/* * Copyright (c) 2011-2013 Apple Inc. All rights reserved. * * @APPLE_OSREFERENCE_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. The rights granted to you under the License * may not be used to create, or enable the creation or redistribution of, * unlawful or unlicensed copies of an Apple operating system, or to * circumvent, violate, or enable the circumvention or violation of, any * terms of an Apple operating system software license agreement. * * 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_OSREFERENCE_LICENSE_HEADER_END@ */ #include #include #include #include #include #include #include #include "assym.s" #include #include "dwarf_unwind.h" #if __ARM_KERNEL_PROTECT__ #include #endif #if XNU_MONITOR /* * CHECK_EXCEPTION_RETURN_DISPATCH_PPL * * Checks if an exception was taken from the PPL, and if so, trampolines back * into the PPL. * x26 - 0 if the exception was taken while in the kernel, 1 if the * exception was taken while in the PPL. */ .macro CHECK_EXCEPTION_RETURN_DISPATCH_PPL cmp x26, xzr b.eq 1f /* Return to the PPL. */ mov x15, #0 mov w10, #PPL_STATE_EXCEPTION #error "XPRR configuration error" 1: .endmacro #endif /* XNU_MONITOR */ #define CBF_DISABLE 0 #define CBF_ENABLE 1 .macro COMPARE_BRANCH_FUSION #if defined(APPLE_ARM64_ARCH_FAMILY) mrs $1, ARM64_REG_HID1 .if $0 == CBF_DISABLE orr $1, $1, ARM64_REG_HID1_disCmpBrFusion .else mov $2, ARM64_REG_HID1_disCmpBrFusion bic $1, $1, $2 .endif msr ARM64_REG_HID1, $1 .if $0 == CBF_DISABLE isb sy .endif #endif .endmacro /* * MAP_KERNEL * * Restores the kernel EL1 mappings, if necessary. * * This may mutate x18. */ .macro MAP_KERNEL #if __ARM_KERNEL_PROTECT__ /* Switch to the kernel ASID (low bit set) for the task. */ mrs x18, TTBR0_EL1 orr x18, x18, #(1 << TTBR_ASID_SHIFT) msr TTBR0_EL1, x18 /* * We eschew some barriers on Apple CPUs, as relative ordering of writes * to the TTBRs and writes to the TCR should be ensured by the * microarchitecture. */ #if !defined(APPLE_ARM64_ARCH_FAMILY) isb sy #endif /* * Update the TCR to map the kernel now that we are using the kernel * ASID. */ MOV64 x18, TCR_EL1_BOOT msr TCR_EL1, x18 isb sy #endif /* __ARM_KERNEL_PROTECT__ */ .endmacro /* * BRANCH_TO_KVA_VECTOR * * Branches to the requested long exception vector in the kernelcache. * arg0 - The label to branch to * arg1 - The index of the label in exc_vectors_tables * * This may mutate x18. */ .macro BRANCH_TO_KVA_VECTOR #if __ARM_KERNEL_PROTECT__ /* * Find the kernelcache table for the exception vectors by accessing * the per-CPU data. */ mrs x18, TPIDR_EL1 ldr x18, [x18, ACT_CPUDATAP] ldr x18, [x18, CPU_EXC_VECTORS] /* * Get the handler for this exception and jump to it. */ ldr x18, [x18, #($1 << 3)] br x18 #else b $0 #endif /* __ARM_KERNEL_PROTECT__ */ .endmacro /* * CHECK_KERNEL_STACK * * Verifies that the kernel stack is aligned and mapped within an expected * stack address range. Note: happens before saving registers (in case we can't * save to kernel stack). * * Expects: * {x0, x1} - saved * x1 - Exception syndrome * sp - Saved state * * Seems like we need an unused argument to the macro for the \@ syntax to work * */ .macro CHECK_KERNEL_STACK unused stp x2, x3, [sp, #-16]! // Save {x2-x3} and x1, x1, #ESR_EC_MASK // Mask the exception class mov x2, #(ESR_EC_SP_ALIGN << ESR_EC_SHIFT) cmp x1, x2 // If we have a stack alignment exception b.eq Lcorrupt_stack_\@ // ...the stack is definitely corrupted mov x2, #(ESR_EC_DABORT_EL1 << ESR_EC_SHIFT) cmp x1, x2 // If we have a data abort, we need to b.ne Lvalid_stack_\@ // ...validate the stack pointer mrs x0, SP_EL0 // Get SP_EL0 mrs x1, TPIDR_EL1 // Get thread pointer Ltest_kstack_\@: ldr x2, [x1, TH_KSTACKPTR] // Get top of kernel stack sub x3, x2, KERNEL_STACK_SIZE // Find bottom of kernel stack cmp x0, x2 // if (SP_EL0 >= kstack top) b.ge Ltest_istack_\@ // jump to istack test cmp x0, x3 // if (SP_EL0 > kstack bottom) b.gt Lvalid_stack_\@ // stack pointer valid Ltest_istack_\@: ldr x1, [x1, ACT_CPUDATAP] // Load the cpu data ptr ldr x2, [x1, CPU_INTSTACK_TOP] // Get top of istack sub x3, x2, INTSTACK_SIZE_NUM // Find bottom of istack cmp x0, x2 // if (SP_EL0 >= istack top) b.ge Lcorrupt_stack_\@ // corrupt stack pointer cmp x0, x3 // if (SP_EL0 > istack bottom) b.gt Lvalid_stack_\@ // stack pointer valid Lcorrupt_stack_\@: ldp x2, x3, [sp], #16 ldp x0, x1, [sp], #16 sub sp, sp, ARM_CONTEXT_SIZE // Allocate exception frame stp x0, x1, [sp, SS64_X0] // Save x0, x1 to the exception frame stp x2, x3, [sp, SS64_X2] // Save x2, x3 to the exception frame mrs x0, SP_EL0 // Get SP_EL0 str x0, [sp, SS64_SP] // Save sp to the exception frame INIT_SAVED_STATE_FLAVORS sp, w0, w1 mov x0, sp // Copy exception frame pointer to x0 adrp x1, fleh_invalid_stack@page // Load address for fleh add x1, x1, fleh_invalid_stack@pageoff // fleh_dispatch64 will save register state before we get there b fleh_dispatch64 Lvalid_stack_\@: ldp x2, x3, [sp], #16 // Restore {x2-x3} .endmacro #if __ARM_KERNEL_PROTECT__ .section __DATA_CONST,__const .align 3 .globl EXT(exc_vectors_table) LEXT(exc_vectors_table) /* Table of exception handlers. * These handlers sometimes contain deadloops. * It's nice to have symbols for them when debugging. */ .quad el1_sp0_synchronous_vector_long .quad el1_sp0_irq_vector_long .quad el1_sp0_fiq_vector_long .quad el1_sp0_serror_vector_long .quad el1_sp1_synchronous_vector_long .quad el1_sp1_irq_vector_long .quad el1_sp1_fiq_vector_long .quad el1_sp1_serror_vector_long .quad el0_synchronous_vector_64_long .quad el0_irq_vector_64_long .quad el0_fiq_vector_64_long .quad el0_serror_vector_64_long #endif /* __ARM_KERNEL_PROTECT__ */ .text #if __ARM_KERNEL_PROTECT__ /* * We need this to be on a page boundary so that we may avoiding mapping * other text along with it. As this must be on the VM page boundary * (due to how the coredumping code currently works), this will be a * 16KB page boundary. */ .align 14 #else .align 12 #endif /* __ARM_KERNEL_PROTECT__ */ .globl EXT(ExceptionVectorsBase) LEXT(ExceptionVectorsBase) Lel1_sp0_synchronous_vector: BRANCH_TO_KVA_VECTOR el1_sp0_synchronous_vector_long, 0 .text .align 7 Lel1_sp0_irq_vector: BRANCH_TO_KVA_VECTOR el1_sp0_irq_vector_long, 1 .text .align 7 Lel1_sp0_fiq_vector: BRANCH_TO_KVA_VECTOR el1_sp0_fiq_vector_long, 2 .text .align 7 Lel1_sp0_serror_vector: BRANCH_TO_KVA_VECTOR el1_sp0_serror_vector_long, 3 .text .align 7 Lel1_sp1_synchronous_vector: BRANCH_TO_KVA_VECTOR el1_sp1_synchronous_vector_long, 4 .text .align 7 Lel1_sp1_irq_vector: BRANCH_TO_KVA_VECTOR el1_sp1_irq_vector_long, 5 .text .align 7 Lel1_sp1_fiq_vector: BRANCH_TO_KVA_VECTOR el1_sp1_fiq_vector_long, 6 .text .align 7 Lel1_sp1_serror_vector: BRANCH_TO_KVA_VECTOR el1_sp1_serror_vector_long, 7 .text .align 7 Lel0_synchronous_vector_64: MAP_KERNEL BRANCH_TO_KVA_VECTOR el0_synchronous_vector_64_long, 8 .text .align 7 Lel0_irq_vector_64: MAP_KERNEL BRANCH_TO_KVA_VECTOR el0_irq_vector_64_long, 9 .text .align 7 Lel0_fiq_vector_64: MAP_KERNEL BRANCH_TO_KVA_VECTOR el0_fiq_vector_64_long, 10 .text .align 7 Lel0_serror_vector_64: MAP_KERNEL BRANCH_TO_KVA_VECTOR el0_serror_vector_64_long, 11 /* Fill out the rest of the page */ .align 12 /********************************* * END OF EXCEPTION VECTORS PAGE * *********************************/ .macro EL1_SP0_VECTOR msr SPSel, #0 // Switch to SP0 sub sp, sp, ARM_CONTEXT_SIZE // Create exception frame stp x0, x1, [sp, SS64_X0] // Save x0, x1 to exception frame add x0, sp, ARM_CONTEXT_SIZE // Calculate the original stack pointer str x0, [sp, SS64_SP] // Save stack pointer to exception frame INIT_SAVED_STATE_FLAVORS sp, w0, w1 mov x0, sp // Copy saved state pointer to x0 .endmacro el1_sp0_synchronous_vector_long: stp x0, x1, [sp, #-16]! // Save x0 and x1 to the exception stack mrs x1, ESR_EL1 // Get the exception syndrome /* If the stack pointer is corrupt, it will manifest either as a data abort * (syndrome 0x25) or a misaligned pointer (syndrome 0x26). We can check * these quickly by testing bit 5 of the exception class. */ tbz x1, #(5 + ESR_EC_SHIFT), Lkernel_stack_valid CHECK_KERNEL_STACK Lkernel_stack_valid: ldp x0, x1, [sp], #16 // Restore x0 and x1 from the exception stack EL1_SP0_VECTOR adrp x1, EXT(fleh_synchronous)@page // Load address for fleh add x1, x1, EXT(fleh_synchronous)@pageoff b fleh_dispatch64 el1_sp0_irq_vector_long: EL1_SP0_VECTOR SWITCH_TO_INT_STACK adrp x1, EXT(fleh_irq)@page // Load address for fleh add x1, x1, EXT(fleh_irq)@pageoff b fleh_dispatch64 el1_sp0_fiq_vector_long: // ARM64_TODO write optimized decrementer EL1_SP0_VECTOR SWITCH_TO_INT_STACK adrp x1, EXT(fleh_fiq)@page // Load address for fleh add x1, x1, EXT(fleh_fiq)@pageoff b fleh_dispatch64 el1_sp0_serror_vector_long: EL1_SP0_VECTOR adrp x1, EXT(fleh_serror)@page // Load address for fleh add x1, x1, EXT(fleh_serror)@pageoff b fleh_dispatch64 .macro EL1_SP1_VECTOR sub sp, sp, ARM_CONTEXT_SIZE // Create exception frame stp x0, x1, [sp, SS64_X0] // Save x0, x1 to exception frame add x0, sp, ARM_CONTEXT_SIZE // Calculate the original stack pointer str x0, [sp, SS64_SP] // Save stack pointer to exception frame INIT_SAVED_STATE_FLAVORS sp, w0, w1 mov x0, sp // Copy saved state pointer to x0 .endmacro el1_sp1_synchronous_vector_long: b check_exception_stack Lel1_sp1_synchronous_valid_stack: #if defined(KERNEL_INTEGRITY_KTRR) b check_ktrr_sctlr_trap Lel1_sp1_synchronous_vector_continue: #endif EL1_SP1_VECTOR adrp x1, fleh_synchronous_sp1@page add x1, x1, fleh_synchronous_sp1@pageoff b fleh_dispatch64 el1_sp1_irq_vector_long: EL1_SP1_VECTOR adrp x1, fleh_irq_sp1@page add x1, x1, fleh_irq_sp1@pageoff b fleh_dispatch64 el1_sp1_fiq_vector_long: EL1_SP1_VECTOR adrp x1, fleh_fiq_sp1@page add x1, x1, fleh_fiq_sp1@pageoff b fleh_dispatch64 el1_sp1_serror_vector_long: EL1_SP1_VECTOR adrp x1, fleh_serror_sp1@page add x1, x1, fleh_serror_sp1@pageoff b fleh_dispatch64 .macro EL0_64_VECTOR stp x0, x1, [sp, #-16]! // Save x0 and x1 to the exception stack #if __ARM_KERNEL_PROTECT__ mov x18, #0 // Zero x18 to avoid leaking data to user SS #endif mrs x0, TPIDR_EL1 // Load the thread register mrs x1, SP_EL0 // Load the user stack pointer add x0, x0, ACT_CONTEXT // Calculate where we store the user context pointer ldr x0, [x0] // Load the user context pointer str x1, [x0, SS64_SP] // Store the user stack pointer in the user PCB msr SP_EL0, x0 // Copy the user PCB pointer to SP0 ldp x0, x1, [sp], #16 // Restore x0 and x1 from the exception stack msr SPSel, #0 // Switch to SP0 stp x0, x1, [sp, SS64_X0] // Save x0, x1 to the user PCB mrs x1, TPIDR_EL1 // Load the thread register mov x0, sp // Copy the user PCB pointer to x0 // x1 contains thread register .endmacro el0_synchronous_vector_64_long: EL0_64_VECTOR sync SWITCH_TO_KERN_STACK adrp x1, EXT(fleh_synchronous)@page // Load address for fleh add x1, x1, EXT(fleh_synchronous)@pageoff b fleh_dispatch64 el0_irq_vector_64_long: EL0_64_VECTOR irq SWITCH_TO_INT_STACK adrp x1, EXT(fleh_irq)@page // load address for fleh add x1, x1, EXT(fleh_irq)@pageoff b fleh_dispatch64 el0_fiq_vector_64_long: EL0_64_VECTOR fiq SWITCH_TO_INT_STACK adrp x1, EXT(fleh_fiq)@page // load address for fleh add x1, x1, EXT(fleh_fiq)@pageoff b fleh_dispatch64 el0_serror_vector_64_long: EL0_64_VECTOR serror SWITCH_TO_KERN_STACK adrp x1, EXT(fleh_serror)@page // load address for fleh add x1, x1, EXT(fleh_serror)@pageoff b fleh_dispatch64 /* * check_exception_stack * * Verifies that stack pointer at SP1 is within exception stack * If not, will simply hang as we have no more stack to fall back on. */ .text .align 2 check_exception_stack: mrs x18, TPIDR_EL1 // Get thread pointer cbz x18, Lvalid_exception_stack // Thread context may not be set early in boot ldr x18, [x18, ACT_CPUDATAP] cbz x18, . // If thread context is set, cpu data should be too ldr x18, [x18, CPU_EXCEPSTACK_TOP] cmp sp, x18 b.gt . // Hang if above exception stack top sub x18, x18, EXCEPSTACK_SIZE_NUM // Find bottom of exception stack cmp sp, x18 b.lt . // Hang if below exception stack bottom Lvalid_exception_stack: mov x18, #0 b Lel1_sp1_synchronous_valid_stack #if defined(KERNEL_INTEGRITY_KTRR) .text .align 2 check_ktrr_sctlr_trap: /* We may abort on an instruction fetch on reset when enabling the MMU by * writing SCTLR_EL1 because the page containing the privileged instruction is * not executable at EL1 (due to KTRR). The abort happens only on SP1 which * would otherwise panic unconditionally. Check for the condition and return * safe execution to the caller on behalf of the faulting function. * * Expected register state: * x22 - Kernel virtual base * x23 - Kernel physical base */ sub sp, sp, ARM_CONTEXT_SIZE // Make some space on the stack stp x0, x1, [sp, SS64_X0] // Stash x0, x1 mrs x0, ESR_EL1 // Check ESR for instr. fetch abort and x0, x0, #0xffffffffffffffc0 // Mask off ESR.ISS.IFSC movz w1, #0x8600, lsl #16 movk w1, #0x0000 cmp x0, x1 mrs x0, ELR_EL1 // Check for expected abort address adrp x1, _pinst_set_sctlr_trap_addr@page add x1, x1, _pinst_set_sctlr_trap_addr@pageoff sub x1, x1, x22 // Convert to physical address add x1, x1, x23 ccmp x0, x1, #0, eq ldp x0, x1, [sp, SS64_X0] // Restore x0, x1 add sp, sp, ARM_CONTEXT_SIZE // Clean up stack b.ne Lel1_sp1_synchronous_vector_continue msr ELR_EL1, lr // Return to caller ERET_CONTEXT_SYNCHRONIZING #endif /* defined(KERNEL_INTEGRITY_KTRR) || defined(KERNEL_INTEGRITY_CTRR) */ /* 64-bit first level exception handler dispatcher. * Completes register context saving and branches to FLEH. * Expects: * {x0, x1, sp} - saved * x0 - arm_context_t * x1 - address of FLEH * fp - previous stack frame if EL1 * lr - unused * sp - kernel stack */ .text .align 2 fleh_dispatch64: /* Save arm_saved_state64 */ SPILL_REGISTERS KERNEL_MODE /* If exception is from userspace, zero unused registers */ and x23, x23, #(PSR64_MODE_EL_MASK) cmp x23, #(PSR64_MODE_EL0) bne 1f SANITIZE_FPCR x25, x2, 2 // x25 is set to current FPCR by SPILL_REGISTERS 2: mov x2, #0 mov x3, #0 mov x4, #0 mov x5, #0 mov x6, #0 mov x7, #0 mov x8, #0 mov x9, #0 mov x10, #0 mov x11, #0 mov x12, #0 mov x13, #0 mov x14, #0 mov x15, #0 mov x16, #0 mov x17, #0 mov x18, #0 mov x19, #0 mov x20, #0 /* x21, x22 cleared in common case below */ mov x23, #0 mov x24, #0 mov x25, #0 #if !XNU_MONITOR mov x26, #0 #endif mov x27, #0 mov x28, #0 mov fp, #0 mov lr, #0 1: mov x21, x0 // Copy arm_context_t pointer to x21 mov x22, x1 // Copy handler routine to x22 #if XNU_MONITOR /* Zero x26 to indicate that this should not return to the PPL. */ mov x26, #0 #endif #if !CONFIG_SKIP_PRECISE_USER_KERNEL_TIME || HAS_FAST_CNTVCT tst x23, PSR64_MODE_EL_MASK // If any EL MODE bits are set, we're coming from b.ne 1f // kernel mode, so skip precise time update PUSH_FRAME bl EXT(timer_state_event_user_to_kernel) POP_FRAME mov x0, x21 // Reload arm_context_t pointer 1: #endif /* !CONFIG_SKIP_PRECISE_USER_KERNEL_TIME || HAS_FAST_CNTVCT */ /* Dispatch to FLEH */ br x22 .text .align 2 .global EXT(fleh_synchronous) LEXT(fleh_synchronous) UNWIND_PROLOGUE UNWIND_DIRECTIVES mrs x1, ESR_EL1 // Load exception syndrome mrs x2, FAR_EL1 // Load fault address /* At this point, the LR contains the value of ELR_EL1. In the case of an * instruction prefetch abort, this will be the faulting pc, which we know * to be invalid. This will prevent us from backtracing through the * exception if we put it in our stack frame, so we load the LR from the * exception saved state instead. */ and w3, w1, #(ESR_EC_MASK) lsr w3, w3, #(ESR_EC_SHIFT) mov w4, #(ESR_EC_IABORT_EL1) cmp w3, w4 b.eq Lfleh_sync_load_lr Lvalid_link_register: PUSH_FRAME bl EXT(sleh_synchronous) POP_FRAME #if XNU_MONITOR CHECK_EXCEPTION_RETURN_DISPATCH_PPL #endif mov x28, xzr // Don't need to check PFZ if there are ASTs b exception_return_dispatch Lfleh_sync_load_lr: ldr lr, [x0, SS64_LR] b Lvalid_link_register UNWIND_EPILOGUE /* Shared prologue code for fleh_irq and fleh_fiq. * Does any interrupt booking we may want to do * before invoking the handler proper. * Expects: * x0 - arm_context_t * x23 - CPSR * fp - Undefined live value (we may push a frame) * lr - Undefined live value (we may push a frame) * sp - Interrupt stack for the current CPU */ .macro BEGIN_INTERRUPT_HANDLER mrs x22, TPIDR_EL1 ldr x23, [x22, ACT_CPUDATAP] // Get current cpu /* Update IRQ count */ ldr w1, [x23, CPU_STAT_IRQ] add w1, w1, #1 // Increment count str w1, [x23, CPU_STAT_IRQ] // Update IRQ count ldr w1, [x23, CPU_STAT_IRQ_WAKE] add w1, w1, #1 // Increment count str w1, [x23, CPU_STAT_IRQ_WAKE] // Update post-wake IRQ count /* Increment preempt count */ ldr w1, [x22, ACT_PREEMPT_CNT] add w1, w1, #1 str w1, [x22, ACT_PREEMPT_CNT] /* Store context in int state */ str x0, [x23, CPU_INT_STATE] // Saved context in cpu_int_state .endmacro /* Shared epilogue code for fleh_irq and fleh_fiq. * Cleans up after the prologue, and may do a bit more * bookkeeping (kdebug related). * Expects: * x22 - Live TPIDR_EL1 value (thread address) * x23 - Address of the current CPU data structure * w24 - 0 if kdebug is disbled, nonzero otherwise * fp - Undefined live value (we may push a frame) * lr - Undefined live value (we may push a frame) * sp - Interrupt stack for the current CPU */ .macro END_INTERRUPT_HANDLER /* Clear int context */ str xzr, [x23, CPU_INT_STATE] /* Decrement preempt count */ ldr w0, [x22, ACT_PREEMPT_CNT] cbnz w0, 1f // Detect underflow b preempt_underflow 1: sub w0, w0, #1 str w0, [x22, ACT_PREEMPT_CNT] /* Switch back to kernel stack */ ldr x0, [x22, TH_KSTACKPTR] mov sp, x0 .endmacro .text .align 2 .global EXT(fleh_irq) LEXT(fleh_irq) BEGIN_INTERRUPT_HANDLER PUSH_FRAME bl EXT(sleh_irq) POP_FRAME END_INTERRUPT_HANDLER #if XNU_MONITOR CHECK_EXCEPTION_RETURN_DISPATCH_PPL #endif mov x28, #1 // Set a bit to check PFZ if there are ASTs b exception_return_dispatch .text .align 2 .global EXT(fleh_fiq_generic) LEXT(fleh_fiq_generic) PANIC_UNIMPLEMENTED .text .align 2 .global EXT(fleh_fiq) LEXT(fleh_fiq) BEGIN_INTERRUPT_HANDLER PUSH_FRAME bl EXT(sleh_fiq) POP_FRAME END_INTERRUPT_HANDLER #if XNU_MONITOR CHECK_EXCEPTION_RETURN_DISPATCH_PPL #endif mov x28, #1 // Set a bit to check PFZ if there are ASTs b exception_return_dispatch .text .align 2 .global EXT(fleh_serror) LEXT(fleh_serror) mrs x1, ESR_EL1 // Load exception syndrome mrs x2, FAR_EL1 // Load fault address PUSH_FRAME bl EXT(sleh_serror) POP_FRAME #if XNU_MONITOR CHECK_EXCEPTION_RETURN_DISPATCH_PPL #endif mov x28, xzr // Don't need to check PFZ If there are ASTs b exception_return_dispatch /* * Register state saved before we get here. */ .text .align 2 fleh_invalid_stack: mrs x1, ESR_EL1 // Load exception syndrome str x1, [x0, SS64_ESR] mrs x2, FAR_EL1 // Load fault address str x2, [x0, SS64_FAR] PUSH_FRAME bl EXT(sleh_invalid_stack) // Shouldn't return! b . .text .align 2 fleh_synchronous_sp1: mrs x1, ESR_EL1 // Load exception syndrome str x1, [x0, SS64_ESR] mrs x2, FAR_EL1 // Load fault address str x2, [x0, SS64_FAR] PUSH_FRAME bl EXT(sleh_synchronous_sp1) b . .text .align 2 fleh_irq_sp1: mov x1, x0 adr x0, Lsp1_irq_str b EXT(panic_with_thread_kernel_state) Lsp1_irq_str: .asciz "IRQ exception taken while SP1 selected" .text .align 2 fleh_fiq_sp1: mov x1, x0 adr x0, Lsp1_fiq_str b EXT(panic_with_thread_kernel_state) Lsp1_fiq_str: .asciz "FIQ exception taken while SP1 selected" .text .align 2 fleh_serror_sp1: mov x1, x0 adr x0, Lsp1_serror_str b EXT(panic_with_thread_kernel_state) Lsp1_serror_str: .asciz "Asynchronous exception taken while SP1 selected" .text .align 2 exception_return_dispatch: ldr w0, [x21, SS64_CPSR] tst w0, PSR64_MODE_EL_MASK b.ne EXT(return_to_kernel) // return to kernel if M[3:2] > 0 b return_to_user .text .align 2 .global EXT(return_to_kernel) LEXT(return_to_kernel) tbnz w0, #DAIF_IRQF_SHIFT, exception_return // Skip AST check if IRQ disabled mrs x3, TPIDR_EL1 // Load thread pointer ldr w1, [x3, ACT_PREEMPT_CNT] // Load preemption count msr DAIFSet, #DAIFSC_ALL // Disable exceptions cbnz x1, exception_return_unint_tpidr_x3 // If preemption disabled, skip AST check ldr x1, [x3, ACT_CPUDATAP] // Get current CPU data pointer ldr x2, [x1, CPU_PENDING_AST] // Get ASTs tst x2, AST_URGENT // If no urgent ASTs, skip ast_taken b.eq exception_return_unint_tpidr_x3 mov sp, x21 // Switch to thread stack for preemption PUSH_FRAME bl EXT(ast_taken_kernel) // Handle AST_URGENT POP_FRAME b exception_return .text .globl EXT(thread_bootstrap_return) LEXT(thread_bootstrap_return) #if CONFIG_DTRACE bl EXT(dtrace_thread_bootstrap) #endif b EXT(arm64_thread_exception_return) .text .globl EXT(arm64_thread_exception_return) LEXT(arm64_thread_exception_return) mrs x0, TPIDR_EL1 add x21, x0, ACT_CONTEXT ldr x21, [x21] mov x28, xzr // // Fall Through to return_to_user from arm64_thread_exception_return. // Note that if we move return_to_user or insert a new routine // below arm64_thread_exception_return, the latter will need to change. // .text /* x21 is always the machine context pointer when we get here * x28 is a bit indicating whether or not we should check if pc is in pfz */ return_to_user: check_user_asts: mrs x3, TPIDR_EL1 // Load thread pointer movn w2, #0 str w2, [x3, TH_IOTIER_OVERRIDE] // Reset IO tier override to -1 before returning to user #if MACH_ASSERT ldr w0, [x3, TH_RWLOCK_CNT] cbnz w0, rwlock_count_notzero // Detect unbalanced RW lock/unlock ldr w0, [x3, ACT_PREEMPT_CNT] cbnz w0, preempt_count_notzero // Detect unbalanced enable/disable preemption #endif ldr w0, [x3, TH_TMP_ALLOC_CNT] cbnz w0, tmp_alloc_count_nozero // Detect KHEAP_TEMP leaks msr DAIFSet, #DAIFSC_ALL // Disable exceptions ldr x4, [x3, ACT_CPUDATAP] // Get current CPU data pointer ldr x0, [x4, CPU_PENDING_AST] // Get ASTs cbz x0, no_asts // If no asts, skip ahead cbz x28, user_take_ast // If we don't need to check PFZ, just handle asts /* At this point, we have ASTs and we need to check whether we are running in the * preemption free zone (PFZ) or not. No ASTs are handled if we are running in * the PFZ since we don't want to handle getting a signal or getting suspended * while holding a spinlock in userspace. * * If userspace was in the PFZ, we know (via coordination with the PFZ code * in commpage_asm.s) that it will not be using x15 and it is therefore safe * to use it to indicate to userspace to come back to take a delayed * preemption, at which point the ASTs will be handled. */ mov x28, xzr // Clear the "check PFZ" bit so that we don't do this again mov x19, x0 // Save x0 since it will be clobbered by commpage_is_in_pfz64 ldr x0, [x21, SS64_PC] // Load pc from machine state bl EXT(commpage_is_in_pfz64) // pc in pfz? cbz x0, restore_and_check_ast // No, deal with other asts mov x0, #1 str x0, [x21, SS64_X15] // Mark x15 for userspace to take delayed preemption mov x0, x19 // restore x0 to asts b no_asts // pretend we have no asts restore_and_check_ast: mov x0, x19 // restore x0 b user_take_ast // Service pending asts no_asts: #if !CONFIG_SKIP_PRECISE_USER_KERNEL_TIME || HAS_FAST_CNTVCT mov x19, x3 // Preserve thread pointer across function call PUSH_FRAME bl EXT(timer_state_event_kernel_to_user) POP_FRAME mov x3, x19 #endif /* !CONFIG_SKIP_PRECISE_USER_KERNEL_TIME || HAS_FAST_CNTVCT */ #if (CONFIG_KERNEL_INTEGRITY && KERNEL_INTEGRITY_WT) /* Watchtower * * Here we attempt to enable NEON access for EL0. If the last entry into the * kernel from user-space was due to an IRQ, the monitor will have disabled * NEON for EL0 _and_ access to CPACR_EL1 from EL1 (1). This forces xnu to * check in with the monitor in order to reenable NEON for EL0 in exchange * for routing IRQs through the monitor (2). This way the monitor will * always 'own' either IRQs or EL0 NEON. * * If Watchtower is disabled or we did not enter the kernel through an IRQ * (e.g. FIQ or syscall) this is a no-op, otherwise we will trap to EL3 * here. * * EL0 user ________ IRQ ______ * EL1 xnu \ ______________________ CPACR_EL1 __/ * EL3 monitor \_/ \___/ * * (1) (2) */ mov x0, #(CPACR_FPEN_ENABLE) msr CPACR_EL1, x0 #endif /* Establish this thread's debug state as the live state on the selected CPU. */ ldr x4, [x3, ACT_CPUDATAP] // Get current CPU data pointer ldr x1, [x4, CPU_USER_DEBUG] // Get Debug context ldr x0, [x3, ACT_DEBUGDATA] cmp x0, x1 beq L_skip_user_set_debug_state // If active CPU debug state does not match thread debug state, apply thread state #if defined(APPLELIGHTNING) /* rdar://53177964 ([Cebu Errata SW WA][v8Debug] MDR NEX L3 clock turns OFF during restoreCheckpoint due to SWStep getting masked) */ ARM64_IS_PCORE x12 // if we're not a pCORE, also do nothing cbz x12, 1f #endif #if defined(APPLELIGHTNING) || defined(APPLEFIRESTORM) mrs x12, ARM64_REG_HID1 // if any debug session ever existed, set forceNexL3ClkOn orr x12, x12, ARM64_REG_HID1_forceNexL3ClkOn msr ARM64_REG_HID1, x12 1: #endif PUSH_FRAME bl EXT(arm_debug_set) // Establish thread debug state in live regs POP_FRAME mrs x3, TPIDR_EL1 // Reload thread pointer L_skip_user_set_debug_state: b exception_return_unint_tpidr_x3 // // Fall through from return_to_user to exception_return. // Note that if we move exception_return or add a new routine below // return_to_user, the latter will have to change. // exception_return: msr DAIFSet, #DAIFSC_ALL // Disable exceptions exception_return_unint: mrs x3, TPIDR_EL1 // Load thread pointer exception_return_unint_tpidr_x3: mov sp, x21 // Reload the pcb pointer exception_return_unint_tpidr_x3_dont_trash_x18: #if __ARM_KERNEL_PROTECT__ /* * If we are going to eret to userspace, we must return through the EL0 * eret mapping. */ ldr w1, [sp, SS64_CPSR] // Load CPSR tbnz w1, PSR64_MODE_EL_SHIFT, Lskip_el0_eret_mapping // Skip if returning to EL1 /* We need to switch to the EL0 mapping of this code to eret to EL0. */ adrp x0, EXT(ExceptionVectorsBase)@page // Load vector base adrp x1, Lexception_return_restore_registers@page // Load target PC add x1, x1, Lexception_return_restore_registers@pageoff MOV64 x2, ARM_KERNEL_PROTECT_EXCEPTION_START // Load EL0 vector address sub x1, x1, x0 // Calculate delta add x0, x2, x1 // Convert KVA to EL0 vector address br x0 Lskip_el0_eret_mapping: #endif /* __ARM_KERNEL_PROTECT__ */ Lexception_return_restore_registers: mov x0, sp // x0 = &pcb // Loads authed $x0->ss_64.pc into x1 and $x0->ss_64.cpsr into w2 AUTH_THREAD_STATE_IN_X0 x20, x21, x22, x23, x24, el0_state_allowed=1 /* Restore special register state */ ldr w3, [sp, NS64_FPSR] ldr w4, [sp, NS64_FPCR] msr ELR_EL1, x1 // Load the return address into ELR msr SPSR_EL1, x2 // Load the return CPSR into SPSR msr FPSR, x3 mrs x5, FPCR CMSR FPCR, x5, x4, 1 1: /* Restore arm_neon_saved_state64 */ ldp q0, q1, [x0, NS64_Q0] ldp q2, q3, [x0, NS64_Q2] ldp q4, q5, [x0, NS64_Q4] ldp q6, q7, [x0, NS64_Q6] ldp q8, q9, [x0, NS64_Q8] ldp q10, q11, [x0, NS64_Q10] ldp q12, q13, [x0, NS64_Q12] ldp q14, q15, [x0, NS64_Q14] ldp q16, q17, [x0, NS64_Q16] ldp q18, q19, [x0, NS64_Q18] ldp q20, q21, [x0, NS64_Q20] ldp q22, q23, [x0, NS64_Q22] ldp q24, q25, [x0, NS64_Q24] ldp q26, q27, [x0, NS64_Q26] ldp q28, q29, [x0, NS64_Q28] ldp q30, q31, [x0, NS64_Q30] /* Restore arm_saved_state64 */ // Skip x0, x1 - we're using them ldp x2, x3, [x0, SS64_X2] ldp x4, x5, [x0, SS64_X4] ldp x6, x7, [x0, SS64_X6] ldp x8, x9, [x0, SS64_X8] ldp x10, x11, [x0, SS64_X10] ldp x12, x13, [x0, SS64_X12] ldp x14, x15, [x0, SS64_X14] // Skip x16, x17 - already loaded + authed by AUTH_THREAD_STATE_IN_X0 ldp x18, x19, [x0, SS64_X18] ldp x20, x21, [x0, SS64_X20] ldp x22, x23, [x0, SS64_X22] ldp x24, x25, [x0, SS64_X24] ldp x26, x27, [x0, SS64_X26] ldr x28, [x0, SS64_X28] ldr fp, [x0, SS64_FP] // Skip lr - already loaded + authed by AUTH_THREAD_STATE_IN_X0 // Restore stack pointer and our last two GPRs ldr x1, [x0, SS64_SP] mov sp, x1 #if __ARM_KERNEL_PROTECT__ ldr w18, [x0, SS64_CPSR] // Stash CPSR #endif /* __ARM_KERNEL_PROTECT__ */ ldp x0, x1, [x0, SS64_X0] // Restore the GPRs #if __ARM_KERNEL_PROTECT__ /* If we are going to eret to userspace, we must unmap the kernel. */ tbnz w18, PSR64_MODE_EL_SHIFT, Lskip_ttbr1_switch /* Update TCR to unmap the kernel. */ MOV64 x18, TCR_EL1_USER msr TCR_EL1, x18 /* * On Apple CPUs, TCR writes and TTBR writes should be ordered relative to * each other due to the microarchitecture. */ #if !defined(APPLE_ARM64_ARCH_FAMILY) isb sy #endif /* Switch to the user ASID (low bit clear) for the task. */ mrs x18, TTBR0_EL1 bic x18, x18, #(1 << TTBR_ASID_SHIFT) msr TTBR0_EL1, x18 mov x18, #0 /* We don't need an ISB here, as the eret is synchronizing. */ Lskip_ttbr1_switch: #endif /* __ARM_KERNEL_PROTECT__ */ ERET_CONTEXT_SYNCHRONIZING user_take_ast: PUSH_FRAME bl EXT(ast_taken_user) // Handle all ASTs, may return via continuation POP_FRAME b check_user_asts // Now try again .text .align 2 preempt_underflow: mrs x0, TPIDR_EL1 str x0, [sp, #-16]! // We'll print thread pointer adr x0, L_underflow_str // Format string CALL_EXTERN panic // Game over L_underflow_str: .asciz "Preemption count negative on thread %p" .align 2 #if MACH_ASSERT .text .align 2 rwlock_count_notzero: mrs x0, TPIDR_EL1 str x0, [sp, #-16]! // We'll print thread pointer ldr w0, [x0, TH_RWLOCK_CNT] str w0, [sp, #8] adr x0, L_rwlock_count_notzero_str // Format string CALL_EXTERN panic // Game over L_rwlock_count_notzero_str: .asciz "RW lock count not 0 on thread %p (%u)" .text .align 2 preempt_count_notzero: mrs x0, TPIDR_EL1 str x0, [sp, #-16]! // We'll print thread pointer ldr w0, [x0, ACT_PREEMPT_CNT] str w0, [sp, #8] adr x0, L_preempt_count_notzero_str // Format string CALL_EXTERN panic // Game over L_preempt_count_notzero_str: .asciz "preemption count not 0 on thread %p (%u)" #endif /* MACH_ASSERT */ .text .align 2 tmp_alloc_count_nozero: mrs x0, TPIDR_EL1 CALL_EXTERN kheap_temp_leak_panic #if __ARM_KERNEL_PROTECT__ /* * This symbol denotes the end of the exception vector/eret range; we page * align it so that we can avoid mapping other text in the EL0 exception * vector mapping. */ .text .align 14 .globl EXT(ExceptionVectorsEnd) LEXT(ExceptionVectorsEnd) #endif /* __ARM_KERNEL_PROTECT__ */ #if XNU_MONITOR /* * Functions to preflight the fleh handlers when the PPL has taken an exception; * mostly concerned with setting up state for the normal fleh code. */ fleh_synchronous_from_ppl: /* Save x0. */ mov x15, x0 /* Grab the ESR. */ mrs x1, ESR_EL1 // Get the exception syndrome /* If the stack pointer is corrupt, it will manifest either as a data abort * (syndrome 0x25) or a misaligned pointer (syndrome 0x26). We can check * these quickly by testing bit 5 of the exception class. */ tbz x1, #(5 + ESR_EC_SHIFT), Lvalid_ppl_stack mrs x0, SP_EL0 // Get SP_EL0 /* Perform high level checks for stack corruption. */ and x1, x1, #ESR_EC_MASK // Mask the exception class mov x2, #(ESR_EC_SP_ALIGN << ESR_EC_SHIFT) cmp x1, x2 // If we have a stack alignment exception b.eq Lcorrupt_ppl_stack // ...the stack is definitely corrupted mov x2, #(ESR_EC_DABORT_EL1 << ESR_EC_SHIFT) cmp x1, x2 // If we have a data abort, we need to b.ne Lvalid_ppl_stack // ...validate the stack pointer Ltest_pstack: /* Bounds check the PPL stack. */ adrp x10, EXT(pmap_stacks_start)@page ldr x10, [x10, #EXT(pmap_stacks_start)@pageoff] adrp x11, EXT(pmap_stacks_end)@page ldr x11, [x11, #EXT(pmap_stacks_end)@pageoff] cmp x0, x10 b.lo Lcorrupt_ppl_stack cmp x0, x11 b.hi Lcorrupt_ppl_stack Lvalid_ppl_stack: /* Restore x0. */ mov x0, x15 /* Switch back to the kernel stack. */ msr SPSel, #0 GET_PMAP_CPU_DATA x5, x6, x7 ldr x6, [x5, PMAP_CPU_DATA_KERN_SAVED_SP] mov sp, x6 /* Hand off to the synch handler. */ b EXT(fleh_synchronous) Lcorrupt_ppl_stack: /* Restore x0. */ mov x0, x15 /* Hand off to the invalid stack handler. */ b fleh_invalid_stack fleh_fiq_from_ppl: SWITCH_TO_INT_STACK b EXT(fleh_fiq) fleh_irq_from_ppl: SWITCH_TO_INT_STACK b EXT(fleh_irq) fleh_serror_from_ppl: GET_PMAP_CPU_DATA x5, x6, x7 ldr x6, [x5, PMAP_CPU_DATA_KERN_SAVED_SP] mov sp, x6 b EXT(fleh_serror) // x15: ppl call number // w10: ppl_state // x20: gxf_enter caller's DAIF .globl EXT(ppl_trampoline_start) LEXT(ppl_trampoline_start) #error "XPRR configuration error" cmp x14, x21 b.ne Lppl_fail_dispatch /* Verify the request ID. */ cmp x15, PMAP_COUNT b.hs Lppl_fail_dispatch GET_PMAP_CPU_DATA x12, x13, x14 /* Mark this CPU as being in the PPL. */ ldr w9, [x12, PMAP_CPU_DATA_PPL_STATE] cmp w9, #PPL_STATE_KERNEL b.eq Lppl_mark_cpu_as_dispatching /* Check to see if we are trying to trap from within the PPL. */ cmp w9, #PPL_STATE_DISPATCH b.eq Lppl_fail_dispatch_ppl /* Ensure that we are returning from an exception. */ cmp w9, #PPL_STATE_EXCEPTION b.ne Lppl_fail_dispatch // where is w10 set? // in CHECK_EXCEPTION_RETURN_DISPATCH_PPL cmp w10, #PPL_STATE_EXCEPTION b.ne Lppl_fail_dispatch /* This is an exception return; set the CPU to the dispatching state. */ mov w9, #PPL_STATE_DISPATCH str w9, [x12, PMAP_CPU_DATA_PPL_STATE] /* Find the save area, and return to the saved PPL context. */ ldr x0, [x12, PMAP_CPU_DATA_SAVE_AREA] mov sp, x0 b EXT(return_to_ppl) Lppl_mark_cpu_as_dispatching: cmp w10, #PPL_STATE_KERNEL b.ne Lppl_fail_dispatch /* Mark the CPU as dispatching. */ mov w13, #PPL_STATE_DISPATCH str w13, [x12, PMAP_CPU_DATA_PPL_STATE] /* Switch to the regular PPL stack. */ // TODO: switch to PPL_STACK earlier in gxf_ppl_entry_handler ldr x9, [x12, PMAP_CPU_DATA_PPL_STACK] // SP0 is thread stack here mov x21, sp // SP0 is now PPL stack mov sp, x9 /* Save the old stack pointer off in case we need it. */ str x21, [x12, PMAP_CPU_DATA_KERN_SAVED_SP] /* Get the handler for the request */ adrp x9, EXT(ppl_handler_table)@page add x9, x9, EXT(ppl_handler_table)@pageoff add x9, x9, x15, lsl #3 ldr x10, [x9] /* Branch to the code that will invoke the PPL request. */ b EXT(ppl_dispatch) Lppl_fail_dispatch_ppl: /* Switch back to the kernel stack. */ ldr x10, [x12, PMAP_CPU_DATA_KERN_SAVED_SP] mov sp, x10 Lppl_fail_dispatch: /* Indicate that we failed. */ mov x15, #PPL_EXIT_BAD_CALL /* Move the DAIF bits into the expected register. */ mov x10, x20 /* Return to kernel mode. */ b ppl_return_to_kernel_mode Lppl_dispatch_exit: /* Indicate that we are cleanly exiting the PPL. */ mov x15, #PPL_EXIT_DISPATCH /* Switch back to the original (kernel thread) stack. */ mov sp, x21 /* Move the saved DAIF bits. */ mov x10, x20 /* Clear the old stack pointer. */ str xzr, [x12, PMAP_CPU_DATA_KERN_SAVED_SP] /* * Mark the CPU as no longer being in the PPL. We spin if our state * machine is broken. */ ldr w9, [x12, PMAP_CPU_DATA_PPL_STATE] cmp w9, #PPL_STATE_DISPATCH b.ne . mov w9, #PPL_STATE_KERNEL str w9, [x12, PMAP_CPU_DATA_PPL_STATE] /* Return to the kernel. */ b ppl_return_to_kernel_mode .text ppl_exit: /* * If we are dealing with an exception, hand off to the first level * exception handler. */ cmp x15, #PPL_EXIT_EXCEPTION b.eq Ljump_to_fleh_handler /* Restore the original AIF state. */ REENABLE_DAIF x10 /* If this was a panic call from the PPL, reinvoke panic. */ cmp x15, #PPL_EXIT_PANIC_CALL b.eq Ljump_to_panic_trap_to_debugger /* Load the preemption count. */ mrs x10, TPIDR_EL1 ldr w12, [x10, ACT_PREEMPT_CNT] /* Detect underflow */ cbnz w12, Lno_preempt_underflow b preempt_underflow Lno_preempt_underflow: /* Lower the preemption count. */ sub w12, w12, #1 str w12, [x10, ACT_PREEMPT_CNT] /* Skip ASTs if the peemption count is not zero. */ cbnz x12, Lppl_skip_ast_taken /* Skip the AST check if interrupts are disabled. */ mrs x1, DAIF tst x1, #DAIF_IRQF b.ne Lppl_skip_ast_taken /* Disable interrupts. */ msr DAIFSet, #(DAIFSC_IRQF | DAIFSC_FIQF) /* IF there is no urgent AST, skip the AST. */ ldr x12, [x10, ACT_CPUDATAP] ldr x14, [x12, CPU_PENDING_AST] tst x14, AST_URGENT b.eq Lppl_defer_ast_taken /* Stash our return value and return reason. */ mov x20, x0 mov x21, x15 /* Handle the AST. */ bl EXT(ast_taken_kernel) /* Restore the return value and the return reason. */ mov x15, x21 mov x0, x20 Lppl_defer_ast_taken: /* Reenable interrupts. */ msr DAIFClr, #(DAIFSC_IRQF | DAIFSC_FIQF) Lppl_skip_ast_taken: /* Pop the stack frame. */ ldp x29, x30, [sp, #0x10] ldp x20, x21, [sp], #0x20 /* Check to see if this was a bad request. */ cmp x15, #PPL_EXIT_BAD_CALL b.eq Lppl_bad_call /* Return. */ ARM64_STACK_EPILOG .align 2 Ljump_to_fleh_handler: br x25 .align 2 Ljump_to_panic_trap_to_debugger: b EXT(panic_trap_to_debugger) Lppl_bad_call: /* Panic. */ adrp x0, Lppl_bad_call_panic_str@page add x0, x0, Lppl_bad_call_panic_str@pageoff b EXT(panic) .text .align 2 .globl EXT(ppl_dispatch) LEXT(ppl_dispatch) /* * Save a couple of important registers (implementation detail; x12 has * the PPL per-CPU data address; x13 is not actually interesting). */ stp x12, x13, [sp, #-0x10]! /* Restore the original AIF state. */ REENABLE_DAIF x20 /* * Note that if the method is NULL, we'll blow up with a prefetch abort, * but the exception vectors will deal with this properly. */ /* Invoke the PPL method. */ #ifdef HAS_APPLE_PAC blraa x10, x9 #else blr x10 #endif /* Disable AIF. */ msr DAIFSet, #(DAIFSC_ASYNCF | DAIFSC_IRQF | DAIFSC_FIQF) /* Restore those important registers. */ ldp x12, x13, [sp], #0x10 /* Mark this as a regular return, and hand off to the return path. */ b Lppl_dispatch_exit .text .align 2 .globl EXT(ppl_bootstrap_dispatch) LEXT(ppl_bootstrap_dispatch) /* Verify the PPL request. */ cmp x15, PMAP_COUNT b.hs Lppl_fail_bootstrap_dispatch /* Get the requested PPL routine. */ adrp x9, EXT(ppl_handler_table)@page add x9, x9, EXT(ppl_handler_table)@pageoff add x9, x9, x15, lsl #3 ldr x10, [x9] /* Invoke the requested PPL routine. */ #ifdef HAS_APPLE_PAC blraa x10, x9 #else blr x10 #endif /* Stash off the return value */ mov x20, x0 /* Drop the preemption count */ bl EXT(_enable_preemption) mov x0, x20 /* Pop the stack frame. */ ldp x29, x30, [sp, #0x10] ldp x20, x21, [sp], #0x20 #if __has_feature(ptrauth_returns) retab #else ret #endif Lppl_fail_bootstrap_dispatch: /* Pop our stack frame and panic. */ ldp x29, x30, [sp, #0x10] ldp x20, x21, [sp], #0x20 #if __has_feature(ptrauth_returns) autibsp #endif adrp x0, Lppl_bad_call_panic_str@page add x0, x0, Lppl_bad_call_panic_str@pageoff b EXT(panic) .text .align 2 .globl EXT(ml_panic_trap_to_debugger) LEXT(ml_panic_trap_to_debugger) mrs x10, DAIF msr DAIFSet, #(DAIFSC_ASYNCF | DAIFSC_IRQF | DAIFSC_FIQF) adrp x12, EXT(pmap_ppl_locked_down)@page ldr w12, [x12, #EXT(pmap_ppl_locked_down)@pageoff] cbz w12, Lnot_in_ppl_dispatch LOAD_PMAP_CPU_DATA x11, x12, x13 ldr w12, [x11, PMAP_CPU_DATA_PPL_STATE] cmp w12, #PPL_STATE_DISPATCH b.ne Lnot_in_ppl_dispatch /* Indicate (for the PPL->kernel transition) that we are panicking. */ mov x15, #PPL_EXIT_PANIC_CALL /* Restore the old stack pointer as we can't push onto PPL stack after we exit PPL */ ldr x12, [x11, PMAP_CPU_DATA_KERN_SAVED_SP] mov sp, x12 mrs x10, DAIF mov w13, #PPL_STATE_PANIC str w13, [x11, PMAP_CPU_DATA_PPL_STATE] /* Now we are ready to exit the PPL. */ b ppl_return_to_kernel_mode Lnot_in_ppl_dispatch: REENABLE_DAIF x10 ret .data Lppl_bad_call_panic_str: .asciz "ppl_dispatch: failed due to bad arguments/state" #else /* XNU_MONITOR */ .text .align 2 .globl EXT(ml_panic_trap_to_debugger) LEXT(ml_panic_trap_to_debugger) ret #endif /* XNU_MONITOR */ /* ARM64_TODO Is globals_asm.h needed? */ //#include "globals_asm.h" /* vim: set ts=4: */