%def header(): /* * Copyright (C) 2016 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. */ /* Art assembly interpreter notes: First validate assembly code by implementing ExecuteXXXImpl() style body (doesn't handle invoke, allows higher-level code to create frame & shadow frame. Once that's working, support direct entry code & eliminate shadow frame (and excess locals allocation. Some (hopefully) temporary ugliness. We'll treat rFP as pointing to the base of the vreg array within the shadow frame. Access the other fields, dex_pc_, method_ and number_of_vregs_ via negative offsets. For now, we'll continue the shadow frame mechanism of double-storing object references - via rFP & number_of_vregs_. */ /* ARM EABI general notes: r0-r3 hold first 4 args to a method; they are not preserved across method calls r4-r8 are available for general use r9 is given special treatment in some situations, but not for us r10 (sl) seems to be generally available r11 (fp) is used by gcc (unless -fomit-frame-pointer is set) r12 (ip) is scratch -- not preserved across method calls r13 (sp) should be managed carefully in case a signal arrives r14 (lr) must be preserved r15 (pc) can be tinkered with directly r0 holds returns of <= 4 bytes r0-r1 hold returns of 8 bytes, low word in r0 Callee must save/restore r4+ (except r12) if it modifies them. If VFP is present, registers s16-s31 (a/k/a d8-d15, a/k/a q4-q7) must be preserved, s0-s15 (d0-d7, q0-a3) do not need to be. Stack is "full descending". Only the arguments that don't fit in the first 4 registers are placed on the stack. "sp" points at the first stacked argument (i.e. the 5th arg). VFP: single-precision results in s0, double-precision results in d0. In the EABI, "sp" must be 64-bit aligned on entry to a function, and any 64-bit quantities (long long, double) must be 64-bit aligned. */ /* Mterp and ARM notes: The following registers have fixed assignments: reg nick purpose r4 rPC interpreted program counter, used for fetching instructions r5 rFP interpreted frame pointer, used for accessing locals and args r6 rSELF self (Thread) pointer r7 rINST first 16-bit code unit of current instruction r8 rIBASE interpreted instruction base pointer, used for computed goto r10 rPROFILE branch profiling countdown r11 rREFS base of object references in shadow frame (ideally, we'll get rid of this later). Macros are provided for common operations. Each macro MUST emit only one instruction to make instruction-counting easier. They MUST NOT alter unspecified registers or condition codes. */ /* * This is a #include, not a %include, because we want the C pre-processor * to expand the macros into assembler assignment statements. */ #include "asm_support.h" #include "interpreter/cfi_asm_support.h" #define MTERP_PROFILE_BRANCHES 1 #define MTERP_LOGGING 0 /* During bringup, we'll use the shadow frame model instead of rFP */ /* single-purpose registers, given names for clarity */ #define rPC r4 #define CFI_DEX 4 // DWARF register number of the register holding dex-pc (xPC). #define CFI_TMP 0 // DWARF register number of the first argument register (r0). #define rFP r5 #define rSELF r6 #define rINST r7 #define rIBASE r8 #define rPROFILE r10 #define rREFS r11 /* * Instead of holding a pointer to the shadow frame, we keep rFP at the base of the vregs. So, * to access other shadow frame fields, we need to use a backwards offset. Define those here. */ #define OFF_FP(a) (a - SHADOWFRAME_VREGS_OFFSET) #define OFF_FP_NUMBER_OF_VREGS OFF_FP(SHADOWFRAME_NUMBER_OF_VREGS_OFFSET) #define OFF_FP_DEX_PC OFF_FP(SHADOWFRAME_DEX_PC_OFFSET) #define OFF_FP_LINK OFF_FP(SHADOWFRAME_LINK_OFFSET) #define OFF_FP_METHOD OFF_FP(SHADOWFRAME_METHOD_OFFSET) #define OFF_FP_RESULT_REGISTER OFF_FP(SHADOWFRAME_RESULT_REGISTER_OFFSET) #define OFF_FP_DEX_PC_PTR OFF_FP(SHADOWFRAME_DEX_PC_PTR_OFFSET) #define OFF_FP_DEX_INSTRUCTIONS OFF_FP(SHADOWFRAME_DEX_INSTRUCTIONS_OFFSET) #define OFF_FP_SHADOWFRAME OFF_FP(0) /* * "export" the PC to dex_pc field in the shadow frame, f/b/o future exception objects. Must * be done *before* something throws. * * It's okay to do this more than once. * * NOTE: the fast interpreter keeps track of dex pc as a direct pointer to the mapped * dex byte codes. However, the rest of the runtime expects dex pc to be an instruction * offset into the code_items_[] array. For effiency, we will "export" the * current dex pc as a direct pointer using the EXPORT_PC macro, and rely on GetDexPC * to convert to a dex pc when needed. */ .macro EXPORT_PC str rPC, [rFP, #OFF_FP_DEX_PC_PTR] .endm .macro EXPORT_DEX_PC tmp ldr \tmp, [rFP, #OFF_FP_DEX_INSTRUCTIONS] str rPC, [rFP, #OFF_FP_DEX_PC_PTR] sub \tmp, rPC, \tmp asr \tmp, #1 str \tmp, [rFP, #OFF_FP_DEX_PC] .endm /* * Fetch the next instruction from rPC into rINST. Does not advance rPC. */ .macro FETCH_INST ldrh rINST, [rPC] .endm /* * Fetch the next instruction from the specified offset. Advances rPC * to point to the next instruction. "_count" is in 16-bit code units. * * Because of the limited size of immediate constants on ARM, this is only * suitable for small forward movements (i.e. don't try to implement "goto" * with this). * * This must come AFTER anything that can throw an exception, or the * exception catch may miss. (This also implies that it must come after * EXPORT_PC.) */ .macro FETCH_ADVANCE_INST count ldrh rINST, [rPC, #((\count)*2)]! .endm /* * The operation performed here is similar to FETCH_ADVANCE_INST, except the * src and dest registers are parameterized (not hard-wired to rPC and rINST). */ .macro PREFETCH_ADVANCE_INST dreg, sreg, count ldrh \dreg, [\sreg, #((\count)*2)]! .endm /* * Similar to FETCH_ADVANCE_INST, but does not update rPC. Used to load * rINST ahead of possible exception point. Be sure to manually advance rPC * later. */ .macro PREFETCH_INST count ldrh rINST, [rPC, #((\count)*2)] .endm /* Advance rPC by some number of code units. */ .macro ADVANCE count add rPC, #((\count)*2) .endm /* * Fetch the next instruction from an offset specified by _reg. Updates * rPC to point to the next instruction. "_reg" must specify the distance * in bytes, *not* 16-bit code units, and may be a signed value. * * We want to write "ldrh rINST, [rPC, _reg, lsl #1]!", but some of the * bits that hold the shift distance are used for the half/byte/sign flags. * In some cases we can pre-double _reg for free, so we require a byte offset * here. */ .macro FETCH_ADVANCE_INST_RB reg ldrh rINST, [rPC, \reg]! .endm /* * Fetch a half-word code unit from an offset past the current PC. The * "_count" value is in 16-bit code units. Does not advance rPC. * * The "_S" variant works the same but treats the value as signed. */ .macro FETCH reg, count ldrh \reg, [rPC, #((\count)*2)] .endm .macro FETCH_S reg, count ldrsh \reg, [rPC, #((\count)*2)] .endm /* * Fetch one byte from an offset past the current PC. Pass in the same * "_count" as you would for FETCH, and an additional 0/1 indicating which * byte of the halfword you want (lo/hi). */ .macro FETCH_B reg, count, byte ldrb \reg, [rPC, #((\count)*2+(\byte))] .endm /* * Put the instruction's opcode field into the specified register. */ .macro GET_INST_OPCODE reg and \reg, rINST, #255 .endm /* * Put the prefetched instruction's opcode field into the specified register. */ .macro GET_PREFETCHED_OPCODE oreg, ireg and \oreg, \ireg, #255 .endm /* * Begin executing the opcode in _reg. Because this only jumps within the * interpreter, we don't have to worry about pre-ARMv5 THUMB interwork. */ .macro GOTO_OPCODE reg add pc, rIBASE, \reg, lsl #${handler_size_bits} .endm .macro GOTO_OPCODE_BASE base,reg add pc, \base, \reg, lsl #${handler_size_bits} .endm /* * Get/set the 32-bit value from a Dalvik register. */ .macro GET_VREG reg, vreg ldr \reg, [rFP, \vreg, lsl #2] .endm .macro SET_VREG reg, vreg str \reg, [rFP, \vreg, lsl #2] mov \reg, #0 str \reg, [rREFS, \vreg, lsl #2] .endm .macro SET_VREG_WIDE regLo, regHi, vreg add ip, rFP, \vreg, lsl #2 strd \regLo, \regHi, [ip] mov \regLo, #0 mov \regHi, #0 add ip, rREFS, \vreg, lsl #2 strd \regLo, \regHi, [ip] .endm .macro SET_VREG_OBJECT reg, vreg, tmpreg str \reg, [rFP, \vreg, lsl #2] str \reg, [rREFS, \vreg, lsl #2] .endm .macro SET_VREG_SHADOW reg, vreg str \reg, [rREFS, \vreg, lsl #2] .endm .macro SET_VREG_FLOAT reg, vreg, tmpreg add \tmpreg, rFP, \vreg, lsl #2 fsts \reg, [\tmpreg] mov \tmpreg, #0 str \tmpreg, [rREFS, \vreg, lsl #2] .endm /* * Clear the corresponding shadow regs for a vreg pair */ .macro CLEAR_SHADOW_PAIR vreg, tmp1, tmp2 mov \tmp1, #0 add \tmp2, \vreg, #1 SET_VREG_SHADOW \tmp1, \vreg SET_VREG_SHADOW \tmp1, \tmp2 .endm /* * Convert a virtual register index into an address. */ .macro VREG_INDEX_TO_ADDR reg, vreg add \reg, rFP, \vreg, lsl #2 /* WARNING/FIXME: handle shadow frame vreg zero if store */ .endm .macro GET_VREG_WIDE_BY_ADDR reg0, reg1, addr ldmia \addr, {\reg0, \reg1} .endm .macro SET_VREG_WIDE_BY_ADDR reg0, reg1, addr stmia \addr, {\reg0, \reg1} .endm .macro GET_VREG_FLOAT_BY_ADDR reg, addr flds \reg, [\addr] .endm .macro SET_VREG_FLOAT_BY_ADDR reg, addr fsts \reg, [\addr] .endm .macro GET_VREG_DOUBLE_BY_ADDR reg, addr fldd \reg, [\addr] .endm .macro SET_VREG_DOUBLE_BY_ADDR reg, addr fstd \reg, [\addr] .endm /* * Refresh handler table. */ .macro REFRESH_IBASE ldr rIBASE, [rSELF, #THREAD_CURRENT_IBASE_OFFSET] .endm /* * function support macros. */ .macro ENTRY name .arm .type \name, #function .hidden \name // Hide this as a global symbol, so we do not incur plt calls. .global \name /* Cache alignment for function entry */ .balign 16 \name: .endm .macro END name .size \name, .-\name .endm // Macro to unpoison (negate) the reference for heap poisoning. .macro UNPOISON_HEAP_REF rRef #ifdef USE_HEAP_POISONING rsb \rRef, \rRef, #0 #endif // USE_HEAP_POISONING .endm %def entry(): /* * Copyright (C) 2016 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. */ /* * Interpreter entry point. */ .text .align 2 /* * On entry: * r0 Thread* self/ * r1 insns_ * r2 ShadowFrame * r3 JValue* result_register * */ ENTRY ExecuteMterpImpl .cfi_startproc stmfd sp!, {r3-r10,fp,lr} @ save 10 regs, (r3 just to align 64) .cfi_adjust_cfa_offset 40 .cfi_rel_offset r3, 0 .cfi_rel_offset r4, 4 .cfi_rel_offset r5, 8 .cfi_rel_offset r6, 12 .cfi_rel_offset r7, 16 .cfi_rel_offset r8, 20 .cfi_rel_offset r9, 24 .cfi_rel_offset r10, 28 .cfi_rel_offset fp, 32 .cfi_rel_offset lr, 36 /* Remember the return register */ str r3, [r2, #SHADOWFRAME_RESULT_REGISTER_OFFSET] /* Remember the dex instruction pointer */ str r1, [r2, #SHADOWFRAME_DEX_INSTRUCTIONS_OFFSET] /* set up "named" registers */ mov rSELF, r0 ldr r0, [r2, #SHADOWFRAME_NUMBER_OF_VREGS_OFFSET] add rFP, r2, #SHADOWFRAME_VREGS_OFFSET @ point to vregs. VREG_INDEX_TO_ADDR rREFS, r0 @ point to reference array in shadow frame ldr r0, [r2, #SHADOWFRAME_DEX_PC_OFFSET] @ Get starting dex_pc. add rPC, r1, r0, lsl #1 @ Create direct pointer to 1st dex opcode CFI_DEFINE_DEX_PC_WITH_OFFSET(CFI_TMP, CFI_DEX, 0) EXPORT_PC /* Starting ibase */ ldr rIBASE, [rSELF, #THREAD_CURRENT_IBASE_OFFSET] /* Set up for backwards branches & osr profiling */ ldr r0, [rFP, #OFF_FP_METHOD] add r1, rFP, #OFF_FP_SHADOWFRAME mov r2, rSELF bl MterpSetUpHotnessCountdown mov rPROFILE, r0 @ Starting hotness countdown to rPROFILE /* start executing the instruction at rPC */ FETCH_INST @ load rINST from rPC GET_INST_OPCODE ip @ extract opcode from rINST GOTO_OPCODE ip @ jump to next instruction /* NOTE: no fallthrough */ // cfi info continues, and covers the whole mterp implementation. END ExecuteMterpImpl %def dchecks_before_helper(): // Call C++ to do debug checks and return to the handler using tail call. .extern MterpCheckBefore mov r0, rSELF add r1, rFP, #OFF_FP_SHADOWFRAME mov r2, rPC b MterpCheckBefore @ (self, shadow_frame, dex_pc_ptr) @ Tail call. %def opcode_pre(): % add_helper(dchecks_before_helper, "mterp_dchecks_before_helper") #if !defined(NDEBUG) bl mterp_dchecks_before_helper #endif %def fallback(): /* Transfer stub to alternate interpreter */ b MterpFallback %def helpers(): ENTRY MterpHelpers %def footer(): /* * =========================================================================== * Common subroutines and data * =========================================================================== */ .text .align 2 /* * We've detected a condition that will result in an exception, but the exception * has not yet been thrown. Just bail out to the reference interpreter to deal with it. * TUNING: for consistency, we may want to just go ahead and handle these here. */ common_errDivideByZero: EXPORT_PC #if MTERP_LOGGING mov r0, rSELF add r1, rFP, #OFF_FP_SHADOWFRAME bl MterpLogDivideByZeroException #endif b MterpCommonFallback common_errArrayIndex: EXPORT_PC #if MTERP_LOGGING mov r0, rSELF add r1, rFP, #OFF_FP_SHADOWFRAME bl MterpLogArrayIndexException #endif b MterpCommonFallback common_errNegativeArraySize: EXPORT_PC #if MTERP_LOGGING mov r0, rSELF add r1, rFP, #OFF_FP_SHADOWFRAME bl MterpLogNegativeArraySizeException #endif b MterpCommonFallback common_errNoSuchMethod: EXPORT_PC #if MTERP_LOGGING mov r0, rSELF add r1, rFP, #OFF_FP_SHADOWFRAME bl MterpLogNoSuchMethodException #endif b MterpCommonFallback common_errNullObject: EXPORT_PC #if MTERP_LOGGING mov r0, rSELF add r1, rFP, #OFF_FP_SHADOWFRAME bl MterpLogNullObjectException #endif b MterpCommonFallback common_exceptionThrown: EXPORT_PC #if MTERP_LOGGING mov r0, rSELF add r1, rFP, #OFF_FP_SHADOWFRAME bl MterpLogExceptionThrownException #endif b MterpCommonFallback MterpSuspendFallback: EXPORT_PC #if MTERP_LOGGING mov r0, rSELF add r1, rFP, #OFF_FP_SHADOWFRAME ldr r2, [rSELF, #THREAD_FLAGS_OFFSET] bl MterpLogSuspendFallback #endif b MterpCommonFallback /* * If we're here, something is out of the ordinary. If there is a pending * exception, handle it. Otherwise, roll back and retry with the reference * interpreter. */ MterpPossibleException: ldr r0, [rSELF, #THREAD_EXCEPTION_OFFSET] cmp r0, #0 @ Exception pending? beq MterpFallback @ If not, fall back to reference interpreter. /* intentional fallthrough - handle pending exception. */ /* * On return from a runtime helper routine, we've found a pending exception. * Can we handle it here - or need to bail out to caller? * */ MterpException: mov r0, rSELF add r1, rFP, #OFF_FP_SHADOWFRAME bl MterpHandleException @ (self, shadow_frame) cmp r0, #0 beq MterpExceptionReturn @ no local catch, back to caller. ldr r0, [rFP, #OFF_FP_DEX_INSTRUCTIONS] ldr r1, [rFP, #OFF_FP_DEX_PC] ldr rIBASE, [rSELF, #THREAD_CURRENT_IBASE_OFFSET] add rPC, r0, r1, lsl #1 @ generate new dex_pc_ptr /* Do we need to switch interpreters? */ ldr r0, [rSELF, #THREAD_USE_MTERP_OFFSET] cmp r0, #0 beq MterpFallback /* resume execution at catch block */ EXPORT_PC FETCH_INST GET_INST_OPCODE ip GOTO_OPCODE ip /* NOTE: no fallthrough */ /* * Common handling for branches with support for Jit profiling. * On entry: * rINST <= signed offset * rPROFILE <= signed hotness countdown (expanded to 32 bits) * condition bits <= set to establish sign of offset (use "NoFlags" entry if not) * * We have quite a few different cases for branch profiling, OSR detection and * suspend check support here. * * Taken backward branches: * If profiling active, do hotness countdown and report if we hit zero. * If in osr check mode, see if our target is a compiled loop header entry and do OSR if so. * Is there a pending suspend request? If so, suspend. * * Taken forward branches and not-taken backward branches: * If in osr check mode, see if our target is a compiled loop header entry and do OSR if so. * * Our most common case is expected to be a taken backward branch with active jit profiling, * but no full OSR check and no pending suspend request. * Next most common case is not-taken branch with no full OSR check. * */ MterpCommonTakenBranchNoFlags: cmp rINST, #0 MterpCommonTakenBranch: bgt .L_forward_branch @ don't add forward branches to hotness /* * We need to subtract 1 from positive values and we should not see 0 here, * so we may use the result of the comparison with -1. */ #if JIT_CHECK_OSR != -1 # error "JIT_CHECK_OSR must be -1." #endif cmp rPROFILE, #JIT_CHECK_OSR beq .L_osr_check subsgt rPROFILE, #1 beq .L_add_batch @ counted down to zero - report .L_resume_backward_branch: ldr lr, [rSELF, #THREAD_FLAGS_OFFSET] REFRESH_IBASE add r2, rINST, rINST @ r2<- byte offset FETCH_ADVANCE_INST_RB r2 @ update rPC, load rINST ands lr, #THREAD_SUSPEND_OR_CHECKPOINT_REQUEST bne .L_suspend_request_pending GET_INST_OPCODE ip @ extract opcode from rINST GOTO_OPCODE ip @ jump to next instruction .L_suspend_request_pending: EXPORT_PC mov r0, rSELF bl MterpSuspendCheck @ (self) cmp r0, #0 bne MterpFallback REFRESH_IBASE @ might have changed during suspend GET_INST_OPCODE ip @ extract opcode from rINST GOTO_OPCODE ip @ jump to next instruction .L_no_count_backwards: cmp rPROFILE, #JIT_CHECK_OSR @ possible OSR re-entry? bne .L_resume_backward_branch .L_osr_check: mov r0, rSELF add r1, rFP, #OFF_FP_SHADOWFRAME mov r2, rINST EXPORT_PC bl MterpMaybeDoOnStackReplacement @ (self, shadow_frame, offset) cmp r0, #0 bne MterpOnStackReplacement b .L_resume_backward_branch .L_forward_branch: cmp rPROFILE, #JIT_CHECK_OSR @ possible OSR re-entry? beq .L_check_osr_forward .L_resume_forward_branch: add r2, rINST, rINST @ r2<- byte offset FETCH_ADVANCE_INST_RB r2 @ update rPC, load rINST GET_INST_OPCODE ip @ extract opcode from rINST GOTO_OPCODE ip @ jump to next instruction .L_check_osr_forward: mov r0, rSELF add r1, rFP, #OFF_FP_SHADOWFRAME mov r2, rINST EXPORT_PC bl MterpMaybeDoOnStackReplacement @ (self, shadow_frame, offset) cmp r0, #0 bne MterpOnStackReplacement b .L_resume_forward_branch .L_add_batch: add r1, rFP, #OFF_FP_SHADOWFRAME strh rPROFILE, [r1, #SHADOWFRAME_HOTNESS_COUNTDOWN_OFFSET] ldr r0, [rFP, #OFF_FP_METHOD] mov r2, rSELF bl MterpAddHotnessBatch @ (method, shadow_frame, self) mov rPROFILE, r0 @ restore new hotness countdown to rPROFILE b .L_no_count_backwards /* * Entered from the conditional branch handlers when OSR check request active on * not-taken path. All Dalvik not-taken conditional branch offsets are 2. */ .L_check_not_taken_osr: mov r0, rSELF add r1, rFP, #OFF_FP_SHADOWFRAME mov r2, #2 EXPORT_PC bl MterpMaybeDoOnStackReplacement @ (self, shadow_frame, offset) cmp r0, #0 bne MterpOnStackReplacement FETCH_ADVANCE_INST 2 GET_INST_OPCODE ip @ extract opcode from rINST GOTO_OPCODE ip @ jump to next instruction /* * On-stack replacement has happened, and now we've returned from the compiled method. */ MterpOnStackReplacement: #if MTERP_LOGGING mov r0, rSELF add r1, rFP, #OFF_FP_SHADOWFRAME mov r2, rINST bl MterpLogOSR #endif mov r0, #1 @ Signal normal return b MterpDone /* * Bail out to reference interpreter. */ MterpFallback: EXPORT_PC #if MTERP_LOGGING mov r0, rSELF add r1, rFP, #OFF_FP_SHADOWFRAME bl MterpLogFallback #endif MterpCommonFallback: mov r0, #0 @ signal retry with reference interpreter. b MterpDone /* * We pushed some registers on the stack in ExecuteMterpImpl, then saved * SP and LR. Here we restore SP, restore the registers, and then restore * LR to PC. * * On entry: * uint32_t* rFP (should still be live, pointer to base of vregs) */ MterpExceptionReturn: mov r0, #1 @ signal return to caller. b MterpDone MterpReturn: ldr r2, [rFP, #OFF_FP_RESULT_REGISTER] str r0, [r2] str r1, [r2, #4] mov r0, #1 @ signal return to caller. MterpDone: /* * At this point, we expect rPROFILE to be non-zero. If negative, hotness is disabled or we're * checking for OSR. If greater than zero, we might have unreported hotness to register * (the difference between the ending rPROFILE and the cached hotness counter). rPROFILE * should only reach zero immediately after a hotness decrement, and is then reset to either * a negative special state or the new non-zero countdown value. */ cmp rPROFILE, #0 bgt MterpProfileActive @ if > 0, we may have some counts to report. ldmfd sp!, {r3-r10,fp,pc} @ restore 10 regs and return MterpProfileActive: mov rINST, r0 @ stash return value /* Report cached hotness counts */ ldr r0, [rFP, #OFF_FP_METHOD] add r1, rFP, #OFF_FP_SHADOWFRAME mov r2, rSELF strh rPROFILE, [r1, #SHADOWFRAME_HOTNESS_COUNTDOWN_OFFSET] bl MterpAddHotnessBatch @ (method, shadow_frame, self) mov r0, rINST @ restore return value ldmfd sp!, {r3-r10,fp,pc} @ restore 10 regs and return .cfi_endproc END MterpHelpers %def instruction_end(): .type artMterpAsmInstructionEnd, #object .hidden artMterpAsmInstructionEnd .global artMterpAsmInstructionEnd artMterpAsmInstructionEnd: %def instruction_start(): .type artMterpAsmInstructionStart, #object .hidden artMterpAsmInstructionStart .global artMterpAsmInstructionStart artMterpAsmInstructionStart = .L_op_nop .text %def default_helper_prefix(): % return "mterp_" %def opcode_start(): ENTRY mterp_${opcode} %def opcode_end(): END mterp_${opcode} %def helper_start(name): ENTRY ${name} %def helper_end(name): END ${name}