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4022 4023 4024 4025 4026 4027 4028 4029 4030 4031 4032 4033 4034 4035 4036 4037 4038 4039 4040 4041 4042 4043 4044 4045 4046 4047 4048 4049 4050 4051 4052 4053 4054 4055 4056 4057 4058 4059 4060 4061 4062 4063 4064 4065 4066 4067 4068 4069 4070 4071 4072 4073 4074 4075 4076 4077 4078 4079 4080 4081 4082 4083 4084 4085 4086 4087 4088 4089 4090 4091 4092 4093 4094 4095 4096 4097 4098 4099 4100 4101 4102 | /* * Copyright (c) 2007-2020 Apple Inc. All rights reserved. * * @APPLE_LICENSE_HEADER_START@ * * This file contains Original Code and/or Modifications of Original Code * as defined in and that are subject to the Apple Public Source License * Version 2.0 (the 'License'). You may not use this file except in * compliance with the License. Please obtain a copy of the License at * http://www.opensource.apple.com/apsl/ and read it before using this * file. * * The Original Code and all software distributed under the License are * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES, * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT. * Please see the License for the specific language governing rights and * limitations under the License. * * @APPLE_LICENSE_HEADER_END@ */ /* * Shared region (... and comm page) * * This file handles the VM shared region and comm page. * */ /* * COMM PAGE * * A "comm page" is an area of memory that is populated by the kernel with * the appropriate platform-specific version of some commonly used code. * There is one "comm page" per platform (cpu-type, 64-bitness) but only * for the native cpu-type. No need to overly optimize translated code * for hardware that is not really there ! * * The comm pages are created and populated at boot time. * * The appropriate comm page is mapped into a process's address space * at exec() time, in vm_map_exec(). It is then inherited on fork(). * * The comm page is shared between the kernel and all applications of * a given platform. Only the kernel can modify it. * * Applications just branch to fixed addresses in the comm page and find * the right version of the code for the platform. There is also some * data provided and updated by the kernel for processes to retrieve easily * without having to do a system call. */ #include <debug.h> #include <kern/ipc_tt.h> #include <kern/kalloc.h> #include <kern/thread_call.h> #include <mach/mach_vm.h> #include <mach/machine.h> #include <vm/vm_map_internal.h> #include <vm/vm_map_lock_internal.h> #include <vm/vm_memory_entry_xnu.h> #include <vm/vm_shared_region_internal.h> #include <vm/vm_kern_xnu.h> #include <vm/memory_object_internal.h> #include <vm/vm_protos_internal.h> #include <vm/vm_object_internal.h> #include <machine/commpage.h> #include <machine/cpu_capabilities.h> #include <sys/random.h> #include <sys/errno.h> #include <sys/code_signing.h> #if defined(__arm64__) #include <arm/cpu_data_internal.h> #include <arm/misc_protos.h> #endif /* * the following codes are used in the subclass * of the DBG_MACH_SHAREDREGION class */ #define PROCESS_SHARED_CACHE_LAYOUT 0x00 #if __has_feature(ptrauth_calls) #include <ptrauth.h> #endif /* __has_feature(ptrauth_calls) */ /* "dyld" uses this to figure out what the kernel supports */ int shared_region_version = 3; /* trace level, output is sent to the system log file */ int shared_region_trace_level = SHARED_REGION_TRACE_ERROR_LVL; /* should local (non-chroot) shared regions persist when no task uses them ? */ int shared_region_persistence = 0; /* no by default */ /* delay in seconds before reclaiming an unused shared region */ TUNABLE_WRITEABLE(int, shared_region_destroy_delay, "vm_shared_region_destroy_delay", 120); #if DEVELOPMENT || DEBUG #define PANIC_ON_DYLD_ISSUE_DEFAULT 0 #else /* DEVELOPMENT || DEBUG */ #define PANIC_ON_DYLD_ISSUE_DEFAULT 0 #endif /* DEVELOPMENT || DEBUG */ TUNABLE_WRITEABLE(int, panic_on_dyld_issue, "panic_on_dyld_issue", PANIC_ON_DYLD_ISSUE_DEFAULT); /* * Cached pointer to the most recently mapped shared region from PID 1, which should * be the most commonly mapped shared region in the system. There are many processes * which do not use this, for a variety of reasons. * * The main consumer of this is stackshot. */ struct vm_shared_region *primary_system_shared_region = NULL; #if XNU_TARGET_OS_OSX /* * Only one cache gets to slide on Desktop, since we can't * tear down slide info properly today and the desktop actually * produces lots of shared caches. */ boolean_t shared_region_completed_slide = FALSE; #endif /* XNU_TARGET_OS_OSX */ /* this lock protects all the shared region data structures */ static LCK_GRP_DECLARE(vm_shared_region_lck_grp, "vm shared region"); static LCK_MTX_DECLARE(vm_shared_region_lock, &vm_shared_region_lck_grp); #define vm_shared_region_lock() lck_mtx_lock(&vm_shared_region_lock) #define vm_shared_region_unlock() lck_mtx_unlock(&vm_shared_region_lock) #define vm_shared_region_sleep(event, interruptible) \ lck_mtx_sleep_with_inheritor(&vm_shared_region_lock, \ LCK_SLEEP_DEFAULT, \ (event_t) (event), \ *(event), \ (interruptible) | THREAD_WAIT_NOREPORT, \ TIMEOUT_WAIT_FOREVER) #define vm_shared_region_wakeup(event) \ wakeup_all_with_inheritor((event), THREAD_AWAKENED) /* the list of currently available shared regions (one per environment) */ queue_head_t vm_shared_region_queue = QUEUE_HEAD_INITIALIZER(vm_shared_region_queue); int vm_shared_region_count = 0; int vm_shared_region_peak = 0; static uint32_t vm_shared_region_lastid = 0; /* for sr_id field */ /* * the number of times an event has forced the recalculation of the reslide * shared region slide. */ #if __has_feature(ptrauth_calls) int vm_shared_region_reslide_count = 0; #endif /* __has_feature(ptrauth_calls) */ static void vm_shared_region_reference_locked(vm_shared_region_t shared_region); static vm_shared_region_t vm_shared_region_create( void *root_dir, cpu_type_t cputype, cpu_subtype_t cpu_subtype, boolean_t is_64bit, int target_page_shift, boolean_t reslide, boolean_t is_driverkit, uint32_t rsr_version); static void vm_shared_region_destroy(vm_shared_region_t shared_region); static kern_return_t vm_shared_region_slide_sanity_check(vm_shared_region_slide_info_entry_t entry, mach_vm_size_t size); static void vm_shared_region_timeout(thread_call_param_t param0, thread_call_param_t param1); static kern_return_t vm_shared_region_slide_mapping( vm_shared_region_t sr, user_addr_t slide_info_addr, mach_vm_size_t slide_info_size, mach_vm_offset_t start, mach_vm_size_t size, mach_vm_offset_t slid_mapping, uint32_t slide, memory_object_control_t, vm_prot_t prot); /* forward */ static kern_return_t vm_shared_region_insert_placeholder(vm_map_t map, vm_shared_region_t shared_region); static kern_return_t vm_shared_region_insert_submap(vm_map_t map, vm_shared_region_t shared_region, bool overwrite); static int __commpage_setup = 0; #if XNU_TARGET_OS_OSX static int __system_power_source = 1; /* init to extrnal power source */ static void post_sys_powersource_internal(int i, int internal); #endif /* XNU_TARGET_OS_OSX */ extern u_int32_t random(void); /* * Retrieve a task's shared region and grab an extra reference to * make sure it doesn't disappear while the caller is using it. * The caller is responsible for consuming that extra reference if * necessary. */ vm_shared_region_t vm_shared_region_get( task_t task) { vm_shared_region_t shared_region; SHARED_REGION_TRACE_DEBUG( ("shared_region: -> get(%p)\n", (void *)VM_KERNEL_ADDRPERM(task))); task_lock(task); vm_shared_region_lock(); shared_region = task->shared_region; if (shared_region != NULL) { assert(shared_region->sr_ref_count > 0); vm_shared_region_reference_locked(shared_region); } vm_shared_region_unlock(); task_unlock(task); SHARED_REGION_TRACE_DEBUG( ("shared_region: get(%p) <- %p\n", (void *)VM_KERNEL_ADDRPERM(task), (void *)VM_KERNEL_ADDRPERM(shared_region))); return shared_region; } static void vm_shared_region_acquire(vm_shared_region_t shared_region) { vm_shared_region_lock(); assert(shared_region->sr_ref_count > 0); while (shared_region->sr_mapping_in_progress != NULL) { /* wait for our turn... */ vm_shared_region_sleep(&shared_region->sr_mapping_in_progress, THREAD_UNINT); } assert(shared_region->sr_mapping_in_progress == NULL); assert(shared_region->sr_ref_count > 0); /* let others know to wait while we're working in this shared region */ shared_region->sr_mapping_in_progress = current_thread(); vm_shared_region_unlock(); } static void vm_shared_region_release(vm_shared_region_t shared_region) { vm_shared_region_lock(); assert(shared_region->sr_mapping_in_progress == current_thread()); shared_region->sr_mapping_in_progress = THREAD_NULL; vm_shared_region_wakeup((event_t) &shared_region->sr_mapping_in_progress); vm_shared_region_unlock(); } static void vm_shared_region_seal( struct vm_shared_region *sr) { vm_map_t sr_map; sr_map = vm_shared_region_vm_map(sr); vm_map_seal(sr_map, true /* nested_pmap */); } vm_map_t vm_shared_region_vm_map( vm_shared_region_t shared_region) { ipc_port_t sr_handle; vm_named_entry_t sr_mem_entry; vm_map_t sr_map; SHARED_REGION_TRACE_DEBUG( ("shared_region: -> vm_map(%p)\n", (void *)VM_KERNEL_ADDRPERM(shared_region))); assert(shared_region->sr_ref_count > 0); sr_handle = shared_region->sr_mem_entry; sr_mem_entry = mach_memory_entry_from_port(sr_handle); sr_map = sr_mem_entry->backing.map; assert(sr_mem_entry->is_sub_map); SHARED_REGION_TRACE_DEBUG( ("shared_region: vm_map(%p) <- %p\n", (void *)VM_KERNEL_ADDRPERM(shared_region), (void *)VM_KERNEL_ADDRPERM(sr_map))); return sr_map; } /* * Set the shared region the process should use. * A NULL new shared region means that we just want to release the old * shared region. * The caller should already have an extra reference on the new shared region * (if any). We release a reference on the old shared region (if any). */ void vm_shared_region_set( task_t task, vm_shared_region_t new_shared_region) { vm_shared_region_t old_shared_region; SHARED_REGION_TRACE_DEBUG( ("shared_region: -> set(%p, %p)\n", (void *)VM_KERNEL_ADDRPERM(task), (void *)VM_KERNEL_ADDRPERM(new_shared_region))); task_lock(task); vm_shared_region_lock(); old_shared_region = task->shared_region; if (new_shared_region) { assert(new_shared_region->sr_ref_count > 0); } task->shared_region = new_shared_region; vm_shared_region_unlock(); task_unlock(task); if (old_shared_region) { assert(old_shared_region->sr_ref_count > 0); vm_shared_region_deallocate(old_shared_region); } SHARED_REGION_TRACE_DEBUG( ("shared_region: set(%p) <- old=%p new=%p\n", (void *)VM_KERNEL_ADDRPERM(task), (void *)VM_KERNEL_ADDRPERM(old_shared_region), (void *)VM_KERNEL_ADDRPERM(new_shared_region))); } /* * New arm64 shared regions match with an existing arm64e region. * They just get a private non-authenticating pager. */ static inline bool match_subtype(cpu_type_t cputype, cpu_subtype_t exist, cpu_subtype_t new) { if (exist == new) { return true; } if (cputype == CPU_TYPE_ARM64 && exist == CPU_SUBTYPE_ARM64E && new == CPU_SUBTYPE_ARM64_ALL) { return true; } return false; } /* * Lookup up the shared region for the desired environment. * If none is found, create a new (empty) one. * Grab an extra reference on the returned shared region, to make sure * it doesn't get destroyed before the caller is done with it. The caller * is responsible for consuming that extra reference if necessary. */ vm_shared_region_t vm_shared_region_lookup( void *root_dir, cpu_type_t cputype, cpu_subtype_t cpu_subtype, boolean_t is_64bit, int target_page_shift, boolean_t reslide, boolean_t is_driverkit, uint32_t rsr_version) { vm_shared_region_t shared_region; vm_shared_region_t new_shared_region; SHARED_REGION_TRACE_DEBUG( ("shared_region: -> lookup(root=%p,cpu=<%d,%d>,64bit=%d,pgshift=%d,reslide=%d,driverkit=%d)\n", (void *)VM_KERNEL_ADDRPERM(root_dir), cputype, cpu_subtype, is_64bit, target_page_shift, reslide, is_driverkit)); shared_region = NULL; new_shared_region = NULL; vm_shared_region_lock(); for (;;) { queue_iterate(&vm_shared_region_queue, shared_region, vm_shared_region_t, sr_q) { assert(shared_region->sr_ref_count > 0); if (shared_region->sr_cpu_type == cputype && match_subtype(cputype, shared_region->sr_cpu_subtype, cpu_subtype) && shared_region->sr_root_dir == root_dir && shared_region->sr_64bit == is_64bit && #if __ARM_MIXED_PAGE_SIZE__ shared_region->sr_page_shift == target_page_shift && #endif /* __ARM_MIXED_PAGE_SIZE__ */ #if __has_feature(ptrauth_calls) shared_region->sr_reslide == reslide && #endif /* __has_feature(ptrauth_calls) */ shared_region->sr_driverkit == is_driverkit && shared_region->sr_rsr_version == rsr_version && !shared_region->sr_stale) { /* found a match ! */ vm_shared_region_reference_locked(shared_region); goto done; } } if (new_shared_region == NULL) { /* no match: create a new one */ vm_shared_region_unlock(); new_shared_region = vm_shared_region_create(root_dir, cputype, cpu_subtype, is_64bit, target_page_shift, reslide, is_driverkit, rsr_version); /* do the lookup again, in case we lost a race */ vm_shared_region_lock(); continue; } /* still no match: use our new one */ shared_region = new_shared_region; new_shared_region = NULL; uint32_t newid = ++vm_shared_region_lastid; if (newid == 0) { panic("shared_region: vm_shared_region_lastid wrapped"); } shared_region->sr_id = newid; shared_region->sr_install_time = mach_absolute_time(); queue_enter(&vm_shared_region_queue, shared_region, vm_shared_region_t, sr_q); vm_shared_region_count++; if (vm_shared_region_count > vm_shared_region_peak) { vm_shared_region_peak = vm_shared_region_count; } break; } done: vm_shared_region_unlock(); if (new_shared_region) { /* * We lost a race with someone else to create a new shared * region for that environment. Get rid of our unused one. */ assert(new_shared_region->sr_ref_count == 1); new_shared_region->sr_ref_count--; vm_shared_region_destroy(new_shared_region); new_shared_region = NULL; } SHARED_REGION_TRACE_DEBUG( ("shared_region: lookup(root=%p,cpu=<%d,%d>,64bit=%d,pgshift=%d,reslide=%d,driverkit=%d) <- %p\n", (void *)VM_KERNEL_ADDRPERM(root_dir), cputype, cpu_subtype, is_64bit, target_page_shift, reslide, is_driverkit, (void *)VM_KERNEL_ADDRPERM(shared_region))); assert(shared_region->sr_ref_count > 0); return shared_region; } /* * Take an extra reference on a shared region. * The vm_shared_region_lock should already be held by the caller. */ static void vm_shared_region_reference_locked( vm_shared_region_t shared_region) { LCK_MTX_ASSERT(&vm_shared_region_lock, LCK_MTX_ASSERT_OWNED); SHARED_REGION_TRACE_DEBUG( ("shared_region: -> reference_locked(%p)\n", (void *)VM_KERNEL_ADDRPERM(shared_region))); assert(shared_region->sr_ref_count > 0); shared_region->sr_ref_count++; assert(shared_region->sr_ref_count != 0); if (shared_region->sr_timer_call != NULL) { boolean_t cancelled; /* cancel and free any pending timeout */ cancelled = thread_call_cancel(shared_region->sr_timer_call); if (cancelled) { thread_call_free(shared_region->sr_timer_call); shared_region->sr_timer_call = NULL; /* release the reference held by the cancelled timer */ shared_region->sr_ref_count--; } else { /* the timer will drop the reference and free itself */ } } SHARED_REGION_TRACE_DEBUG( ("shared_region: reference_locked(%p) <- %d\n", (void *)VM_KERNEL_ADDRPERM(shared_region), shared_region->sr_ref_count)); } /* * Take a reference on a shared region. */ void vm_shared_region_reference(vm_shared_region_t shared_region) { SHARED_REGION_TRACE_DEBUG( ("shared_region: -> reference(%p)\n", (void *)VM_KERNEL_ADDRPERM(shared_region))); vm_shared_region_lock(); vm_shared_region_reference_locked(shared_region); vm_shared_region_unlock(); SHARED_REGION_TRACE_DEBUG( ("shared_region: reference(%p) <- %d\n", (void *)VM_KERNEL_ADDRPERM(shared_region), shared_region->sr_ref_count)); } /* * Release a reference on the shared region. * Destroy it if there are no references left. */ void vm_shared_region_deallocate( vm_shared_region_t shared_region) { SHARED_REGION_TRACE_DEBUG( ("shared_region: -> deallocate(%p)\n", (void *)VM_KERNEL_ADDRPERM(shared_region))); vm_shared_region_lock(); assert(shared_region->sr_ref_count > 0); if (shared_region->sr_root_dir == NULL) { /* * Local (i.e. based on the boot volume) shared regions * can persist or not based on the "shared_region_persistence" * sysctl. * Make sure that this one complies. * * See comments in vm_shared_region_slide() for notes about * shared regions we have slid (which are not torn down currently). */ if (shared_region_persistence && !shared_region->sr_persists) { /* make this one persistent */ shared_region->sr_ref_count++; shared_region->sr_persists = TRUE; } else if (!shared_region_persistence && shared_region->sr_persists) { /* make this one no longer persistent */ assert(shared_region->sr_ref_count > 1); shared_region->sr_ref_count--; shared_region->sr_persists = FALSE; } } assert(shared_region->sr_ref_count > 0); shared_region->sr_ref_count--; SHARED_REGION_TRACE_DEBUG( ("shared_region: deallocate(%p): ref now %d\n", (void *)VM_KERNEL_ADDRPERM(shared_region), shared_region->sr_ref_count)); if (shared_region->sr_ref_count == 0) { uint64_t deadline; /* * Even though a shared region is unused, delay a while before * tearing it down, in case a new app launch can use it. * We don't keep around stale shared regions, nor older RSR ones. */ if (shared_region->sr_timer_call == NULL && shared_region_destroy_delay != 0 && !shared_region->sr_stale && !(shared_region->sr_rsr_version != 0 && shared_region->sr_rsr_version != rsr_get_version())) { /* hold one reference for the timer */ assert(!shared_region->sr_mapping_in_progress); shared_region->sr_ref_count++; /* set up the timer */ shared_region->sr_timer_call = thread_call_allocate( (thread_call_func_t) vm_shared_region_timeout, (thread_call_param_t) shared_region); /* schedule the timer */ clock_interval_to_deadline(shared_region_destroy_delay, NSEC_PER_SEC, &deadline); thread_call_enter_delayed(shared_region->sr_timer_call, deadline); SHARED_REGION_TRACE_DEBUG( ("shared_region: deallocate(%p): armed timer\n", (void *)VM_KERNEL_ADDRPERM(shared_region))); vm_shared_region_unlock(); } else { /* timer expired: let go of this shared region */ /* Make sure there's no cached pointer to the region. */ if (primary_system_shared_region == shared_region) { primary_system_shared_region = NULL; } /* * Remove it from the queue first, so no one can find * it... */ queue_remove(&vm_shared_region_queue, shared_region, vm_shared_region_t, sr_q); vm_shared_region_count--; vm_shared_region_unlock(); /* ... and destroy it */ vm_shared_region_destroy(shared_region); shared_region = NULL; } } else { vm_shared_region_unlock(); } SHARED_REGION_TRACE_DEBUG( ("shared_region: deallocate(%p) <-\n", (void *)VM_KERNEL_ADDRPERM(shared_region))); } void vm_shared_region_timeout( thread_call_param_t param0, __unused thread_call_param_t param1) { vm_shared_region_t shared_region; shared_region = (vm_shared_region_t) param0; vm_shared_region_deallocate(shared_region); } /* * Create a new (empty) shared region for a new environment. */ static vm_shared_region_t vm_shared_region_create( void *root_dir, cpu_type_t cputype, cpu_subtype_t cpu_subtype, boolean_t is_64bit, int target_page_shift, #if !__has_feature(ptrauth_calls) __unused #endif /* __has_feature(ptrauth_calls) */ boolean_t reslide, boolean_t is_driverkit, uint32_t rsr_version) { vm_named_entry_t mem_entry; ipc_port_t mem_entry_port; vm_shared_region_t shared_region; vm_map_t sub_map, config_map; pmap_t nested_pmap, config_pmap; mach_vm_offset_t base_address, pmap_nesting_start; mach_vm_size_t size, pmap_nesting_size; SHARED_REGION_TRACE_INFO( ("shared_region: -> create(root=%p,cpu=<%d,%d>,64bit=%d,pgshift=%d,reslide=%d,driverkit=%d)\n", (void *)VM_KERNEL_ADDRPERM(root_dir), cputype, cpu_subtype, is_64bit, target_page_shift, reslide, is_driverkit)); base_address = 0; size = 0; mem_entry = NULL; mem_entry_port = IPC_PORT_NULL; sub_map = VM_MAP_NULL; config_map = VM_MAP_NULL; nested_pmap = PMAP_NULL; config_pmap = PMAP_NULL; /* create a new shared region structure... */ shared_region = kalloc_type(struct vm_shared_region, Z_WAITOK | Z_NOFAIL); /* figure out the correct settings for the desired environment */ if (is_64bit) { switch (cputype) { #if defined(__arm64__) case CPU_TYPE_ARM64: base_address = SHARED_REGION_BASE_ARM64; size = SHARED_REGION_SIZE_ARM64; pmap_nesting_start = SHARED_REGION_NESTING_BASE_ARM64; pmap_nesting_size = SHARED_REGION_NESTING_SIZE_ARM64; break; #else case CPU_TYPE_I386: base_address = SHARED_REGION_BASE_X86_64; size = SHARED_REGION_SIZE_X86_64; pmap_nesting_start = SHARED_REGION_NESTING_BASE_X86_64; pmap_nesting_size = SHARED_REGION_NESTING_SIZE_X86_64; break; case CPU_TYPE_POWERPC: base_address = SHARED_REGION_BASE_PPC64; size = SHARED_REGION_SIZE_PPC64; pmap_nesting_start = SHARED_REGION_NESTING_BASE_PPC64; pmap_nesting_size = SHARED_REGION_NESTING_SIZE_PPC64; break; #endif default: SHARED_REGION_TRACE_ERROR( ("shared_region: create: unknown cpu type %d\n", cputype)); kfree_type(struct vm_shared_region, shared_region); shared_region = NULL; goto done; } } else { switch (cputype) { #if defined(__arm64__) case CPU_TYPE_ARM: base_address = SHARED_REGION_BASE_ARM; size = SHARED_REGION_SIZE_ARM; pmap_nesting_start = SHARED_REGION_NESTING_BASE_ARM; pmap_nesting_size = SHARED_REGION_NESTING_SIZE_ARM; break; #else case CPU_TYPE_I386: base_address = SHARED_REGION_BASE_I386; size = SHARED_REGION_SIZE_I386; pmap_nesting_start = SHARED_REGION_NESTING_BASE_I386; pmap_nesting_size = SHARED_REGION_NESTING_SIZE_I386; break; case CPU_TYPE_POWERPC: base_address = SHARED_REGION_BASE_PPC; size = SHARED_REGION_SIZE_PPC; pmap_nesting_start = SHARED_REGION_NESTING_BASE_PPC; pmap_nesting_size = SHARED_REGION_NESTING_SIZE_PPC; break; #endif default: SHARED_REGION_TRACE_ERROR( ("shared_region: create: unknown cpu type %d\n", cputype)); kfree_type(struct vm_shared_region, shared_region); shared_region = NULL; goto done; } } /* create a memory entry structure and a Mach port handle */ mem_entry = mach_memory_entry_allocate(&mem_entry_port); #if defined(__arm64__) { int pmap_flags = 0; pmap_flags |= is_64bit ? PMAP_CREATE_64BIT : 0; #if __ARM_MIXED_PAGE_SIZE__ if (cputype == CPU_TYPE_ARM64 && target_page_shift == FOURK_PAGE_SHIFT) { /* arm64/4k address space */ pmap_flags |= PMAP_CREATE_FORCE_4K_PAGES; } #endif /* __ARM_MIXED_PAGE_SIZE__ */ nested_pmap = pmap_create_options(NULL, 0, pmap_flags | PMAP_CREATE_NESTED); config_pmap = pmap_create_options(NULL, 0, pmap_flags); if ((nested_pmap != PMAP_NULL) && (config_pmap != PMAP_NULL)) { pmap_set_nested(nested_pmap); #if CODE_SIGNING_MONITOR csm_setup_nested_address_space(nested_pmap, base_address, size); #endif /* CODE_SIGNING_MONITOR */ int vm_map_pageshift = PAGE_SHIFT; if (is_64bit || page_shift_user32 == SIXTEENK_PAGE_SHIFT) { /* enforce 16KB alignment of VM map entries */ vm_map_pageshift = SIXTEENK_PAGE_SHIFT; } #if __ARM_MIXED_PAGE_SIZE__ if (cputype == CPU_TYPE_ARM64 && target_page_shift == FOURK_PAGE_SHIFT) { /* arm64/4k address space */ vm_map_pageshift = FOURK_PAGE_SHIFT; } #endif /* __ARM_MIXED_PAGE_SIZE__ */ pmap_set_shared_region(config_pmap, nested_pmap, base_address, size); sub_map = vm_map_create_with_page_shift(nested_pmap, 0, (vm_map_offset_t)size, vm_map_pageshift, VM_MAP_CREATE_DEFAULT); config_map = vm_map_create_with_page_shift(config_pmap, base_address, base_address + size, vm_map_pageshift, VM_MAP_CREATE_DEFAULT); } } #else /* defined(__arm64__) */ { /* create a VM sub map and its pmap */ nested_pmap = pmap_create_options(NULL, 0, is_64bit); config_pmap = pmap_create_options(NULL, 0, is_64bit); if ((nested_pmap != NULL) && (config_pmap != NULL)) { pmap_set_shared_region(config_pmap, nested_pmap, base_address, size); sub_map = vm_map_create_options(nested_pmap, 0, (vm_map_offset_t)size, VM_MAP_CREATE_DEFAULT); config_map = vm_map_create_options(config_pmap, base_address, base_address + size, VM_MAP_CREATE_DEFAULT); } } #endif /* defined(__arm64__) */ if (sub_map != VM_MAP_NULL) { nested_pmap = PMAP_NULL; } if (config_map != VM_MAP_NULL) { config_pmap = PMAP_NULL; } if (nested_pmap != PMAP_NULL) { pmap_destroy(nested_pmap); } if (config_pmap != PMAP_NULL) { pmap_destroy(config_pmap); } if ((sub_map == VM_MAP_NULL) || (config_map == VM_MAP_NULL)) { if (sub_map != VM_MAP_NULL) { vm_map_deallocate(sub_map); } if (config_map != VM_MAP_NULL) { vm_map_deallocate(config_map); } ipc_port_release_send(mem_entry_port); kfree_type(struct vm_shared_region, shared_region); shared_region = NULL; SHARED_REGION_TRACE_ERROR(("shared_region: create: couldn't allocate maps\n")); goto done; } /* shared regions should always enforce code-signing */ vm_map_cs_enforcement_set(sub_map, true); assert(vm_map_cs_enforcement(sub_map)); assert(pmap_get_vm_map_cs_enforced(vm_map_pmap(sub_map))); vm_map_cs_enforcement_set(config_map, true); assert(vm_map_cs_enforcement(config_map)); assert(pmap_get_vm_map_cs_enforced(vm_map_pmap(config_map))); assert(!sub_map->disable_vmentry_reuse); sub_map->is_nested_map = TRUE; sub_map->vmmap_sealed = VM_MAP_WILL_BE_SEALED; /* make the memory entry point to the VM sub map */ mem_entry->is_sub_map = TRUE; mem_entry->backing.map = sub_map; mem_entry->size = size; mem_entry->protection = VM_PROT_ALL; /* make the shared region point at the memory entry */ shared_region->sr_mem_entry = mem_entry_port; /* fill in the shared region's environment and settings */ shared_region->sr_config_map = config_map; shared_region->sr_base_address = base_address; shared_region->sr_size = size; shared_region->sr_pmap_nesting_start = pmap_nesting_start; shared_region->sr_pmap_nesting_size = pmap_nesting_size; shared_region->sr_cpu_type = cputype; shared_region->sr_cpu_subtype = cpu_subtype; shared_region->sr_64bit = (uint8_t)is_64bit; #if __ARM_MIXED_PAGE_SIZE__ shared_region->sr_page_shift = (uint8_t)target_page_shift; #endif /* __ARM_MIXED_PAGE_SIZE__ */ shared_region->sr_driverkit = (uint8_t)is_driverkit; shared_region->sr_rsr_version = rsr_version; shared_region->sr_root_dir = root_dir; queue_init(&shared_region->sr_q); shared_region->sr_mapping_in_progress = THREAD_NULL; shared_region->sr_slide_in_progress = THREAD_NULL; shared_region->sr_persists = FALSE; shared_region->sr_stale = FALSE; shared_region->sr_timer_call = NULL; shared_region->sr_first_mapping = (mach_vm_offset_t) -1; /* grab a reference for the caller */ shared_region->sr_ref_count = 1; shared_region->sr_slide = 0; /* not slid yet */ /* Initialize UUID and other metadata */ memset(&shared_region->sr_uuid, '\0', sizeof(shared_region->sr_uuid)); shared_region->sr_uuid_copied = FALSE; shared_region->sr_images_count = 0; shared_region->sr_images = NULL; #if __has_feature(ptrauth_calls) shared_region->sr_reslide = reslide; shared_region->sr_num_auth_section = 0; shared_region->sr_next_auth_section = 0; shared_region->sr_auth_section = NULL; #endif /* __has_feature(ptrauth_calls) */ kern_return_t kr = vm_shared_region_insert_submap(config_map, shared_region, false); if (kr != KERN_SUCCESS) { SHARED_REGION_TRACE_ERROR( ("shared_region: create(%p): insert_submap returned 0x%x\n", shared_region, kr)); shared_region->sr_ref_count = 0; vm_shared_region_destroy(shared_region); shared_region = NULL; } done: if (shared_region) { SHARED_REGION_TRACE_INFO( ("shared_region: create(root=%p,cpu=<%d,%d>,64bit=%d,reslide=%d,driverkit=%d," "base=0x%llx,size=0x%llx) <- " "%p mem=(%p,%p) map=%p pmap=%p\n", (void *)VM_KERNEL_ADDRPERM(root_dir), cputype, cpu_subtype, is_64bit, reslide, is_driverkit, (long long)base_address, (long long)size, (void *)VM_KERNEL_ADDRPERM(shared_region), (void *)VM_KERNEL_ADDRPERM(mem_entry_port), (void *)VM_KERNEL_ADDRPERM(mem_entry), (void *)VM_KERNEL_ADDRPERM(sub_map), (void *)VM_KERNEL_ADDRPERM(sub_map->pmap))); } else { SHARED_REGION_TRACE_INFO( ("shared_region: create(root=%p,cpu=<%d,%d>,64bit=%d,driverkit=%d," "base=0x%llx,size=0x%llx) <- NULL", (void *)VM_KERNEL_ADDRPERM(root_dir), cputype, cpu_subtype, is_64bit, is_driverkit, (long long)base_address, (long long)size)); } return shared_region; } /* * Destroy a now-unused shared region. * The shared region is no longer in the queue and can not be looked up. */ static void vm_shared_region_destroy( vm_shared_region_t shared_region) { vm_named_entry_t mem_entry; vm_map_t map; SHARED_REGION_TRACE_INFO( ("shared_region: -> destroy(%p) (root=%p,cpu=<%d,%d>,64bit=%d,driverkit=%d)\n", (void *)VM_KERNEL_ADDRPERM(shared_region), (void *)VM_KERNEL_ADDRPERM(shared_region->sr_root_dir), shared_region->sr_cpu_type, shared_region->sr_cpu_subtype, shared_region->sr_64bit, shared_region->sr_driverkit)); assert(shared_region->sr_ref_count == 0); assert(!shared_region->sr_persists); mem_entry = mach_memory_entry_from_port(shared_region->sr_mem_entry); assert(mem_entry->is_sub_map); assert(!mem_entry->internal); assert(!mem_entry->is_copy); if (shared_region->sr_config_map != VM_MAP_NULL) { vm_map_deallocate(shared_region->sr_config_map); shared_region->sr_config_map = VM_MAP_NULL; } map = mem_entry->backing.map; /* * Clean up the pmap first. The virtual addresses that were * entered in this possibly "nested" pmap may have different values * than the VM map's min and max offsets, if the VM sub map was * mapped at a non-zero offset in the processes' main VM maps, which * is usually the case, so the clean-up we do in vm_map_destroy() would * not be enough. */ if (map->pmap) { pmap_remove(map->pmap, (vm_map_offset_t)shared_region->sr_base_address, (vm_map_offset_t)(shared_region->sr_base_address + shared_region->sr_size)); } /* * Release our (one and only) handle on the memory entry. * This will generate a no-senders notification, which will be processed * by ipc_notify_no_senders_kobject(), which will release the one and only * reference on the memory entry and cause it to be destroyed, along * with the VM sub map and its pmap. */ mach_memory_entry_port_release(shared_region->sr_mem_entry); mem_entry = NULL; shared_region->sr_mem_entry = IPC_PORT_NULL; if (shared_region->sr_timer_call) { thread_call_free(shared_region->sr_timer_call); } #if __has_feature(ptrauth_calls) /* * Free the cached copies of slide_info for the AUTH regions. */ for (uint_t i = 0; i < shared_region->sr_num_auth_section; ++i) { vm_shared_region_slide_info_t si = shared_region->sr_auth_section[i]; if (si != NULL) { vm_object_deallocate(si->si_slide_object); kfree_data(si->si_slide_info_entry, si->si_slide_info_size); kfree_type(struct vm_shared_region_slide_info, si); shared_region->sr_auth_section[i] = NULL; } } if (shared_region->sr_auth_section != NULL) { assert(shared_region->sr_num_auth_section > 0); kfree_type(vm_shared_region_slide_info_t, shared_region->sr_num_auth_section, shared_region->sr_auth_section); shared_region->sr_auth_section = NULL; shared_region->sr_num_auth_section = 0; } #endif /* __has_feature(ptrauth_calls) */ /* release the shared region structure... */ kfree_type(struct vm_shared_region, shared_region); SHARED_REGION_TRACE_DEBUG( ("shared_region: destroy(%p) <-\n", (void *)VM_KERNEL_ADDRPERM(shared_region))); shared_region = NULL; } /* * Gets the address of the first (in time) mapping in the shared region. * If used during initial task setup by dyld, task should non-NULL. */ kern_return_t vm_shared_region_start_address( vm_shared_region_t shared_region, mach_vm_offset_t *start_address) { kern_return_t kr; mach_vm_offset_t sr_base_address; mach_vm_offset_t sr_first_mapping; SHARED_REGION_TRACE_DEBUG( ("shared_region: -> start_address(%p)\n", (void *)VM_KERNEL_ADDRPERM(shared_region))); vm_shared_region_lock(); /* * Wait if there's another thread establishing a mapping * in this shared region right when we're looking at it. * We want a consistent view of the map... */ while (shared_region->sr_mapping_in_progress != NULL) { /* wait for our turn... */ vm_shared_region_sleep(&shared_region->sr_mapping_in_progress, THREAD_UNINT); } assert(shared_region->sr_mapping_in_progress == NULL); assert(shared_region->sr_ref_count > 0); sr_base_address = shared_region->sr_base_address; sr_first_mapping = shared_region->sr_first_mapping; if (sr_first_mapping == (mach_vm_offset_t) -1) { /* shared region is empty */ kr = KERN_INVALID_ADDRESS; } else { kr = KERN_SUCCESS; *start_address = sr_base_address + sr_first_mapping; } vm_shared_region_unlock(); SHARED_REGION_TRACE_DEBUG( ("shared_region: start_address(%p) <- 0x%llx\n", (void *)VM_KERNEL_ADDRPERM(shared_region), (long long)shared_region->sr_base_address)); return kr; } kern_return_t vm_shared_region_update_task(task_t task, vm_shared_region_t shared_region, mach_vm_offset_t start_address) { kern_return_t kr = KERN_SUCCESS; uuid_t shared_region_uuid; _Static_assert(sizeof(shared_region_uuid) == sizeof(task->task_shared_region_uuid), "sizeof task_shared_region_uuid != sizeof uuid_t"); task_lock(task); if (task->task_shared_region_slide == -1) { assert(vm_map_is_sealed(vm_shared_region_vm_map(shared_region))); kr = vm_shared_region_insert_submap(task->map, shared_region, true); if (kr == KERN_SUCCESS) { task->task_shared_region_slide = shared_region->sr_slide; /* * Drop the task lock to avoid potential deadlock if copyin() faults. * With the lock dropped, another thread in the task could theoretically * call this function, observe task_shared_region_slide != -1, and * return before the UUID has been copied to the task, but in practice * dyld should only issue the shared_region_check_np() syscall that ends * up invoking this function exactly once, and while the task is still * single-threaded at that. */ task_unlock(task); /* * Now that shared region is accessible in the task's address space, * copyin the UUID for debugging/telemetry purposes. * copyin had better succeed here. We've already inserted the submap, * which can't be undone or re-done later. If the shared region header * isn't accessible at this point, we have big problems. */ const uint_t sc_header_uuid_offset = offsetof(struct _dyld_cache_header, uuid); if (copyin((user_addr_t)(start_address + sc_header_uuid_offset), (char *)&shared_region_uuid, sizeof(shared_region_uuid)) != 0) { SHARED_REGION_TRACE_ERROR( ("shared_region: update_task(%p) copyin failed\n", (void *)VM_KERNEL_ADDRPERM(shared_region))); } task_lock(task); memcpy(&task->task_shared_region_uuid, shared_region_uuid, sizeof(shared_region_uuid)); } } task_unlock(task); return kr; } /* * Look up a pre-existing mapping in shared region, for replacement. * Takes an extra object reference if found. */ __static_testable kern_return_t find_mapping_to_slide(vm_map_t map, vm_map_address_t addr, vm_map_entry_t entry) { vm_map_entry_t found_entry; /* * Verify that we don't need to lock entries here. * * If the map is a constant submap, we wouldn't lock the entries when * descended into it anyway. The range lock doesn't support being * called on a sealed submap directly, since it'll attempt to lock the * entries and panic. */ assert(vm_map_is_sealed_or_will_be_sealed(map)); vmlp_api_start(FIND_MAPPING_TO_SLIDE); found_entry = vm_map_lookup(map, addr); if (found_entry == VM_MAP_ENTRY_NULL) { vmlp_api_end(FIND_MAPPING_TO_SLIDE, kr); return KERN_INVALID_ADDRESS; } *entry = *found_entry; /* extra ref to keep object alive while map is unlocked */ vm_object_reference(VME_OBJECT(found_entry)); vmlp_api_end(FIND_MAPPING_TO_SLIDE, KERN_SUCCESS); return KERN_SUCCESS; } static bool shared_region_make_permanent( vm_shared_region_t sr, vm_prot_t max_prot) { if (sr->sr_cpu_type == CPU_TYPE_X86_64) { return false; } if (max_prot & VM_PROT_WRITE) { /* * Potentially writable mapping: no major issue with allowing * it to be replaced since its contents could be modified * anyway. */ return false; } if (max_prot & VM_PROT_EXECUTE) { /* * Potentially executable mapping: some software might want * to try and replace it to interpose their own code when a * given routine is called or returns, for example. * So let's not make it "permanent". */ return false; } /* * Make this mapping "permanent" to prevent it from being deleted * and/or replaced with another mapping. */ return true; } static bool shared_region_tpro_protect( vm_shared_region_t sr, vm_prot_t max_prot __unused) { if (sr->sr_cpu_type != CPU_TYPE_ARM64) { return false; } /* * Unless otherwise explicitly requested all other mappings do not get * TPRO protection. */ return false; } #if __has_feature(ptrauth_calls) /* * Determine if this task is actually using pointer signing. */ static boolean_t task_sign_pointers(task_t task) { if (task->map && task->map->pmap && !task->map->pmap->disable_jop) { return TRUE; } return FALSE; } /* * If the shared region contains mappings that are authenticated, then * remap them into the task private map. * * Failures are possible in this routine when jetsam kills a process * just as dyld is trying to set it up. The vm_map and task shared region * info get torn down w/o waiting for this thread to finish up. */ __attribute__((noinline)) kern_return_t vm_shared_region_auth_remap(vm_shared_region_t sr) { memory_object_t sr_pager = MEMORY_OBJECT_NULL; task_t task = current_task(); vm_shared_region_slide_info_t si; uint_t i; vm_object_t object; vm_map_t sr_map; struct vm_map_entry tmp_entry_store = {0}; vm_map_entry_t tmp_entry = NULL; vm_map_kernel_flags_t vmk_flags; vm_map_offset_t map_addr; kern_return_t kr = KERN_SUCCESS; boolean_t use_ptr_auth = task_sign_pointers(task); /* * Taking the full shared region lock here shouldn't be necessary for * functional correctness here, so we could potentially gain some scalability * by only taking the task lock here which would avoid the possibility of * serializing multiple tasks at the auth_remap step. But shared_region_pager_match() * is slightly racy and can produce duplicate pagers without shared-region-wide * synchronization, which is a potential memory footprint issue. */ vm_shared_region_acquire(sr); /* Just return if already done. */ if (task->shared_region_auth_remapped) { vm_shared_region_release(sr); return KERN_SUCCESS; } /* * Remap any sections with pointer authentications into the private map. */ for (i = 0; i < sr->sr_num_auth_section; ++i) { si = sr->sr_auth_section[i]; assert(si != NULL); assert(si->si_ptrauth); /* * We have mapping that needs to be private. * Look for an existing slid mapping's pager with matching * object, offset, slide info and shared_region_id to reuse. */ object = si->si_slide_object; sr_pager = shared_region_pager_match(object, si->si_start, si, use_ptr_auth ? task->jop_pid : 0); if (sr_pager == MEMORY_OBJECT_NULL) { printf("%s(): shared_region_pager_match() failed\n", __func__); kr = KERN_FAILURE; goto done; } /* * verify matching jop_pid for this task and this pager */ if (use_ptr_auth) { shared_region_pager_match_task_key(sr_pager, task); } sr_map = vm_shared_region_vm_map(sr); tmp_entry = NULL; kr = find_mapping_to_slide(sr_map, si->si_slid_address - sr->sr_base_address, &tmp_entry_store); if (kr != KERN_SUCCESS) { printf("%s(): find_mapping_to_slide() failed\n", __func__); goto done; } tmp_entry = &tmp_entry_store; /* * Check that the object exactly covers the region to slide. */ if (tmp_entry->vme_end - tmp_entry->vme_start != si->si_end - si->si_start) { printf("%s(): doesn't fully cover\n", __func__); kr = KERN_FAILURE; goto done; } /* * map the pager over the portion of the mapping that needs sliding */ vmk_flags = VM_MAP_KERNEL_FLAGS_FIXED(.vmf_overwrite = true); vmk_flags.vmkf_overwrite_immutable = true; vmk_flags.vmf_permanent = shared_region_make_permanent(sr, tmp_entry->max_protection); /* Preserve the TPRO flag if task has TPRO enabled */ vmk_flags.vmf_tpro = (vm_map_tpro(task->map) && tmp_entry->used_for_tpro && task_has_tpro(task)); map_addr = si->si_slid_address; kr = mach_vm_map_kernel(task->map, vm_sanitize_wrap_addr_ref(&map_addr), si->si_end - si->si_start, 0, vmk_flags, (ipc_port_t)(uintptr_t) sr_pager, 0, TRUE, tmp_entry->protection, tmp_entry->max_protection, tmp_entry->inheritance); memory_object_deallocate(sr_pager); sr_pager = MEMORY_OBJECT_NULL; if (kr != KERN_SUCCESS) { printf("%s(): mach_vm_map_kernel() failed\n", __func__); goto done; } assertf(map_addr == si->si_slid_address, "map_addr=0x%llx si_slid_address=0x%llx tmp_entry=%p\n", (uint64_t)map_addr, (uint64_t)si->si_slid_address, tmp_entry); /* Drop the ref count grabbed by find_mapping_to_slide */ vm_object_deallocate(VME_OBJECT(tmp_entry)); tmp_entry = NULL; } done: if (tmp_entry) { /* Drop the ref count grabbed by find_mapping_to_slide */ vm_object_deallocate(VME_OBJECT(tmp_entry)); tmp_entry = NULL; } /* * Drop any extra reference to the pager in case we're quitting due to an error above. */ if (sr_pager != MEMORY_OBJECT_NULL) { memory_object_deallocate(sr_pager); } /* * Mark the region as having it's auth sections remapped. */ task->shared_region_auth_remapped = TRUE; vm_shared_region_release(sr); return kr; } #endif /* __has_feature(ptrauth_calls) */ void vm_shared_region_undo_mappings( vm_shared_region_t shared_region, vm_map_t sr_map, mach_vm_offset_t sr_base_address, struct _sr_file_mappings *srf_mappings, struct _sr_file_mappings *srf_mappings_current, unsigned int srf_current_mappings_count) { unsigned int j = 0; struct _sr_file_mappings *srfmp; unsigned int mappings_count; struct shared_file_mapping_slide_np *mappings; shared_region->sr_first_mapping = (mach_vm_offset_t) -1; if (sr_map == NULL) { ipc_port_t sr_handle; vm_named_entry_t sr_mem_entry; /* no need to lock because this data is never modified... */ sr_handle = shared_region->sr_mem_entry; sr_mem_entry = mach_memory_entry_from_port(sr_handle); sr_map = sr_mem_entry->backing.map; sr_base_address = shared_region->sr_base_address; } /* * Undo the mappings we've established so far. */ for (srfmp = &srf_mappings[0]; srfmp <= srf_mappings_current; srfmp++) { mappings = srfmp->mappings; mappings_count = srfmp->mappings_count; if (srfmp == srf_mappings_current) { mappings_count = srf_current_mappings_count; } for (j = 0; j < mappings_count; j++) { kern_return_t kr2; mach_vm_offset_t start, end; if (mappings[j].sms_size == 0) { /* * We didn't establish this * mapping, so nothing to undo. */ continue; } SHARED_REGION_TRACE_INFO( ("shared_region: mapping[%d]: " "address:0x%016llx " "size:0x%016llx " "offset:0x%016llx " "maxprot:0x%x prot:0x%x: " "undoing...\n", j, (long long)mappings[j].sms_address, (long long)mappings[j].sms_size, (long long)mappings[j].sms_file_offset, mappings[j].sms_max_prot, mappings[j].sms_init_prot)); start = (mappings[j].sms_address - sr_base_address); end = start + mappings[j].sms_size; start = vm_map_trunc_page(start, VM_MAP_PAGE_MASK(sr_map)); end = vm_map_round_page(end, VM_MAP_PAGE_MASK(sr_map)); kr2 = vm_map_remove_guard(sr_map, start, end, VM_MAP_REMOVE_IMMUTABLE, KMEM_GUARD_NONE); assert(kr2 == KERN_SUCCESS); } } } /* * First part of vm_shared_region_map_file(). Split out to * avoid kernel stack overflow. */ __attribute__((noinline)) static kern_return_t vm_shared_region_map_file_setup( vm_shared_region_t shared_region, int sr_file_mappings_count, struct _sr_file_mappings *sr_file_mappings, unsigned int *mappings_to_slide_cnt, struct shared_file_mapping_slide_np **mappings_to_slide, mach_vm_offset_t *slid_mappings, memory_object_control_t *slid_file_controls, mach_vm_offset_t *sfm_min_address, mach_vm_offset_t *sfm_max_address, vm_map_t *sr_map_ptr, vm_map_offset_t *lowest_unnestable_addr_ptr, unsigned int vmsr_num_slides) { kern_return_t kr = KERN_SUCCESS; memory_object_control_t file_control; vm_object_t file_object; ipc_port_t sr_handle; vm_named_entry_t sr_mem_entry; vm_map_t sr_map; mach_vm_offset_t sr_base_address; unsigned int i = 0; mach_port_t map_port; vm_map_offset_t target_address; vm_object_t object; vm_object_size_t obj_size; vm_map_offset_t lowest_unnestable_addr = 0; vm_map_kernel_flags_t vmk_flags; mach_vm_offset_t sfm_end; uint32_t mappings_count; struct shared_file_mapping_slide_np *mappings; struct _sr_file_mappings *srfmp; assert(shared_region->sr_mapping_in_progress == current_thread()); /* no need to lock because this data is never modified... */ sr_handle = shared_region->sr_mem_entry; sr_mem_entry = mach_memory_entry_from_port(sr_handle); sr_map = sr_mem_entry->backing.map; sr_base_address = shared_region->sr_base_address; SHARED_REGION_TRACE_DEBUG( ("shared_region: -> map(%p)\n", (void *)VM_KERNEL_ADDRPERM(shared_region))); mappings_count = 0; mappings = NULL; srfmp = NULL; /* process all the files to be mapped */ for (srfmp = &sr_file_mappings[0]; srfmp < &sr_file_mappings[sr_file_mappings_count]; srfmp++) { i = 0; /* reset i early because it's used in the error recovery path */ mappings_count = srfmp->mappings_count; mappings = srfmp->mappings; file_control = srfmp->file_control; if (mappings_count == 0) { /* no mappings here... */ continue; } /* * The code below can only correctly "slide" (perform relocations) for one * value of the slide amount. So if a file has a non-zero slide, it has to * match any previous value. A zero slide value is ok for things that are * just directly mapped. */ if (shared_region->sr_slide == 0 && srfmp->slide != 0) { shared_region->sr_slide = srfmp->slide; } else if (shared_region->sr_slide != 0 && srfmp->slide != 0 && shared_region->sr_slide != srfmp->slide) { SHARED_REGION_TRACE_ERROR( ("shared_region: more than 1 non-zero slide value amount " "slide 1:0x%x slide 2:0x%x\n ", shared_region->sr_slide, srfmp->slide)); kr = KERN_INVALID_ARGUMENT; break; } /* * An FD of -1 means we need to copyin the data to an anonymous object. */ if (srfmp->fd == -1) { assert(mappings_count == 1); SHARED_REGION_TRACE_INFO( ("shared_region: mapping[0]: " "address:0x%016llx size:0x%016llx offset/addr:0x%016llx " "maxprot:0x%x prot:0x%x fd==-1\n", (long long)mappings[0].sms_address, (long long)mappings[0].sms_size, (long long)mappings[0].sms_file_offset, mappings[0].sms_max_prot, mappings[0].sms_init_prot)); /* * We need an anon object to hold the data in the shared region. * The size needs to be suitable to map into kernel. */ obj_size = vm_object_round_page(mappings->sms_size); object = vm_object_allocate(obj_size, kernel_map->serial_id); if (object == VM_OBJECT_NULL) { printf("%s(): for fd==-1 vm_object_allocate() failed\n", __func__); kr = KERN_RESOURCE_SHORTAGE; break; } /* * map the object into the kernel */ vm_map_offset_t kaddr = 0; vmk_flags = VM_MAP_KERNEL_FLAGS_ANYWHERE(); vmk_flags.vmkf_no_copy_on_read = 1; vmk_flags.vmkf_range_id = KMEM_RANGE_ID_DATA_SHARED; kr = vm_map_enter(kernel_map, &kaddr, obj_size, 0, vmk_flags, object, 0, FALSE, (VM_PROT_READ | VM_PROT_WRITE), (VM_PROT_READ | VM_PROT_WRITE), VM_INHERIT_NONE); if (kr != KERN_SUCCESS) { printf("%s(): for fd==-1 vm_map_enter() in kernel failed\n", __func__); vm_object_deallocate(object); object = VM_OBJECT_NULL; break; } /* * We'll need another reference to keep the object alive after * we vm_map_remove() it from the kernel. */ vm_object_reference(object); /* * Zero out the object's pages, so we can't leak data. */ bzero((void *)kaddr, obj_size); /* * Copyin the data from dyld to the new object. * Then remove the kernel mapping. */ int copyin_err = copyin((user_addr_t)mappings->sms_file_offset, (void *)kaddr, mappings->sms_size); vm_map_remove(kernel_map, kaddr, kaddr + obj_size); if (copyin_err) { printf("%s(): for fd==-1 copyin(%p) failed, errno=%d\n", __func__, (void*)mappings->sms_file_offset, copyin_err); switch (copyin_err) { case EPERM: case EACCES: kr = KERN_PROTECTION_FAILURE; break; case EFAULT: kr = KERN_INVALID_ADDRESS; break; default: kr = KERN_FAILURE; break; } vm_object_deallocate(object); object = VM_OBJECT_NULL; break; } /* * Finally map the object into the shared region. */ target_address = (vm_map_offset_t)(mappings[0].sms_address - sr_base_address); vmk_flags = VM_MAP_KERNEL_FLAGS_FIXED(); vmk_flags.vmkf_no_copy_on_read = 1; vmk_flags.vmf_permanent = shared_region_make_permanent(shared_region, mappings[0].sms_max_prot); kr = vm_map_enter( sr_map, &target_address, vm_map_round_page(mappings[0].sms_size, VM_MAP_PAGE_MASK(sr_map)), 0, vmk_flags, object, 0, FALSE, /* copy */ mappings[0].sms_init_prot & VM_PROT_ALL, mappings[0].sms_max_prot & VM_PROT_ALL, VM_INHERIT_DEFAULT); if (kr != KERN_SUCCESS) { printf("%s(): for fd==-1 vm_map_enter() in SR failed\n", __func__); vm_object_deallocate(object); break; } if (mappings[0].sms_address < *sfm_min_address) { *sfm_min_address = mappings[0].sms_address; } if (os_add_overflow(mappings[0].sms_address, mappings[0].sms_size, &sfm_end) || (vm_map_round_page(sfm_end, VM_MAP_PAGE_MASK(sr_map)) < mappings[0].sms_address)) { /* overflow */ kr = KERN_INVALID_ARGUMENT; break; } if (sfm_end > *sfm_max_address) { *sfm_max_address = sfm_end; } continue; } /* get the VM object associated with the file to be mapped */ file_object = memory_object_control_to_vm_object(file_control); assert(file_object); if (!file_object->object_is_shared_cache) { vm_object_lock(file_object); file_object->object_is_shared_cache = true; vm_object_unlock(file_object); } #if CONFIG_SECLUDED_MEMORY /* * Camera will need the shared cache, so don't put the pages * on the secluded queue, assume that's the primary region. * Also keep DEXT shared cache pages off secluded. */ if (primary_system_shared_region == NULL || primary_system_shared_region == shared_region || shared_region->sr_driverkit) { memory_object_mark_eligible_for_secluded(file_control, FALSE); } #endif /* CONFIG_SECLUDED_MEMORY */ /* establish the mappings for that file */ for (i = 0; i < mappings_count; i++) { SHARED_REGION_TRACE_INFO( ("shared_region: mapping[%d]: " "address:0x%016llx size:0x%016llx offset:0x%016llx " "maxprot:0x%x prot:0x%x\n", i, (long long)mappings[i].sms_address, (long long)mappings[i].sms_size, (long long)mappings[i].sms_file_offset, mappings[i].sms_max_prot, mappings[i].sms_init_prot)); if (mappings[i].sms_address < *sfm_min_address) { *sfm_min_address = mappings[i].sms_address; } if (os_add_overflow(mappings[i].sms_address, mappings[i].sms_size, &sfm_end) || (vm_map_round_page(sfm_end, VM_MAP_PAGE_MASK(sr_map)) < mappings[i].sms_address)) { /* overflow */ kr = KERN_INVALID_ARGUMENT; break; } if (sfm_end > *sfm_max_address) { *sfm_max_address = sfm_end; } if (mappings[i].sms_init_prot & VM_PROT_ZF) { /* zero-filled memory */ map_port = MACH_PORT_NULL; } else { /* file-backed memory */ __IGNORE_WCASTALIGN(map_port = (ipc_port_t) file_object->pager); } /* * Remember which mappings need sliding. */ if (mappings[i].sms_max_prot & VM_PROT_SLIDE) { if (*mappings_to_slide_cnt == vmsr_num_slides) { SHARED_REGION_TRACE_INFO( ("shared_region: mapping[%d]: " "address:0x%016llx size:0x%016llx " "offset:0x%016llx " "maxprot:0x%x prot:0x%x " "too many mappings to slide...\n", i, (long long)mappings[i].sms_address, (long long)mappings[i].sms_size, (long long)mappings[i].sms_file_offset, mappings[i].sms_max_prot, mappings[i].sms_init_prot)); } else { mappings_to_slide[*mappings_to_slide_cnt] = &mappings[i]; *mappings_to_slide_cnt += 1; } } /* mapping's address is relative to the shared region base */ if (__improbable( os_sub_overflow( mappings[i].sms_address, sr_base_address, &target_address))) { kr = KERN_INVALID_ARGUMENT; break; } vmk_flags = VM_MAP_KERNEL_FLAGS_FIXED(); /* no copy-on-read for mapped binaries */ vmk_flags.vmkf_no_copy_on_read = 1; vmk_flags.vmf_permanent = shared_region_make_permanent( shared_region, mappings[i].sms_max_prot); vmk_flags.vmf_tpro = shared_region_tpro_protect( shared_region, mappings[i].sms_max_prot); /* establish that mapping, OK if it's "already" there */ if (map_port == MACH_PORT_NULL) { /* * We want to map some anonymous memory in a shared region. * We have to create the VM object now, so that it can be mapped "copy-on-write". */ obj_size = vm_map_round_page(mappings[i].sms_size, VM_MAP_PAGE_MASK(sr_map)); object = vm_object_allocate(obj_size, sr_map->serial_id); if (object == VM_OBJECT_NULL) { kr = KERN_RESOURCE_SHORTAGE; } else { kr = vm_map_enter( sr_map, &target_address, vm_map_round_page(mappings[i].sms_size, VM_MAP_PAGE_MASK(sr_map)), 0, vmk_flags, object, 0, FALSE, /* copy */ mappings[i].sms_init_prot & VM_PROT_ALL, mappings[i].sms_max_prot & VM_PROT_ALL, VM_INHERIT_DEFAULT); } } else { object = VM_OBJECT_NULL; /* no anonymous memory here */ kr = mach_vm_map_kernel( sr_map, vm_sanitize_wrap_addr_ref(&target_address), vm_map_round_page( mappings[i].sms_size, VM_MAP_PAGE_MASK(sr_map)), 0, vmk_flags, map_port, mappings[i].sms_file_offset, TRUE, mappings[i].sms_init_prot & VM_PROT_ALL, mappings[i].sms_max_prot & VM_PROT_ALL, VM_INHERIT_DEFAULT); } if (kr == KERN_SUCCESS) { /* * Record the first successful mapping(s) in the shared * region by file. We're protected by "sr_mapping_in_progress" * here, so no need to lock "shared_region". * * Note that if we have an AOT shared cache (ARM) for a * translated task, then it's always the first file. * The original "native" (i.e. x86) shared cache is the * second file. */ if (shared_region->sr_first_mapping == (mach_vm_offset_t)-1) { shared_region->sr_first_mapping = target_address; } if (*mappings_to_slide_cnt > 0 && mappings_to_slide[*mappings_to_slide_cnt - 1] == &mappings[i]) { slid_mappings[*mappings_to_slide_cnt - 1] = target_address; slid_file_controls[*mappings_to_slide_cnt - 1] = file_control; } /* * Record the lowest writable address in this * sub map, to log any unexpected unnesting below * that address (see log_unnest_badness()). */ if ((mappings[i].sms_init_prot & VM_PROT_WRITE) && sr_map->is_nested_map && (lowest_unnestable_addr == 0 || (target_address < lowest_unnestable_addr))) { lowest_unnestable_addr = target_address; } } else { if (map_port == MACH_PORT_NULL) { /* * Get rid of the VM object we just created * but failed to map. */ vm_object_deallocate(object); object = VM_OBJECT_NULL; } break; } } if (kr != KERN_SUCCESS) { break; } } if (kr != KERN_SUCCESS) { /* the last mapping we tried (mappings[i]) failed ! */ assert(i < mappings_count); SHARED_REGION_TRACE_ERROR( ("shared_region: mapping[%d]: " "address:0x%016llx size:0x%016llx " "offset:0x%016llx " "maxprot:0x%x prot:0x%x failed 0x%x\n", i, (long long)mappings[i].sms_address, (long long)mappings[i].sms_size, (long long)mappings[i].sms_file_offset, mappings[i].sms_max_prot, mappings[i].sms_init_prot, kr)); /* * Respect the design of vm_shared_region_undo_mappings * as we are holding the sr_mapping_in_progress here. * So don't allow sr_map == NULL otherwise vm_shared_region_undo_mappings * will be blocked at waiting sr_mapping_in_progress to be NULL. */ assert(sr_map != NULL); /* undo all the previous mappings */ vm_shared_region_undo_mappings(shared_region, sr_map, sr_base_address, sr_file_mappings, srfmp, i); return kr; } *lowest_unnestable_addr_ptr = lowest_unnestable_addr; *sr_map_ptr = sr_map; return KERN_SUCCESS; } /* forwared declaration */ __attribute__((noinline)) static void vm_shared_region_map_file_final( vm_shared_region_t shared_region, vm_map_t sr_map, mach_vm_offset_t sfm_min_address, mach_vm_offset_t sfm_max_address); /* * Establish some mappings of a file in the shared region. * This is used by "dyld" via the shared_region_map_np() system call * to populate the shared region with the appropriate shared cache. * * One could also call it several times to incrementally load several * libraries, as long as they do not overlap. * It will return KERN_SUCCESS if the mappings were successfully established * or if they were already established identically by another process. */ __attribute__((noinline)) kern_return_t vm_shared_region_map_file( vm_shared_region_t shared_region, int sr_file_mappings_count, struct _sr_file_mappings *sr_file_mappings) { kern_return_t kr = KERN_SUCCESS; unsigned int i; unsigned int mappings_to_slide_cnt = 0; mach_vm_offset_t sfm_min_address = (mach_vm_offset_t)-1; mach_vm_offset_t sfm_max_address = 0; vm_map_t sr_map = NULL; vm_map_offset_t lowest_unnestable_addr = 0; unsigned int vmsr_num_slides = 0; typedef mach_vm_offset_t slid_mappings_t __kernel_data_semantics; slid_mappings_t *slid_mappings = NULL; /* [0..vmsr_num_slides] */ memory_object_control_t *slid_file_controls = NULL; /* [0..vmsr_num_slides] */ struct shared_file_mapping_slide_np **mappings_to_slide = NULL; /* [0..vmsr_num_slides] */ struct _sr_file_mappings *srfmp; vm_map_switch_context_t switch_ctx; bool map_switched = false; vmlp_api_start(VM_SHARED_REGION_MAP_FILE); /* * Figure out how many of the mappings have slides. */ for (srfmp = &sr_file_mappings[0]; srfmp < &sr_file_mappings[sr_file_mappings_count]; srfmp++) { for (i = 0; i < srfmp->mappings_count; ++i) { if (srfmp->mappings[i].sms_max_prot & VM_PROT_SLIDE) { ++vmsr_num_slides; } } } /* Allocate per slide data structures */ if (vmsr_num_slides > 0) { slid_mappings = kalloc_data(vmsr_num_slides * sizeof(*slid_mappings), Z_WAITOK); slid_file_controls = kalloc_type(memory_object_control_t, vmsr_num_slides, Z_WAITOK); mappings_to_slide = kalloc_type(struct shared_file_mapping_slide_np *, vmsr_num_slides, Z_WAITOK | Z_ZERO); } vm_shared_region_acquire(shared_region); /* * Did someone race in and map this shared region already, or did an earlier mapping fail? */ if (shared_region->sr_first_mapping != -1) { #if DEVELOPMENT || DEBUG printf("shared_region: caught race in map and slide\n"); #endif /* DEVELOPMENT || DEBUG */ kr = KERN_FAILURE; goto done; } kr = vm_shared_region_map_file_setup(shared_region, sr_file_mappings_count, sr_file_mappings, &mappings_to_slide_cnt, mappings_to_slide, slid_mappings, slid_file_controls, &sfm_min_address, &sfm_max_address, &sr_map, &lowest_unnestable_addr, vmsr_num_slides); if (kr != KERN_SUCCESS) { goto done; } assert(vmsr_num_slides == mappings_to_slide_cnt); assert(shared_region->sr_config_map != NULL); switch_ctx = vm_map_switch_to(shared_region->sr_config_map); map_switched = true; /* * The call above installed direct mappings to the shared cache file. * Now we go back and overwrite the mappings that need relocation * with a special shared region pager. * * Note that this does copyin() of data, needed by the pager, which * the previous code just established mappings for. This is why we * do it in a separate pass. */ #if __has_feature(ptrauth_calls) /* * need to allocate storage needed for any sr_auth_sections */ for (i = 0; i < mappings_to_slide_cnt; ++i) { if (shared_region->sr_cpu_type == CPU_TYPE_ARM64 && shared_region->sr_cpu_subtype == CPU_SUBTYPE_ARM64E && !(mappings_to_slide[i]->sms_max_prot & VM_PROT_NOAUTH)) { ++shared_region->sr_num_auth_section; } } if (shared_region->sr_num_auth_section > 0) { shared_region->sr_auth_section = kalloc_type(vm_shared_region_slide_info_t, shared_region->sr_num_auth_section, Z_WAITOK | Z_ZERO); } #endif /* __has_feature(ptrauth_calls) */ for (i = 0; i < mappings_to_slide_cnt; ++i) { kr = vm_shared_region_slide(shared_region->sr_slide, mappings_to_slide[i]->sms_file_offset, mappings_to_slide[i]->sms_size, mappings_to_slide[i]->sms_slide_start, mappings_to_slide[i]->sms_slide_size, slid_mappings[i], slid_file_controls[i], mappings_to_slide[i]->sms_max_prot); if (kr != KERN_SUCCESS) { SHARED_REGION_TRACE_ERROR( ("shared_region: region_slide(" "slide:0x%x start:0x%016llx " "size:0x%016llx) failed 0x%x\n", shared_region->sr_slide, (long long)mappings_to_slide[i]->sms_slide_start, (long long)mappings_to_slide[i]->sms_slide_size, kr)); vm_shared_region_undo_mappings(shared_region, sr_map, shared_region->sr_base_address, &sr_file_mappings[0], &sr_file_mappings[sr_file_mappings_count - 1], sr_file_mappings_count); goto done; } } assert(kr == KERN_SUCCESS); /* adjust the map's "lowest_unnestable_start" */ lowest_unnestable_addr &= ~(pmap_shared_region_size_min(sr_map->pmap) - 1); if (lowest_unnestable_addr != sr_map->lowest_unnestable_start) { vm_map_ilk_lock(sr_map); vmlp_range_event_none(sr_map); sr_map->lowest_unnestable_start = lowest_unnestable_addr; vm_map_ilk_unlock(sr_map); } vm_shared_region_lock(); assert(shared_region->sr_ref_count > 0); assert(shared_region->sr_mapping_in_progress == current_thread()); vm_shared_region_map_file_final(shared_region, sr_map, sfm_min_address, sfm_max_address); vm_shared_region_unlock(); done: #ifndef NO_NESTED_PMAP /* * If we succeeded, we know the bounds of the shared region. * Trim our pmaps to only cover this range (if applicable to * this platform). */ if (kr == KERN_SUCCESS) { pmap_trim(shared_region->sr_config_map->pmap, sr_map->pmap, sfm_min_address, sfm_max_address - sfm_min_address); } #endif if (map_switched) { vm_map_switch_back(switch_ctx); } if (kr == KERN_SUCCESS) { vm_map_deallocate(shared_region->sr_config_map); shared_region->sr_config_map = VM_MAP_NULL; } if (kr == KERN_SUCCESS) { vm_shared_region_seal(shared_region); } vm_shared_region_release(shared_region); SHARED_REGION_TRACE_DEBUG( ("shared_region: map(%p) <- 0x%x \n", (void *)VM_KERNEL_ADDRPERM(shared_region), kr)); if (vmsr_num_slides > 0) { kfree_data(slid_mappings, vmsr_num_slides * sizeof(*slid_mappings)); kfree_type(memory_object_control_t, vmsr_num_slides, slid_file_controls); kfree_type(struct shared_file_mapping_slide_np *, vmsr_num_slides, mappings_to_slide); } vmlp_api_end(VM_SHARED_REGION_MAP_FILE, kr); return kr; } /* * Final part of vm_shared_region_map_file(). * Kept in separate function to avoid blowing out the stack. */ __attribute__((noinline)) static void vm_shared_region_map_file_final( vm_shared_region_t shared_region, vm_map_t sr_map __unused, mach_vm_offset_t sfm_min_address __unused, mach_vm_offset_t sfm_max_address __unused) { struct _dyld_cache_header sr_cache_header; int error; size_t image_array_length; struct _dyld_cache_image_text_info *sr_image_layout; boolean_t locally_built = FALSE; /* * copy in the shared region UUID to the shared region structure. * we do this indirectly by first copying in the shared cache header * and then copying the UUID from there because we'll need to look * at other content from the shared cache header. */ if (!shared_region->sr_uuid_copied) { error = copyin((user_addr_t)(shared_region->sr_base_address + shared_region->sr_first_mapping), (char *)&sr_cache_header, sizeof(sr_cache_header)); if (error == 0) { memcpy(&shared_region->sr_uuid, &sr_cache_header.uuid, sizeof(shared_region->sr_uuid)); shared_region->sr_uuid_copied = TRUE; locally_built = sr_cache_header.locallyBuiltCache; } else { #if DEVELOPMENT || DEBUG panic("shared_region: copyin shared_cache_header(sr_base_addr:0x%016llx sr_first_mapping:0x%016llx " "offset:0 size:0x%016llx) failed with %d\n", (long long)shared_region->sr_base_address, (long long)shared_region->sr_first_mapping, (long long)sizeof(sr_cache_header), error); #endif /* DEVELOPMENT || DEBUG */ shared_region->sr_uuid_copied = FALSE; } } /* * We save a pointer to the shared cache mapped by the "init task", i.e. launchd. This is used by * the stackshot code to reduce output size in the common case that everything maps the same shared cache. * One gotcha is that "userspace reboots" can occur which can cause a new shared region to be the primary * region. In that case, launchd re-exec's itself, so we may go through this path multiple times. We * let the most recent one win. * * Check whether the shared cache is a custom built one and copy in the shared cache layout accordingly. */ bool is_init_task = (task_pid(current_task()) == 1); if (shared_region->sr_uuid_copied && is_init_task) { /* Copy in the shared cache layout if we're running with a locally built shared cache */ if (locally_built) { KDBG((MACHDBG_CODE(DBG_MACH_SHAREDREGION, PROCESS_SHARED_CACHE_LAYOUT)) | DBG_FUNC_START); image_array_length = (size_t)(sr_cache_header.imagesTextCount * sizeof(struct _dyld_cache_image_text_info)); sr_image_layout = kalloc_data(image_array_length, Z_WAITOK); error = copyin((user_addr_t)(shared_region->sr_base_address + shared_region->sr_first_mapping + sr_cache_header.imagesTextOffset), (char *)sr_image_layout, image_array_length); if (error == 0) { if (sr_cache_header.imagesTextCount >= UINT32_MAX) { panic("shared_region: sr_cache_header.imagesTextCount >= UINT32_MAX"); } shared_region->sr_images = kalloc_data((vm_size_t)(sr_cache_header.imagesTextCount * sizeof(struct dyld_uuid_info_64)), Z_WAITOK); for (size_t index = 0; index < sr_cache_header.imagesTextCount; index++) { memcpy((char *)&shared_region->sr_images[index].imageUUID, (char *)&sr_image_layout[index].uuid, sizeof(shared_region->sr_images[index].imageUUID)); shared_region->sr_images[index].imageLoadAddress = sr_image_layout[index].loadAddress; } shared_region->sr_images_count = (uint32_t) sr_cache_header.imagesTextCount; } else { #if DEVELOPMENT || DEBUG panic("shared_region: copyin shared_cache_layout(sr_base_addr:0x%016llx sr_first_mapping:0x%016llx " "offset:0x%016llx size:0x%016llx) failed with %d\n", (long long)shared_region->sr_base_address, (long long)shared_region->sr_first_mapping, (long long)sr_cache_header.imagesTextOffset, (long long)image_array_length, error); #endif /* DEVELOPMENT || DEBUG */ } KDBG((MACHDBG_CODE(DBG_MACH_SHAREDREGION, PROCESS_SHARED_CACHE_LAYOUT)) | DBG_FUNC_END, shared_region->sr_images_count); kfree_data(sr_image_layout, image_array_length); sr_image_layout = NULL; } primary_system_shared_region = shared_region; } } /* * Insert the real shared region submap entry into a task's VM map over the placeholder * installed by vm_map_exec(). Note that this function can only be called once per vm_map, * and cannot be undone. This is because it results in the shared region's pmap being nested * into [map]'s pmap; on some platforms the security model requires this nesting relationship * to be permanent, so the nested pmap cannot be "de-nested" from the top-level pmap or * "re-nested" again into the same top-level pmap. */ kern_return_t vm_shared_region_insert_submap(vm_map_t map, vm_shared_region_t shared_region, bool overwrite) { vm_map_offset_t sr_address, sr_offset, target_address; vm_map_size_t sr_size, mapping_size; vm_map_offset_t sr_pmap_nesting_start; vm_map_size_t sr_pmap_nesting_size; ipc_port_t sr_handle; vm_prot_t cur_prot, max_prot; vm_map_kernel_flags_t vmk_flags; kern_return_t kr = KERN_SUCCESS; /* no need to lock since this data is never modified */ sr_address = (vm_map_offset_t)shared_region->sr_base_address; sr_size = (vm_map_size_t)shared_region->sr_size; sr_handle = shared_region->sr_mem_entry; sr_pmap_nesting_start = (vm_map_offset_t)shared_region->sr_pmap_nesting_start; sr_pmap_nesting_size = (vm_map_size_t)shared_region->sr_pmap_nesting_size; vmk_flags = VM_MAP_KERNEL_FLAGS_FIXED(); if (overwrite) { vmk_flags.vmf_overwrite = true; vmk_flags.vmkf_overwrite_immutable = true; } /* * vm_map_lookup_and_lock_object() expects the parent map entry * for a shared region submap to have protections r-- by default. */ cur_prot = VM_PROT_READ; if (VM_MAP_POLICY_WRITABLE_SHARED_REGION(map)) { /* * XXX BINARY COMPATIBILITY * java6 apparently needs to modify some code in the * dyld shared cache and needs to be allowed to add * write access... */ max_prot = VM_PROT_ALL; } else { max_prot = VM_PROT_READ; /* make it "permanent" to protect against re-mappings */ vmk_flags.vmf_permanent = true; } /* * Start mapping the shared region's VM sub map into the task's VM map. */ sr_offset = 0; if (sr_pmap_nesting_start > sr_address) { /* we need to map a range without pmap-nesting first */ target_address = sr_address; mapping_size = sr_pmap_nesting_start - sr_address; kr = mach_vm_map_kernel( map, vm_sanitize_wrap_addr_ref(&target_address), mapping_size, 0, vmk_flags, sr_handle, sr_offset, TRUE, cur_prot, max_prot, VM_INHERIT_SHARE); if (kr != KERN_SUCCESS) { SHARED_REGION_TRACE_ERROR( ("shared_region: insert_submap(%p,%p): " "vm_map_enter(0x%llx,0x%llx,%p) error 0x%x\n", (void *)VM_KERNEL_ADDRPERM(map), (void *)VM_KERNEL_ADDRPERM(shared_region), (long long)target_address, (long long)mapping_size, (void *)VM_KERNEL_ADDRPERM(sr_handle), kr)); return kr; } SHARED_REGION_TRACE_DEBUG( ("shared_region: insert_submap(%p,%p): " "vm_map_enter(0x%llx,0x%llx,%p) error 0x%x\n", (void *)VM_KERNEL_ADDRPERM(map), (void *)VM_KERNEL_ADDRPERM(shared_region), (long long)target_address, (long long)mapping_size, (void *)VM_KERNEL_ADDRPERM(sr_handle), kr)); sr_offset += mapping_size; sr_size -= mapping_size; } /* The pmap-nesting is triggered by the "vmkf_nested_pmap" flag. */ vmk_flags.vmkf_nested_pmap = true; vmk_flags.vm_tag = VM_MEMORY_SHARED_PMAP; /* * Use pmap-nesting to map the majority of the shared region into the task's * VM space. Very rarely will architectures have a shared region that isn't * the same size as the pmap-nesting region, or start at a different address * than the pmap-nesting region, so this code will map the entirety of the * shared region for most architectures. */ assert((sr_address + sr_offset) == sr_pmap_nesting_start); target_address = sr_pmap_nesting_start; kr = mach_vm_map_kernel( map, vm_sanitize_wrap_addr_ref(&target_address), sr_pmap_nesting_size, 0, vmk_flags, sr_handle, sr_offset, TRUE, cur_prot, max_prot, VM_INHERIT_SHARE); if (kr != KERN_SUCCESS) { SHARED_REGION_TRACE_ERROR( ("shared_region: insert_submap(%p,%p): " "vm_map_enter(0x%llx,0x%llx,%p) error 0x%x\n", (void *)VM_KERNEL_ADDRPERM(map), (void *)VM_KERNEL_ADDRPERM(shared_region), (long long)target_address, (long long)sr_pmap_nesting_size, (void *)VM_KERNEL_ADDRPERM(sr_handle), kr)); return kr; } SHARED_REGION_TRACE_DEBUG( ("shared_region: insert_submap(%p,%p): " "nested vm_map_enter(0x%llx,0x%llx,%p) error 0x%x\n", (void *)VM_KERNEL_ADDRPERM(map), (void *)VM_KERNEL_ADDRPERM(shared_region), (long long)target_address, (long long)sr_pmap_nesting_size, (void *)VM_KERNEL_ADDRPERM(sr_handle), kr)); sr_offset += sr_pmap_nesting_size; sr_size -= sr_pmap_nesting_size; if (sr_size > 0) { /* and there's some left to be mapped without pmap-nesting */ vmk_flags.vmkf_nested_pmap = false; /* no pmap nesting */ target_address = sr_address + sr_offset; mapping_size = sr_size; kr = mach_vm_map_kernel( map, vm_sanitize_wrap_addr_ref(&target_address), mapping_size, 0, VM_MAP_KERNEL_FLAGS_FIXED(), sr_handle, sr_offset, TRUE, cur_prot, max_prot, VM_INHERIT_SHARE); if (kr != KERN_SUCCESS) { SHARED_REGION_TRACE_ERROR( ("shared_region: insert_submap(%p,%p): " "vm_map_enter(0x%llx,0x%llx,%p) error 0x%x\n", (void *)VM_KERNEL_ADDRPERM(map), (void *)VM_KERNEL_ADDRPERM(shared_region), (long long)target_address, (long long)mapping_size, (void *)VM_KERNEL_ADDRPERM(sr_handle), kr)); return kr; } SHARED_REGION_TRACE_DEBUG( ("shared_region: insert_submap(%p,%p): " "vm_map_enter(0x%llx,0x%llx,%p) error 0x%x\n", (void *)VM_KERNEL_ADDRPERM(map), (void *)VM_KERNEL_ADDRPERM(shared_region), (long long)target_address, (long long)mapping_size, (void *)VM_KERNEL_ADDRPERM(sr_handle), kr)); sr_offset += mapping_size; sr_size -= mapping_size; } assert(sr_size == 0); return kr; } /* * Inserts a VM_PROT_NONE placeholder covering the shared region into [map]. * This is intended to be called when a new task is exec'ed and initially associated * with a shared region. Once the userspace dyld initialization sequence successfully * queries the shared region start address via the shared_region_check_np syscall, * this placeholder will be replaced with the real shared region submap entry. */ static kern_return_t vm_shared_region_insert_placeholder(vm_map_t map, vm_shared_region_t shared_region) { vm_map_kernel_flags_t vmk_flags = VM_MAP_KERNEL_FLAGS_FIXED_PERMANENT(); vm_map_offset_t address = shared_region->sr_base_address; kern_return_t kr = vm_map_enter( map, &address, shared_region->sr_size, (vm_map_offset_t)0, vmk_flags, VM_OBJECT_NULL, (vm_object_offset_t)0, FALSE, VM_PROT_NONE, VM_PROT_NONE, VM_INHERIT_COPY); /** * If placeholder-insertion failed, e.g. due to a statically-linked executable already * using this region, don't establish the pmap-level shared region association. * The shared region reference for this task will be dropped and the task will be treated * as though it has no shared region. */ if (kr == KERN_SUCCESS) { pmap_set_shared_region(map->pmap, vm_shared_region_vm_map(shared_region)->pmap, address, shared_region->sr_size); } return kr; } /* * Enter the appropriate shared region into "map" for "task". * This involves looking up the shared region (and possibly creating a new * one) for the desired environment, then entering a permanent placeholder * entry for the shared region. If the task actually chooses to map a * shared region, this placeholder will later be overwritten by a submap * entry for the real shared region in vm_shared_region_insert_submap(). */ kern_return_t vm_shared_region_enter( struct _vm_map *map, struct task *task, boolean_t is_64bit, void *fsroot, cpu_type_t cpu, cpu_subtype_t cpu_subtype, boolean_t reslide, boolean_t is_driverkit, uint32_t rsr_version) { kern_return_t kr; vm_shared_region_t shared_region; SHARED_REGION_TRACE_DEBUG( ("shared_region: -> " "enter(map=%p,task=%p,root=%p,cpu=<%d,%d>,64bit=%d,driverkit=%d)\n", (void *)VM_KERNEL_ADDRPERM(map), (void *)VM_KERNEL_ADDRPERM(task), (void *)VM_KERNEL_ADDRPERM(fsroot), cpu, cpu_subtype, is_64bit, is_driverkit)); /* lookup (create if needed) the shared region for this environment */ shared_region = vm_shared_region_lookup(fsroot, cpu, cpu_subtype, is_64bit, VM_MAP_PAGE_SHIFT(map), reslide, is_driverkit, rsr_version); if (shared_region == NULL) { /* this should not happen ! */ SHARED_REGION_TRACE_ERROR( ("shared_region: -> " "enter(map=%p,task=%p,root=%p,cpu=<%d,%d>,64bit=%d,reslide=%d,driverkit=%d): " "lookup failed !\n", (void *)VM_KERNEL_ADDRPERM(map), (void *)VM_KERNEL_ADDRPERM(task), (void *)VM_KERNEL_ADDRPERM(fsroot), cpu, cpu_subtype, is_64bit, reslide, is_driverkit)); //panic("shared_region_enter: lookup failed"); return KERN_FAILURE; } kr = vm_shared_region_insert_placeholder(map, shared_region); if (kr == KERN_SUCCESS) { /* let the task use that shared region */ vm_shared_region_set(task, shared_region); } else { /* drop our reference since we're not using it */ vm_shared_region_deallocate(shared_region); vm_shared_region_set(task, NULL); } SHARED_REGION_TRACE_DEBUG( ("shared_region: enter(%p,%p,%p,%d,%d,%d,%d,%d) <- 0x%x\n", (void *)VM_KERNEL_ADDRPERM(map), (void *)VM_KERNEL_ADDRPERM(task), (void *)VM_KERNEL_ADDRPERM(fsroot), cpu, cpu_subtype, is_64bit, reslide, is_driverkit, kr)); return kr; } void vm_shared_region_remove( task_t task, vm_shared_region_t sr) { vm_map_t map; mach_vm_offset_t start; mach_vm_size_t size; vm_map_kernel_flags_t vmk_flags; kern_return_t kr; if (sr == NULL) { return; } map = get_task_map(task); start = sr->sr_base_address; size = sr->sr_size; vmk_flags = VM_MAP_KERNEL_FLAGS_FIXED(.vmf_overwrite = true); vmk_flags.vmkf_overwrite_immutable = true; vmk_flags.vm_tag = VM_MEMORY_DYLD; /* range_id is set by mach_vm_map_kernel */ kr = mach_vm_map_kernel(map, vm_sanitize_wrap_addr_ref(&start), size, 0, /* mask */ vmk_flags, MACH_PORT_NULL, 0, FALSE, /* copy */ VM_PROT_NONE, VM_PROT_NONE, VM_INHERIT_DEFAULT); if (kr != KERN_SUCCESS) { printf("%s:%d vm_map(0x%llx, 0x%llx) error %d\n", __FUNCTION__, __LINE__, (uint64_t)sr->sr_base_address, (uint64_t)size, kr); } } #define SANE_SLIDE_INFO_SIZE (2560*1024) /*Can be changed if needed*/ kern_return_t vm_shared_region_sliding_valid(uint32_t slide) { kern_return_t kr = KERN_SUCCESS; vm_shared_region_t sr = vm_shared_region_get(current_task()); /* No region yet? we're fine. */ if (sr == NULL) { return kr; } if (sr->sr_slide != 0 && slide != 0) { if (slide == sr->sr_slide) { /* * Request for sliding when we've * already done it with exactly the * same slide value before. * This isn't wrong technically but * we don't want to slide again and * so we return this value. */ kr = KERN_INVALID_ARGUMENT; } else { printf("Mismatched shared region slide\n"); kr = KERN_FAILURE; } } vm_shared_region_deallocate(sr); return kr; } /* * Actually create (really overwrite) the mapping to part of the shared cache which * undergoes relocation. This routine reads in the relocation info from dyld and * verifies it. It then creates a (or finds a matching) shared region pager which * handles the actual modification of the page contents and installs the mapping * using that pager. */ kern_return_t vm_shared_region_slide_mapping( vm_shared_region_t sr, user_addr_t slide_info_addr, mach_vm_size_t slide_info_size, mach_vm_offset_t start, mach_vm_size_t size, mach_vm_offset_t slid_mapping, uint32_t slide, memory_object_control_t sr_file_control, vm_prot_t prot) { kern_return_t kr; vm_object_t object = VM_OBJECT_NULL; vm_shared_region_slide_info_t si = NULL; vm_map_entry_t tmp_entry = VM_MAP_ENTRY_NULL; struct vm_map_entry tmp_entry_store; memory_object_t sr_pager = MEMORY_OBJECT_NULL; vm_map_t sr_map; vm_map_kernel_flags_t vmk_flags; vm_map_offset_t map_addr; void *slide_info_entry = NULL; int error; assert(sr->sr_slide_in_progress); if (sr_file_control == MEMORY_OBJECT_CONTROL_NULL) { return KERN_INVALID_ARGUMENT; } /* * Copy in and verify the relocation information. */ if (slide_info_size < MIN_SLIDE_INFO_SIZE) { printf("Slide_info_size too small: %lx\n", (uintptr_t)slide_info_size); return KERN_FAILURE; } if (slide_info_size > SANE_SLIDE_INFO_SIZE) { printf("Slide_info_size too large: %lx\n", (uintptr_t)slide_info_size); return KERN_FAILURE; } slide_info_entry = kalloc_data((vm_size_t)slide_info_size, Z_WAITOK); if (slide_info_entry == NULL) { return KERN_RESOURCE_SHORTAGE; } error = copyin(slide_info_addr, slide_info_entry, (size_t)slide_info_size); if (error) { printf("copyin of slide_info (%p) failed\n", (void*)slide_info_addr); kr = KERN_INVALID_ADDRESS; goto done; } if ((kr = vm_shared_region_slide_sanity_check(slide_info_entry, slide_info_size)) != KERN_SUCCESS) { printf("Sanity Check failed for slide_info\n"); goto done; } /* * Allocate and fill in a vm_shared_region_slide_info. * This will either be used by a new pager, or used to find * a pre-existing matching pager. */ object = memory_object_control_to_vm_object(sr_file_control); if (object == VM_OBJECT_NULL || object->internal) { object = VM_OBJECT_NULL; kr = KERN_INVALID_ADDRESS; goto done; } si = kalloc_type(struct vm_shared_region_slide_info, Z_WAITOK | Z_NOFAIL); vm_object_lock(object); vm_object_reference_locked(object); /* for si->slide_object */ object->object_is_shared_cache = TRUE; vm_object_unlock(object); si->si_slide_info_entry = slide_info_entry; si->si_slide_info_size = slide_info_size; assert(slid_mapping != (mach_vm_offset_t) -1); si->si_slid_address = slid_mapping + sr->sr_base_address; si->si_slide_object = object; si->si_start = start; si->si_end = si->si_start + size; si->si_slide = slide; #if __has_feature(ptrauth_calls) /* * If there is authenticated pointer data in this slid mapping, * then just add the information needed to create new pagers for * different shared_region_id's later. */ if (sr->sr_cpu_type == CPU_TYPE_ARM64 && sr->sr_cpu_subtype == CPU_SUBTYPE_ARM64E && !(prot & VM_PROT_NOAUTH)) { if (sr->sr_next_auth_section == sr->sr_num_auth_section) { printf("Too many auth/private sections for shared region!!\n"); kr = KERN_INVALID_ARGUMENT; goto done; } si->si_ptrauth = TRUE; sr->sr_auth_section[sr->sr_next_auth_section++] = si; /* * Remember the shared region, since that's where we'll * stash this info for all auth pagers to share. Each pager * will need to take a reference to it. */ si->si_shared_region = sr; kr = KERN_SUCCESS; goto done; } si->si_shared_region = NULL; si->si_ptrauth = FALSE; #endif /* __has_feature(ptrauth_calls) */ /* * find the pre-existing shared region's map entry to slide */ sr_map = vm_shared_region_vm_map(sr); kr = find_mapping_to_slide(sr_map, (vm_map_address_t)slid_mapping, &tmp_entry_store); if (kr != KERN_SUCCESS) { goto done; } tmp_entry = &tmp_entry_store; /* * The object must exactly cover the region to slide. */ assert(VME_OFFSET(tmp_entry) == start); assert(tmp_entry->vme_end - tmp_entry->vme_start == size); /* * We trust that the contents of this object are not writable, so * we do not need to get a "copy" of it. */ /* create a "shared_region" sliding pager */ sr_pager = shared_region_pager_setup(VME_OBJECT(tmp_entry), VME_OFFSET(tmp_entry), si, 0); if (sr_pager == MEMORY_OBJECT_NULL) { kr = KERN_RESOURCE_SHORTAGE; goto done; } #if CONFIG_SECLUDED_MEMORY /* * The shared region pagers used by camera or DEXT should have * pagers that won't go on the secluded queue. */ if (primary_system_shared_region == NULL || primary_system_shared_region == sr || sr->sr_driverkit) { memory_object_mark_eligible_for_secluded(sr_pager->mo_control, FALSE); } #endif /* CONFIG_SECLUDED_MEMORY */ /* map that pager over the portion of the mapping that needs sliding */ map_addr = tmp_entry->vme_start; vmk_flags = VM_MAP_KERNEL_FLAGS_FIXED(.vmf_overwrite = true); vmk_flags.vmkf_overwrite_immutable = true; vmk_flags.vmf_permanent = shared_region_make_permanent(sr, tmp_entry->max_protection); vmk_flags.vmf_tpro = shared_region_tpro_protect(sr, prot); kr = mach_vm_map_kernel(sr_map, vm_sanitize_wrap_addr_ref(&map_addr), tmp_entry->vme_end - tmp_entry->vme_start, 0, vmk_flags, (ipc_port_t)(uintptr_t) sr_pager, 0, TRUE, /* copy; to make sure this object stays "clean" */ tmp_entry->protection, tmp_entry->max_protection, tmp_entry->inheritance); assertf(kr == KERN_SUCCESS, "kr = 0x%x\n", kr); assertf(map_addr == tmp_entry->vme_start, "map_addr=0x%llx vme_start=0x%llx tmp_entry=%p\n", (uint64_t)map_addr, (uint64_t) tmp_entry->vme_start, tmp_entry); /* success! */ kr = KERN_SUCCESS; done: if (sr_pager != NULL) { /* * Release the sr_pager reference obtained by shared_region_pager_setup(). * The mapping, if it succeeded, is now holding a reference on the memory object. */ memory_object_deallocate(sr_pager); sr_pager = MEMORY_OBJECT_NULL; } if (tmp_entry != NULL) { /* release extra ref on tmp_entry's VM object */ vm_object_deallocate(VME_OBJECT(tmp_entry)); tmp_entry = VM_MAP_ENTRY_NULL; } if (kr != KERN_SUCCESS) { /* cleanup */ if (si != NULL) { if (si->si_slide_object) { vm_object_deallocate(si->si_slide_object); si->si_slide_object = VM_OBJECT_NULL; } kfree_type(struct vm_shared_region_slide_info, si); si = NULL; } if (slide_info_entry != NULL) { kfree_data(slide_info_entry, (vm_size_t)slide_info_size); slide_info_entry = NULL; } } return kr; } static kern_return_t vm_shared_region_slide_sanity_check_v1( vm_shared_region_slide_info_entry_v1_t s_info) { uint32_t pageIndex = 0; uint16_t entryIndex = 0; uint16_t *toc = NULL; toc = (uint16_t*)((uintptr_t)s_info + s_info->toc_offset); for (; pageIndex < s_info->toc_count; pageIndex++) { entryIndex = (uint16_t)(toc[pageIndex]); if (entryIndex >= s_info->entry_count) { printf("No sliding bitmap entry for pageIndex: %d at entryIndex: %d amongst %d entries\n", pageIndex, entryIndex, s_info->entry_count); return KERN_FAILURE; } } return KERN_SUCCESS; } static kern_return_t vm_shared_region_slide_sanity_check_v2( vm_shared_region_slide_info_entry_v2_t s_info, mach_vm_size_t slide_info_size) { if (slide_info_size < sizeof(struct vm_shared_region_slide_info_entry_v2)) { printf("%s bad slide_info_size: %lx\n", __func__, (uintptr_t)slide_info_size); return KERN_FAILURE; } if (s_info->page_size != PAGE_SIZE_FOR_SR_SLIDE) { return KERN_FAILURE; } /* Ensure that the slide info doesn't reference any data outside of its bounds. */ uint32_t page_starts_count = s_info->page_starts_count; uint32_t page_extras_count = s_info->page_extras_count; mach_vm_size_t num_trailing_entries = page_starts_count + page_extras_count; if (num_trailing_entries < page_starts_count) { return KERN_FAILURE; } /* Scale by sizeof(uint16_t). Hard-coding the size simplifies the overflow check. */ mach_vm_size_t trailing_size = num_trailing_entries << 1; if (trailing_size >> 1 != num_trailing_entries) { return KERN_FAILURE; } mach_vm_size_t required_size = sizeof(*s_info) + trailing_size; if (required_size < sizeof(*s_info)) { return KERN_FAILURE; } if (required_size > slide_info_size) { return KERN_FAILURE; } return KERN_SUCCESS; } static kern_return_t vm_shared_region_slide_sanity_check_v3( vm_shared_region_slide_info_entry_v3_t s_info, mach_vm_size_t slide_info_size) { if (slide_info_size < sizeof(struct vm_shared_region_slide_info_entry_v3)) { printf("%s bad slide_info_size: %lx\n", __func__, (uintptr_t)slide_info_size); return KERN_FAILURE; } if (s_info->page_size != PAGE_SIZE_FOR_SR_SLIDE) { printf("vm_shared_region_slide_sanity_check_v3: s_info->page_size != PAGE_SIZE_FOR_SR_SL 0x%llx != 0x%llx\n", (uint64_t)s_info->page_size, (uint64_t)PAGE_SIZE_FOR_SR_SLIDE); return KERN_FAILURE; } uint32_t page_starts_count = s_info->page_starts_count; mach_vm_size_t num_trailing_entries = page_starts_count; mach_vm_size_t trailing_size = num_trailing_entries << 1; mach_vm_size_t required_size = sizeof(*s_info) + trailing_size; if (required_size < sizeof(*s_info)) { printf("vm_shared_region_slide_sanity_check_v3: required_size != sizeof(*s_info) 0x%llx != 0x%llx\n", (uint64_t)required_size, (uint64_t)sizeof(*s_info)); return KERN_FAILURE; } if (required_size > slide_info_size) { printf("vm_shared_region_slide_sanity_check_v3: required_size != slide_info_size 0x%llx != 0x%llx\n", (uint64_t)required_size, (uint64_t)slide_info_size); return KERN_FAILURE; } return KERN_SUCCESS; } static kern_return_t vm_shared_region_slide_sanity_check_v4( vm_shared_region_slide_info_entry_v4_t s_info, mach_vm_size_t slide_info_size) { if (slide_info_size < sizeof(struct vm_shared_region_slide_info_entry_v4)) { printf("%s bad slide_info_size: %lx\n", __func__, (uintptr_t)slide_info_size); return KERN_FAILURE; } if (s_info->page_size != PAGE_SIZE_FOR_SR_SLIDE) { return KERN_FAILURE; } /* Ensure that the slide info doesn't reference any data outside of its bounds. */ uint32_t page_starts_count = s_info->page_starts_count; uint32_t page_extras_count = s_info->page_extras_count; mach_vm_size_t num_trailing_entries = page_starts_count + page_extras_count; if (num_trailing_entries < page_starts_count) { return KERN_FAILURE; } /* Scale by sizeof(uint16_t). Hard-coding the size simplifies the overflow check. */ mach_vm_size_t trailing_size = num_trailing_entries << 1; if (trailing_size >> 1 != num_trailing_entries) { return KERN_FAILURE; } mach_vm_size_t required_size = sizeof(*s_info) + trailing_size; if (required_size < sizeof(*s_info)) { return KERN_FAILURE; } if (required_size > slide_info_size) { return KERN_FAILURE; } return KERN_SUCCESS; } static kern_return_t vm_shared_region_slide_sanity_check_v5( vm_shared_region_slide_info_entry_v5_t s_info, mach_vm_size_t slide_info_size) { if (slide_info_size < sizeof(struct vm_shared_region_slide_info_entry_v5)) { printf("%s bad slide_info_size: %lx\n", __func__, (uintptr_t)slide_info_size); return KERN_FAILURE; } if (s_info->page_size != PAGE_SIZE_FOR_SR_SLIDE_16KB) { printf("vm_shared_region_slide_sanity_check_v5: s_info->page_size != PAGE_SIZE_FOR_SR_SL 0x%llx != 0x%llx\n", (uint64_t)s_info->page_size, (uint64_t)PAGE_SIZE_FOR_SR_SLIDE_16KB); return KERN_FAILURE; } uint32_t page_starts_count = s_info->page_starts_count; mach_vm_size_t num_trailing_entries = page_starts_count; mach_vm_size_t trailing_size = num_trailing_entries << 1; mach_vm_size_t required_size = sizeof(*s_info) + trailing_size; if (required_size < sizeof(*s_info)) { printf("vm_shared_region_slide_sanity_check_v5: required_size != sizeof(*s_info) 0x%llx != 0x%llx\n", (uint64_t)required_size, (uint64_t)sizeof(*s_info)); return KERN_FAILURE; } if (required_size > slide_info_size) { printf("vm_shared_region_slide_sanity_check_v5: required_size != slide_info_size 0x%llx != 0x%llx\n", (uint64_t)required_size, (uint64_t)slide_info_size); return KERN_FAILURE; } return KERN_SUCCESS; } static kern_return_t vm_shared_region_slide_sanity_check( vm_shared_region_slide_info_entry_t s_info, mach_vm_size_t s_info_size) { kern_return_t kr; switch (s_info->version) { case 1: kr = vm_shared_region_slide_sanity_check_v1(&s_info->v1); break; case 2: kr = vm_shared_region_slide_sanity_check_v2(&s_info->v2, s_info_size); break; case 3: kr = vm_shared_region_slide_sanity_check_v3(&s_info->v3, s_info_size); break; case 4: kr = vm_shared_region_slide_sanity_check_v4(&s_info->v4, s_info_size); break; case 5: kr = vm_shared_region_slide_sanity_check_v5(&s_info->v5, s_info_size); break; default: kr = KERN_FAILURE; } return kr; } static kern_return_t vm_shared_region_slide_page_v1(vm_shared_region_slide_info_t si, vm_offset_t vaddr, uint32_t pageIndex) { uint16_t *toc = NULL; slide_info_entry_toc_t bitmap = NULL; uint32_t i = 0, j = 0; uint8_t b = 0; uint32_t slide = si->si_slide; int is_64 = task_has_64Bit_addr(current_task()); vm_shared_region_slide_info_entry_v1_t s_info = &si->si_slide_info_entry->v1; toc = (uint16_t*)((uintptr_t)s_info + s_info->toc_offset); if (pageIndex >= s_info->toc_count) { printf("No slide entry for this page in toc. PageIndex: %d Toc Count: %d\n", pageIndex, s_info->toc_count); } else { uint16_t entryIndex = (uint16_t)(toc[pageIndex]); slide_info_entry_toc_t slide_info_entries = (slide_info_entry_toc_t)((uintptr_t)s_info + s_info->entry_offset); if (entryIndex >= s_info->entry_count) { printf("No sliding bitmap entry for entryIndex: %d amongst %d entries\n", entryIndex, s_info->entry_count); } else { bitmap = &slide_info_entries[entryIndex]; for (i = 0; i < NUM_SLIDING_BITMAPS_PER_PAGE; ++i) { b = bitmap->entry[i]; if (b != 0) { for (j = 0; j < 8; ++j) { if (b & (1 << j)) { uint32_t *ptr_to_slide; uint32_t old_value; ptr_to_slide = (uint32_t*)((uintptr_t)(vaddr) + (sizeof(uint32_t) * (i * 8 + j))); old_value = *ptr_to_slide; *ptr_to_slide += slide; if (is_64 && *ptr_to_slide < old_value) { /* * We just slid the low 32 bits of a 64-bit pointer * and it looks like there should have been a carry-over * to the upper 32 bits. * The sliding failed... */ printf("vm_shared_region_slide() carry over: i=%d j=%d b=0x%x slide=0x%x old=0x%x new=0x%x\n", i, j, b, slide, old_value, *ptr_to_slide); return KERN_FAILURE; } } } } } } } return KERN_SUCCESS; } static kern_return_t rebase_chain_32( uint8_t *page_content, uint16_t start_offset, uint32_t slide_amount, vm_shared_region_slide_info_entry_v2_t s_info) { const uint32_t last_page_offset = PAGE_SIZE_FOR_SR_SLIDE - sizeof(uint32_t); const uint32_t delta_mask = (uint32_t)(s_info->delta_mask); const uint32_t value_mask = ~delta_mask; const uint32_t value_add = (uint32_t)(s_info->value_add); const uint32_t delta_shift = __builtin_ctzll(delta_mask) - 2; uint32_t page_offset = start_offset; uint32_t delta = 1; while (delta != 0 && page_offset <= last_page_offset) { uint8_t *loc; uint32_t value; loc = page_content + page_offset; memcpy(&value, loc, sizeof(value)); delta = (value & delta_mask) >> delta_shift; value &= value_mask; if (value != 0) { value += value_add; value += slide_amount; } memcpy(loc, &value, sizeof(value)); page_offset += delta; } /* If the offset went past the end of the page, then the slide data is invalid. */ if (page_offset > last_page_offset) { return KERN_FAILURE; } return KERN_SUCCESS; } static kern_return_t rebase_chain_64( uint8_t *page_content, uint16_t start_offset, uint32_t slide_amount, vm_shared_region_slide_info_entry_v2_t s_info) { const uint32_t last_page_offset = PAGE_SIZE_FOR_SR_SLIDE - sizeof(uint64_t); const uint64_t delta_mask = s_info->delta_mask; const uint64_t value_mask = ~delta_mask; const uint64_t value_add = s_info->value_add; const uint64_t delta_shift = __builtin_ctzll(delta_mask) - 2; uint32_t page_offset = start_offset; uint32_t delta = 1; while (delta != 0 && page_offset <= last_page_offset) { uint8_t *loc; uint64_t value; loc = page_content + page_offset; memcpy(&value, loc, sizeof(value)); delta = (uint32_t)((value & delta_mask) >> delta_shift); value &= value_mask; if (value != 0) { value += value_add; value += slide_amount; } memcpy(loc, &value, sizeof(value)); page_offset += delta; } if (page_offset + sizeof(uint32_t) == PAGE_SIZE_FOR_SR_SLIDE) { /* If a pointer straddling the page boundary needs to be adjusted, then * add the slide to the lower half. The encoding guarantees that the upper * half on the next page will need no masking. * * This assumes a little-endian machine and that the region being slid * never crosses a 4 GB boundary. */ uint8_t *loc = page_content + page_offset; uint32_t value; memcpy(&value, loc, sizeof(value)); value += slide_amount; memcpy(loc, &value, sizeof(value)); } else if (page_offset > last_page_offset) { return KERN_FAILURE; } return KERN_SUCCESS; } static kern_return_t rebase_chain( boolean_t is_64, uint32_t pageIndex, uint8_t *page_content, uint16_t start_offset, uint32_t slide_amount, vm_shared_region_slide_info_entry_v2_t s_info) { kern_return_t kr; if (is_64) { kr = rebase_chain_64(page_content, start_offset, slide_amount, s_info); } else { kr = rebase_chain_32(page_content, start_offset, slide_amount, s_info); } if (kr != KERN_SUCCESS) { printf("vm_shared_region_slide_page() offset overflow: pageIndex=%u, start_offset=%u, slide_amount=%u\n", pageIndex, start_offset, slide_amount); } return kr; } static kern_return_t vm_shared_region_slide_page_v2(vm_shared_region_slide_info_t si, vm_offset_t vaddr, uint32_t pageIndex) { vm_shared_region_slide_info_entry_v2_t s_info = &si->si_slide_info_entry->v2; const uint32_t slide_amount = si->si_slide; /* The high bits of the delta_mask field are nonzero precisely when the shared * cache is 64-bit. */ const boolean_t is_64 = (s_info->delta_mask >> 32) != 0; const uint16_t *page_starts = (uint16_t *)((uintptr_t)s_info + s_info->page_starts_offset); const uint16_t *page_extras = (uint16_t *)((uintptr_t)s_info + s_info->page_extras_offset); uint8_t *page_content = (uint8_t *)vaddr; uint16_t page_entry; if (pageIndex >= s_info->page_starts_count) { printf("vm_shared_region_slide_page() did not find page start in slide info: pageIndex=%u, count=%u\n", pageIndex, s_info->page_starts_count); return KERN_FAILURE; } page_entry = page_starts[pageIndex]; if (page_entry == DYLD_CACHE_SLIDE_PAGE_ATTR_NO_REBASE) { return KERN_SUCCESS; } if (page_entry & DYLD_CACHE_SLIDE_PAGE_ATTR_EXTRA) { uint16_t chain_index = page_entry & DYLD_CACHE_SLIDE_PAGE_VALUE; uint16_t info; do { uint16_t page_start_offset; kern_return_t kr; if (chain_index >= s_info->page_extras_count) { printf("vm_shared_region_slide_page() out-of-bounds extras index: index=%u, count=%u\n", chain_index, s_info->page_extras_count); return KERN_FAILURE; } info = page_extras[chain_index]; page_start_offset = (uint16_t)((info & DYLD_CACHE_SLIDE_PAGE_VALUE) << DYLD_CACHE_SLIDE_PAGE_OFFSET_SHIFT); kr = rebase_chain(is_64, pageIndex, page_content, page_start_offset, slide_amount, s_info); if (kr != KERN_SUCCESS) { return KERN_FAILURE; } chain_index++; } while (!(info & DYLD_CACHE_SLIDE_PAGE_ATTR_END)); } else { const uint16_t page_start_offset = (uint16_t)(page_entry << DYLD_CACHE_SLIDE_PAGE_OFFSET_SHIFT); kern_return_t kr; kr = rebase_chain(is_64, pageIndex, page_content, page_start_offset, slide_amount, s_info); if (kr != KERN_SUCCESS) { return KERN_FAILURE; } } return KERN_SUCCESS; } static kern_return_t vm_shared_region_slide_page_v3( vm_shared_region_slide_info_t si, vm_offset_t vaddr, __unused mach_vm_offset_t uservaddr, uint32_t pageIndex, #if !__has_feature(ptrauth_calls) __unused #endif /* !__has_feature(ptrauth_calls) */ uint64_t jop_key) { vm_shared_region_slide_info_entry_v3_t s_info = &si->si_slide_info_entry->v3; const uint32_t slide_amount = si->si_slide; uint8_t *page_content = (uint8_t *)vaddr; uint16_t page_entry; if (pageIndex >= s_info->page_starts_count) { printf("vm_shared_region_slide_page() did not find page start in slide info: pageIndex=%u, count=%u\n", pageIndex, s_info->page_starts_count); return KERN_FAILURE; } page_entry = s_info->page_starts[pageIndex]; if (page_entry == DYLD_CACHE_SLIDE_V3_PAGE_ATTR_NO_REBASE) { return KERN_SUCCESS; } uint8_t* rebaseLocation = page_content; uint64_t delta = page_entry; do { rebaseLocation += delta; uint64_t value; memcpy(&value, rebaseLocation, sizeof(value)); delta = ((value & 0x3FF8000000000000) >> 51) * sizeof(uint64_t); // A pointer is one of : // { // uint64_t pointerValue : 51; // uint64_t offsetToNextPointer : 11; // uint64_t isBind : 1 = 0; // uint64_t authenticated : 1 = 0; // } // { // uint32_t offsetFromSharedCacheBase; // uint16_t diversityData; // uint16_t hasAddressDiversity : 1; // uint16_t hasDKey : 1; // uint16_t hasBKey : 1; // uint16_t offsetToNextPointer : 11; // uint16_t isBind : 1; // uint16_t authenticated : 1 = 1; // } bool isBind = (value & (1ULL << 62)) != 0; if (isBind) { #if CONFIG_SPTM pmap_batch_sign_user_ptr(NULL, NULL, 0, 0, 0); assert(preemption_enabled()); #endif /* CONFIG_SPTM */ return KERN_FAILURE; } #if __has_feature(ptrauth_calls) uint16_t diversity_data = (uint16_t)(value >> 32); bool hasAddressDiversity = (value & (1ULL << 48)) != 0; ptrauth_key key = (ptrauth_key)((value >> 49) & 0x3); #endif /* __has_feature(ptrauth_calls) */ bool isAuthenticated = (value & (1ULL << 63)) != 0; if (isAuthenticated) { // The new value for a rebase is the low 32-bits of the threaded value plus the slide. value = (value & 0xFFFFFFFF) + slide_amount; // Add in the offset from the mach_header const uint64_t value_add = s_info->value_add; value += value_add; #if __has_feature(ptrauth_calls) uint64_t discriminator = diversity_data; if (hasAddressDiversity) { // First calculate a new discriminator using the address of where we are trying to store the value uintptr_t pageOffset = rebaseLocation - page_content; discriminator = __builtin_ptrauth_blend_discriminator((void*)(((uintptr_t)uservaddr) + pageOffset), discriminator); } if (jop_key != 0 && si->si_ptrauth && !arm_user_jop_disabled()) { #if CONFIG_SPTM pmap_batch_sign_user_ptr(rebaseLocation, (void *)value, key, discriminator, jop_key); #else /* CONFIG_SPTM */ /* * these pointers are used in user mode. disable the kernel key diversification * so we can sign them for use in user mode. */ value = (uintptr_t)pmap_sign_user_ptr((void *)value, key, discriminator, jop_key); memcpy(rebaseLocation, &value, sizeof(value)); #endif /* CONFIG_SPTM */ } else { memcpy(rebaseLocation, &value, sizeof(value)); } #endif /* __has_feature(ptrauth_calls) */ } else { // The new value for a rebase is the low 51-bits of the threaded value plus the slide. // Regular pointer which needs to fit in 51-bits of value. // C++ RTTI uses the top bit, so we'll allow the whole top-byte // and the bottom 43-bits to be fit in to 51-bits. uint64_t top8Bits = value & 0x0007F80000000000ULL; uint64_t bottom43Bits = value & 0x000007FFFFFFFFFFULL; uint64_t targetValue = (top8Bits << 13) | bottom43Bits; value = targetValue + slide_amount; memcpy(rebaseLocation, &value, sizeof(value)); } } while (delta != 0); #if CONFIG_SPTM /* Sign the leftovers if there's any. */ pmap_batch_sign_user_ptr(NULL, NULL, 0, 0, 0); assert(preemption_enabled()); #endif /* CONFIG_SPTM */ return KERN_SUCCESS; } static kern_return_t rebase_chainv4( uint8_t *page_content, uint16_t start_offset, uint32_t slide_amount, vm_shared_region_slide_info_entry_v4_t s_info) { const uint32_t last_page_offset = PAGE_SIZE_FOR_SR_SLIDE - sizeof(uint32_t); const uint32_t delta_mask = (uint32_t)(s_info->delta_mask); const uint32_t value_mask = ~delta_mask; const uint32_t value_add = (uint32_t)(s_info->value_add); const uint32_t delta_shift = __builtin_ctzll(delta_mask) - 2; uint32_t page_offset = start_offset; uint32_t delta = 1; while (delta != 0 && page_offset <= last_page_offset) { uint8_t *loc; uint32_t value; loc = page_content + page_offset; memcpy(&value, loc, sizeof(value)); delta = (value & delta_mask) >> delta_shift; value &= value_mask; if ((value & 0xFFFF8000) == 0) { // small positive non-pointer, use as-is } else if ((value & 0x3FFF8000) == 0x3FFF8000) { // small negative non-pointer value |= 0xC0000000; } else { // pointer that needs rebasing value += value_add; value += slide_amount; } memcpy(loc, &value, sizeof(value)); page_offset += delta; } /* If the offset went past the end of the page, then the slide data is invalid. */ if (page_offset > last_page_offset) { return KERN_FAILURE; } return KERN_SUCCESS; } static kern_return_t vm_shared_region_slide_page_v4(vm_shared_region_slide_info_t si, vm_offset_t vaddr, uint32_t pageIndex) { vm_shared_region_slide_info_entry_v4_t s_info = &si->si_slide_info_entry->v4; const uint32_t slide_amount = si->si_slide; const uint16_t *page_starts = (uint16_t *)((uintptr_t)s_info + s_info->page_starts_offset); const uint16_t *page_extras = (uint16_t *)((uintptr_t)s_info + s_info->page_extras_offset); uint8_t *page_content = (uint8_t *)vaddr; uint16_t page_entry; if (pageIndex >= s_info->page_starts_count) { printf("vm_shared_region_slide_page() did not find page start in slide info: pageIndex=%u, count=%u\n", pageIndex, s_info->page_starts_count); return KERN_FAILURE; } page_entry = page_starts[pageIndex]; if (page_entry == DYLD_CACHE_SLIDE4_PAGE_NO_REBASE) { return KERN_SUCCESS; } if (page_entry & DYLD_CACHE_SLIDE4_PAGE_USE_EXTRA) { uint16_t chain_index = page_entry & DYLD_CACHE_SLIDE4_PAGE_INDEX; uint16_t info; do { uint16_t page_start_offset; kern_return_t kr; if (chain_index >= s_info->page_extras_count) { printf("vm_shared_region_slide_page() out-of-bounds extras index: index=%u, count=%u\n", chain_index, s_info->page_extras_count); return KERN_FAILURE; } info = page_extras[chain_index]; page_start_offset = (uint16_t)((info & DYLD_CACHE_SLIDE4_PAGE_INDEX) << DYLD_CACHE_SLIDE_PAGE_OFFSET_SHIFT); kr = rebase_chainv4(page_content, page_start_offset, slide_amount, s_info); if (kr != KERN_SUCCESS) { return KERN_FAILURE; } chain_index++; } while (!(info & DYLD_CACHE_SLIDE4_PAGE_EXTRA_END)); } else { const uint16_t page_start_offset = (uint16_t)(page_entry << DYLD_CACHE_SLIDE_PAGE_OFFSET_SHIFT); kern_return_t kr; kr = rebase_chainv4(page_content, page_start_offset, slide_amount, s_info); if (kr != KERN_SUCCESS) { return KERN_FAILURE; } } return KERN_SUCCESS; } static kern_return_t vm_shared_region_slide_page_v5( vm_shared_region_slide_info_t si, vm_offset_t vaddr, __unused mach_vm_offset_t uservaddr, uint32_t pageIndex, #if !__has_feature(ptrauth_calls) __unused #endif /* !__has_feature(ptrauth_calls) */ uint64_t jop_key) { vm_shared_region_slide_info_entry_v5_t s_info = &si->si_slide_info_entry->v5; const uint32_t slide_amount = si->si_slide; const uint64_t value_add = s_info->value_add; uint8_t *page_content = (uint8_t *)vaddr; uint16_t page_entry; if (pageIndex >= s_info->page_starts_count) { printf("vm_shared_region_slide_page() did not find page start in slide info: pageIndex=%u, count=%u\n", pageIndex, s_info->page_starts_count); return KERN_FAILURE; } page_entry = s_info->page_starts[pageIndex]; if (page_entry == DYLD_CACHE_SLIDE_V5_PAGE_ATTR_NO_REBASE) { return KERN_SUCCESS; } uint8_t* rebaseLocation = page_content; uint64_t delta = page_entry; do { rebaseLocation += delta; uint64_t value; memcpy(&value, rebaseLocation, sizeof(value)); delta = ((value & 0x7FF0000000000000ULL) >> 52) * sizeof(uint64_t); // A pointer is one of : // { // uint64_t runtimeOffset : 34, // offset from the start of the shared cache // high8 : 8, // unused : 10, // next : 11, // 8-byte stide // auth : 1; // == 0 // } // { // uint64_t runtimeOffset : 34, // offset from the start of the shared cache // diversity : 16, // addrDiv : 1, // keyIsData : 1, // implicitly always the 'A' key. 0 -> IA. 1 -> DA // next : 11, // 8-byte stide // auth : 1; // == 1 // } #if __has_feature(ptrauth_calls) bool addrDiv = ((value & (1ULL << 50)) != 0); bool keyIsData = ((value & (1ULL << 51)) != 0); // the key is always A, and the bit tells us if its IA or ID ptrauth_key key = keyIsData ? ptrauth_key_asda : ptrauth_key_asia; uint16_t diversity = (uint16_t)((value >> 34) & 0xFFFF); #endif /* __has_feature(ptrauth_calls) */ uint64_t high8 = (value << 22) & 0xFF00000000000000ULL; bool isAuthenticated = (value & (1ULL << 63)) != 0; // The new value for a rebase is the low 34-bits of the threaded value plus the base plus slide. value = (value & 0x3FFFFFFFFULL) + value_add + slide_amount; if (isAuthenticated) { #if __has_feature(ptrauth_calls) uint64_t discriminator = diversity; if (addrDiv) { // First calculate a new discriminator using the address of where we are trying to store the value uintptr_t pageOffset = rebaseLocation - page_content; discriminator = __builtin_ptrauth_blend_discriminator((void*)(((uintptr_t)uservaddr) + pageOffset), discriminator); } if (jop_key != 0 && si->si_ptrauth && !arm_user_jop_disabled()) { #if CONFIG_SPTM pmap_batch_sign_user_ptr(rebaseLocation, (void *)value, key, discriminator, jop_key); #else /* CONFIG_SPTM */ /* * these pointers are used in user mode. disable the kernel key diversification * so we can sign them for use in user mode. */ value = (uintptr_t)pmap_sign_user_ptr((void *)value, key, discriminator, jop_key); memcpy(rebaseLocation, &value, sizeof(value)); #endif /* CONFIG_SPTM */ } else { memcpy(rebaseLocation, &value, sizeof(value)); } #endif /* __has_feature(ptrauth_calls) */ } else { // the value already has the correct low bits, so just add in the high8 if it exists value += high8; memcpy(rebaseLocation, &value, sizeof(value)); } } while (delta != 0); #if CONFIG_SPTM /* Sign the leftovers if there's any. */ pmap_batch_sign_user_ptr(NULL, NULL, 0, 0, 0); assert(preemption_enabled()); #endif /* CONFIG_SPTM */ return KERN_SUCCESS; } kern_return_t vm_shared_region_slide_page( vm_shared_region_slide_info_t si, vm_offset_t vaddr, mach_vm_offset_t uservaddr, uint32_t pageIndex, uint64_t jop_key) { switch (si->si_slide_info_entry->version) { case 1: return vm_shared_region_slide_page_v1(si, vaddr, pageIndex); case 2: return vm_shared_region_slide_page_v2(si, vaddr, pageIndex); case 3: return vm_shared_region_slide_page_v3(si, vaddr, uservaddr, pageIndex, jop_key); case 4: return vm_shared_region_slide_page_v4(si, vaddr, pageIndex); case 5: return vm_shared_region_slide_page_v5(si, vaddr, uservaddr, pageIndex, jop_key); default: return KERN_FAILURE; } } /******************************************************************************/ /* Comm page support */ /******************************************************************************/ SECURITY_READ_ONLY_LATE(ipc_port_t) commpage32_handle = IPC_PORT_NULL; SECURITY_READ_ONLY_LATE(ipc_port_t) commpage64_handle = IPC_PORT_NULL; SECURITY_READ_ONLY_LATE(vm_named_entry_t) commpage32_entry = NULL; SECURITY_READ_ONLY_LATE(vm_named_entry_t) commpage64_entry = NULL; SECURITY_READ_ONLY_LATE(vm_map_t) commpage32_map = VM_MAP_NULL; SECURITY_READ_ONLY_LATE(vm_map_t) commpage64_map = VM_MAP_NULL; SECURITY_READ_ONLY_LATE(ipc_port_t) commpage_text32_handle = IPC_PORT_NULL; SECURITY_READ_ONLY_LATE(ipc_port_t) commpage_text64_handle = IPC_PORT_NULL; SECURITY_READ_ONLY_LATE(vm_named_entry_t) commpage_text32_entry = NULL; SECURITY_READ_ONLY_LATE(vm_named_entry_t) commpage_text64_entry = NULL; SECURITY_READ_ONLY_LATE(vm_map_t) commpage_text32_map = VM_MAP_NULL; SECURITY_READ_ONLY_LATE(vm_map_t) commpage_text64_map = VM_MAP_NULL; SECURITY_READ_ONLY_LATE(user32_addr_t) commpage_text32_location = 0; SECURITY_READ_ONLY_LATE(user64_addr_t) commpage_text64_location = 0; #if defined(__i386__) || defined(__x86_64__) /* * Create a memory entry, VM submap and pmap for one commpage. */ static void _vm_commpage_init( ipc_port_t *handlep, vm_map_size_t size) { vm_named_entry_t mem_entry; vm_map_t new_map; SHARED_REGION_TRACE_DEBUG( ("commpage: -> _init(0x%llx)\n", (long long)size)); pmap_t new_pmap = pmap_create_options(NULL, 0, 0); if (new_pmap == NULL) { panic("_vm_commpage_init: could not allocate pmap"); } new_map = vm_map_create_options(new_pmap, 0, size, VM_MAP_CREATE_DEFAULT); new_map->vmmap_sealed = VM_MAP_WILL_BE_SEALED; mem_entry = mach_memory_entry_allocate(handlep); mem_entry->backing.map = new_map; mem_entry->internal = TRUE; mem_entry->is_sub_map = TRUE; mem_entry->offset = 0; mem_entry->protection = VM_PROT_ALL; mem_entry->size = size; SHARED_REGION_TRACE_DEBUG( ("commpage: _init(0x%llx) <- %p\n", (long long)size, (void *)VM_KERNEL_ADDRPERM(*handlep))); } #endif /* * Initialize the comm text pages at boot time */ void vm_commpage_text_init(void) { SHARED_REGION_TRACE_DEBUG( ("commpage text: ->init()\n")); #if defined(__i386__) || defined(__x86_64__) /* create the 32 bit comm text page */ unsigned int offset = (random() % _PFZ32_SLIDE_RANGE) << PAGE_SHIFT; /* restricting to 32bMAX-2PAGE */ _vm_commpage_init(&commpage_text32_handle, _COMM_PAGE_TEXT_AREA_LENGTH); commpage_text32_entry = mach_memory_entry_from_port(commpage_text32_handle); commpage_text32_map = commpage_text32_entry->backing.map; commpage_text32_location = (user32_addr_t) (_COMM_PAGE32_TEXT_START + offset); /* XXX if (cpu_is_64bit_capable()) ? */ /* create the 64-bit comm page */ offset = (random() % _PFZ64_SLIDE_RANGE) << PAGE_SHIFT; /* restricting sliding upto 2Mb range */ _vm_commpage_init(&commpage_text64_handle, _COMM_PAGE_TEXT_AREA_LENGTH); commpage_text64_entry = mach_memory_entry_from_port(commpage_text64_handle); commpage_text64_map = commpage_text64_entry->backing.map; commpage_text64_location = (user64_addr_t) (_COMM_PAGE64_TEXT_START + offset); #endif commpage_text_populate(); /* populate the routines in here */ SHARED_REGION_TRACE_DEBUG( ("commpage text: init() <-\n")); } /* * Initialize the comm pages at boot time. */ void vm_commpage_init(void) { SHARED_REGION_TRACE_DEBUG( ("commpage: -> init()\n")); #if defined(__i386__) || defined(__x86_64__) /* create the 32-bit comm page */ _vm_commpage_init(&commpage32_handle, _COMM_PAGE32_AREA_LENGTH); commpage32_entry = mach_memory_entry_from_port(commpage32_handle); commpage32_map = commpage32_entry->backing.map; /* XXX if (cpu_is_64bit_capable()) ? */ /* create the 64-bit comm page */ _vm_commpage_init(&commpage64_handle, _COMM_PAGE64_AREA_LENGTH); commpage64_entry = mach_memory_entry_from_port(commpage64_handle); commpage64_map = commpage64_entry->backing.map; #endif /* __i386__ || __x86_64__ */ /* populate them according to this specific platform */ commpage_populate(); __commpage_setup = 1; #if XNU_TARGET_OS_OSX if (__system_power_source == 0) { post_sys_powersource_internal(0, 1); } #endif /* XNU_TARGET_OS_OSX */ SHARED_REGION_TRACE_DEBUG( ("commpage: init() <-\n")); } /* * Enter the appropriate comm page into the task's address space. * This is called at exec() time via vm_map_exec(). */ kern_return_t vm_commpage_enter( vm_map_t map, task_t task, boolean_t is64bit) { #if defined(__arm64__) #pragma unused(is64bit) (void)task; (void)map; pmap_insert_commpage(vm_map_pmap(map)); return KERN_SUCCESS; #else ipc_port_t commpage_handle, commpage_text_handle; vm_map_offset_t commpage_address, objc_address, commpage_text_address; vm_map_size_t commpage_size, objc_size, commpage_text_size; vm_map_kernel_flags_t vmk_flags; kern_return_t kr; SHARED_REGION_TRACE_DEBUG( ("commpage: -> enter(%p,%p)\n", (void *)VM_KERNEL_ADDRPERM(map), (void *)VM_KERNEL_ADDRPERM(task))); commpage_text_size = _COMM_PAGE_TEXT_AREA_LENGTH; /* the comm page is likely to be beyond the actual end of the VM map */ vmk_flags = VM_MAP_KERNEL_FLAGS_FIXED(); vmk_flags.vmkf_beyond_max = TRUE; /* select the appropriate comm page for this task */ assert(!(is64bit ^ vm_map_is_64bit(map))); if (is64bit) { commpage_handle = commpage64_handle; commpage_address = (vm_map_offset_t) _COMM_PAGE64_BASE_ADDRESS; commpage_size = _COMM_PAGE64_AREA_LENGTH; objc_size = _COMM_PAGE64_OBJC_SIZE; objc_address = _COMM_PAGE64_OBJC_BASE; commpage_text_handle = commpage_text64_handle; commpage_text_address = (vm_map_offset_t) commpage_text64_location; } else { commpage_handle = commpage32_handle; commpage_address = (vm_map_offset_t)(unsigned) _COMM_PAGE32_BASE_ADDRESS; commpage_size = _COMM_PAGE32_AREA_LENGTH; objc_size = _COMM_PAGE32_OBJC_SIZE; objc_address = _COMM_PAGE32_OBJC_BASE; commpage_text_handle = commpage_text32_handle; commpage_text_address = (vm_map_offset_t) commpage_text32_location; } if ((commpage_address & (pmap_commpage_size_min(map->pmap) - 1)) == 0 && (commpage_size & (pmap_commpage_size_min(map->pmap) - 1)) == 0) { /* the commpage is properly aligned or sized for pmap-nesting */ vmk_flags.vm_tag = VM_MEMORY_SHARED_PMAP; vmk_flags.vmkf_nested_pmap = TRUE; } /* map the comm page in the task's address space */ assert(commpage_handle != IPC_PORT_NULL); kr = mach_vm_map_kernel( map, vm_sanitize_wrap_addr_ref(&commpage_address), commpage_size, 0, vmk_flags, commpage_handle, 0, FALSE, VM_PROT_READ, VM_PROT_READ, VM_INHERIT_SHARE); if (kr != KERN_SUCCESS) { SHARED_REGION_TRACE_ERROR( ("commpage: enter(%p,0x%llx,0x%llx) " "commpage %p mapping failed 0x%x\n", (void *)VM_KERNEL_ADDRPERM(map), (long long)commpage_address, (long long)commpage_size, (void *)VM_KERNEL_ADDRPERM(commpage_handle), kr)); } /* map the comm text page in the task's address space */ assert(commpage_text_handle != IPC_PORT_NULL); kr = mach_vm_map_kernel( map, vm_sanitize_wrap_addr_ref(&commpage_text_address), commpage_text_size, 0, vmk_flags, commpage_text_handle, 0, FALSE, VM_PROT_READ | VM_PROT_EXECUTE, VM_PROT_READ | VM_PROT_EXECUTE, VM_INHERIT_SHARE); if (kr != KERN_SUCCESS) { SHARED_REGION_TRACE_ERROR( ("commpage text: enter(%p,0x%llx,0x%llx) " "commpage text %p mapping failed 0x%x\n", (void *)VM_KERNEL_ADDRPERM(map), (long long)commpage_text_address, (long long)commpage_text_size, (void *)VM_KERNEL_ADDRPERM(commpage_text_handle), kr)); } /* * Since we're here, we also pre-allocate some virtual space for the * Objective-C run-time, if needed... */ if (objc_size != 0) { kr = mach_vm_map_kernel( map, vm_sanitize_wrap_addr_ref(&objc_address), objc_size, 0, vmk_flags, IPC_PORT_NULL, 0, FALSE, VM_PROT_ALL, VM_PROT_ALL, VM_INHERIT_DEFAULT); if (kr != KERN_SUCCESS) { SHARED_REGION_TRACE_ERROR( ("commpage: enter(%p,0x%llx,0x%llx) " "objc mapping failed 0x%x\n", (void *)VM_KERNEL_ADDRPERM(map), (long long)objc_address, (long long)objc_size, kr)); } } SHARED_REGION_TRACE_DEBUG( ("commpage: enter(%p,%p) <- 0x%x\n", (void *)VM_KERNEL_ADDRPERM(map), (void *)VM_KERNEL_ADDRPERM(task), kr)); return kr; #endif } int vm_shared_region_slide( uint32_t slide, mach_vm_offset_t entry_start_address, mach_vm_size_t entry_size, mach_vm_offset_t slide_start, mach_vm_size_t slide_size, mach_vm_offset_t slid_mapping, memory_object_control_t sr_file_control, vm_prot_t prot) { vm_shared_region_t sr; kern_return_t error; SHARED_REGION_TRACE_DEBUG( ("vm_shared_region_slide: -> slide %#x, entry_start %#llx, entry_size %#llx, slide_start %#llx, slide_size %#llx\n", slide, entry_start_address, entry_size, slide_start, slide_size)); sr = vm_shared_region_get(current_task()); if (sr == NULL) { /* * This may happen if our process was terminated, in which case no reason * to keep setting up the shared region. */ printf("%s: no shared region?\n", __FUNCTION__); SHARED_REGION_TRACE_DEBUG( ("vm_shared_region_slide: <- %d (no shared region)\n", KERN_FAILURE)); return KERN_FAILURE; } /* * Protect from concurrent access. */ vm_shared_region_lock(); while (sr->sr_slide_in_progress) { vm_shared_region_sleep(&sr->sr_slide_in_progress, THREAD_UNINT); } sr->sr_slide_in_progress = current_thread(); vm_shared_region_unlock(); error = vm_shared_region_slide_mapping(sr, (user_addr_t)slide_start, slide_size, entry_start_address, entry_size, slid_mapping, slide, sr_file_control, prot); if (error) { printf("slide_info initialization failed with kr=%d\n", error); } vm_shared_region_lock(); assert(sr->sr_slide_in_progress == current_thread()); sr->sr_slide_in_progress = THREAD_NULL; vm_shared_region_wakeup(&sr->sr_slide_in_progress); #if XNU_TARGET_OS_OSX if (error == KERN_SUCCESS) { shared_region_completed_slide = TRUE; } #endif /* XNU_TARGET_OS_OSX */ vm_shared_region_unlock(); vm_shared_region_deallocate(sr); SHARED_REGION_TRACE_DEBUG( ("vm_shared_region_slide: <- %d\n", error)); return error; } /* * Used during Authenticated Root Volume macOS boot. * Launchd re-execs itself and wants the new launchd to use * the shared cache from the new root volume. This call * makes all the existing shared caches stale to allow * that to happen. */ void vm_shared_region_pivot(void) { vm_shared_region_t shared_region = NULL; vm_shared_region_lock(); queue_iterate(&vm_shared_region_queue, shared_region, vm_shared_region_t, sr_q) { assert(shared_region->sr_ref_count > 0); shared_region->sr_stale = TRUE; if (shared_region->sr_timer_call) { /* * We have a shared region ready to be destroyed * and just waiting for a delayed timer to fire. * Marking it stale cements its ineligibility to * be used ever again. So let's shorten the timer * aggressively down to 10 milliseconds and get rid of it. * This is a single quantum and we don't need to go * shorter than this duration. We want it to be short * enough, however, because we could have an unmount * of the volume hosting this shared region just behind * us. */ uint64_t deadline; assert(shared_region->sr_ref_count == 1); /* * Free the old timer call. Returns with a reference held. * If the old timer has fired and is waiting for the vm_shared_region_lock * lock, we will just return with an additional ref_count i.e. 2. * The old timer will then fire and just drop the ref count down to 1 * with no other modifications. */ vm_shared_region_reference_locked(shared_region); /* set up the timer. Keep the reference from above for this timer.*/ shared_region->sr_timer_call = thread_call_allocate( (thread_call_func_t) vm_shared_region_timeout, (thread_call_param_t) shared_region); /* schedule the timer */ clock_interval_to_deadline(10, /* 10 milliseconds */ NSEC_PER_MSEC, &deadline); thread_call_enter_delayed(shared_region->sr_timer_call, deadline); SHARED_REGION_TRACE_DEBUG( ("shared_region: pivot(%p): armed timer\n", (void *)VM_KERNEL_ADDRPERM(shared_region))); } } vm_shared_region_unlock(); } /* * Routine to mark any non-standard slide shared cache region as stale. * This causes the next "reslide" spawn to create a new shared region. */ void vm_shared_region_reslide_stale(boolean_t driverkit) { #if __has_feature(ptrauth_calls) vm_shared_region_t shared_region = NULL; vm_shared_region_lock(); queue_iterate(&vm_shared_region_queue, shared_region, vm_shared_region_t, sr_q) { assert(shared_region->sr_ref_count > 0); if (shared_region->sr_driverkit == driverkit && !shared_region->sr_stale && shared_region->sr_reslide) { shared_region->sr_stale = TRUE; vm_shared_region_reslide_count++; } } vm_shared_region_unlock(); #else (void)driverkit; #endif /* __has_feature(ptrauth_calls) */ } /* * report if the task is using a reslide shared cache region. */ bool vm_shared_region_is_reslide(__unused struct task *task) { bool is_reslide = FALSE; #if __has_feature(ptrauth_calls) vm_shared_region_t sr = vm_shared_region_get(task); if (sr != NULL) { is_reslide = sr->sr_reslide; vm_shared_region_deallocate(sr); } #endif /* __has_feature(ptrauth_calls) */ return is_reslide; } /* * This is called from powermanagement code to let kernel know the current source of power. * 0 if it is external source (connected to power ) * 1 if it is internal power source ie battery */ void #if XNU_TARGET_OS_OSX post_sys_powersource(int i) #else /* XNU_TARGET_OS_OSX */ post_sys_powersource(__unused int i) #endif /* XNU_TARGET_OS_OSX */ { #if XNU_TARGET_OS_OSX post_sys_powersource_internal(i, 0); #endif /* XNU_TARGET_OS_OSX */ } #if XNU_TARGET_OS_OSX static void post_sys_powersource_internal(int i, int internal) { if (internal == 0) { __system_power_source = i; } } #endif /* XNU_TARGET_OS_OSX */ void * vm_shared_region_root_dir( struct vm_shared_region *sr) { void *vnode; vm_shared_region_lock(); vnode = sr->sr_root_dir; vm_shared_region_unlock(); return vnode; } |