/* SPDX-License-Identifier: GPL-2.0-only */ #ifndef CPU_X86_SMM_H #define CPU_X86_SMM_H #include #include #include #include #include #define SMM_DEFAULT_BASE 0x30000 #define SMM_DEFAULT_SIZE 0x10000 /* used only by C programs so far */ #define SMM_BASE 0xa0000 #define SMM_ENTRY_OFFSET 0x8000 #define SMM_SAVE_STATE_BEGIN(x) (SMM_ENTRY_OFFSET + (x)) #define APM_CNT 0xb2 #define APM_CNT_NOOP_SMI 0x00 #define APM_CNT_ACPI_DISABLE 0x1e #define APM_CNT_ACPI_ENABLE 0xe1 #define APM_CNT_ROUTE_ALL_XHCI 0xca #define APM_CNT_FINALIZE 0xcb #define APM_CNT_LEGACY 0xcc #define APM_CNT_MBI_UPDATE 0xeb #define APM_CNT_SMMINFO 0xec #define APM_CNT_SMMSTORE 0xed #define APM_CNT_ELOG_GSMI 0xef #define APM_STS 0xb3 #define SMM_PCI_RESOURCE_STORE_NUM_RESOURCES 6 /* Send cmd to APM_CNT with HAVE_SMI_HANDLER checking. */ int apm_control(u8 cmd); u8 apm_get_apmc(void); void io_trap_handler(int smif); int mainboard_io_trap_handler(int smif); void southbridge_smi_set_eos(void); void global_smi_enable(void); void global_smi_enable_no_pwrbtn(void); void cpu_smi_handler(void); void northbridge_smi_handler(void); void southbridge_smi_handler(void); void mainboard_smi_gpi(u32 gpi_sts); int mainboard_smi_apmc(u8 data); void mainboard_smi_sleep(u8 slp_typ); void mainboard_smi_finalize(void); int mainboard_set_smm_log_level(void); void smm_soc_early_init(void); void smm_soc_exit(void); /* This is the SMM handler. */ extern unsigned char _binary_smm_start[]; extern unsigned char _binary_smm_end[]; struct smm_pci_resource_info { pci_devfn_t pci_addr; uint16_t class_device; uint8_t class_prog; struct resource resources[SMM_PCI_RESOURCE_STORE_NUM_RESOURCES]; }; struct smm_runtime { u32 smbase; u32 smm_size; u32 save_state_size; u32 num_cpus; u32 gnvs_ptr; u32 cbmemc_size; void *cbmemc; #if CONFIG(SMM_PCI_RESOURCE_STORE) struct smm_pci_resource_info pci_resources[CONFIG_SMM_PCI_RESOURCE_STORE_NUM_SLOTS]; #endif uintptr_t save_state_top[CONFIG_MAX_CPUS]; int smm_log_level; } __packed; struct smm_module_params { size_t cpu; /* A canary value that has been placed at the end of the stack. * If (uintptr_t)canary != *canary then a stack overflow has occurred. */ const uintptr_t *canary; }; /* These parameters are used by the SMM stub code. A pointer to the params * is also passed to the C-base handler. */ struct smm_stub_params { u32 stack_size; u32 stack_top; u32 c_handler; u32 fxsave_area; u32 fxsave_area_size; /* The apic_id_to_cpu provides a mapping from APIC id to CPU number. * The CPU number is indicated by the index into the array by matching * the default APIC id and value at the index. The stub loader * initializes this array with a 1:1 mapping. If the APIC ids are not * contiguous like the 1:1 mapping it is up to the caller of the stub * loader to adjust this mapping. */ u16 apic_id_to_cpu[CONFIG_MAX_CPUS]; } __packed; /* smm_handler_t is called with arg of smm_module_params pointer. */ typedef asmlinkage void (*smm_handler_t)(void *); /* SMM Runtime helpers. */ #if ENV_SMM extern struct global_nvs *gnvs; #endif /* Entry point for SMM modules. */ asmlinkage void smm_handler_start(void *params); /* Retrieve SMM save state for a given CPU. WARNING: This does not take into * account CPUs which are configured to not save their state to RAM. */ void *smm_get_save_state(int cpu); /* Returns true if the region overlaps with the SMM */ bool smm_region_overlaps_handler(const struct region *r); /* Returns true if the memory pointed to overlaps with SMM reserved memory. */ static inline bool smm_points_to_smram(const void *ptr, const size_t len) { const struct region r = {(uintptr_t)ptr, len}; return smm_region_overlaps_handler(&r); } /* SMM Module Loading API */ /* The smm_loader_params structure provides direction to the SMM loader: * - num_cpus - number of concurrent cpus in handler needing stack * optional for setting up relocation handler. * - cpu_save_state_size - the SMM save state size per cpu * - num_concurrent_save_states - number of concurrent cpus needing save state * space * - handler - optional handler to call. Only used during SMM relocation setup. * - runtime - this field is a result only. The SMM runtime location is filled * into this field so the code doing the loading can manipulate the * runtime's assumptions. e.g. updating the APIC id to CPU map to * handle sparse APIC id space. */ struct smm_loader_params { size_t num_cpus; size_t cpu_save_state_size; size_t num_concurrent_save_states; smm_handler_t handler; struct smm_stub_params *stub_params; }; /* All of these return 0 on success, < 0 on failure. */ int smm_setup_stack(const uintptr_t perm_smbase, const size_t perm_smram_size, const unsigned int total_cpus, const size_t stack_size); int smm_setup_relocation_handler(struct smm_loader_params *params); int smm_load_module(uintptr_t smram_base, size_t smram_size, struct smm_loader_params *params); u32 smm_get_cpu_smbase(unsigned int cpu_num); /* Backup and restore default SMM region. */ void *backup_default_smm_area(void); void restore_default_smm_area(void *smm_save_area); /* * Fills in the arguments for the entire SMM region covered by chipset * protections. e.g. TSEG. */ void smm_region(uintptr_t *start, size_t *size); static inline void aseg_region(uintptr_t *start, size_t *size) { *start = SMM_BASE; *size = SMM_DEFAULT_SIZE; /* SMM_CODE_SEGMENT_SIZE ? */ } enum { /* SMM handler area. */ SMM_SUBREGION_HANDLER, /* SMM cache region. */ SMM_SUBREGION_CACHE, /* Chipset specific area. */ SMM_SUBREGION_CHIPSET, /* Total sub regions supported. */ SMM_SUBREGION_NUM, }; /* Fills in the start and size for the requested SMM subregion. Returns * 0 on success, < 0 on failure. */ int smm_subregion(int sub, uintptr_t *start, size_t *size); /* Print the SMM memory layout on console. */ void smm_list_regions(void); #define SMM_REVISION_OFFSET_FROM_TOP (0x8000 - 0x7efc) /* Return the SMM save state revision. The revision can be fetched from the smm savestate which is always at the same offset downward from the top of the save state. */ uint32_t smm_revision(void); /* Returns the PM ACPI SMI port. On Intel systems this typically not configurable (APM_CNT, 0xb2). On AMD systems it is sometimes configurable. */ uint16_t pm_acpi_smi_cmd_port(void); const volatile struct smm_pci_resource_info *smm_get_pci_resource_store(void); void smm_pci_get_stored_resources(const volatile struct smm_pci_resource_info **out_slots, size_t *out_size); /* Weak handler function to store PCI BARs. */ void smm_mainboard_pci_resource_store_init(struct smm_pci_resource_info *slots, size_t size); /* Helper function to fill BARs from an array of device pointers. */ bool smm_pci_resource_store_fill_resources(struct smm_pci_resource_info *slots, size_t num_slots, const struct device **devices, size_t num_devices); void smm_pci_resource_store_init(struct smm_runtime *smm_runtime); #endif /* CPU_X86_SMM_H */