This patch contains updated scripts to reduce qemu build time by

[kvmfornfv.git] / kernel / arch / xtensa / kernel / vectors.S

/*
 * arch/xtensa/kernel/vectors.S
 *
 * This file contains all exception vectors (user, kernel, and double),
 * as well as the window vectors (overflow and underflow), and the debug
 * vector. These are the primary vectors executed by the processor if an
 * exception occurs.
 *
 * This file is subject to the terms and conditions of the GNU General
 * Public License.  See the file "COPYING" in the main directory of
 * this archive for more details.
 *
 * Copyright (C) 2005 - 2008 Tensilica, Inc.
 *
 * Chris Zankel <chris@zankel.net>
 *
 */

/*
 * We use a two-level table approach. The user and kernel exception vectors
 * use a first-level dispatch table to dispatch the exception to a registered
 * fast handler or the default handler, if no fast handler was registered.
 * The default handler sets up a C-stack and dispatches the exception to a
 * registerd C handler in the second-level dispatch table.
 *
 * Fast handler entry condition:
 *
 *   a0:        trashed, original value saved on stack (PT_AREG0)
 *   a1:        a1
 *   a2:        new stack pointer, original value in depc
 *   a3:        dispatch table
 *   depc:      a2, original value saved on stack (PT_DEPC)
 *   excsave_1: a3
 *
 * The value for PT_DEPC saved to stack also functions as a boolean to
 * indicate that the exception is either a double or a regular exception:
 *
 *   PT_DEPC    >= VALID_DOUBLE_EXCEPTION_ADDRESS: double exception
 *              <  VALID_DOUBLE_EXCEPTION_ADDRESS: regular exception
 *
 * Note:  Neither the kernel nor the user exception handler generate literals.
 *
 */

#include <linux/linkage.h>
#include <asm/ptrace.h>
#include <asm/current.h>
#include <asm/asm-offsets.h>
#include <asm/pgtable.h>
#include <asm/processor.h>
#include <asm/page.h>
#include <asm/thread_info.h>
#include <asm/vectors.h>

#define WINDOW_VECTORS_SIZE   0x180


/*
 * User exception vector. (Exceptions with PS.UM == 1, PS.EXCM == 0)
 *
 * We get here when an exception occurred while we were in userland.
 * We switch to the kernel stack and jump to the first level handler
 * associated to the exception cause.
 *
 * Note: the saved kernel stack pointer (EXC_TABLE_KSTK) is already
 *       decremented by PT_USER_SIZE.
 */

        .section .UserExceptionVector.text, "ax"

ENTRY(_UserExceptionVector)

        xsr     a3, excsave1            # save a3 and get dispatch table
        wsr     a2, depc                # save a2
        l32i    a2, a3, EXC_TABLE_KSTK  # load kernel stack to a2
        s32i    a0, a2, PT_AREG0        # save a0 to ESF
        rsr     a0, exccause            # retrieve exception cause
        s32i    a0, a2, PT_DEPC         # mark it as a regular exception
        addx4   a0, a0, a3              # find entry in table
        l32i    a0, a0, EXC_TABLE_FAST_USER     # load handler
        xsr     a3, excsave1            # restore a3 and dispatch table
        jx      a0

ENDPROC(_UserExceptionVector)

/*
 * Kernel exception vector. (Exceptions with PS.UM == 0, PS.EXCM == 0)
 *
 * We get this exception when we were already in kernel space.
 * We decrement the current stack pointer (kernel) by PT_SIZE and
 * jump to the first-level handler associated with the exception cause.
 *
 * Note: we need to preserve space for the spill region.
 */

        .section .KernelExceptionVector.text, "ax"

ENTRY(_KernelExceptionVector)

        xsr     a3, excsave1            # save a3, and get dispatch table
        wsr     a2, depc                # save a2
        addi    a2, a1, -16-PT_SIZE     # adjust stack pointer
        s32i    a0, a2, PT_AREG0        # save a0 to ESF
        rsr     a0, exccause            # retrieve exception cause
        s32i    a0, a2, PT_DEPC         # mark it as a regular exception
        addx4   a0, a0, a3              # find entry in table
        l32i    a0, a0, EXC_TABLE_FAST_KERNEL   # load handler address
        xsr     a3, excsave1            # restore a3 and dispatch table
        jx      a0

ENDPROC(_KernelExceptionVector)

/*
 * Double exception vector (Exceptions with PS.EXCM == 1)
 * We get this exception when another exception occurs while were are
 * already in an exception, such as window overflow/underflow exception,
 * or 'expected' exceptions, for example memory exception when we were trying
 * to read data from an invalid address in user space.
 *
 * Note that this vector is never invoked for level-1 interrupts, because such
 * interrupts are disabled (masked) when PS.EXCM is set.
 *
 * We decode the exception and take the appropriate action.  However, the
 * double exception vector is much more careful, because a lot more error
 * cases go through the double exception vector than through the user and
 * kernel exception vectors.
 *
 * Occasionally, the kernel expects a double exception to occur.  This usually
 * happens when accessing user-space memory with the user's permissions
 * (l32e/s32e instructions).  The kernel state, though, is not always suitable
 * for immediate transfer of control to handle_double, where "normal" exception
 * processing occurs. Also in kernel mode, TLB misses can occur if accessing
 * vmalloc memory, possibly requiring repair in a double exception handler.
 *
 * The variable at TABLE_FIXUP offset from the pointer in EXCSAVE_1 doubles as
 * a boolean variable and a pointer to a fixup routine. If the variable
 * EXC_TABLE_FIXUP is non-zero, this handler jumps to that address. A value of
 * zero indicates to use the default kernel/user exception handler.
 * There is only one exception, when the value is identical to the exc_table
 * label, the kernel is in trouble. This mechanism is used to protect critical
 * sections, mainly when the handler writes to the stack to assert the stack
 * pointer is valid. Once the fixup/default handler leaves that area, the
 * EXC_TABLE_FIXUP variable is reset to the fixup handler or zero.
 *
 * Procedures wishing to use this mechanism should set EXC_TABLE_FIXUP to the
 * nonzero address of a fixup routine before it could cause a double exception
 * and reset it before it returns.
 *
 * Some other things to take care of when a fast exception handler doesn't
 * specify a particular fixup handler but wants to use the default handlers:
 *
 *  - The original stack pointer (in a1) must not be modified. The fast
 *    exception handler should only use a2 as the stack pointer.
 *
 *  - If the fast handler manipulates the stack pointer (in a2), it has to
 *    register a valid fixup handler and cannot use the default handlers.
 *
 *  - The handler can use any other generic register from a3 to a15, but it
 *    must save the content of these registers to stack (PT_AREG3...PT_AREGx)
 *
 *  - These registers must be saved before a double exception can occur.
 *
 *  - If we ever implement handling signals while in double exceptions, the
 *    number of registers a fast handler has saved (excluding a0 and a1) must
 *    be written to  PT_AREG1. (1 if only a3 is used, 2 for a3 and a4, etc. )
 *
 * The fixup handlers are special handlers:
 *
 *  - Fixup entry conditions differ from regular exceptions:
 *
 *      a0:        DEPC
 *      a1:        a1
 *      a2:        trashed, original value in EXC_TABLE_DOUBLE_SAVE
 *      a3:        exctable
 *      depc:      a0
 *      excsave_1: a3
 *
 *  - When the kernel enters the fixup handler, it still assumes it is in a
 *    critical section, so EXC_TABLE_FIXUP variable is set to exc_table.
 *    The fixup handler, therefore, has to re-register itself as the fixup
 *    handler before it returns from the double exception.
 *
 *  - Fixup handler can share the same exception frame with the fast handler.
 *    The kernel stack pointer is not changed when entering the fixup handler.
 *
 *  - Fixup handlers can jump to the default kernel and user exception
 *    handlers. Before it jumps, though, it has to setup a exception frame
 *    on stack. Because the default handler resets the register fixup handler
 *    the fixup handler must make sure that the default handler returns to
 *    it instead of the exception address, so it can re-register itself as
 *    the fixup handler.
 *
 * In case of a critical condition where the kernel cannot recover, we jump
 * to unrecoverable_exception with the following entry conditions.
 * All registers a0...a15 are unchanged from the last exception, except:
 *
 *      a0:        last address before we jumped to the unrecoverable_exception.
 *      excsave_1: a0
 *
 *
 * See the handle_alloca_user and spill_registers routines for example clients.
 *
 * FIXME: Note: we currently don't allow signal handling coming from a double
 *        exception, so the item markt with (*) is not required.
 */

        .section .DoubleExceptionVector.text, "ax"
        .begin literal_prefix .DoubleExceptionVector
        .globl _DoubleExceptionVector_WindowUnderflow
        .globl _DoubleExceptionVector_WindowOverflow

ENTRY(_DoubleExceptionVector)

        xsr     a3, excsave1
        s32i    a2, a3, EXC_TABLE_DOUBLE_SAVE

        /* Check for kernel double exception (usually fatal). */

        rsr     a2, ps
        _bbci.l a2, PS_UM_BIT, .Lksp

        /* Check if we are currently handling a window exception. */
        /* Note: We don't need to indicate that we enter a critical section. */

        xsr     a0, depc                # get DEPC, save a0

        movi    a2, WINDOW_VECTORS_VADDR
        _bltu   a0, a2, .Lfixup
        addi    a2, a2, WINDOW_VECTORS_SIZE
        _bgeu   a0, a2, .Lfixup

        /* Window overflow/underflow exception. Get stack pointer. */

        l32i    a2, a3, EXC_TABLE_KSTK

        /* Check for overflow/underflow exception, jump if overflow. */

        bbci.l  a0, 6, _DoubleExceptionVector_WindowOverflow

        /*
         * Restart window underflow exception.
         * Currently:
         *      depc = orig a0,
         *      a0 = orig DEPC,
         *      a2 = new sp based on KSTK from exc_table
         *      a3 = excsave_1
         *      excsave_1 = orig a3
         *
         * We return to the instruction in user space that caused the window
         * underflow exception. Therefore, we change window base to the value
         * before we entered the window underflow exception and prepare the
         * registers to return as if we were coming from a regular exception
         * by changing depc (in a0).
         * Note: We can trash the current window frame (a0...a3) and depc!
         */
_DoubleExceptionVector_WindowUnderflow:
        xsr     a3, excsave1
        wsr     a2, depc                # save stack pointer temporarily
        rsr     a0, ps
        extui   a0, a0, PS_OWB_SHIFT, PS_OWB_WIDTH
        wsr     a0, windowbase
        rsync

        /* We are now in the previous window frame. Save registers again. */

        xsr     a2, depc                # save a2 and get stack pointer
        s32i    a0, a2, PT_AREG0
        xsr     a3, excsave1
        rsr     a0, exccause
        s32i    a0, a2, PT_DEPC         # mark it as a regular exception
        addx4   a0, a0, a3
        xsr     a3, excsave1
        l32i    a0, a0, EXC_TABLE_FAST_USER
        jx      a0

        /*
         * We only allow the ITLB miss exception if we are in kernel space.
         * All other exceptions are unexpected and thus unrecoverable!
         */

#ifdef CONFIG_MMU
        .extern fast_second_level_miss_double_kernel

.Lksp:  /* a0: a0, a1: a1, a2: a2, a3: trashed, depc: depc, excsave: a3 */

        rsr     a3, exccause
        beqi    a3, EXCCAUSE_ITLB_MISS, 1f
        addi    a3, a3, -EXCCAUSE_DTLB_MISS
        bnez    a3, .Lunrecoverable
1:      movi    a3, fast_second_level_miss_double_kernel
        jx      a3
#else
.equ    .Lksp,  .Lunrecoverable
#endif

        /* Critical! We can't handle this situation. PANIC! */

        .extern unrecoverable_exception

.Lunrecoverable_fixup:
        l32i    a2, a3, EXC_TABLE_DOUBLE_SAVE
        xsr     a0, depc

.Lunrecoverable:
        rsr     a3, excsave1
        wsr     a0, excsave1
        movi    a0, unrecoverable_exception
        callx0  a0

.Lfixup:/* Check for a fixup handler or if we were in a critical section. */

        /* a0: depc, a1: a1, a2: trash, a3: exctable, depc: a0, excsave1: a3 */

        /* Enter critical section. */

        l32i    a2, a3, EXC_TABLE_FIXUP
        s32i    a3, a3, EXC_TABLE_FIXUP
        beq     a2, a3, .Lunrecoverable_fixup   # critical section
        beqz    a2, .Ldflt                      # no handler was registered

        /* a0: depc, a1: a1, a2: trash, a3: exctable, depc: a0, excsave: a3 */

        jx      a2

.Ldflt: /* Get stack pointer. */

        l32i    a2, a3, EXC_TABLE_DOUBLE_SAVE
        addi    a2, a2, -PT_USER_SIZE

        /* a0: depc, a1: a1, a2: kstk, a3: exctable, depc: a0, excsave: a3 */

        s32i    a0, a2, PT_DEPC
        l32i    a0, a3, EXC_TABLE_DOUBLE_SAVE
        xsr     a0, depc
        s32i    a0, a2, PT_AREG0

        /* a0: avail, a1: a1, a2: kstk, a3: exctable, depc: a2, excsave: a3 */

        rsr     a0, exccause
        addx4   a0, a0, a3
        xsr     a3, excsave1
        l32i    a0, a0, EXC_TABLE_FAST_USER
        jx      a0

        /*
         * Restart window OVERFLOW exception.
         * Currently:
         *      depc = orig a0,
         *      a0 = orig DEPC,
         *      a2 = new sp based on KSTK from exc_table
         *      a3 = EXCSAVE_1
         *      excsave_1 = orig a3
         *
         * We return to the instruction in user space that caused the window
         * overflow exception. Therefore, we change window base to the value
         * before we entered the window overflow exception and prepare the
         * registers to return as if we were coming from a regular exception
         * by changing DEPC (in a0).
         *
         * NOTE: We CANNOT trash the current window frame (a0...a3), but we
         * can clobber depc.
         *
         * The tricky part here is that overflow8 and overflow12 handlers
         * save a0, then clobber a0.  To restart the handler, we have to restore
         * a0 if the double exception was past the point where a0 was clobbered.
         *
         * To keep things simple, we take advantage of the fact all overflow
         * handlers save a0 in their very first instruction.  If DEPC was past
         * that instruction, we can safely restore a0 from where it was saved
         * on the stack.
         *
         * a0: depc, a1: a1, a2: kstk, a3: exc_table, depc: a0, excsave1: a3
         */
_DoubleExceptionVector_WindowOverflow:
        extui   a2, a0, 0, 6    # get offset into 64-byte vector handler
        beqz    a2, 1f          # if at start of vector, don't restore

        addi    a0, a0, -128
        bbsi.l  a0, 8, 1f       # don't restore except for overflow 8 and 12

        /*
         * This fixup handler is for the extremely unlikely case where the
         * overflow handler's reference thru a0 gets a hardware TLB refill
         * that bumps out the (distinct, aliasing) TLB entry that mapped its
         * prior references thru a9/a13, and where our reference now thru
         * a9/a13 gets a 2nd-level miss exception (not hardware TLB refill).
         */
        movi    a2, window_overflow_restore_a0_fixup
        s32i    a2, a3, EXC_TABLE_FIXUP
        l32i    a2, a3, EXC_TABLE_DOUBLE_SAVE
        xsr     a3, excsave1

        bbsi.l  a0, 7, 2f

        /*
         * Restore a0 as saved by _WindowOverflow8().
         */

        l32e    a0, a9, -16
        wsr     a0, depc        # replace the saved a0
        j       3f

2:
        /*
         * Restore a0 as saved by _WindowOverflow12().
         */

        l32e    a0, a13, -16
        wsr     a0, depc        # replace the saved a0
3:
        xsr     a3, excsave1
        movi    a0, 0
        s32i    a0, a3, EXC_TABLE_FIXUP
        s32i    a2, a3, EXC_TABLE_DOUBLE_SAVE
1:
        /*
         * Restore WindowBase while leaving all address registers restored.
         * We have to use ROTW for this, because WSR.WINDOWBASE requires
         * an address register (which would prevent restore).
         *
         * Window Base goes from 0 ... 7 (Module 8)
         * Window Start is 8 bits; Ex: (0b1010 1010):0x55 from series of call4s
         */

        rsr     a0, ps
        extui   a0, a0, PS_OWB_SHIFT, PS_OWB_WIDTH
        rsr     a2, windowbase
        sub     a0, a2, a0
        extui   a0, a0, 0, 3

        l32i    a2, a3, EXC_TABLE_DOUBLE_SAVE
        xsr     a3, excsave1
        beqi    a0, 1, .L1pane
        beqi    a0, 3, .L3pane

        rsr     a0, depc
        rotw    -2

        /*
         * We are now in the user code's original window frame.
         * Process the exception as a user exception as if it was
         * taken by the user code.
         *
         * This is similar to the user exception vector,
         * except that PT_DEPC isn't set to EXCCAUSE.
         */
1:
        xsr     a3, excsave1
        wsr     a2, depc
        l32i    a2, a3, EXC_TABLE_KSTK
        s32i    a0, a2, PT_AREG0
        rsr     a0, exccause

        s32i    a0, a2, PT_DEPC

_DoubleExceptionVector_handle_exception:
        addi    a0, a0, -EXCCAUSE_UNALIGNED
        beqz    a0, 2f
        addx4   a0, a0, a3
        l32i    a0, a0, EXC_TABLE_FAST_USER + 4 * EXCCAUSE_UNALIGNED
        xsr     a3, excsave1
        jx      a0
2:
        movi    a0, user_exception
        xsr     a3, excsave1
        jx      a0

.L1pane:
        rsr     a0, depc
        rotw    -1
        j       1b

.L3pane:
        rsr     a0, depc
        rotw    -3
        j       1b


ENDPROC(_DoubleExceptionVector)

        .end literal_prefix

        .text
/*
 * Fixup handler for TLB miss in double exception handler for window owerflow.
 * We get here with windowbase set to the window that was being spilled and
 * a0 trashed. a0 bit 7 determines if this is a call8 (bit clear) or call12
 * (bit set) window.
 *
 * We do the following here:
 * - go to the original window retaining a0 value;
 * - set up exception stack to return back to appropriate a0 restore code
 *   (we'll need to rotate window back and there's no place to save this
 *    information, use different return address for that);
 * - handle the exception;
 * - go to the window that was being spilled;
 * - set up window_overflow_restore_a0_fixup as a fixup routine;
 * - reload a0;
 * - restore the original window;
 * - reset the default fixup routine;
 * - return to user. By the time we get to this fixup handler all information
 *   about the conditions of the original double exception that happened in
 *   the window overflow handler is lost, so we just return to userspace to
 *   retry overflow from start.
 *
 * a0: value of depc, original value in depc
 * a2: trashed, original value in EXC_TABLE_DOUBLE_SAVE
 * a3: exctable, original value in excsave1
 */

ENTRY(window_overflow_restore_a0_fixup)

        rsr     a0, ps
        extui   a0, a0, PS_OWB_SHIFT, PS_OWB_WIDTH
        rsr     a2, windowbase
        sub     a0, a2, a0
        extui   a0, a0, 0, 3
        l32i    a2, a3, EXC_TABLE_DOUBLE_SAVE
        xsr     a3, excsave1

        _beqi   a0, 1, .Lhandle_1
        _beqi   a0, 3, .Lhandle_3

        .macro  overflow_fixup_handle_exception_pane n

        rsr     a0, depc
        rotw    -\n

        xsr     a3, excsave1
        wsr     a2, depc
        l32i    a2, a3, EXC_TABLE_KSTK
        s32i    a0, a2, PT_AREG0

        movi    a0, .Lrestore_\n
        s32i    a0, a2, PT_DEPC
        rsr     a0, exccause
        j       _DoubleExceptionVector_handle_exception

        .endm

        overflow_fixup_handle_exception_pane 2
.Lhandle_1:
        overflow_fixup_handle_exception_pane 1
.Lhandle_3:
        overflow_fixup_handle_exception_pane 3

        .macro  overflow_fixup_restore_a0_pane n

        rotw    \n
        /* Need to preserve a0 value here to be able to handle exception
         * that may occur on a0 reload from stack. It may occur because
         * TLB miss handler may not be atomic and pointer to page table
         * may be lost before we get here. There are no free registers,
         * so we need to use EXC_TABLE_DOUBLE_SAVE area.
         */
        xsr     a3, excsave1
        s32i    a2, a3, EXC_TABLE_DOUBLE_SAVE
        movi    a2, window_overflow_restore_a0_fixup
        s32i    a2, a3, EXC_TABLE_FIXUP
        l32i    a2, a3, EXC_TABLE_DOUBLE_SAVE
        xsr     a3, excsave1
        bbsi.l  a0, 7, 1f
        l32e    a0, a9, -16
        j       2f
1:
        l32e    a0, a13, -16
2:
        rotw    -\n

        .endm

.Lrestore_2:
        overflow_fixup_restore_a0_pane 2

.Lset_default_fixup:
        xsr     a3, excsave1
        s32i    a2, a3, EXC_TABLE_DOUBLE_SAVE
        movi    a2, 0
        s32i    a2, a3, EXC_TABLE_FIXUP
        l32i    a2, a3, EXC_TABLE_DOUBLE_SAVE
        xsr     a3, excsave1
        rfe

.Lrestore_1:
        overflow_fixup_restore_a0_pane 1
        j       .Lset_default_fixup
.Lrestore_3:
        overflow_fixup_restore_a0_pane 3
        j       .Lset_default_fixup

ENDPROC(window_overflow_restore_a0_fixup)

/*
 * Debug interrupt vector
 *
 * There is not much space here, so simply jump to another handler.
 * EXCSAVE[DEBUGLEVEL] has been set to that handler.
 */

        .section .DebugInterruptVector.text, "ax"

ENTRY(_DebugInterruptVector)

        xsr     a0, SREG_EXCSAVE + XCHAL_DEBUGLEVEL
        jx      a0

ENDPROC(_DebugInterruptVector)



/*
 * Medium priority level interrupt vectors
 *
 * Each takes less than 16 (0x10) bytes, no literals, by placing
 * the extra 8 bytes that would otherwise be required in the window
 * vectors area where there is space.  With relocatable vectors,
 * all vectors are within ~ 4 kB range of each other, so we can
 * simply jump (J) to another vector without having to use JX.
 *
 * common_exception code gets current IRQ level in PS.INTLEVEL
 * and preserves it for the IRQ handling time.
 */

        .macro  irq_entry_level level

        .if     XCHAL_EXCM_LEVEL >= \level
        .section .Level\level\()InterruptVector.text, "ax"
ENTRY(_Level\level\()InterruptVector)
        wsr     a0, excsave2
        rsr     a0, epc\level
        wsr     a0, epc1
        .if     \level <= LOCKLEVEL
        movi    a0, EXCCAUSE_LEVEL1_INTERRUPT
        .else
        movi    a0, EXCCAUSE_MAPPED_NMI
        .endif
        wsr     a0, exccause
        rsr     a0, eps\level
                                        # branch to user or kernel vector
        j       _SimulateUserKernelVectorException
        .endif

        .endm

        irq_entry_level 2
        irq_entry_level 3
        irq_entry_level 4
        irq_entry_level 5
        irq_entry_level 6


/* Window overflow and underflow handlers.
 * The handlers must be 64 bytes apart, first starting with the underflow
 * handlers underflow-4 to underflow-12, then the overflow handlers
 * overflow-4 to overflow-12.
 *
 * Note: We rerun the underflow handlers if we hit an exception, so
 *       we try to access any page that would cause a page fault early.
 */

#define ENTRY_ALIGN64(name)     \
        .globl name;            \
        .align 64;              \
        name:

        .section                .WindowVectors.text, "ax"


/* 4-Register Window Overflow Vector (Handler) */

ENTRY_ALIGN64(_WindowOverflow4)

        s32e    a0, a5, -16
        s32e    a1, a5, -12
        s32e    a2, a5,  -8
        s32e    a3, a5,  -4
        rfwo

ENDPROC(_WindowOverflow4)


#if XCHAL_EXCM_LEVEL >= 2
        /*  Not a window vector - but a convenient location
         *  (where we know there's space) for continuation of
         *  medium priority interrupt dispatch code.
         *  On entry here, a0 contains PS, and EPC2 contains saved a0:
         */
        .align 4
_SimulateUserKernelVectorException:
        addi    a0, a0, (1 << PS_EXCM_BIT)
#if !XTENSA_FAKE_NMI
        wsr     a0, ps
#endif
        bbsi.l  a0, PS_UM_BIT, 1f       # branch if user mode
        xsr     a0, excsave2            # restore a0
        j       _KernelExceptionVector  # simulate kernel vector exception
1:      xsr     a0, excsave2            # restore a0
        j       _UserExceptionVector    # simulate user vector exception
#endif


/* 4-Register Window Underflow Vector (Handler) */

ENTRY_ALIGN64(_WindowUnderflow4)

        l32e    a0, a5, -16
        l32e    a1, a5, -12
        l32e    a2, a5,  -8
        l32e    a3, a5,  -4
        rfwu

ENDPROC(_WindowUnderflow4)

/* 8-Register Window Overflow Vector (Handler) */

ENTRY_ALIGN64(_WindowOverflow8)

        s32e    a0, a9, -16
        l32e    a0, a1, -12
        s32e    a2, a9,  -8
        s32e    a1, a9, -12
        s32e    a3, a9,  -4
        s32e    a4, a0, -32
        s32e    a5, a0, -28
        s32e    a6, a0, -24
        s32e    a7, a0, -20
        rfwo

ENDPROC(_WindowOverflow8)

/* 8-Register Window Underflow Vector (Handler) */

ENTRY_ALIGN64(_WindowUnderflow8)

        l32e    a1, a9, -12
        l32e    a0, a9, -16
        l32e    a7, a1, -12
        l32e    a2, a9,  -8
        l32e    a4, a7, -32
        l32e    a3, a9,  -4
        l32e    a5, a7, -28
        l32e    a6, a7, -24
        l32e    a7, a7, -20
        rfwu

ENDPROC(_WindowUnderflow8)

/* 12-Register Window Overflow Vector (Handler) */

ENTRY_ALIGN64(_WindowOverflow12)

        s32e    a0,  a13, -16
        l32e    a0,  a1,  -12
        s32e    a1,  a13, -12
        s32e    a2,  a13,  -8
        s32e    a3,  a13,  -4
        s32e    a4,  a0,  -48
        s32e    a5,  a0,  -44
        s32e    a6,  a0,  -40
        s32e    a7,  a0,  -36
        s32e    a8,  a0,  -32
        s32e    a9,  a0,  -28
        s32e    a10, a0,  -24
        s32e    a11, a0,  -20
        rfwo

ENDPROC(_WindowOverflow12)

/* 12-Register Window Underflow Vector (Handler) */

ENTRY_ALIGN64(_WindowUnderflow12)

        l32e    a1,  a13, -12
        l32e    a0,  a13, -16
        l32e    a11, a1,  -12
        l32e    a2,  a13,  -8
        l32e    a4,  a11, -48
        l32e    a8,  a11, -32
        l32e    a3,  a13,  -4
        l32e    a5,  a11, -44
        l32e    a6,  a11, -40
        l32e    a7,  a11, -36
        l32e    a9,  a11, -28
        l32e    a10, a11, -24
        l32e    a11, a11, -20
        rfwu

ENDPROC(_WindowUnderflow12)

        .text