TOMOYO Linux Cross Reference
Linux/arch/powerpc/kernel/rtas.c

   // SPDX-License-Identifier: GPL-2.0-or-later
   /*
    *
    * Procedures for interfacing to the RTAS on CHRP machines.
    *
    * Peter Bergner, IBM   March 2001.
    * Copyright (C) 2001 IBM.
    */
   
  #define pr_fmt(fmt)     "rtas: " fmt
  
  #include <linux/bsearch.h>
  #include <linux/capability.h>
  #include <linux/delay.h>
  #include <linux/export.h>
  #include <linux/init.h>
  #include <linux/kconfig.h>
  #include <linux/kernel.h>
  #include <linux/lockdep.h>
  #include <linux/memblock.h>
  #include <linux/mutex.h>
  #include <linux/nospec.h>
  #include <linux/of.h>
  #include <linux/of_fdt.h>
  #include <linux/reboot.h>
  #include <linux/sched.h>
  #include <linux/security.h>
  #include <linux/slab.h>
  #include <linux/spinlock.h>
  #include <linux/stdarg.h>
  #include <linux/syscalls.h>
  #include <linux/types.h>
  #include <linux/uaccess.h>
  #include <linux/xarray.h>
  
  #include <asm/delay.h>
  #include <asm/firmware.h>
  #include <asm/interrupt.h>
  #include <asm/machdep.h>
  #include <asm/mmu.h>
  #include <asm/page.h>
  #include <asm/rtas-work-area.h>
  #include <asm/rtas.h>
  #include <asm/time.h>
  #include <asm/trace.h>
  #include <asm/udbg.h>
  
  struct rtas_filter {
          /* Indexes into the args buffer, -1 if not used */
          const int buf_idx1;
          const int size_idx1;
          const int buf_idx2;
          const int size_idx2;
          /*
           * Assumed buffer size per the spec if the function does not
           * have a size parameter, e.g. ibm,errinjct. 0 if unused.
           */
          const int fixed_size;
  };
  
  /**
   * struct rtas_function - Descriptor for RTAS functions.
   *
   * @token: Value of @name if it exists under the /rtas node.
   * @name: Function name.
   * @filter: If non-NULL, invoking this function via the rtas syscall is
   *          generally allowed, and @filter describes constraints on the
   *          arguments. See also @banned_for_syscall_on_le.
   * @banned_for_syscall_on_le: Set when call via sys_rtas is generally allowed
   *                            but specifically restricted on ppc64le. Such
   *                            functions are believed to have no users on
   *                            ppc64le, and we want to keep it that way. It does
   *                            not make sense for this to be set when @filter
   *                            is NULL.
   * @lock: Pointer to an optional dedicated per-function mutex. This
   *        should be set for functions that require multiple calls in
   *        sequence to complete a single operation, and such sequences
   *        will disrupt each other if allowed to interleave. Users of
   *        this function are required to hold the associated lock for
   *        the duration of the call sequence. Add an explanatory
   *        comment to the function table entry if setting this member.
   */
  struct rtas_function {
          s32 token;
          const bool banned_for_syscall_on_le:1;
          const char * const name;
          const struct rtas_filter *filter;
          struct mutex *lock;
  };
  
  /*
   * Per-function locks for sequence-based RTAS functions.
   */
  static DEFINE_MUTEX(rtas_ibm_activate_firmware_lock);
  static DEFINE_MUTEX(rtas_ibm_get_dynamic_sensor_state_lock);
  static DEFINE_MUTEX(rtas_ibm_get_indices_lock);
  static DEFINE_MUTEX(rtas_ibm_lpar_perftools_lock);
  static DEFINE_MUTEX(rtas_ibm_physical_attestation_lock);
  static DEFINE_MUTEX(rtas_ibm_set_dynamic_indicator_lock);
 DEFINE_MUTEX(rtas_ibm_get_vpd_lock);
 
 static struct rtas_function rtas_function_table[] __ro_after_init = {
         [RTAS_FNIDX__CHECK_EXCEPTION] = {
                 .name = "check-exception",
         },
         [RTAS_FNIDX__DISPLAY_CHARACTER] = {
                 .name = "display-character",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = -1, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__EVENT_SCAN] = {
                 .name = "event-scan",
         },
         [RTAS_FNIDX__FREEZE_TIME_BASE] = {
                 .name = "freeze-time-base",
         },
         [RTAS_FNIDX__GET_POWER_LEVEL] = {
                 .name = "get-power-level",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = -1, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__GET_SENSOR_STATE] = {
                 .name = "get-sensor-state",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = -1, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__GET_TERM_CHAR] = {
                 .name = "get-term-char",
         },
         [RTAS_FNIDX__GET_TIME_OF_DAY] = {
                 .name = "get-time-of-day",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = -1, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__IBM_ACTIVATE_FIRMWARE] = {
                 .name = "ibm,activate-firmware",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = -1, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
                 /*
                  * PAPR+ as of v2.13 doesn't explicitly impose any
                  * restriction, but this typically requires multiple
                  * calls before success, and there's no reason to
                  * allow sequences to interleave.
                  */
                 .lock = &rtas_ibm_activate_firmware_lock,
         },
         [RTAS_FNIDX__IBM_CBE_START_PTCAL] = {
                 .name = "ibm,cbe-start-ptcal",
         },
         [RTAS_FNIDX__IBM_CBE_STOP_PTCAL] = {
                 .name = "ibm,cbe-stop-ptcal",
         },
         [RTAS_FNIDX__IBM_CHANGE_MSI] = {
                 .name = "ibm,change-msi",
         },
         [RTAS_FNIDX__IBM_CLOSE_ERRINJCT] = {
                 .name = "ibm,close-errinjct",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = -1, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__IBM_CONFIGURE_BRIDGE] = {
                 .name = "ibm,configure-bridge",
         },
         [RTAS_FNIDX__IBM_CONFIGURE_CONNECTOR] = {
                 .name = "ibm,configure-connector",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = 0, .size_idx1 = -1,
                         .buf_idx2 = 1, .size_idx2 = -1,
                         .fixed_size = 4096,
                 },
         },
         [RTAS_FNIDX__IBM_CONFIGURE_KERNEL_DUMP] = {
                 .name = "ibm,configure-kernel-dump",
         },
         [RTAS_FNIDX__IBM_CONFIGURE_PE] = {
                 .name = "ibm,configure-pe",
         },
         [RTAS_FNIDX__IBM_CREATE_PE_DMA_WINDOW] = {
                 .name = "ibm,create-pe-dma-window",
         },
         [RTAS_FNIDX__IBM_DISPLAY_MESSAGE] = {
                 .name = "ibm,display-message",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = 0, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__IBM_ERRINJCT] = {
                 .name = "ibm,errinjct",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = 2, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                         .fixed_size = 1024,
                 },
         },
         [RTAS_FNIDX__IBM_EXTI2C] = {
                 .name = "ibm,exti2c",
         },
         [RTAS_FNIDX__IBM_GET_CONFIG_ADDR_INFO] = {
                 .name = "ibm,get-config-addr-info",
         },
         [RTAS_FNIDX__IBM_GET_CONFIG_ADDR_INFO2] = {
                 .name = "ibm,get-config-addr-info2",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = -1, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__IBM_GET_DYNAMIC_SENSOR_STATE] = {
                 .name = "ibm,get-dynamic-sensor-state",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = 1, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
                 /*
                  * PAPR+ v2.13 R1–7.3.19–3 is explicit that the OS
                  * must not call ibm,get-dynamic-sensor-state with
                  * different inputs until a non-retry status has been
                  * returned.
                  */
                 .lock = &rtas_ibm_get_dynamic_sensor_state_lock,
         },
         [RTAS_FNIDX__IBM_GET_INDICES] = {
                 .name = "ibm,get-indices",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = 2, .size_idx1 = 3,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
                 /*
                  * PAPR+ v2.13 R1–7.3.17–2 says that the OS must not
                  * interleave ibm,get-indices call sequences with
                  * different inputs.
                  */
                 .lock = &rtas_ibm_get_indices_lock,
         },
         [RTAS_FNIDX__IBM_GET_RIO_TOPOLOGY] = {
                 .name = "ibm,get-rio-topology",
         },
         [RTAS_FNIDX__IBM_GET_SYSTEM_PARAMETER] = {
                 .name = "ibm,get-system-parameter",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = 1, .size_idx1 = 2,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__IBM_GET_VPD] = {
                 .name = "ibm,get-vpd",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = 0, .size_idx1 = -1,
                         .buf_idx2 = 1, .size_idx2 = 2,
                 },
                 /*
                  * PAPR+ v2.13 R1–7.3.20–4 indicates that sequences
                  * should not be allowed to interleave.
                  */
                 .lock = &rtas_ibm_get_vpd_lock,
         },
         [RTAS_FNIDX__IBM_GET_XIVE] = {
                 .name = "ibm,get-xive",
         },
         [RTAS_FNIDX__IBM_INT_OFF] = {
                 .name = "ibm,int-off",
         },
         [RTAS_FNIDX__IBM_INT_ON] = {
                 .name = "ibm,int-on",
         },
         [RTAS_FNIDX__IBM_IO_QUIESCE_ACK] = {
                 .name = "ibm,io-quiesce-ack",
         },
         [RTAS_FNIDX__IBM_LPAR_PERFTOOLS] = {
                 .name = "ibm,lpar-perftools",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = 2, .size_idx1 = 3,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
                 /*
                  * PAPR+ v2.13 R1–7.3.26–6 says the OS should allow
                  * only one call sequence in progress at a time.
                  */
                 .lock = &rtas_ibm_lpar_perftools_lock,
         },
         [RTAS_FNIDX__IBM_MANAGE_FLASH_IMAGE] = {
                 .name = "ibm,manage-flash-image",
         },
         [RTAS_FNIDX__IBM_MANAGE_STORAGE_PRESERVATION] = {
                 .name = "ibm,manage-storage-preservation",
         },
         [RTAS_FNIDX__IBM_NMI_INTERLOCK] = {
                 .name = "ibm,nmi-interlock",
         },
         [RTAS_FNIDX__IBM_NMI_REGISTER] = {
                 .name = "ibm,nmi-register",
         },
         [RTAS_FNIDX__IBM_OPEN_ERRINJCT] = {
                 .name = "ibm,open-errinjct",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = -1, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__IBM_OPEN_SRIOV_ALLOW_UNFREEZE] = {
                 .name = "ibm,open-sriov-allow-unfreeze",
         },
         [RTAS_FNIDX__IBM_OPEN_SRIOV_MAP_PE_NUMBER] = {
                 .name = "ibm,open-sriov-map-pe-number",
         },
         [RTAS_FNIDX__IBM_OS_TERM] = {
                 .name = "ibm,os-term",
         },
         [RTAS_FNIDX__IBM_PARTNER_CONTROL] = {
                 .name = "ibm,partner-control",
         },
         [RTAS_FNIDX__IBM_PHYSICAL_ATTESTATION] = {
                 .name = "ibm,physical-attestation",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = 0, .size_idx1 = 1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
                 /*
                  * This follows a sequence-based pattern similar to
                  * ibm,get-vpd et al. Since PAPR+ restricts
                  * interleaving call sequences for other functions of
                  * this style, assume the restriction applies here,
                  * even though it's not explicit in the spec.
                  */
                 .lock = &rtas_ibm_physical_attestation_lock,
         },
         [RTAS_FNIDX__IBM_PLATFORM_DUMP] = {
                 .name = "ibm,platform-dump",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = 4, .size_idx1 = 5,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
                 /*
                  * PAPR+ v2.13 7.3.3.4.1 indicates that concurrent
                  * sequences of ibm,platform-dump are allowed if they
                  * are operating on different dump tags. So leave the
                  * lock pointer unset for now. This may need
                  * reconsideration if kernel-internal users appear.
                  */
         },
         [RTAS_FNIDX__IBM_POWER_OFF_UPS] = {
                 .name = "ibm,power-off-ups",
         },
         [RTAS_FNIDX__IBM_QUERY_INTERRUPT_SOURCE_NUMBER] = {
                 .name = "ibm,query-interrupt-source-number",
         },
         [RTAS_FNIDX__IBM_QUERY_PE_DMA_WINDOW] = {
                 .name = "ibm,query-pe-dma-window",
         },
         [RTAS_FNIDX__IBM_READ_PCI_CONFIG] = {
                 .name = "ibm,read-pci-config",
         },
         [RTAS_FNIDX__IBM_READ_SLOT_RESET_STATE] = {
                 .name = "ibm,read-slot-reset-state",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = -1, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__IBM_READ_SLOT_RESET_STATE2] = {
                 .name = "ibm,read-slot-reset-state2",
         },
         [RTAS_FNIDX__IBM_REMOVE_PE_DMA_WINDOW] = {
                 .name = "ibm,remove-pe-dma-window",
         },
         [RTAS_FNIDX__IBM_RESET_PE_DMA_WINDOW] = {
                 /*
                  * Note: PAPR+ v2.13 7.3.31.4.1 spells this as
                  * "ibm,reset-pe-dma-windows" (plural), but RTAS
                  * implementations use the singular form in practice.
                  */
                 .name = "ibm,reset-pe-dma-window",
         },
         [RTAS_FNIDX__IBM_SCAN_LOG_DUMP] = {
                 .name = "ibm,scan-log-dump",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = 0, .size_idx1 = 1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__IBM_SET_DYNAMIC_INDICATOR] = {
                 .name = "ibm,set-dynamic-indicator",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = 2, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
                 /*
                  * PAPR+ v2.13 R1–7.3.18–3 says the OS must not call
                  * this function with different inputs until a
                  * non-retry status has been returned.
                  */
                 .lock = &rtas_ibm_set_dynamic_indicator_lock,
         },
         [RTAS_FNIDX__IBM_SET_EEH_OPTION] = {
                 .name = "ibm,set-eeh-option",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = -1, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__IBM_SET_SLOT_RESET] = {
                 .name = "ibm,set-slot-reset",
         },
         [RTAS_FNIDX__IBM_SET_SYSTEM_PARAMETER] = {
                 .name = "ibm,set-system-parameter",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = 1, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__IBM_SET_XIVE] = {
                 .name = "ibm,set-xive",
         },
         [RTAS_FNIDX__IBM_SLOT_ERROR_DETAIL] = {
                 .name = "ibm,slot-error-detail",
         },
         [RTAS_FNIDX__IBM_SUSPEND_ME] = {
                 .name = "ibm,suspend-me",
                 .banned_for_syscall_on_le = true,
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = -1, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__IBM_TUNE_DMA_PARMS] = {
                 .name = "ibm,tune-dma-parms",
         },
         [RTAS_FNIDX__IBM_UPDATE_FLASH_64_AND_REBOOT] = {
                 .name = "ibm,update-flash-64-and-reboot",
         },
         [RTAS_FNIDX__IBM_UPDATE_NODES] = {
                 .name = "ibm,update-nodes",
                 .banned_for_syscall_on_le = true,
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = 0, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                         .fixed_size = 4096,
                 },
         },
         [RTAS_FNIDX__IBM_UPDATE_PROPERTIES] = {
                 .name = "ibm,update-properties",
                 .banned_for_syscall_on_le = true,
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = 0, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                         .fixed_size = 4096,
                 },
         },
         [RTAS_FNIDX__IBM_VALIDATE_FLASH_IMAGE] = {
                 .name = "ibm,validate-flash-image",
         },
         [RTAS_FNIDX__IBM_WRITE_PCI_CONFIG] = {
                 .name = "ibm,write-pci-config",
         },
         [RTAS_FNIDX__NVRAM_FETCH] = {
                 .name = "nvram-fetch",
         },
         [RTAS_FNIDX__NVRAM_STORE] = {
                 .name = "nvram-store",
         },
         [RTAS_FNIDX__POWER_OFF] = {
                 .name = "power-off",
         },
         [RTAS_FNIDX__PUT_TERM_CHAR] = {
                 .name = "put-term-char",
         },
         [RTAS_FNIDX__QUERY_CPU_STOPPED_STATE] = {
                 .name = "query-cpu-stopped-state",
         },
         [RTAS_FNIDX__READ_PCI_CONFIG] = {
                 .name = "read-pci-config",
         },
         [RTAS_FNIDX__RTAS_LAST_ERROR] = {
                 .name = "rtas-last-error",
         },
         [RTAS_FNIDX__SET_INDICATOR] = {
                 .name = "set-indicator",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = -1, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__SET_POWER_LEVEL] = {
                 .name = "set-power-level",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = -1, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__SET_TIME_FOR_POWER_ON] = {
                 .name = "set-time-for-power-on",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = -1, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__SET_TIME_OF_DAY] = {
                 .name = "set-time-of-day",
                 .filter = &(const struct rtas_filter) {
                         .buf_idx1 = -1, .size_idx1 = -1,
                         .buf_idx2 = -1, .size_idx2 = -1,
                 },
         },
         [RTAS_FNIDX__START_CPU] = {
                 .name = "start-cpu",
         },
         [RTAS_FNIDX__STOP_SELF] = {
                 .name = "stop-self",
         },
         [RTAS_FNIDX__SYSTEM_REBOOT] = {
                 .name = "system-reboot",
         },
         [RTAS_FNIDX__THAW_TIME_BASE] = {
                 .name = "thaw-time-base",
         },
         [RTAS_FNIDX__WRITE_PCI_CONFIG] = {
                 .name = "write-pci-config",
         },
 };
 
 #define for_each_rtas_function(funcp)                                       \
         for (funcp = &rtas_function_table[0];                               \
              funcp < &rtas_function_table[ARRAY_SIZE(rtas_function_table)]; \
              ++funcp)
 
 /*
  * Nearly all RTAS calls need to be serialized. All uses of the
  * default rtas_args block must hold rtas_lock.
  *
  * Exceptions to the RTAS serialization requirement (e.g. stop-self)
  * must use a separate rtas_args structure.
  */
 static DEFINE_RAW_SPINLOCK(rtas_lock);
 static struct rtas_args rtas_args;
 
 /**
  * rtas_function_token() - RTAS function token lookup.
  * @handle: Function handle, e.g. RTAS_FN_EVENT_SCAN.
  *
  * Context: Any context.
  * Return: the token value for the function if implemented by this platform,
  *         otherwise RTAS_UNKNOWN_SERVICE.
  */
 s32 rtas_function_token(const rtas_fn_handle_t handle)
 {
         const size_t index = handle.index;
         const bool out_of_bounds = index >= ARRAY_SIZE(rtas_function_table);
 
         if (WARN_ONCE(out_of_bounds, "invalid function index %zu", index))
                 return RTAS_UNKNOWN_SERVICE;
         /*
          * Various drivers attempt token lookups on non-RTAS
          * platforms.
          */
         if (!rtas.dev)
                 return RTAS_UNKNOWN_SERVICE;
 
         return rtas_function_table[index].token;
 }
 EXPORT_SYMBOL_GPL(rtas_function_token);
 
 static int rtas_function_cmp(const void *a, const void *b)
 {
         const struct rtas_function *f1 = a;
         const struct rtas_function *f2 = b;
 
         return strcmp(f1->name, f2->name);
 }
 
 /*
  * Boot-time initialization of the function table needs the lookup to
  * return a non-const-qualified object. Use rtas_name_to_function()
  * in all other contexts.
  */
 static struct rtas_function *__rtas_name_to_function(const char *name)
 {
         const struct rtas_function key = {
                 .name = name,
         };
         struct rtas_function *found;
 
         found = bsearch(&key, rtas_function_table, ARRAY_SIZE(rtas_function_table),
                         sizeof(rtas_function_table[0]), rtas_function_cmp);
 
         return found;
 }
 
 static const struct rtas_function *rtas_name_to_function(const char *name)
 {
         return __rtas_name_to_function(name);
 }
 
 static DEFINE_XARRAY(rtas_token_to_function_xarray);
 
 static int __init rtas_token_to_function_xarray_init(void)
 {
         const struct rtas_function *func;
         int err = 0;
 
         for_each_rtas_function(func) {
                 const s32 token = func->token;
 
                 if (token == RTAS_UNKNOWN_SERVICE)
                         continue;
 
                 err = xa_err(xa_store(&rtas_token_to_function_xarray,
                                       token, (void *)func, GFP_KERNEL));
                 if (err)
                         break;
         }
 
         return err;
 }
 arch_initcall(rtas_token_to_function_xarray_init);
 
 /*
  * For use by sys_rtas(), where the token value is provided by user
  * space and we don't want to warn on failed lookups.
  */
 static const struct rtas_function *rtas_token_to_function_untrusted(s32 token)
 {
         return xa_load(&rtas_token_to_function_xarray, token);
 }
 
 /*
  * Reverse lookup for deriving the function descriptor from a
  * known-good token value in contexts where the former is not already
  * available. @token must be valid, e.g. derived from the result of a
  * prior lookup against the function table.
  */
 static const struct rtas_function *rtas_token_to_function(s32 token)
 {
         const struct rtas_function *func;
 
         if (WARN_ONCE(token < 0, "invalid token %d", token))
                 return NULL;
 
         func = rtas_token_to_function_untrusted(token);
         if (func)
                 return func;
         /*
          * Fall back to linear scan in case the reverse mapping hasn't
          * been initialized yet.
          */
         if (xa_empty(&rtas_token_to_function_xarray)) {
                 for_each_rtas_function(func) {
                         if (func->token == token)
                                 return func;
                 }
         }
 
         WARN_ONCE(true, "unexpected failed lookup for token %d", token);
         return NULL;
 }
 
 /* This is here deliberately so it's only used in this file */
 void enter_rtas(unsigned long);
 
 static void __do_enter_rtas(struct rtas_args *args)
 {
         enter_rtas(__pa(args));
         srr_regs_clobbered(); /* rtas uses SRRs, invalidate */
 }
 
 static void __do_enter_rtas_trace(struct rtas_args *args)
 {
         const struct rtas_function *func = rtas_token_to_function(be32_to_cpu(args->token));
 
         /*
          * If there is a per-function lock, it must be held by the
          * caller.
          */
         if (func->lock)
                 lockdep_assert_held(func->lock);
 
         if (args == &rtas_args)
                 lockdep_assert_held(&rtas_lock);
 
         trace_rtas_input(args, func->name);
         trace_rtas_ll_entry(args);
 
         __do_enter_rtas(args);
 
         trace_rtas_ll_exit(args);
         trace_rtas_output(args, func->name);
 }
 
 static void do_enter_rtas(struct rtas_args *args)
 {
         const unsigned long msr = mfmsr();
         /*
          * Situations where we want to skip any active tracepoints for
          * safety reasons:
          *
          * 1. The last code executed on an offline CPU as it stops,
          *    i.e. we're about to call stop-self. The tracepoints'
          *    function name lookup uses xarray, which uses RCU, which
          *    isn't valid to call on an offline CPU.  Any events
          *    emitted on an offline CPU will be discarded anyway.
          *
          * 2. In real mode, as when invoking ibm,nmi-interlock from
          *    the pseries MCE handler. We cannot count on trace
          *    buffers or the entries in rtas_token_to_function_xarray
          *    to be contained in the RMO.
          */
         const unsigned long mask = MSR_IR | MSR_DR;
         const bool can_trace = likely(cpu_online(raw_smp_processor_id()) &&
                                       (msr & mask) == mask);
         /*
          * Make sure MSR[RI] is currently enabled as it will be forced later
          * in enter_rtas.
          */
         BUG_ON(!(msr & MSR_RI));
 
         BUG_ON(!irqs_disabled());
 
         hard_irq_disable(); /* Ensure MSR[EE] is disabled on PPC64 */
 
         if (can_trace)
                 __do_enter_rtas_trace(args);
         else
                 __do_enter_rtas(args);
 }
 
 struct rtas_t rtas;
 
 DEFINE_SPINLOCK(rtas_data_buf_lock);
 EXPORT_SYMBOL_GPL(rtas_data_buf_lock);
 
 char rtas_data_buf[RTAS_DATA_BUF_SIZE] __aligned(SZ_4K);
 EXPORT_SYMBOL_GPL(rtas_data_buf);
 
 unsigned long rtas_rmo_buf;
 
 /*
  * If non-NULL, this gets called when the kernel terminates.
  * This is done like this so rtas_flash can be a module.
  */
 void (*rtas_flash_term_hook)(int);
 EXPORT_SYMBOL_GPL(rtas_flash_term_hook);
 
 /*
  * call_rtas_display_status and call_rtas_display_status_delay
  * are designed only for very early low-level debugging, which
  * is why the token is hard-coded to 10.
  */
 static void call_rtas_display_status(unsigned char c)
 {
         unsigned long flags;
 
         if (!rtas.base)
                 return;
 
         raw_spin_lock_irqsave(&rtas_lock, flags);
         rtas_call_unlocked(&rtas_args, 10, 1, 1, NULL, c);
         raw_spin_unlock_irqrestore(&rtas_lock, flags);
 }
 
 static void call_rtas_display_status_delay(char c)
 {
         static int pending_newline = 0;  /* did last write end with unprinted newline? */
         static int width = 16;
 
         if (c == '\n') {
                 while (width-- > 0)
                         call_rtas_display_status(' ');
                 width = 16;
                 mdelay(500);
                 pending_newline = 1;
         } else {
                 if (pending_newline) {
                         call_rtas_display_status('\r');
                         call_rtas_display_status('\n');
                 }
                 pending_newline = 0;
                 if (width--) {
                         call_rtas_display_status(c);
                         udelay(10000);
                 }
         }
 }
 
 void __init udbg_init_rtas_panel(void)
 {
         udbg_putc = call_rtas_display_status_delay;
 }
 
 #ifdef CONFIG_UDBG_RTAS_CONSOLE
 
 /* If you think you're dying before early_init_dt_scan_rtas() does its
  * work, you can hard code the token values for your firmware here and
  * hardcode rtas.base/entry etc.
  */
 static unsigned int rtas_putchar_token = RTAS_UNKNOWN_SERVICE;
 static unsigned int rtas_getchar_token = RTAS_UNKNOWN_SERVICE;
 
 static void udbg_rtascon_putc(char c)
 {
         int tries;
 
         if (!rtas.base)
                 return;
 
         /* Add CRs before LFs */
         if (c == '\n')
                 udbg_rtascon_putc('\r');
 
         /* if there is more than one character to be displayed, wait a bit */
         for (tries = 0; tries < 16; tries++) {
                 if (rtas_call(rtas_putchar_token, 1, 1, NULL, c) == 0)
                         break;
                 udelay(1000);
         }
 }
 
 static int udbg_rtascon_getc_poll(void)
 {
         int c;
 
         if (!rtas.base)
                 return -1;
 
         if (rtas_call(rtas_getchar_token, 0, 2, &c))
                 return -1;
 
         return c;
 }
 
 static int udbg_rtascon_getc(void)
 {
         int c;
 
         while ((c = udbg_rtascon_getc_poll()) == -1)
                 ;
 
         return c;
 }
 
 
 void __init udbg_init_rtas_console(void)
 {
         udbg_putc = udbg_rtascon_putc;
         udbg_getc = udbg_rtascon_getc;
         udbg_getc_poll = udbg_rtascon_getc_poll;
 }
 #endif /* CONFIG_UDBG_RTAS_CONSOLE */
 
 void rtas_progress(char *s, unsigned short hex)
 {
         struct device_node *root;
         int width;
         const __be32 *p;
         char *os;
         static int display_character, set_indicator;
         static int display_width, display_lines, form_feed;
         static const int *row_width;
         static DEFINE_SPINLOCK(progress_lock);
         static int current_line;
         static int pending_newline = 0;  /* did last write end with unprinted newline? */
 
         if (!rtas.base)
                 return;
 
         if (display_width == 0) {
                 display_width = 0x10;
                 if ((root = of_find_node_by_path("/rtas"))) {
                         if ((p = of_get_property(root,
                                         "ibm,display-line-length", NULL)))
                                 display_width = be32_to_cpu(*p);
                         if ((p = of_get_property(root,
                                         "ibm,form-feed", NULL)))
                                 form_feed = be32_to_cpu(*p);
                         if ((p = of_get_property(root,
                                         "ibm,display-number-of-lines", NULL)))
                                 display_lines = be32_to_cpu(*p);
                         row_width = of_get_property(root,
                                         "ibm,display-truncation-length", NULL);
                         of_node_put(root);
                 }
                 display_character = rtas_function_token(RTAS_FN_DISPLAY_CHARACTER);
                 set_indicator = rtas_function_token(RTAS_FN_SET_INDICATOR);
         }
 
         if (display_character == RTAS_UNKNOWN_SERVICE) {
                 /* use hex display if available */
                 if (set_indicator != RTAS_UNKNOWN_SERVICE)
                         rtas_call(set_indicator, 3, 1, NULL, 6, 0, hex);
                 return;
         }
 
         spin_lock(&progress_lock);
 
         /*
          * Last write ended with newline, but we didn't print it since
          * it would just clear the bottom line of output. Print it now
          * instead.
          *
          * If no newline is pending and form feed is supported, clear the
          * display with a form feed; otherwise, print a CR to start output
          * at the beginning of the line.
          */
         if (pending_newline) {
                 rtas_call(display_character, 1, 1, NULL, '\r');
                 rtas_call(display_character, 1, 1, NULL, '\n');
                 pending_newline = 0;
         } else {
                 current_line = 0;
                 if (form_feed)
                         rtas_call(display_character, 1, 1, NULL,
                                   (char)form_feed);
                 else
                         rtas_call(display_character, 1, 1, NULL, '\r');
         }
 
         if (row_width)
                 width = row_width[current_line];
         else
                 width = display_width;
         os = s;
         while (*os) {
                 if (*os == '\n' || *os == '\r') {
                         /* If newline is the last character, save it
                          * until next call to avoid bumping up the
                          * display output.
                          */
                         if (*os == '\n' && !os[1]) {
                                 pending_newline = 1;
                                 current_line++;
                                 if (current_line > display_lines-1)
                                         current_line = display_lines-1;
                                 spin_unlock(&progress_lock);
                                 return;
                         }
 
                         /* RTAS wants CR-LF, not just LF */
 
                         if (*os == '\n') {
                                 rtas_call(display_character, 1, 1, NULL, '\r');
                                 rtas_call(display_character, 1, 1, NULL, '\n');
                         } else {
                                 /* CR might be used to re-draw a line, so we'll
                                  * leave it alone and not add LF.
                                  */
                                 rtas_call(display_character, 1, 1, NULL, *os);
                         }
 
                         if (row_width)
                                 width = row_width[current_line];
                         else
                                 width = display_width;
                 } else {
                         width--;
                         rtas_call(display_character, 1, 1, NULL, *os);
                 }
 
                 os++;
 
                 /* if we overwrite the screen length */
                 if (width <= 0)
                         while ((*os != 0) && (*os != '\n') && (*os != '\r'))
                                 os++;
         }
 
         spin_unlock(&progress_lock);
 }
 EXPORT_SYMBOL_GPL(rtas_progress);               /* needed by rtas_flash module */
 
 int rtas_token(const char *service)
 {
         const struct rtas_function *func;
         const __be32 *tokp;
 
         if (rtas.dev == NULL)
                 return RTAS_UNKNOWN_SERVICE;
 
         func = rtas_name_to_function(service);
         if (func)
                 return func->token;
         /*
          * The caller is looking up a name that is not known to be an
          * RTAS function. Either it's a function that needs to be
          * added to the table, or they're misusing rtas_token() to
          * access non-function properties of the /rtas node. Warn and
          * fall back to the legacy behavior.
          */
         WARN_ONCE(1, "unknown function `%s`, should it be added to rtas_function_table?\n",
                   service);
 
         tokp = of_get_property(rtas.dev, service, NULL);
         return tokp ? be32_to_cpu(*tokp) : RTAS_UNKNOWN_SERVICE;
 }
 EXPORT_SYMBOL_GPL(rtas_token);
 
 #ifdef CONFIG_RTAS_ERROR_LOGGING
 
 static u32 rtas_error_log_max __ro_after_init = RTAS_ERROR_LOG_MAX;
 
 /*
  * Return the firmware-specified size of the error log buffer
  *  for all rtas calls that require an error buffer argument.
  *  This includes 'check-exception' and 'rtas-last-error'.
  */
 int rtas_get_error_log_max(void)
 {
         return rtas_error_log_max;
 }
 
 static void __init init_error_log_max(void)
 {
         static const char propname[] __initconst = "rtas-error-log-max";
         u32 max;
 
         if (of_property_read_u32(rtas.dev, propname, &max)) {
                 pr_warn("%s not found, using default of %u\n",
                         propname, RTAS_ERROR_LOG_MAX);
                 max = RTAS_ERROR_LOG_MAX;
         }
 
         if (max > RTAS_ERROR_LOG_MAX) {
                 pr_warn("%s = %u, clamping max error log size to %u\n",
                         propname, max, RTAS_ERROR_LOG_MAX);
                 max = RTAS_ERROR_LOG_MAX;
         }
 
         rtas_error_log_max = max;
 }
 
 
 static char rtas_err_buf[RTAS_ERROR_LOG_MAX];
 
 /** Return a copy of the detailed error text associated with the
  *  most recent failed call to rtas.  Because the error text
  *  might go stale if there are any other intervening rtas calls,
  *  this routine must be called atomically with whatever produced
  *  the error (i.e. with rtas_lock still held from the previous call).
  */
 static char *__fetch_rtas_last_error(char *altbuf)
 {
         const s32 token = rtas_function_token(RTAS_FN_RTAS_LAST_ERROR);
         struct rtas_args err_args, save_args;
         u32 bufsz;
         char *buf = NULL;
 
         lockdep_assert_held(&rtas_lock);
 
         if (token == -1)
                 return NULL;
 
         bufsz = rtas_get_error_log_max();
 
         err_args.token = cpu_to_be32(token);
         err_args.nargs = cpu_to_be32(2);
         err_args.nret = cpu_to_be32(1);
         err_args.args[0] = cpu_to_be32(__pa(rtas_err_buf));
         err_args.args[1] = cpu_to_be32(bufsz);
         err_args.args[2] = 0;
 
         save_args = rtas_args;
         rtas_args = err_args;
 
         do_enter_rtas(&rtas_args);
 
         err_args = rtas_args;
         rtas_args = save_args;
 
         /* Log the error in the unlikely case that there was one. */
         if (unlikely(err_args.args[2] == 0)) {
                 if (altbuf) {
                         buf = altbuf;
                 } else {
                         buf = rtas_err_buf;
                         if (slab_is_available())
                                 buf = kmalloc(RTAS_ERROR_LOG_MAX, GFP_ATOMIC);
                 }
                 if (buf)
                         memmove(buf, rtas_err_buf, RTAS_ERROR_LOG_MAX);
         }
 
         return buf;
 }
 
 #define get_errorlog_buffer()   kmalloc(RTAS_ERROR_LOG_MAX, GFP_KERNEL)
 
 #else /* CONFIG_RTAS_ERROR_LOGGING */
 #define __fetch_rtas_last_error(x)      NULL
 #define get_errorlog_buffer()           NULL
 static void __init init_error_log_max(void) {}
 #endif
 
 
 static void
 va_rtas_call_unlocked(struct rtas_args *args, int token, int nargs, int nret,
                       va_list list)
 {
         int i;
 
         args->token = cpu_to_be32(token);
         args->nargs = cpu_to_be32(nargs);
         args->nret  = cpu_to_be32(nret);
         args->rets  = &(args->args[nargs]);
 
         for (i = 0; i < nargs; ++i)
                 args->args[i] = cpu_to_be32(va_arg(list, __u32));
 
         for (i = 0; i < nret; ++i)
                 args->rets[i] = 0;
 
         do_enter_rtas(args);
 }
 
 /**
  * rtas_call_unlocked() - Invoke an RTAS firmware function without synchronization.
  * @args: RTAS parameter block to be used for the call, must obey RTAS addressing
  *        constraints.
  * @token: Identifies the function being invoked.
  * @nargs: Number of input parameters. Does not include token.
  * @nret: Number of output parameters, including the call status.
  * @....: List of @nargs input parameters.
  *
  * Invokes the RTAS function indicated by @token, which the caller
  * should obtain via rtas_function_token().
  *
  * This function is similar to rtas_call(), but must be used with a
  * limited set of RTAS calls specifically exempted from the general
  * requirement that only one RTAS call may be in progress at any
  * time. Examples include stop-self and ibm,nmi-interlock.
  */
 void rtas_call_unlocked(struct rtas_args *args, int token, int nargs, int nret, ...)
 {
         va_list list;
 
         va_start(list, nret);
         va_rtas_call_unlocked(args, token, nargs, nret, list);
         va_end(list);
 }
 
 static bool token_is_restricted_errinjct(s32 token)
 {
         return token == rtas_function_token(RTAS_FN_IBM_OPEN_ERRINJCT) ||
                token == rtas_function_token(RTAS_FN_IBM_ERRINJCT);
 }
 
 /**
  * rtas_call() - Invoke an RTAS firmware function.
  * @token: Identifies the function being invoked.
  * @nargs: Number of input parameters. Does not include token.
  * @nret: Number of output parameters, including the call status.
  * @outputs: Array of @nret output words.
  * @....: List of @nargs input parameters.
  *
  * Invokes the RTAS function indicated by @token, which the caller
  * should obtain via rtas_function_token().
  *
  * The @nargs and @nret arguments must match the number of input and
  * output parameters specified for the RTAS function.
  *
  * rtas_call() returns RTAS status codes, not conventional Linux errno
  * values. Callers must translate any failure to an appropriate errno
  * in syscall context. Most callers of RTAS functions that can return
  * -2 or 990x should use rtas_busy_delay() to correctly handle those
  * statuses before calling again.
  *
  * The return value descriptions are adapted from 7.2.8 [RTAS] Return
  * Codes of the PAPR and CHRP specifications.
  *
  * Context: Process context preferably, interrupt context if
  *          necessary.  Acquires an internal spinlock and may perform
  *          GFP_ATOMIC slab allocation in error path. Unsafe for NMI
  *          context.
  * Return:
  * *                          0 - RTAS function call succeeded.
  * *                         -1 - RTAS function encountered a hardware or
  *                                platform error, or the token is invalid,
  *                                or the function is restricted by kernel policy.
  * *                         -2 - Specs say "A necessary hardware device was busy,
  *                                and the requested function could not be
  *                                performed. The operation should be retried at
  *                                a later time." This is misleading, at least with
  *                                respect to current RTAS implementations. What it
  *                                usually means in practice is that the function
  *                                could not be completed while meeting RTAS's
  *                                deadline for returning control to the OS (250us
  *                                for PAPR/PowerVM, typically), but the call may be
  *                                immediately reattempted to resume work on it.
  * *                         -3 - Parameter error.
  * *                         -7 - Unexpected state change.
  * *                9000...9899 - Vendor-specific success codes.
  * *                9900...9905 - Advisory extended delay. Caller should try
  *                                again after ~10^x ms has elapsed, where x is
  *                                the last digit of the status [0-5]. Again going
  *                                beyond the PAPR text, 990x on PowerVM indicates
  *                                contention for RTAS-internal resources. Other
  *                                RTAS call sequences in progress should be
  *                                allowed to complete before reattempting the
  *                                call.
  * *                      -9000 - Multi-level isolation error.
  * *              -9999...-9004 - Vendor-specific error codes.
  * * Additional negative values - Function-specific error.
  * * Additional positive values - Function-specific success.
  */
 int rtas_call(int token, int nargs, int nret, int *outputs, ...)
 {
         struct pin_cookie cookie;
         va_list list;
         int i;
         unsigned long flags;
         struct rtas_args *args;
         char *buff_copy = NULL;
         int ret;
 
         if (!rtas.entry || token == RTAS_UNKNOWN_SERVICE)
                 return -1;
 
         if (token_is_restricted_errinjct(token)) {
                 /*
                  * It would be nicer to not discard the error value
                  * from security_locked_down(), but callers expect an
                  * RTAS status, not an errno.
                  */
                 if (security_locked_down(LOCKDOWN_RTAS_ERROR_INJECTION))
                         return -1;
         }
 
         if ((mfmsr() & (MSR_IR|MSR_DR)) != (MSR_IR|MSR_DR)) {
                 WARN_ON_ONCE(1);
                 return -1;
         }
 
         raw_spin_lock_irqsave(&rtas_lock, flags);
         cookie = lockdep_pin_lock(&rtas_lock);
 
         /* We use the global rtas args buffer */
         args = &rtas_args;
 
         va_start(list, outputs);
         va_rtas_call_unlocked(args, token, nargs, nret, list);
         va_end(list);
 
         /* A -1 return code indicates that the last command couldn't
            be completed due to a hardware error. */
         if (be32_to_cpu(args->rets[0]) == -1)
                 buff_copy = __fetch_rtas_last_error(NULL);
 
         if (nret > 1 && outputs != NULL)
                 for (i = 0; i < nret-1; ++i)
                         outputs[i] = be32_to_cpu(args->rets[i + 1]);
         ret = (nret > 0) ? be32_to_cpu(args->rets[0]) : 0;
 
         lockdep_unpin_lock(&rtas_lock, cookie);
         raw_spin_unlock_irqrestore(&rtas_lock, flags);
 
         if (buff_copy) {
                 log_error(buff_copy, ERR_TYPE_RTAS_LOG, 0);
                 if (slab_is_available())
                         kfree(buff_copy);
         }
         return ret;
 }
 EXPORT_SYMBOL_GPL(rtas_call);
 
 /**
  * rtas_busy_delay_time() - From an RTAS status value, calculate the
  *                          suggested delay time in milliseconds.
  *
  * @status: a value returned from rtas_call() or similar APIs which return
  *          the status of a RTAS function call.
  *
  * Context: Any context.
  *
  * Return:
  * * 100000 - If @status is 9905.
  * * 10000  - If @status is 9904.
  * * 1000   - If @status is 9903.
  * * 100    - If @status is 9902.
  * * 10     - If @status is 9901.
  * * 1      - If @status is either 9900 or -2. This is "wrong" for -2, but
  *            some callers depend on this behavior, and the worst outcome
  *            is that they will delay for longer than necessary.
  * * 0      - If @status is not a busy or extended delay value.
  */
 unsigned int rtas_busy_delay_time(int status)
 {
         int order;
         unsigned int ms = 0;
 
         if (status == RTAS_BUSY) {
                 ms = 1;
         } else if (status >= RTAS_EXTENDED_DELAY_MIN &&
                    status <= RTAS_EXTENDED_DELAY_MAX) {
                 order = status - RTAS_EXTENDED_DELAY_MIN;
                 for (ms = 1; order > 0; order--)
                         ms *= 10;
         }
 
         return ms;
 }
 
 /*
  * Early boot fallback for rtas_busy_delay().
  */
 static bool __init rtas_busy_delay_early(int status)
 {
         static size_t successive_ext_delays __initdata;
         bool retry;
 
         switch (status) {
         case RTAS_EXTENDED_DELAY_MIN...RTAS_EXTENDED_DELAY_MAX:
                 /*
                  * In the unlikely case that we receive an extended
                  * delay status in early boot, the OS is probably not
                  * the cause, and there's nothing we can do to clear
                  * the condition. Best we can do is delay for a bit
                  * and hope it's transient. Lie to the caller if it
                  * seems like we're stuck in a retry loop.
                  */
                 mdelay(1);
                 retry = true;
                 successive_ext_delays += 1;
                 if (successive_ext_delays > 1000) {
                         pr_err("too many extended delays, giving up\n");
                         dump_stack();
                         retry = false;
                         successive_ext_delays = 0;
                 }
                 break;
         case RTAS_BUSY:
                 retry = true;
                 successive_ext_delays = 0;
                 break;
         default:
                 retry = false;
                 successive_ext_delays = 0;
                 break;
         }
 
         return retry;
 }
 
 /**
  * rtas_busy_delay() - helper for RTAS busy and extended delay statuses
  *
  * @status: a value returned from rtas_call() or similar APIs which return
  *          the status of a RTAS function call.
  *
  * Context: Process context. May sleep or schedule.
  *
  * Return:
  * * true  - @status is RTAS_BUSY or an extended delay hint. The
  *           caller may assume that the CPU has been yielded if necessary,
  *           and that an appropriate delay for @status has elapsed.
  *           Generally the caller should reattempt the RTAS call which
  *           yielded @status.
  *
  * * false - @status is not @RTAS_BUSY nor an extended delay hint. The
  *           caller is responsible for handling @status.
  */
 bool __ref rtas_busy_delay(int status)
 {
         unsigned int ms;
         bool ret;
 
         /*
          * Can't do timed sleeps before timekeeping is up.
          */
         if (system_state < SYSTEM_SCHEDULING)
                 return rtas_busy_delay_early(status);
 
         switch (status) {
         case RTAS_EXTENDED_DELAY_MIN...RTAS_EXTENDED_DELAY_MAX:
                 ret = true;
                 ms = rtas_busy_delay_time(status);
                 /*
                  * The extended delay hint can be as high as 100 seconds.
                  * Surely any function returning such a status is either
                  * buggy or isn't going to be significantly slowed by us
                  * polling at 1HZ. Clamp the sleep time to one second.
                  */
                 ms = clamp(ms, 1U, 1000U);
                 /*
                  * The delay hint is an order-of-magnitude suggestion, not
                  * a minimum. It is fine, possibly even advantageous, for
                  * us to pause for less time than hinted. For small values,
                  * use usleep_range() to ensure we don't sleep much longer
                  * than actually needed.
                  *
                  * See Documentation/timers/timers-howto.rst for
                  * explanation of the threshold used here. In effect we use
                  * usleep_range() for 9900 and 9901, msleep() for
                  * 9902-9905.
                  */
                 if (ms <= 20)
                         usleep_range(ms * 100, ms * 1000);
                 else
                         msleep(ms);
                 break;
         case RTAS_BUSY:
                 ret = true;
                 /*
                  * We should call again immediately if there's no other
                  * work to do.
                  */
                 cond_resched();
                 break;
         default:
                 ret = false;
                 /*
                  * Not a busy or extended delay status; the caller should
                  * handle @status itself. Ensure we warn on misuses in
                  * atomic context regardless.
                  */
                 might_sleep();
                 break;
         }
 
         return ret;
 }
 EXPORT_SYMBOL_GPL(rtas_busy_delay);
 
 int rtas_error_rc(int rtas_rc)
 {
         int rc;
 
         switch (rtas_rc) {
         case RTAS_HARDWARE_ERROR:       /* Hardware Error */
                 rc = -EIO;
                 break;
         case RTAS_INVALID_PARAMETER:    /* Bad indicator/domain/etc */
                 rc = -EINVAL;
                 break;
         case -9000:                     /* Isolation error */
                 rc = -EFAULT;
                 break;
         case -9001:                     /* Outstanding TCE/PTE */
                 rc = -EEXIST;
                 break;
         case -9002:                     /* No usable slot */
                 rc = -ENODEV;
                 break;
         default:
                 pr_err("%s: unexpected error %d\n", __func__, rtas_rc);
                 rc = -ERANGE;
                 break;
         }
         return rc;
 }
 EXPORT_SYMBOL_GPL(rtas_error_rc);
 
 int rtas_get_power_level(int powerdomain, int *level)
 {
         int token = rtas_function_token(RTAS_FN_GET_POWER_LEVEL);
         int rc;
 
         if (token == RTAS_UNKNOWN_SERVICE)
                 return -ENOENT;
 
         while ((rc = rtas_call(token, 1, 2, level, powerdomain)) == RTAS_BUSY)
                 udelay(1);
 
         if (rc < 0)
                 return rtas_error_rc(rc);
         return rc;
 }
 EXPORT_SYMBOL_GPL(rtas_get_power_level);
 
 int rtas_set_power_level(int powerdomain, int level, int *setlevel)
 {
         int token = rtas_function_token(RTAS_FN_SET_POWER_LEVEL);
         int rc;
 
         if (token == RTAS_UNKNOWN_SERVICE)
                 return -ENOENT;
 
         do {
                 rc = rtas_call(token, 2, 2, setlevel, powerdomain, level);
         } while (rtas_busy_delay(rc));
 
         if (rc < 0)
                 return rtas_error_rc(rc);
         return rc;
 }
 EXPORT_SYMBOL_GPL(rtas_set_power_level);
 
 int rtas_get_sensor(int sensor, int index, int *state)
 {
         int token = rtas_function_token(RTAS_FN_GET_SENSOR_STATE);
         int rc;
 
         if (token == RTAS_UNKNOWN_SERVICE)
                 return -ENOENT;
 
         do {
                 rc = rtas_call(token, 2, 2, state, sensor, index);
         } while (rtas_busy_delay(rc));
 
         if (rc < 0)
                 return rtas_error_rc(rc);
         return rc;
 }
 EXPORT_SYMBOL_GPL(rtas_get_sensor);
 
 int rtas_get_sensor_fast(int sensor, int index, int *state)
 {
         int token = rtas_function_token(RTAS_FN_GET_SENSOR_STATE);
         int rc;
 
         if (token == RTAS_UNKNOWN_SERVICE)
                 return -ENOENT;
 
         rc = rtas_call(token, 2, 2, state, sensor, index);
         WARN_ON(rc == RTAS_BUSY || (rc >= RTAS_EXTENDED_DELAY_MIN &&
                                     rc <= RTAS_EXTENDED_DELAY_MAX));
 
         if (rc < 0)
                 return rtas_error_rc(rc);
         return rc;
 }
 
 bool rtas_indicator_present(int token, int *maxindex)
 {
         int proplen, count, i;
         const struct indicator_elem {
                 __be32 token;
                 __be32 maxindex;
         } *indicators;
 
         indicators = of_get_property(rtas.dev, "rtas-indicators", &proplen);
         if (!indicators)
                 return false;
 
         count = proplen / sizeof(struct indicator_elem);
 
         for (i = 0; i < count; i++) {
                 if (__be32_to_cpu(indicators[i].token) != token)
                         continue;
                 if (maxindex)
                         *maxindex = __be32_to_cpu(indicators[i].maxindex);
                 return true;
         }
 
         return false;
 }
 
 int rtas_set_indicator(int indicator, int index, int new_value)
 {
         int token = rtas_function_token(RTAS_FN_SET_INDICATOR);
         int rc;
 
         if (token == RTAS_UNKNOWN_SERVICE)
                 return -ENOENT;
 
         do {
                 rc = rtas_call(token, 3, 1, NULL, indicator, index, new_value);
         } while (rtas_busy_delay(rc));
 
         if (rc < 0)
                 return rtas_error_rc(rc);
         return rc;
 }
 EXPORT_SYMBOL_GPL(rtas_set_indicator);
 
 /*
  * Ignoring RTAS extended delay
  */
 int rtas_set_indicator_fast(int indicator, int index, int new_value)
 {
         int token = rtas_function_token(RTAS_FN_SET_INDICATOR);
         int rc;
 
         if (token == RTAS_UNKNOWN_SERVICE)
                 return -ENOENT;
 
         rc = rtas_call(token, 3, 1, NULL, indicator, index, new_value);
 
         WARN_ON(rc == RTAS_BUSY || (rc >= RTAS_EXTENDED_DELAY_MIN &&
                                     rc <= RTAS_EXTENDED_DELAY_MAX));
 
         if (rc < 0)
                 return rtas_error_rc(rc);
 
         return rc;
 }
 
 /**
  * rtas_ibm_suspend_me() - Call ibm,suspend-me to suspend the LPAR.
  *
  * @fw_status: RTAS call status will be placed here if not NULL.
  *
  * rtas_ibm_suspend_me() should be called only on a CPU which has
  * received H_CONTINUE from the H_JOIN hcall. All other active CPUs
  * should be waiting to return from H_JOIN.
  *
  * rtas_ibm_suspend_me() may suspend execution of the OS
  * indefinitely. Callers should take appropriate measures upon return, such as
  * resetting watchdog facilities.
  *
  * Callers may choose to retry this call if @fw_status is
  * %RTAS_THREADS_ACTIVE.
  *
  * Return:
  * 0          - The partition has resumed from suspend, possibly after
  *              migration to a different host.
  * -ECANCELED - The operation was aborted.
  * -EAGAIN    - There were other CPUs not in H_JOIN at the time of the call.
  * -EBUSY     - Some other condition prevented the suspend from succeeding.
  * -EIO       - Hardware/platform error.
  */
 int rtas_ibm_suspend_me(int *fw_status)
 {
         int token = rtas_function_token(RTAS_FN_IBM_SUSPEND_ME);
         int fwrc;
         int ret;
 
         fwrc = rtas_call(token, 0, 1, NULL);
 
         switch (fwrc) {
         case 0:
                 ret = 0;
                 break;
         case RTAS_SUSPEND_ABORTED:
                 ret = -ECANCELED;
                 break;
         case RTAS_THREADS_ACTIVE:
                 ret = -EAGAIN;
                 break;
         case RTAS_NOT_SUSPENDABLE:
         case RTAS_OUTSTANDING_COPROC:
                 ret = -EBUSY;
                 break;
         case -1:
         default:
                 ret = -EIO;
                 break;
         }
 
         if (fw_status)
                 *fw_status = fwrc;
 
         return ret;
 }
 
 void __noreturn rtas_restart(char *cmd)
 {
         if (rtas_flash_term_hook)
                 rtas_flash_term_hook(SYS_RESTART);
         pr_emerg("system-reboot returned %d\n",
                  rtas_call(rtas_function_token(RTAS_FN_SYSTEM_REBOOT), 0, 1, NULL));
         for (;;);
 }
 
 void rtas_power_off(void)
 {
         if (rtas_flash_term_hook)
                 rtas_flash_term_hook(SYS_POWER_OFF);
         /* allow power on only with power button press */
         pr_emerg("power-off returned %d\n",
                  rtas_call(rtas_function_token(RTAS_FN_POWER_OFF), 2, 1, NULL, -1, -1));
         for (;;);
 }
 
 void __noreturn rtas_halt(void)
 {
         if (rtas_flash_term_hook)
                 rtas_flash_term_hook(SYS_HALT);
         /* allow power on only with power button press */
         pr_emerg("power-off returned %d\n",
                  rtas_call(rtas_function_token(RTAS_FN_POWER_OFF), 2, 1, NULL, -1, -1));
         for (;;);
 }
 
 /* Must be in the RMO region, so we place it here */
 static char rtas_os_term_buf[2048];
 static bool ibm_extended_os_term;
 
 void rtas_os_term(char *str)
 {
         s32 token = rtas_function_token(RTAS_FN_IBM_OS_TERM);
         static struct rtas_args args;
         int status;
 
         /*
          * Firmware with the ibm,extended-os-term property is guaranteed
          * to always return from an ibm,os-term call. Earlier versions without
          * this property may terminate the partition which we want to avoid
          * since it interferes with panic_timeout.
          */
 
         if (token == RTAS_UNKNOWN_SERVICE || !ibm_extended_os_term)
                 return;
 
         snprintf(rtas_os_term_buf, 2048, "OS panic: %s", str);
 
         /*
          * Keep calling as long as RTAS returns a "try again" status,
          * but don't use rtas_busy_delay(), which potentially
          * schedules.
          */
         do {
                 rtas_call_unlocked(&args, token, 1, 1, NULL, __pa(rtas_os_term_buf));
                 status = be32_to_cpu(args.rets[0]);
         } while (rtas_busy_delay_time(status));
 
         if (status != 0)
                 pr_emerg("ibm,os-term call failed %d\n", status);
 }
 
 /**
  * rtas_activate_firmware() - Activate a new version of firmware.
  *
  * Context: This function may sleep.
  *
  * Activate a new version of partition firmware. The OS must call this
  * after resuming from a partition hibernation or migration in order
  * to maintain the ability to perform live firmware updates. It's not
  * catastrophic for this method to be absent or to fail; just log the
  * condition in that case.
  */
 void rtas_activate_firmware(void)
 {
         int token = rtas_function_token(RTAS_FN_IBM_ACTIVATE_FIRMWARE);
         int fwrc;
 
         if (token == RTAS_UNKNOWN_SERVICE) {
                 pr_notice("ibm,activate-firmware method unavailable\n");
                 return;
         }
 
         mutex_lock(&rtas_ibm_activate_firmware_lock);
 
         do {
                 fwrc = rtas_call(token, 0, 1, NULL);
         } while (rtas_busy_delay(fwrc));
 
         mutex_unlock(&rtas_ibm_activate_firmware_lock);
 
         if (fwrc)
                 pr_err("ibm,activate-firmware failed (%i)\n", fwrc);
 }
 
 /**
  * get_pseries_errorlog() - Find a specific pseries error log in an RTAS
  *                          extended event log.
  * @log: RTAS error/event log
  * @section_id: two character section identifier
  *
  * Return: A pointer to the specified errorlog or NULL if not found.
  */
 noinstr struct pseries_errorlog *get_pseries_errorlog(struct rtas_error_log *log,
                                                       uint16_t section_id)
 {
         struct rtas_ext_event_log_v6 *ext_log =
                 (struct rtas_ext_event_log_v6 *)log->buffer;
         struct pseries_errorlog *sect;
         unsigned char *p, *log_end;
         uint32_t ext_log_length = rtas_error_extended_log_length(log);
         uint8_t log_format = rtas_ext_event_log_format(ext_log);
         uint32_t company_id = rtas_ext_event_company_id(ext_log);
 
         /* Check that we understand the format */
         if (ext_log_length < sizeof(struct rtas_ext_event_log_v6) ||
             log_format != RTAS_V6EXT_LOG_FORMAT_EVENT_LOG ||
             company_id != RTAS_V6EXT_COMPANY_ID_IBM)
                 return NULL;
 
         log_end = log->buffer + ext_log_length;
         p = ext_log->vendor_log;
 
         while (p < log_end) {
                 sect = (struct pseries_errorlog *)p;
                 if (pseries_errorlog_id(sect) == section_id)
                         return sect;
                 p += pseries_errorlog_length(sect);
         }
 
         return NULL;
 }
 
 /*
  * The sys_rtas syscall, as originally designed, allows root to pass
  * arbitrary physical addresses to RTAS calls. A number of RTAS calls
  * can be abused to write to arbitrary memory and do other things that
  * are potentially harmful to system integrity, and thus should only
  * be used inside the kernel and not exposed to userspace.
  *
  * All known legitimate users of the sys_rtas syscall will only ever
  * pass addresses that fall within the RMO buffer, and use a known
  * subset of RTAS calls.
  *
  * Accordingly, we filter RTAS requests to check that the call is
  * permitted, and that provided pointers fall within the RMO buffer.
  * If a function is allowed to be invoked via the syscall, then its
  * entry in the rtas_functions table points to a rtas_filter that
  * describes its constraints, with the indexes of the parameters which
  * are expected to contain addresses and sizes of buffers allocated
  * inside the RMO buffer.
  */
 
 static bool in_rmo_buf(u32 base, u32 end)
 {
         return base >= rtas_rmo_buf &&
                 base < (rtas_rmo_buf + RTAS_USER_REGION_SIZE) &&
                 base <= end &&
                 end >= rtas_rmo_buf &&
                 end < (rtas_rmo_buf + RTAS_USER_REGION_SIZE);
 }
 
 static bool block_rtas_call(const struct rtas_function *func, int nargs,
                             struct rtas_args *args)
 {
         const struct rtas_filter *f;
         const bool is_platform_dump =
                 func == &rtas_function_table[RTAS_FNIDX__IBM_PLATFORM_DUMP];
         const bool is_config_conn =
                 func == &rtas_function_table[RTAS_FNIDX__IBM_CONFIGURE_CONNECTOR];
         u32 base, size, end;
 
         /*
          * Only functions with filters attached are allowed.
          */
         f = func->filter;
         if (!f)
                 goto err;
         /*
          * And some functions aren't allowed on LE.
          */
         if (IS_ENABLED(CONFIG_CPU_LITTLE_ENDIAN) && func->banned_for_syscall_on_le)
                 goto err;
 
         if (f->buf_idx1 != -1) {
                 base = be32_to_cpu(args->args[f->buf_idx1]);
                 if (f->size_idx1 != -1)
                         size = be32_to_cpu(args->args[f->size_idx1]);
                 else if (f->fixed_size)
                         size = f->fixed_size;
                 else
                         size = 1;
 
                 end = base + size - 1;
 
                 /*
                  * Special case for ibm,platform-dump - NULL buffer
                  * address is used to indicate end of dump processing
                  */
                 if (is_platform_dump && base == 0)
                         return false;
 
                 if (!in_rmo_buf(base, end))
                         goto err;
         }
 
         if (f->buf_idx2 != -1) {
                 base = be32_to_cpu(args->args[f->buf_idx2]);
                 if (f->size_idx2 != -1)
                         size = be32_to_cpu(args->args[f->size_idx2]);
                 else if (f->fixed_size)
                         size = f->fixed_size;
                 else
                         size = 1;
                 end = base + size - 1;
 
                 /*
                  * Special case for ibm,configure-connector where the
                  * address can be 0
                  */
                 if (is_config_conn && base == 0)
                         return false;
 
                 if (!in_rmo_buf(base, end))
                         goto err;
         }
 
         return false;
 err:
         pr_err_ratelimited("sys_rtas: RTAS call blocked - exploit attempt?\n");
         pr_err_ratelimited("sys_rtas: %s nargs=%d (called by %s)\n",
                            func->name, nargs, current->comm);
         return true;
 }
 
 /* We assume to be passed big endian arguments */
 SYSCALL_DEFINE1(rtas, struct rtas_args __user *, uargs)
 {
         const struct rtas_function *func;
         struct pin_cookie cookie;
         struct rtas_args args;
         unsigned long flags;
         char *buff_copy, *errbuf = NULL;
         int nargs, nret, token;
 
         if (!capable(CAP_SYS_ADMIN))
                 return -EPERM;
 
         if (!rtas.entry)
                 return -EINVAL;
 
         if (copy_from_user(&args, uargs, 3 * sizeof(u32)) != 0)
                 return -EFAULT;
 
         nargs = be32_to_cpu(args.nargs);
         nret  = be32_to_cpu(args.nret);
         token = be32_to_cpu(args.token);
 
         if (nargs >= ARRAY_SIZE(args.args)
             || nret > ARRAY_SIZE(args.args)
             || nargs + nret > ARRAY_SIZE(args.args))
                 return -EINVAL;
 
         nargs = array_index_nospec(nargs, ARRAY_SIZE(args.args));
         nret = array_index_nospec(nret, ARRAY_SIZE(args.args) - nargs);
 
         /* Copy in args. */
         if (copy_from_user(args.args, uargs->args,
                            nargs * sizeof(rtas_arg_t)) != 0)
                 return -EFAULT;
 
         /*
          * If this token doesn't correspond to a function the kernel
          * understands, you're not allowed to call it.
          */
         func = rtas_token_to_function_untrusted(token);
         if (!func)
                 return -EINVAL;
 
         args.rets = &args.args[nargs];
         memset(args.rets, 0, nret * sizeof(rtas_arg_t));
 
         if (block_rtas_call(func, nargs, &args))
                 return -EINVAL;
 
         if (token_is_restricted_errinjct(token)) {
                 int err;
 
                 err = security_locked_down(LOCKDOWN_RTAS_ERROR_INJECTION);
                 if (err)
                         return err;
         }
 
         /* Need to handle ibm,suspend_me call specially */
         if (token == rtas_function_token(RTAS_FN_IBM_SUSPEND_ME)) {
 
                 /*
                  * rtas_ibm_suspend_me assumes the streamid handle is in cpu
                  * endian, or at least the hcall within it requires it.
                  */
                 int rc = 0;
                 u64 handle = ((u64)be32_to_cpu(args.args[0]) << 32)
                               | be32_to_cpu(args.args[1]);
                 rc = rtas_syscall_dispatch_ibm_suspend_me(handle);
                 if (rc == -EAGAIN)
                         args.rets[0] = cpu_to_be32(RTAS_NOT_SUSPENDABLE);
                 else if (rc == -EIO)
                         args.rets[0] = cpu_to_be32(-1);
                 else if (rc)
                         return rc;
                 goto copy_return;
         }
 
         buff_copy = get_errorlog_buffer();
 
         /*
          * If this function has a mutex assigned to it, we must
          * acquire it to avoid interleaving with any kernel-based uses
          * of the same function. Kernel-based sequences acquire the
          * appropriate mutex explicitly.
          */
         if (func->lock)
                 mutex_lock(func->lock);
 
         raw_spin_lock_irqsave(&rtas_lock, flags);
         cookie = lockdep_pin_lock(&rtas_lock);
 
         rtas_args = args;
         do_enter_rtas(&rtas_args);
         args = rtas_args;
 
         /* A -1 return code indicates that the last command couldn't
            be completed due to a hardware error. */
         if (be32_to_cpu(args.rets[0]) == -1)
                 errbuf = __fetch_rtas_last_error(buff_copy);
 
         lockdep_unpin_lock(&rtas_lock, cookie);
         raw_spin_unlock_irqrestore(&rtas_lock, flags);
 
         if (func->lock)
                 mutex_unlock(func->lock);
 
         if (buff_copy) {
                 if (errbuf)
                         log_error(errbuf, ERR_TYPE_RTAS_LOG, 0);
                 kfree(buff_copy);
         }
 
  copy_return:
         /* Copy out args. */
         if (copy_to_user(uargs->args + nargs,
                          args.args + nargs,
                          nret * sizeof(rtas_arg_t)) != 0)
                 return -EFAULT;
 
         return 0;
 }
 
 static void __init rtas_function_table_init(void)
 {
         struct property *prop;
 
         for (size_t i = 0; i < ARRAY_SIZE(rtas_function_table); ++i) {
                 struct rtas_function *curr = &rtas_function_table[i];
                 struct rtas_function *prior;
                 int cmp;
 
                 curr->token = RTAS_UNKNOWN_SERVICE;
 
                 if (i == 0)
                         continue;
                 /*
                  * Ensure table is sorted correctly for binary search
                  * on function names.
                  */
                 prior = &rtas_function_table[i - 1];
 
                 cmp = strcmp(prior->name, curr->name);
                 if (cmp < 0)
                         continue;
 
                 if (cmp == 0) {
                         pr_err("'%s' has duplicate function table entries\n",
                                curr->name);
                 } else {
                         pr_err("function table unsorted: '%s' wrongly precedes '%s'\n",
                                prior->name, curr->name);
                 }
         }
 
         for_each_property_of_node(rtas.dev, prop) {
                 struct rtas_function *func;
 
                 if (prop->length != sizeof(u32))
                         continue;
 
                 func = __rtas_name_to_function(prop->name);
                 if (!func)
                         continue;
 
                 func->token = be32_to_cpup((__be32 *)prop->value);
 
                 pr_debug("function %s has token %u\n", func->name, func->token);
         }
 }
 
 /*
  * Call early during boot, before mem init, to retrieve the RTAS
  * information from the device-tree and allocate the RMO buffer for userland
  * accesses.
  */
 void __init rtas_initialize(void)
 {
         unsigned long rtas_region = RTAS_INSTANTIATE_MAX;
         u32 base, size, entry;
         int no_base, no_size, no_entry;
 
         /* Get RTAS dev node and fill up our "rtas" structure with infos
          * about it.
          */
         rtas.dev = of_find_node_by_name(NULL, "rtas");
         if (!rtas.dev)
                 return;
 
         no_base = of_property_read_u32(rtas.dev, "linux,rtas-base", &base);
         no_size = of_property_read_u32(rtas.dev, "rtas-size", &size);
         if (no_base || no_size) {
                 of_node_put(rtas.dev);
                 rtas.dev = NULL;
                 return;
         }
 
         rtas.base = base;
         rtas.size = size;
         no_entry = of_property_read_u32(rtas.dev, "linux,rtas-entry", &entry);
         rtas.entry = no_entry ? rtas.base : entry;
 
         init_error_log_max();
 
         /* Must be called before any function token lookups */
         rtas_function_table_init();
 
         /*
          * Discover this now to avoid a device tree lookup in the
          * panic path.
          */
         ibm_extended_os_term = of_property_read_bool(rtas.dev, "ibm,extended-os-term");
 
         /* If RTAS was found, allocate the RMO buffer for it and look for
          * the stop-self token if any
          */
 #ifdef CONFIG_PPC64
         if (firmware_has_feature(FW_FEATURE_LPAR))
                 rtas_region = min(ppc64_rma_size, RTAS_INSTANTIATE_MAX);
 #endif
         rtas_rmo_buf = memblock_phys_alloc_range(RTAS_USER_REGION_SIZE, PAGE_SIZE,
                                                  0, rtas_region);
         if (!rtas_rmo_buf)
                 panic("ERROR: RTAS: Failed to allocate %lx bytes below %pa\n",
                       PAGE_SIZE, &rtas_region);
 
         rtas_work_area_reserve_arena(rtas_region);
 }
 
 int __init early_init_dt_scan_rtas(unsigned long node,
                 const char *uname, int depth, void *data)
 {
         const u32 *basep, *entryp, *sizep;
 
         if (depth != 1 || strcmp(uname, "rtas") != 0)
                 return 0;
 
         basep  = of_get_flat_dt_prop(node, "linux,rtas-base", NULL);
         entryp = of_get_flat_dt_prop(node, "linux,rtas-entry", NULL);
         sizep  = of_get_flat_dt_prop(node, "rtas-size", NULL);
 
 #ifdef CONFIG_PPC64
         /* need this feature to decide the crashkernel offset */
         if (of_get_flat_dt_prop(node, "ibm,hypertas-functions", NULL))
                 powerpc_firmware_features |= FW_FEATURE_LPAR;
 #endif
 
         if (basep && entryp && sizep) {
                 rtas.base = *basep;
                 rtas.entry = *entryp;
                 rtas.size = *sizep;
         }
 
 #ifdef CONFIG_UDBG_RTAS_CONSOLE
         basep = of_get_flat_dt_prop(node, "put-term-char", NULL);
         if (basep)
                 rtas_putchar_token = *basep;
 
         basep = of_get_flat_dt_prop(node, "get-term-char", NULL);
         if (basep)
                 rtas_getchar_token = *basep;
 
         if (rtas_putchar_token != RTAS_UNKNOWN_SERVICE &&
             rtas_getchar_token != RTAS_UNKNOWN_SERVICE)
                 udbg_init_rtas_console();
 
 #endif
 
         /* break now */
         return 1;
 }
 
 static DEFINE_RAW_SPINLOCK(timebase_lock);
 static u64 timebase = 0;
 
 void rtas_give_timebase(void)
 {
         unsigned long flags;
 
         raw_spin_lock_irqsave(&timebase_lock, flags);
         hard_irq_disable();
         rtas_call(rtas_function_token(RTAS_FN_FREEZE_TIME_BASE), 0, 1, NULL);
         timebase = get_tb();
         raw_spin_unlock(&timebase_lock);
 
         while (timebase)
                 barrier();
         rtas_call(rtas_function_token(RTAS_FN_THAW_TIME_BASE), 0, 1, NULL);
         local_irq_restore(flags);
 }
 
 void rtas_take_timebase(void)
 {
         while (!timebase)
                 barrier();
         raw_spin_lock(&timebase_lock);
         set_tb(timebase >> 32, timebase & 0xffffffff);
         timebase = 0;
         raw_spin_unlock(&timebase_lock);
 }
 

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