/* SPDX-License-Identifier: GPL-2.0-only */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "chip.h" static const struct pcie_rp_group pch_lp_rp_groups[] = { { .slot = PCH_DEV_SLOT_PCIE, .count = 8 }, { .slot = PCH_DEV_SLOT_PCIE_1, .count = 8 }, { 0 } }; static const struct pcie_rp_group pch_h_rp_groups[] = { { .slot = PCH_DEV_SLOT_PCIE, .count = 8 }, { .slot = PCH_DEV_SLOT_PCIE_1, .count = 8 }, { .slot = PCH_DEV_SLOT_PCIE_2, .count = 8 }, { 0 } }; #if CONFIG(HAVE_ACPI_TABLES) const char *soc_acpi_name(const struct device *dev) { if (dev->path.type == DEVICE_PATH_DOMAIN) return "PCI0"; if (dev->path.type == DEVICE_PATH_USB) { switch (dev->path.usb.port_type) { case 0: /* Root Hub */ return "RHUB"; case 2: /* USB2 ports */ switch (dev->path.usb.port_id) { case 0: return "HS01"; case 1: return "HS02"; case 2: return "HS03"; case 3: return "HS04"; case 4: return "HS05"; case 5: return "HS06"; case 6: return "HS07"; case 7: return "HS08"; case 8: return "HS09"; case 9: return "HS10"; case 10: return "HS11"; case 11: return "HS12"; } break; case 3: /* USB3 ports */ switch (dev->path.usb.port_id) { case 0: return "SS01"; case 1: return "SS02"; case 2: return "SS03"; case 3: return "SS04"; case 4: return "SS05"; case 5: return "SS06"; } break; } return NULL; } if (dev->path.type != DEVICE_PATH_PCI) return NULL; switch (dev->path.pci.devfn) { case SA_DEVFN_ROOT: return "MCHC"; case SA_DEVFN_IGD: return "GFX0"; case PCH_DEVFN_ISH: return "ISHB"; case PCH_DEVFN_XHCI: return "XHCI"; case PCH_DEVFN_USBOTG: return "XDCI"; case PCH_DEVFN_THERMAL: return "THRM"; case PCH_DEVFN_I2C0: return "I2C0"; case PCH_DEVFN_I2C1: return "I2C1"; case PCH_DEVFN_I2C2: return "I2C2"; case PCH_DEVFN_I2C3: return "I2C3"; case PCH_DEVFN_CSE: return "CSE1"; case PCH_DEVFN_CSE_2: return "CSE2"; case PCH_DEVFN_CSE_IDER: return "CSED"; case PCH_DEVFN_CSE_KT: return "CSKT"; case PCH_DEVFN_CSE_3: return "CSE3"; case PCH_DEVFN_SATA: return "SATA"; case PCH_DEVFN_UART2: return "UAR2"; case PCH_DEVFN_I2C4: return "I2C4"; case PCH_DEVFN_I2C5: return "I2C5"; case PCH_DEVFN_PCIE1: return "RP01"; case PCH_DEVFN_PCIE2: return "RP02"; case PCH_DEVFN_PCIE3: return "RP03"; case PCH_DEVFN_PCIE4: return "RP04"; case PCH_DEVFN_PCIE5: return "RP05"; case PCH_DEVFN_PCIE6: return "RP06"; case PCH_DEVFN_PCIE7: return "RP07"; case PCH_DEVFN_PCIE8: return "RP08"; case PCH_DEVFN_PCIE9: return "RP09"; case PCH_DEVFN_PCIE10: return "RP10"; case PCH_DEVFN_PCIE11: return "RP11"; case PCH_DEVFN_PCIE12: return "RP12"; case PCH_DEVFN_PCIE13: return "RP13"; case PCH_DEVFN_PCIE14: return "RP14"; case PCH_DEVFN_PCIE15: return "RP15"; case PCH_DEVFN_PCIE16: return "RP16"; case PCH_DEVFN_PCIE17: return "RP17"; case PCH_DEVFN_PCIE18: return "RP18"; case PCH_DEVFN_PCIE19: return "RP19"; case PCH_DEVFN_PCIE20: return "RP20"; case PCH_DEVFN_PCIE21: return "RP21"; case PCH_DEVFN_PCIE22: return "RP22"; case PCH_DEVFN_PCIE23: return "RP23"; case PCH_DEVFN_PCIE24: return "RP24"; case PCH_DEVFN_UART0: return "UAR0"; case PCH_DEVFN_UART1: return "UAR1"; case PCH_DEVFN_GSPI0: return "SPI0"; case PCH_DEVFN_GSPI1: return "SPI1"; case PCH_DEVFN_GSPI2: return "SPI2"; case PCH_DEVFN_EMMC: return "EMMC"; case PCH_DEVFN_SDCARD: return "SDXC"; case PCH_DEVFN_P2SB: return "P2SB"; case PCH_DEVFN_PMC: return "PMC_"; case PCH_DEVFN_HDA: return "HDAS"; case PCH_DEVFN_SMBUS: return "SBUS"; case PCH_DEVFN_SPI: return "FSPI"; case PCH_DEVFN_GBE: return "IGBE"; case PCH_DEVFN_TRACEHUB:return "THUB"; } return NULL; } #endif void soc_init_pre_device(void *chip_info) { /* Perform silicon specific init. */ fsp_silicon_init(); /* Display FIRMWARE_VERSION_INFO_HOB */ fsp_display_fvi_version_hob(); soc_gpio_pm_configuration(); /* swap enabled PCI ports in device tree if needed */ if (CONFIG(SOC_INTEL_CANNONLAKE_PCH_H)) pcie_rp_update_devicetree(pch_h_rp_groups); else pcie_rp_update_devicetree(pch_lp_rp_groups); } static void cpu_fill_ssdt(const struct device *dev) { generate_cpu_entries(dev); if (!generate_pin_irq_map()) printk(BIOS_ERR, "Failed to generate ACPI _PRT table!\n"); } static void cpu_set_north_irqs(struct device *dev) { irq_program_non_pch(); } static struct device_operations pci_domain_ops = { .read_resources = &pci_domain_read_resources, .set_resources = &pci_domain_set_resources, .scan_bus = &pci_domain_scan_bus, #if CONFIG(HAVE_ACPI_TABLES) .acpi_name = &soc_acpi_name, #endif }; static struct device_operations cpu_bus_ops = { .read_resources = noop_read_resources, .set_resources = noop_set_resources, .enable_resources = cpu_set_north_irqs, #if CONFIG(HAVE_ACPI_TABLES) .acpi_fill_ssdt = cpu_fill_ssdt, #endif }; static void soc_enable(struct device *dev) { /* Set the operations if it is a special bus type */ if (dev->path.type == DEVICE_PATH_DOMAIN) dev->ops = &pci_domain_ops; else if (dev->path.type == DEVICE_PATH_CPU_CLUSTER) dev->ops = &cpu_bus_ops; else if (dev->path.type == DEVICE_PATH_GPIO) block_gpio_enable(dev); else if (dev->path.type == DEVICE_PATH_PCI && dev->path.pci.devfn == PCH_DEVFN_PMC) dev->ops = &pmc_ops; } struct chip_operations soc_intel_cannonlake_ops = { CHIP_NAME("Intel Cannonlake") .enable_dev = &soc_enable, .init = &soc_init_pre_device, };