cc20f8efca
NMI routine sdk_wDev_ProcessFiq seems to be written in C, meets ABI calling conventions for callee-saved registers. Not sure why SDK handlers saved them. NMI handler now also meets the ABI requirement that stack is 16 byte aligned (doesn't seem strictly necessary, but can't hurt.)
498 lines
16 KiB
ArmAsm
498 lines
16 KiB
ArmAsm
/* Xtensa Exception (ie interrupt) Vectors & low-level handler code
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*
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* Core exception handler code is placed in the .vecbase section, which gets
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* picked up specially in the linker script and placed at beginning of IRAM.
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*
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* The actual VecBase symbol should be the first thing in .vecbase (this is not
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* strictly important as it gets set by symbol lookup not by hardcoded address,
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* but having it at 0x40100000 means that the exception vectors have memorable
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* offsets, which match the default Boot ROM vector offsets. So convenient for
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* human understanding.
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*
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* Part of esp-open-rtos
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* Original vector contents Copyright (C) 2014-2015 Espressif Systems
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* Additions Copyright (C) Superhouse Automation Pty Ltd and Angus Gratton
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* BSD Licensed as described in the file LICENSE
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*/
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#include "led_debug.s"
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/* Some UserException causes, see table Table 4–64 in ISA reference */
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#define CAUSE_SYSCALL 1
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#define CAUSE_LOADSTORE 3
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#define CAUSE_LVL1INT 4
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.section .bss
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.balign 16
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NMIHandlerStack: # stack space for NMI handler
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.skip 4*0x100
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.NMIHandlerStackTop:
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.balign 16
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LoadStoreErrorHandlerStack:
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.word 0 # a0
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.word 0 # (unused)
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.word 0 # a2
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.word 0 # a3
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.word 0 # a4
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/***************************** Exception Vectors *****************************/
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.section .vecbase.text, "x"
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/* Note: Exception vectors must be aligned on a 256-byte (0x100) boundary or
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* they will not function properly. (This is taken care of in the linker
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* script by ensuring .vecbase.text is aligned properly, and putting VecBase
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* right at the beginning of .vecbase.text) */
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.org 0
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VecBase:
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.global VecBase
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/* IMPORTANT: exception vector literals will go here, but we
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* can't have more than 4 otherwise we push DebugExceptionVector past
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* offset 0x10 relative to VecBase. There should be ways to avoid this,
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* and also keep the VecBase offsets easy to read, but this works for
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* now. */
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.literal_position
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.org VecBase + 0x10
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DebugExceptionVector:
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.type DebugExceptionVector, @function
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wsr a0, excsave2
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call0 sdk_user_fatal_exception_handler
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rfi 2
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.org VecBase + 0x20
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NMIExceptionVector:
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.type NMIExceptionVector, @function
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j NMIExceptionHandler
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.org VecBase + 0x30
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KernelExceptionVector:
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.type KernelExceptionVector, @function
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break 1, 0
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call0 sdk_user_fatal_exception_handler
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rfe
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.org VecBase + 0x50
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UserExceptionVector:
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.type UserExceptionVector, @function
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wsr a1, excsave1
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rsr a1, exccause
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beqi a1, CAUSE_LOADSTORE, LoadStoreErrorHandler
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j UserExceptionHandler
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.org VecBase + 0x70
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DoubleExceptionVector:
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.type DoubleExceptionVector, @function
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break 1, 4
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call0 sdk_user_fatal_exception_handler
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/* Reset vector at offset 0x80 is unused, as vecbase gets reset to mask ROM
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* vectors on chip reset. */
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/*************************** LoadStoreError Handler **************************/
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.section .vecbase.text, "x"
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/* Xtensa "Load/Store Exception" handler:
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* Completes L8/L16 load instructions from Instruction address space, for which
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* the architecture only supports 32-bit reads.
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*
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* Called from UserExceptionVector if EXCCAUSE is LoadStoreErrorCause
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*
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* (Fast path (no branches) is for L8UI)
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*/
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.literal_position
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.balign 4
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LoadStoreErrorHandler:
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.type LoadStoreErrorHandler, @function
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/* Registers are saved in the address corresponding to their register
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* number times 4. This allows a quick and easy mapping later on when
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* needing to store the value to a particular register number. */
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movi sp, LoadStoreErrorHandlerStack
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s32i a0, sp, 0
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s32i a2, sp, 0x08
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s32i a3, sp, 0x0c
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s32i a4, sp, 0x10
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rsr a0, sar # Save SAR in a0 to restore later
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/* Examine the opcode which generated the exception */
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/* Note: Instructions are in this order to avoid pipeline stalls. */
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rsr a2, epc1
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movi a3, ~3
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ssa8l a2 # sar is now correct shift for aligned read
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and a2, a2, a3 # a2 now 4-byte aligned address of instruction
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l32i a4, a2, 0
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l32i a2, a2, 4
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movi a3, 0x00700F # opcode mask for l8ui/l16si/l16ui
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src a2, a2, a4 # a2 now instruction that failed
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and a3, a2, a3 # a3 is masked instruction
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bnei a3, 0x000002, .LSE_check_l16
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/* Note: At this point, opcode could technically be one of two things:
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* xx0xx2 (L8UI)
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* xx8xx2 (Reserved (invalid) opcode)
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* It is assumed that we'll never get to this point from an illegal
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* opcode, so we don't bother to check for that case and presume this
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* is always an L8UI. */
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movi a4, ~3
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rsr a3, excvaddr # read faulting address
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and a4, a3, a4 # a4 now word aligned read address
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l32i a4, a4, 0 # perform the actual read
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ssa8l a3 # sar is now shift to extract a3's byte
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srl a3, a4 # shift right correct distance
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extui a4, a3, 0, 8 # mask off bits we need for an l8
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.LSE_post_fetch:
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/* We jump back here after either the L8UI or the L16*I routines do the
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* necessary work to read the value from memory.
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* At this point, a2 holds the faulting instruction and a4 holds the
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* correctly read value.
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* Restore original SAR value (saved in a0) and update EPC so we'll
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* return back to the instruction following the one we just emulated */
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/* Note: Instructions are in this order to avoid pipeline stalls */
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rsr a3, epc1
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wsr a0, sar
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addi a3, a3, 0x3
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wsr a3, epc1
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/* Stupid opcode tricks: The jumptable we use later on needs 16 bytes
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* per entry (so we can avoid a second jump by just doing a RFE inside
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* each entry). Unfortunately, however, Xtensa doesn't have an addx16
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* operation to make that easy for us. Luckily, all of the faulting
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* opcodes we're processing are guaranteed to have bit 3 be zero, which
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* means if we just shift the register bits of the opcode down by 3
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* instead of 4, we will get the register number multiplied by 2. This
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* combined with an addx8 will give us an effective addx16 without
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* needing any extra shift operations. */
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extui a2, a2, 3, 5 # a2 is now destination register 0-15 times 2
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bgei a2, 10, .LSE_assign_reg # a5..a15 use jumptable
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beqi a2, 2, .LSE_assign_a1 # a1 uses a special routine
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/* We're storing into a0 or a2..a4, which are all saved in our "stack"
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* area. Calculate the correct address and stick the value in there,
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* then just do our normal restore and RFE (no jumps required, which
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* actually makes a0..a4 substantially faster). */
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addx2 a2, a2, sp
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s32i a4, a2, 0
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/* Restore all regs and return */
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l32i a0, sp, 0
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l32i a2, sp, 0x08
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l32i a3, sp, 0x0c
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l32i a4, sp, 0x10
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rsr a1, excsave1 # restore a1 saved by UserExceptionVector
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rfe
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.LSE_assign_reg:
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/* At this point, a2 contains the register number times 2, a4 is the
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* read value. */
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/* Calculate the jumptable address, and restore all regs except a2 and
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* a4 so we have less to do after jumping. */
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/* Note: Instructions are in this order to avoid pipeline stalls. */
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movi a3, .LSE_jumptable_base
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l32i a0, sp, 0
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addx8 a2, a2, a3 # a2 is now the address to jump to
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l32i a3, sp, 0x0c
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jx a2
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.balign 4
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.LSE_check_l16:
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/* At this point, a2 contains the opcode, a3 is masked opcode */
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movi a4, 0x001002 # l16si or l16ui opcode after masking
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bne a3, a4, .LSE_wrong_opcode
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/* Note: At this point, the opcode could be one of two things:
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* xx1xx2 (L16UI)
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* xx9xx2 (L16SI)
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* Both of these we can handle. */
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movi a4, ~3
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rsr a3, excvaddr # read faulting address
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and a4, a3, a4 # a4 now word aligned read address
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l32i a4, a4, 0 # perform the actual read
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ssa8l a3 # sar is now shift to extract a3's bytes
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srl a3, a4 # shift right correct distance
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extui a4, a3, 0, 16 # mask off bits we need for an l16
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bbci a2, 15, .LSE_post_fetch # Not a signed op
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bbci a4, 15, .LSE_post_fetch # Value does not need sign-extension
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movi a3, 0xFFFF0000
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or a4, a3, a4 # set 32-bit sign bits
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j .LSE_post_fetch
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.LSE_wrong_opcode:
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/* If we got here it's not an opcode we can try to fix, so bomb out.
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* Restore registers so any dump the fatal exception routine produces
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* will have correct values */
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wsr a0, sar
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l32i a0, sp, 0
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l32i a2, sp, 0x08
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l32i a3, sp, 0x0c
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l32i a4, sp, 0x10
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rsr a1, excsave1
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call0 sdk_user_fatal_exception_handler
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.balign 4
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.LSE_assign_a1:
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/* a1 is saved in excsave1, so just update that with the value, */
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wsr a4, excsave1
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/* Then restore all regs and return */
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l32i a0, sp, 0
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l32i a2, sp, 0x08
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l32i a3, sp, 0x0c
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l32i a4, sp, 0x10
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rsr a1, excsave1
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rfe
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.balign 4
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.LSE_jumptable:
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/* The first 5 entries (80 bytes) of this table are unused (registers
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* a0..a4 are handled separately above). Rather than have a whole bunch
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* of wasted space, we just pretend that the table starts 80 bytes
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* earlier in memory. */
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.set .LSE_jumptable_base, .LSE_jumptable - (16 * 5)
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.org .LSE_jumptable_base + (16 * 5)
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mov a5, a4
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l32i a2, sp, 0x08
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l32i a4, sp, 0x10
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rsr a1, excsave1
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rfe
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.org .LSE_jumptable_base + (16 * 6)
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mov a6, a4
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l32i a2, sp, 0x08
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l32i a4, sp, 0x10
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rsr a1, excsave1
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rfe
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.org .LSE_jumptable_base + (16 * 7)
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mov a7, a4
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l32i a2, sp, 0x08
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l32i a4, sp, 0x10
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rsr a1, excsave1
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rfe
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.org .LSE_jumptable_base + (16 * 8)
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mov a8, a4
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l32i a2, sp, 0x08
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l32i a4, sp, 0x10
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rsr a1, excsave1
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rfe
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.org .LSE_jumptable_base + (16 * 9)
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mov a9, a4
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l32i a2, sp, 0x08
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l32i a4, sp, 0x10
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rsr a1, excsave1
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rfe
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.org .LSE_jumptable_base + (16 * 10)
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mov a10, a4
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l32i a2, sp, 0x08
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l32i a4, sp, 0x10
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rsr a1, excsave1
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rfe
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.org .LSE_jumptable_base + (16 * 11)
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mov a11, a4
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l32i a2, sp, 0x08
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l32i a4, sp, 0x10
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rsr a1, excsave1
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rfe
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.org .LSE_jumptable_base + (16 * 12)
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mov a12, a4
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l32i a2, sp, 0x08
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l32i a4, sp, 0x10
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rsr a1, excsave1
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rfe
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.org .LSE_jumptable_base + (16 * 13)
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mov a13, a4
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l32i a2, sp, 0x08
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l32i a4, sp, 0x10
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rsr a1, excsave1
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rfe
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.org .LSE_jumptable_base + (16 * 14)
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mov a14, a4
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l32i a2, sp, 0x08
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l32i a4, sp, 0x10
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rsr a1, excsave1
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rfe
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.org .LSE_jumptable_base + (16 * 15)
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mov a15, a4
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l32i a2, sp, 0x08
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l32i a4, sp, 0x10
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rsr a1, excsave1
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rfe
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/****************************** call_user_start ******************************/
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.section .vecbase.text, "x"
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/* This is the first entrypoint called from the ROM after loading the image
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* into IRAM. It just sets up the VECBASE register to point at our own
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* exception vectors and then calls sdk_user_start() */
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.literal_position
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.balign 4
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call_user_start:
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.global call_user_start
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.type call_user_start, @function
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movi a2, VecBase
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wsr a2, vecbase
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call0 sdk_user_start
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/*************************** NMI Exception Handler ***************************/
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.section .vecbase.text, "x"
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.literal_position
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.balign 16
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NMIExceptionHandler:
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.type NMIExceptionHandler, @function
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wsr sp, excsave3 # excsave3 holds user stack
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movi sp, .NMIHandlerStackTop - 0x40
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s32i a0, sp, 0x00
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s32i a2, sp, 0x04
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s32i a3, sp, 0x08
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s32i a4, sp, 0x0c
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s32i a5, sp, 0x10
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s32i a6, sp, 0x14
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s32i a7, sp, 0x18
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s32i a8, sp, 0x1c
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s32i a9, sp, 0x20
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s32i a10, sp, 0x24
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s32i a11, sp, 0x28
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rsr a0, epc1
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s32i a0, sp, 0x2c
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rsr a0, exccause
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s32i a0, sp, 0x30
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rsr a0, excsave1
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s32i a0, sp, 0x34
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rsr a0, excvaddr
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s32i a0, sp, 0x38
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rsr a0, sar
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s32i a0, sp, 0x3c
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movi a0, 0x23 # Override PS for NMI handler
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wsr a0, ps
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rsync
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call0 sdk_wDev_ProcessFiq
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l32i a0, sp, 0x3c
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wsr a0, sar
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l32i a0, sp, 0x38
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wsr a0, excvaddr
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l32i a0, sp, 0x34
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wsr a0, excsave1
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l32i a0, sp, 0x30
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wsr a0, exccause
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l32i a0, sp, 0x2c
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wsr a0, epc1
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l32i a11, sp, 0x28
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l32i a10, sp, 0x24
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l32i a9, sp, 0x20
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l32i a8, sp, 0x1c
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l32i a7, sp, 0x18
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l32i a6, sp, 0x14
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l32i a5, sp, 0x10
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l32i a4, sp, 0x0c
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l32i a3, sp, 0x08
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movi a0, 0x33 # Reset PS
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wsr a0, ps
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rsync
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/* set dport nmi status to 1 (wDev_ProcessFiq clears bit 0 and verifies it
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* stays cleared, see
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* http://esp8266-re.foogod.com/wiki/WDev_ProcessFiq_%28IoT_RTOS_SDK_0.9.9%29)
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*/
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movi a0, 0x3ff00000
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movi a2, 0x1
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s32i a2, a0, 0
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l32i a2, sp, 0x04
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l32i a0, sp, 0x00
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movi a1, 0x0
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xsr a1, excsave3 # Load stack back from excsave3, clear excsave3
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rfi 3
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/*********************** General UserException Handler ***********************/
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.section .vecbase.text, "x"
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/* Called by UserExceptionVector if EXCCAUSE is anything other than
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* LoadStoreCause. */
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.literal_position
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.balign 4
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UserExceptionHandler:
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.type UserExceptionHandler, @function
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xsr a0, excsave1 # a0 now contains sp
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mov sp, a0
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addi sp, sp, -0x50
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s32i a0, sp, 0x10
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rsr a0, ps
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s32i a0, sp, 0x08
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rsr a0, epc1
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s32i a0, sp, 0x04
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rsr a0, excsave1
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s32i a0, sp, 0x0c
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movi a0, _xt_user_exit
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s32i a0, sp, 0x0
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call0 sdk__xt_int_enter
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movi a0, 0x23
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wsr a0, ps
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rsync
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rsr a2, exccause
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/* Any UserException cause other than a level 1 interrupt is fatal */
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bnei a2, CAUSE_LVL1INT, .UserFailOtherExceptionCause
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.UserHandleInterrupt:
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rsil a0, 1
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rsr a2, intenable
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rsr a3, interrupt
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movi a4, 0x3fff
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and a2, a2, a3
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and a2, a2, a4 # a2 = 0x3FFF & INTENABLE & INTERRUPT
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call0 _xt_isr_handler
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j sdk__xt_int_exit # once finished, jumps to _xt_user_exit via stack
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.literal_position
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.UserFailOtherExceptionCause:
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break 1, 1
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call0 sdk_user_fatal_exception_handler
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/* _xt_user_exit is pushed onto the stack as part of the user exception handler,
|
||
restores same set registers which were saved there and returns from exception */
|
||
_xt_user_exit:
|
||
.global _xt_user_exit
|
||
.type _xt_user_exit, @function
|
||
l32i a0, sp, 0x8
|
||
wsr a0, ps
|
||
l32i a0, sp, 0x4
|
||
wsr a0, epc1
|
||
l32i a0, sp, 0xc
|
||
l32i sp, sp, 0x10
|
||
rsync
|
||
rfe
|