dbdb299bb1
1. move xtensa specific files out of esp32 component 2. merge xtensa-debug-module component into xtensa
939 lines
27 KiB
C
939 lines
27 KiB
C
/*
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* xtensa/coreasm.h -- assembler-specific definitions that depend on CORE configuration
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*
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* Source for configuration-independent binaries (which link in a
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* configuration-specific HAL library) must NEVER include this file.
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* It is perfectly normal, however, for the HAL itself to include this file.
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*
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* This file must NOT include xtensa/config/system.h. Any assembler
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* header file that depends on system information should likely go
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* in a new systemasm.h (or sysasm.h) header file.
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*
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* NOTE: macro beqi32 is NOT configuration-dependent, and is placed
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* here until we have a proper configuration-independent header file.
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*/
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/* $Id: //depot/rel/Eaglenest/Xtensa/OS/include/xtensa/coreasm.h#3 $ */
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/*
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* Copyright (c) 2000-2014 Tensilica Inc.
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*
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* Permission is hereby granted, free of charge, to any person obtaining
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* a copy of this software and associated documentation files (the
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* "Software"), to deal in the Software without restriction, including
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* without limitation the rights to use, copy, modify, merge, publish,
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* distribute, sublicense, and/or sell copies of the Software, and to
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* permit persons to whom the Software is furnished to do so, subject to
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* the following conditions:
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*
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* The above copyright notice and this permission notice shall be included
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* in all copies or substantial portions of the Software.
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*
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* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND,
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* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF
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* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.
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* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY
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* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT,
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* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE
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* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
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*/
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#ifndef XTENSA_COREASM_H
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#define XTENSA_COREASM_H
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/*
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* Tell header files this is assembly source, so they can avoid non-assembler
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* definitions (eg. C types etc):
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*/
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#ifndef _ASMLANGUAGE /* conditionalize to avoid cpp warnings (3rd parties might use same macro) */
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#define _ASMLANGUAGE
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#endif
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#include <xtensa/config/core.h>
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#include <xtensa/config/specreg.h>
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#include <xtensa/config/system.h>
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/*
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* Assembly-language specific definitions (assembly macros, etc.).
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*/
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/*----------------------------------------------------------------------
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* find_ms_setbit
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*
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* This macro finds the most significant bit that is set in <as>
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* and return its index + <base> in <ad>, or <base> - 1 if <as> is zero.
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* The index counts starting at zero for the lsbit, so the return
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* value ranges from <base>-1 (no bit set) to <base>+31 (msbit set).
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*
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* Parameters:
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* <ad> destination address register (any register)
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* <as> source address register
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* <at> temporary address register (must be different than <as>)
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* <base> constant value added to result (usually 0 or 1)
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* On entry:
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* <ad> = undefined if different than <as>
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* <as> = value whose most significant set bit is to be found
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* <at> = undefined
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* no other registers are used by this macro.
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* On exit:
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* <ad> = <base> + index of msbit set in original <as>,
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* = <base> - 1 if original <as> was zero.
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* <as> clobbered (if not <ad>)
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* <at> clobbered (if not <ad>)
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* Example:
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* find_ms_setbit a0, a4, a0, 0 -- return in a0 index of msbit set in a4
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*/
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.macro find_ms_setbit ad, as, at, base
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#if XCHAL_HAVE_NSA
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movi \at, 31+\base
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nsau \as, \as // get index of \as, numbered from msbit (32 if absent)
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sub \ad, \at, \as // get numbering from lsbit (0..31, -1 if absent)
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#else /* XCHAL_HAVE_NSA */
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movi \at, \base // start with result of 0 (point to lsbit of 32)
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beqz \as, 2f // special case for zero argument: return -1
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bltui \as, 0x10000, 1f // is it one of the 16 lsbits? (if so, check lower 16 bits)
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addi \at, \at, 16 // no, increment result to upper 16 bits (of 32)
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//srli \as, \as, 16 // check upper half (shift right 16 bits)
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extui \as, \as, 16, 16 // check upper half (shift right 16 bits)
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1: bltui \as, 0x100, 1f // is it one of the 8 lsbits? (if so, check lower 8 bits)
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addi \at, \at, 8 // no, increment result to upper 8 bits (of 16)
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srli \as, \as, 8 // shift right to check upper 8 bits
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1: bltui \as, 0x10, 1f // is it one of the 4 lsbits? (if so, check lower 4 bits)
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addi \at, \at, 4 // no, increment result to upper 4 bits (of 8)
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srli \as, \as, 4 // shift right 4 bits to check upper half
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1: bltui \as, 0x4, 1f // is it one of the 2 lsbits? (if so, check lower 2 bits)
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addi \at, \at, 2 // no, increment result to upper 2 bits (of 4)
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srli \as, \as, 2 // shift right 2 bits to check upper half
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1: bltui \as, 0x2, 1f // is it the lsbit?
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addi \at, \at, 2 // no, increment result to upper bit (of 2)
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2: addi \at, \at, -1 // (from just above: add 1; from beqz: return -1)
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//srli \as, \as, 1
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1: // done! \at contains index of msbit set (or -1 if none set)
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.if 0x\ad - 0x\at // destination different than \at ? (works because regs are a0-a15)
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mov \ad, \at // then move result to \ad
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.endif
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#endif /* XCHAL_HAVE_NSA */
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.endm // find_ms_setbit
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/*----------------------------------------------------------------------
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* find_ls_setbit
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*
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* This macro finds the least significant bit that is set in <as>,
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* and return its index in <ad>.
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* Usage is the same as for the find_ms_setbit macro.
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* Example:
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* find_ls_setbit a0, a4, a0, 0 -- return in a0 index of lsbit set in a4
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*/
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.macro find_ls_setbit ad, as, at, base
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neg \at, \as // keep only the least-significant bit that is set...
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and \as, \at, \as // ... in \as
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find_ms_setbit \ad, \as, \at, \base
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.endm // find_ls_setbit
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/*----------------------------------------------------------------------
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* find_ls_one
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*
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* Same as find_ls_setbit with base zero.
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* Source (as) and destination (ad) registers must be different.
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* Provided for backward compatibility.
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*/
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.macro find_ls_one ad, as
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find_ls_setbit \ad, \as, \ad, 0
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.endm // find_ls_one
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/*----------------------------------------------------------------------
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* floop, floopnez, floopgtz, floopend
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*
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* These macros are used for fast inner loops that
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* work whether or not the Loops options is configured.
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* If the Loops option is configured, they simply use
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* the zero-overhead LOOP instructions; otherwise
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* they use explicit decrement and branch instructions.
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*
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* They are used in pairs, with floop, floopnez or floopgtz
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* at the beginning of the loop, and floopend at the end.
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*
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* Each pair of loop macro calls must be given the loop count
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* address register and a unique label for that loop.
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*
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* Example:
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*
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* movi a3, 16 // loop 16 times
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* floop a3, myloop1
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* :
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* bnez a7, end1 // exit loop if a7 != 0
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* :
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* floopend a3, myloop1
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* end1:
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*
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* Like the LOOP instructions, these macros cannot be
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* nested, must include at least one instruction,
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* cannot call functions inside the loop, etc.
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* The loop can be exited by jumping to the instruction
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* following floopend (or elsewhere outside the loop),
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* or continued by jumping to a NOP instruction placed
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* immediately before floopend.
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*
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* Unlike LOOP instructions, the register passed to floop*
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* cannot be used inside the loop, because it is used as
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* the loop counter if the Loops option is not configured.
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* And its value is undefined after exiting the loop.
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* And because the loop counter register is active inside
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* the loop, you can't easily use this construct to loop
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* across a register file using ROTW as you might with LOOP
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* instructions, unless you copy the loop register along.
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*/
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/* Named label version of the macros: */
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.macro floop ar, endlabel
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floop_ \ar, .Lfloopstart_\endlabel, .Lfloopend_\endlabel
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.endm
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.macro floopnez ar, endlabel
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floopnez_ \ar, .Lfloopstart_\endlabel, .Lfloopend_\endlabel
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.endm
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.macro floopgtz ar, endlabel
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floopgtz_ \ar, .Lfloopstart_\endlabel, .Lfloopend_\endlabel
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.endm
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.macro floopend ar, endlabel
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floopend_ \ar, .Lfloopstart_\endlabel, .Lfloopend_\endlabel
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.endm
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/* Numbered local label version of the macros: */
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#if 0 /*UNTESTED*/
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.macro floop89 ar
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floop_ \ar, 8, 9f
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.endm
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.macro floopnez89 ar
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floopnez_ \ar, 8, 9f
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.endm
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.macro floopgtz89 ar
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floopgtz_ \ar, 8, 9f
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.endm
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.macro floopend89 ar
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floopend_ \ar, 8b, 9
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.endm
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#endif /*0*/
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/* Underlying version of the macros: */
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.macro floop_ ar, startlabel, endlabelref
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.ifdef _infloop_
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.if _infloop_
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.err // Error: floop cannot be nested
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.endif
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.endif
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.set _infloop_, 1
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#if XCHAL_HAVE_LOOPS
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loop \ar, \endlabelref
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#else /* XCHAL_HAVE_LOOPS */
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\startlabel:
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addi \ar, \ar, -1
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#endif /* XCHAL_HAVE_LOOPS */
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.endm // floop_
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.macro floopnez_ ar, startlabel, endlabelref
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.ifdef _infloop_
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.if _infloop_
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.err // Error: floopnez cannot be nested
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.endif
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.endif
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.set _infloop_, 1
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#if XCHAL_HAVE_LOOPS
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loopnez \ar, \endlabelref
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#else /* XCHAL_HAVE_LOOPS */
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beqz \ar, \endlabelref
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\startlabel:
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addi \ar, \ar, -1
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#endif /* XCHAL_HAVE_LOOPS */
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.endm // floopnez_
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.macro floopgtz_ ar, startlabel, endlabelref
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.ifdef _infloop_
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.if _infloop_
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.err // Error: floopgtz cannot be nested
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.endif
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.endif
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.set _infloop_, 1
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#if XCHAL_HAVE_LOOPS
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loopgtz \ar, \endlabelref
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#else /* XCHAL_HAVE_LOOPS */
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bltz \ar, \endlabelref
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beqz \ar, \endlabelref
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\startlabel:
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addi \ar, \ar, -1
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#endif /* XCHAL_HAVE_LOOPS */
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.endm // floopgtz_
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.macro floopend_ ar, startlabelref, endlabel
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.ifndef _infloop_
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.err // Error: floopend without matching floopXXX
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.endif
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.ifeq _infloop_
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.err // Error: floopend without matching floopXXX
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.endif
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.set _infloop_, 0
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#if ! XCHAL_HAVE_LOOPS
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bnez \ar, \startlabelref
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#endif /* XCHAL_HAVE_LOOPS */
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\endlabel:
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.endm // floopend_
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/*----------------------------------------------------------------------
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* crsil -- conditional RSIL (read/set interrupt level)
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*
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* Executes the RSIL instruction if it exists, else just reads PS.
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* The RSIL instruction does not exist in the new exception architecture
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* if the interrupt option is not selected.
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*/
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.macro crsil ar, newlevel
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#if XCHAL_HAVE_OLD_EXC_ARCH || XCHAL_HAVE_INTERRUPTS
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rsil \ar, \newlevel
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#else
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rsr \ar, PS
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#endif
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.endm // crsil
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/*----------------------------------------------------------------------
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* safe_movi_a0 -- move constant into a0 when L32R is not safe
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*
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* This macro is typically used by interrupt/exception handlers.
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* Loads a 32-bit constant in a0, without using any other register,
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* and without corrupting the LITBASE register, even when the
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* value of the LITBASE register is unknown (eg. when application
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* code and interrupt/exception handling code are built independently,
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* and thus with independent values of the LITBASE register;
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* debug monitors are one example of this).
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*
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* Worst-case size of resulting code: 17 bytes.
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*/
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.macro safe_movi_a0 constant
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#if XCHAL_HAVE_ABSOLUTE_LITERALS
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/* Contort a PC-relative literal load even though we may be in litbase-relative mode: */
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j 1f
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.begin no-transform // ensure what follows is assembled exactly as-is
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.align 4 // ensure constant and call0 target ...
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.byte 0 // ... are 4-byte aligned (call0 instruction is 3 bytes long)
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1: call0 2f // read PC (that follows call0) in a0
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.long \constant // 32-bit constant to load into a0
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2:
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.end no-transform
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l32i a0, a0, 0 // load constant
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#else
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movi a0, \constant // no LITBASE, can assume PC-relative L32R
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#endif
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.endm
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/*----------------------------------------------------------------------
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* window_spill{4,8,12}
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*
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* These macros spill callers' register windows to the stack.
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* They work for both privileged and non-privileged tasks.
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* Must be called from a windowed ABI context, eg. within
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* a windowed ABI function (ie. valid stack frame, window
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* exceptions enabled, not in exception mode, etc).
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*
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* This macro requires a single invocation of the window_spill_common
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* macro in the same assembly unit and section.
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*
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* Note that using window_spill{4,8,12} macros is more efficient
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* than calling a function implemented using window_spill_function,
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* because the latter needs extra code to figure out the size of
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* the call to the spilling function.
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*
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* Example usage:
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*
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* .text
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* .align 4
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* .global some_function
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* .type some_function,@function
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* some_function:
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* entry a1, 16
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* :
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* :
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*
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* window_spill4 // Spill windows of some_function's callers; preserves a0..a3 only;
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* // to use window_spill{8,12} in this example function we'd have
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* // to increase space allocated by the entry instruction, because
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* // 16 bytes only allows call4; 32 or 48 bytes (+locals) are needed
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* // for call8/window_spill8 or call12/window_spill12 respectively.
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*
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* :
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*
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* retw
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*
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* window_spill_common // instantiates code used by window_spill4
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*
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*
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* On entry:
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* none (if window_spill4)
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* stack frame has enough space allocated for call8 (if window_spill8)
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* stack frame has enough space allocated for call12 (if window_spill12)
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* On exit:
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* a4..a15 clobbered (if window_spill4)
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* a8..a15 clobbered (if window_spill8)
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* a12..a15 clobbered (if window_spill12)
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* no caller windows are in live registers
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*/
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.macro window_spill4
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#if XCHAL_HAVE_WINDOWED
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# if XCHAL_NUM_AREGS == 16
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movi a15, 0 // for 16-register files, no need to call to reach the end
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# elif XCHAL_NUM_AREGS == 32
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call4 .L__wdwspill_assist28 // call deep enough to clear out any live callers
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# elif XCHAL_NUM_AREGS == 64
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call4 .L__wdwspill_assist60 // call deep enough to clear out any live callers
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# endif
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#endif
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.endm // window_spill4
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.macro window_spill8
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#if XCHAL_HAVE_WINDOWED
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# if XCHAL_NUM_AREGS == 16
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movi a15, 0 // for 16-register files, no need to call to reach the end
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# elif XCHAL_NUM_AREGS == 32
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call8 .L__wdwspill_assist24 // call deep enough to clear out any live callers
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# elif XCHAL_NUM_AREGS == 64
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call8 .L__wdwspill_assist56 // call deep enough to clear out any live callers
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# endif
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#endif
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.endm // window_spill8
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.macro window_spill12
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#if XCHAL_HAVE_WINDOWED
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# if XCHAL_NUM_AREGS == 16
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movi a15, 0 // for 16-register files, no need to call to reach the end
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# elif XCHAL_NUM_AREGS == 32
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call12 .L__wdwspill_assist20 // call deep enough to clear out any live callers
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# elif XCHAL_NUM_AREGS == 64
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call12 .L__wdwspill_assist52 // call deep enough to clear out any live callers
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# endif
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#endif
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.endm // window_spill12
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/*----------------------------------------------------------------------
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* window_spill_function
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*
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* This macro outputs a function that will spill its caller's callers'
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* register windows to the stack. Eg. it could be used to implement
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* a version of xthal_window_spill() that works in non-privileged tasks.
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* This works for both privileged and non-privileged tasks.
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*
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* Typical usage:
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*
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* .text
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* .align 4
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* .global my_spill_function
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* .type my_spill_function,@function
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* my_spill_function:
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* window_spill_function
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*
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* On entry to resulting function:
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* none
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* On exit from resulting function:
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* none (no caller windows are in live registers)
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*/
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.macro window_spill_function
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#if XCHAL_HAVE_WINDOWED
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# if XCHAL_NUM_AREGS == 32
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entry sp, 48
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bbci.l a0, 31, 1f // branch if called with call4
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bbsi.l a0, 30, 2f // branch if called with call12
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call8 .L__wdwspill_assist16 // called with call8, only need another 8
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retw
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1: call12 .L__wdwspill_assist16 // called with call4, only need another 12
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retw
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2: call4 .L__wdwspill_assist16 // called with call12, only need another 4
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retw
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# elif XCHAL_NUM_AREGS == 64
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entry sp, 48
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bbci.l a0, 31, 1f // branch if called with call4
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bbsi.l a0, 30, 2f // branch if called with call12
|
|
call4 .L__wdwspill_assist52 // called with call8, only need a call4
|
|
retw
|
|
1: call8 .L__wdwspill_assist52 // called with call4, only need a call8
|
|
retw
|
|
2: call12 .L__wdwspill_assist40 // called with call12, can skip a call12
|
|
retw
|
|
# elif XCHAL_NUM_AREGS == 16
|
|
entry sp, 16
|
|
bbci.l a0, 31, 1f // branch if called with call4
|
|
bbsi.l a0, 30, 2f // branch if called with call12
|
|
movi a7, 0 // called with call8
|
|
retw
|
|
1: movi a11, 0 // called with call4
|
|
2: retw // if called with call12, everything already spilled
|
|
|
|
// movi a15, 0 // trick to spill all but the direct caller
|
|
// j 1f
|
|
// // The entry instruction is magical in the assembler (gets auto-aligned)
|
|
// // so we have to jump to it to avoid falling through the padding.
|
|
// // We need entry/retw to know where to return.
|
|
//1: entry sp, 16
|
|
// retw
|
|
# else
|
|
# error "unrecognized address register file size"
|
|
# endif
|
|
|
|
#endif /* XCHAL_HAVE_WINDOWED */
|
|
window_spill_common
|
|
.endm // window_spill_function
|
|
|
|
/*----------------------------------------------------------------------
|
|
* window_spill_common
|
|
*
|
|
* Common code used by any number of invocations of the window_spill##
|
|
* and window_spill_function macros.
|
|
*
|
|
* Must be instantiated exactly once within a given assembly unit,
|
|
* within call/j range of and same section as window_spill##
|
|
* macro invocations for that assembly unit.
|
|
* (Is automatically instantiated by the window_spill_function macro.)
|
|
*/
|
|
|
|
.macro window_spill_common
|
|
#if XCHAL_HAVE_WINDOWED && (XCHAL_NUM_AREGS == 32 || XCHAL_NUM_AREGS == 64)
|
|
.ifndef .L__wdwspill_defined
|
|
# if XCHAL_NUM_AREGS >= 64
|
|
.L__wdwspill_assist60:
|
|
entry sp, 32
|
|
call8 .L__wdwspill_assist52
|
|
retw
|
|
.L__wdwspill_assist56:
|
|
entry sp, 16
|
|
call4 .L__wdwspill_assist52
|
|
retw
|
|
.L__wdwspill_assist52:
|
|
entry sp, 48
|
|
call12 .L__wdwspill_assist40
|
|
retw
|
|
.L__wdwspill_assist40:
|
|
entry sp, 48
|
|
call12 .L__wdwspill_assist28
|
|
retw
|
|
# endif
|
|
.L__wdwspill_assist28:
|
|
entry sp, 48
|
|
call12 .L__wdwspill_assist16
|
|
retw
|
|
.L__wdwspill_assist24:
|
|
entry sp, 32
|
|
call8 .L__wdwspill_assist16
|
|
retw
|
|
.L__wdwspill_assist20:
|
|
entry sp, 16
|
|
call4 .L__wdwspill_assist16
|
|
retw
|
|
.L__wdwspill_assist16:
|
|
entry sp, 16
|
|
movi a15, 0
|
|
retw
|
|
.set .L__wdwspill_defined, 1
|
|
.endif
|
|
#endif /* XCHAL_HAVE_WINDOWED with 32 or 64 aregs */
|
|
.endm // window_spill_common
|
|
|
|
/*----------------------------------------------------------------------
|
|
* beqi32
|
|
*
|
|
* macro implements version of beqi for arbitrary 32-bit immediate value
|
|
*
|
|
* beqi32 ax, ay, imm32, label
|
|
*
|
|
* Compares value in register ax with imm32 value and jumps to label if
|
|
* equal. Clobbers register ay if needed
|
|
*
|
|
*/
|
|
.macro beqi32 ax, ay, imm, label
|
|
.ifeq ((\imm-1) & ~7) // 1..8 ?
|
|
beqi \ax, \imm, \label
|
|
.else
|
|
.ifeq (\imm+1) // -1 ?
|
|
beqi \ax, \imm, \label
|
|
.else
|
|
.ifeq (\imm) // 0 ?
|
|
beqz \ax, \label
|
|
.else
|
|
// We could also handle immediates 10,12,16,32,64,128,256
|
|
// but it would be a long macro...
|
|
movi \ay, \imm
|
|
beq \ax, \ay, \label
|
|
.endif
|
|
.endif
|
|
.endif
|
|
.endm // beqi32
|
|
|
|
/*----------------------------------------------------------------------
|
|
* isync_retw_nop
|
|
*
|
|
* This macro must be invoked immediately after ISYNC if ISYNC
|
|
* would otherwise be immediately followed by RETW (or other instruction
|
|
* modifying WindowBase or WindowStart), in a context where
|
|
* kernel vector mode may be selected, and level-one interrupts
|
|
* and window overflows may be enabled, on an XEA1 configuration.
|
|
*
|
|
* On hardware with erratum "XEA1KWIN" (see <xtensa/core.h> for details),
|
|
* XEA1 code must have at least one instruction between ISYNC and RETW if
|
|
* run in kernel vector mode with interrupts and window overflows enabled.
|
|
*/
|
|
.macro isync_retw_nop
|
|
#if XCHAL_MAYHAVE_ERRATUM_XEA1KWIN
|
|
nop
|
|
#endif
|
|
.endm
|
|
|
|
/*----------------------------------------------------------------------
|
|
* isync_erratum453
|
|
*
|
|
* This macro must be invoked at certain points in the code,
|
|
* such as in exception and interrupt vectors in particular,
|
|
* to work around erratum 453.
|
|
*/
|
|
.macro isync_erratum453
|
|
#if XCHAL_ERRATUM_453
|
|
isync
|
|
#endif
|
|
.endm
|
|
|
|
|
|
|
|
/*----------------------------------------------------------------------
|
|
* abs
|
|
*
|
|
* implements abs on machines that do not have it configured
|
|
*/
|
|
|
|
#if !XCHAL_HAVE_ABS
|
|
.macro abs arr, ars
|
|
.ifc \arr, \ars
|
|
//src equal dest is less efficient
|
|
bgez \arr, 1f
|
|
neg \arr, \arr
|
|
1:
|
|
.else
|
|
neg \arr, \ars
|
|
movgez \arr, \ars, \ars
|
|
.endif
|
|
.endm
|
|
#endif /* !XCHAL_HAVE_ABS */
|
|
|
|
|
|
/*----------------------------------------------------------------------
|
|
* addx2
|
|
*
|
|
* implements addx2 on machines that do not have it configured
|
|
*
|
|
*/
|
|
|
|
#if !XCHAL_HAVE_ADDX
|
|
.macro addx2 arr, ars, art
|
|
.ifc \arr, \art
|
|
.ifc \arr, \ars
|
|
// addx2 a, a, a (not common)
|
|
.err
|
|
.else
|
|
add \arr, \ars, \art
|
|
add \arr, \ars, \art
|
|
.endif
|
|
.else
|
|
//addx2 a, b, c
|
|
//addx2 a, a, b
|
|
//addx2 a, b, b
|
|
slli \arr, \ars, 1
|
|
add \arr, \arr, \art
|
|
.endif
|
|
.endm
|
|
#endif /* !XCHAL_HAVE_ADDX */
|
|
|
|
/*----------------------------------------------------------------------
|
|
* addx4
|
|
*
|
|
* implements addx4 on machines that do not have it configured
|
|
*
|
|
*/
|
|
|
|
#if !XCHAL_HAVE_ADDX
|
|
.macro addx4 arr, ars, art
|
|
.ifc \arr, \art
|
|
.ifc \arr, \ars
|
|
// addx4 a, a, a (not common)
|
|
.err
|
|
.else
|
|
//# addx4 a, b, a
|
|
add \arr, \ars, \art
|
|
add \arr, \ars, \art
|
|
add \arr, \ars, \art
|
|
add \arr, \ars, \art
|
|
.endif
|
|
.else
|
|
//addx4 a, b, c
|
|
//addx4 a, a, b
|
|
//addx4 a, b, b
|
|
slli \arr, \ars, 2
|
|
add \arr, \arr, \art
|
|
.endif
|
|
.endm
|
|
#endif /* !XCHAL_HAVE_ADDX */
|
|
|
|
/*----------------------------------------------------------------------
|
|
* addx8
|
|
*
|
|
* implements addx8 on machines that do not have it configured
|
|
*
|
|
*/
|
|
|
|
#if !XCHAL_HAVE_ADDX
|
|
.macro addx8 arr, ars, art
|
|
.ifc \arr, \art
|
|
.ifc \arr, \ars
|
|
//addx8 a, a, a (not common)
|
|
.err
|
|
.else
|
|
//addx8 a, b, a
|
|
add \arr, \ars, \art
|
|
add \arr, \ars, \art
|
|
add \arr, \ars, \art
|
|
add \arr, \ars, \art
|
|
add \arr, \ars, \art
|
|
add \arr, \ars, \art
|
|
add \arr, \ars, \art
|
|
add \arr, \ars, \art
|
|
.endif
|
|
.else
|
|
//addx8 a, b, c
|
|
//addx8 a, a, b
|
|
//addx8 a, b, b
|
|
slli \arr, \ars, 3
|
|
add \arr, \arr, \art
|
|
.endif
|
|
.endm
|
|
#endif /* !XCHAL_HAVE_ADDX */
|
|
|
|
|
|
/*----------------------------------------------------------------------
|
|
* rfe_rfue
|
|
*
|
|
* Maps to RFUE on XEA1, and RFE on XEA2. No mapping on XEAX.
|
|
*/
|
|
|
|
#if XCHAL_HAVE_XEA1
|
|
.macro rfe_rfue
|
|
rfue
|
|
.endm
|
|
#elif XCHAL_HAVE_XEA2
|
|
.macro rfe_rfue
|
|
rfe
|
|
.endm
|
|
#endif
|
|
|
|
|
|
/*----------------------------------------------------------------------
|
|
* abi_entry
|
|
*
|
|
* Generate proper function entry sequence for the current ABI
|
|
* (windowed or call0). Takes care of allocating stack space (up to 1kB)
|
|
* and saving the return PC, if necessary. The corresponding abi_return
|
|
* macro does the corresponding stack deallocation and restoring return PC.
|
|
*
|
|
* Parameters are:
|
|
*
|
|
* locsize Number of bytes to allocate on the stack
|
|
* for local variables (and for args to pass to
|
|
* callees, if any calls are made). Defaults to zero.
|
|
* The macro rounds this up to a multiple of 16.
|
|
* NOTE: large values are allowed (e.g. up to 1 GB).
|
|
*
|
|
* callsize Maximum call size made by this function.
|
|
* Leave zero (default) for leaf functions, i.e. if
|
|
* this function makes no calls to other functions.
|
|
* Otherwise must be set to 4, 8, or 12 according
|
|
* to whether the "largest" call made is a call[x]4,
|
|
* call[x]8, or call[x]12 (for call0 ABI, it makes
|
|
* no difference whether this is set to 4, 8 or 12,
|
|
* but it must be set to one of these values).
|
|
*
|
|
* NOTE: It is up to the caller to align the entry point, declare the
|
|
* function symbol, make it global, etc.
|
|
*
|
|
* NOTE: This macro relies on assembler relaxation for large values
|
|
* of locsize. It might not work with the no-transform directive.
|
|
* NOTE: For the call0 ABI, this macro ensures SP is allocated or
|
|
* de-allocated cleanly, i.e. without temporarily allocating too much
|
|
* (or allocating negatively!) due to addi relaxation.
|
|
*
|
|
* NOTE: Generating the proper sequence and register allocation for
|
|
* making calls in an ABI independent manner is a separate topic not
|
|
* covered by this macro.
|
|
*
|
|
* NOTE: To access arguments, you can't use a fixed offset from SP.
|
|
* The offset depends on the ABI, whether the function is leaf, etc.
|
|
* The simplest method is probably to use the .locsz symbol, which
|
|
* is set by this macro to the actual number of bytes allocated on
|
|
* the stack, in other words, to the offset from SP to the arguments.
|
|
* E.g. for a function whose arguments are all 32-bit integers, you
|
|
* can get the 7th and 8th arguments (1st and 2nd args stored on stack)
|
|
* using:
|
|
* l32i a2, sp, .locsz
|
|
* l32i a3, sp, .locsz+4
|
|
* (this example works as long as locsize is under L32I's offset limit
|
|
* of 1020 minus up to 48 bytes of ABI-specific stack usage;
|
|
* otherwise you might first need to do "addi a?, sp, .locsz"
|
|
* or similar sequence).
|
|
*
|
|
* NOTE: For call0 ABI, this macro (and abi_return) may clobber a9
|
|
* (a caller-saved register).
|
|
*
|
|
* Examples:
|
|
* abi_entry
|
|
* abi_entry 5
|
|
* abi_entry 22, 8
|
|
* abi_entry 0, 4
|
|
*/
|
|
|
|
/*
|
|
* Compute .locsz and .callsz without emitting any instructions.
|
|
* Used by both abi_entry and abi_return.
|
|
* Assumes locsize >= 0.
|
|
*/
|
|
.macro abi_entry_size locsize=0, callsize=0
|
|
#if XCHAL_HAVE_WINDOWED && !__XTENSA_CALL0_ABI__
|
|
.ifeq \callsize
|
|
.set .callsz, 16
|
|
.else
|
|
.ifeq \callsize-4
|
|
.set .callsz, 16
|
|
.else
|
|
.ifeq \callsize-8
|
|
.set .callsz, 32
|
|
.else
|
|
.ifeq \callsize-12
|
|
.set .callsz, 48
|
|
.else
|
|
.error "abi_entry: invalid call size \callsize"
|
|
.endif
|
|
.endif
|
|
.endif
|
|
.endif
|
|
.set .locsz, .callsz + ((\locsize + 15) & -16)
|
|
#else
|
|
.set .callsz, \callsize
|
|
.if .callsz /* if calls, need space for return PC */
|
|
.set .locsz, (\locsize + 4 + 15) & -16
|
|
.else
|
|
.set .locsz, (\locsize + 15) & -16
|
|
.endif
|
|
#endif
|
|
.endm
|
|
|
|
.macro abi_entry locsize=0, callsize=0
|
|
.iflt \locsize
|
|
.error "abi_entry: invalid negative size of locals (\locsize)"
|
|
.endif
|
|
abi_entry_size \locsize, \callsize
|
|
#if XCHAL_HAVE_WINDOWED && !__XTENSA_CALL0_ABI__
|
|
.ifgt .locsz - 32760 /* .locsz > 32760 (ENTRY's max range)? */
|
|
/* Funky computation to try to have assembler use addmi efficiently if possible: */
|
|
entry sp, 0x7F00 + (.locsz & 0xF0)
|
|
addi a12, sp, - ((.locsz & -0x100) - 0x7F00)
|
|
movsp sp, a12
|
|
.else
|
|
entry sp, .locsz
|
|
.endif
|
|
#else
|
|
.if .locsz
|
|
.ifle .locsz - 128 /* if locsz <= 128 */
|
|
addi sp, sp, -.locsz
|
|
.if .callsz
|
|
s32i a0, sp, .locsz - 4
|
|
.endif
|
|
.elseif .callsz /* locsz > 128, with calls: */
|
|
movi a9, .locsz - 16 /* note: a9 is caller-saved */
|
|
addi sp, sp, -16
|
|
s32i a0, sp, 12
|
|
sub sp, sp, a9
|
|
.else /* locsz > 128, no calls: */
|
|
movi a9, .locsz
|
|
sub sp, sp, a9
|
|
.endif /* end */
|
|
.endif
|
|
#endif
|
|
.endm
|
|
|
|
|
|
|
|
/*----------------------------------------------------------------------
|
|
* abi_return
|
|
*
|
|
* Generate proper function exit sequence for the current ABI
|
|
* (windowed or call0). Takes care of freeing stack space and
|
|
* restoring the return PC, if necessary.
|
|
* NOTE: This macro MUST be invoked following a corresponding
|
|
* abi_entry macro invocation. For call0 ABI in particular,
|
|
* all stack and PC restoration are done according to the last
|
|
* abi_entry macro invoked before this macro in the assembly file.
|
|
*
|
|
* Normally this macro takes no arguments. However to allow
|
|
* for placing abi_return *before* abi_entry (as must be done
|
|
* for some highly optimized assembly), it optionally takes
|
|
* exactly the same arguments as abi_entry.
|
|
*/
|
|
|
|
.macro abi_return locsize=-1, callsize=0
|
|
.ifge \locsize
|
|
abi_entry_size \locsize, \callsize
|
|
.endif
|
|
#if XCHAL_HAVE_WINDOWED && !__XTENSA_CALL0_ABI__
|
|
retw
|
|
#else
|
|
.if .locsz
|
|
.iflt .locsz - 128 /* if locsz < 128 */
|
|
.if .callsz
|
|
l32i a0, sp, .locsz - 4
|
|
.endif
|
|
addi sp, sp, .locsz
|
|
.elseif .callsz /* locsz >= 128, with calls: */
|
|
addi a9, sp, .locsz - 16
|
|
l32i a0, a9, 12
|
|
addi sp, a9, 16
|
|
.else /* locsz >= 128, no calls: */
|
|
movi a9, .locsz
|
|
add sp, sp, a9
|
|
.endif /* end */
|
|
.endif
|
|
ret
|
|
#endif
|
|
.endm
|
|
|
|
|
|
/*
|
|
* HW erratum fixes.
|
|
*/
|
|
|
|
.macro hw_erratum_487_fix
|
|
#if defined XSHAL_ERRATUM_487_FIX
|
|
isync
|
|
#endif
|
|
.endm
|
|
|
|
|
|
#endif /*XTENSA_COREASM_H*/
|
|
|