/* 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 /* * Table of devices that need their AOAC registers enabled and waited * upon (usually about .55 milliseconds). Instead of individual delays * waiting for each device to become available, a single delay will be * executed. */ static const unsigned int aoac_devs[] = { FCH_AOAC_DEV_UART0 + CONFIG_UART_FOR_CONSOLE * 2, FCH_AOAC_DEV_AMBA, FCH_AOAC_DEV_I2C0, FCH_AOAC_DEV_I2C1, FCH_AOAC_DEV_I2C2, FCH_AOAC_DEV_I2C3, }; static int is_sata_config(void) { return !((SataNativeIde == CONFIG_STONEYRIDGE_SATA_MODE) || (SataLegacyIde == CONFIG_STONEYRIDGE_SATA_MODE)); } static inline int sb_sata_enable(void) { /* True if IDE or AHCI. */ return (SataNativeIde == CONFIG_STONEYRIDGE_SATA_MODE) || (SataAhci == CONFIG_STONEYRIDGE_SATA_MODE); } static inline int sb_ide_enable(void) { /* True if IDE or LEGACY IDE. */ return (SataNativeIde == CONFIG_STONEYRIDGE_SATA_MODE) || (SataLegacyIde == CONFIG_STONEYRIDGE_SATA_MODE); } void SetFchResetParams(FCH_RESET_INTERFACE *params) { const struct device *dev = pcidev_path_on_root(SATA_DEVFN); params->Xhci0Enable = CONFIG(STONEYRIDGE_XHCI_ENABLE); if (dev && dev->enabled) { params->SataEnable = sb_sata_enable(); params->IdeEnable = sb_ide_enable(); } else { params->SataEnable = FALSE; params->IdeEnable = FALSE; } } void SetFchEnvParams(FCH_INTERFACE *params) { const struct device *dev = pcidev_path_on_root(SATA_DEVFN); params->AzaliaController = AzEnable; params->SataClass = CONFIG_STONEYRIDGE_SATA_MODE; if (dev && dev->enabled) { params->SataEnable = is_sata_config(); params->IdeEnable = !params->SataEnable; params->SataIdeMode = (CONFIG_STONEYRIDGE_SATA_MODE == SataLegacyIde); } else { params->SataEnable = FALSE; params->IdeEnable = FALSE; params->SataIdeMode = FALSE; } } void SetFchMidParams(FCH_INTERFACE *params) { SetFchEnvParams(params); } /* * Table of APIC register index and associated IRQ name. Using IDX_XXX_NAME * provides a visible association with the index, therefore helping * maintainability of table. If a new index/name is defined in * amd_pci_int_defs.h, just add the pair at the end of this table. * Order is not important. */ static const struct irq_idx_name irq_association[] = { { PIRQ_A, "INTA#" }, { PIRQ_B, "INTB#" }, { PIRQ_C, "INTC#" }, { PIRQ_D, "INTD#" }, { PIRQ_E, "INTE#" }, { PIRQ_F, "INTF#" }, { PIRQ_G, "INTG#" }, { PIRQ_H, "INTH#" }, { PIRQ_MISC, "Misc" }, { PIRQ_MISC0, "Misc0" }, { PIRQ_MISC1, "Misc1" }, { PIRQ_MISC2, "Misc2" }, { PIRQ_SIRQA, "Ser IRQ INTA" }, { PIRQ_SIRQB, "Ser IRQ INTB" }, { PIRQ_SIRQC, "Ser IRQ INTC" }, { PIRQ_SIRQD, "Ser IRQ INTD" }, { PIRQ_SCI, "SCI" }, { PIRQ_SMBUS, "SMBUS" }, { PIRQ_ASF, "ASF" }, { PIRQ_HDA, "HDA" }, { PIRQ_FC, "FC" }, { PIRQ_PMON, "PerMon" }, { PIRQ_SD, "SD" }, { PIRQ_SDIO, "SDIOt" }, { PIRQ_EHCI, "EHCI" }, { PIRQ_XHCI, "XHCI" }, { PIRQ_SATA, "SATA" }, { PIRQ_GPIO, "GPIO" }, { PIRQ_I2C0, "I2C0" }, { PIRQ_I2C1, "I2C1" }, { PIRQ_I2C2, "I2C2" }, { PIRQ_I2C3, "I2C3" }, { PIRQ_UART0, "UART0" }, { PIRQ_UART1, "UART1" }, }; const struct irq_idx_name *sb_get_apic_reg_association(size_t *size) { *size = ARRAY_SIZE(irq_association); return irq_association; } void enable_aoac_devices(void) { bool status; int i; for (i = 0; i < ARRAY_SIZE(aoac_devs); i++) power_on_aoac_device(aoac_devs[i]); /* Wait for AOAC devices to indicate power and clock OK */ do { udelay(100); status = true; for (i = 0; i < ARRAY_SIZE(aoac_devs); i++) status &= is_aoac_device_enabled(aoac_devs[i]); } while (!status); } static void sb_enable_lpc(void) { u8 byte; /* Enable LPC controller */ byte = pm_io_read8(PM_LPC_GATING); byte |= PM_LPC_ENABLE; pm_io_write8(PM_LPC_GATING, byte); } static void sb_lpc_decode(void) { u32 tmp = 0; /* Enable I/O decode to LPC bus */ tmp = DECODE_ENABLE_PARALLEL_PORT0 | DECODE_ENABLE_PARALLEL_PORT2 | DECODE_ENABLE_PARALLEL_PORT4 | DECODE_ENABLE_SERIAL_PORT0 | DECODE_ENABLE_SERIAL_PORT1 | DECODE_ENABLE_SERIAL_PORT2 | DECODE_ENABLE_SERIAL_PORT3 | DECODE_ENABLE_SERIAL_PORT4 | DECODE_ENABLE_SERIAL_PORT5 | DECODE_ENABLE_SERIAL_PORT6 | DECODE_ENABLE_SERIAL_PORT7 | DECODE_ENABLE_AUDIO_PORT0 | DECODE_ENABLE_AUDIO_PORT1 | DECODE_ENABLE_AUDIO_PORT2 | DECODE_ENABLE_AUDIO_PORT3 | DECODE_ENABLE_MSS_PORT2 | DECODE_ENABLE_MSS_PORT3 | DECODE_ENABLE_FDC_PORT0 | DECODE_ENABLE_FDC_PORT1 | DECODE_ENABLE_GAME_PORT | DECODE_ENABLE_KBC_PORT | DECODE_ENABLE_ACPIUC_PORT | DECODE_ENABLE_ADLIB_PORT; /* Decode SIOs at 2E/2F and 4E/4F */ if (CONFIG(STONEYRIDGE_LEGACY_FREE)) tmp |= DECODE_ALTERNATE_SIO_ENABLE | DECODE_SIO_ENABLE; lpc_enable_decode(tmp); } void fch_clk_output_48Mhz(u32 osc) { u32 ctrl; /* * Clear the disable for OSCOUT1 (signal typically named XnnM_25M_48M) * or OSCOUT2 (USBCLK/25M_48M_OSC). The frequency defaults to 48MHz. */ ctrl = misc_read32(MISC_CLK_CNTL1); switch (osc) { case 1: ctrl &= ~OSCOUT1_CLK_OUTPUT_ENB; break; case 2: ctrl &= ~OSCOUT2_CLK_OUTPUT_ENB; break; default: return; /* do nothing if invalid */ } misc_write32(MISC_CLK_CNTL1, ctrl); } static void sb_init_spi_base(void) { /* Make sure the base address is predictable */ if (ENV_X86) lpc_set_spibase(SPI_BASE_ADDRESS); lpc_enable_spi_rom(SPI_ROM_ENABLE); } void sb_set_spi100(u16 norm, u16 fast, u16 alt, u16 tpm) { spi_write16(SPI100_SPEED_CONFIG, (norm << SPI_NORM_SPEED_NEW_SH) | (fast << SPI_FAST_SPEED_NEW_SH) | (alt << SPI_ALT_SPEED_NEW_SH) | (tpm << SPI_TPM_SPEED_NEW_SH)); spi_write16(SPI100_ENABLE, SPI_USE_SPI100); } static void sb_disable_4dw_burst(void) { spi_write16(SPI100_HOST_PREF_CONFIG, spi_read16(SPI100_HOST_PREF_CONFIG) & ~SPI_RD4DW_EN_HOST); } void sb_read_mode(u32 mode) { spi_write32(SPI_CNTRL0, (spi_read32(SPI_CNTRL0) & ~SPI_READ_MODE_MASK) | mode); } static void setup_spread_spectrum(int *reboot) { uint16_t rstcfg = pm_read16(PWR_RESET_CFG); rstcfg &= ~TOGGLE_ALL_PWR_GOOD; pm_write16(PWR_RESET_CFG, rstcfg); uint32_t cntl1 = misc_read32(MISC_CLK_CNTL1); if (cntl1 & CG1PLL_FBDIV_TEST) { printk(BIOS_DEBUG, "Spread spectrum is ready\n"); misc_write32(MISC_CGPLL_CONFIG1, misc_read32(MISC_CGPLL_CONFIG1) | CG1PLL_SPREAD_SPECTRUM_ENABLE); return; } printk(BIOS_DEBUG, "Setting up spread spectrum\n"); uint32_t cfg6 = misc_read32(MISC_CGPLL_CONFIG6); cfg6 &= ~CG1PLL_LF_MODE_MASK; cfg6 |= (0x0f8 << CG1PLL_LF_MODE_SHIFT) & CG1PLL_LF_MODE_MASK; misc_write32(MISC_CGPLL_CONFIG6, cfg6); uint32_t cfg3 = misc_read32(MISC_CGPLL_CONFIG3); cfg3 &= ~CG1PLL_REFDIV_MASK; cfg3 |= (0x003 << CG1PLL_REFDIV_SHIFT) & CG1PLL_REFDIV_MASK; cfg3 &= ~CG1PLL_FBDIV_MASK; cfg3 |= (0x04b << CG1PLL_FBDIV_SHIFT) & CG1PLL_FBDIV_MASK; misc_write32(MISC_CGPLL_CONFIG3, cfg3); uint32_t cfg5 = misc_read32(MISC_CGPLL_CONFIG5); cfg5 &= ~SS_AMOUNT_NFRAC_SLIP_MASK; cfg5 |= (0x2 << SS_AMOUNT_NFRAC_SLIP_SHIFT) & SS_AMOUNT_NFRAC_SLIP_MASK; misc_write32(MISC_CGPLL_CONFIG5, cfg5); uint32_t cfg4 = misc_read32(MISC_CGPLL_CONFIG4); cfg4 &= ~SS_AMOUNT_DSFRAC_MASK; cfg4 |= (0xd000 << SS_AMOUNT_DSFRAC_SHIFT) & SS_AMOUNT_DSFRAC_MASK; cfg4 &= ~SS_STEP_SIZE_DSFRAC_MASK; cfg4 |= (0x02d5 << SS_STEP_SIZE_DSFRAC_SHIFT) & SS_STEP_SIZE_DSFRAC_MASK; misc_write32(MISC_CGPLL_CONFIG4, cfg4); rstcfg |= TOGGLE_ALL_PWR_GOOD; pm_write16(PWR_RESET_CFG, rstcfg); cntl1 |= CG1PLL_FBDIV_TEST; misc_write32(MISC_CLK_CNTL1, cntl1); *reboot = 1; } static void setup_misc(int *reboot) { /* Undocumented register */ uint32_t reg = misc_read32(0x50); if (!(reg & BIT(16))) { reg |= BIT(16); misc_write32(0x50, reg); *reboot = 1; } } /* Before console init */ void bootblock_fch_early_init(void) { int reboot = 0; lpc_enable_rom(); sb_enable_lpc(); lpc_enable_port80(); sb_lpc_decode(); lpc_enable_spi_prefetch(); sb_init_spi_base(); sb_disable_4dw_burst(); /* Must be disabled on CZ(ST) */ enable_acpimmio_decode_pm04(); fch_smbus_init(); fch_enable_cf9_io(); setup_spread_spectrum(&reboot); setup_misc(&reboot); if (reboot) warm_reset(); fch_enable_legacy_io(); enable_aoac_devices(); /* disable the keyboard reset function before mainboard GPIO setup */ if (CONFIG(DISABLE_KEYBOARD_RESET_PIN)) fch_disable_kb_rst(); } /* After console init */ void bootblock_fch_init(void) { pm_set_power_failure_state(); fch_print_pmxc0_status(); show_spi_speeds_and_modes(); } static void fch_init_acpi_ports(void) { u32 reg; /* We use some of these ports in SMM regardless of whether or not * ACPI tables are generated. Enable these ports indiscriminately. */ pm_write16(PM_EVT_BLK, ACPI_PM_EVT_BLK); pm_write16(PM1_CNT_BLK, ACPI_PM1_CNT_BLK); pm_write16(PM_TMR_BLK, ACPI_PM_TMR_BLK); pm_write16(PM_GPE0_BLK, ACPI_GPE0_BLK); /* CpuControl is in \_SB.CP00, 6 bytes */ pm_write16(PM_CPU_CTRL, ACPI_CPU_CONTROL); if (CONFIG(HAVE_SMI_HANDLER)) { /* APMC - SMI Command Port */ pm_write16(PM_ACPI_SMI_CMD, APM_CNT); configure_smi(SMITYPE_SMI_CMD_PORT, SMI_MODE_SMI); /* SMI on SlpTyp requires sending SMI before completion * response of the I/O write. The BKDG also specifies * clearing ForceStpClkRetry for SMI trapping. */ reg = pm_read32(PM_PCI_CTRL); reg |= FORCE_SLPSTATE_RETRY; reg &= ~FORCE_STPCLK_RETRY; pm_write32(PM_PCI_CTRL, reg); /* Disable SlpTyp feature */ reg = pm_read8(PM_RST_CTRL1); reg &= ~SLPTYPE_CONTROL_EN; pm_write8(PM_RST_CTRL1, reg); configure_smi(SMITYPE_SLP_TYP, SMI_MODE_SMI); } else { pm_write16(PM_ACPI_SMI_CMD, 0); } /* Decode ACPI registers and enable standard features */ pm_write8(PM_ACPI_CONF, PM_ACPI_DECODE_STD | PM_ACPI_GLOBAL_EN | PM_ACPI_RTC_EN_EN | PM_ACPI_TIMER_EN_EN); } void fch_init(void *chip_info) { fch_init_acpi_ports(); } static void set_sb_aoac(struct aoac_devs *aoac) { const struct device *sd, *sata; aoac->ic0e = is_aoac_device_enabled(FCH_AOAC_DEV_I2C0); aoac->ic1e = is_aoac_device_enabled(FCH_AOAC_DEV_I2C1); aoac->ic2e = is_aoac_device_enabled(FCH_AOAC_DEV_I2C2); aoac->ic3e = is_aoac_device_enabled(FCH_AOAC_DEV_I2C3); aoac->ut0e = is_aoac_device_enabled(FCH_AOAC_DEV_UART0); aoac->ut1e = is_aoac_device_enabled(FCH_AOAC_DEV_UART1); aoac->ehce = is_aoac_device_enabled(FCH_AOAC_DEV_USB2); aoac->xhce = is_aoac_device_enabled(FCH_AOAC_DEV_USB3); /* Rely on these being in sync with devicetree */ sd = pcidev_path_on_root(SD_DEVFN); aoac->sd_e = sd && sd->enabled ? 1 : 0; sata = pcidev_path_on_root(SATA_DEVFN); aoac->st_e = sata && sata->enabled ? 1 : 0; aoac->espi = 1; } static void set_sb_gnvs(struct global_nvs *gnvs) { uintptr_t amdfw_rom; uintptr_t xhci_fw; uintptr_t fwaddr; size_t fwsize; amdfw_rom = 0x20000 - (0x80000 << CONFIG_AMD_FWM_POSITION_INDEX); xhci_fw = read32((void *)(amdfw_rom + XHCI_FW_SIG_OFFSET)); fwaddr = 2 + read16((void *)(xhci_fw + XHCI_FW_ADDR_OFFSET + XHCI_FW_BOOTRAM_SIZE)); fwsize = read16((void *)(xhci_fw + XHCI_FW_SIZE_OFFSET + XHCI_FW_BOOTRAM_SIZE)); gnvs->fw00 = 0; gnvs->fw01 = ((32 * KiB) << 16) + 0; gnvs->fw02 = fwaddr + XHCI_FW_BOOTRAM_SIZE; gnvs->fw03 = fwsize << 16; gnvs->eh10 = pci_read_config32(SOC_EHCI1_DEV, PCI_BASE_ADDRESS_0) & ~PCI_BASE_ADDRESS_MEM_ATTR_MASK; } void fch_final(void *chip_info) { struct global_nvs *gnvs = acpi_get_gnvs(); if (gnvs) { set_sb_aoac(&gnvs->aoac); set_sb_gnvs(gnvs); } } /* * Update the PCI devices with a valid IRQ number * that is set in the mainboard PCI_IRQ structures. */ static void set_pci_irqs(void *unused) { /* Write PCI_INTR regs 0xC00/0xC01 */ write_pci_int_table(); /* Write IRQs for all devicetree enabled devices */ write_pci_cfg_irqs(); } /* * Hook this function into the PCI state machine * on entry into BS_DEV_ENABLE. */ BOOT_STATE_INIT_ENTRY(BS_DEV_ENABLE, BS_ON_ENTRY, set_pci_irqs, NULL);