, TCSS_XHCI etc.) are locked after FSP-S hence * provide a custom SSID (same as DID by default) value via UPD. */ static void fill_fsps_pci_ssid_params(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) { struct svid_ssid_init_entry { union { struct { uint64_t reg:12; uint64_t function:3; uint64_t device:5; uint64_t bus:8; uint64_t ignore1:4; uint64_t segment:16; uint64_t ignore2:16; }; uint64_t data; }; struct { uint16_t svid; uint16_t ssid; }; uint32_t ignore3; }; static struct svid_ssid_init_entry ssid_table[MAX_ONBOARD_PCIE_DEVICES]; const struct device *dev; int i = 0; for (dev = all_devices; dev; dev = dev->next) { if (!(is_dev_enabled(dev) && dev->path.type == DEVICE_PATH_PCI && dev->upstream->secondary == 0)) continue; if (dev->path.pci.devfn == PCI_DEVFN_ROOT) { evaluate_ssid(dev, &s_cfg->SiCustomizedSvid, &s_cfg->SiCustomizedSsid); } else { ssid_table[i].reg = PCI_SUBSYSTEM_VENDOR_ID; ssid_table[i].device = PCI_SLOT(dev->path.pci.devfn); ssid_table[i].function = PCI_FUNC(dev->path.pci.devfn); evaluate_ssid(dev, &ssid_table[i].svid, &ssid_table[i].ssid); i++; } } s_cfg->SiSsidTablePtr = (uintptr_t)ssid_table; s_cfg->SiNumberOfSsidTableEntry = i; /* Ensure FSP will program the registers */ s_cfg->SiSkipSsidProgramming = 0; } static void soc_silicon_init_params(FSP_S_CONFIG *s_cfg, struct soc_intel_meteorlake_config *config) { /* Override settings per board if required. */ mainboard_update_soc_chip_config(config); void (*fill_fsps_params[])(FSP_S_CONFIG *s_cfg, const struct soc_intel_meteorlake_config *config) = { fill_fsps_lpss_params, fill_fsps_cpu_params, fill_fsps_igd_params, fill_fsps_tcss_params, fill_fsps_chipset_lockdown_params, fill_fsps_xhci_params, fill_fsps_xdci_params, fill_fsps_uart_params, fill_fsps_sata_params, fill_fsps_thermal_params, fill_fsps_lan_params, fill_fsps_cnvi_params, fill_fsps_vmd_params, fill_fsps_tbt_params, fill_fsps_8254_params, fill_fsps_pm_timer_params, fill_fsps_pcie_params, fill_fsps_misc_power_params, fill_fsps_ufs_params, fill_fsps_ai_params, fill_fsps_irq_params, fill_fsps_pci_ssid_params, }; for (size_t i = 0; i < ARRAY_SIZE(fill_fsps_params); i++) fill_fsps_params[i](s_cfg, config); } /* UPD parameters to be initialized before SiliconInit */ void platform_fsp_silicon_init_params_cb(FSPS_UPD *supd) { struct soc_intel_meteorlake_config *config; FSP_S_CONFIG *s_cfg = &supd->FspsConfig; FSPS_ARCHx_UPD *s_arch_cfg = &supd->FspsArchUpd; config = config_of_soc(); arch_silicon_init_params(s_arch_cfg); soc_silicon_init_params(s_cfg, config); mainboard_silicon_init_params(s_cfg); } /* * Callbacks for SoC/Mainboard specific overrides for FspMultiPhaseSiInit * This platform supports below MultiPhaseSIInit Phase(s): * Phase | FSP return point | Purpose * ------- + ------------------------------------------------ + ------------------------------- * 1 | After TCSS initialization completed | for TCSS specific init * 2 | Before BIOS Reset CPL is set by FSP-S | for CPU specific init */ void platform_fsp_silicon_multi_phase_init_cb(uint32_t phase_index) { switch (phase_index) { case 1: /* TCSS specific initialization here */ printk(BIOS_DEBUG, "FSP MultiPhaseSiInit %s/%s called\n", __FILE__, __func__); if (CONFIG(SOC_INTEL_COMMON_BLOCK_TCSS)) { const config_t *config = config_of_soc(); tcss_configure(config->typec_aux_bias_pads); } break; case 2: /* CPU specific initialization here */ printk(BIOS_DEBUG, "FSP MultiPhaseSiInit %s/%s called\n", __FILE__, __func__); before_post_cpus_init(); /* Enable BIOS Reset CPL */ enable_bios_reset_cpl(); break; default: break; } } /* Mainboard GPIO Configuration */ __weak void mainboard_silicon_init_params(FSP_S_CONFIG *s_cfg) { printk(BIOS_DEBUG, "WEAK: %s/%s called\n", __FILE__, __func__); } /* Handle FSP logo params */ void soc_load_logo(FSPS_UPD *supd) { fsp_convert_bmp_to_gop_blt(&supd->FspsConfig.LogoPtr, &supd->FspsConfig.LogoSize, &supd->FspsConfig.BltBufferAddress, &supd->FspsConfig.BltBufferSize, &supd->FspsConfig.LogoPixelHeight, &supd->FspsConfig.LogoPixelWidth); }