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LeafOS / LeafOS-Project / android_art / dcfa89bfc06a6c211bbb64fa81313eaf6454ab67 / . / runtime / arch / mips / quick_entrypoints_mips.S
blob: b10d1fc849c4c762f5a53eaee75272b796e00801 [file] [log] [blame]
/*
* Copyright (C) 2012 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "asm_support_mips.S"
#include "arch/quick_alloc_entrypoints.S"
.set noreorder
.balign 4
/* Deliver the given exception */
.extern artDeliverExceptionFromCode
/* Deliver an exception pending on a thread */
.extern artDeliverPendingExceptionFromCode
#define ARG_SLOT_SIZE 32 // space for a0-a3 plus 4 more words
/*
* Macro that sets up the callee save frame to conform with
* Runtime::CreateCalleeSaveMethod(kSaveAllCalleeSaves)
* Callee-save: $s0-$s8 + $gp + $ra, 11 total + 1 word for Method*
* Clobbers $t0 and $sp
* Allocates ARG_SLOT_SIZE bytes at the bottom of the stack for arg slots.
* Reserves FRAME_SIZE_SAVE_ALL_CALLEE_SAVES + ARG_SLOT_SIZE bytes on the stack
*/
.macro SETUP_SAVE_ALL_CALLEE_SAVES_FRAME
addiu $sp, $sp, -112
.cfi_adjust_cfa_offset 112
// Ugly compile-time check, but we only have the preprocessor.
#if (FRAME_SIZE_SAVE_ALL_CALLEE_SAVES != 112)
#error "FRAME_SIZE_SAVE_ALL_CALLEE_SAVES(MIPS) size not as expected."
#endif
sw $ra, 108($sp)
.cfi_rel_offset 31, 108
sw $s8, 104($sp)
.cfi_rel_offset 30, 104
sw $gp, 100($sp)
.cfi_rel_offset 28, 100
sw $s7, 96($sp)
.cfi_rel_offset 23, 96
sw $s6, 92($sp)
.cfi_rel_offset 22, 92
sw $s5, 88($sp)
.cfi_rel_offset 21, 88
sw $s4, 84($sp)
.cfi_rel_offset 20, 84
sw $s3, 80($sp)
.cfi_rel_offset 19, 80
sw $s2, 76($sp)
.cfi_rel_offset 18, 76
sw $s1, 72($sp)
.cfi_rel_offset 17, 72
sw $s0, 68($sp)
.cfi_rel_offset 16, 68
// 4-byte placeholder for register $zero, serving for alignment
// of the following double precision floating point registers.
CHECK_ALIGNMENT $sp, $t1
sdc1 $f30, 56($sp)
sdc1 $f28, 48($sp)
sdc1 $f26, 40($sp)
sdc1 $f24, 32($sp)
sdc1 $f22, 24($sp)
sdc1 $f20, 16($sp)
# 1 word for holding Method* plus 12 bytes padding to keep contents of SP
# a multiple of 16.
lw $t0, %got(_ZN3art7Runtime9instance_E)($gp)
lw $t0, 0($t0)
lw $t0, RUNTIME_SAVE_ALL_CALLEE_SAVES_METHOD_OFFSET($t0)
sw $t0, 0($sp) # Place Method* at bottom of stack.
sw $sp, THREAD_TOP_QUICK_FRAME_OFFSET(rSELF) # Place sp in Thread::Current()->top_quick_frame.
addiu $sp, $sp, -ARG_SLOT_SIZE # reserve argument slots on the stack
.cfi_adjust_cfa_offset ARG_SLOT_SIZE
.endm
/*
* Macro that sets up the callee save frame to conform with
* Runtime::CreateCalleeSaveMethod(kSaveRefsOnly). Restoration assumes non-moving GC.
* Does not include rSUSPEND or rSELF
* callee-save: $s2-$s8 + $gp + $ra, 9 total + 2 words padding + 1 word to hold Method*
* Clobbers $t0 and $sp
* Allocates ARG_SLOT_SIZE bytes at the bottom of the stack for arg slots.
* Reserves FRAME_SIZE_SAVE_REFS_ONLY + ARG_SLOT_SIZE bytes on the stack
*/
.macro SETUP_SAVE_REFS_ONLY_FRAME
addiu $sp, $sp, -48
.cfi_adjust_cfa_offset 48
// Ugly compile-time check, but we only have the preprocessor.
#if (FRAME_SIZE_SAVE_REFS_ONLY != 48)
#error "FRAME_SIZE_SAVE_REFS_ONLY(MIPS) size not as expected."
#endif
sw $ra, 44($sp)
.cfi_rel_offset 31, 44
sw $s8, 40($sp)
.cfi_rel_offset 30, 40
sw $gp, 36($sp)
.cfi_rel_offset 28, 36
sw $s7, 32($sp)
.cfi_rel_offset 23, 32
sw $s6, 28($sp)
.cfi_rel_offset 22, 28
sw $s5, 24($sp)
.cfi_rel_offset 21, 24
sw $s4, 20($sp)
.cfi_rel_offset 20, 20
sw $s3, 16($sp)
.cfi_rel_offset 19, 16
sw $s2, 12($sp)
.cfi_rel_offset 18, 12
# 2 words for alignment and bottom word will hold Method*
lw $t0, %got(_ZN3art7Runtime9instance_E)($gp)
lw $t0, 0($t0)
lw $t0, RUNTIME_SAVE_REFS_ONLY_METHOD_OFFSET($t0)
sw $t0, 0($sp) # Place Method* at bottom of stack.
sw $sp, THREAD_TOP_QUICK_FRAME_OFFSET(rSELF) # Place sp in Thread::Current()->top_quick_frame.
addiu $sp, $sp, -ARG_SLOT_SIZE # reserve argument slots on the stack
.cfi_adjust_cfa_offset ARG_SLOT_SIZE
.endm
.macro RESTORE_SAVE_REFS_ONLY_FRAME
addiu $sp, $sp, ARG_SLOT_SIZE # remove argument slots on the stack
.cfi_adjust_cfa_offset -ARG_SLOT_SIZE
lw $ra, 44($sp)
.cfi_restore 31
lw $s8, 40($sp)
.cfi_restore 30
lw $gp, 36($sp)
.cfi_restore 28
lw $s7, 32($sp)
.cfi_restore 23
lw $s6, 28($sp)
.cfi_restore 22
lw $s5, 24($sp)
.cfi_restore 21
lw $s4, 20($sp)
.cfi_restore 20
lw $s3, 16($sp)
.cfi_restore 19
lw $s2, 12($sp)
.cfi_restore 18
addiu $sp, $sp, 48
.cfi_adjust_cfa_offset -48
.endm
.macro RESTORE_SAVE_REFS_ONLY_FRAME_AND_RETURN
RESTORE_SAVE_REFS_ONLY_FRAME
jalr $zero, $ra
nop
.endm
/*
* Individually usable part of macro SETUP_SAVE_REFS_AND_ARGS_FRAME_REGISTERS_ONLY.
*/
.macro SETUP_SAVE_REFS_AND_ARGS_FRAME_S4_THRU_S8
sw $s8, 104($sp)
.cfi_rel_offset 30, 104
sw $s7, 96($sp)
.cfi_rel_offset 23, 96
sw $s6, 92($sp)
.cfi_rel_offset 22, 92
sw $s5, 88($sp)
.cfi_rel_offset 21, 88
sw $s4, 84($sp)
.cfi_rel_offset 20, 84
.endm
/*
* Macro that sets up the callee save frame to conform with
* Runtime::CreateCalleeSaveMethod(kSaveRefsAndArgs).
* callee-save: $a1-$a3, $t0-$t1, $s2-$s8, $gp, $ra, $f8-$f19
* (26 total + 1 word padding + method*)
*/
.macro SETUP_SAVE_REFS_AND_ARGS_FRAME_REGISTERS_ONLY save_s4_thru_s8=1
addiu $sp, $sp, -112
.cfi_adjust_cfa_offset 112
// Ugly compile-time check, but we only have the preprocessor.
#if (FRAME_SIZE_SAVE_REFS_AND_ARGS != 112)
#error "FRAME_SIZE_SAVE_REFS_AND_ARGS(MIPS) size not as expected."
#endif
sw $ra, 108($sp)
.cfi_rel_offset 31, 108
sw $gp, 100($sp)
.cfi_rel_offset 28, 100
.if \save_s4_thru_s8
SETUP_SAVE_REFS_AND_ARGS_FRAME_S4_THRU_S8
.endif
sw $s3, 80($sp)
.cfi_rel_offset 19, 80
sw $s2, 76($sp)
.cfi_rel_offset 18, 76
sw $t1, 72($sp)
.cfi_rel_offset 9, 72
sw $t0, 68($sp)
.cfi_rel_offset 8, 68
sw $a3, 64($sp)
.cfi_rel_offset 7, 64
sw $a2, 60($sp)
.cfi_rel_offset 6, 60
sw $a1, 56($sp)
.cfi_rel_offset 5, 56
CHECK_ALIGNMENT $sp, $t8
sdc1 $f18, 48($sp)
sdc1 $f16, 40($sp)
sdc1 $f14, 32($sp)
sdc1 $f12, 24($sp)
sdc1 $f10, 16($sp)
sdc1 $f8, 8($sp)
# bottom will hold Method*
.endm
/*
* Macro that sets up the callee save frame to conform with
* Runtime::CreateCalleeSaveMethod(kSaveRefsAndArgs). Restoration assumes non-moving GC.
* callee-save: $a1-$a3, $t0-$t1, $s2-$s8, $gp, $ra, $f8-$f19
* (26 total + 1 word padding + method*)
* Clobbers $t0 and $sp
* Allocates ARG_SLOT_SIZE bytes at the bottom of the stack for arg slots.
* Reserves FRAME_SIZE_SAVE_REFS_AND_ARGS + ARG_SLOT_SIZE bytes on the stack
*/
.macro SETUP_SAVE_REFS_AND_ARGS_FRAME save_s4_thru_s8_only=0
.if \save_s4_thru_s8_only
// It is expected that `SETUP_SAVE_REFS_AND_ARGS_FRAME_REGISTERS_ONLY /* save_s4_thru_s8 */ 0`
// has been done prior to `SETUP_SAVE_REFS_AND_ARGS_FRAME /* save_s4_thru_s8_only */ 1`.
SETUP_SAVE_REFS_AND_ARGS_FRAME_S4_THRU_S8
.else
SETUP_SAVE_REFS_AND_ARGS_FRAME_REGISTERS_ONLY
.endif
lw $t0, %got(_ZN3art7Runtime9instance_E)($gp)
lw $t0, 0($t0)
lw $t0, RUNTIME_SAVE_REFS_AND_ARGS_METHOD_OFFSET($t0)
sw $t0, 0($sp) # Place Method* at bottom of stack.
sw $sp, THREAD_TOP_QUICK_FRAME_OFFSET(rSELF) # Place sp in Thread::Current()->top_quick_frame.
addiu $sp, $sp, -ARG_SLOT_SIZE # reserve argument slots on the stack
.cfi_adjust_cfa_offset ARG_SLOT_SIZE
.endm
/*
* Macro that sets up the callee save frame to conform with
* Runtime::CreateCalleeSaveMethod(kSaveRefsAndArgs). Restoration assumes non-moving GC.
* callee-save: $a1-$a3, $t0-$t1, $s2-$s8, $gp, $ra, $f8-$f19
* (26 total + 1 word padding + method*)
* Clobbers $sp
* Use $a0 as the Method* and loads it into bottom of stack.
* Allocates ARG_SLOT_SIZE bytes at the bottom of the stack for arg slots.
* Reserves FRAME_SIZE_SAVE_REFS_AND_ARGS + ARG_SLOT_SIZE bytes on the stack
*/
.macro SETUP_SAVE_REFS_AND_ARGS_FRAME_WITH_METHOD_IN_A0
SETUP_SAVE_REFS_AND_ARGS_FRAME_REGISTERS_ONLY
sw $a0, 0($sp) # Place Method* at bottom of stack.
sw $sp, THREAD_TOP_QUICK_FRAME_OFFSET(rSELF) # Place sp in Thread::Current()->top_quick_frame.
addiu $sp, $sp, -ARG_SLOT_SIZE # reserve argument slots on the stack
.cfi_adjust_cfa_offset ARG_SLOT_SIZE
.endm
/*
* Individually usable part of macro RESTORE_SAVE_REFS_AND_ARGS_FRAME.
*/
.macro RESTORE_SAVE_REFS_AND_ARGS_FRAME_GP
lw $gp, 100($sp)
.cfi_restore 28
.endm
/*
* Individually usable part of macro RESTORE_SAVE_REFS_AND_ARGS_FRAME.
*/
.macro RESTORE_SAVE_REFS_AND_ARGS_FRAME_A1
lw $a1, 56($sp)
.cfi_restore 5
.endm
.macro RESTORE_SAVE_REFS_AND_ARGS_FRAME restore_s4_thru_s8=1, remove_arg_slots=1
.if \remove_arg_slots
addiu $sp, $sp, ARG_SLOT_SIZE # Remove argument slots from the stack.
.cfi_adjust_cfa_offset -ARG_SLOT_SIZE
.endif
lw $ra, 108($sp)
.cfi_restore 31
.if \restore_s4_thru_s8
lw $s8, 104($sp)
.cfi_restore 30
.endif
RESTORE_SAVE_REFS_AND_ARGS_FRAME_GP
.if \restore_s4_thru_s8
lw $s7, 96($sp)
.cfi_restore 23
lw $s6, 92($sp)
.cfi_restore 22
lw $s5, 88($sp)
.cfi_restore 21
lw $s4, 84($sp)
.cfi_restore 20
.endif
lw $s3, 80($sp)
.cfi_restore 19
lw $s2, 76($sp)
.cfi_restore 18
lw $t1, 72($sp)
.cfi_restore 9
lw $t0, 68($sp)
.cfi_restore 8
lw $a3, 64($sp)
.cfi_restore 7
lw $a2, 60($sp)
.cfi_restore 6
RESTORE_SAVE_REFS_AND_ARGS_FRAME_A1
CHECK_ALIGNMENT $sp, $t8
ldc1 $f18, 48($sp)
ldc1 $f16, 40($sp)
ldc1 $f14, 32($sp)
ldc1 $f12, 24($sp)
ldc1 $f10, 16($sp)
ldc1 $f8, 8($sp)
addiu $sp, $sp, 112 # Pop frame.
.cfi_adjust_cfa_offset -112
.endm
/*
* Macro that sets up the callee save frame to conform with
* Runtime::CreateCalleeSaveMethod(kSaveEverything).
* when the $sp has already been decremented by FRAME_SIZE_SAVE_EVERYTHING.
* Callee-save: $at, $v0-$v1, $a0-$a3, $t0-$t7, $s0-$s7, $t8-$t9, $gp, $fp $ra, $f0-$f31;
* 28(GPR)+ 32(FPR) + 3 words for padding and 1 word for Method*
* Clobbers $t0 and $t1.
* Allocates ARG_SLOT_SIZE bytes at the bottom of the stack for arg slots.
* Reserves FRAME_SIZE_SAVE_EVERYTHING + ARG_SLOT_SIZE bytes on the stack.
* This macro sets up $gp; entrypoints using it should start with ENTRY_NO_GP.
*/
.macro SETUP_SAVE_EVERYTHING_FRAME_DECREMENTED_SP runtime_method_offset = RUNTIME_SAVE_EVERYTHING_METHOD_OFFSET
// Ugly compile-time check, but we only have the preprocessor.
#if (FRAME_SIZE_SAVE_EVERYTHING != 256)
#error "FRAME_SIZE_SAVE_EVERYTHING(MIPS) size not as expected."
#endif
sw $ra, 252($sp)
.cfi_rel_offset 31, 252
sw $fp, 248($sp)
.cfi_rel_offset 30, 248
sw $gp, 244($sp)
.cfi_rel_offset 28, 244
sw $t9, 240($sp)
.cfi_rel_offset 25, 240
sw $t8, 236($sp)
.cfi_rel_offset 24, 236
sw $s7, 232($sp)
.cfi_rel_offset 23, 232
sw $s6, 228($sp)
.cfi_rel_offset 22, 228
sw $s5, 224($sp)
.cfi_rel_offset 21, 224
sw $s4, 220($sp)
.cfi_rel_offset 20, 220
sw $s3, 216($sp)
.cfi_rel_offset 19, 216
sw $s2, 212($sp)
.cfi_rel_offset 18, 212
sw $s1, 208($sp)
.cfi_rel_offset 17, 208
sw $s0, 204($sp)
.cfi_rel_offset 16, 204
sw $t7, 200($sp)
.cfi_rel_offset 15, 200
sw $t6, 196($sp)
.cfi_rel_offset 14, 196
sw $t5, 192($sp)
.cfi_rel_offset 13, 192
sw $t4, 188($sp)
.cfi_rel_offset 12, 188
sw $t3, 184($sp)
.cfi_rel_offset 11, 184
sw $t2, 180($sp)
.cfi_rel_offset 10, 180
sw $t1, 176($sp)
.cfi_rel_offset 9, 176
sw $t0, 172($sp)
.cfi_rel_offset 8, 172
sw $a3, 168($sp)
.cfi_rel_offset 7, 168
sw $a2, 164($sp)
.cfi_rel_offset 6, 164
sw $a1, 160($sp)
.cfi_rel_offset 5, 160
sw $a0, 156($sp)
.cfi_rel_offset 4, 156
sw $v1, 152($sp)
.cfi_rel_offset 3, 152
sw $v0, 148($sp)
.cfi_rel_offset 2, 148
// Set up $gp, clobbering $ra and using the branch delay slot for a useful instruction.
bal 1f
.set push
.set noat
sw $at, 144($sp)
.cfi_rel_offset 1, 144
.set pop
1:
.cpload $ra
CHECK_ALIGNMENT $sp, $t1
sdc1 $f30, 136($sp)
sdc1 $f28, 128($sp)
sdc1 $f26, 120($sp)
sdc1 $f24, 112($sp)
sdc1 $f22, 104($sp)
sdc1 $f20, 96($sp)
sdc1 $f18, 88($sp)
sdc1 $f16, 80($sp)
sdc1 $f14, 72($sp)
sdc1 $f12, 64($sp)
sdc1 $f10, 56($sp)
sdc1 $f8, 48($sp)
sdc1 $f6, 40($sp)
sdc1 $f4, 32($sp)
sdc1 $f2, 24($sp)
sdc1 $f0, 16($sp)
# 3 words padding and 1 word for holding Method*
lw $t0, %got(_ZN3art7Runtime9instance_E)($gp)
lw $t0, 0($t0)
lw $t0, \runtime_method_offset($t0)
sw $t0, 0($sp) # Place Method* at bottom of stack.
sw $sp, THREAD_TOP_QUICK_FRAME_OFFSET(rSELF) # Place sp in Thread::Current()->top_quick_frame.
addiu $sp, $sp, -ARG_SLOT_SIZE # reserve argument slots on the stack
.cfi_adjust_cfa_offset ARG_SLOT_SIZE
.endm
/*
* Macro that sets up the callee save frame to conform with
* Runtime::CreateCalleeSaveMethod(kSaveEverything).
* Callee-save: $at, $v0-$v1, $a0-$a3, $t0-$t7, $s0-$s7, $t8-$t9, $gp, $fp $ra, $f0-$f31;
* 28(GPR)+ 32(FPR) + 3 words for padding and 1 word for Method*
* Clobbers $t0 and $t1.
* Allocates ARG_SLOT_SIZE bytes at the bottom of the stack for arg slots.
* Reserves FRAME_SIZE_SAVE_EVERYTHING + ARG_SLOT_SIZE bytes on the stack.
* This macro sets up $gp; entrypoints using it should start with ENTRY_NO_GP.
*/
.macro SETUP_SAVE_EVERYTHING_FRAME runtime_method_offset = RUNTIME_SAVE_EVERYTHING_METHOD_OFFSET
addiu $sp, $sp, -(FRAME_SIZE_SAVE_EVERYTHING)
.cfi_adjust_cfa_offset (FRAME_SIZE_SAVE_EVERYTHING)
SETUP_SAVE_EVERYTHING_FRAME_DECREMENTED_SP \runtime_method_offset
.endm
.macro RESTORE_SAVE_EVERYTHING_FRAME restore_a0=1
addiu $sp, $sp, ARG_SLOT_SIZE # remove argument slots on the stack
.cfi_adjust_cfa_offset -ARG_SLOT_SIZE
CHECK_ALIGNMENT $sp, $t1
ldc1 $f30, 136($sp)
ldc1 $f28, 128($sp)
ldc1 $f26, 120($sp)
ldc1 $f24, 112($sp)
ldc1 $f22, 104($sp)
ldc1 $f20, 96($sp)
ldc1 $f18, 88($sp)
ldc1 $f16, 80($sp)
ldc1 $f14, 72($sp)
ldc1 $f12, 64($sp)
ldc1 $f10, 56($sp)
ldc1 $f8, 48($sp)
ldc1 $f6, 40($sp)
ldc1 $f4, 32($sp)
ldc1 $f2, 24($sp)
ldc1 $f0, 16($sp)
lw $ra, 252($sp)
.cfi_restore 31
lw $fp, 248($sp)
.cfi_restore 30
lw $gp, 244($sp)
.cfi_restore 28
lw $t9, 240($sp)
.cfi_restore 25
lw $t8, 236($sp)
.cfi_restore 24
lw $s7, 232($sp)
.cfi_restore 23
lw $s6, 228($sp)
.cfi_restore 22
lw $s5, 224($sp)
.cfi_restore 21
lw $s4, 220($sp)
.cfi_restore 20
lw $s3, 216($sp)
.cfi_restore 19
lw $s2, 212($sp)
.cfi_restore 18
lw $s1, 208($sp)
.cfi_restore 17
lw $s0, 204($sp)
.cfi_restore 16
lw $t7, 200($sp)
.cfi_restore 15
lw $t6, 196($sp)
.cfi_restore 14
lw $t5, 192($sp)
.cfi_restore 13
lw $t4, 188($sp)
.cfi_restore 12
lw $t3, 184($sp)
.cfi_restore 11
lw $t2, 180($sp)
.cfi_restore 10
lw $t1, 176($sp)
.cfi_restore 9
lw $t0, 172($sp)
.cfi_restore 8
lw $a3, 168($sp)
.cfi_restore 7
lw $a2, 164($sp)
.cfi_restore 6
lw $a1, 160($sp)
.cfi_restore 5
.if \restore_a0
lw $a0, 156($sp)
.cfi_restore 4
.endif
lw $v1, 152($sp)
.cfi_restore 3
lw $v0, 148($sp)
.cfi_restore 2
.set push
.set noat
lw $at, 144($sp)
.cfi_restore 1
.set pop
addiu $sp, $sp, 256 # pop frame
.cfi_adjust_cfa_offset -256
.endm
/*
* Macro that calls through to artDeliverPendingExceptionFromCode, where the pending
* exception is Thread::Current()->exception_ when the runtime method frame is ready.
* Requires $gp properly set up.
*/
.macro DELIVER_PENDING_EXCEPTION_FRAME_READY
la $t9, artDeliverPendingExceptionFromCode
jalr $zero, $t9 # artDeliverPendingExceptionFromCode(Thread*)
move $a0, rSELF # pass Thread::Current
.endm
/*
* Macro that calls through to artDeliverPendingExceptionFromCode, where the pending
* exception is Thread::Current()->exception_.
* Requires $gp properly set up.
*/
.macro DELIVER_PENDING_EXCEPTION
SETUP_SAVE_ALL_CALLEE_SAVES_FRAME # save callee saves for throw
DELIVER_PENDING_EXCEPTION_FRAME_READY
.endm
.macro RETURN_IF_NO_EXCEPTION
lw $t0, THREAD_EXCEPTION_OFFSET(rSELF) # load Thread::Current()->exception_
RESTORE_SAVE_REFS_ONLY_FRAME
bnez $t0, 1f # success if no exception is pending
nop
jalr $zero, $ra
nop
1:
DELIVER_PENDING_EXCEPTION
.endm
.macro RETURN_IF_ZERO
RESTORE_SAVE_REFS_ONLY_FRAME
bnez $v0, 1f # success?
nop
jalr $zero, $ra # return on success
nop
1:
DELIVER_PENDING_EXCEPTION
.endm
.macro RETURN_IF_RESULT_IS_NON_ZERO_OR_DELIVER
RESTORE_SAVE_REFS_ONLY_FRAME
beqz $v0, 1f # success?
nop
jalr $zero, $ra # return on success
nop
1:
DELIVER_PENDING_EXCEPTION
.endm
/*
* On stack replacement stub.
* On entry:
* a0 = stack to copy
* a1 = size of stack
* a2 = pc to call
* a3 = JValue* result
* [sp + 16] = shorty
* [sp + 20] = thread
*/
ENTRY art_quick_osr_stub
// Save callee general purpose registers, RA and GP.
addiu $sp, $sp, -48
.cfi_adjust_cfa_offset 48
sw $ra, 44($sp)
.cfi_rel_offset 31, 44
sw $s8, 40($sp)
.cfi_rel_offset 30, 40
sw $gp, 36($sp)
.cfi_rel_offset 28, 36
sw $s7, 32($sp)
.cfi_rel_offset 23, 32
sw $s6, 28($sp)
.cfi_rel_offset 22, 28
sw $s5, 24($sp)
.cfi_rel_offset 21, 24
sw $s4, 20($sp)
.cfi_rel_offset 20, 20
sw $s3, 16($sp)
.cfi_rel_offset 19, 16
sw $s2, 12($sp)
.cfi_rel_offset 18, 12
sw $s1, 8($sp)
.cfi_rel_offset 17, 8
sw $s0, 4($sp)
.cfi_rel_offset 16, 4
move $s8, $sp # Save the stack pointer
move $s7, $a1 # Save size of stack
move $s6, $a2 # Save the pc to call
lw rSELF, 48+20($sp) # Save managed thread pointer into rSELF
addiu $t0, $sp, -12 # Reserve space for stack pointer,
# JValue* result, and ArtMethod* slot.
srl $t0, $t0, 4 # Align stack pointer to 16 bytes
sll $sp, $t0, 4 # Update stack pointer
sw $s8, 4($sp) # Save old stack pointer
sw $a3, 8($sp) # Save JValue* result
sw $zero, 0($sp) # Store null for ArtMethod* at bottom of frame
subu $sp, $a1 # Reserve space for callee stack
move $a2, $a1
move $a1, $a0
move $a0, $sp
la $t9, memcpy
jalr $t9 # memcpy (dest a0, src a1, bytes a2)
addiu $sp, $sp, -16 # make space for argument slots for memcpy
bal .Losr_entry # Call the method
addiu $sp, $sp, 16 # restore stack after memcpy
lw $a2, 8($sp) # Restore JValue* result
lw $sp, 4($sp) # Restore saved stack pointer
lw $a0, 48+16($sp) # load shorty
lbu $a0, 0($a0) # load return type
li $a1, 'D' # put char 'D' into a1
beq $a0, $a1, .Losr_fp_result # Test if result type char == 'D'
li $a1, 'F' # put char 'F' into a1
beq $a0, $a1, .Losr_fp_result # Test if result type char == 'F'
nop
sw $v0, 0($a2)
b .Losr_exit
sw $v1, 4($a2) # store v0/v1 into result
.Losr_fp_result:
CHECK_ALIGNMENT $a2, $t0, 8
sdc1 $f0, 0($a2) # store f0/f1 into result
.Losr_exit:
lw $ra, 44($sp)
.cfi_restore 31
lw $s8, 40($sp)
.cfi_restore 30
lw $gp, 36($sp)
.cfi_restore 28
lw $s7, 32($sp)
.cfi_restore 23
lw $s6, 28($sp)
.cfi_restore 22
lw $s5, 24($sp)
.cfi_restore 21
lw $s4, 20($sp)
.cfi_restore 20
lw $s3, 16($sp)
.cfi_restore 19
lw $s2, 12($sp)
.cfi_restore 18
lw $s1, 8($sp)
.cfi_restore 17
lw $s0, 4($sp)
.cfi_restore 16
jalr $zero, $ra
addiu $sp, $sp, 48
.cfi_adjust_cfa_offset -48
.Losr_entry:
addiu $s7, $s7, -4
addu $t0, $s7, $sp
move $t9, $s6
jalr $zero, $t9
sw $ra, 0($t0) # Store RA per the compiler ABI
END art_quick_osr_stub
/*
* On entry $a0 is uint32_t* gprs_ and $a1 is uint32_t* fprs_.
* Note that fprs_ is expected to be an address that is a multiple of 8.
* FIXME: just guessing about the shape of the jmpbuf. Where will pc be?
*/
ENTRY art_quick_do_long_jump
CHECK_ALIGNMENT $a1, $t1, 8
ldc1 $f0, 0*8($a1)
ldc1 $f2, 1*8($a1)
ldc1 $f4, 2*8($a1)
ldc1 $f6, 3*8($a1)
ldc1 $f8, 4*8($a1)
ldc1 $f10, 5*8($a1)
ldc1 $f12, 6*8($a1)
ldc1 $f14, 7*8($a1)
ldc1 $f16, 8*8($a1)
ldc1 $f18, 9*8($a1)
ldc1 $f20, 10*8($a1)
ldc1 $f22, 11*8($a1)
ldc1 $f24, 12*8($a1)
ldc1 $f26, 13*8($a1)
ldc1 $f28, 14*8($a1)
ldc1 $f30, 15*8($a1)
.set push
.set nomacro
.set noat
lw $at, 4($a0)
.set pop
lw $v0, 8($a0)
lw $v1, 12($a0)
lw $a1, 20($a0)
lw $a2, 24($a0)
lw $a3, 28($a0)
lw $t0, 32($a0)
lw $t1, 36($a0)
lw $t2, 40($a0)
lw $t3, 44($a0)
lw $t4, 48($a0)
lw $t5, 52($a0)
lw $t6, 56($a0)
lw $t7, 60($a0)
lw $s0, 64($a0)
lw $s1, 68($a0)
lw $s2, 72($a0)
lw $s3, 76($a0)
lw $s4, 80($a0)
lw $s5, 84($a0)
lw $s6, 88($a0)
lw $s7, 92($a0)
lw $t8, 96($a0)
lw $t9, 100($a0)
lw $gp, 112($a0)
lw $sp, 116($a0)
lw $fp, 120($a0)
lw $ra, 124($a0)
lw $a0, 16($a0)
move $v0, $zero # clear result registers v0 and v1 (in branch delay slot)
jalr $zero, $t9 # do long jump
move $v1, $zero
END art_quick_do_long_jump
/*
* Called by managed code, saves most registers (forms basis of long jump context) and passes
* the bottom of the stack. artDeliverExceptionFromCode will place the callee save Method* at
* the bottom of the thread. On entry a0 holds Throwable*
*/
ENTRY art_quick_deliver_exception
SETUP_SAVE_ALL_CALLEE_SAVES_FRAME
la $t9, artDeliverExceptionFromCode
jalr $zero, $t9 # artDeliverExceptionFromCode(Throwable*, Thread*)
move $a1, rSELF # pass Thread::Current
END art_quick_deliver_exception
/*
* Called by managed code to create and deliver a NullPointerException
*/
.extern artThrowNullPointerExceptionFromCode
ENTRY_NO_GP art_quick_throw_null_pointer_exception
// Note that setting up $gp does not rely on $t9 here, so branching here directly is OK,
// even after clobbering any registers we don't need to preserve, such as $gp or $t0.
SETUP_SAVE_EVERYTHING_FRAME
la $t9, artThrowNullPointerExceptionFromCode
jalr $zero, $t9 # artThrowNullPointerExceptionFromCode(Thread*)
move $a0, rSELF # pass Thread::Current
END art_quick_throw_null_pointer_exception
/*
* Call installed by a signal handler to create and deliver a NullPointerException.
*/
.extern artThrowNullPointerExceptionFromSignal
ENTRY_NO_GP_CUSTOM_CFA art_quick_throw_null_pointer_exception_from_signal, FRAME_SIZE_SAVE_EVERYTHING
SETUP_SAVE_EVERYTHING_FRAME_DECREMENTED_SP
# Retrieve the fault address from the padding where the signal handler stores it.
lw $a0, (ARG_SLOT_SIZE + __SIZEOF_POINTER__)($sp)
la $t9, artThrowNullPointerExceptionFromSignal
jalr $zero, $t9 # artThrowNullPointerExceptionFromSignal(uintptr_t, Thread*)
move $a1, rSELF # pass Thread::Current
END art_quick_throw_null_pointer_exception_from_signal
/*
* Called by managed code to create and deliver an ArithmeticException
*/
.extern artThrowDivZeroFromCode
ENTRY_NO_GP art_quick_throw_div_zero
SETUP_SAVE_EVERYTHING_FRAME
la $t9, artThrowDivZeroFromCode
jalr $zero, $t9 # artThrowDivZeroFromCode(Thread*)
move $a0, rSELF # pass Thread::Current
END art_quick_throw_div_zero
/*
* Called by managed code to create and deliver an ArrayIndexOutOfBoundsException
*/
.extern artThrowArrayBoundsFromCode
ENTRY_NO_GP art_quick_throw_array_bounds
// Note that setting up $gp does not rely on $t9 here, so branching here directly is OK,
// even after clobbering any registers we don't need to preserve, such as $gp or $t0.
SETUP_SAVE_EVERYTHING_FRAME
la $t9, artThrowArrayBoundsFromCode
jalr $zero, $t9 # artThrowArrayBoundsFromCode(index, limit, Thread*)
move $a2, rSELF # pass Thread::Current
END art_quick_throw_array_bounds
/*
* Called by managed code to create and deliver a StringIndexOutOfBoundsException
* as if thrown from a call to String.charAt().
*/
.extern artThrowStringBoundsFromCode
ENTRY_NO_GP art_quick_throw_string_bounds
SETUP_SAVE_EVERYTHING_FRAME
la $t9, artThrowStringBoundsFromCode
jalr $zero, $t9 # artThrowStringBoundsFromCode(index, limit, Thread*)
move $a2, rSELF # pass Thread::Current
END art_quick_throw_string_bounds
/*
* Called by managed code to create and deliver a StackOverflowError.
*/
.extern artThrowStackOverflowFromCode
ENTRY art_quick_throw_stack_overflow
SETUP_SAVE_ALL_CALLEE_SAVES_FRAME
la $t9, artThrowStackOverflowFromCode
jalr $zero, $t9 # artThrowStackOverflowFromCode(Thread*)
move $a0, rSELF # pass Thread::Current
END art_quick_throw_stack_overflow
/*
* All generated callsites for interface invokes and invocation slow paths will load arguments
* as usual - except instead of loading arg0/$a0 with the target Method*, arg0/$a0 will contain
* the method_idx. This wrapper will save arg1-arg3, and call the appropriate C helper.
* NOTE: "this" is first visable argument of the target, and so can be found in arg1/$a1.
*
* The helper will attempt to locate the target and return a 64-bit result in $v0/$v1 consisting
* of the target Method* in $v0 and method->code_ in $v1.
*
* If unsuccessful, the helper will return null/null. There will be a pending exception in the
* thread and we branch to another stub to deliver it.
*
* On success this wrapper will restore arguments and *jump* to the target, leaving the lr
* pointing back to the original caller.
*/
.macro INVOKE_TRAMPOLINE_BODY cxx_name, save_s4_thru_s8_only=0
.extern \cxx_name
SETUP_SAVE_REFS_AND_ARGS_FRAME \save_s4_thru_s8_only # save callee saves in case
# allocation triggers GC
move $a2, rSELF # pass Thread::Current
la $t9, \cxx_name
jalr $t9 # (method_idx, this, Thread*, $sp)
addiu $a3, $sp, ARG_SLOT_SIZE # pass $sp (remove arg slots)
move $a0, $v0 # save target Method*
RESTORE_SAVE_REFS_AND_ARGS_FRAME
beqz $v0, 1f
move $t9, $v1 # save $v0->code_
jalr $zero, $t9
nop
1:
DELIVER_PENDING_EXCEPTION
.endm
.macro INVOKE_TRAMPOLINE c_name, cxx_name
ENTRY \c_name
INVOKE_TRAMPOLINE_BODY \cxx_name
END \c_name
.endm
INVOKE_TRAMPOLINE art_quick_invoke_interface_trampoline_with_access_check, artInvokeInterfaceTrampolineWithAccessCheck
INVOKE_TRAMPOLINE art_quick_invoke_static_trampoline_with_access_check, artInvokeStaticTrampolineWithAccessCheck
INVOKE_TRAMPOLINE art_quick_invoke_direct_trampoline_with_access_check, artInvokeDirectTrampolineWithAccessCheck
INVOKE_TRAMPOLINE art_quick_invoke_super_trampoline_with_access_check, artInvokeSuperTrampolineWithAccessCheck
INVOKE_TRAMPOLINE art_quick_invoke_virtual_trampoline_with_access_check, artInvokeVirtualTrampolineWithAccessCheck
// Each of the following macros expands into four instructions or 16 bytes.
// They are used to build indexable "tables" of code.
.macro LOAD_WORD_TO_REG reg, next_arg, index_reg, label
lw $\reg, -4($\next_arg) # next_arg points to argument after the current one (offset is 4)
b \label
addiu $\index_reg, 16
.balign 16
.endm
.macro LOAD_LONG_TO_REG reg1, reg2, next_arg, index_reg, next_index, label
lw $\reg1, -8($\next_arg) # next_arg points to argument after the current one (offset is 8)
lw $\reg2, -4($\next_arg)
b \label
li $\index_reg, \next_index
.balign 16
.endm
.macro LOAD_FLOAT_TO_REG reg, next_arg, index_reg, label
lwc1 $\reg, -4($\next_arg) # next_arg points to argument after the current one (offset is 4)
b \label
addiu $\index_reg, 16
.balign 16
.endm
#if defined(__mips_isa_rev) && __mips_isa_rev > 2
// LDu expands into 3 instructions for 64-bit FPU, so index_reg cannot be updated here.
.macro LOAD_DOUBLE_TO_REG reg1, reg2, next_arg, index_reg, tmp, label
.set reorder # force use of the branch delay slot
LDu $\reg1, $\reg2, -8, $\next_arg, $\tmp # next_arg points to argument after the current one
# (offset is 8)
b \label
.set noreorder
.balign 16
.endm
#else
// LDu expands into 2 instructions for 32-bit FPU, so index_reg is updated here.
.macro LOAD_DOUBLE_TO_REG reg1, reg2, next_arg, index_reg, tmp, label
LDu $\reg1, $\reg2, -8, $\next_arg, $\tmp # next_arg points to argument after the current one
# (offset is 8)
b \label
addiu $\index_reg, 16
.balign 16
.endm
#endif
.macro LOAD_END index_reg, next_index, label
b \label
li $\index_reg, \next_index
.balign 16
.endm
#define SPILL_SIZE 32
/*
* Invocation stub for quick code.
* On entry:
* a0 = method pointer
* a1 = argument array or null for no argument methods
* a2 = size of argument array in bytes
* a3 = (managed) thread pointer
* [sp + 16] = JValue* result
* [sp + 20] = shorty
*/
ENTRY art_quick_invoke_stub
sw $a0, 0($sp) # save out a0
addiu $sp, $sp, -SPILL_SIZE # spill s0, s1, fp, ra and gp
.cfi_adjust_cfa_offset SPILL_SIZE
sw $gp, 16($sp)
sw $ra, 12($sp)
.cfi_rel_offset 31, 12
sw $fp, 8($sp)
.cfi_rel_offset 30, 8
sw $s1, 4($sp)
.cfi_rel_offset 17, 4
sw $s0, 0($sp)
.cfi_rel_offset 16, 0
move $fp, $sp # save sp in fp
.cfi_def_cfa_register 30
move $s1, $a3 # move managed thread pointer into s1
addiu $t0, $a2, 4 # create space for ArtMethod* in frame.
subu $t0, $sp, $t0 # reserve & align *stack* to 16 bytes:
srl $t0, $t0, 4 # native calling convention only aligns to 8B,
sll $sp, $t0, 4 # so we have to ensure ART 16B alignment ourselves.
addiu $a0, $sp, 4 # pass stack pointer + ArtMethod* as dest for memcpy
la $t9, memcpy
jalr $t9 # (dest, src, bytes)
addiu $sp, $sp, -16 # make space for argument slots for memcpy
addiu $sp, $sp, 16 # restore stack after memcpy
lw $gp, 16($fp) # restore $gp
lw $a0, SPILL_SIZE($fp) # restore ArtMethod*
lw $a1, 4($sp) # a1 = this*
addiu $t8, $sp, 8 # t8 = pointer to the current argument (skip ArtMethod* and this*)
li $t6, 0 # t6 = gpr_index = 0 (corresponds to A2; A0 and A1 are skipped)
li $t7, 0 # t7 = fp_index = 0
lw $t9, 20 + SPILL_SIZE($fp) # get shorty (20 is offset from the $sp on entry + SPILL_SIZE
# as the $fp is SPILL_SIZE bytes below the $sp on entry)
addiu $t9, 1 # t9 = shorty + 1 (skip 1 for return type)
// Load the base addresses of tabInt ... tabDouble.
// We will use the register indices (gpr_index, fp_index) to branch.
// Note that the indices are scaled by 16, so they can be added to the bases directly.
#if defined(__mips_isa_rev) && __mips_isa_rev >= 6
lapc $t2, tabInt
lapc $t3, tabLong
lapc $t4, tabSingle
lapc $t5, tabDouble
#else
bltzal $zero, tabBase # nal
addiu $t2, $ra, %lo(tabInt - tabBase)
tabBase:
addiu $t3, $ra, %lo(tabLong - tabBase)
addiu $t4, $ra, %lo(tabSingle - tabBase)
addiu $t5, $ra, %lo(tabDouble - tabBase)
#endif
loop:
lbu $ra, 0($t9) # ra = shorty[i]
beqz $ra, loopEnd # finish getting args when shorty[i] == '\0'
addiu $t9, 1
addiu $ra, -'J'
beqz $ra, isLong # branch if result type char == 'J'
addiu $ra, 'J' - 'D'
beqz $ra, isDouble # branch if result type char == 'D'
addiu $ra, 'D' - 'F'
beqz $ra, isSingle # branch if result type char == 'F'
addu $ra, $t2, $t6
jalr $zero, $ra
addiu $t8, 4 # next_arg = curr_arg + 4
isLong:
addu $ra, $t3, $t6
jalr $zero, $ra
addiu $t8, 8 # next_arg = curr_arg + 8
isSingle:
addu $ra, $t4, $t7
jalr $zero, $ra
addiu $t8, 4 # next_arg = curr_arg + 4
isDouble:
addu $ra, $t5, $t7
#if defined(__mips_isa_rev) && __mips_isa_rev > 2
addiu $t7, 16 # fp_index += 16 didn't fit into LOAD_DOUBLE_TO_REG
#endif
jalr $zero, $ra
addiu $t8, 8 # next_arg = curr_arg + 8
loopEnd:
lw $t9, ART_METHOD_QUICK_CODE_OFFSET_32($a0) # get pointer to the code
jalr $t9 # call the method
sw $zero, 0($sp) # store null for ArtMethod* at bottom of frame
move $sp, $fp # restore the stack
lw $s0, 0($sp)
.cfi_restore 16
lw $s1, 4($sp)
.cfi_restore 17
lw $fp, 8($sp)
.cfi_restore 30
lw $ra, 12($sp)
.cfi_restore 31
addiu $sp, $sp, SPILL_SIZE
.cfi_adjust_cfa_offset -SPILL_SIZE
lw $t0, 16($sp) # get result pointer
lw $t1, 20($sp) # get shorty
lb $t1, 0($t1) # get result type char
li $t2, 'D' # put char 'D' into t2
beq $t1, $t2, 5f # branch if result type char == 'D'
li $t3, 'F' # put char 'F' into t3
beq $t1, $t3, 5f # branch if result type char == 'F'
sw $v0, 0($t0) # store the result
jalr $zero, $ra
sw $v1, 4($t0) # store the other half of the result
5:
CHECK_ALIGNMENT $t0, $t1, 8
sdc1 $f0, 0($t0) # store floating point result
jalr $zero, $ra
nop
// Note that gpr_index is kept within the range of tabInt and tabLong
// and fp_index is kept within the range of tabSingle and tabDouble.
.balign 16
tabInt:
LOAD_WORD_TO_REG a2, t8, t6, loop # a2 = current argument, gpr_index += 16
LOAD_WORD_TO_REG a3, t8, t6, loop # a3 = current argument, gpr_index += 16
LOAD_WORD_TO_REG t0, t8, t6, loop # t0 = current argument, gpr_index += 16
LOAD_WORD_TO_REG t1, t8, t6, loop # t1 = current argument, gpr_index += 16
LOAD_END t6, 4*16, loop # no more GPR args, gpr_index = 4*16
tabLong:
LOAD_LONG_TO_REG a2, a3, t8, t6, 2*16, loop # a2_a3 = curr_arg, gpr_index = 2*16
LOAD_LONG_TO_REG t0, t1, t8, t6, 4*16, loop # t0_t1 = curr_arg, gpr_index = 4*16
LOAD_LONG_TO_REG t0, t1, t8, t6, 4*16, loop # t0_t1 = curr_arg, gpr_index = 4*16
LOAD_END t6, 4*16, loop # no more GPR args, gpr_index = 4*16
LOAD_END t6, 4*16, loop # no more GPR args, gpr_index = 4*16
tabSingle:
LOAD_FLOAT_TO_REG f8, t8, t7, loop # f8 = curr_arg, fp_index += 16
LOAD_FLOAT_TO_REG f10, t8, t7, loop # f10 = curr_arg, fp_index += 16
LOAD_FLOAT_TO_REG f12, t8, t7, loop # f12 = curr_arg, fp_index += 16
LOAD_FLOAT_TO_REG f14, t8, t7, loop # f14 = curr_arg, fp_index += 16
LOAD_FLOAT_TO_REG f16, t8, t7, loop # f16 = curr_arg, fp_index += 16
LOAD_FLOAT_TO_REG f18, t8, t7, loop # f18 = curr_arg, fp_index += 16
LOAD_END t7, 6*16, loop # no more FPR args, fp_index = 6*16
tabDouble:
LOAD_DOUBLE_TO_REG f8, f9, t8, t7, ra, loop # f8_f9 = curr_arg; if FPU32, fp_index += 16
LOAD_DOUBLE_TO_REG f10, f11, t8, t7, ra, loop # f10_f11 = curr_arg; if FPU32, fp_index += 16
LOAD_DOUBLE_TO_REG f12, f13, t8, t7, ra, loop # f12_f13 = curr_arg; if FPU32, fp_index += 16
LOAD_DOUBLE_TO_REG f14, f15, t8, t7, ra, loop # f14_f15 = curr_arg; if FPU32, fp_index += 16
LOAD_DOUBLE_TO_REG f16, f17, t8, t7, ra, loop # f16_f17 = curr_arg; if FPU32, fp_index += 16
LOAD_DOUBLE_TO_REG f18, f19, t8, t7, ra, loop # f18_f19 = curr_arg; if FPU32, fp_index += 16
LOAD_END t7, 6*16, loop # no more FPR args, fp_index = 6*16
END art_quick_invoke_stub
/*
* Invocation static stub for quick code.
* On entry:
* a0 = method pointer
* a1 = argument array or null for no argument methods
* a2 = size of argument array in bytes
* a3 = (managed) thread pointer
* [sp + 16] = JValue* result
* [sp + 20] = shorty
*/
ENTRY art_quick_invoke_static_stub
sw $a0, 0($sp) # save out a0
addiu $sp, $sp, -SPILL_SIZE # spill s0, s1, fp, ra and gp
.cfi_adjust_cfa_offset SPILL_SIZE
sw $gp, 16($sp)
sw $ra, 12($sp)
.cfi_rel_offset 31, 12
sw $fp, 8($sp)
.cfi_rel_offset 30, 8
sw $s1, 4($sp)
.cfi_rel_offset 17, 4
sw $s0, 0($sp)
.cfi_rel_offset 16, 0
move $fp, $sp # save sp in fp
.cfi_def_cfa_register 30
move $s1, $a3 # move managed thread pointer into s1
addiu $t0, $a2, 4 # create space for ArtMethod* in frame.
subu $t0, $sp, $t0 # reserve & align *stack* to 16 bytes:
srl $t0, $t0, 4 # native calling convention only aligns to 8B,
sll $sp, $t0, 4 # so we have to ensure ART 16B alignment ourselves.
addiu $a0, $sp, 4 # pass stack pointer + ArtMethod* as dest for memcpy
la $t9, memcpy
jalr $t9 # (dest, src, bytes)
addiu $sp, $sp, -16 # make space for argument slots for memcpy
addiu $sp, $sp, 16 # restore stack after memcpy
lw $gp, 16($fp) # restore $gp
lw $a0, SPILL_SIZE($fp) # restore ArtMethod*
addiu $t8, $sp, 4 # t8 = pointer to the current argument (skip ArtMethod*)
li $t6, 0 # t6 = gpr_index = 0 (corresponds to A1; A0 is skipped)
li $t7, 0 # t7 = fp_index = 0
lw $t9, 20 + SPILL_SIZE($fp) # get shorty (20 is offset from the $sp on entry + SPILL_SIZE
# as the $fp is SPILL_SIZE bytes below the $sp on entry)
addiu $t9, 1 # t9 = shorty + 1 (skip 1 for return type)
// Load the base addresses of tabIntS ... tabDoubleS.
// We will use the register indices (gpr_index, fp_index) to branch.
// Note that the indices are scaled by 16, so they can be added to the bases directly.
#if defined(__mips_isa_rev) && __mips_isa_rev >= 6
lapc $t2, tabIntS
lapc $t3, tabLongS
lapc $t4, tabSingleS
lapc $t5, tabDoubleS
#else
bltzal $zero, tabBaseS # nal
addiu $t2, $ra, %lo(tabIntS - tabBaseS)
tabBaseS:
addiu $t3, $ra, %lo(tabLongS - tabBaseS)
addiu $t4, $ra, %lo(tabSingleS - tabBaseS)
addiu $t5, $ra, %lo(tabDoubleS - tabBaseS)
#endif
loopS:
lbu $ra, 0($t9) # ra = shorty[i]
beqz $ra, loopEndS # finish getting args when shorty[i] == '\0'
addiu $t9, 1
addiu $ra, -'J'
beqz $ra, isLongS # branch if result type char == 'J'
addiu $ra, 'J' - 'D'
beqz $ra, isDoubleS # branch if result type char == 'D'
addiu $ra, 'D' - 'F'
beqz $ra, isSingleS # branch if result type char == 'F'
addu $ra, $t2, $t6
jalr $zero, $ra
addiu $t8, 4 # next_arg = curr_arg + 4
isLongS:
addu $ra, $t3, $t6
jalr $zero, $ra
addiu $t8, 8 # next_arg = curr_arg + 8
isSingleS:
addu $ra, $t4, $t7
jalr $zero, $ra
addiu $t8, 4 # next_arg = curr_arg + 4
isDoubleS:
addu $ra, $t5, $t7
#if defined(__mips_isa_rev) && __mips_isa_rev > 2
addiu $t7, 16 # fp_index += 16 didn't fit into LOAD_DOUBLE_TO_REG
#endif
jalr $zero, $ra
addiu $t8, 8 # next_arg = curr_arg + 8
loopEndS:
lw $t9, ART_METHOD_QUICK_CODE_OFFSET_32($a0) # get pointer to the code
jalr $t9 # call the method
sw $zero, 0($sp) # store null for ArtMethod* at bottom of frame
move $sp, $fp # restore the stack
lw $s0, 0($sp)
.cfi_restore 16
lw $s1, 4($sp)
.cfi_restore 17
lw $fp, 8($sp)
.cfi_restore 30
lw $ra, 12($sp)
.cfi_restore 31
addiu $sp, $sp, SPILL_SIZE
.cfi_adjust_cfa_offset -SPILL_SIZE
lw $t0, 16($sp) # get result pointer
lw $t1, 20($sp) # get shorty
lb $t1, 0($t1) # get result type char
li $t2, 'D' # put char 'D' into t2
beq $t1, $t2, 6f # branch if result type char == 'D'
li $t3, 'F' # put char 'F' into t3
beq $t1, $t3, 6f # branch if result type char == 'F'
sw $v0, 0($t0) # store the result
jalr $zero, $ra
sw $v1, 4($t0) # store the other half of the result
6:
CHECK_ALIGNMENT $t0, $t1, 8
sdc1 $f0, 0($t0) # store floating point result
jalr $zero, $ra
nop
// Note that gpr_index is kept within the range of tabIntS and tabLongS
// and fp_index is kept within the range of tabSingleS and tabDoubleS.
.balign 16
tabIntS:
LOAD_WORD_TO_REG a1, t8, t6, loopS # a1 = current argument, gpr_index += 16
LOAD_WORD_TO_REG a2, t8, t6, loopS # a2 = current argument, gpr_index += 16
LOAD_WORD_TO_REG a3, t8, t6, loopS # a3 = current argument, gpr_index += 16
LOAD_WORD_TO_REG t0, t8, t6, loopS # t0 = current argument, gpr_index += 16
LOAD_WORD_TO_REG t1, t8, t6, loopS # t1 = current argument, gpr_index += 16
LOAD_END t6, 5*16, loopS # no more GPR args, gpr_index = 5*16
tabLongS:
LOAD_LONG_TO_REG a2, a3, t8, t6, 3*16, loopS # a2_a3 = curr_arg, gpr_index = 3*16
LOAD_LONG_TO_REG a2, a3, t8, t6, 3*16, loopS # a2_a3 = curr_arg, gpr_index = 3*16
LOAD_LONG_TO_REG t0, t1, t8, t6, 5*16, loopS # t0_t1 = curr_arg, gpr_index = 5*16
LOAD_LONG_TO_REG t0, t1, t8, t6, 5*16, loopS # t0_t1 = curr_arg, gpr_index = 5*16
LOAD_END t6, 5*16, loopS # no more GPR args, gpr_index = 5*16
LOAD_END t6, 5*16, loopS # no more GPR args, gpr_index = 5*16
tabSingleS:
LOAD_FLOAT_TO_REG f8, t8, t7, loopS # f8 = curr_arg, fp_index += 16
LOAD_FLOAT_TO_REG f10, t8, t7, loopS # f10 = curr_arg, fp_index += 16
LOAD_FLOAT_TO_REG f12, t8, t7, loopS # f12 = curr_arg, fp_index += 16
LOAD_FLOAT_TO_REG f14, t8, t7, loopS # f14 = curr_arg, fp_index += 16
LOAD_FLOAT_TO_REG f16, t8, t7, loopS # f16 = curr_arg, fp_index += 16
LOAD_FLOAT_TO_REG f18, t8, t7, loopS # f18 = curr_arg, fp_index += 16
LOAD_END t7, 6*16, loopS # no more FPR args, fp_index = 6*16
tabDoubleS:
LOAD_DOUBLE_TO_REG f8, f9, t8, t7, ra, loopS # f8_f9 = curr_arg; if FPU32, fp_index += 16
LOAD_DOUBLE_TO_REG f10, f11, t8, t7, ra, loopS # f10_f11 = curr_arg; if FPU32, fp_index += 16
LOAD_DOUBLE_TO_REG f12, f13, t8, t7, ra, loopS # f12_f13 = curr_arg; if FPU32, fp_index += 16
LOAD_DOUBLE_TO_REG f14, f15, t8, t7, ra, loopS # f14_f15 = curr_arg; if FPU32, fp_index += 16
LOAD_DOUBLE_TO_REG f16, f17, t8, t7, ra, loopS # f16_f17 = curr_arg; if FPU32, fp_index += 16
LOAD_DOUBLE_TO_REG f18, f19, t8, t7, ra, loopS # f18_f19 = curr_arg; if FPU32, fp_index += 16
LOAD_END t7, 6*16, loopS # no more FPR args, fp_index = 6*16
END art_quick_invoke_static_stub
#undef SPILL_SIZE
/*
* Entry from managed code that calls artHandleFillArrayDataFromCode and delivers exception on
* failure.
*/
.extern artHandleFillArrayDataFromCode
ENTRY art_quick_handle_fill_data
lw $a2, 0($sp) # pass referrer's Method*
SETUP_SAVE_REFS_ONLY_FRAME # save callee saves in case exception allocation triggers GC
la $t9, artHandleFillArrayDataFromCode
jalr $t9 # (payload offset, Array*, method, Thread*)
move $a3, rSELF # pass Thread::Current
RETURN_IF_ZERO
END art_quick_handle_fill_data
/*
* Entry from managed code that calls artLockObjectFromCode, may block for GC.
*/
.extern artLockObjectFromCode
ENTRY art_quick_lock_object
beqz $a0, art_quick_throw_null_pointer_exception
li $t8, LOCK_WORD_THIN_LOCK_COUNT_ONE
li $t3, LOCK_WORD_GC_STATE_MASK_SHIFTED_TOGGLED
.Lretry_lock:
lw $t0, THREAD_ID_OFFSET(rSELF) # TODO: Can the thread ID really change during the loop?
ll $t1, MIRROR_OBJECT_LOCK_WORD_OFFSET($a0)
and $t2, $t1, $t3 # zero the gc bits
bnez $t2, .Lnot_unlocked # already thin locked
# Unlocked case - $t1: original lock word that's zero except for the read barrier bits.
or $t2, $t1, $t0 # $t2 holds thread id with count of 0 with preserved read barrier bits
sc $t2, MIRROR_OBJECT_LOCK_WORD_OFFSET($a0)
beqz $t2, .Lretry_lock # store failed, retry
nop
jalr $zero, $ra
sync # full (LoadLoad|LoadStore) memory barrier
.Lnot_unlocked:
# $t1: original lock word, $t0: thread_id with count of 0 and zero read barrier bits
srl $t2, $t1, LOCK_WORD_STATE_SHIFT
bnez $t2, .Lslow_lock # if either of the top two bits are set, go slow path
xor $t2, $t1, $t0 # lock_word.ThreadId() ^ self->ThreadId()
andi $t2, $t2, 0xFFFF # zero top 16 bits
bnez $t2, .Lslow_lock # lock word and self thread id's match -> recursive lock
# otherwise contention, go to slow path
and $t2, $t1, $t3 # zero the gc bits
addu $t2, $t2, $t8 # increment count in lock word
srl $t2, $t2, LOCK_WORD_STATE_SHIFT # if the first gc state bit is set, we overflowed.
bnez $t2, .Lslow_lock # if we overflow the count go slow path
addu $t2, $t1, $t8 # increment count for real
sc $t2, MIRROR_OBJECT_LOCK_WORD_OFFSET($a0)
beqz $t2, .Lretry_lock # store failed, retry
nop
jalr $zero, $ra
nop
.Lslow_lock:
SETUP_SAVE_REFS_ONLY_FRAME # save callee saves in case we block
la $t9, artLockObjectFromCode
jalr $t9 # (Object* obj, Thread*)
move $a1, rSELF # pass Thread::Current
RETURN_IF_ZERO
END art_quick_lock_object
ENTRY art_quick_lock_object_no_inline
beqz $a0, art_quick_throw_null_pointer_exception
nop
SETUP_SAVE_REFS_ONLY_FRAME # save callee saves in case we block
la $t9, artLockObjectFromCode
jalr $t9 # (Object* obj, Thread*)
move $a1, rSELF # pass Thread::Current
RETURN_IF_ZERO
END art_quick_lock_object_no_inline
/*
* Entry from managed code that calls artUnlockObjectFromCode and delivers exception on failure.
*/
.extern artUnlockObjectFromCode
ENTRY art_quick_unlock_object
beqz $a0, art_quick_throw_null_pointer_exception
li $t8, LOCK_WORD_THIN_LOCK_COUNT_ONE
li $t3, LOCK_WORD_GC_STATE_MASK_SHIFTED_TOGGLED
.Lretry_unlock:
#ifndef USE_READ_BARRIER
lw $t1, MIRROR_OBJECT_LOCK_WORD_OFFSET($a0)
#else
ll $t1, MIRROR_OBJECT_LOCK_WORD_OFFSET($a0) # Need to use atomic read-modify-write for read barrier
#endif
srl $t2, $t1, LOCK_WORD_STATE_SHIFT
bnez $t2, .Lslow_unlock # if either of the top two bits are set, go slow path
lw $t0, THREAD_ID_OFFSET(rSELF)
and $t2, $t1, $t3 # zero the gc bits
xor $t2, $t2, $t0 # lock_word.ThreadId() ^ self->ThreadId()
andi $t2, $t2, 0xFFFF # zero top 16 bits
bnez $t2, .Lslow_unlock # do lock word and self thread id's match?
and $t2, $t1, $t3 # zero the gc bits
bgeu $t2, $t8, .Lrecursive_thin_unlock
# transition to unlocked
nor $t2, $zero, $t3 # $t2 = LOCK_WORD_GC_STATE_MASK_SHIFTED
and $t2, $t1, $t2 # $t2: zero except for the preserved gc bits
sync # full (LoadStore|StoreStore) memory barrier
#ifndef USE_READ_BARRIER
jalr $zero, $ra
sw $t2, MIRROR_OBJECT_LOCK_WORD_OFFSET($a0)
#else
sc $t2, MIRROR_OBJECT_LOCK_WORD_OFFSET($a0)
beqz $t2, .Lretry_unlock # store failed, retry
nop
jalr $zero, $ra
nop
#endif
.Lrecursive_thin_unlock:
# t1: original lock word
subu $t2, $t1, $t8 # decrement count
#ifndef USE_READ_BARRIER
jalr $zero, $ra
sw $t2, MIRROR_OBJECT_LOCK_WORD_OFFSET($a0)
#else
sc $t2, MIRROR_OBJECT_LOCK_WORD_OFFSET($a0)
beqz $t2, .Lretry_unlock # store failed, retry
nop
jalr $zero, $ra
nop
#endif
.Lslow_unlock:
SETUP_SAVE_REFS_ONLY_FRAME # save callee saves in case exception allocation triggers GC
la $t9, artUnlockObjectFromCode
jalr $t9 # (Object* obj, Thread*)
move $a1, rSELF # pass Thread::Current
RETURN_IF_ZERO
END art_quick_unlock_object
ENTRY art_quick_unlock_object_no_inline
beqz $a0, art_quick_throw_null_pointer_exception
nop
SETUP_SAVE_REFS_ONLY_FRAME # save callee saves in case exception allocation triggers GC
la $t9, artUnlockObjectFromCode
jalr $t9 # (Object* obj, Thread*)
move $a1, rSELF # pass Thread::Current
RETURN_IF_ZERO
END art_quick_unlock_object_no_inline
/*
* Entry from managed code that calls artInstanceOfFromCode and delivers exception on failure.
*/
.extern artInstanceOfFromCode
.extern artThrowClassCastExceptionForObject
ENTRY art_quick_check_instance_of
// Type check using the bit string passes null as the target class. In that case just throw.
beqz $a1, .Lthrow_class_cast_exception_for_bitstring_check
nop
addiu $sp, $sp, -32
.cfi_adjust_cfa_offset 32
sw $gp, 16($sp)
sw $ra, 12($sp)
.cfi_rel_offset 31, 12
sw $t9, 8($sp)
sw $a1, 4($sp)
sw $a0, 0($sp)
la $t9, artInstanceOfFromCode
jalr $t9
addiu $sp, $sp, -16 # reserve argument slots on the stack
addiu $sp, $sp, 16
lw $gp, 16($sp)
beqz $v0, .Lthrow_class_cast_exception
lw $ra, 12($sp)
jalr $zero, $ra
addiu $sp, $sp, 32
.cfi_adjust_cfa_offset -32
.Lthrow_class_cast_exception:
lw $t9, 8($sp)
lw $a1, 4($sp)
lw $a0, 0($sp)
addiu $sp, $sp, 32
.cfi_adjust_cfa_offset -32
.Lthrow_class_cast_exception_for_bitstring_check:
SETUP_SAVE_ALL_CALLEE_SAVES_FRAME
la $t9, artThrowClassCastExceptionForObject
jalr $zero, $t9 # artThrowClassCastException (Object*, Class*, Thread*)
move $a2, rSELF # pass Thread::Current
END art_quick_check_instance_of
/*
* Restore rReg's value from offset($sp) if rReg is not the same as rExclude.
* nReg is the register number for rReg.
*/
.macro POP_REG_NE rReg, nReg, offset, rExclude
.ifnc \rReg, \rExclude
lw \rReg, \offset($sp) # restore rReg
.cfi_restore \nReg
.endif
.endm
/*
* Macro to insert read barrier, only used in art_quick_aput_obj.
* rObj and rDest are registers, offset is a defined literal such as MIRROR_OBJECT_CLASS_OFFSET.
* TODO: When read barrier has a fast path, add heap unpoisoning support for the fast path.
*/
.macro READ_BARRIER rDest, rObj, offset
#ifdef USE_READ_BARRIER
# saved registers used in art_quick_aput_obj: a0-a2, t0-t1, t9, ra. 8 words for 16B alignment.
addiu $sp, $sp, -32
.cfi_adjust_cfa_offset 32
sw $ra, 28($sp)
.cfi_rel_offset 31, 28
sw $t9, 24($sp)
.cfi_rel_offset 25, 24
sw $t1, 20($sp)
.cfi_rel_offset 9, 20
sw $t0, 16($sp)
.cfi_rel_offset 8, 16
sw $a2, 8($sp) # padding slot at offset 12 (padding can be any slot in the 32B)
.cfi_rel_offset 6, 8
sw $a1, 4($sp)
.cfi_rel_offset 5, 4
sw $a0, 0($sp)
.cfi_rel_offset 4, 0
# move $a0, \rRef # pass ref in a0 (no-op for now since parameter ref is unused)
.ifnc \rObj, $a1
move $a1, \rObj # pass rObj
.endif
addiu $a2, $zero, \offset # pass offset
la $t9, artReadBarrierSlow
jalr $t9 # artReadBarrierSlow(ref, rObj, offset)
addiu $sp, $sp, -16 # Use branch delay slot to reserve argument slots on the stack
# before the call to artReadBarrierSlow.
addiu $sp, $sp, 16 # restore stack after call to artReadBarrierSlow
# No need to unpoison return value in v0, artReadBarrierSlow() would do the unpoisoning.
move \rDest, $v0 # save return value in rDest
# (rDest cannot be v0 in art_quick_aput_obj)
lw $a0, 0($sp) # restore registers except rDest
# (rDest can only be t0 or t1 in art_quick_aput_obj)
.cfi_restore 4
lw $a1, 4($sp)
.cfi_restore 5
lw $a2, 8($sp)
.cfi_restore 6
POP_REG_NE $t0, 8, 16, \rDest
POP_REG_NE $t1, 9, 20, \rDest
lw $t9, 24($sp)
.cfi_restore 25
lw $ra, 28($sp) # restore $ra
.cfi_restore 31
addiu $sp, $sp, 32
.cfi_adjust_cfa_offset -32
#else
lw \rDest, \offset(\rObj)
UNPOISON_HEAP_REF \rDest
#endif // USE_READ_BARRIER
.endm
#ifdef USE_READ_BARRIER
.extern artReadBarrierSlow
#endif
ENTRY art_quick_aput_obj
beqz $a2, .Ldo_aput_null
nop
READ_BARRIER $t0, $a0, MIRROR_OBJECT_CLASS_OFFSET
READ_BARRIER $t1, $a2, MIRROR_OBJECT_CLASS_OFFSET
READ_BARRIER $t0, $t0, MIRROR_CLASS_COMPONENT_TYPE_OFFSET
bne $t1, $t0, .Lcheck_assignability # value's type == array's component type - trivial assignability
nop
.Ldo_aput:
sll $a1, $a1, 2
add $t0, $a0, $a1
POISON_HEAP_REF $a2
sw $a2, MIRROR_OBJECT_ARRAY_DATA_OFFSET($t0)
lw $t0, THREAD_CARD_TABLE_OFFSET(rSELF)
srl $t1, $a0, CARD_TABLE_CARD_SHIFT
add $t1, $t1, $t0
sb $t0, ($t1)
jalr $zero, $ra
nop
.Ldo_aput_null:
sll $a1, $a1, 2
add $t0, $a0, $a1
sw $a2, MIRROR_OBJECT_ARRAY_DATA_OFFSET($t0)
jalr $zero, $ra
nop
.Lcheck_assignability:
addiu $sp, $sp, -32
.cfi_adjust_cfa_offset 32
sw $ra, 28($sp)
.cfi_rel_offset 31, 28
sw $gp, 16($sp)
sw $t9, 12($sp)
sw $a2, 8($sp)
sw $a1, 4($sp)
sw $a0, 0($sp)
move $a1, $t1
move $a0, $t0
la $t9, artIsAssignableFromCode
jalr $t9 # (Class*, Class*)
addiu $sp, $sp, -16 # reserve argument slots on the stack
addiu $sp, $sp, 16
lw $ra, 28($sp)
lw $gp, 16($sp)
lw $t9, 12($sp)
lw $a2, 8($sp)
lw $a1, 4($sp)
lw $a0, 0($sp)
addiu $sp, 32
.cfi_adjust_cfa_offset -32
bnez $v0, .Ldo_aput
nop
SETUP_SAVE_ALL_CALLEE_SAVES_FRAME
move $a1, $a2
la $t9, artThrowArrayStoreException
jalr $zero, $t9 # artThrowArrayStoreException(Class*, Class*, Thread*)
move $a2, rSELF # pass Thread::Current
END art_quick_aput_obj
// Macros taking opportunity of code similarities for downcalls.
.macro ONE_ARG_REF_DOWNCALL name, entrypoint, return
.extern \entrypoint
ENTRY \name
SETUP_SAVE_REFS_ONLY_FRAME # save callee saves in case of GC
la $t9, \entrypoint
jalr $t9 # (field_idx, Thread*)
move $a1, rSELF # pass Thread::Current
\return # RETURN_IF_NO_EXCEPTION or RETURN_IF_ZERO
END \name
.endm
.macro TWO_ARG_REF_DOWNCALL name, entrypoint, return
.extern \entrypoint
ENTRY \name
SETUP_SAVE_REFS_ONLY_FRAME # save callee saves in case of GC
la $t9, \entrypoint
jalr $t9 # (field_idx, Object*, Thread*) or
# (field_idx, new_val, Thread*)
move $a2, rSELF # pass Thread::Current
\return # RETURN_IF_NO_EXCEPTION or RETURN_IF_ZERO
END \name
.endm
.macro THREE_ARG_REF_DOWNCALL name, entrypoint, return
.extern \entrypoint
ENTRY \name
SETUP_SAVE_REFS_ONLY_FRAME # save callee saves in case of GC
la $t9, \entrypoint
jalr $t9 # (field_idx, Object*, new_val, Thread*)
move $a3, rSELF # pass Thread::Current
\return # RETURN_IF_NO_EXCEPTION or RETURN_IF_ZERO
END \name
.endm
.macro FOUR_ARG_REF_DOWNCALL name, entrypoint, return
.extern \entrypoint
ENTRY \name
SETUP_SAVE_REFS_ONLY_FRAME # save callee saves in case of GC
la $t9, \entrypoint
jalr $t9 # (field_idx, Object*, 64-bit new_val, Thread*) or
# (field_idx, 64-bit new_val, Thread*)
# Note that a 64-bit new_val needs to be aligned with
# an even-numbered register, hence A1 may be skipped
# for new_val to reside in A2-A3.
sw rSELF, 16($sp) # pass Thread::Current
\return # RETURN_IF_NO_EXCEPTION or RETURN_IF_ZERO
END \name
.endm
/*
* Called by managed code to resolve a static/instance field and load/store a value.
*
* Note: Functions `art{Get,Set}<Kind>{Static,Instance}FromCompiledCode` are
* defined with a macro in runtime/entrypoints/quick/quick_field_entrypoints.cc.
*/
ONE_ARG_REF_DOWNCALL art_quick_get_byte_static, artGetByteStaticFromCompiledCode, RETURN_IF_NO_EXCEPTION
ONE_ARG_REF_DOWNCALL art_quick_get_boolean_static, artGetBooleanStaticFromCompiledCode, RETURN_IF_NO_EXCEPTION
ONE_ARG_REF_DOWNCALL art_quick_get_short_static, artGetShortStaticFromCompiledCode, RETURN_IF_NO_EXCEPTION
ONE_ARG_REF_DOWNCALL art_quick_get_char_static, artGetCharStaticFromCompiledCode, RETURN_IF_NO_EXCEPTION
ONE_ARG_REF_DOWNCALL art_quick_get32_static, artGet32StaticFromCompiledCode, RETURN_IF_NO_EXCEPTION
ONE_ARG_REF_DOWNCALL art_quick_get_obj_static, artGetObjStaticFromCompiledCode, RETURN_IF_NO_EXCEPTION
ONE_ARG_REF_DOWNCALL art_quick_get64_static, artGet64StaticFromCompiledCode, RETURN_IF_NO_EXCEPTION
TWO_ARG_REF_DOWNCALL art_quick_get_byte_instance, artGetByteInstanceFromCompiledCode, RETURN_IF_NO_EXCEPTION
TWO_ARG_REF_DOWNCALL art_quick_get_boolean_instance, artGetBooleanInstanceFromCompiledCode, RETURN_IF_NO_EXCEPTION
TWO_ARG_REF_DOWNCALL art_quick_get_short_instance, artGetShortInstanceFromCompiledCode, RETURN_IF_NO_EXCEPTION
TWO_ARG_REF_DOWNCALL art_quick_get_char_instance, artGetCharInstanceFromCompiledCode, RETURN_IF_NO_EXCEPTION
TWO_ARG_REF_DOWNCALL art_quick_get32_instance, artGet32InstanceFromCompiledCode, RETURN_IF_NO_EXCEPTION
TWO_ARG_REF_DOWNCALL art_quick_get_obj_instance, artGetObjInstanceFromCompiledCode, RETURN_IF_NO_EXCEPTION
TWO_ARG_REF_DOWNCALL art_quick_get64_instance, artGet64InstanceFromCompiledCode, RETURN_IF_NO_EXCEPTION
TWO_ARG_REF_DOWNCALL art_quick_set8_static, artSet8StaticFromCompiledCode, RETURN_IF_ZERO
TWO_ARG_REF_DOWNCALL art_quick_set16_static, artSet16StaticFromCompiledCode, RETURN_IF_ZERO
TWO_ARG_REF_DOWNCALL art_quick_set32_static, artSet32StaticFromCompiledCode, RETURN_IF_ZERO
TWO_ARG_REF_DOWNCALL art_quick_set_obj_static, artSetObjStaticFromCompiledCode, RETURN_IF_ZERO
FOUR_ARG_REF_DOWNCALL art_quick_set64_static, artSet64StaticFromCompiledCode, RETURN_IF_ZERO
THREE_ARG_REF_DOWNCALL art_quick_set8_instance, artSet8InstanceFromCompiledCode, RETURN_IF_ZERO
THREE_ARG_REF_DOWNCALL art_quick_set16_instance, artSet16InstanceFromCompiledCode, RETURN_IF_ZERO
THREE_ARG_REF_DOWNCALL art_quick_set32_instance, artSet32InstanceFromCompiledCode, RETURN_IF_ZERO
THREE_ARG_REF_DOWNCALL art_quick_set_obj_instance, artSetObjInstanceFromCompiledCode, RETURN_IF_ZERO
FOUR_ARG_REF_DOWNCALL art_quick_set64_instance, artSet64InstanceFromCompiledCode, RETURN_IF_ZERO
// Macro to facilitate adding new allocation entrypoints.
.macro ONE_ARG_DOWNCALL name, entrypoint, return
.extern \entrypoint
ENTRY \name
SETUP_SAVE_REFS_ONLY_FRAME # save callee saves in case of GC
la $t9, \entrypoint
jalr $t9
move $a1, rSELF # pass Thread::Current
\return
END \name
.endm
.macro TWO_ARG_DOWNCALL name, entrypoint, return
.extern \entrypoint
ENTRY \name
SETUP_SAVE_REFS_ONLY_FRAME # save callee saves in case of GC
la $t9, \entrypoint
jalr $t9
move $a2, rSELF # pass Thread::Current
\return
END \name
.endm
.macro THREE_ARG_DOWNCALL name, entrypoint, return
.extern \entrypoint
ENTRY \name
SETUP_SAVE_REFS_ONLY_FRAME # save callee saves in case of GC
la $t9, \entrypoint
jalr $t9
move $a3, rSELF # pass Thread::Current
\return
END \name
.endm
.macro FOUR_ARG_DOWNCALL name, entrypoint, return
.extern \entrypoint
ENTRY \name
SETUP_SAVE_REFS_ONLY_FRAME # save callee saves in case of GC
la $t9, \entrypoint
jalr $t9
sw rSELF, 16($sp) # pass Thread::Current
\return
END \name
.endm
// Generate the allocation entrypoints for each allocator.
GENERATE_ALLOC_ENTRYPOINTS_FOR_NON_TLAB_ALLOCATORS
// Comment out allocators that have mips specific asm.
// GENERATE_ALLOC_ENTRYPOINTS_ALLOC_OBJECT_RESOLVED(_region_tlab, RegionTLAB)
// GENERATE_ALLOC_ENTRYPOINTS_ALLOC_OBJECT_INITIALIZED(_region_tlab, RegionTLAB)
GENERATE_ALLOC_ENTRYPOINTS_ALLOC_OBJECT_WITH_ACCESS_CHECK(_region_tlab, RegionTLAB)
GENERATE_ALLOC_ENTRYPOINTS_ALLOC_STRING_OBJECT(_region_tlab, RegionTLAB)
// GENERATE_ALLOC_ENTRYPOINTS_ALLOC_ARRAY_RESOLVED(_region_tlab, RegionTLAB)
// GENERATE_ALLOC_ENTRYPOINTS_ALLOC_ARRAY_RESOLVED8(_region_tlab, RegionTLAB)
// GENERATE_ALLOC_ENTRYPOINTS_ALLOC_ARRAY_RESOLVED16(_region_tlab, RegionTLAB)
// GENERATE_ALLOC_ENTRYPOINTS_ALLOC_ARRAY_RESOLVED32(_region_tlab, RegionTLAB)
// GENERATE_ALLOC_ENTRYPOINTS_ALLOC_ARRAY_RESOLVED64(_region_tlab, RegionTLAB)
GENERATE_ALLOC_ENTRYPOINTS_ALLOC_STRING_FROM_BYTES(_region_tlab, RegionTLAB)
GENERATE_ALLOC_ENTRYPOINTS_ALLOC_STRING_FROM_CHARS(_region_tlab, RegionTLAB)
GENERATE_ALLOC_ENTRYPOINTS_ALLOC_STRING_FROM_STRING(_region_tlab, RegionTLAB)
// GENERATE_ALLOC_ENTRYPOINTS_ALLOC_OBJECT_RESOLVED(_tlab, TLAB)
// GENERATE_ALLOC_ENTRYPOINTS_ALLOC_OBJECT_INITIALIZED(_tlab, TLAB)
GENERATE_ALLOC_ENTRYPOINTS_ALLOC_OBJECT_WITH_ACCESS_CHECK(_tlab, TLAB)
GENERATE_ALLOC_ENTRYPOINTS_ALLOC_STRING_OBJECT(_tlab, TLAB)
// GENERATE_ALLOC_ENTRYPOINTS_ALLOC_ARRAY_RESOLVED(_tlab, TLAB)
// GENERATE_ALLOC_ENTRYPOINTS_ALLOC_ARRAY_RESOLVED8(_tlab, TLAB)
// GENERATE_ALLOC_ENTRYPOINTS_ALLOC_ARRAY_RESOLVED16(_tlab, TLAB)
// GENERATE_ALLOC_ENTRYPOINTS_ALLOC_ARRAY_RESOLVED32(_tlab, TLAB)
// GENERATE_ALLOC_ENTRYPOINTS_ALLOC_ARRAY_RESOLVED64(_tlab, TLAB)
GENERATE_ALLOC_ENTRYPOINTS_ALLOC_STRING_FROM_BYTES(_tlab, TLAB)
GENERATE_ALLOC_ENTRYPOINTS_ALLOC_STRING_FROM_CHARS(_tlab, TLAB)
GENERATE_ALLOC_ENTRYPOINTS_ALLOC_STRING_FROM_STRING(_tlab, TLAB)
// A hand-written override for:
// GENERATE_ALLOC_ENTRYPOINTS_ALLOC_OBJECT_RESOLVED(_rosalloc, RosAlloc)
// GENERATE_ALLOC_ENTRYPOINTS_ALLOC_OBJECT_INITIALIZED(_rosalloc, RosAlloc)
.macro ART_QUICK_ALLOC_OBJECT_ROSALLOC c_name, cxx_name, isInitialized
ENTRY_NO_GP \c_name
# Fast path rosalloc allocation
# a0: type
# s1: Thread::Current
# -----------------------------
# t1: object size
# t2: rosalloc run
# t3: thread stack top offset
# t4: thread stack bottom offset
# v0: free list head
#
# t5, t6 : temps
lw $t3, THREAD_LOCAL_ALLOC_STACK_TOP_OFFSET($s1) # Check if thread local allocation
lw $t4, THREAD_LOCAL_ALLOC_STACK_END_OFFSET($s1) # stack has any room left.
bgeu $t3, $t4, .Lslow_path_\c_name
lw $t1, MIRROR_CLASS_OBJECT_SIZE_ALLOC_FAST_PATH_OFFSET($a0) # Load object size (t1).
li $t5, ROSALLOC_MAX_THREAD_LOCAL_BRACKET_SIZE # Check if size is for a thread local
# allocation. Also does the
# initialized and finalizable checks.
# When isInitialized == 0, then the class is potentially not yet initialized.
# If the class is not yet initialized, the object size will be very large to force the branch
# below to be taken.
#
# See InitializeClassVisitors in class-inl.h for more details.
bgtu $t1, $t5, .Lslow_path_\c_name
# Compute the rosalloc bracket index from the size. Since the size is already aligned we can
# combine the two shifts together.
srl $t1, $t1, (ROSALLOC_BRACKET_QUANTUM_SIZE_SHIFT - POINTER_SIZE_SHIFT)
addu $t2, $t1, $s1
lw $t2, (THREAD_ROSALLOC_RUNS_OFFSET - __SIZEOF_POINTER__)($t2) # Load rosalloc run (t2).
# Load the free list head (v0).
# NOTE: this will be the return val.
lw $v0, (ROSALLOC_RUN_FREE_LIST_OFFSET + ROSALLOC_RUN_FREE_LIST_HEAD_OFFSET)($t2)
beqz $v0, .Lslow_path_\c_name
nop
# Load the next pointer of the head and update the list head with the next pointer.
lw $t5, ROSALLOC_SLOT_NEXT_OFFSET($v0)
sw $t5, (ROSALLOC_RUN_FREE_LIST_OFFSET + ROSALLOC_RUN_FREE_LIST_HEAD_OFFSET)($t2)
# Store the class pointer in the header. This also overwrites the first pointer. The offsets are
# asserted to match.
#if ROSALLOC_SLOT_NEXT_OFFSET != MIRROR_OBJECT_CLASS_OFFSET
#error "Class pointer needs to overwrite next pointer."
#endif
POISON_HEAP_REF $a0
sw $a0, MIRROR_OBJECT_CLASS_OFFSET($v0)
# Push the new object onto the thread local allocation stack and increment the thread local
# allocation stack top.
sw $v0, 0($t3)
addiu $t3, $t3, COMPRESSED_REFERENCE_SIZE
sw $t3, THREAD_LOCAL_ALLOC_STACK_TOP_OFFSET($s1)
# Decrement the size of the free list.
lw $t5, (ROSALLOC_RUN_FREE_LIST_OFFSET + ROSALLOC_RUN_FREE_LIST_SIZE_OFFSET)($t2)
addiu $t5, $t5, -1
sw $t5, (ROSALLOC_RUN_FREE_LIST_OFFSET + ROSALLOC_RUN_FREE_LIST_SIZE_OFFSET)($t2)
.if \isInitialized == 0
# This barrier is only necessary when the allocation also requires a class initialization check.
#
# If the class is already observably initialized, then new-instance allocations are protected
# from publishing by the compiler which inserts its own StoreStore barrier.
sync # Fence.
.endif
jalr $zero, $ra
nop
.Lslow_path_\c_name:
addiu $t9, $t9, (.Lslow_path_\c_name - \c_name) + 4
.cpload $t9
SETUP_SAVE_REFS_ONLY_FRAME
la $t9, \cxx_name
jalr $t9
move $a1, $s1 # Pass self as argument.
RETURN_IF_RESULT_IS_NON_ZERO_OR_DELIVER
END \c_name
.endm
ART_QUICK_ALLOC_OBJECT_ROSALLOC art_quick_alloc_object_resolved_rosalloc, artAllocObjectFromCodeResolvedRosAlloc, /* isInitialized */ 0
ART_QUICK_ALLOC_OBJECT_ROSALLOC art_quick_alloc_object_initialized_rosalloc, artAllocObjectFromCodeInitializedRosAlloc, /* isInitialized */ 1
// The common fast path code for art_quick_alloc_object_resolved/initialized_tlab
// and art_quick_alloc_object_resolved/initialized_region_tlab.
//
// a0: type, s1(rSELF): Thread::Current.
// Need to preserve a0 to the slow path.
//
// If isInitialized=1 then the compiler assumes the object's class has already been initialized.
// If isInitialized=0 the compiler can only assume it's been at least resolved.
.macro ALLOC_OBJECT_RESOLVED_TLAB_FAST_PATH slowPathLabel isInitialized
lw $v0, THREAD_LOCAL_POS_OFFSET(rSELF) # Load thread_local_pos.
lw $a2, THREAD_LOCAL_END_OFFSET(rSELF) # Load thread_local_end.
subu $a3, $a2, $v0 # Compute the remaining buffer size.
lw $t0, MIRROR_CLASS_OBJECT_SIZE_ALLOC_FAST_PATH_OFFSET($a0) # Load the object size.
# When isInitialized == 0, then the class is potentially not yet initialized.
# If the class is not yet initialized, the object size will be very large to force the branch
# below to be taken.
#
# See InitializeClassVisitors in class-inl.h for more details.
bgtu $t0, $a3, \slowPathLabel # Check if it fits.
addu $t1, $v0, $t0 # Add object size to tlab pos (in branch
# delay slot).
# "Point of no slow path". Won't go to the slow path from here on.
sw $t1, THREAD_LOCAL_POS_OFFSET(rSELF) # Store new thread_local_pos.
lw $a2, THREAD_LOCAL_OBJECTS_OFFSET(rSELF) # Increment thread_local_objects.
addiu $a2, $a2, 1
sw $a2, THREAD_LOCAL_OBJECTS_OFFSET(rSELF)
POISON_HEAP_REF $a0
sw $a0, MIRROR_OBJECT_CLASS_OFFSET($v0) # Store the class pointer.
.if \isInitialized == 0
# This barrier is only necessary when the allocation also requires a class initialization check.
#
# If the class is already observably initialized, then new-instance allocations are protected
# from publishing by the compiler which inserts its own StoreStore barrier.
sync # Fence.
.endif
jalr $zero, $ra
nop
.endm
// The common code for art_quick_alloc_object_resolved/initialized_tlab
// and art_quick_alloc_object_resolved/initialized_region_tlab.
.macro GENERATE_ALLOC_OBJECT_TLAB name, entrypoint, isInitialized
ENTRY_NO_GP \name
# Fast path tlab allocation.
# a0: type, s1(rSELF): Thread::Current.
ALLOC_OBJECT_RESOLVED_TLAB_FAST_PATH .Lslow_path_\name, \isInitialized
.Lslow_path_\name:
addiu $t9, $t9, (.Lslow_path_\name - \name) + 4
.cpload $t9
SETUP_SAVE_REFS_ONLY_FRAME # Save callee saves in case of GC.
la $t9, \entrypoint
jalr $t9 # (mirror::Class*, Thread*)
move $a1, rSELF # Pass Thread::Current.
RETURN_IF_RESULT_IS_NON_ZERO_OR_DELIVER
END \name
.endm
GENERATE_ALLOC_OBJECT_TLAB art_quick_alloc_object_resolved_region_tlab, artAllocObjectFromCodeResolvedRegionTLAB, /* isInitialized */ 0
GENERATE_ALLOC_OBJECT_TLAB art_quick_alloc_object_initialized_region_tlab, artAllocObjectFromCodeInitializedRegionTLAB, /* isInitialized */ 1
GENERATE_ALLOC_OBJECT_TLAB art_quick_alloc_object_resolved_tlab, artAllocObjectFromCodeResolvedTLAB, /* isInitialized */ 0
GENERATE_ALLOC_OBJECT_TLAB art_quick_alloc_object_initialized_tlab, artAllocObjectFromCodeInitializedTLAB, /* isInitialized */ 1
// The common fast path code for art_quick_alloc_array_resolved/initialized_tlab
// and art_quick_alloc_array_resolved/initialized_region_tlab.
//
// a0: type, a1: component_count, a2: total_size, s1(rSELF): Thread::Current.
// Need to preserve a0 and a1 to the slow path.
.macro ALLOC_ARRAY_TLAB_FAST_PATH_RESOLVED_WITH_SIZE slowPathLabel
li $a3, OBJECT_ALIGNMENT_MASK_TOGGLED # Apply alignemnt mask
and $a2, $a2, $a3 # (addr + 7) & ~7.
lw $v0, THREAD_LOCAL_POS_OFFSET(rSELF) # Load thread_local_pos.
lw $t1, THREAD_LOCAL_END_OFFSET(rSELF) # Load thread_local_end.
subu $t2, $t1, $v0 # Compute the remaining buffer size.
bgtu $a2, $t2, \slowPathLabel # Check if it fits.
addu $a2, $v0, $a2 # Add object size to tlab pos (in branch
# delay slot).
# "Point of no slow path". Won't go to the slow path from here on.
sw $a2, THREAD_LOCAL_POS_OFFSET(rSELF) # Store new thread_local_pos.
lw $a2, THREAD_LOCAL_OBJECTS_OFFSET(rSELF) # Increment thread_local_objects.
addiu $a2, $a2, 1
sw $a2, THREAD_LOCAL_OBJECTS_OFFSET(rSELF)
POISON_HEAP_REF $a0
sw $a0, MIRROR_OBJECT_CLASS_OFFSET($v0) # Store the class pointer.
jalr $zero, $ra
sw $a1, MIRROR_ARRAY_LENGTH_OFFSET($v0) # Store the array length.
.endm
.macro GENERATE_ALLOC_ARRAY_TLAB name, entrypoint, size_setup
ENTRY_NO_GP \name
# Fast path array allocation for region tlab allocation.
# a0: mirror::Class* type
# a1: int32_t component_count
# s1(rSELF): Thread::Current
\size_setup .Lslow_path_\name
ALLOC_ARRAY_TLAB_FAST_PATH_RESOLVED_WITH_SIZE .Lslow_path_\name
.Lslow_path_\name:
# a0: mirror::Class* type
# a1: int32_t component_count
# a2: Thread* self
addiu $t9, $t9, (.Lslow_path_\name - \name) + 4
.cpload $t9
SETUP_SAVE_REFS_ONLY_FRAME # Save callee saves in case of GC.
la $t9, \entrypoint
jalr $t9
move $a2, rSELF # Pass Thread::Current.
RETURN_IF_RESULT_IS_NON_ZERO_OR_DELIVER
END \name
.endm
.macro COMPUTE_ARRAY_SIZE_UNKNOWN slow_path
break # We should never enter here.
# Code below is for reference.
# Possibly a large object, go slow.
# Also does negative array size check.
li $a2, ((MIN_LARGE_OBJECT_THRESHOLD - MIRROR_WIDE_ARRAY_DATA_OFFSET) / 8)
bgtu $a1, $a2, \slow_path
# Array classes are never finalizable
# or uninitialized, no need to check.
lw $a3, MIRROR_CLASS_COMPONENT_TYPE_OFFSET($a0) # Load component type.
UNPOISON_HEAP_REF $a3
lw $a3, MIRROR_CLASS_OBJECT_PRIMITIVE_TYPE_OFFSET($a3)
srl $a3, $a3, PRIMITIVE_TYPE_SIZE_SHIFT_SHIFT # Component size shift is in high 16 bits.
sllv $a2, $a1, $a3 # Calculate data size.
# Add array data offset and alignment.
addiu $a2, $a2, (MIRROR_INT_ARRAY_DATA_OFFSET + OBJECT_ALIGNMENT_MASK)
#if MIRROR_WIDE_ARRAY_DATA_OFFSET != MIRROR_INT_ARRAY_DATA_OFFSET + 4
#error Long array data offset must be 4 greater than int array data offset.
#endif
addiu $a3, $a3, 1 # Add 4 to the length only if the component
andi $a3, $a3, 4 # size shift is 3 (for 64 bit alignment).
addu $a2, $a2, $a3
.endm
.macro COMPUTE_ARRAY_SIZE_8 slow_path
# Possibly a large object, go slow.
# Also does negative array size check.
li $a2, (MIN_LARGE_OBJECT_THRESHOLD - MIRROR_INT_ARRAY_DATA_OFFSET)
bgtu $a1, $a2, \slow_path
# Add array data offset and alignment (in branch delay slot).
addiu $a2, $a1, (MIRROR_INT_ARRAY_DATA_OFFSET + OBJECT_ALIGNMENT_MASK)
.endm
.macro COMPUTE_ARRAY_SIZE_16 slow_path
# Possibly a large object, go slow.
# Also does negative array size check.
li $a2, ((MIN_LARGE_OBJECT_THRESHOLD - MIRROR_INT_ARRAY_DATA_OFFSET) / 2)
bgtu $a1, $a2, \slow_path
sll $a2, $a1, 1
# Add array data offset and alignment.
addiu $a2, $a2, (MIRROR_INT_ARRAY_DATA_OFFSET + OBJECT_ALIGNMENT_MASK)
.endm
.macro COMPUTE_ARRAY_SIZE_32 slow_path
# Possibly a large object, go slow.
# Also does negative array size check.
li $a2, ((MIN_LARGE_OBJECT_THRESHOLD - MIRROR_INT_ARRAY_DATA_OFFSET) / 4)
bgtu $a1, $a2, \slow_path
sll $a2, $a1, 2
# Add array data offset and alignment.
addiu $a2, $a2, (MIRROR_INT_ARRAY_DATA_OFFSET + OBJECT_ALIGNMENT_MASK)
.endm
.macro COMPUTE_ARRAY_SIZE_64 slow_path
# Possibly a large object, go slow.
# Also does negative array size check.
li $a2, ((MIN_LARGE_OBJECT_THRESHOLD - MIRROR_LONG_ARRAY_DATA_OFFSET) / 8)
bgtu $a1, $a2, \slow_path
sll $a2, $a1, 3
# Add array data offset and alignment.
addiu $a2, $a2, (MIRROR_WIDE_ARRAY_DATA_OFFSET + OBJECT_ALIGNMENT_MASK)
.endm
GENERATE_ALLOC_ARRAY_TLAB art_quick_alloc_array_resolved_region_tlab, artAllocArrayFromCodeResolvedRegionTLAB, COMPUTE_ARRAY_SIZE_UNKNOWN
GENERATE_ALLOC_ARRAY_TLAB art_quick_alloc_array_resolved8_region_tlab, artAllocArrayFromCodeResolvedRegionTLAB, COMPUTE_ARRAY_SIZE_8
GENERATE_ALLOC_ARRAY_TLAB art_quick_alloc_array_resolved16_region_tlab, artAllocArrayFromCodeResolvedRegionTLAB, COMPUTE_ARRAY_SIZE_16
GENERATE_ALLOC_ARRAY_TLAB art_quick_alloc_array_resolved32_region_tlab, artAllocArrayFromCodeResolvedRegionTLAB, COMPUTE_ARRAY_SIZE_32
GENERATE_ALLOC_ARRAY_TLAB art_quick_alloc_array_resolved64_region_tlab, artAllocArrayFromCodeResolvedRegionTLAB, COMPUTE_ARRAY_SIZE_64
GENERATE_ALLOC_ARRAY_TLAB art_quick_alloc_array_resolved_tlab, artAllocArrayFromCodeResolvedTLAB, COMPUTE_ARRAY_SIZE_UNKNOWN
GENERATE_ALLOC_ARRAY_TLAB art_quick_alloc_array_resolved8_tlab, artAllocArrayFromCodeResolvedTLAB, COMPUTE_ARRAY_SIZE_8
GENERATE_ALLOC_ARRAY_TLAB art_quick_alloc_array_resolved16_tlab, artAllocArrayFromCodeResolvedTLAB, COMPUTE_ARRAY_SIZE_16
GENERATE_ALLOC_ARRAY_TLAB art_quick_alloc_array_resolved32_tlab, artAllocArrayFromCodeResolvedTLAB, COMPUTE_ARRAY_SIZE_32
GENERATE_ALLOC_ARRAY_TLAB art_quick_alloc_array_resolved64_tlab, artAllocArrayFromCodeResolvedTLAB, COMPUTE_ARRAY_SIZE_64
/*
* Macro for resolution and initialization of indexed DEX file
* constants such as classes and strings. $a0 is both input and
* output.
*/
.macro ONE_ARG_SAVE_EVERYTHING_DOWNCALL name, entrypoint, runtime_method_offset = RUNTIME_SAVE_EVERYTHING_METHOD_OFFSET
.extern \entrypoint
ENTRY_NO_GP \name
SETUP_SAVE_EVERYTHING_FRAME \runtime_method_offset # Save everything in case of GC.
move $s2, $gp # Preserve $gp across the call for exception delivery.
la $t9, \entrypoint
jalr $t9 # (uint32_t index, Thread*)
move $a1, rSELF # Pass Thread::Current (in delay slot).
beqz $v0, 1f # Success?
move $a0, $v0 # Move result to $a0 (in delay slot).
RESTORE_SAVE_EVERYTHING_FRAME 0 # Restore everything except $a0.
jalr $zero, $ra # Return on success.
nop
1:
move $gp, $s2
DELIVER_PENDING_EXCEPTION_FRAME_READY
END \name
.endm
.macro ONE_ARG_SAVE_EVERYTHING_DOWNCALL_FOR_CLINIT name, entrypoint
ONE_ARG_SAVE_EVERYTHING_DOWNCALL \name, \entrypoint, RUNTIME_SAVE_EVERYTHING_FOR_CLINIT_METHOD_OFFSET
.endm
/*
* Entry from managed code to resolve a method handle. On entry, A0 holds the method handle
* index. On success the MethodHandle is returned, otherwise an exception is raised.
*/
ONE_ARG_SAVE_EVERYTHING_DOWNCALL art_quick_resolve_method_handle, artResolveMethodHandleFromCode
/*
* Entry from managed code to resolve a method type. On entry, A0 holds the method type index.
* On success the MethodType is returned, otherwise an exception is raised.
*/
ONE_ARG_SAVE_EVERYTHING_DOWNCALL art_quick_resolve_method_type, artResolveMethodTypeFromCode
/*
* Entry from managed code to resolve a string, this stub will allocate a String and deliver an
* exception on error. On success the String is returned. A0 holds the string index. The fast
* path check for hit in strings cache has already been performed.
*/
ONE_ARG_SAVE_EVERYTHING_DOWNCALL art_quick_resolve_string, artResolveStringFromCode
/*
* Entry from managed code when uninitialized static storage, this stub will run the class
* initializer and deliver the exception on error. On success the static storage base is
* returned.
*/
ONE_ARG_SAVE_EVERYTHING_DOWNCALL_FOR_CLINIT art_quick_initialize_static_storage, artInitializeStaticStorageFromCode
/*
* Entry from managed code when dex cache misses for a type_idx.
*/
ONE_ARG_SAVE_EVERYTHING_DOWNCALL_FOR_CLINIT art_quick_resolve_type, artResolveTypeFromCode
/*
* Entry from managed code when type_idx needs to be checked for access and dex cache may also
* miss.
*/
ONE_ARG_SAVE_EVERYTHING_DOWNCALL art_quick_resolve_type_and_verify_access, artResolveTypeAndVerifyAccessFromCode
/*
* Called by managed code when the value in rSUSPEND has been decremented to 0.
*/
.extern artTestSuspendFromCode
ENTRY_NO_GP art_quick_test_suspend
SETUP_SAVE_EVERYTHING_FRAME RUNTIME_SAVE_EVERYTHING_FOR_SUSPEND_CHECK_METHOD_OFFSET
# save everything for stack crawl
la $t9, artTestSuspendFromCode
jalr $t9 # (Thread*)
move $a0, rSELF
RESTORE_SAVE_EVERYTHING_FRAME
jalr $zero, $ra
nop
END art_quick_test_suspend
/*
* Called by managed code that is attempting to call a method on a proxy class. On entry
* a0 holds the proxy method; a1, a2 and a3 may contain arguments.
*/
.extern artQuickProxyInvokeHandler
ENTRY art_quick_proxy_invoke_handler
SETUP_SAVE_REFS_AND_ARGS_FRAME_WITH_METHOD_IN_A0
move $a2, rSELF # pass Thread::Current
la $t9, artQuickProxyInvokeHandler
jalr $t9 # (Method* proxy method, receiver, Thread*, SP)
addiu $a3, $sp, ARG_SLOT_SIZE # pass $sp (remove arg slots)
lw $t7, THREAD_EXCEPTION_OFFSET(rSELF) # load Thread::Current()->exception_
RESTORE_SAVE_REFS_AND_ARGS_FRAME
bnez $t7, 1f
# don't care if $v0 and/or $v1 are modified, when exception branch taken
MTD $v0, $v1, $f0, $f1 # move float value to return value
jalr $zero, $ra
nop
1:
DELIVER_PENDING_EXCEPTION
END art_quick_proxy_invoke_handler
/*
* Called to resolve an imt conflict.
* a0 is the conflict ArtMethod.
* t7 is a hidden argument that holds the target interface method's dex method index.
*
* Note that this stub writes to v0-v1, a0, t2-t9, f0-f7.
*/
.extern artLookupResolvedMethod
.extern __atomic_load_8 # For int64_t std::atomic::load(std::memory_order).
ENTRY art_quick_imt_conflict_trampoline
SETUP_SAVE_REFS_AND_ARGS_FRAME_REGISTERS_ONLY /* save_s4_thru_s8 */ 0
lw $t8, FRAME_SIZE_SAVE_REFS_AND_ARGS($sp) # $t8 = referrer.
// If the method is obsolete, just go through the dex cache miss slow path.
// The obsolete flag is set with suspended threads, so we do not need an acquire operation here.
lw $t9, ART_METHOD_ACCESS_FLAGS_OFFSET($t8) # $t9 = access flags.
sll $t9, $t9, 31 - ACC_OBSOLETE_METHOD_SHIFT # Move obsolete method bit to sign bit.
bltz $t9, .Limt_conflict_trampoline_dex_cache_miss
lw $t8, ART_METHOD_DECLARING_CLASS_OFFSET($t8) # $t8 = declaring class (no read barrier).
lw $t8, MIRROR_CLASS_DEX_CACHE_OFFSET($t8) # $t8 = dex cache (without read barrier).
UNPOISON_HEAP_REF $t8
la $t9, __atomic_load_8
addiu $sp, $sp, -ARG_SLOT_SIZE # Reserve argument slots on the stack.
.cfi_adjust_cfa_offset ARG_SLOT_SIZE
lw $t8, MIRROR_DEX_CACHE_RESOLVED_METHODS_OFFSET($t8) # $t8 = dex cache methods array.
move $s2, $t7 # $s2 = method index (callee-saved).
lw $s3, ART_METHOD_JNI_OFFSET_32($a0) # $s3 = ImtConflictTable (callee-saved).
sll $t7, $t7, 32 - METHOD_DEX_CACHE_HASH_BITS # $t7 = slot index in top bits, zeroes below.
srl $t7, $t7, 32 - METHOD_DEX_CACHE_HASH_BITS - (POINTER_SIZE_SHIFT + 1)
# $t7 = slot offset.
li $a1, STD_MEMORY_ORDER_RELAXED # $a1 = std::memory_order_relaxed.
jalr $t9 # [$v0, $v1] = __atomic_load_8($a0, $a1).
addu $a0, $t8, $t7 # $a0 = DexCache method slot address.
bne $v1, $s2, .Limt_conflict_trampoline_dex_cache_miss # Branch if method index miss.
addiu $sp, $sp, ARG_SLOT_SIZE # Remove argument slots from the stack.
.cfi_adjust_cfa_offset -ARG_SLOT_SIZE
.Limt_table_iterate:
lw $t8, 0($s3) # Load next entry in ImtConflictTable.
# Branch if found.
beq $t8, $v0, .Limt_table_found
nop
# If the entry is null, the interface method is not in the ImtConflictTable.
beqz $t8, .Lconflict_trampoline
nop
# Iterate over the entries of the ImtConflictTable.
b .Limt_table_iterate
addiu $s3, $s3, 2 * __SIZEOF_POINTER__ # Iterate to the next entry.
.Limt_table_found:
# We successfully hit an entry in the table. Load the target method and jump to it.
.cfi_remember_state
lw $a0, __SIZEOF_POINTER__($s3)
lw $t9, ART_METHOD_QUICK_CODE_OFFSET_32($a0)
RESTORE_SAVE_REFS_AND_ARGS_FRAME /* restore_s4_thru_s8 */ 0, /* remove_arg_slots */ 0
jalr $zero, $t9
nop
.cfi_restore_state
.Lconflict_trampoline:
# Call the runtime stub to populate the ImtConflictTable and jump to the resolved method.
.cfi_remember_state
RESTORE_SAVE_REFS_AND_ARGS_FRAME_GP # Restore clobbered $gp.
RESTORE_SAVE_REFS_AND_ARGS_FRAME_A1 # Restore this.
move $a0, $v0 # Load interface method.
INVOKE_TRAMPOLINE_BODY artInvokeInterfaceTrampoline, /* save_s4_thru_s8_only */ 1
.cfi_restore_state
.Limt_conflict_trampoline_dex_cache_miss:
# We're not creating a proper runtime method frame here,
# artLookupResolvedMethod() is not allowed to walk the stack.
RESTORE_SAVE_REFS_AND_ARGS_FRAME_GP # Restore clobbered $gp.
lw $a1, FRAME_SIZE_SAVE_REFS_AND_ARGS($sp) # $a1 = referrer.
la $t9, artLookupResolvedMethod
addiu $sp, $sp, -ARG_SLOT_SIZE # Reserve argument slots on the stack.
.cfi_adjust_cfa_offset ARG_SLOT_SIZE
jalr $t9 # (uint32_t method_index, ArtMethod* referrer).
move $a0, $s2 # $a0 = method index.
# If the method wasn't resolved, skip the lookup and go to artInvokeInterfaceTrampoline().
beqz $v0, .Lconflict_trampoline
addiu $sp, $sp, ARG_SLOT_SIZE # Remove argument slots from the stack.
.cfi_adjust_cfa_offset -ARG_SLOT_SIZE
b .Limt_table_iterate
nop
END art_quick_imt_conflict_trampoline
.extern artQuickResolutionTrampoline
ENTRY art_quick_resolution_trampoline
SETUP_SAVE_REFS_AND_ARGS_FRAME
move $a2, rSELF # pass Thread::Current
la $t9, artQuickResolutionTrampoline
jalr $t9 # (Method* called, receiver, Thread*, SP)
addiu $a3, $sp, ARG_SLOT_SIZE # pass $sp (remove arg slots)
beqz $v0, 1f
lw $a0, ARG_SLOT_SIZE($sp) # load resolved method to $a0
RESTORE_SAVE_REFS_AND_ARGS_FRAME
move $t9, $v0 # code pointer must be in $t9 to generate the global pointer
jalr $zero, $t9 # tail call to method
nop
1:
RESTORE_SAVE_REFS_AND_ARGS_FRAME
DELIVER_PENDING_EXCEPTION
END art_quick_resolution_trampoline
.extern artQuickGenericJniTrampoline
.extern artQuickGenericJniEndTrampoline
ENTRY art_quick_generic_jni_trampoline
SETUP_SAVE_REFS_AND_ARGS_FRAME_WITH_METHOD_IN_A0
move $s8, $sp # save $sp to $s8
move $s3, $gp # save $gp to $s3
# prepare for call to artQuickGenericJniTrampoline(Thread*, SP)
move $a0, rSELF # pass Thread::Current
addiu $a1, $sp, ARG_SLOT_SIZE # save $sp (remove arg slots)
la $t9, artQuickGenericJniTrampoline
jalr $t9 # (Thread*, SP)
addiu $sp, $sp, -5120 # reserve space on the stack
# The C call will have registered the complete save-frame on success.
# The result of the call is:
# v0: ptr to native code, 0 on error.
# v1: ptr to the bottom of the used area of the alloca, can restore stack till here.
beq $v0, $zero, 2f # check entry error
move $t9, $v0 # save the code ptr
move $sp, $v1 # release part of the alloca
# Load parameters from stack into registers
lw $a0, 0($sp)
lw $a1, 4($sp)
lw $a2, 8($sp)
lw $a3, 12($sp)
# artQuickGenericJniTrampoline sets bit 0 of the native code address to 1
# when the first two arguments are both single precision floats. This lets
# us extract them properly from the stack and load into floating point
# registers.
MTD $a0, $a1, $f12, $f13
andi $t0, $t9, 1
xor $t9, $t9, $t0
bnez $t0, 1f
mtc1 $a1, $f14
MTD $a2, $a3, $f14, $f15
1:
jalr $t9 # native call
nop
addiu $sp, $sp, 16 # remove arg slots
move $gp, $s3 # restore $gp from $s3
# result sign extension is handled in C code
# prepare for call to artQuickGenericJniEndTrampoline(Thread*, result, result_f)
move $a0, rSELF # pass Thread::Current
move $a2, $v0 # pass result
move $a3, $v1
addiu $sp, $sp, -32 # reserve arg slots
la $t9, artQuickGenericJniEndTrampoline
jalr $t9
s.d $f0, 16($sp) # pass result_f
lw $t0, THREAD_EXCEPTION_OFFSET(rSELF) # load Thread::Current()->exception_
bne $t0, $zero, 2f # check for pending exceptions
move $sp, $s8 # tear down the alloca
# tear down the callee-save frame
RESTORE_SAVE_REFS_AND_ARGS_FRAME
MTD $v0, $v1, $f0, $f1 # move float value to return value
jalr $zero, $ra
nop
2:
lw $t0, THREAD_TOP_QUICK_FRAME_OFFSET(rSELF)
addiu $sp, $t0, -1 // Remove the GenericJNI tag.
move $gp, $s3 # restore $gp from $s3
# This will create a new save-all frame, required by the runtime.
DELIVER_PENDING_EXCEPTION
END art_quick_generic_jni_trampoline
.extern artQuickToInterpreterBridge
ENTRY art_quick_to_interpreter_bridge
SETUP_SAVE_REFS_AND_ARGS_FRAME
move $a1, rSELF # pass Thread::Current
la $t9, artQuickToInterpreterBridge
jalr $t9 # (Method* method, Thread*, SP)
addiu $a2, $sp, ARG_SLOT_SIZE # pass $sp (remove arg slots)
lw $t7, THREAD_EXCEPTION_OFFSET(rSELF) # load Thread::Current()->exception_
RESTORE_SAVE_REFS_AND_ARGS_FRAME
bnez $t7, 1f
# don't care if $v0 and/or $v1 are modified, when exception branch taken
MTD $v0, $v1, $f0, $f1 # move float value to return value
jalr $zero, $ra
nop
1:
DELIVER_PENDING_EXCEPTION
END art_quick_to_interpreter_bridge
.extern artInvokeObsoleteMethod
ENTRY art_invoke_obsolete_method_stub
SETUP_SAVE_ALL_CALLEE_SAVES_FRAME
la $t9, artInvokeObsoleteMethod
jalr $t9 # (Method* method, Thread* self)
move $a1, rSELF # pass Thread::Current
END art_invoke_obsolete_method_stub
/*
* Routine that intercepts method calls and returns.
*/
.extern artInstrumentationMethodEntryFromCode
.extern artInstrumentationMethodExitFromCode
ENTRY art_quick_instrumentation_entry
SETUP_SAVE_REFS_AND_ARGS_FRAME
sw $a0, 28($sp) # save arg0 in free arg slot
addiu $a3, $sp, ARG_SLOT_SIZE # Pass $sp.
la $t9, artInstrumentationMethodEntryFromCode
jalr $t9 # (Method*, Object*, Thread*, SP)
move $a2, rSELF # pass Thread::Current
beqz $v0, .Ldeliver_instrumentation_entry_exception
move $t9, $v0 # $t9 holds reference to code
lw $a0, 28($sp) # restore arg0 from free arg slot
RESTORE_SAVE_REFS_AND_ARGS_FRAME
la $ra, art_quick_instrumentation_exit
jalr $zero, $t9 # call method, returning to art_quick_instrumentation_exit
nop
.Ldeliver_instrumentation_entry_exception:
RESTORE_SAVE_REFS_AND_ARGS_FRAME
DELIVER_PENDING_EXCEPTION
END art_quick_instrumentation_entry
ENTRY_NO_GP art_quick_instrumentation_exit
move $ra, $zero # RA points here, so clobber with 0 for later checks.
SETUP_SAVE_EVERYTHING_FRAME # Allocates ARG_SLOT_SIZE bytes at the bottom of the stack.
move $s2, $gp # Preserve $gp across the call for exception delivery.
addiu $a3, $sp, ARG_SLOT_SIZE+16 # Pass fpr_res pointer ($f0 in SAVE_EVERYTHING_FRAME).
addiu $a2, $sp, ARG_SLOT_SIZE+148 # Pass gpr_res pointer ($v0 in SAVE_EVERYTHING_FRAME).
addiu $a1, $sp, ARG_SLOT_SIZE # Pass $sp.
la $t9, artInstrumentationMethodExitFromCode
jalr $t9 # (Thread*, SP, gpr_res*, fpr_res*)
move $a0, rSELF # Pass Thread::Current.
beqz $v0, .Ldo_deliver_instrumentation_exception
move $gp, $s2 # Deliver exception if we got nullptr as function.
bnez $v1, .Ldeoptimize
# Normal return.
sw $v0, (ARG_SLOT_SIZE+FRAME_SIZE_SAVE_EVERYTHING-4)($sp) # Set return pc.
RESTORE_SAVE_EVERYTHING_FRAME
jalr $zero, $ra
nop
.Ldo_deliver_instrumentation_exception:
DELIVER_PENDING_EXCEPTION_FRAME_READY
.Ldeoptimize:
b art_quick_deoptimize
sw $v1, (ARG_SLOT_SIZE+FRAME_SIZE_SAVE_EVERYTHING-4)($sp)
# Fake a call from instrumentation return pc.
END art_quick_instrumentation_exit
/*
* Instrumentation has requested that we deoptimize into the interpreter. The deoptimization
* will long jump to the upcall with a special exception of -1.
*/
.extern artDeoptimize
ENTRY_NO_GP_CUSTOM_CFA art_quick_deoptimize, ARG_SLOT_SIZE+FRAME_SIZE_SAVE_EVERYTHING
# SETUP_SAVE_EVERYTHING_FRAME has been done by art_quick_instrumentation_exit.
.cfi_rel_offset 31, ARG_SLOT_SIZE+252
.cfi_rel_offset 30, ARG_SLOT_SIZE+248
.cfi_rel_offset 28, ARG_SLOT_SIZE+244
.cfi_rel_offset 25, ARG_SLOT_SIZE+240
.cfi_rel_offset 24, ARG_SLOT_SIZE+236
.cfi_rel_offset 23, ARG_SLOT_SIZE+232
.cfi_rel_offset 22, ARG_SLOT_SIZE+228
.cfi_rel_offset 21, ARG_SLOT_SIZE+224
.cfi_rel_offset 20, ARG_SLOT_SIZE+220
.cfi_rel_offset 19, ARG_SLOT_SIZE+216
.cfi_rel_offset 18, ARG_SLOT_SIZE+212
.cfi_rel_offset 17, ARG_SLOT_SIZE+208
.cfi_rel_offset 16, ARG_SLOT_SIZE+204
.cfi_rel_offset 15, ARG_SLOT_SIZE+200
.cfi_rel_offset 14, ARG_SLOT_SIZE+196
.cfi_rel_offset 13, ARG_SLOT_SIZE+192
.cfi_rel_offset 12, ARG_SLOT_SIZE+188
.cfi_rel_offset 11, ARG_SLOT_SIZE+184
.cfi_rel_offset 10, ARG_SLOT_SIZE+180
.cfi_rel_offset 9, ARG_SLOT_SIZE+176
.cfi_rel_offset 8, ARG_SLOT_SIZE+172
.cfi_rel_offset 7, ARG_SLOT_SIZE+168
.cfi_rel_offset 6, ARG_SLOT_SIZE+164
.cfi_rel_offset 5, ARG_SLOT_SIZE+160
.cfi_rel_offset 4, ARG_SLOT_SIZE+156
.cfi_rel_offset 3, ARG_SLOT_SIZE+152
.cfi_rel_offset 2, ARG_SLOT_SIZE+148
.cfi_rel_offset 1, ARG_SLOT_SIZE+144
la $t9, artDeoptimize
jalr $t9 # (Thread*)
move $a0, rSELF # pass Thread::current
break
END art_quick_deoptimize
/*
* Compiled code has requested that we deoptimize into the interpreter. The deoptimization
* will long jump to the upcall with a special exception of -1.
*/
.extern artDeoptimizeFromCompiledCode
ENTRY_NO_GP art_quick_deoptimize_from_compiled_code
SETUP_SAVE_EVERYTHING_FRAME
la $t9, artDeoptimizeFromCompiledCode
jalr $t9 # (DeoptimizationKind, Thread*)
move $a1, rSELF # pass Thread::current
END art_quick_deoptimize_from_compiled_code
/*
* Long integer shift. This is different from the generic 32/64-bit
* binary operations because vAA/vBB are 64-bit but vCC (the shift
* distance) is 32-bit. Also, Dalvik requires us to ignore all but the low
* 6 bits.
* On entry:
* $a0: low word
* $a1: high word
* $a2: shift count
*/
ENTRY_NO_GP art_quick_shl_long
/* shl-long vAA, vBB, vCC */
sll $v0, $a0, $a2 # rlo<- alo << (shift&31)
not $v1, $a2 # rhi<- 31-shift (shift is 5b)
srl $a0, 1
srl $a0, $v1 # alo<- alo >> (32-(shift&31))
sll $v1, $a1, $a2 # rhi<- ahi << (shift&31)
andi $a2, 0x20 # shift< shift & 0x20
beqz $a2, 1f
or $v1, $a0 # rhi<- rhi | alo
move $v1, $v0 # rhi<- rlo (if shift&0x20)
move $v0, $zero # rlo<- 0 (if shift&0x20)
1: jalr $zero, $ra
nop
END art_quick_shl_long
/*
* Long integer shift. This is different from the generic 32/64-bit
* binary operations because vAA/vBB are 64-bit but vCC (the shift
* distance) is 32-bit. Also, Dalvik requires us to ignore all but the low
* 6 bits.
* On entry:
* $a0: low word
* $a1: high word
* $a2: shift count
*/
ENTRY_NO_GP art_quick_shr_long
sra $v1, $a1, $a2 # rhi<- ahi >> (shift&31)
srl $v0, $a0, $a2 # rlo<- alo >> (shift&31)
sra $a3, $a1, 31 # $a3<- sign(ah)
not $a0, $a2 # alo<- 31-shift (shift is 5b)
sll $a1, 1
sll $a1, $a0 # ahi<- ahi << (32-(shift&31))
andi $a2, 0x20 # shift & 0x20
beqz $a2, 1f
or $v0, $a1 # rlo<- rlo | ahi
move $v0, $v1 # rlo<- rhi (if shift&0x20)
move $v1, $a3 # rhi<- sign(ahi) (if shift&0x20)
1: jalr $zero, $ra
nop
END art_quick_shr_long
/*
* Long integer shift. This is different from the generic 32/64-bit
* binary operations because vAA/vBB are 64-bit but vCC (the shift
* distance) is 32-bit. Also, Dalvik requires us to ignore all but the low
* 6 bits.
* On entry:
* $a0: low word
* $a1: high word
* $a2: shift count
*/
/* ushr-long vAA, vBB, vCC */
ENTRY_NO_GP art_quick_ushr_long
srl $v1, $a1, $a2 # rhi<- ahi >> (shift&31)
srl $v0, $a0, $a2 # rlo<- alo >> (shift&31)
not $a0, $a2 # alo<- 31-shift (shift is 5b)
sll $a1, 1
sll $a1, $a0 # ahi<- ahi << (32-(shift&31))
andi $a2, 0x20 # shift & 0x20
beqz $a2, 1f
or $v0, $a1 # rlo<- rlo | ahi
move $v0, $v1 # rlo<- rhi (if shift&0x20)
move $v1, $zero # rhi<- 0 (if shift&0x20)
1: jalr $zero, $ra
nop
END art_quick_ushr_long
/* java.lang.String.indexOf(int ch, int fromIndex=0) */
ENTRY_NO_GP art_quick_indexof
/* $a0 holds address of "this" */
/* $a1 holds "ch" */
/* $a2 holds "fromIndex" */
#if (STRING_COMPRESSION_FEATURE)
lw $a3, MIRROR_STRING_COUNT_OFFSET($a0) # 'count' field of this
#else
lw $t0, MIRROR_STRING_COUNT_OFFSET($a0) # this.length()
#endif
slt $t1, $a2, $zero # if fromIndex < 0
#if defined(_MIPS_ARCH_MIPS32R6)
seleqz $a2, $a2, $t1 # fromIndex = 0;
#else
movn $a2, $zero, $t1 # fromIndex = 0;
#endif
#if (STRING_COMPRESSION_FEATURE)
srl $t0, $a3, 1 # $a3 holds count (with flag) and $t0 holds actual length
#endif
subu $t0, $t0, $a2 # this.length() - fromIndex
blez $t0, 6f # if this.length()-fromIndex <= 0
li $v0, -1 # return -1;
#if (STRING_COMPRESSION_FEATURE)
sll $a3, $a3, 31 # Extract compression flag.
beqz $a3, .Lstring_indexof_compressed
move $t2, $a0 # Save a copy in $t2 to later compute result (in branch delay slot).
#endif
sll $v0, $a2, 1 # $a0 += $a2 * 2
addu $a0, $a0, $v0 # " ditto "
move $v0, $a2 # Set i to fromIndex.
1:
lhu $t3, MIRROR_STRING_VALUE_OFFSET($a0) # if this.charAt(i) == ch
beq $t3, $a1, 6f # return i;
addu $a0, $a0, 2 # i++
subu $t0, $t0, 1 # this.length() - i
bnez $t0, 1b # while this.length() - i > 0
addu $v0, $v0, 1 # i++
li $v0, -1 # if this.length() - i <= 0
# return -1;
6:
j $ra
nop
#if (STRING_COMPRESSION_FEATURE)
.Lstring_indexof_compressed:
addu $a0, $a0, $a2 # $a0 += $a2
.Lstring_indexof_compressed_loop:
lbu $t3, MIRROR_STRING_VALUE_OFFSET($a0)
beq $t3, $a1, .Lstring_indexof_compressed_matched
subu $t0, $t0, 1
bgtz $t0, .Lstring_indexof_compressed_loop
addu $a0, $a0, 1
.Lstring_indexof_nomatch:
jalr $zero, $ra
li $v0, -1 # return -1;
.Lstring_indexof_compressed_matched:
jalr $zero, $ra
subu $v0, $a0, $t2 # return (current - start);
#endif
END art_quick_indexof
/* java.lang.String.compareTo(String anotherString) */
ENTRY_NO_GP art_quick_string_compareto
/* $a0 holds address of "this" */
/* $a1 holds address of "anotherString" */
beq $a0, $a1, .Lstring_compareto_length_diff # this and anotherString are the same object
move $a3, $a2 # trick to return 0 (it returns a2 - a3)
#if (STRING_COMPRESSION_FEATURE)
lw $t0, MIRROR_STRING_COUNT_OFFSET($a0) # 'count' field of this
lw $t1, MIRROR_STRING_COUNT_OFFSET($a1) # 'count' field of anotherString
sra $a2, $t0, 1 # this.length()
sra $a3, $t1, 1 # anotherString.length()
#else
lw $a2, MIRROR_STRING_COUNT_OFFSET($a0) # this.length()
lw $a3, MIRROR_STRING_COUNT_OFFSET($a1) # anotherString.length()
#endif
MINu $t2, $a2, $a3
# $t2 now holds min(this.length(),anotherString.length())
# while min(this.length(),anotherString.length())-i != 0
beqz $t2, .Lstring_compareto_length_diff # if $t2==0
nop # return (this.length() - anotherString.length())
#if (STRING_COMPRESSION_FEATURE)
# Differ cases:
sll $t3, $t0, 31
beqz $t3, .Lstring_compareto_this_is_compressed
sll $t3, $t1, 31 # In branch delay slot.
beqz $t3, .Lstring_compareto_that_is_compressed
nop
b .Lstring_compareto_both_not_compressed
nop
.Lstring_compareto_this_is_compressed:
beqz $t3, .Lstring_compareto_both_compressed
nop
/* If (this->IsCompressed() && that->IsCompressed() == false) */
.Lstring_compareto_loop_comparison_this_compressed:
lbu $t0, MIRROR_STRING_VALUE_OFFSET($a0)
lhu $t1, MIRROR_STRING_VALUE_OFFSET($a1)
bne $t0, $t1, .Lstring_compareto_char_diff
addiu $a0, $a0, 1 # point at this.charAt(i++) - compressed
subu $t2, $t2, 1 # new value of min(this.length(),anotherString.length())-i
bnez $t2, .Lstring_compareto_loop_comparison_this_compressed
addiu $a1, $a1, 2 # point at anotherString.charAt(i++) - uncompressed
jalr $zero, $ra
subu $v0, $a2, $a3 # return (this.length() - anotherString.length())
.Lstring_compareto_that_is_compressed:
lhu $t0, MIRROR_STRING_VALUE_OFFSET($a0)
lbu $t1, MIRROR_STRING_VALUE_OFFSET($a1)
bne $t0, $t1, .Lstring_compareto_char_diff
addiu $a0, $a0, 2 # point at this.charAt(i++) - uncompressed
subu $t2, $t2, 1 # new value of min(this.length(),anotherString.length())-i
bnez $t2, .Lstring_compareto_that_is_compressed
addiu $a1, $a1, 1 # point at anotherString.charAt(i++) - compressed
jalr $zero, $ra
subu $v0, $a2, $a3 # return (this.length() - anotherString.length())
.Lstring_compareto_both_compressed:
lbu $t0, MIRROR_STRING_VALUE_OFFSET($a0)
lbu $t1, MIRROR_STRING_VALUE_OFFSET($a1)
bne $t0, $t1, .Lstring_compareto_char_diff
addiu $a0, $a0, 1 # point at this.charAt(i++) - compressed
subu $t2, $t2, 1 # new value of min(this.length(),anotherString.length())-i
bnez $t2, .Lstring_compareto_both_compressed
addiu $a1, $a1, 1 # point at anotherString.charAt(i++) - compressed
jalr $zero, $ra
subu $v0, $a2, $a3 # return (this.length() - anotherString.length())
#endif
.Lstring_compareto_both_not_compressed:
lhu $t0, MIRROR_STRING_VALUE_OFFSET($a0) # while this.charAt(i) == anotherString.charAt(i)
lhu $t1, MIRROR_STRING_VALUE_OFFSET($a1)
bne $t0, $t1, .Lstring_compareto_char_diff # if this.charAt(i) != anotherString.charAt(i)
# return (this.charAt(i) - anotherString.charAt(i))
addiu $a0, $a0, 2 # point at this.charAt(i++)
subu $t2, $t2, 1 # new value of min(this.length(),anotherString.length())-i
bnez $t2, .Lstring_compareto_both_not_compressed
addiu $a1, $a1, 2 # point at anotherString.charAt(i++)
.Lstring_compareto_length_diff:
jalr $zero, $ra
subu $v0, $a2, $a3 # return (this.length() - anotherString.length())
.Lstring_compareto_char_diff:
jalr $zero, $ra
subu $v0, $t0, $t1 # return (this.charAt(i) - anotherString.charAt(i))
END art_quick_string_compareto
/*
* Create a function `name` calling the ReadBarrier::Mark routine,
* getting its argument and returning its result through register
* `reg`, saving and restoring all caller-save registers.
*/
.macro READ_BARRIER_MARK_REG name, reg
ENTRY \name
// Null check so that we can load the lock word.
bnez \reg, .Lnot_null_\name
nop
.Lret_rb_\name:
jalr $zero, $ra
nop
.Lnot_null_\name:
// Check lock word for mark bit, if marked return.
lw $t9, MIRROR_OBJECT_LOCK_WORD_OFFSET(\reg)
.set push
.set noat
sll $at, $t9, 31 - LOCK_WORD_MARK_BIT_SHIFT # Move mark bit to sign bit.
bltz $at, .Lret_rb_\name
#if (LOCK_WORD_STATE_SHIFT != 30) || (LOCK_WORD_STATE_FORWARDING_ADDRESS != 3)
// The below code depends on the lock word state being in the highest bits
// and the "forwarding address" state having all bits set.
#error "Unexpected lock word state shift or forwarding address state value."
#endif
// Test that both the forwarding state bits are 1.
sll $at, $t9, 1
and $at, $at, $t9 # Sign bit = 1 IFF both bits are 1.
bltz $at, .Lret_forwarding_address\name
nop
.set pop
addiu $sp, $sp, -160 # Includes 16 bytes of space for argument registers a0-a3.
.cfi_adjust_cfa_offset 160
sw $ra, 156($sp)
.cfi_rel_offset 31, 156
sw $t8, 152($sp)
.cfi_rel_offset 24, 152
sw $t7, 148($sp)
.cfi_rel_offset 15, 148
sw $t6, 144($sp)
.cfi_rel_offset 14, 144
sw $t5, 140($sp)
.cfi_rel_offset 13, 140
sw $t4, 136($sp)
.cfi_rel_offset 12, 136
sw $t3, 132($sp)
.cfi_rel_offset 11, 132
sw $t2, 128($sp)
.cfi_rel_offset 10, 128
sw $t1, 124($sp)
.cfi_rel_offset 9, 124
sw $t0, 120($sp)
.cfi_rel_offset 8, 120
sw $a3, 116($sp)
.cfi_rel_offset 7, 116
sw $a2, 112($sp)
.cfi_rel_offset 6, 112
sw $a1, 108($sp)
.cfi_rel_offset 5, 108
sw $a0, 104($sp)
.cfi_rel_offset 4, 104
sw $v1, 100($sp)
.cfi_rel_offset 3, 100
sw $v0, 96($sp)
.cfi_rel_offset 2, 96
la $t9, artReadBarrierMark
sdc1 $f18, 88($sp)
sdc1 $f16, 80($sp)
sdc1 $f14, 72($sp)
sdc1 $f12, 64($sp)
sdc1 $f10, 56($sp)
sdc1 $f8, 48($sp)
sdc1 $f6, 40($sp)
sdc1 $f4, 32($sp)
sdc1 $f2, 24($sp)
.ifnc \reg, $a0
move $a0, \reg # pass obj from `reg` in a0
.endif
jalr $t9 # v0 <- artReadBarrierMark(obj)
sdc1 $f0, 16($sp) # in delay slot
lw $ra, 156($sp)
.cfi_restore 31
lw $t8, 152($sp)
.cfi_restore 24
lw $t7, 148($sp)
.cfi_restore 15
lw $t6, 144($sp)
.cfi_restore 14
lw $t5, 140($sp)
.cfi_restore 13
lw $t4, 136($sp)
.cfi_restore 12
lw $t3, 132($sp)
.cfi_restore 11
lw $t2, 128($sp)
.cfi_restore 10
lw $t1, 124($sp)
.cfi_restore 9
lw $t0, 120($sp)
.cfi_restore 8
lw $a3, 116($sp)
.cfi_restore 7
lw $a2, 112($sp)
.cfi_restore 6
lw $a1, 108($sp)
.cfi_restore 5
lw $a0, 104($sp)
.cfi_restore 4
lw $v1, 100($sp)
.cfi_restore 3
.ifnc \reg, $v0
move \reg, $v0 # `reg` <- v0
lw $v0, 96($sp)
.cfi_restore 2
.endif
ldc1 $f18, 88($sp)
ldc1 $f16, 80($sp)
ldc1 $f14, 72($sp)
ldc1 $f12, 64($sp)
ldc1 $f10, 56($sp)
ldc1 $f8, 48($sp)
ldc1 $f6, 40($sp)
ldc1 $f4, 32($sp)
ldc1 $f2, 24($sp)
ldc1 $f0, 16($sp)
jalr $zero, $ra
addiu $sp, $sp, 160
.cfi_adjust_cfa_offset -160
.Lret_forwarding_address\name:
jalr $zero, $ra
// Shift left by the forwarding address shift. This clears out the state bits since they are
// in the top 2 bits of the lock word.
sll \reg, $t9, LOCK_WORD_STATE_FORWARDING_ADDRESS_SHIFT
END \name
.endm
// Note that art_quick_read_barrier_mark_regXX corresponds to register XX+1.
// ZERO (register 0) is reserved.
// AT (register 1) is reserved as a temporary/scratch register.
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg01, $v0
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg02, $v1
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg03, $a0
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg04, $a1
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg05, $a2
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg06, $a3
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg07, $t0
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg08, $t1
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg09, $t2
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg10, $t3
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg11, $t4
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg12, $t5
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg13, $t6
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg14, $t7
// S0 and S1 (registers 16 and 17) are reserved as suspended and thread registers.
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg17, $s2
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg18, $s3
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg19, $s4
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg20, $s5
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg21, $s6
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg22, $s7
// T8 and T9 (registers 24 and 25) are reserved as temporary/scratch registers.
// K0, K1, GP, SP (registers 26 - 29) are reserved.
READ_BARRIER_MARK_REG art_quick_read_barrier_mark_reg29, $s8
// RA (register 31) is reserved.
// Caller code:
// Short constant offset/index:
// R2: | R6:
// lw $t9, pReadBarrierMarkReg00
// beqz $t9, skip_call | beqzc $t9, skip_call
// addiu $t9, $t9, thunk_disp | nop
// jalr $t9 | jialc $t9, thunk_disp
// nop |
// skip_call: | skip_call:
// lw `out`, ofs(`obj`) | lw `out`, ofs(`obj`)
// [subu `out`, $zero, `out`] | [subu `out`, $zero, `out`] # Unpoison reference.
.macro BRB_FIELD_SHORT_OFFSET_ENTRY obj
1:
# Explicit null check. May be redundant (for array elements or when the field
# offset is larger than the page size, 4KB).
# $ra will be adjusted to point to lw's stack map when throwing NPE.
beqz \obj, .Lintrospection_throw_npe
#if defined(_MIPS_ARCH_MIPS32R6)
lapc $gp, .Lintrospection_exits # $gp = address of .Lintrospection_exits.
#else
addiu $gp, $t9, (.Lintrospection_exits - 1b) # $gp = address of .Lintrospection_exits.
#endif
.set push
.set noat
lw $at, MIRROR_OBJECT_LOCK_WORD_OFFSET(\obj)
sll $at, $at, 31 - LOCK_WORD_READ_BARRIER_STATE_SHIFT # Move barrier state bit
# to sign bit.
bltz $at, .Lintrospection_field_array # If gray, load reference, mark.
move $t8, \obj # Move `obj` to $t8 for common code.
.set pop
jalr $zero, $ra # Otherwise, load-load barrier and return.
sync
.endm
// Caller code (R2):
// Long constant offset/index: | Variable index:
// lw $t9, pReadBarrierMarkReg00
// lui $t8, ofs_hi | sll $t8, `index`, 2
// beqz $t9, skip_call | beqz $t9, skip_call
// addiu $t9, $t9, thunk_disp | addiu $t9, $t9, thunk_disp
// jalr $t9 | jalr $t9
// skip_call: | skip_call:
// addu $t8, $t8, `obj` | addu $t8, $t8, `obj`
// lw `out`, ofs_lo($t8) | lw `out`, ofs($t8)
// [subu `out`, $zero, `out`] | [subu `out`, $zero, `out`] # Unpoison reference.
//
// Caller code (R6):
// Long constant offset/index: | Variable index:
// lw $t9, pReadBarrierMarkReg00
// beqz $t9, skip_call | beqz $t9, skip_call
// aui $t8, `obj`, ofs_hi | lsa $t8, `index`, `obj`, 2
// jialc $t9, thunk_disp | jialc $t9, thunk_disp
// skip_call: | skip_call:
// lw `out`, ofs_lo($t8) | lw `out`, ofs($t8)
// [subu `out`, $zero, `out`] | [subu `out`, $zero, `out`] # Unpoison reference.
.macro BRB_FIELD_LONG_OFFSET_ENTRY obj
1:
# No explicit null check for variable indices or large constant indices/offsets
# as it must have been done earlier.
#if defined(_MIPS_ARCH_MIPS32R6)
lapc $gp, .Lintrospection_exits # $gp = address of .Lintrospection_exits.
#else
addiu $gp, $t9, (.Lintrospection_exits - 1b) # $gp = address of .Lintrospection_exits.
#endif
.set push
.set noat
lw $at, MIRROR_OBJECT_LOCK_WORD_OFFSET(\obj)
sll $at, $at, 31 - LOCK_WORD_READ_BARRIER_STATE_SHIFT # Move barrier state bit
# to sign bit.
bltz $at, .Lintrospection_field_array # If gray, load reference, mark.
nop
.set pop
jalr $zero, $ra # Otherwise, load-load barrier and return.
sync
break # Padding to 8 instructions.
.endm
.macro BRB_GC_ROOT_ENTRY root
1:
#if defined(_MIPS_ARCH_MIPS32R6)
lapc $gp, .Lintrospection_exit_\root # $gp = exit point address.
#else
addiu $gp, $t9, (.Lintrospection_exit_\root - 1b) # $gp = exit point address.
#endif
bnez \root, .Lintrospection_common
move $t8, \root # Move reference to $t8 for common code.
jalr $zero, $ra # Return if null.
# The next instruction (from the following BRB_GC_ROOT_ENTRY) fills the delay slot.
# This instruction has no effect (actual NOP for the last entry; otherwise changes $gp,
# which is unused after that anyway).
.endm
.macro BRB_FIELD_EXIT out
.Lintrospection_exit_\out:
jalr $zero, $ra
move \out, $t8 # Return reference in expected register.
.endm
.macro BRB_FIELD_EXIT_BREAK
break
break
.endm
ENTRY_NO_GP art_quick_read_barrier_mark_introspection
# Entry points for offsets/indices not fitting into int16_t and for variable indices.
BRB_FIELD_LONG_OFFSET_ENTRY $v0
BRB_FIELD_LONG_OFFSET_ENTRY $v1
BRB_FIELD_LONG_OFFSET_ENTRY $a0
BRB_FIELD_LONG_OFFSET_ENTRY $a1
BRB_FIELD_LONG_OFFSET_ENTRY $a2
BRB_FIELD_LONG_OFFSET_ENTRY $a3
BRB_FIELD_LONG_OFFSET_ENTRY $t0
BRB_FIELD_LONG_OFFSET_ENTRY $t1
BRB_FIELD_LONG_OFFSET_ENTRY $t2
BRB_FIELD_LONG_OFFSET_ENTRY $t3
BRB_FIELD_LONG_OFFSET_ENTRY $t4
BRB_FIELD_LONG_OFFSET_ENTRY $t5
BRB_FIELD_LONG_OFFSET_ENTRY $t6
BRB_FIELD_LONG_OFFSET_ENTRY $t7
BRB_FIELD_LONG_OFFSET_ENTRY $s2
BRB_FIELD_LONG_OFFSET_ENTRY $s3
BRB_FIELD_LONG_OFFSET_ENTRY $s4
BRB_FIELD_LONG_OFFSET_ENTRY $s5
BRB_FIELD_LONG_OFFSET_ENTRY $s6
BRB_FIELD_LONG_OFFSET_ENTRY $s7
BRB_FIELD_LONG_OFFSET_ENTRY $s8
# Entry points for offsets/indices fitting into int16_t.
BRB_FIELD_SHORT_OFFSET_ENTRY $v0
BRB_FIELD_SHORT_OFFSET_ENTRY $v1
BRB_FIELD_SHORT_OFFSET_ENTRY $a0
BRB_FIELD_SHORT_OFFSET_ENTRY $a1
BRB_FIELD_SHORT_OFFSET_ENTRY $a2
BRB_FIELD_SHORT_OFFSET_ENTRY $a3
BRB_FIELD_SHORT_OFFSET_ENTRY $t0
BRB_FIELD_SHORT_OFFSET_ENTRY $t1
BRB_FIELD_SHORT_OFFSET_ENTRY $t2
BRB_FIELD_SHORT_OFFSET_ENTRY $t3
BRB_FIELD_SHORT_OFFSET_ENTRY $t4
BRB_FIELD_SHORT_OFFSET_ENTRY $t5
BRB_FIELD_SHORT_OFFSET_ENTRY $t6
BRB_FIELD_SHORT_OFFSET_ENTRY $t7
BRB_FIELD_SHORT_OFFSET_ENTRY $s2
BRB_FIELD_SHORT_OFFSET_ENTRY $s3
BRB_FIELD_SHORT_OFFSET_ENTRY $s4
BRB_FIELD_SHORT_OFFSET_ENTRY $s5
BRB_FIELD_SHORT_OFFSET_ENTRY $s6
BRB_FIELD_SHORT_OFFSET_ENTRY $s7
BRB_FIELD_SHORT_OFFSET_ENTRY $s8
.global art_quick_read_barrier_mark_introspection_gc_roots
art_quick_read_barrier_mark_introspection_gc_roots:
# Entry points for GC roots.
BRB_GC_ROOT_ENTRY $v0
BRB_GC_ROOT_ENTRY $v1
BRB_GC_ROOT_ENTRY $a0
BRB_GC_ROOT_ENTRY $a1
BRB_GC_ROOT_ENTRY $a2
BRB_GC_ROOT_ENTRY $a3
BRB_GC_ROOT_ENTRY $t0
BRB_GC_ROOT_ENTRY $t1
BRB_GC_ROOT_ENTRY $t2
BRB_GC_ROOT_ENTRY $t3
BRB_GC_ROOT_ENTRY $t4
BRB_GC_ROOT_ENTRY $t5
BRB_GC_ROOT_ENTRY $t6
BRB_GC_ROOT_ENTRY $t7
BRB_GC_ROOT_ENTRY $s2
BRB_GC_ROOT_ENTRY $s3
BRB_GC_ROOT_ENTRY $s4
BRB_GC_ROOT_ENTRY $s5
BRB_GC_ROOT_ENTRY $s6
BRB_GC_ROOT_ENTRY $s7
BRB_GC_ROOT_ENTRY $s8
.global art_quick_read_barrier_mark_introspection_end_of_entries
art_quick_read_barrier_mark_introspection_end_of_entries:
nop # Fill the delay slot of the last BRB_GC_ROOT_ENTRY.
.Lintrospection_throw_npe:
b art_quick_throw_null_pointer_exception
addiu $ra, $ra, 4 # Skip lw, make $ra point to lw's stack map.
.set push
.set noat
// Fields and array elements.
.Lintrospection_field_array:
// Get the field/element address using $t8 and the offset from the lw instruction.
lh $at, 0($ra) # $ra points to lw: $at = field/element offset.
addiu $ra, $ra, 4 + HEAP_POISON_INSTR_SIZE # Skip lw(+subu).
addu $t8, $t8, $at # $t8 = field/element address.
// Calculate the address of the exit point, store it in $gp and load the reference into $t8.
lb $at, (-HEAP_POISON_INSTR_SIZE - 2)($ra) # $ra-HEAP_POISON_INSTR_SIZE-4 points to
# "lw `out`, ...".
andi $at, $at, 31 # Extract `out` from lw.
sll $at, $at, 3 # Multiply `out` by the exit point size (BRB_FIELD_EXIT* macros).
lw $t8, 0($t8) # $t8 = reference.
UNPOISON_HEAP_REF $t8
// Return if null reference.
bnez $t8, .Lintrospection_common
addu $gp, $gp, $at # $gp = address of the exit point.
// Early return through the exit point.
.Lintrospection_return_early:
jalr $zero, $gp # Move $t8 to `out` and return.
nop
// Code common for GC roots, fields and array elements.
.Lintrospection_common:
// Check lock word for mark bit, if marked return.
lw $t9, MIRROR_OBJECT_LOCK_WORD_OFFSET($t8)
sll $at, $t9, 31 - LOCK_WORD_MARK_BIT_SHIFT # Move mark bit to sign bit.
bltz $at, .Lintrospection_return_early
#if (LOCK_WORD_STATE_SHIFT != 30) || (LOCK_WORD_STATE_FORWARDING_ADDRESS != 3)
// The below code depends on the lock word state being in the highest bits
// and the "forwarding address" state having all bits set.
#error "Unexpected lock word state shift or forwarding address state value."
#endif
// Test that both the forwarding state bits are 1.
sll $at, $t9, 1
and $at, $at, $t9 # Sign bit = 1 IFF both bits are 1.
bgez $at, .Lintrospection_mark
nop
.set pop
// Shift left by the forwarding address shift. This clears out the state bits since they are
// in the top 2 bits of the lock word.
jalr $zero, $gp # Move $t8 to `out` and return.
sll $t8, $t9, LOCK_WORD_STATE_FORWARDING_ADDRESS_SHIFT
.Lintrospection_mark:
// Partially set up the stack frame preserving only $ra.
addiu $sp, $sp, -160 # Includes 16 bytes of space for argument registers $a0-$a3.
.cfi_adjust_cfa_offset 160
sw $ra, 156($sp)
.cfi_rel_offset 31, 156
// Set up $gp, clobbering $ra and using the branch delay slot for a useful instruction.
bal 1f
sw $gp, 152($sp) # Preserve the exit point address.
1:
.cpload $ra
// Finalize the stack frame and call.
sw $t7, 148($sp)
.cfi_rel_offset 15, 148
sw $t6, 144($sp)
.cfi_rel_offset 14, 144
sw $t5, 140($sp)
.cfi_rel_offset 13, 140
sw $t4, 136($sp)
.cfi_rel_offset 12, 136
sw $t3, 132($sp)
.cfi_rel_offset 11, 132
sw $t2, 128($sp)
.cfi_rel_offset 10, 128
sw $t1, 124($sp)
.cfi_rel_offset 9, 124
sw $t0, 120($sp)
.cfi_rel_offset 8, 120
sw $a3, 116($sp)
.cfi_rel_offset 7, 116
sw $a2, 112($sp)
.cfi_rel_offset 6, 112
sw $a1, 108($sp)
.cfi_rel_offset 5, 108
sw $a0, 104($sp)
.cfi_rel_offset 4, 104
sw $v1, 100($sp)
.cfi_rel_offset 3, 100
sw $v0, 96($sp)
.cfi_rel_offset 2, 96
la $t9, artReadBarrierMark
sdc1 $f18, 88($sp)
sdc1 $f16, 80($sp)
sdc1 $f14, 72($sp)
sdc1 $f12, 64($sp)
sdc1 $f10, 56($sp)
sdc1 $f8, 48($sp)
sdc1 $f6, 40($sp)
sdc1 $f4, 32($sp)
sdc1 $f2, 24($sp)
sdc1 $f0, 16($sp)
jalr $t9 # $v0 <- artReadBarrierMark(reference)
move $a0, $t8 # Pass reference in $a0.
move $t8, $v0
lw $ra, 156($sp)
.cfi_restore 31
lw $gp, 152($sp) # $gp = address of the exit point.
lw $t7, 148($sp)
.cfi_restore 15
lw $t6, 144($sp)
.cfi_restore 14
lw $t5, 140($sp)
.cfi_restore 13
lw $t4, 136($sp)
.cfi_restore 12
lw $t3, 132($sp)
.cfi_restore 11
lw $t2, 128($sp)
.cfi_restore 10
lw $t1, 124($sp)
.cfi_restore 9
lw $t0, 120($sp)
.cfi_restore 8
lw $a3, 116($sp)
.cfi_restore 7
lw $a2, 112($sp)
.cfi_restore 6
lw $a1, 108($sp)
.cfi_restore 5
lw $a0, 104($sp)
.cfi_restore 4
lw $v1, 100($sp)
.cfi_restore 3
lw $v0, 96($sp)
.cfi_restore 2
ldc1 $f18, 88($sp)
ldc1 $f16, 80($sp)
ldc1 $f14, 72($sp)
ldc1 $f12, 64($sp)
ldc1 $f10, 56($sp)
ldc1 $f8, 48($sp)
ldc1 $f6, 40($sp)
ldc1 $f4, 32($sp)
ldc1 $f2, 24($sp)
ldc1 $f0, 16($sp)
// Return through the exit point.
jalr $zero, $gp # Move $t8 to `out` and return.
addiu $sp, $sp, 160
.cfi_adjust_cfa_offset -160
.Lintrospection_exits:
BRB_FIELD_EXIT_BREAK
BRB_FIELD_EXIT_BREAK
BRB_FIELD_EXIT $v0
BRB_FIELD_EXIT $v1
BRB_FIELD_EXIT $a0
BRB_FIELD_EXIT $a1
BRB_FIELD_EXIT $a2
BRB_FIELD_EXIT $a3
BRB_FIELD_EXIT $t0
BRB_FIELD_EXIT $t1
BRB_FIELD_EXIT $t2
BRB_FIELD_EXIT $t3
BRB_FIELD_EXIT $t4
BRB_FIELD_EXIT $t5
BRB_FIELD_EXIT $t6
BRB_FIELD_EXIT $t7
BRB_FIELD_EXIT_BREAK
BRB_FIELD_EXIT_BREAK
BRB_FIELD_EXIT $s2
BRB_FIELD_EXIT $s3
BRB_FIELD_EXIT $s4
BRB_FIELD_EXIT $s5
BRB_FIELD_EXIT $s6
BRB_FIELD_EXIT $s7
BRB_FIELD_EXIT_BREAK
BRB_FIELD_EXIT_BREAK
BRB_FIELD_EXIT_BREAK
BRB_FIELD_EXIT_BREAK
BRB_FIELD_EXIT_BREAK
BRB_FIELD_EXIT_BREAK
BRB_FIELD_EXIT $s8
BRB_FIELD_EXIT_BREAK
END art_quick_read_barrier_mark_introspection
/*
* Polymorphic method invocation.
* On entry:
* a0 = unused
* a1 = receiver
*/
.extern artInvokePolymorphic
ENTRY art_quick_invoke_polymorphic
SETUP_SAVE_REFS_AND_ARGS_FRAME
move $a0, $a1 # Make $a0 the receiver.
move $a1, rSELF # Make $a1 an alias for the current Thread.
la $t9, artInvokePolymorphic # Invoke artInvokePolymorphic
jalr $t9 # with args (receiver, Thread*, context).
addiu $a2, $sp, ARG_SLOT_SIZE # Make $a2 a pointer to the saved frame context.
lw $t7, THREAD_EXCEPTION_OFFSET(rSELF) # load Thread::Current()->exception_
RESTORE_SAVE_REFS_AND_ARGS_FRAME
bnez $t7, 1f
# don't care if $v0 and/or $v1 are modified, when exception branch taken
MTD $v0, $v1, $f0, $f1 # move float value to return value
jalr $zero, $ra
nop
1:
DELIVER_PENDING_EXCEPTION
END art_quick_invoke_polymorphic
/*
* InvokeCustom invocation.
* On entry:
* a0 = call_site_idx
*/
.extern artInvokeCustom
ENTRY art_quick_invoke_custom
SETUP_SAVE_REFS_AND_ARGS_FRAME
move $a1, rSELF # Make $a1 an alias for the current Thread.
la $t9, artInvokeCustom # Invoke artInvokeCustom
jalr $t9 # with args (call_site_idx, Thread*, context).
addiu $a2, $sp, ARG_SLOT_SIZE # Make $a2 a pointer to the saved frame context.
lw $t7, THREAD_EXCEPTION_OFFSET(rSELF) # load Thread::Current()->exception_
RESTORE_SAVE_REFS_AND_ARGS_FRAME
bnez $t7, 1f
# don't care if $v0 and/or $v1 are modified, when exception branch taken
MTD $v0, $v1, $f0, $f1 # move float value to return value
jalr $zero, $ra
nop
END art_quick_invoke_custom