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gerrit-public.fairphone.software / platform / dalvik / 76e15e367ae1189b6f641ba8d16ca92bd179dac0 / . / vm / mterp / armv5te / footer.S
blob: 2980fa744046ebdf5f20501878f0135d96504002 [file] [log] [blame]
/*
* ===========================================================================
* Common subroutines and data
* ===========================================================================
*/
.text
.align 2
#if defined(WITH_JIT)
#if defined(WITH_SELF_VERIFICATION)
/*
* "longjmp" to a translation after single-stepping. Before returning
* to translation, must save state for self-verification.
*/
.global dvmJitResumeTranslation @ (Thread* self, u4* dFP)
dvmJitResumeTranslation:
mov rSELF, r0 @ restore self
mov rPC, r1 @ restore Dalvik pc
mov rFP, r2 @ restore Dalvik fp
ldr r10, [rSELF,#offThread_jitResumeNPC] @ resume address
mov r2, #0
str r2, [rSELF,#offThread_jitResumeNPC] @ reset resume address
ldr sp, [rSELF,#offThread_jitResumeNSP] @ cut back native stack
b jitSVShadowRunStart @ resume as if cache hit
@ expects resume addr in r10
.global dvmJitToInterpPunt
dvmJitToInterpPunt:
mov r2,#kSVSPunt @ r2<- interpreter entry point
mov r3, #0
str r3, [rSELF, #offThread_inJitCodeCache] @ Back to the interp land
b jitSVShadowRunEnd @ doesn't return
.global dvmJitToInterpSingleStep
dvmJitToInterpSingleStep:
mov rPC, r0 @ set up dalvik pc
EXPORT_PC()
str lr, [rSELF,#offThread_jitResumeNPC]
str sp, [rSELF,#offThread_jitResumeNSP]
str r1, [rSELF,#offThread_jitResumeDPC]
mov r2,#kSVSSingleStep @ r2<- interpreter entry point
b jitSVShadowRunEnd @ doesn't return
.global dvmJitToInterpNoChainNoProfile
dvmJitToInterpNoChainNoProfile:
mov r0,rPC @ pass our target PC
mov r2,#kSVSNoProfile @ r2<- interpreter entry point
mov r3, #0 @ 0 means !inJitCodeCache
str r3, [rSELF, #offThread_inJitCodeCache] @ back to the interp land
b jitSVShadowRunEnd @ doesn't return
.global dvmJitToInterpTraceSelectNoChain
dvmJitToInterpTraceSelectNoChain:
mov r0,rPC @ pass our target PC
mov r2,#kSVSTraceSelect @ r2<- interpreter entry point
mov r3, #0 @ 0 means !inJitCodeCache
str r3, [rSELF, #offThread_inJitCodeCache] @ Back to the interp land
b jitSVShadowRunEnd @ doesn't return
.global dvmJitToInterpTraceSelect
dvmJitToInterpTraceSelect:
ldr r0,[lr, #-1] @ pass our target PC
mov r2,#kSVSTraceSelect @ r2<- interpreter entry point
mov r3, #0 @ 0 means !inJitCodeCache
str r3, [rSELF, #offThread_inJitCodeCache] @ Back to the interp land
b jitSVShadowRunEnd @ doesn't return
.global dvmJitToInterpBackwardBranch
dvmJitToInterpBackwardBranch:
ldr r0,[lr, #-1] @ pass our target PC
mov r2,#kSVSBackwardBranch @ r2<- interpreter entry point
mov r3, #0 @ 0 means !inJitCodeCache
str r3, [rSELF, #offThread_inJitCodeCache] @ Back to the interp land
b jitSVShadowRunEnd @ doesn't return
.global dvmJitToInterpNormal
dvmJitToInterpNormal:
ldr r0,[lr, #-1] @ pass our target PC
mov r2,#kSVSNormal @ r2<- interpreter entry point
mov r3, #0 @ 0 means !inJitCodeCache
str r3, [rSELF, #offThread_inJitCodeCache] @ Back to the interp land
b jitSVShadowRunEnd @ doesn't return
.global dvmJitToInterpNoChain
dvmJitToInterpNoChain:
mov r0,rPC @ pass our target PC
mov r2,#kSVSNoChain @ r2<- interpreter entry point
mov r3, #0 @ 0 means !inJitCodeCache
str r3, [rSELF, #offThread_inJitCodeCache] @ Back to the interp land
b jitSVShadowRunEnd @ doesn't return
#else
/*
* "longjmp" to a translation after single-stepping.
*/
.global dvmJitResumeTranslation @ (Thread* self, u4* dFP)
dvmJitResumeTranslation:
mov rSELF, r0 @ restore self
mov rPC, r1 @ restore Dalvik pc
mov rFP, r2 @ restore Dalvik fp
ldr r0, [rSELF,#offThread_jitResumeNPC]
mov r2, #0
str r2, [rSELF,#offThread_jitResumeNPC] @ reset resume address
ldr sp, [rSELF,#offThread_jitResumeNSP] @ cut back native stack
bx r0 @ resume translation
/*
* Return from the translation cache to the interpreter when the compiler is
* having issues translating/executing a Dalvik instruction. We have to skip
* the code cache lookup otherwise it is possible to indefinitely bouce
* between the interpreter and the code cache if the instruction that fails
* to be compiled happens to be at a trace start.
*/
.global dvmJitToInterpPunt
dvmJitToInterpPunt:
mov rPC, r0
#if defined(WITH_JIT_TUNING)
mov r0,lr
bl dvmBumpPunt;
#endif
EXPORT_PC()
mov r0, #0
str r0, [rSELF, #offThread_inJitCodeCache] @ Back to the interp land
ldr rIBASE, [rSELF, #offThread_curHandlerTable]
FETCH_INST()
GET_INST_OPCODE(ip)
GOTO_OPCODE(ip)
/*
* Return to the interpreter to handle a single instruction.
* We'll use the normal single-stepping mechanism via interpBreak,
* but also save the native pc of the resume point in the translation
* and the native sp so that we can later do the equivalent of a
* longjmp() to resume.
* On entry:
* dPC <= Dalvik PC of instrucion to interpret
* lr <= resume point in translation
* r1 <= Dalvik PC of next instruction
*/
.global dvmJitToInterpSingleStep
dvmJitToInterpSingleStep:
mov rPC, r0 @ set up dalvik pc
EXPORT_PC()
str lr, [rSELF,#offThread_jitResumeNPC]
str sp, [rSELF,#offThread_jitResumeNSP]
str r1, [rSELF,#offThread_jitResumeDPC]
mov r1, #1
str r1, [rSELF,#offThread_singleStepCount] @ just step once
mov r0, rSELF
mov r1, #kSubModeCountedStep
bl dvmEnableSubMode @ (self, newMode)
ldr rIBASE, [rSELF,#offThread_curHandlerTable]
FETCH_INST()
GET_INST_OPCODE(ip)
GOTO_OPCODE(ip)
/*
* Return from the translation cache and immediately request
* a translation for the exit target. Commonly used for callees.
*/
.global dvmJitToInterpTraceSelectNoChain
dvmJitToInterpTraceSelectNoChain:
#if defined(WITH_JIT_TUNING)
bl dvmBumpNoChain
#endif
mov r0,rPC
mov r1,rSELF
bl dvmJitGetTraceAddrThread @ (pc, self)
str r0, [rSELF, #offThread_inJitCodeCache] @ set the inJitCodeCache flag
mov r1, rPC @ arg1 of translation may need this
mov lr, #0 @ in case target is HANDLER_INTERPRET
cmp r0,#0 @ !0 means translation exists
bxne r0 @ continue native execution if so
b 2f @ branch over to use the interpreter
/*
* Return from the translation cache and immediately request
* a translation for the exit target. Commonly used following
* invokes.
*/
.global dvmJitToInterpTraceSelect
dvmJitToInterpTraceSelect:
ldr rPC,[lr, #-1] @ get our target PC
add rINST,lr,#-5 @ save start of chain branch
add rINST, #-4 @ .. which is 9 bytes back
mov r0,rPC
mov r1,rSELF
bl dvmJitGetTraceAddrThread @ (pc, self)
str r0, [rSELF, #offThread_inJitCodeCache] @ set the inJitCodeCache flag
cmp r0,#0
beq 2f
mov r1,rINST
bl dvmJitChain @ r0<- dvmJitChain(codeAddr,chainAddr)
mov r1, rPC @ arg1 of translation may need this
mov lr, #0 @ in case target is HANDLER_INTERPRET
cmp r0,#0 @ successful chain?
bxne r0 @ continue native execution
b toInterpreter @ didn't chain - resume with interpreter
/* No translation, so request one if profiling isn't disabled*/
2:
ldr rIBASE, [rSELF, #offThread_curHandlerTable]
ldr r0, [rSELF, #offThread_pJitProfTable]
FETCH_INST()
cmp r0, #0
movne r2,#kJitTSelectRequestHot @ ask for trace selection
bne common_selectTrace
GET_INST_OPCODE(ip)
GOTO_OPCODE(ip)
/*
* Return from the translation cache to the interpreter.
* The return was done with a BLX from thumb mode, and
* the following 32-bit word contains the target rPC value.
* Note that lr (r14) will have its low-order bit set to denote
* its thumb-mode origin.
*
* We'll need to stash our lr origin away, recover the new
* target and then check to see if there is a translation available
* for our new target. If so, we do a translation chain and
* go back to native execution. Otherwise, it's back to the
* interpreter (after treating this entry as a potential
* trace start).
*/
.global dvmJitToInterpNormal
dvmJitToInterpNormal:
ldr rPC,[lr, #-1] @ get our target PC
add rINST,lr,#-5 @ save start of chain branch
add rINST,#-4 @ .. which is 9 bytes back
#if defined(WITH_JIT_TUNING)
bl dvmBumpNormal
#endif
mov r0,rPC
mov r1,rSELF
bl dvmJitGetTraceAddrThread @ (pc, self)
str r0, [rSELF, #offThread_inJitCodeCache] @ set the inJitCodeCache flag
cmp r0,#0
beq toInterpreter @ go if not, otherwise do chain
mov r1,rINST
bl dvmJitChain @ r0<- dvmJitChain(codeAddr,chainAddr)
mov r1, rPC @ arg1 of translation may need this
mov lr, #0 @ in case target is HANDLER_INTERPRET
cmp r0,#0 @ successful chain?
bxne r0 @ continue native execution
b toInterpreter @ didn't chain - resume with interpreter
/*
* Return from the translation cache to the interpreter to do method invocation.
* Check if translation exists for the callee, but don't chain to it.
*/
.global dvmJitToInterpNoChainNoProfile
dvmJitToInterpNoChainNoProfile:
#if defined(WITH_JIT_TUNING)
bl dvmBumpNoChain
#endif
mov r0,rPC
mov r1,rSELF
bl dvmJitGetTraceAddrThread @ (pc, self)
str r0, [rSELF, #offThread_inJitCodeCache] @ set the inJitCodeCache flag
mov r1, rPC @ arg1 of translation may need this
mov lr, #0 @ in case target is HANDLER_INTERPRET
cmp r0,#0
bxne r0 @ continue native execution if so
EXPORT_PC()
ldr rIBASE, [rSELF, #offThread_curHandlerTable]
FETCH_INST()
GET_INST_OPCODE(ip) @ extract opcode from rINST
GOTO_OPCODE(ip) @ jump to next instruction
/*
* Return from the translation cache to the interpreter to do method invocation.
* Check if translation exists for the callee, but don't chain to it.
*/
.global dvmJitToInterpNoChain
dvmJitToInterpNoChain:
#if defined(WITH_JIT_TUNING)
bl dvmBumpNoChain
#endif
mov r0,rPC
mov r1,rSELF
bl dvmJitGetTraceAddrThread @ (pc, self)
str r0, [rSELF, #offThread_inJitCodeCache] @ set the inJitCodeCache flag
mov r1, rPC @ arg1 of translation may need this
mov lr, #0 @ in case target is HANDLER_INTERPRET
cmp r0,#0
bxne r0 @ continue native execution if so
#endif
/*
* No translation, restore interpreter regs and start interpreting.
* rSELF & rFP were preserved in the translated code, and rPC has
* already been restored by the time we get here. We'll need to set
* up rIBASE & rINST, and load the address of the JitTable into r0.
*/
toInterpreter:
EXPORT_PC()
ldr rIBASE, [rSELF, #offThread_curHandlerTable]
FETCH_INST()
ldr r0, [rSELF, #offThread_pJitProfTable]
ldr rIBASE, [rSELF, #offThread_curHandlerTable]
@ NOTE: intended fallthrough
/*
* Similar to common_updateProfile, but tests for null pJitProfTable
* r0 holds pJifProfTAble, rINST is loaded, rPC is current and
* rIBASE has been recently refreshed.
*/
common_testUpdateProfile:
cmp r0, #0 @ JIT switched off?
beq 4f @ return to interp if so
/*
* Common code to update potential trace start counter, and initiate
* a trace-build if appropriate.
* On entry here:
* r0 <= pJitProfTable (verified non-NULL)
* rPC <= Dalvik PC
* rINST <= next instruction
*/
common_updateProfile:
eor r3,rPC,rPC,lsr #12 @ cheap, but fast hash function
lsl r3,r3,#(32 - JIT_PROF_SIZE_LOG_2) @ shift out excess bits
ldrb r1,[r0,r3,lsr #(32 - JIT_PROF_SIZE_LOG_2)] @ get counter
GET_INST_OPCODE(ip)
subs r1,r1,#1 @ decrement counter
strb r1,[r0,r3,lsr #(32 - JIT_PROF_SIZE_LOG_2)] @ and store it
GOTO_OPCODE_IFNE(ip) @ if not threshold, fallthrough otherwise */
/* Looks good, reset the counter */
ldr r1, [rSELF, #offThread_jitThreshold]
strb r1,[r0,r3,lsr #(32 - JIT_PROF_SIZE_LOG_2)] @ reset counter
EXPORT_PC()
mov r0,rPC
mov r1,rSELF
bl dvmJitGetTraceAddrThread @ (pc, self)
str r0, [rSELF, #offThread_inJitCodeCache] @ set the inJitCodeCache flag
mov r1, rPC @ arg1 of translation may need this
mov lr, #0 @ in case target is HANDLER_INTERPRET
cmp r0,#0
#if !defined(WITH_SELF_VERIFICATION)
bxne r0 @ jump to the translation
mov r2,#kJitTSelectRequest @ ask for trace selection
@ fall-through to common_selectTrace
#else
moveq r2,#kJitTSelectRequest @ ask for trace selection
beq common_selectTrace
/*
* At this point, we have a target translation. However, if
* that translation is actually the interpret-only pseudo-translation
* we want to treat it the same as no translation.
*/
mov r10, r0 @ save target
bl dvmCompilerGetInterpretTemplate
cmp r0, r10 @ special case?
bne jitSVShadowRunStart @ set up self verification shadow space
@ Need to clear the inJitCodeCache flag
mov r3, #0 @ 0 means not in the JIT code cache
str r3, [rSELF, #offThread_inJitCodeCache] @ back to the interp land
GET_INST_OPCODE(ip)
GOTO_OPCODE(ip)
/* no return */
#endif
/*
* On entry:
* r2 is jit state.
*/
common_selectTrace:
ldrh r0,[rSELF,#offThread_subMode]
ands r0, #(kSubModeJitTraceBuild | kSubModeJitSV)
bne 3f @ already doing JIT work, continue
str r2,[rSELF,#offThread_jitState]
mov r0, rSELF
/*
* Call out to validate trace-building request. If successful,
* rIBASE will be swapped to to send us into single-stepping trace
* building mode, so we need to refresh before we continue.
*/
EXPORT_PC()
SAVE_PC_FP_TO_SELF() @ copy of pc/fp to Thread
bl dvmJitCheckTraceRequest
3:
FETCH_INST()
ldr rIBASE, [rSELF, #offThread_curHandlerTable]
4:
GET_INST_OPCODE(ip) @ extract opcode from rINST
GOTO_OPCODE(ip)
/* no return */
#endif
#if defined(WITH_SELF_VERIFICATION)
/*
* Save PC and registers to shadow memory for self verification mode
* before jumping to native translation.
* On entry:
* rPC, rFP, rSELF: the values that they should contain
* r10: the address of the target translation.
*/
jitSVShadowRunStart:
mov r0,rPC @ r0<- program counter
mov r1,rFP @ r1<- frame pointer
mov r2,rSELF @ r2<- self (Thread) pointer
mov r3,r10 @ r3<- target translation
bl dvmSelfVerificationSaveState @ save registers to shadow space
ldr rFP,[r0,#offShadowSpace_shadowFP] @ rFP<- fp in shadow space
bx r10 @ jump to the translation
/*
* Restore PC, registers, and interpreter state to original values
* before jumping back to the interpreter.
* On entry:
* r0: dPC
* r2: self verification state
*/
jitSVShadowRunEnd:
mov r1,rFP @ pass ending fp
mov r3,rSELF @ pass self ptr for convenience
bl dvmSelfVerificationRestoreState @ restore pc and fp values
LOAD_PC_FP_FROM_SELF() @ restore pc, fp
ldr r1,[r0,#offShadowSpace_svState] @ get self verification state
cmp r1,#0 @ check for punt condition
beq 1f
@ Set up SV single-stepping
mov r0, rSELF
mov r1, #kSubModeJitSV
bl dvmEnableSubMode @ (self, subMode)
mov r2,#kJitSelfVerification @ ask for self verification
str r2,[rSELF,#offThread_jitState]
@ intentional fallthrough
1: @ exit to interpreter without check
EXPORT_PC()
ldr rIBASE, [rSELF, #offThread_curHandlerTable]
FETCH_INST()
GET_INST_OPCODE(ip)
GOTO_OPCODE(ip)
#endif
/*
* The equivalent of "goto bail", this calls through the "bail handler".
* It will end this interpreter activation, and return to the caller
* of dvmMterpStdRun.
*
* State registers will be saved to the "thread" area before bailing
* debugging purposes
*/
common_gotoBail:
SAVE_PC_FP_TO_SELF() @ export state to "thread"
mov r0, rSELF @ r0<- self ptr
b dvmMterpStdBail @ call(self, changeInterp)
/*
* The JIT's invoke method needs to remember the callsite class and
* target pair. Save them here so that they are available to
* dvmCheckJit following the interpretation of this invoke.
*/
#if defined(WITH_JIT)
save_callsiteinfo:
cmp r9, #0
ldrne r9, [r9, #offObject_clazz]
str r0, [rSELF, #offThread_methodToCall]
str r9, [rSELF, #offThread_callsiteClass]
bx lr
#endif
/*
* Common code for method invocation with range.
*
* On entry:
* r0 is "Method* methodToCall", r9 is "this"
*/
common_invokeMethodRange:
.LinvokeNewRange:
#if defined(WITH_JIT)
ldrh r1, [rSELF, #offThread_subMode]
ands r1, #kSubModeJitTraceBuild
blne save_callsiteinfo
#endif
@ prepare to copy args to "outs" area of current frame
movs r2, rINST, lsr #8 @ r2<- AA (arg count) -- test for zero
SAVEAREA_FROM_FP(r10, rFP) @ r10<- stack save area
beq .LinvokeArgsDone @ if no args, skip the rest
FETCH(r1, 2) @ r1<- CCCC
.LinvokeRangeArgs:
@ r0=methodToCall, r1=CCCC, r2=count, r10=outs
@ (very few methods have > 10 args; could unroll for common cases)
add r3, rFP, r1, lsl #2 @ r3<- &fp[CCCC]
sub r10, r10, r2, lsl #2 @ r10<- "outs" area, for call args
1: ldr r1, [r3], #4 @ val = *fp++
subs r2, r2, #1 @ count--
str r1, [r10], #4 @ *outs++ = val
bne 1b @ ...while count != 0
b .LinvokeArgsDone
/*
* Common code for method invocation without range.
*
* On entry:
* r0 is "Method* methodToCall", r9 is "this"
*/
common_invokeMethodNoRange:
.LinvokeNewNoRange:
#if defined(WITH_JIT)
ldrh r1, [rSELF, #offThread_subMode]
ands r1, #kSubModeJitTraceBuild
blne save_callsiteinfo
#endif
@ prepare to copy args to "outs" area of current frame
movs r2, rINST, lsr #12 @ r2<- B (arg count) -- test for zero
SAVEAREA_FROM_FP(r10, rFP) @ r10<- stack save area
FETCH(r1, 2) @ r1<- GFED (load here to hide latency)
beq .LinvokeArgsDone
@ r0=methodToCall, r1=GFED, r2=count, r10=outs
.LinvokeNonRange:
rsb r2, r2, #5 @ r2<- 5-r2
add pc, pc, r2, lsl #4 @ computed goto, 4 instrs each
bl common_abort @ (skipped due to ARM prefetch)
5: and ip, rINST, #0x0f00 @ isolate A
ldr r2, [rFP, ip, lsr #6] @ r2<- vA (shift right 8, left 2)
mov r0, r0 @ nop
str r2, [r10, #-4]! @ *--outs = vA
4: and ip, r1, #0xf000 @ isolate G
ldr r2, [rFP, ip, lsr #10] @ r2<- vG (shift right 12, left 2)
mov r0, r0 @ nop
str r2, [r10, #-4]! @ *--outs = vG
3: and ip, r1, #0x0f00 @ isolate F
ldr r2, [rFP, ip, lsr #6] @ r2<- vF
mov r0, r0 @ nop
str r2, [r10, #-4]! @ *--outs = vF
2: and ip, r1, #0x00f0 @ isolate E
ldr r2, [rFP, ip, lsr #2] @ r2<- vE
mov r0, r0 @ nop
str r2, [r10, #-4]! @ *--outs = vE
1: and ip, r1, #0x000f @ isolate D
ldr r2, [rFP, ip, lsl #2] @ r2<- vD
mov r0, r0 @ nop
str r2, [r10, #-4]! @ *--outs = vD
0: @ fall through to .LinvokeArgsDone
.LinvokeArgsDone: @ r0=methodToCall
ldrh r9, [r0, #offMethod_registersSize] @ r9<- methodToCall->regsSize
ldrh r3, [r0, #offMethod_outsSize] @ r3<- methodToCall->outsSize
ldr r2, [r0, #offMethod_insns] @ r2<- method->insns
ldr rINST, [r0, #offMethod_clazz] @ rINST<- method->clazz
@ find space for the new stack frame, check for overflow
SAVEAREA_FROM_FP(r1, rFP) @ r1<- stack save area
sub r1, r1, r9, lsl #2 @ r1<- newFp (old savearea - regsSize)
SAVEAREA_FROM_FP(r10, r1) @ r10<- newSaveArea
@ bl common_dumpRegs
ldr r9, [rSELF, #offThread_interpStackEnd] @ r9<- interpStackEnd
sub r3, r10, r3, lsl #2 @ r3<- bottom (newsave - outsSize)
cmp r3, r9 @ bottom < interpStackEnd?
ldrh lr, [rSELF, #offThread_subMode]
ldr r3, [r0, #offMethod_accessFlags] @ r3<- methodToCall->accessFlags
blo .LstackOverflow @ yes, this frame will overflow stack
@ set up newSaveArea
#ifdef EASY_GDB
SAVEAREA_FROM_FP(ip, rFP) @ ip<- stack save area
str ip, [r10, #offStackSaveArea_prevSave]
#endif
str rFP, [r10, #offStackSaveArea_prevFrame]
str rPC, [r10, #offStackSaveArea_savedPc]
#if defined(WITH_JIT)
mov r9, #0
str r9, [r10, #offStackSaveArea_returnAddr]
#endif
str r0, [r10, #offStackSaveArea_method]
@ Profiling?
cmp lr, #0 @ any special modes happening?
bne 2f @ go if so
1:
tst r3, #ACC_NATIVE
bne .LinvokeNative
/*
stmfd sp!, {r0-r3}
bl common_printNewline
mov r0, rFP
mov r1, #0
bl dvmDumpFp
ldmfd sp!, {r0-r3}
stmfd sp!, {r0-r3}
mov r0, r1
mov r1, r10
bl dvmDumpFp
bl common_printNewline
ldmfd sp!, {r0-r3}
*/
ldrh r9, [r2] @ r9 <- load INST from new PC
ldr r3, [rINST, #offClassObject_pDvmDex] @ r3<- method->clazz->pDvmDex
mov rPC, r2 @ publish new rPC
@ Update state values for the new method
@ r0=methodToCall, r1=newFp, r3=newMethodClass, r9=newINST
str r0, [rSELF, #offThread_method] @ self->method = methodToCall
str r3, [rSELF, #offThread_methodClassDex] @ self->methodClassDex = ...
mov r2, #1
str r2, [rSELF, #offThread_debugIsMethodEntry]
#if defined(WITH_JIT)
ldr r0, [rSELF, #offThread_pJitProfTable]
mov rFP, r1 @ fp = newFp
GET_PREFETCHED_OPCODE(ip, r9) @ extract prefetched opcode from r9
mov rINST, r9 @ publish new rINST
str r1, [rSELF, #offThread_curFrame] @ curFrame = newFp
cmp r0,#0
bne common_updateProfile
GOTO_OPCODE(ip) @ jump to next instruction
#else
mov rFP, r1 @ fp = newFp
GET_PREFETCHED_OPCODE(ip, r9) @ extract prefetched opcode from r9
mov rINST, r9 @ publish new rINST
str r1, [rSELF, #offThread_curFrame] @ curFrame = newFp
GOTO_OPCODE(ip) @ jump to next instruction
#endif
2:
@ Profiling - record method entry. r0: methodToCall
stmfd sp!, {r0-r3} @ preserve r0-r3
str rPC, [rSELF, #offThread_pc] @ update interpSave.pc
mov r1, r0
mov r0, rSELF
bl dvmReportInvoke @ (self, method)
ldmfd sp!, {r0-r3} @ restore r0-r3
b 1b
.LinvokeNative:
@ Prep for the native call
@ r0=methodToCall, r1=newFp, r10=newSaveArea
ldrh lr, [rSELF, #offThread_subMode]
ldr r9, [rSELF, #offThread_jniLocal_topCookie]@r9<-thread->localRef->...
str r1, [rSELF, #offThread_curFrame] @ curFrame = newFp
str r9, [r10, #offStackSaveArea_localRefCookie] @newFp->localRefCookie=top
mov r2, r0 @ r2<- methodToCall
mov r0, r1 @ r0<- newFp (points to args)
add r1, rSELF, #offThread_retval @ r1<- &retval
mov r3, rSELF @ arg3<- self
#ifdef ASSIST_DEBUGGER
/* insert fake function header to help gdb find the stack frame */
b .Lskip
.type dalvik_mterp, %function
dalvik_mterp:
.fnstart
MTERP_ENTRY1
MTERP_ENTRY2
.Lskip:
#endif
cmp lr, #0 @ any special SubModes active?
bne 11f @ go handle them if so
ldr ip, [r2, #offMethod_nativeFunc] @ pc<- methodToCall->nativeFunc
blx ip
7:
@ native return; r10=newSaveArea
@ equivalent to dvmPopJniLocals
ldr r0, [r10, #offStackSaveArea_localRefCookie] @ r0<- saved top
ldr r1, [rSELF, #offThread_exception] @ check for exception
str rFP, [rSELF, #offThread_curFrame] @ curFrame = fp
cmp r1, #0 @ null?
str r0, [rSELF, #offThread_jniLocal_topCookie] @ new top <- old top
bne common_exceptionThrown @ no, handle exception
FETCH_ADVANCE_INST(3) @ advance rPC, load rINST
GET_INST_OPCODE(ip) @ extract opcode from rINST
GOTO_OPCODE(ip) @ jump to next instruction
11:
@ r0=newFp, r1=&retval, r2=methodToCall, r3=self, lr=subModes
stmfd sp!, {r0-r3} @ save all but subModes
mov r0, r2 @ r0<- methodToCall
mov r1, rSELF
mov r2, rFP
bl dvmReportPreNativeInvoke @ (methodToCall, self, fp)
ldmfd sp, {r0-r3} @ refresh. NOTE: no sp autoincrement
@ Call the native method
ldr ip, [r2, #offMethod_nativeFunc] @ pc<- methodToCall->nativeFunc
blx ip
@ Restore the pre-call arguments
ldmfd sp!, {r0-r3} @ r2<- methodToCall (others unneeded)
@ Finish up any post-invoke subMode requirements
mov r0, r2 @ r0<- methodToCall
mov r1, rSELF
mov r2, rFP
bl dvmReportPostNativeInvoke @ (methodToCall, self, fp)
b 7b @ resume
.LstackOverflow: @ r0=methodToCall
mov r1, r0 @ r1<- methodToCall
mov r0, rSELF @ r0<- self
bl dvmHandleStackOverflow
b common_exceptionThrown
#ifdef ASSIST_DEBUGGER
.fnend
.size dalvik_mterp, .-dalvik_mterp
#endif
/*
* Common code for method invocation, calling through "glue code".
*
* TODO: now that we have range and non-range invoke handlers, this
* needs to be split into two. Maybe just create entry points
* that set r9 and jump here?
*
* On entry:
* r0 is "Method* methodToCall", the method we're trying to call
* r9 is "bool methodCallRange", indicating if this is a /range variant
*/
.if 0
.LinvokeOld:
sub sp, sp, #8 @ space for args + pad
FETCH(ip, 2) @ ip<- FEDC or CCCC
mov r2, r0 @ A2<- methodToCall
mov r0, rSELF @ A0<- self
SAVE_PC_FP_TO_SELF() @ export state to "self"
mov r1, r9 @ A1<- methodCallRange
mov r3, rINST, lsr #8 @ A3<- AA
str ip, [sp, #0] @ A4<- ip
bl dvmMterp_invokeMethod @ call the C invokeMethod
add sp, sp, #8 @ remove arg area
b common_resumeAfterGlueCall @ continue to next instruction
.endif
/*
* Common code for handling a return instruction.
*
* This does not return.
*/
common_returnFromMethod:
.LreturnNew:
ldrh lr, [rSELF, #offThread_subMode]
SAVEAREA_FROM_FP(r0, rFP)
ldr r9, [r0, #offStackSaveArea_savedPc] @ r9 = saveArea->savedPc
cmp lr, #0 @ any special subMode handling needed?
bne 19f
14:
ldr rFP, [r0, #offStackSaveArea_prevFrame] @ fp = saveArea->prevFrame
ldr r2, [rFP, #(offStackSaveArea_method - sizeofStackSaveArea)]
@ r2<- method we're returning to
cmp r2, #0 @ is this a break frame?
#if defined(WORKAROUND_CORTEX_A9_745320)
/* Don't use conditional loads if the HW defect exists */
beq 15f
ldr r10, [r2, #offMethod_clazz] @ r10<- method->clazz
15:
#else
ldrne r10, [r2, #offMethod_clazz] @ r10<- method->clazz
#endif
beq common_gotoBail @ break frame, bail out completely
ldr rIBASE, [rSELF, #offThread_curHandlerTable] @ refresh rIBASE
PREFETCH_ADVANCE_INST(rINST, r9, 3) @ advance r9, update new rINST
str r2, [rSELF, #offThread_method]@ self->method = newSave->method
ldr r1, [r10, #offClassObject_pDvmDex] @ r1<- method->clazz->pDvmDex
str rFP, [rSELF, #offThread_curFrame] @ curFrame = fp
#if defined(WITH_JIT)
ldr r10, [r0, #offStackSaveArea_returnAddr] @ r10 = saveArea->returnAddr
mov rPC, r9 @ publish new rPC
str r1, [rSELF, #offThread_methodClassDex]
str r10, [rSELF, #offThread_inJitCodeCache] @ may return to JIT'ed land
cmp r10, #0 @ caller is compiled code
blxne r10
GET_INST_OPCODE(ip) @ extract opcode from rINST
GOTO_OPCODE(ip) @ jump to next instruction
#else
GET_INST_OPCODE(ip) @ extract opcode from rINST
mov rPC, r9 @ publish new rPC
str r1, [rSELF, #offThread_methodClassDex]
GOTO_OPCODE(ip) @ jump to next instruction
#endif
19:
@ Handle special actions
@ On entry, r0: StackSaveArea
ldr r1, [r0, #offStackSaveArea_prevFrame] @ r2<- prevFP
str rPC, [rSELF, #offThread_pc] @ update interpSave.pc
str r1, [rSELF, #offThread_curFrame] @ update interpSave.curFrame
mov r0, rSELF
bl dvmReportReturn @ (self)
SAVEAREA_FROM_FP(r0, rFP) @ restore StackSaveArea
b 14b @ continue
/*
* Return handling, calls through "glue code".
*/
.if 0
.LreturnOld:
SAVE_PC_FP_TO_SELF() @ export state
mov r0, rSELF @ arg to function
bl dvmMterp_returnFromMethod
b common_resumeAfterGlueCall
.endif
/*
* Somebody has thrown an exception. Handle it.
*
* If the exception processing code returns to us (instead of falling
* out of the interpreter), continue with whatever the next instruction
* now happens to be.
*
* This does not return.
*/
.global dvmMterpCommonExceptionThrown
dvmMterpCommonExceptionThrown:
common_exceptionThrown:
.LexceptionNew:
EXPORT_PC()
mov r0, rSELF
bl dvmCheckSuspendPending
ldr r9, [rSELF, #offThread_exception] @ r9<- self->exception
mov r1, rSELF @ r1<- self
mov r0, r9 @ r0<- exception
bl dvmAddTrackedAlloc @ don't let the exception be GCed
ldrh r2, [rSELF, #offThread_subMode] @ get subMode flags
mov r3, #0 @ r3<- NULL
str r3, [rSELF, #offThread_exception] @ self->exception = NULL
@ Special subMode?
cmp r2, #0 @ any special subMode handling needed?
bne 7f @ go if so
8:
/* set up args and a local for "&fp" */
/* (str sp, [sp, #-4]! would be perfect here, but is discouraged) */
str rFP, [sp, #-4]! @ *--sp = fp
mov ip, sp @ ip<- &fp
mov r3, #0 @ r3<- false
str ip, [sp, #-4]! @ *--sp = &fp
ldr r1, [rSELF, #offThread_method] @ r1<- self->method
mov r0, rSELF @ r0<- self
ldr r1, [r1, #offMethod_insns] @ r1<- method->insns
mov r2, r9 @ r2<- exception
sub r1, rPC, r1 @ r1<- pc - method->insns
mov r1, r1, asr #1 @ r1<- offset in code units
/* call, r0 gets catchRelPc (a code-unit offset) */
bl dvmFindCatchBlock @ call(self, relPc, exc, scan?, &fp)
/* fix earlier stack overflow if necessary; may trash rFP */
ldrb r1, [rSELF, #offThread_stackOverflowed]
cmp r1, #0 @ did we overflow earlier?
beq 1f @ no, skip ahead
mov rFP, r0 @ save relPc result in rFP
mov r0, rSELF @ r0<- self
mov r1, r9 @ r1<- exception
bl dvmCleanupStackOverflow @ call(self)
mov r0, rFP @ restore result
1:
/* update frame pointer and check result from dvmFindCatchBlock */
ldr rFP, [sp, #4] @ retrieve the updated rFP
cmp r0, #0 @ is catchRelPc < 0?
add sp, sp, #8 @ restore stack
bmi .LnotCaughtLocally
/* adjust locals to match self->interpSave.curFrame and updated PC */
SAVEAREA_FROM_FP(r1, rFP) @ r1<- new save area
ldr r1, [r1, #offStackSaveArea_method] @ r1<- new method
str r1, [rSELF, #offThread_method] @ self->method = new method
ldr r2, [r1, #offMethod_clazz] @ r2<- method->clazz
ldr r3, [r1, #offMethod_insns] @ r3<- method->insns
ldr r2, [r2, #offClassObject_pDvmDex] @ r2<- method->clazz->pDvmDex
add rPC, r3, r0, asl #1 @ rPC<- method->insns + catchRelPc
str r2, [rSELF, #offThread_methodClassDex] @ self->pDvmDex = meth...
/* release the tracked alloc on the exception */
mov r0, r9 @ r0<- exception
mov r1, rSELF @ r1<- self
bl dvmReleaseTrackedAlloc @ release the exception
/* restore the exception if the handler wants it */
ldr rIBASE, [rSELF, #offThread_curHandlerTable] @ refresh rIBASE
FETCH_INST() @ load rINST from rPC
GET_INST_OPCODE(ip) @ extract opcode from rINST
cmp ip, #OP_MOVE_EXCEPTION @ is it "move-exception"?
streq r9, [rSELF, #offThread_exception] @ yes, restore the exception
GOTO_OPCODE(ip) @ jump to next instruction
@ Manage debugger bookkeeping
7:
str rPC, [rSELF, #offThread_pc] @ update interpSave.pc
str rFP, [rSELF, #offThread_curFrame] @ update interpSave.curFrame
mov r0, rSELF @ arg0<- self
mov r1, r9 @ arg1<- exception
bl dvmReportExceptionThrow @ (self, exception)
b 8b @ resume with normal handling
.LnotCaughtLocally: @ r9=exception
/* fix stack overflow if necessary */
ldrb r1, [rSELF, #offThread_stackOverflowed]
cmp r1, #0 @ did we overflow earlier?
movne r0, rSELF @ if yes: r0<- self
movne r1, r9 @ if yes: r1<- exception
blne dvmCleanupStackOverflow @ if yes: call(self)
@ may want to show "not caught locally" debug messages here
#if DVM_SHOW_EXCEPTION >= 2
/* call __android_log_print(prio, tag, format, ...) */
/* "Exception %s from %s:%d not caught locally" */
@ dvmLineNumFromPC(method, pc - method->insns)
ldr r0, [rSELF, #offThread_method]
ldr r1, [r0, #offMethod_insns]
sub r1, rPC, r1
asr r1, r1, #1
bl dvmLineNumFromPC
str r0, [sp, #-4]!
@ dvmGetMethodSourceFile(method)
ldr r0, [rSELF, #offThread_method]
bl dvmGetMethodSourceFile
str r0, [sp, #-4]!
@ exception->clazz->descriptor
ldr r3, [r9, #offObject_clazz]
ldr r3, [r3, #offClassObject_descriptor]
@
ldr r2, strExceptionNotCaughtLocally
0: add r2, pc
ldr r1, strLogTag
1: add r1, pc
mov r0, #3 @ LOG_DEBUG
bl __android_log_print
#endif
str r9, [rSELF, #offThread_exception] @ restore exception
mov r0, r9 @ r0<- exception
mov r1, rSELF @ r1<- self
bl dvmReleaseTrackedAlloc @ release the exception
b common_gotoBail @ bail out
strExceptionNotCaughtLocally:
.word PCREL_REF(.LstrExceptionNotCaughtLocally,0b)
strLogTag:
.word PCREL_REF(.LstrLogTag,1b)
/*
* Exception handling, calls through "glue code".
*/
.if 0
.LexceptionOld:
SAVE_PC_FP_TO_SELF() @ export state
mov r0, rSELF @ arg to function
bl dvmMterp_exceptionThrown
b common_resumeAfterGlueCall
.endif
#if defined(WITH_JIT)
/*
* If the JIT is actively building a trace we need to make sure
* that the field is fully resolved before including the current
* instruction.
*
* On entry:
* r10: &dvmDex->pResFields[field]
* r0: field pointer (must preserve)
*/
common_verifyField:
ldrh r3, [rSELF, #offThread_subMode] @ r3 <- submode byte
ands r3, #kSubModeJitTraceBuild
bxeq lr @ Not building trace, continue
ldr r1, [r10] @ r1<- reload resolved StaticField ptr
cmp r1, #0 @ resolution complete?
bxne lr @ yes, continue
stmfd sp!, {r0-r2,lr} @ save regs
mov r0, rSELF
mov r1, rPC
bl dvmJitEndTraceSelect @ (self,pc) end trace before this inst
ldmfd sp!, {r0-r2, lr}
bx lr @ return
#endif
/*
* After returning from a "glued" function, pull out the updated
* values and start executing at the next instruction.
*/
common_resumeAfterGlueCall:
LOAD_PC_FP_FROM_SELF() @ pull rPC and rFP out of thread
ldr rIBASE, [rSELF, #offThread_curHandlerTable] @ refresh
FETCH_INST() @ load rINST from rPC
GET_INST_OPCODE(ip) @ extract opcode from rINST
GOTO_OPCODE(ip) @ jump to next instruction
/*
* Invalid array index. Note that our calling convention is strange; we use r1
* and r3 because those just happen to be the registers all our callers are
* using. We move r3 before calling the C function, but r1 happens to match.
* r1: index
* r3: size
*/
common_errArrayIndex:
EXPORT_PC()
mov r0, r3
bl dvmThrowArrayIndexOutOfBoundsException
b common_exceptionThrown
/*
* Integer divide or mod by zero.
*/
common_errDivideByZero:
EXPORT_PC()
ldr r0, strDivideByZero
0: add r0, pc
bl dvmThrowArithmeticException
b common_exceptionThrown
strDivideByZero:
.word PCREL_REF(.LstrDivideByZero,0b)
/*
* Attempt to allocate an array with a negative size.
* On entry: length in r1
*/
common_errNegativeArraySize:
EXPORT_PC()
mov r0, r1 @ arg0 <- len
bl dvmThrowNegativeArraySizeException @ (len)
b common_exceptionThrown
/*
* Invocation of a non-existent method.
* On entry: method name in r1
*/
common_errNoSuchMethod:
EXPORT_PC()
mov r0, r1
bl dvmThrowNoSuchMethodError
b common_exceptionThrown
/*
* We encountered a null object when we weren't expecting one. We
* export the PC, throw a NullPointerException, and goto the exception
* processing code.
*/
common_errNullObject:
EXPORT_PC()
mov r0, #0
bl dvmThrowNullPointerException
b common_exceptionThrown
/*
* For debugging, cause an immediate fault. The source address will
* be in lr (use a bl instruction to jump here).
*/
common_abort:
ldr pc, .LdeadFood
.LdeadFood:
.word 0xdeadf00d
/*
* Spit out a "we were here", preserving all registers. (The attempt
* to save ip won't work, but we need to save an even number of
* registers for EABI 64-bit stack alignment.)
*/
.macro SQUEAK num
common_squeak\num:
stmfd sp!, {r0, r1, r2, r3, ip, lr}
ldr r0, strSqueak\num
0: add r0, pc
mov r1, #\num
bl printf
ldmfd sp!, {r0, r1, r2, r3, ip, lr}
bx lr
strSqueak\num:
.word PCREL_REF(.LstrSqueak,0b)
.endm
SQUEAK 0
SQUEAK 1
SQUEAK 2
SQUEAK 3
SQUEAK 4
SQUEAK 5
/*
* Spit out the number in r0, preserving registers.
*/
common_printNum:
stmfd sp!, {r0, r1, r2, r3, ip, lr}
mov r1, r0
ldr r0, strSqueak
0: add r0, pc
bl printf
ldmfd sp!, {r0, r1, r2, r3, ip, lr}
bx lr
strSqueak:
.word PCREL_REF(.LstrSqueak,0b)
/*
* Print a newline, preserving registers.
*/
common_printNewline:
stmfd sp!, {r0, r1, r2, r3, ip, lr}
ldr r0, strNewline
0: add r0, pc
bl printf
ldmfd sp!, {r0, r1, r2, r3, ip, lr}
bx lr
strNewline:
.word PCREL_REF(.LstrNewline,0b)
/*
* Print the 32-bit quantity in r0 as a hex value, preserving registers.
*/
common_printHex:
stmfd sp!, {r0, r1, r2, r3, ip, lr}
mov r1, r0
ldr r0, strPrintHex
0: add r0, pc
bl printf
ldmfd sp!, {r0, r1, r2, r3, ip, lr}
bx lr
strPrintHex:
.word PCREL_REF(.LstrPrintHex,0b)
/*
* Print the 64-bit quantity in r0-r1, preserving registers.
*/
common_printLong:
stmfd sp!, {r0, r1, r2, r3, ip, lr}
mov r3, r1
mov r2, r0
ldr r0, strPrintLong
0: add r0, pc
bl printf
ldmfd sp!, {r0, r1, r2, r3, ip, lr}
bx lr
strPrintLong:
.word PCREL_REF(.LstrPrintLong,0b)
/*
* Print full method info. Pass the Method* in r0. Preserves regs.
*/
common_printMethod:
stmfd sp!, {r0, r1, r2, r3, ip, lr}
bl dvmMterpPrintMethod
ldmfd sp!, {r0, r1, r2, r3, ip, lr}
bx lr
/*
* Call a C helper function that dumps regs and possibly some
* additional info. Requires the C function to be compiled in.
*/
.if 0
common_dumpRegs:
stmfd sp!, {r0, r1, r2, r3, ip, lr}
bl dvmMterpDumpArmRegs
ldmfd sp!, {r0, r1, r2, r3, ip, lr}
bx lr
.endif
#if 0
/*
* Experiment on VFP mode.
*
* uint32_t setFPSCR(uint32_t val, uint32_t mask)
*
* Updates the bits specified by "mask", setting them to the values in "val".
*/
setFPSCR:
and r0, r0, r1 @ make sure no stray bits are set
fmrx r2, fpscr @ get VFP reg
mvn r1, r1 @ bit-invert mask
and r2, r2, r1 @ clear masked bits
orr r2, r2, r0 @ set specified bits
fmxr fpscr, r2 @ set VFP reg
mov r0, r2 @ return new value
bx lr
.align 2
.global dvmConfigureFP
.type dvmConfigureFP, %function
dvmConfigureFP:
stmfd sp!, {ip, lr}
/* 0x03000000 sets DN/FZ */
/* 0x00009f00 clears the six exception enable flags */
bl common_squeak0
mov r0, #0x03000000 @ r0<- 0x03000000
add r1, r0, #0x9f00 @ r1<- 0x03009f00
bl setFPSCR
ldmfd sp!, {ip, pc}
#endif
/*
* Zero-terminated ASCII string data.
*
* On ARM we have two choices: do like gcc does, and LDR from a .word
* with the address, or use an ADR pseudo-op to get the address
* directly. ADR saves 4 bytes and an indirection, but it's using a
* PC-relative addressing mode and hence has a limited range, which
* makes it not work well with mergeable string sections.
*/
.section .rodata.str1.4,"aMS",%progbits,1
.LstrBadEntryPoint:
.asciz "Bad entry point %d\n"
.LstrFilledNewArrayNotImpl:
.asciz "filled-new-array only implemented for objects and 'int'"
.LstrDivideByZero:
.asciz "divide by zero"
.LstrLogTag:
.asciz "mterp"
.LstrExceptionNotCaughtLocally:
.asciz "Exception %s from %s:%d not caught locally\n"
.LstrNewline:
.asciz "\n"
.LstrSqueak:
.asciz "<%d>"
.LstrPrintHex:
.asciz "<%#x>"
.LstrPrintLong:
.asciz "<%lld>"