intvec_32.S 52.4 KB
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/*
 * Copyright 2010 Tilera Corporation. All Rights Reserved.
 *
 *   This program is free software; you can redistribute it and/or
 *   modify it under the terms of the GNU General Public License
 *   as published by the Free Software Foundation, version 2.
 *
 *   This program is distributed in the hope that it will be useful, but
 *   WITHOUT ANY WARRANTY; without even the implied warranty of
 *   MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE, GOOD TITLE or
 *   NON INFRINGEMENT.  See the GNU General Public License for
 *   more details.
 *
 * Linux interrupt vectors.
 */

#include <linux/linkage.h>
#include <linux/errno.h>
#include <linux/init.h>
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#include <linux/unistd.h>
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#include <asm/ptrace.h>
#include <asm/thread_info.h>
#include <asm/irqflags.h>
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#include <asm/atomic_32.h>
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#include <asm/asm-offsets.h>
#include <hv/hypervisor.h>
#include <arch/abi.h>
#include <arch/interrupts.h>
#include <arch/spr_def.h>

#ifdef CONFIG_PREEMPT
# error "No support for kernel preemption currently"
#endif

#define PTREGS_PTR(reg, ptreg) addli reg, sp, C_ABI_SAVE_AREA_SIZE + (ptreg)

#define PTREGS_OFFSET_SYSCALL PTREGS_OFFSET_REG(TREG_SYSCALL_NR)

#if !CHIP_HAS_WH64()
	/* By making this an empty macro, we can use wh64 in the code. */
	.macro  wh64 reg
	.endm
#endif

	.macro  push_reg reg, ptr=sp, delta=-4
	{
	 sw     \ptr, \reg
	 addli  \ptr, \ptr, \delta
	}
	.endm

	.macro  pop_reg reg, ptr=sp, delta=4
	{
	 lw     \reg, \ptr
	 addli  \ptr, \ptr, \delta
	}
	.endm

	.macro  pop_reg_zero reg, zreg, ptr=sp, delta=4
	{
	 move   \zreg, zero
	 lw     \reg, \ptr
	 addi   \ptr, \ptr, \delta
	}
	.endm

	.macro  push_extra_callee_saves reg
	PTREGS_PTR(\reg, PTREGS_OFFSET_REG(51))
	push_reg r51, \reg
	push_reg r50, \reg
	push_reg r49, \reg
	push_reg r48, \reg
	push_reg r47, \reg
	push_reg r46, \reg
	push_reg r45, \reg
	push_reg r44, \reg
	push_reg r43, \reg
	push_reg r42, \reg
	push_reg r41, \reg
	push_reg r40, \reg
	push_reg r39, \reg
	push_reg r38, \reg
	push_reg r37, \reg
	push_reg r36, \reg
	push_reg r35, \reg
	push_reg r34, \reg, PTREGS_OFFSET_BASE - PTREGS_OFFSET_REG(34)
	.endm

	.macro  panic str
	.pushsection .rodata, "a"
1:
	.asciz  "\str"
	.popsection
	{
	 moveli r0, lo16(1b)
	}
	{
	 auli   r0, r0, ha16(1b)
	 jal    panic
	}
	.endm

#ifdef __COLLECT_LINKER_FEEDBACK__
	.pushsection .text.intvec_feedback,"ax"
intvec_feedback:
	.popsection
#endif

	/*
	 * Default interrupt handler.
	 *
	 * vecnum is where we'll put this code.
	 * c_routine is the C routine we'll call.
	 *
	 * The C routine is passed two arguments:
	 * - A pointer to the pt_regs state.
	 * - The interrupt vector number.
	 *
	 * The "processing" argument specifies the code for processing
	 * the interrupt. Defaults to "handle_interrupt".
	 */
	.macro  int_hand vecnum, vecname, c_routine, processing=handle_interrupt
	.org    (\vecnum << 8)
intvec_\vecname:
	.ifc    \vecnum, INT_SWINT_1
	blz     TREG_SYSCALL_NR_NAME, sys_cmpxchg
	.endif

	/* Temporarily save a register so we have somewhere to work. */

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	mtspr   SPR_SYSTEM_SAVE_K_1, r0
	mfspr   r0, SPR_EX_CONTEXT_K_1
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	/* The cmpxchg code clears sp to force us to reset it here on fault. */
	{
	 bz     sp, 2f
	 andi   r0, r0, SPR_EX_CONTEXT_1_1__PL_MASK  /* mask off ICS */
	}

	.ifc    \vecnum, INT_DOUBLE_FAULT
	/*
	 * For double-faults from user-space, fall through to the normal
	 * register save and stack setup path.  Otherwise, it's the
	 * hypervisor giving us one last chance to dump diagnostics, and we
	 * branch to the kernel_double_fault routine to do so.
	 */
	bz      r0, 1f
	j       _kernel_double_fault
1:
	.else
	/*
	 * If we're coming from user-space, then set sp to the top of
	 * the kernel stack.  Otherwise, assume sp is already valid.
	 */
	{
	 bnz    r0, 0f
	 move   r0, sp
	}
	.endif

	.ifc    \c_routine, do_page_fault
	/*
	 * The page_fault handler may be downcalled directly by the
	 * hypervisor even when Linux is running and has ICS set.
	 *
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	 * In this case the contents of EX_CONTEXT_K_1 reflect the
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	 * previous fault and can't be relied on to choose whether or
	 * not to reinitialize the stack pointer.  So we add a test
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	 * to see whether SYSTEM_SAVE_K_2 has the high bit set,
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	 * and if so we don't reinitialize sp, since we must be coming
	 * from Linux.  (In fact the precise case is !(val & ~1),
	 * but any Linux PC has to have the high bit set.)
	 *
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	 * Note that the hypervisor *always* sets SYSTEM_SAVE_K_2 for
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	 * any path that turns into a downcall to one of our TLB handlers.
	 */
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	mfspr   r0, SPR_SYSTEM_SAVE_K_2
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	{
	 blz    r0, 0f    /* high bit in S_S_1_2 is for a PC to use */
	 move   r0, sp
	}
	.endif

2:
	/*
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	 * SYSTEM_SAVE_K_0 holds the cpu number in the low bits, and
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	 * the current stack top in the higher bits.  So we recover
	 * our stack top by just masking off the low bits, then
	 * point sp at the top aligned address on the actual stack page.
	 */
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	mfspr   r0, SPR_SYSTEM_SAVE_K_0
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	mm      r0, r0, zero, LOG2_THREAD_SIZE, 31

0:
	/*
	 * Align the stack mod 64 so we can properly predict what
	 * cache lines we need to write-hint to reduce memory fetch
	 * latency as we enter the kernel.  The layout of memory is
	 * as follows, with cache line 0 at the lowest VA, and cache
	 * line 4 just below the r0 value this "andi" computes.
	 * Note that we never write to cache line 4, and we skip
	 * cache line 1 for syscalls.
	 *
	 *    cache line 4: ptregs padding (two words)
	 *    cache line 3: r46...lr, pc, ex1, faultnum, orig_r0, flags, pad
	 *    cache line 2: r30...r45
	 *    cache line 1: r14...r29
	 *    cache line 0: 2 x frame, r0..r13
	 */
	andi    r0, r0, -64

	/*
	 * Push the first four registers on the stack, so that we can set
	 * them to vector-unique values before we jump to the common code.
	 *
	 * Registers are pushed on the stack as a struct pt_regs,
	 * with the sp initially just above the struct, and when we're
	 * done, sp points to the base of the struct, minus
	 * C_ABI_SAVE_AREA_SIZE, so we can directly jal to C code.
	 *
	 * This routine saves just the first four registers, plus the
	 * stack context so we can do proper backtracing right away,
	 * and defers to handle_interrupt to save the rest.
	 * The backtracer needs pc, ex1, lr, sp, r52, and faultnum.
	 */
	addli   r0, r0, PTREGS_OFFSET_LR - (PTREGS_SIZE + KSTK_PTREGS_GAP)
	wh64    r0    /* cache line 3 */
	{
	 sw     r0, lr
	 addli  r0, r0, PTREGS_OFFSET_SP - PTREGS_OFFSET_LR
	}
	{
	 sw     r0, sp
	 addli  sp, r0, PTREGS_OFFSET_REG(52) - PTREGS_OFFSET_SP
	}
	{
	 sw     sp, r52
	 addli  sp, sp, PTREGS_OFFSET_REG(1) - PTREGS_OFFSET_REG(52)
	}
	wh64    sp    /* cache line 0 */
	{
	 sw     sp, r1
	 addli  sp, sp, PTREGS_OFFSET_REG(2) - PTREGS_OFFSET_REG(1)
	}
	{
	 sw     sp, r2
	 addli  sp, sp, PTREGS_OFFSET_REG(3) - PTREGS_OFFSET_REG(2)
	}
	{
	 sw     sp, r3
	 addli  sp, sp, PTREGS_OFFSET_PC - PTREGS_OFFSET_REG(3)
	}
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	mfspr   r0, SPR_EX_CONTEXT_K_0
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	.ifc \processing,handle_syscall
	/*
	 * Bump the saved PC by one bundle so that when we return, we won't
	 * execute the same swint instruction again.  We need to do this while
	 * we're in the critical section.
	 */
	addi    r0, r0, 8
	.endif
	{
	 sw     sp, r0
	 addli  sp, sp, PTREGS_OFFSET_EX1 - PTREGS_OFFSET_PC
	}
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	mfspr   r0, SPR_EX_CONTEXT_K_1
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	{
	 sw     sp, r0
	 addi   sp, sp, PTREGS_OFFSET_FAULTNUM - PTREGS_OFFSET_EX1
	/*
	 * Use r0 for syscalls so it's a temporary; use r1 for interrupts
	 * so that it gets passed through unchanged to the handler routine.
	 * Note that the .if conditional confusingly spans bundles.
	 */
	 .ifc \processing,handle_syscall
	 movei  r0, \vecnum
	}
	{
	 sw     sp, r0
	 .else
	 movei  r1, \vecnum
	}
	{
	 sw     sp, r1
	 .endif
	 addli  sp, sp, PTREGS_OFFSET_REG(0) - PTREGS_OFFSET_FAULTNUM
	}
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	mfspr   r0, SPR_SYSTEM_SAVE_K_1    /* Original r0 */
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	{
	 sw     sp, r0
	 addi   sp, sp, -PTREGS_OFFSET_REG(0) - 4
	}
	{
	 sw     sp, zero        /* write zero into "Next SP" frame pointer */
	 addi   sp, sp, -4      /* leave SP pointing at bottom of frame */
	}
	.ifc \processing,handle_syscall
	j       handle_syscall
	.else
	/*
	 * Capture per-interrupt SPR context to registers.
	 * We overload the meaning of r3 on this path such that if its bit 31
	 * is set, we have to mask all interrupts including NMIs before
	 * clearing the interrupt critical section bit.
	 * See discussion below at "finish_interrupt_save".
	 */
	.ifc \c_routine, do_page_fault
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	mfspr   r2, SPR_SYSTEM_SAVE_K_3   /* address of page fault */
	mfspr   r3, SPR_SYSTEM_SAVE_K_2   /* info about page fault */
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	.else
	.ifc \vecnum, INT_DOUBLE_FAULT
	{
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	 mfspr  r2, SPR_SYSTEM_SAVE_K_2   /* double fault info from HV */
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	 movei  r3, 0
	}
	.else
	.ifc \c_routine, do_trap
	{
	 mfspr  r2, GPV_REASON
	 movei  r3, 0
	}
	.else
	.ifc \c_routine, op_handle_perf_interrupt
	{
	 mfspr  r2, PERF_COUNT_STS
	 movei  r3, -1   /* not used, but set for consistency */
	}
	.else
#if CHIP_HAS_AUX_PERF_COUNTERS()
	.ifc \c_routine, op_handle_aux_perf_interrupt
	{
	 mfspr  r2, AUX_PERF_COUNT_STS
	 movei  r3, -1   /* not used, but set for consistency */
	}
	.else
#endif
	movei   r3, 0
#if CHIP_HAS_AUX_PERF_COUNTERS()
	.endif
#endif
	.endif
	.endif
	.endif
	.endif
	/* Put function pointer in r0 */
	moveli  r0, lo16(\c_routine)
	{
	 auli   r0, r0, ha16(\c_routine)
	 j       \processing
	}
	.endif
	ENDPROC(intvec_\vecname)

#ifdef __COLLECT_LINKER_FEEDBACK__
	.pushsection .text.intvec_feedback,"ax"
	.org    (\vecnum << 5)
	FEEDBACK_ENTER_EXPLICIT(intvec_\vecname, .intrpt1, 1 << 8)
	jrp     lr
	.popsection
#endif

	.endm


	/*
	 * Save the rest of the registers that we didn't save in the actual
	 * vector itself.  We can't use r0-r10 inclusive here.
	 */
	.macro  finish_interrupt_save, function

	/* If it's a syscall, save a proper orig_r0, otherwise just zero. */
	PTREGS_PTR(r52, PTREGS_OFFSET_ORIG_R0)
	{
	 .ifc \function,handle_syscall
	 sw     r52, r0
	 .else
	 sw     r52, zero
	 .endif
	 PTREGS_PTR(r52, PTREGS_OFFSET_TP)
	}

	/*
	 * For ordinary syscalls, we save neither caller- nor callee-
	 * save registers, since the syscall invoker doesn't expect the
	 * caller-saves to be saved, and the called kernel functions will
	 * take care of saving the callee-saves for us.
	 *
	 * For interrupts we save just the caller-save registers.  Saving
	 * them is required (since the "caller" can't save them).  Again,
	 * the called kernel functions will restore the callee-save
	 * registers for us appropriately.
	 *
	 * On return, we normally restore nothing special for syscalls,
	 * and just the caller-save registers for interrupts.
	 *
	 * However, there are some important caveats to all this:
	 *
	 * - We always save a few callee-save registers to give us
	 *   some scratchpad registers to carry across function calls.
	 *
	 * - fork/vfork/etc require us to save all the callee-save
	 *   registers, which we do in PTREGS_SYSCALL_ALL_REGS, below.
	 *
	 * - We always save r0..r5 and r10 for syscalls, since we need
	 *   to reload them a bit later for the actual kernel call, and
	 *   since we might need them for -ERESTARTNOINTR, etc.
	 *
	 * - Before invoking a signal handler, we save the unsaved
	 *   callee-save registers so they are visible to the
	 *   signal handler or any ptracer.
	 *
	 * - If the unsaved callee-save registers are modified, we set
	 *   a bit in pt_regs so we know to reload them from pt_regs
	 *   and not just rely on the kernel function unwinding.
	 *   (Done for ptrace register writes and SA_SIGINFO handler.)
	 */
	{
	 sw     r52, tp
	 PTREGS_PTR(r52, PTREGS_OFFSET_REG(33))
	}
	wh64    r52    /* cache line 2 */
	push_reg r33, r52
	push_reg r32, r52
	push_reg r31, r52
	.ifc \function,handle_syscall
	push_reg r30, r52, PTREGS_OFFSET_SYSCALL - PTREGS_OFFSET_REG(30)
	push_reg TREG_SYSCALL_NR_NAME, r52, \
	  PTREGS_OFFSET_REG(5) - PTREGS_OFFSET_SYSCALL
	.else

	push_reg r30, r52, PTREGS_OFFSET_REG(29) - PTREGS_OFFSET_REG(30)
	wh64    r52    /* cache line 1 */
	push_reg r29, r52
	push_reg r28, r52
	push_reg r27, r52
	push_reg r26, r52
	push_reg r25, r52
	push_reg r24, r52
	push_reg r23, r52
	push_reg r22, r52
	push_reg r21, r52
	push_reg r20, r52
	push_reg r19, r52
	push_reg r18, r52
	push_reg r17, r52
	push_reg r16, r52
	push_reg r15, r52
	push_reg r14, r52
	push_reg r13, r52
	push_reg r12, r52
	push_reg r11, r52
	push_reg r10, r52
	push_reg r9, r52
	push_reg r8, r52
	push_reg r7, r52
	push_reg r6, r52

	.endif

	push_reg r5, r52
	sw      r52, r4

	/* Load tp with our per-cpu offset. */
#ifdef CONFIG_SMP
	{
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	 mfspr  r20, SPR_SYSTEM_SAVE_K_0
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	 moveli r21, lo16(__per_cpu_offset)
	}
	{
	 auli   r21, r21, ha16(__per_cpu_offset)
	 mm     r20, r20, zero, 0, LOG2_THREAD_SIZE-1
	}
	s2a     r20, r20, r21
	lw      tp, r20
#else
	move    tp, zero
#endif

	/*
	 * If we will be returning to the kernel, we will need to
	 * reset the interrupt masks to the state they had before.
	 * Set DISABLE_IRQ in flags iff we came from PL1 with irqs disabled.
	 * We load flags in r32 here so we can jump to .Lrestore_regs
	 * directly after do_page_fault_ics() if necessary.
	 */
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	mfspr   r32, SPR_EX_CONTEXT_K_1
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	{
	 andi   r32, r32, SPR_EX_CONTEXT_1_1__PL_MASK  /* mask off ICS */
	 PTREGS_PTR(r21, PTREGS_OFFSET_FLAGS)
	}
	bzt     r32, 1f       /* zero if from user space */
	IRQS_DISABLED(r32)    /* zero if irqs enabled */
#if PT_FLAGS_DISABLE_IRQ != 1
# error Value of IRQS_DISABLED used to set PT_FLAGS_DISABLE_IRQ; fix
#endif
1:
	.ifnc \function,handle_syscall
	/* Record the fact that we saved the caller-save registers above. */
	ori     r32, r32, PT_FLAGS_CALLER_SAVES
	.endif
	sw      r21, r32

#ifdef __COLLECT_LINKER_FEEDBACK__
	/*
	 * Notify the feedback routines that we were in the
	 * appropriate fixed interrupt vector area.  Note that we
	 * still have ICS set at this point, so we can't invoke any
	 * atomic operations or we will panic.  The feedback
	 * routines internally preserve r0..r10 and r30 up.
	 */
	.ifnc \function,handle_syscall
	shli    r20, r1, 5
	.else
	moveli  r20, INT_SWINT_1 << 5
	.endif
	addli   r20, r20, lo16(intvec_feedback)
	auli    r20, r20, ha16(intvec_feedback)
	jalr    r20

	/* And now notify the feedback routines that we are here. */
	FEEDBACK_ENTER(\function)
#endif

	/*
	 * we've captured enough state to the stack (including in
	 * particular our EX_CONTEXT state) that we can now release
	 * the interrupt critical section and replace it with our
	 * standard "interrupts disabled" mask value.  This allows
	 * synchronous interrupts (and profile interrupts) to punch
	 * through from this point onwards.
	 *
	 * If bit 31 of r3 is set during a non-NMI interrupt, we know we
	 * are on the path where the hypervisor has punched through our
	 * ICS with a page fault, so we call out to do_page_fault_ics()
	 * to figure out what to do with it.  If the fault was in
	 * an atomic op, we unlock the atomic lock, adjust the
	 * saved register state a little, and return "zero" in r4,
	 * falling through into the normal page-fault interrupt code.
	 * If the fault was in a kernel-space atomic operation, then
	 * do_page_fault_ics() resolves it itself, returns "one" in r4,
	 * and as a result goes directly to restoring registers and iret,
	 * without trying to adjust the interrupt masks at all.
	 * The do_page_fault_ics() API involves passing and returning
	 * a five-word struct (in registers) to avoid writing the
	 * save and restore code here.
	 */
	.ifc \function,handle_nmi
	IRQ_DISABLE_ALL(r20)
	.else
	.ifnc \function,handle_syscall
	bgezt   r3, 1f
	{
	 PTREGS_PTR(r0, PTREGS_OFFSET_BASE)
	 jal    do_page_fault_ics
	}
	FEEDBACK_REENTER(\function)
	bzt     r4, 1f
	j       .Lrestore_regs
1:
	.endif
	IRQ_DISABLE(r20, r21)
	.endif
	mtspr   INTERRUPT_CRITICAL_SECTION, zero

#if CHIP_HAS_WH64()
	/*
	 * Prepare the first 256 stack bytes to be rapidly accessible
	 * without having to fetch the background data.  We don't really
	 * know how far to write-hint, but kernel stacks generally
	 * aren't that big, and write-hinting here does take some time.
	 */
	addi    r52, sp, -64
	{
	 wh64   r52
	 addi   r52, r52, -64
	}
	{
	 wh64   r52
	 addi   r52, r52, -64
	}
	{
	 wh64   r52
	 addi   r52, r52, -64
	}
	wh64    r52
#endif

#ifdef CONFIG_TRACE_IRQFLAGS
	.ifnc \function,handle_nmi
	/*
	 * We finally have enough state set up to notify the irq
	 * tracing code that irqs were disabled on entry to the handler.
	 * The TRACE_IRQS_OFF call clobbers registers r0-r29.
	 * For syscalls, we already have the register state saved away
	 * on the stack, so we don't bother to do any register saves here,
	 * and later we pop the registers back off the kernel stack.
	 * For interrupt handlers, save r0-r3 in callee-saved registers.
	 */
	.ifnc \function,handle_syscall
	{ move r30, r0; move r31, r1 }
	{ move r32, r2; move r33, r3 }
	.endif
	TRACE_IRQS_OFF
	.ifnc \function,handle_syscall
	{ move r0, r30; move r1, r31 }
	{ move r2, r32; move r3, r33 }
	.endif
	.endif
#endif

	.endm

	.macro  check_single_stepping, kind, not_single_stepping
	/*
	 * Check for single stepping in user-level priv
	 *   kind can be "normal", "ill", or "syscall"
	 * At end, if fall-thru
	 *   r29: thread_info->step_state
	 *   r28: &pt_regs->pc
	 *   r27: pt_regs->pc
	 *   r26: thread_info->step_state->buffer
	 */

	/* Check for single stepping */
	GET_THREAD_INFO(r29)
	{
	 /* Get pointer to field holding step state */
	 addi   r29, r29, THREAD_INFO_STEP_STATE_OFFSET

	 /* Get pointer to EX1 in register state */
	 PTREGS_PTR(r27, PTREGS_OFFSET_EX1)
	}
	{
	 /* Get pointer to field holding PC */
	 PTREGS_PTR(r28, PTREGS_OFFSET_PC)

	 /* Load the pointer to the step state */
	 lw     r29, r29
	}
	/* Load EX1 */
	lw      r27, r27
	{
	 /* Points to flags */
	 addi   r23, r29, SINGLESTEP_STATE_FLAGS_OFFSET

	 /* No single stepping if there is no step state structure */
	 bzt    r29, \not_single_stepping
	}
	{
	 /* mask off ICS and any other high bits */
	 andi   r27, r27, SPR_EX_CONTEXT_1_1__PL_MASK

	 /* Load pointer to single step instruction buffer */
	 lw     r26, r29
	}
	/* Check priv state */
	bnz     r27, \not_single_stepping

	/* Get flags */
	lw      r22, r23
	{
	 /* Branch if single-step mode not enabled */
	 bbnst  r22, \not_single_stepping

	 /* Clear enabled flag */
	 andi   r22, r22, ~SINGLESTEP_STATE_MASK_IS_ENABLED
	}
	.ifc \kind,normal
	{
	 /* Load PC */
	 lw     r27, r28

	 /* Point to the entry containing the original PC */
	 addi   r24, r29, SINGLESTEP_STATE_ORIG_PC_OFFSET
	}
	{
	 /* Disable single stepping flag */
	 sw     r23, r22
	}
	{
	 /* Get the original pc */
	 lw     r24, r24

	 /* See if the PC is at the start of the single step buffer */
	 seq    r25, r26, r27
	}
	/*
	 * NOTE: it is really expected that the PC be in the single step buffer
	 *       at this point
	 */
	bzt     r25, \not_single_stepping

	/* Restore the original PC */
	sw      r28, r24
	.else
	.ifc \kind,syscall
	{
	 /* Load PC */
	 lw     r27, r28

	 /* Point to the entry containing the next PC */
	 addi   r24, r29, SINGLESTEP_STATE_NEXT_PC_OFFSET
	}
	{
	 /* Increment the stopped PC by the bundle size */
	 addi   r26, r26, 8

	 /* Disable single stepping flag */
	 sw     r23, r22
	}
	{
	 /* Get the next pc */
	 lw     r24, r24

	 /*
	  * See if the PC is one bundle past the start of the
	  * single step buffer
	  */
	 seq    r25, r26, r27
	}
	{
	 /*
	  * NOTE: it is really expected that the PC be in the
	  * single step buffer at this point
	  */
	 bzt    r25, \not_single_stepping
	}
	/* Set to the next PC */
	sw      r28, r24
	.else
	{
	 /* Point to 3rd bundle in buffer */
	 addi   r25, r26, 16

	 /* Load PC */
	 lw      r27, r28
	}
	{
	 /* Disable single stepping flag */
	 sw      r23, r22

	 /* See if the PC is in the single step buffer */
	 slte_u  r24, r26, r27
	}
	{
	 slte_u r25, r27, r25

	 /*
	  * NOTE: it is really expected that the PC be in the
	  * single step buffer at this point
	  */
	 bzt    r24, \not_single_stepping
	}
	bzt     r25, \not_single_stepping
	.endif
	.endif
	.endm

	/*
	 * Redispatch a downcall.
	 */
	.macro  dc_dispatch vecnum, vecname
	.org    (\vecnum << 8)
intvec_\vecname:
	j       hv_downcall_dispatch
	ENDPROC(intvec_\vecname)
	.endm

	/*
	 * Common code for most interrupts.  The C function we're eventually
	 * going to is in r0, and the faultnum is in r1; the original
	 * values for those registers are on the stack.
	 */
	.pushsection .text.handle_interrupt,"ax"
handle_interrupt:
	finish_interrupt_save handle_interrupt

	/*
	 * Check for if we are single stepping in user level. If so, then
	 * we need to restore the PC.
	 */

	check_single_stepping normal, .Ldispatch_interrupt
.Ldispatch_interrupt:

	/* Jump to the C routine; it should enable irqs as soon as possible. */
	{
	 jalr   r0
	 PTREGS_PTR(r0, PTREGS_OFFSET_BASE)
	}
	FEEDBACK_REENTER(handle_interrupt)
	{
	 movei  r30, 0   /* not an NMI */
	 j      interrupt_return
	}
	STD_ENDPROC(handle_interrupt)

/*
 * This routine takes a boolean in r30 indicating if this is an NMI.
 * If so, we also expect a boolean in r31 indicating whether to
 * re-enable the oprofile interrupts.
802 803 804 805
 *
 * Note that .Lresume_userspace is jumped to directly in several
 * places, and we need to make sure r30 is set correctly in those
 * callers as well.
806 807 808 809 810 811 812 813 814 815 816 817 818 819 820 821 822 823 824 825 826 827 828 829 830 831 832 833 834 835 836 837 838 839 840
 */
STD_ENTRY(interrupt_return)
	/* If we're resuming to kernel space, don't check thread flags. */
	{
	 bnz    r30, .Lrestore_all  /* NMIs don't special-case user-space */
	 PTREGS_PTR(r29, PTREGS_OFFSET_EX1)
	}
	lw      r29, r29
	andi    r29, r29, SPR_EX_CONTEXT_1_1__PL_MASK  /* mask off ICS */
	{
	 bzt    r29, .Lresume_userspace
	 PTREGS_PTR(r29, PTREGS_OFFSET_PC)
	}

	/* If we're resuming to _cpu_idle_nap, bump PC forward by 8. */
	{
	 lw     r28, r29
	 moveli r27, lo16(_cpu_idle_nap)
	}
	{
	 auli   r27, r27, ha16(_cpu_idle_nap)
	}
	{
	 seq    r27, r27, r28
	}
	{
	 bbns   r27, .Lrestore_all
	 addi   r28, r28, 8
	}
	sw      r29, r28
	j       .Lrestore_all

.Lresume_userspace:
	FEEDBACK_REENTER(interrupt_return)

841 842 843 844 845 846 847 848 849 850 851 852
	/*
	 * Use r33 to hold whether we have already loaded the callee-saves
	 * into ptregs.  We don't want to do it twice in this loop, since
	 * then we'd clobber whatever changes are made by ptrace, etc.
	 * Get base of stack in r32.
	 */
	{
	 GET_THREAD_INFO(r32)
	 movei  r33, 0
	}

.Lretry_work_pending:
853 854 855 856 857 858 859 860 861 862 863 864 865 866
	/*
	 * Disable interrupts so as to make sure we don't
	 * miss an interrupt that sets any of the thread flags (like
	 * need_resched or sigpending) between sampling and the iret.
	 * Routines like schedule() or do_signal() may re-enable
	 * interrupts before returning.
	 */
	IRQ_DISABLE(r20, r21)
	TRACE_IRQS_OFF  /* Note: clobbers registers r0-r29 */


	/* Check to see if there is any work to do before returning to user. */
	{
	 addi   r29, r32, THREAD_INFO_FLAGS_OFFSET
867
	 moveli r1, lo16(_TIF_ALLWORK_MASK)
868 869 870
	}
	{
	 lw     r29, r29
871
	 auli   r1, r1, ha16(_TIF_ALLWORK_MASK)
872
	}
873 874 875 876 877
	and     r1, r29, r1
	bzt     r1, .Lrestore_all

	/*
	 * Make sure we have all the registers saved for signal
878 879 880
	 * handling, notify-resume, or single-step.  Call out to C
	 * code to figure out exactly what we need to do for each flag bit,
	 * then if necessary, reload the flags and recheck.
881 882 883
	 */
	{
	 PTREGS_PTR(r0, PTREGS_OFFSET_BASE)
884
	 bnz    r33, 1f
885
	}
886 887 888 889
	push_extra_callee_saves r0
	movei   r33, 1
1:	jal     do_work_pending
	bnz     r0, .Lretry_work_pending
890 891 892 893 894 895 896 897 898 899 900 901 902 903 904 905 906 907 908 909 910 911 912 913 914 915 916 917 918 919 920 921 922 923 924 925 926 927 928 929 930 931 932 933 934 935 936 937 938 939 940 941 942 943 944 945 946 947 948 949 950 951 952 953 954 955 956 957 958 959 960 961 962 963 964 965 966 967 968 969 970 971 972 973 974 975 976 977 978

	/*
	 * In the NMI case we
	 * omit the call to single_process_check_nohz, which normally checks
	 * to see if we should start or stop the scheduler tick, because
	 * we can't call arbitrary Linux code from an NMI context.
	 * We always call the homecache TLB deferral code to re-trigger
	 * the deferral mechanism.
	 *
	 * The other chunk of responsibility this code has is to reset the
	 * interrupt masks appropriately to reset irqs and NMIs.  We have
	 * to call TRACE_IRQS_OFF and TRACE_IRQS_ON to support all the
	 * lockdep-type stuff, but we can't set ICS until afterwards, since
	 * ICS can only be used in very tight chunks of code to avoid
	 * tripping over various assertions that it is off.
	 *
	 * (There is what looks like a window of vulnerability here since
	 * we might take a profile interrupt between the two SPR writes
	 * that set the mask, but since we write the low SPR word first,
	 * and our interrupt entry code checks the low SPR word, any
	 * profile interrupt will actually disable interrupts in both SPRs
	 * before returning, which is OK.)
	 */
.Lrestore_all:
	PTREGS_PTR(r0, PTREGS_OFFSET_EX1)
	{
	 lw     r0, r0
	 PTREGS_PTR(r32, PTREGS_OFFSET_FLAGS)
	}
	{
	 andi   r0, r0, SPR_EX_CONTEXT_1_1__PL_MASK
	 lw     r32, r32
	}
	bnz    r0, 1f
	j       2f
#if PT_FLAGS_DISABLE_IRQ != 1
# error Assuming PT_FLAGS_DISABLE_IRQ == 1 so we can use bbnst below
#endif
1:	bbnst   r32, 2f
	IRQ_DISABLE(r20,r21)
	TRACE_IRQS_OFF
	movei   r0, 1
	mtspr   INTERRUPT_CRITICAL_SECTION, r0
	bzt     r30, .Lrestore_regs
	j       3f
2:	TRACE_IRQS_ON
	movei   r0, 1
	mtspr   INTERRUPT_CRITICAL_SECTION, r0
	IRQ_ENABLE(r20, r21)
	bzt     r30, .Lrestore_regs
3:


	/*
	 * We now commit to returning from this interrupt, since we will be
	 * doing things like setting EX_CONTEXT SPRs and unwinding the stack
	 * frame.  No calls should be made to any other code after this point.
	 * This code should only be entered with ICS set.
	 * r32 must still be set to ptregs.flags.
	 * We launch loads to each cache line separately first, so we can
	 * get some parallelism out of the memory subsystem.
	 * We start zeroing caller-saved registers throughout, since
	 * that will save some cycles if this turns out to be a syscall.
	 */
.Lrestore_regs:
	FEEDBACK_REENTER(interrupt_return)   /* called from elsewhere */

	/*
	 * Rotate so we have one high bit and one low bit to test.
	 * - low bit says whether to restore all the callee-saved registers,
	 *   or just r30-r33, and r52 up.
	 * - high bit (i.e. sign bit) says whether to restore all the
	 *   caller-saved registers, or just r0.
	 */
#if PT_FLAGS_CALLER_SAVES != 2 || PT_FLAGS_RESTORE_REGS != 4
# error Rotate trick does not work :-)
#endif
	{
	 rli    r20, r32, 30
	 PTREGS_PTR(sp, PTREGS_OFFSET_REG(0))
	}

	/*
	 * Load cache lines 0, 2, and 3 in that order, then use
	 * the last loaded value, which makes it likely that the other
	 * cache lines have also loaded, at which point we should be
	 * able to safely read all the remaining words on those cache
	 * lines without waiting for the memory subsystem.
	 */
979
	pop_reg_zero r0, r28, sp, PTREGS_OFFSET_REG(30) - PTREGS_OFFSET_REG(0)
980 981 982 983
	pop_reg_zero r30, r2, sp, PTREGS_OFFSET_PC - PTREGS_OFFSET_REG(30)
	pop_reg_zero r21, r3, sp, PTREGS_OFFSET_EX1 - PTREGS_OFFSET_PC
	pop_reg_zero lr, r4, sp, PTREGS_OFFSET_REG(52) - PTREGS_OFFSET_EX1
	{
984
	 mtspr  SPR_EX_CONTEXT_K_0, r21
985 986 987
	 move   r5, zero
	}
	{
988
	 mtspr  SPR_EX_CONTEXT_K_1, lr
989 990 991 992 993 994 995 996 997 998 999 1000 1001 1002 1003 1004 1005 1006 1007 1008 1009 1010 1011 1012 1013 1014 1015 1016 1017 1018 1019 1020 1021 1022 1023 1024 1025 1026 1027 1028 1029 1030 1031 1032 1033 1034 1035 1036 1037 1038 1039 1040 1041 1042 1043
	 andi   lr, lr, SPR_EX_CONTEXT_1_1__PL_MASK  /* mask off ICS */
	}

	/* Restore callee-saveds that we actually use. */
	pop_reg_zero r52, r6, sp, PTREGS_OFFSET_REG(31) - PTREGS_OFFSET_REG(52)
	pop_reg_zero r31, r7
	pop_reg_zero r32, r8
	pop_reg_zero r33, r9, sp, PTREGS_OFFSET_REG(29) - PTREGS_OFFSET_REG(33)

	/*
	 * If we modified other callee-saveds, restore them now.
	 * This is rare, but could be via ptrace or signal handler.
	 */
	{
	 move   r10, zero
	 bbs    r20, .Lrestore_callees
	}
.Lcontinue_restore_regs:

	/* Check if we're returning from a syscall. */
	{
	 move   r11, zero
	 blzt   r20, 1f  /* no, so go restore callee-save registers */
	}

	/*
	 * Check if we're returning to userspace.
	 * Note that if we're not, we don't worry about zeroing everything.
	 */
	{
	 addli  sp, sp, PTREGS_OFFSET_LR - PTREGS_OFFSET_REG(29)
	 bnz    lr, .Lkernel_return
	}

	/*
	 * On return from syscall, we've restored r0 from pt_regs, but we
	 * clear the remainder of the caller-saved registers.  We could
	 * restore the syscall arguments, but there's not much point,
	 * and it ensures user programs aren't trying to use the
	 * caller-saves if we clear them, as well as avoiding leaking
	 * kernel pointers into userspace.
	 */
	pop_reg_zero lr, r12, sp, PTREGS_OFFSET_TP - PTREGS_OFFSET_LR
	pop_reg_zero tp, r13, sp, PTREGS_OFFSET_SP - PTREGS_OFFSET_TP
	{
	 lw     sp, sp
	 move   r14, zero
	 move   r15, zero
	}
	{ move r16, zero; move r17, zero }
	{ move r18, zero; move r19, zero }
	{ move r20, zero; move r21, zero }
	{ move r22, zero; move r23, zero }
	{ move r24, zero; move r25, zero }
	{ move r26, zero; move r27, zero }
1044 1045 1046

	/* Set r1 to errno if we are returning an error, otherwise zero. */
	{
1047
	 moveli r29, 4096
1048 1049 1050 1051 1052 1053 1054
	 sub    r1, zero, r0
	}
	slt_u   r29, r1, r29
	{
	 mnz    r1, r29, r1
	 move   r29, zero
	}
1055 1056 1057 1058 1059 1060 1061 1062 1063 1064 1065 1066 1067 1068 1069 1070 1071 1072 1073 1074 1075 1076 1077 1078 1079 1080 1081 1082 1083 1084 1085 1086 1087 1088 1089 1090 1091 1092 1093 1094 1095 1096 1097 1098 1099 1100 1101 1102 1103 1104 1105 1106 1107 1108 1109 1110 1111 1112 1113 1114 1115 1116 1117 1118 1119 1120 1121 1122 1123 1124 1125 1126 1127 1128 1129 1130 1131 1132 1133 1134 1135 1136 1137 1138 1139 1140 1141 1142 1143 1144 1145 1146 1147 1148 1149 1150 1151 1152 1153 1154 1155 1156 1157 1158 1159 1160 1161 1162 1163 1164 1165 1166 1167 1168 1169 1170 1171 1172 1173 1174 1175 1176 1177 1178 1179 1180 1181 1182 1183 1184 1185 1186 1187 1188 1189 1190 1191 1192 1193
	iret

	/*
	 * Not a syscall, so restore caller-saved registers.
	 * First kick off a load for cache line 1, which we're touching
	 * for the first time here.
	 */
	.align 64
1:	pop_reg r29, sp, PTREGS_OFFSET_REG(1) - PTREGS_OFFSET_REG(29)
	pop_reg r1
	pop_reg r2
	pop_reg r3
	pop_reg r4
	pop_reg r5
	pop_reg r6
	pop_reg r7
	pop_reg r8
	pop_reg r9
	pop_reg r10
	pop_reg r11
	pop_reg r12
	pop_reg r13
	pop_reg r14
	pop_reg r15
	pop_reg r16
	pop_reg r17
	pop_reg r18
	pop_reg r19
	pop_reg r20
	pop_reg r21
	pop_reg r22
	pop_reg r23
	pop_reg r24
	pop_reg r25
	pop_reg r26
	pop_reg r27
	pop_reg r28, sp, PTREGS_OFFSET_LR - PTREGS_OFFSET_REG(28)
	/* r29 already restored above */
	bnz     lr, .Lkernel_return
	pop_reg lr, sp, PTREGS_OFFSET_TP - PTREGS_OFFSET_LR
	pop_reg tp, sp, PTREGS_OFFSET_SP - PTREGS_OFFSET_TP
	lw      sp, sp
	iret

	/*
	 * We can't restore tp when in kernel mode, since a thread might
	 * have migrated from another cpu and brought a stale tp value.
	 */
.Lkernel_return:
	pop_reg lr, sp, PTREGS_OFFSET_SP - PTREGS_OFFSET_LR
	lw      sp, sp
	iret

	/* Restore callee-saved registers from r34 to r51. */
.Lrestore_callees:
	addli  sp, sp, PTREGS_OFFSET_REG(34) - PTREGS_OFFSET_REG(29)
	pop_reg r34
	pop_reg r35
	pop_reg r36
	pop_reg r37
	pop_reg r38
	pop_reg r39
	pop_reg r40
	pop_reg r41
	pop_reg r42
	pop_reg r43
	pop_reg r44
	pop_reg r45
	pop_reg r46
	pop_reg r47
	pop_reg r48
	pop_reg r49
	pop_reg r50
	pop_reg r51, sp, PTREGS_OFFSET_REG(29) - PTREGS_OFFSET_REG(51)
	j .Lcontinue_restore_regs
	STD_ENDPROC(interrupt_return)

	/*
	 * Some interrupts don't check for single stepping
	 */
	.pushsection .text.handle_interrupt_no_single_step,"ax"
handle_interrupt_no_single_step:
	finish_interrupt_save handle_interrupt_no_single_step
	{
	 jalr   r0
	 PTREGS_PTR(r0, PTREGS_OFFSET_BASE)
	}
	FEEDBACK_REENTER(handle_interrupt_no_single_step)
	{
	 movei  r30, 0   /* not an NMI */
	 j      interrupt_return
	}
	STD_ENDPROC(handle_interrupt_no_single_step)

	/*
	 * "NMI" interrupts mask ALL interrupts before calling the
	 * handler, and don't check thread flags, etc., on the way
	 * back out.  In general, the only things we do here for NMIs
	 * are the register save/restore, fixing the PC if we were
	 * doing single step, and the dataplane kernel-TLB management.
	 * We don't (for example) deal with start/stop of the sched tick.
	 */
	.pushsection .text.handle_nmi,"ax"
handle_nmi:
	finish_interrupt_save handle_nmi
	check_single_stepping normal, .Ldispatch_nmi
.Ldispatch_nmi:
	{
	 jalr   r0
	 PTREGS_PTR(r0, PTREGS_OFFSET_BASE)
	}
	FEEDBACK_REENTER(handle_nmi)
	j       interrupt_return
	STD_ENDPROC(handle_nmi)

	/*
	 * Parallel code for syscalls to handle_interrupt.
	 */
	.pushsection .text.handle_syscall,"ax"
handle_syscall:
	finish_interrupt_save handle_syscall

	/*
	 * Check for if we are single stepping in user level. If so, then
	 * we need to restore the PC.
	 */
	check_single_stepping syscall, .Ldispatch_syscall
.Ldispatch_syscall:

	/* Enable irqs. */
	TRACE_IRQS_ON
	IRQ_ENABLE(r20, r21)

	/* Bump the counter for syscalls made on this tile. */
	moveli  r20, lo16(irq_stat + IRQ_CPUSTAT_SYSCALL_COUNT_OFFSET)
	auli    r20, r20, ha16(irq_stat + IRQ_CPUSTAT_SYSCALL_COUNT_OFFSET)
	add     r20, r20, tp
	lw      r21, r20
	addi    r21, r21, 1
1194 1195 1196 1197
	{
	 sw     r20, r21
	 GET_THREAD_INFO(r31)
	}
1198 1199 1200 1201 1202 1203 1204 1205 1206 1207 1208 1209 1210 1211 1212 1213 1214 1215 1216 1217 1218 1219 1220 1221 1222 1223 1224 1225 1226 1227 1228 1229 1230 1231 1232 1233 1234 1235 1236 1237

	/* Trace syscalls, if requested. */
	addi	r31, r31, THREAD_INFO_FLAGS_OFFSET
	lw	r30, r31
	andi    r30, r30, _TIF_SYSCALL_TRACE
	bzt	r30, .Lrestore_syscall_regs
	jal	do_syscall_trace
	FEEDBACK_REENTER(handle_syscall)

	/*
	 * We always reload our registers from the stack at this
	 * point.  They might be valid, if we didn't build with
	 * TRACE_IRQFLAGS, and this isn't a dataplane tile, and we're not
	 * doing syscall tracing, but there are enough cases now that it
	 * seems simplest just to do the reload unconditionally.
	 */
.Lrestore_syscall_regs:
	PTREGS_PTR(r11, PTREGS_OFFSET_REG(0))
	pop_reg r0, r11
	pop_reg r1, r11
	pop_reg r2, r11
	pop_reg r3, r11
	pop_reg r4, r11
	pop_reg r5, r11, PTREGS_OFFSET_SYSCALL - PTREGS_OFFSET_REG(5)
	pop_reg TREG_SYSCALL_NR_NAME, r11

	/* Ensure that the syscall number is within the legal range. */
	moveli  r21, __NR_syscalls
	{
	 slt_u  r21, TREG_SYSCALL_NR_NAME, r21
	 moveli r20, lo16(sys_call_table)
	}
	{
	 bbns   r21, .Linvalid_syscall
	 auli   r20, r20, ha16(sys_call_table)
	}
	s2a     r20, TREG_SYSCALL_NR_NAME, r20
	lw      r20, r20

	/* Jump to syscall handler. */
1238 1239
	jalr    r20
.Lhandle_syscall_link: /* value of "lr" after "jalr r20" above */
1240 1241 1242 1243 1244 1245 1246 1247

	/*
	 * Write our r0 onto the stack so it gets restored instead
	 * of whatever the user had there before.
	 */
	PTREGS_PTR(r29, PTREGS_OFFSET_REG(0))
	sw      r29, r0

1248 1249 1250
.Lsyscall_sigreturn_skip:
	FEEDBACK_REENTER(handle_syscall)

1251 1252 1253 1254 1255 1256
	/* Do syscall trace again, if requested. */
	lw	r30, r31
	andi    r30, r30, _TIF_SYSCALL_TRACE
	bzt     r30, 1f
	jal	do_syscall_trace
	FEEDBACK_REENTER(handle_syscall)
1257 1258 1259 1260
1:	{
	 movei  r30, 0               /* not an NMI */
	 j      .Lresume_userspace   /* jump into middle of interrupt_return */
	}
1261 1262 1263 1264 1265 1266 1267 1268

.Linvalid_syscall:
	/* Report an invalid syscall back to the user program */
	{
	 PTREGS_PTR(r29, PTREGS_OFFSET_REG(0))
	 movei  r28, -ENOSYS
	}
	sw      r29, r28
1269 1270 1271 1272
	{
	 movei  r30, 0               /* not an NMI */
	 j      .Lresume_userspace   /* jump into middle of interrupt_return */
	}
1273 1274 1275 1276 1277 1278 1279 1280 1281 1282 1283 1284 1285 1286 1287
	STD_ENDPROC(handle_syscall)

	/* Return the address for oprofile to suppress in backtraces. */
STD_ENTRY_SECTION(handle_syscall_link_address, .text.handle_syscall)
	lnk     r0
	{
	 addli  r0, r0, .Lhandle_syscall_link - .
	 jrp    lr
	}
	STD_ENDPROC(handle_syscall_link_address)

STD_ENTRY(ret_from_fork)
	jal     sim_notify_fork
	jal     schedule_tail
	FEEDBACK_REENTER(ret_from_fork)
1288 1289 1290 1291
	{
	 movei  r30, 0               /* not an NMI */
	 j      .Lresume_userspace   /* jump into middle of interrupt_return */
	}
1292 1293
	STD_ENDPROC(ret_from_fork)

1294 1295 1296 1297 1298 1299 1300 1301 1302 1303 1304 1305 1306 1307 1308
STD_ENTRY(ret_from_kernel_thread)
	jal     sim_notify_fork
	jal     schedule_tail
	FEEDBACK_REENTER(ret_from_fork)
	{
	 move   r0, r31
	 jalr   r30
	}
	FEEDBACK_REENTER(ret_from_kernel_thread)
	{
	 movei  r30, 0               /* not an NMI */
	 j      .Lresume_userspace   /* jump into middle of interrupt_return */
	}
	STD_ENDPROC(ret_from_kernel_thread)

1309 1310 1311 1312 1313 1314 1315 1316 1317 1318 1319 1320 1321 1322 1323 1324 1325 1326 1327 1328 1329 1330 1331 1332 1333 1334 1335 1336 1337 1338 1339 1340 1341 1342 1343 1344 1345 1346 1347 1348 1349 1350 1351 1352 1353 1354 1355 1356 1357 1358 1359 1360 1361 1362 1363 1364 1365 1366 1367 1368 1369 1370 1371 1372 1373 1374 1375 1376 1377 1378 1379 1380 1381 1382 1383 1384 1385 1386 1387 1388 1389 1390 1391 1392
	/*
	 * Code for ill interrupt.
	 */
	.pushsection .text.handle_ill,"ax"
handle_ill:
	finish_interrupt_save handle_ill

	/*
	 * Check for if we are single stepping in user level. If so, then
	 * we need to restore the PC.
	 */
	check_single_stepping ill, .Ldispatch_normal_ill

	{
	 /* See if the PC is the 1st bundle in the buffer */
	 seq    r25, r27, r26

	 /* Point to the 2nd bundle in the buffer */
	 addi   r26, r26, 8
	}
	{
	 /* Point to the original pc */
	 addi   r24, r29, SINGLESTEP_STATE_ORIG_PC_OFFSET

	 /* Branch if the PC is the 1st bundle in the buffer */
	 bnz    r25, 3f
	}
	{
	 /* See if the PC is the 2nd bundle of the buffer */
	 seq    r25, r27, r26

	 /* Set PC to next instruction */
	 addi   r24, r29, SINGLESTEP_STATE_NEXT_PC_OFFSET
	}
	{
	 /* Point to flags */
	 addi   r25, r29, SINGLESTEP_STATE_FLAGS_OFFSET

	 /* Branch if PC is in the second bundle */
	 bz     r25, 2f
	}
	/* Load flags */
	lw      r25, r25
	{
	 /*
	  * Get the offset for the register to restore
	  * Note: the lower bound is 2, so we have implicit scaling by 4.
	  *  No multiplication of the register number by the size of a register
	  *  is needed.
	  */
	 mm     r27, r25, zero, SINGLESTEP_STATE_TARGET_LB, \
		SINGLESTEP_STATE_TARGET_UB

	 /* Mask Rewrite_LR */
	 andi   r25, r25, SINGLESTEP_STATE_MASK_UPDATE
	}
	{
	 addi   r29, r29, SINGLESTEP_STATE_UPDATE_VALUE_OFFSET

	 /* Don't rewrite temp register */
	 bz     r25, 3f
	}
	{
	 /* Get the temp value */
	 lw     r29, r29

	 /* Point to where the register is stored */
	 add    r27, r27, sp
	}

	/* Add in the C ABI save area size to the register offset */
	addi    r27, r27, C_ABI_SAVE_AREA_SIZE

	/* Restore the user's register with the temp value */
	sw      r27, r29
	j       3f

2:
	/* Must be in the third bundle */
	addi    r24, r29, SINGLESTEP_STATE_BRANCH_NEXT_PC_OFFSET

3:
	/* set PC and continue */
	lw      r26, r24
1393 1394 1395 1396
	{
	 sw     r28, r26
	 GET_THREAD_INFO(r0)
	}
1397

1398 1399 1400 1401 1402 1403
	/*
	 * Clear TIF_SINGLESTEP to prevent recursion if we execute an ill.
	 * The normal non-arch flow redundantly clears TIF_SINGLESTEP, but we
	 * need to clear it here and can't really impose on all other arches.
	 * So what's another write between friends?
	 */
1404 1405 1406 1407 1408 1409 1410 1411 1412 1413 1414 1415 1416 1417 1418 1419 1420 1421

	addi    r1, r0, THREAD_INFO_FLAGS_OFFSET
	{
	 lw     r2, r1
	 addi   r0, r0, THREAD_INFO_TASK_OFFSET  /* currently a no-op */
	}
	andi    r2, r2, ~_TIF_SINGLESTEP
	sw      r1, r2

	/* Issue a sigtrap */
	{
	 lw     r0, r0          /* indirect thru thread_info to get task_info*/
	 addi   r1, sp, C_ABI_SAVE_AREA_SIZE  /* put ptregs pointer into r1 */
	 move   r2, zero        /* load error code into r2 */
	}

	jal     send_sigtrap    /* issue a SIGTRAP */
	FEEDBACK_REENTER(handle_ill)
1422 1423 1424 1425
	{
	 movei  r30, 0               /* not an NMI */
	 j      .Lresume_userspace   /* jump into middle of interrupt_return */
	}
1426 1427 1428 1429 1430 1431 1432 1433 1434 1435 1436 1437 1438 1439 1440 1441

.Ldispatch_normal_ill:
	{
	 jalr   r0
	 PTREGS_PTR(r0, PTREGS_OFFSET_BASE)
	}
	FEEDBACK_REENTER(handle_ill)
	{
	 movei  r30, 0   /* not an NMI */
	 j      interrupt_return
	}
	STD_ENDPROC(handle_ill)

/* Various stub interrupt handlers and syscall handlers */

STD_ENTRY_LOCAL(_kernel_double_fault)
1442
	mfspr   r1, SPR_EX_CONTEXT_K_0
1443 1444 1445 1446 1447 1448 1449 1450
	move    r2, lr
	move    r3, sp
	move    r4, r52
	addi    sp, sp, -C_ABI_SAVE_AREA_SIZE
	j       kernel_double_fault
	STD_ENDPROC(_kernel_double_fault)

STD_ENTRY_LOCAL(bad_intr)
1451
	mfspr   r2, SPR_EX_CONTEXT_K_0
1452 1453 1454
	panic   "Unhandled interrupt %#x: PC %#lx"
	STD_ENDPROC(bad_intr)

1455 1456 1457 1458 1459 1460 1461 1462 1463 1464 1465 1466 1467 1468 1469 1470
/*
 * Special-case sigreturn to not write r0 to the stack on return.
 * This is technically more efficient, but it also avoids difficulties
 * in the 64-bit OS when handling 32-bit compat code, since we must not
 * sign-extend r0 for the sigreturn return-value case.
 */
#define PTREGS_SYSCALL_SIGRETURN(x, reg)                \
	STD_ENTRY(_##x);                                \
	addli   lr, lr, .Lsyscall_sigreturn_skip - .Lhandle_syscall_link; \
	{                                               \
	 PTREGS_PTR(reg, PTREGS_OFFSET_BASE);           \
	 j      x                                       \
	};                                              \
	STD_ENDPROC(_##x)

PTREGS_SYSCALL_SIGRETURN(sys_rt_sigreturn, r0)
1471

1472
/* Save additional callee-saves to pt_regs and jump to standard function. */
1473 1474 1475 1476
STD_ENTRY(_sys_clone)
	push_extra_callee_saves r4
	j       sys_clone
	STD_ENDPROC(_sys_clone)
1477 1478 1479 1480 1481 1482 1483 1484 1485 1486 1487 1488

/*
 * This entrypoint is taken for the cmpxchg and atomic_update fast
 * swints.  We may wish to generalize it to other fast swints at some
 * point, but for now there are just two very similar ones, which
 * makes it faster.
 *
 * The fast swint code is designed to have a small footprint.  It does
 * not save or restore any GPRs, counting on the caller-save registers
 * to be available to it on entry.  It does not modify any callee-save
 * registers (including "lr").  It does not check what PL it is being
 * called at, so you'd better not call it other than at PL0.
1489 1490
 * The <atomic.h> wrapper assumes it only clobbers r20-r29, so if
 * it ever is necessary to use more registers, be aware.
1491 1492 1493 1494 1495
 *
 * It does not use the stack, but since it might be re-interrupted by
 * a page fault which would assume the stack was valid, it does
 * save/restore the stack pointer and zero it out to make sure it gets reset.
 * Since we always keep interrupts disabled, the hypervisor won't
1496
 * clobber our EX_CONTEXT_K_x registers, so we don't save/restore them
1497 1498 1499 1500 1501 1502 1503 1504 1505 1506
 * (other than to advance the PC on return).
 *
 * We have to manually validate the user vs kernel address range
 * (since at PL1 we can read/write both), and for performance reasons
 * we don't allow cmpxchg on the fc000000 memory region, since we only
 * validate that the user address is below PAGE_OFFSET.
 *
 * We place it in the __HEAD section to ensure it is relatively
 * near to the intvec_SWINT_1 code (reachable by a conditional branch).
 *
1507 1508 1509 1510
 * Our use of ATOMIC_LOCK_REG here must match do_page_fault_ics().
 *
 * As we do in lib/atomic_asm_32.S, we bypass a store if the value we
 * would store is the same as the value we just loaded.
1511 1512 1513 1514 1515
 */
	__HEAD
	.align 64
	/* Align much later jump on the start of a cache line. */
#if !ATOMIC_LOCKS_FOUND_VIA_TABLE()
1516 1517 1518 1519
	nop
#if PAGE_SIZE >= 0x10000
	nop
#endif
1520 1521 1522 1523 1524 1525 1526 1527 1528 1529 1530 1531 1532 1533 1534 1535 1536 1537 1538 1539 1540 1541 1542 1543 1544 1545 1546
#endif
ENTRY(sys_cmpxchg)

	/*
	 * Save "sp" and set it zero for any possible page fault.
	 *
	 * HACK: We want to both zero sp and check r0's alignment,
	 * so we do both at once. If "sp" becomes nonzero we
	 * know r0 is unaligned and branch to the error handler that
	 * restores sp, so this is OK.
	 *
	 * ICS is disabled right now so having a garbage but nonzero
	 * sp is OK, since we won't execute any faulting instructions
	 * when it is nonzero.
	 */
	{
	 move   r27, sp
	 andi	sp, r0, 3
	}

	/*
	 * Get the lock address in ATOMIC_LOCK_REG, and also validate that the
	 * address is less than PAGE_OFFSET, since that won't trap at PL1.
	 * We only use bits less than PAGE_SHIFT to avoid having to worry
	 * about aliasing among multiple mappings of the same physical page,
	 * and we ignore the low 3 bits so we have one lock that covers
	 * both a cmpxchg64() and a cmpxchg() on either its low or high word.
1547
	 * NOTE: this must match __atomic_hashed_lock() in lib/atomic_32.c.
1548 1549
	 */

1550 1551 1552 1553
#if (PAGE_OFFSET & 0xffff) != 0
# error Code here assumes PAGE_OFFSET can be loaded with just hi16()
#endif

1554 1555 1556 1557 1558 1559 1560 1561 1562 1563 1564 1565 1566 1567 1568 1569 1570
#if ATOMIC_LOCKS_FOUND_VIA_TABLE()
	{
	 /* Check for unaligned input. */
	 bnz    sp, .Lcmpxchg_badaddr
	 mm     r25, r0, zero, 3, PAGE_SHIFT-1
	}
	{
	 crc32_32 r25, zero, r25
	 moveli r21, lo16(atomic_lock_ptr)
	}
	{
	 auli   r21, r21, ha16(atomic_lock_ptr)
	 auli   r23, zero, hi16(PAGE_OFFSET)  /* hugepage-aligned */
	}
	{
	 shri	r20, r25, 32 - ATOMIC_HASH_L1_SHIFT
	 slt_u  r23, r0, r23
1571
	 lw	r26, r0  /* see comment in the "#else" for the "lw r26". */
1572 1573 1574 1575 1576 1577 1578 1579 1580 1581 1582 1583 1584 1585 1586 1587 1588
	}
	{
	 s2a    r21, r20, r21
	 bbns   r23, .Lcmpxchg_badaddr
	}
	{
	 lw     r21, r21
	 seqi	r23, TREG_SYSCALL_NR_NAME, __NR_FAST_cmpxchg64
	 andi	r25, r25, ATOMIC_HASH_L2_SIZE - 1
	}
	{
	 /* Branch away at this point if we're doing a 64-bit cmpxchg. */
	 bbs    r23, .Lcmpxchg64
	 andi   r23, r0, 7       /* Precompute alignment for cmpxchg64. */
	}
	{
	 s2a	ATOMIC_LOCK_REG_NAME, r25, r21
1589
	 j      .Lcmpxchg32_tns   /* see comment in the #else for the jump. */
1590 1591 1592 1593 1594 1595 1596 1597 1598 1599 1600 1601 1602 1603 1604 1605 1606 1607 1608 1609 1610 1611 1612 1613 1614 1615 1616 1617 1618 1619 1620 1621 1622 1623 1624 1625 1626
	}

#else /* ATOMIC_LOCKS_FOUND_VIA_TABLE() */
	{
	 /* Check for unaligned input. */
	 bnz    sp, .Lcmpxchg_badaddr
	 auli   r23, zero, hi16(PAGE_OFFSET)  /* hugepage-aligned */
	}
	{
	 /*
	  * Slide bits into position for 'mm'. We want to ignore
	  * the low 3 bits of r0, and consider only the next
	  * ATOMIC_HASH_SHIFT bits.
	  * Because of C pointer arithmetic, we want to compute this:
	  *
	  * ((char*)atomic_locks +
	  *  (((r0 >> 3) & (1 << (ATOMIC_HASH_SIZE - 1))) << 2))
	  *
	  * Instead of two shifts we just ">> 1", and use 'mm'
	  * to ignore the low and high bits we don't want.
	  */
	 shri	r25, r0, 1

	 slt_u  r23, r0, r23

	 /*
	  * Ensure that the TLB is loaded before we take out the lock.
	  * On tilepro, this will start fetching the value all the way
	  * into our L1 as well (and if it gets modified before we
	  * grab the lock, it will be invalidated from our cache
	  * before we reload it).  On tile64, we'll start fetching it
	  * into our L1 if we're the home, and if we're not, we'll
	  * still at least start fetching it into the home's L2.
	  */
	 lw	r26, r0
	}
	{
1627
	 auli	r21, zero, ha16(atomic_locks)
1628 1629 1630

	 bbns   r23, .Lcmpxchg_badaddr
	}
1631 1632 1633 1634
#if PAGE_SIZE < 0x10000
	/* atomic_locks is page-aligned so for big pages we don't need this. */
	addli   r21, r21, lo16(atomic_locks)
#endif
1635 1636 1637 1638 1639 1640 1641 1642 1643 1644 1645 1646 1647 1648 1649 1650 1651 1652 1653
	{
	 /*
	  * Insert the hash bits into the page-aligned pointer.
	  * ATOMIC_HASH_SHIFT is so big that we don't actually hash
	  * the unmasked address bits, as that may cause unnecessary
	  * collisions.
	  */
	 mm	ATOMIC_LOCK_REG_NAME, r25, r21, 2, (ATOMIC_HASH_SHIFT + 2) - 1

	 seqi	r23, TREG_SYSCALL_NR_NAME, __NR_FAST_cmpxchg64
	}
	{
	 /* Branch away at this point if we're doing a 64-bit cmpxchg. */
	 bbs    r23, .Lcmpxchg64
	 andi   r23, r0, 7       /* Precompute alignment for cmpxchg64. */
	}
	{
	 /*
	  * We very carefully align the code that actually runs with
1654
	  * the lock held (twelve bundles) so that we know it is all in
1655 1656
	  * the icache when we start.  This instruction (the jump) is
	  * at the start of the first cache line, address zero mod 64;
1657 1658 1659 1660
	  * we jump to the very end of the second cache line to get that
	  * line loaded in the icache, then fall through to issue the tns
	  * in the third cache line, at which point it's all cached.
	  * Note that is for performance, not correctness.
1661 1662 1663 1664 1665 1666
	  */
	 j      .Lcmpxchg32_tns
	}

#endif /* ATOMIC_LOCKS_FOUND_VIA_TABLE() */

1667 1668 1669
/* Symbol for do_page_fault_ics() to use to compare against the PC. */
.global __sys_cmpxchg_grab_lock
__sys_cmpxchg_grab_lock:
1670 1671 1672 1673 1674 1675 1676 1677 1678 1679 1680 1681 1682 1683 1684 1685 1686 1687 1688 1689

	/*
	 * Perform the actual cmpxchg or atomic_update.
	 */
.Ldo_cmpxchg32:
	{
	 lw     r21, r0
	 seqi	r23, TREG_SYSCALL_NR_NAME, __NR_FAST_atomic_update
	 move	r24, r2
	}
	{
	 seq    r22, r21, r1     /* See if cmpxchg matches. */
	 and	r25, r21, r1     /* If atomic_update, compute (*mem & mask) */
	}
	{
	 or	r22, r22, r23    /* Skip compare branch for atomic_update. */
	 add	r25, r25, r2     /* Compute (*mem & mask) + addend. */
	}
	{
	 mvnz	r24, r23, r25    /* Use atomic_update value if appropriate. */
1690
	 bbns   r22, .Lcmpxchg32_nostore
1691
	}
1692 1693
	seq     r22, r24, r21    /* Are we storing the value we loaded? */
	bbs     r22, .Lcmpxchg32_nostore
1694 1695
	sw      r0, r24

1696
	/* The following instruction is the start of the second cache line. */
1697 1698 1699
	/* Do slow mtspr here so the following "mf" waits less. */
	{
	 move   sp, r27
1700
	 mtspr  SPR_EX_CONTEXT_K_0, r28
1701 1702 1703 1704 1705 1706 1707 1708 1709 1710
	}
	mf

	{
	 move   r0, r21
	 sw     ATOMIC_LOCK_REG_NAME, zero
	}
	iret

	/* Duplicated code here in the case where we don't overlap "mf" */
1711
.Lcmpxchg32_nostore:
1712 1713 1714 1715 1716 1717
	{
	 move   r0, r21
	 sw     ATOMIC_LOCK_REG_NAME, zero
	}
	{
	 move   sp, r27
1718
	 mtspr  SPR_EX_CONTEXT_K_0, r28
1719 1720 1721 1722 1723 1724 1725 1726 1727 1728 1729 1730 1731 1732 1733 1734 1735 1736 1737 1738 1739 1740 1741 1742 1743
	}
	iret

	/*
	 * The locking code is the same for 32-bit cmpxchg/atomic_update,
	 * and for 64-bit cmpxchg.  We provide it as a macro and put
	 * it into both versions.  We can't share the code literally
	 * since it depends on having the right branch-back address.
	 */
	.macro  cmpxchg_lock, bitwidth

	/* Lock; if we succeed, jump back up to the read-modify-write. */
#ifdef CONFIG_SMP
	tns     r21, ATOMIC_LOCK_REG_NAME
#else
	/*
	 * Non-SMP preserves all the lock infrastructure, to keep the
	 * code simpler for the interesting (SMP) case.  However, we do
	 * one small optimization here and in atomic_asm.S, which is
	 * to fake out acquiring the actual lock in the atomic_lock table.
	 */
	movei	r21, 0
#endif

	/* Issue the slow SPR here while the tns result is in flight. */
1744
	mfspr   r28, SPR_EX_CONTEXT_K_0
1745 1746 1747 1748 1749 1750 1751

	{
	 addi   r28, r28, 8    /* return to the instruction after the swint1 */
	 bzt    r21, .Ldo_cmpxchg\bitwidth
	}
	/*
	 * The preceding instruction is the last thing that must be
1752
	 * hot in the icache before we do the "tns" above.
1753 1754 1755 1756 1757 1758 1759 1760 1761 1762 1763 1764 1765 1766 1767 1768 1769 1770 1771 1772 1773 1774 1775 1776 1777 1778 1779 1780 1781 1782
	 */

#ifdef CONFIG_SMP
	/*
	 * We failed to acquire the tns lock on our first try.  Now use
	 * bounded exponential backoff to retry, like __atomic_spinlock().
	 */
	{
	 moveli r23, 2048       /* maximum backoff time in cycles */
	 moveli r25, 32         /* starting backoff time in cycles */
	}
1:	mfspr   r26, CYCLE_LOW  /* get start point for this backoff */
2:	mfspr   r22, CYCLE_LOW  /* test to see if we've backed off enough */
	sub     r22, r22, r26
	slt     r22, r22, r25
	bbst    r22, 2b
	{
	 shli   r25, r25, 1     /* double the backoff; retry the tns */
	 tns    r21, ATOMIC_LOCK_REG_NAME
	}
	slt     r26, r23, r25   /* is the proposed backoff too big? */
	{
	 mvnz   r25, r26, r23
	 bzt    r21, .Ldo_cmpxchg\bitwidth
	}
	j       1b
#endif /* CONFIG_SMP */
	.endm

.Lcmpxchg32_tns:
1783 1784 1785 1786 1787 1788
	/*
	 * This is the last instruction on the second cache line.
	 * The nop here loads the second line, then we fall through
	 * to the tns to load the third line before we take the lock.
	 */
	nop
1789 1790 1791 1792 1793 1794 1795 1796 1797 1798 1799 1800 1801 1802 1803 1804 1805 1806 1807 1808 1809 1810 1811 1812 1813 1814 1815 1816 1817 1818 1819 1820 1821 1822 1823 1824 1825 1826 1827 1828 1829 1830 1831 1832 1833 1834 1835 1836 1837
	cmpxchg_lock 32

	/*
	 * This code is invoked from sys_cmpxchg after most of the
	 * preconditions have been checked.  We still need to check
	 * that r0 is 8-byte aligned, since if it's not we won't
	 * actually be atomic.  However, ATOMIC_LOCK_REG has the atomic
	 * lock pointer and r27/r28 have the saved SP/PC.
	 * r23 is holding "r0 & 7" so we can test for alignment.
	 * The compare value is in r2/r3; the new value is in r4/r5.
	 * On return, we must put the old value in r0/r1.
	 */
	.align 64
.Lcmpxchg64:
	{
#if ATOMIC_LOCKS_FOUND_VIA_TABLE()
	 s2a	ATOMIC_LOCK_REG_NAME, r25, r21
#endif
	 bzt     r23, .Lcmpxchg64_tns
	}
	j       .Lcmpxchg_badaddr

.Ldo_cmpxchg64:
	{
	 lw     r21, r0
	 addi   r25, r0, 4
	}
	{
	 lw     r1, r25
	}
	seq     r26, r21, r2
	{
	 bz     r26, .Lcmpxchg64_mismatch
	 seq    r26, r1, r3
	}
	{
	 bz     r26, .Lcmpxchg64_mismatch
	}
	sw      r0, r4
	sw      r25, r5

	/*
	 * The 32-bit path provides optimized "match" and "mismatch"
	 * iret paths, but we don't have enough bundles in this cache line
	 * to do that, so we just make even the "mismatch" path do an "mf".
	 */
.Lcmpxchg64_mismatch:
	{
	 move   sp, r27
1838
	 mtspr  SPR_EX_CONTEXT_K_0, r28
1839 1840 1841 1842 1843 1844 1845 1846 1847 1848 1849 1850 1851 1852 1853 1854 1855 1856 1857 1858 1859 1860 1861 1862 1863 1864 1865 1866 1867 1868 1869 1870 1871 1872 1873 1874 1875 1876 1877
	}
	mf
	{
	 move   r0, r21
	 sw     ATOMIC_LOCK_REG_NAME, zero
	}
	iret

.Lcmpxchg64_tns:
	cmpxchg_lock 64


	/*
	 * Reset sp and revector to sys_cmpxchg_badaddr(), which will
	 * just raise the appropriate signal and exit.  Doing it this
	 * way means we don't have to duplicate the code in intvec.S's
	 * int_hand macro that locates the top of the stack.
	 */
.Lcmpxchg_badaddr:
	{
	 moveli TREG_SYSCALL_NR_NAME, __NR_cmpxchg_badaddr
	 move   sp, r27
	}
	j       intvec_SWINT_1
	ENDPROC(sys_cmpxchg)
	ENTRY(__sys_cmpxchg_end)


/* The single-step support may need to read all the registers. */
int_unalign:
	push_extra_callee_saves r0
	j       do_trap

/* Include .intrpt1 array of interrupt vectors */
	.section ".intrpt1", "ax"

#define op_handle_perf_interrupt bad_intr
#define op_handle_aux_perf_interrupt bad_intr

1878
#ifndef CONFIG_HARDWALL
1879
#define do_hardwall_trap bad_intr
1880
#endif
1881 1882 1883 1884 1885 1886 1887 1888 1889 1890 1891 1892 1893 1894 1895 1896 1897 1898 1899 1900 1901 1902 1903 1904 1905 1906 1907 1908 1909 1910 1911 1912 1913 1914 1915 1916 1917 1918

	int_hand     INT_ITLB_MISS, ITLB_MISS, \
		     do_page_fault, handle_interrupt_no_single_step
	int_hand     INT_MEM_ERROR, MEM_ERROR, bad_intr
	int_hand     INT_ILL, ILL, do_trap, handle_ill
	int_hand     INT_GPV, GPV, do_trap
	int_hand     INT_SN_ACCESS, SN_ACCESS, do_trap
	int_hand     INT_IDN_ACCESS, IDN_ACCESS, do_trap
	int_hand     INT_UDN_ACCESS, UDN_ACCESS, do_trap
	int_hand     INT_IDN_REFILL, IDN_REFILL, bad_intr
	int_hand     INT_UDN_REFILL, UDN_REFILL, bad_intr
	int_hand     INT_IDN_COMPLETE, IDN_COMPLETE, bad_intr
	int_hand     INT_UDN_COMPLETE, UDN_COMPLETE, bad_intr
	int_hand     INT_SWINT_3, SWINT_3, do_trap
	int_hand     INT_SWINT_2, SWINT_2, do_trap
	int_hand     INT_SWINT_1, SWINT_1, SYSCALL, handle_syscall
	int_hand     INT_SWINT_0, SWINT_0, do_trap
	int_hand     INT_UNALIGN_DATA, UNALIGN_DATA, int_unalign
	int_hand     INT_DTLB_MISS, DTLB_MISS, do_page_fault
	int_hand     INT_DTLB_ACCESS, DTLB_ACCESS, do_page_fault
	int_hand     INT_DMATLB_MISS, DMATLB_MISS, do_page_fault
	int_hand     INT_DMATLB_ACCESS, DMATLB_ACCESS, do_page_fault
	int_hand     INT_SNITLB_MISS, SNITLB_MISS, do_page_fault
	int_hand     INT_SN_NOTIFY, SN_NOTIFY, bad_intr
	int_hand     INT_SN_FIREWALL, SN_FIREWALL, do_hardwall_trap
	int_hand     INT_IDN_FIREWALL, IDN_FIREWALL, bad_intr
	int_hand     INT_UDN_FIREWALL, UDN_FIREWALL, do_hardwall_trap
	int_hand     INT_TILE_TIMER, TILE_TIMER, do_timer_interrupt
	int_hand     INT_IDN_TIMER, IDN_TIMER, bad_intr
	int_hand     INT_UDN_TIMER, UDN_TIMER, bad_intr
	int_hand     INT_DMA_NOTIFY, DMA_NOTIFY, bad_intr
	int_hand     INT_IDN_CA, IDN_CA, bad_intr
	int_hand     INT_UDN_CA, UDN_CA, bad_intr
	int_hand     INT_IDN_AVAIL, IDN_AVAIL, bad_intr
	int_hand     INT_UDN_AVAIL, UDN_AVAIL, bad_intr
	int_hand     INT_PERF_COUNT, PERF_COUNT, \
		     op_handle_perf_interrupt, handle_nmi
	int_hand     INT_INTCTRL_3, INTCTRL_3, bad_intr
1919 1920 1921 1922
#if CONFIG_KERNEL_PL == 2
	dc_dispatch  INT_INTCTRL_2, INTCTRL_2
	int_hand     INT_INTCTRL_1, INTCTRL_1, bad_intr
#else
1923 1924
	int_hand     INT_INTCTRL_2, INTCTRL_2, bad_intr
	dc_dispatch  INT_INTCTRL_1, INTCTRL_1
1925
#endif
1926 1927
	int_hand     INT_INTCTRL_0, INTCTRL_0, bad_intr
	int_hand     INT_MESSAGE_RCV_DWNCL, MESSAGE_RCV_DWNCL, \
1928
		     hv_message_intr
1929
	int_hand     INT_DEV_INTR_DWNCL, DEV_INTR_DWNCL, \
1930
		     tile_dev_intr
1931 1932 1933
	int_hand     INT_I_ASID, I_ASID, bad_intr
	int_hand     INT_D_ASID, D_ASID, bad_intr
	int_hand     INT_DMATLB_MISS_DWNCL, DMATLB_MISS_DWNCL, \
1934
		     do_page_fault
1935
	int_hand     INT_SNITLB_MISS_DWNCL, SNITLB_MISS_DWNCL, \
1936
		     do_page_fault
1937
	int_hand     INT_DMATLB_ACCESS_DWNCL, DMATLB_ACCESS_DWNCL, \
1938
		     do_page_fault
1939 1940 1941 1942 1943 1944 1945 1946 1947
	int_hand     INT_SN_CPL, SN_CPL, bad_intr
	int_hand     INT_DOUBLE_FAULT, DOUBLE_FAULT, do_trap
#if CHIP_HAS_AUX_PERF_COUNTERS()
	int_hand     INT_AUX_PERF_COUNT, AUX_PERF_COUNT, \
		     op_handle_aux_perf_interrupt, handle_nmi
#endif

	/* Synthetic interrupt delivered only by the simulator */
	int_hand     INT_BREAKPOINT, BREAKPOINT, do_breakpoint