|// Low-level VM code for MIPS CPUs. |// Bytecode interpreter, fast functions and helper functions. |// Copyright (C) 2005-2022 Mike Pall. See Copyright Notice in luajit.h |// |// MIPS soft-float support contributed by Djordje Kovacevic and |// Stefan Pejic from RT-RK.com, sponsored by Cisco Systems, Inc. | |.arch mips |.section code_op, code_sub | |.actionlist build_actionlist |.globals GLOB_ |.globalnames globnames |.externnames extnames | |// Note: The ragged indentation of the instructions is intentional. |// The starting columns indicate data dependencies. | |//----------------------------------------------------------------------- | |// Fixed register assignments for the interpreter. |// Don't use: r0 = 0, r26/r27 = reserved, r28 = gp, r29 = sp, r31 = ra | |.macro .FPU, a, b |.if FPU | a, b |.endif |.endmacro | |// The following must be C callee-save (but BASE is often refetched). |.define BASE, r16 // Base of current Lua stack frame. |.define KBASE, r17 // Constants of current Lua function. |.define PC, r18 // Next PC. |.define DISPATCH, r19 // Opcode dispatch table. |.define LREG, r20 // Register holding lua_State (also in SAVE_L). |.define MULTRES, r21 // Size of multi-result: (nresults+1)*8. | |.define JGL, r30 // On-trace: global_State + 32768. | |// Constants for type-comparisons, stores and conversions. C callee-save. |.define TISNUM, r22 |.define TISNIL, r30 |.if FPU |.define TOBIT, f30 // 2^52 + 2^51. |.endif | |// The following temporaries are not saved across C calls, except for RA. |.define RA, r23 // Callee-save. |.define RB, r8 |.define RC, r9 |.define RD, r10 |.define INS, r11 | |.define AT, r1 // Assembler temporary. |.define TMP0, r12 |.define TMP1, r13 |.define TMP2, r14 |.define TMP3, r15 | |// MIPS o32 calling convention. |.define CFUNCADDR, r25 |.define CARG1, r4 |.define CARG2, r5 |.define CARG3, r6 |.define CARG4, r7 | |.define CRET1, r2 |.define CRET2, r3 | |.if ENDIAN_LE |.define SFRETLO, CRET1 |.define SFRETHI, CRET2 |.define SFARG1LO, CARG1 |.define SFARG1HI, CARG2 |.define SFARG2LO, CARG3 |.define SFARG2HI, CARG4 |.else |.define SFRETLO, CRET2 |.define SFRETHI, CRET1 |.define SFARG1LO, CARG2 |.define SFARG1HI, CARG1 |.define SFARG2LO, CARG4 |.define SFARG2HI, CARG3 |.endif | |.if FPU |.define FARG1, f12 |.define FARG2, f14 | |.define FRET1, f0 |.define FRET2, f2 |.endif | |// Stack layout while in interpreter. Must match with lj_frame.h. |.if FPU // MIPS32 hard-float. | |.define CFRAME_SPACE, 112 // Delta for sp. | |.define SAVE_ERRF, 124(sp) // 32 bit C frame info. |.define SAVE_NRES, 120(sp) |.define SAVE_CFRAME, 116(sp) |.define SAVE_L, 112(sp) |//----- 8 byte aligned, ^^^^ 16 byte register save area, owned by interpreter. |.define SAVE_GPR_, 72 // .. 72+10*4: 32 bit GPR saves. |.define SAVE_FPR_, 24 // .. 24+6*8: 64 bit FPR saves. | |.else // MIPS32 soft-float | |.define CFRAME_SPACE, 64 // Delta for sp. | |.define SAVE_ERRF, 76(sp) // 32 bit C frame info. |.define SAVE_NRES, 72(sp) |.define SAVE_CFRAME, 68(sp) |.define SAVE_L, 64(sp) |//----- 8 byte aligned, ^^^^ 16 byte register save area, owned by interpreter. |.define SAVE_GPR_, 24 // .. 24+10*4: 32 bit GPR saves. | |.endif | |.define SAVE_PC, 20(sp) |.define ARG5, 16(sp) |.define CSAVE_4, 12(sp) |.define CSAVE_3, 8(sp) |.define CSAVE_2, 4(sp) |.define CSAVE_1, 0(sp) |//----- 8 byte aligned, ^^^^ 16 byte register save area, owned by callee. | |.define ARG5_OFS, 16 |.define SAVE_MULTRES, ARG5 | |//----------------------------------------------------------------------- | |.macro saveregs | addiu sp, sp, -CFRAME_SPACE | sw ra, SAVE_GPR_+9*4(sp) | sw r30, SAVE_GPR_+8*4(sp) | .FPU sdc1 f30, SAVE_FPR_+5*8(sp) | sw r23, SAVE_GPR_+7*4(sp) | sw r22, SAVE_GPR_+6*4(sp) | .FPU sdc1 f28, SAVE_FPR_+4*8(sp) | sw r21, SAVE_GPR_+5*4(sp) | sw r20, SAVE_GPR_+4*4(sp) | .FPU sdc1 f26, SAVE_FPR_+3*8(sp) | sw r19, SAVE_GPR_+3*4(sp) | sw r18, SAVE_GPR_+2*4(sp) | .FPU sdc1 f24, SAVE_FPR_+2*8(sp) | sw r17, SAVE_GPR_+1*4(sp) | sw r16, SAVE_GPR_+0*4(sp) | .FPU sdc1 f22, SAVE_FPR_+1*8(sp) | .FPU sdc1 f20, SAVE_FPR_+0*8(sp) |.endmacro | |.macro restoreregs_ret | lw ra, SAVE_GPR_+9*4(sp) | lw r30, SAVE_GPR_+8*4(sp) | .FPU ldc1 f30, SAVE_FPR_+5*8(sp) | lw r23, SAVE_GPR_+7*4(sp) | lw r22, SAVE_GPR_+6*4(sp) | .FPU ldc1 f28, SAVE_FPR_+4*8(sp) | lw r21, SAVE_GPR_+5*4(sp) | lw r20, SAVE_GPR_+4*4(sp) | .FPU ldc1 f26, SAVE_FPR_+3*8(sp) | lw r19, SAVE_GPR_+3*4(sp) | lw r18, SAVE_GPR_+2*4(sp) | .FPU ldc1 f24, SAVE_FPR_+2*8(sp) | lw r17, SAVE_GPR_+1*4(sp) | lw r16, SAVE_GPR_+0*4(sp) | .FPU ldc1 f22, SAVE_FPR_+1*8(sp) | .FPU ldc1 f20, SAVE_FPR_+0*8(sp) | jr ra | addiu sp, sp, CFRAME_SPACE |.endmacro | |// Type definitions. Some of these are only used for documentation. |.type L, lua_State, LREG |.type GL, global_State |.type TVALUE, TValue |.type GCOBJ, GCobj |.type STR, GCstr |.type TAB, GCtab |.type LFUNC, GCfuncL |.type CFUNC, GCfuncC |.type PROTO, GCproto |.type UPVAL, GCupval |.type NODE, Node |.type NARGS8, int |.type TRACE, GCtrace |.type SBUF, SBuf | |//----------------------------------------------------------------------- | |// Trap for not-yet-implemented parts. |.macro NYI; .long 0xec1cf0f0; .endmacro | |// Macros to mark delay slots. |.macro ., a; a; .endmacro |.macro ., a,b; a,b; .endmacro |.macro ., a,b,c; a,b,c; .endmacro | |//----------------------------------------------------------------------- | |// Endian-specific defines. |.if ENDIAN_LE |.define FRAME_PC, -4 |.define FRAME_FUNC, -8 |.define HI, 4 |.define LO, 0 |.define OFS_RD, 2 |.define OFS_RA, 1 |.define OFS_OP, 0 |.else |.define FRAME_PC, -8 |.define FRAME_FUNC, -4 |.define HI, 0 |.define LO, 4 |.define OFS_RD, 0 |.define OFS_RA, 2 |.define OFS_OP, 3 |.endif | |// Instruction decode. |.macro decode_OP1, dst, ins; andi dst, ins, 0xff; .endmacro |.macro decode_OP4a, dst, ins; andi dst, ins, 0xff; .endmacro |.macro decode_OP4b, dst; sll dst, dst, 2; .endmacro |.macro decode_RC4a, dst, ins; srl dst, ins, 14; .endmacro |.macro decode_RC4b, dst; andi dst, dst, 0x3fc; .endmacro |.macro decode_RD4b, dst; sll dst, dst, 2; .endmacro |.macro decode_RA8a, dst, ins; srl dst, ins, 5; .endmacro |.macro decode_RA8b, dst; andi dst, dst, 0x7f8; .endmacro |.macro decode_RB8a, dst, ins; srl dst, ins, 21; .endmacro |.macro decode_RB8b, dst; andi dst, dst, 0x7f8; .endmacro |.macro decode_RD8a, dst, ins; srl dst, ins, 16; .endmacro |.macro decode_RD8b, dst; sll dst, dst, 3; .endmacro |.macro decode_RDtoRC8, dst, src; andi dst, src, 0x7f8; .endmacro | |// Instruction fetch. |.macro ins_NEXT1 | lw INS, 0(PC) | addiu PC, PC, 4 |.endmacro |// Instruction decode+dispatch. |.macro ins_NEXT2 | decode_OP4a TMP1, INS | decode_OP4b TMP1 | addu TMP0, DISPATCH, TMP1 | decode_RD8a RD, INS | lw AT, 0(TMP0) | decode_RA8a RA, INS | decode_RD8b RD | jr AT | decode_RA8b RA |.endmacro |.macro ins_NEXT | ins_NEXT1 | ins_NEXT2 |.endmacro | |// Instruction footer. |.if 1 | // Replicated dispatch. Less unpredictable branches, but higher I-Cache use. | .define ins_next, ins_NEXT | .define ins_next_, ins_NEXT | .define ins_next1, ins_NEXT1 | .define ins_next2, ins_NEXT2 |.else | // Common dispatch. Lower I-Cache use, only one (very) unpredictable branch. | // Affects only certain kinds of benchmarks (and only with -j off). | .macro ins_next | b ->ins_next | .endmacro | .macro ins_next1 | .endmacro | .macro ins_next2 | b ->ins_next | .endmacro | .macro ins_next_ | ->ins_next: | ins_NEXT | .endmacro |.endif | |// Call decode and dispatch. |.macro ins_callt | // BASE = new base, RB = LFUNC/CFUNC, RC = nargs*8, FRAME_PC(BASE) = PC | lw PC, LFUNC:RB->pc | lw INS, 0(PC) | addiu PC, PC, 4 | decode_OP4a TMP1, INS | decode_RA8a RA, INS | decode_OP4b TMP1 | decode_RA8b RA | addu TMP0, DISPATCH, TMP1 | lw TMP0, 0(TMP0) | jr TMP0 | addu RA, RA, BASE |.endmacro | |.macro ins_call | // BASE = new base, RB = LFUNC/CFUNC, RC = nargs*8, PC = caller PC | sw PC, FRAME_PC(BASE) | ins_callt |.endmacro | |//----------------------------------------------------------------------- | |.macro branch_RD | srl TMP0, RD, 1 | lui AT, (-(BCBIAS_J*4 >> 16) & 65535) | addu TMP0, TMP0, AT | addu PC, PC, TMP0 |.endmacro | |// Assumes DISPATCH is relative to GL. #define DISPATCH_GL(field) (GG_DISP2G + (int)offsetof(global_State, field)) #define DISPATCH_J(field) (GG_DISP2J + (int)offsetof(jit_State, field)) #define GG_DISP2GOT (GG_OFS(got) - GG_OFS(dispatch)) #define DISPATCH_GOT(name) (GG_DISP2GOT + 4*LJ_GOT_##name) | #define PC2PROTO(field) ((int)offsetof(GCproto, field)-(int)sizeof(GCproto)) | |.macro load_got, func | lw CFUNCADDR, DISPATCH_GOT(func)(DISPATCH) |.endmacro |// Much faster. Sadly, there's no easy way to force the required code layout. |// .macro call_intern, func; bal extern func; .endmacro |.macro call_intern, func; jalr CFUNCADDR; .endmacro |.macro call_extern; jalr CFUNCADDR; .endmacro |.macro jmp_extern; jr CFUNCADDR; .endmacro | |.macro hotcheck, delta, target | srl TMP1, PC, 1 | andi TMP1, TMP1, 126 | addu TMP1, TMP1, DISPATCH | lhu TMP2, GG_DISP2HOT(TMP1) | addiu TMP2, TMP2, -delta | bltz TMP2, target |. sh TMP2, GG_DISP2HOT(TMP1) |.endmacro | |.macro hotloop | hotcheck HOTCOUNT_LOOP, ->vm_hotloop |.endmacro | |.macro hotcall | hotcheck HOTCOUNT_CALL, ->vm_hotcall |.endmacro | |// Set current VM state. Uses TMP0. |.macro li_vmstate, st; li TMP0, ~LJ_VMST_..st; .endmacro |.macro st_vmstate; sw TMP0, DISPATCH_GL(vmstate)(DISPATCH); .endmacro | |// Move table write barrier back. Overwrites mark and tmp. |.macro barrierback, tab, mark, tmp, target | lw tmp, DISPATCH_GL(gc.grayagain)(DISPATCH) | andi mark, mark, ~LJ_GC_BLACK & 255 // black2gray(tab) | sw tab, DISPATCH_GL(gc.grayagain)(DISPATCH) | sb mark, tab->marked | b target |. sw tmp, tab->gclist |.endmacro | |//----------------------------------------------------------------------- /* Generate subroutines used by opcodes and other parts of the VM. */ /* The .code_sub section should be last to help static branch prediction. */ static void build_subroutines(BuildCtx *ctx) { |.code_sub | |//----------------------------------------------------------------------- |//-- Return handling ---------------------------------------------------- |//----------------------------------------------------------------------- | |->vm_returnp: | // See vm_return. Also: TMP2 = previous base. | andi AT, PC, FRAME_P | beqz AT, ->cont_dispatch |. li TMP1, LJ_TTRUE | | // Return from pcall or xpcall fast func. | lw PC, FRAME_PC(TMP2) // Fetch PC of previous frame. | move BASE, TMP2 // Restore caller base. | // Prepending may overwrite the pcall frame, so do it at the end. | sw TMP1, FRAME_PC(RA) // Prepend true to results. | addiu RA, RA, -8 | |->vm_returnc: | addiu RD, RD, 8 // RD = (nresults+1)*8. | andi TMP0, PC, FRAME_TYPE | beqz RD, ->vm_unwind_c_eh |. li CRET1, LUA_YIELD | beqz TMP0, ->BC_RET_Z // Handle regular return to Lua. |. move MULTRES, RD | |->vm_return: | // BASE = base, RA = resultptr, RD/MULTRES = (nresults+1)*8, PC = return | // TMP0 = PC & FRAME_TYPE | li TMP2, -8 | xori AT, TMP0, FRAME_C | and TMP2, PC, TMP2 | bnez AT, ->vm_returnp |. subu TMP2, BASE, TMP2 // TMP2 = previous base. | | addiu TMP1, RD, -8 | sw TMP2, L->base | li_vmstate C | lw TMP2, SAVE_NRES | addiu BASE, BASE, -8 | st_vmstate | beqz TMP1, >2 |. sll TMP2, TMP2, 3 |1: | addiu TMP1, TMP1, -8 | lw SFRETHI, HI(RA) | lw SFRETLO, LO(RA) | addiu RA, RA, 8 | sw SFRETHI, HI(BASE) | sw SFRETLO, LO(BASE) | bnez TMP1, <1 |. addiu BASE, BASE, 8 | |2: | bne TMP2, RD, >6 |3: |. sw BASE, L->top // Store new top. | |->vm_leave_cp: | lw TMP0, SAVE_CFRAME // Restore previous C frame. | move CRET1, r0 // Ok return status for vm_pcall. | sw TMP0, L->cframe | |->vm_leave_unw: | restoreregs_ret | |6: | lw TMP1, L->maxstack | slt AT, TMP2, RD | bnez AT, >7 // Less results wanted? | // More results wanted. Check stack size and fill up results with nil. |. slt AT, BASE, TMP1 | beqz AT, >8 |. nop | sw TISNIL, HI(BASE) | addiu RD, RD, 8 | b <2 |. addiu BASE, BASE, 8 | |7: // Less results wanted. | subu TMP0, RD, TMP2 | subu TMP0, BASE, TMP0 // Either keep top or shrink it. | b <3 |. movn BASE, TMP0, TMP2 // LUA_MULTRET+1 case? | |8: // Corner case: need to grow stack for filling up results. | // This can happen if: | // - A C function grows the stack (a lot). | // - The GC shrinks the stack in between. | // - A return back from a lua_call() with (high) nresults adjustment. | load_got lj_state_growstack | move MULTRES, RD | srl CARG2, TMP2, 3 | call_intern lj_state_growstack // (lua_State *L, int n) |. move CARG1, L | lw TMP2, SAVE_NRES | lw BASE, L->top // Need the (realloced) L->top in BASE. | move RD, MULTRES | b <2 |. sll TMP2, TMP2, 3 | |->vm_unwind_c: // Unwind C stack, return from vm_pcall. | // (void *cframe, int errcode) | move sp, CARG1 | move CRET1, CARG2 |->vm_unwind_c_eh: // Landing pad for external unwinder. | lw L, SAVE_L | li TMP0, ~LJ_VMST_C | lw GL:TMP1, L->glref | b ->vm_leave_unw |. sw TMP0, GL:TMP1->vmstate | |->vm_unwind_ff: // Unwind C stack, return from ff pcall. | // (void *cframe) | li AT, -4 | and sp, CARG1, AT |->vm_unwind_ff_eh: // Landing pad for external unwinder. | lw L, SAVE_L | .FPU lui TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). | li TISNUM, LJ_TISNUM // Setup type comparison constants. | li TISNIL, LJ_TNIL | lw BASE, L->base | lw DISPATCH, L->glref // Setup pointer to dispatch table. | .FPU mtc1 TMP3, TOBIT | li TMP1, LJ_TFALSE | li_vmstate INTERP | lw PC, FRAME_PC(BASE) // Fetch PC of previous frame. | .FPU cvt.d.s TOBIT, TOBIT | addiu RA, BASE, -8 // Results start at BASE-8. | addiu DISPATCH, DISPATCH, GG_G2DISP | sw TMP1, HI(RA) // Prepend false to error message. | st_vmstate | b ->vm_returnc |. li RD, 16 // 2 results: false + error message. | |->vm_unwind_stub: // Jump to exit stub from unwinder. | jr CARG1 |. move ra, CARG2 | |//----------------------------------------------------------------------- |//-- Grow stack for calls ----------------------------------------------- |//----------------------------------------------------------------------- | |->vm_growstack_c: // Grow stack for C function. | b >2 |. li CARG2, LUA_MINSTACK | |->vm_growstack_l: // Grow stack for Lua function. | // BASE = new base, RA = BASE+framesize*8, RC = nargs*8, PC = first PC | addu RC, BASE, RC | subu RA, RA, BASE | sw BASE, L->base | addiu PC, PC, 4 // Must point after first instruction. | sw RC, L->top | srl CARG2, RA, 3 |2: | // L->base = new base, L->top = top | load_got lj_state_growstack | sw PC, SAVE_PC | call_intern lj_state_growstack // (lua_State *L, int n) |. move CARG1, L | lw BASE, L->base | lw RC, L->top | lw LFUNC:RB, FRAME_FUNC(BASE) | subu RC, RC, BASE | // BASE = new base, RB = LFUNC/CFUNC, RC = nargs*8, FRAME_PC(BASE) = PC | ins_callt // Just retry the call. | |//----------------------------------------------------------------------- |//-- Entry points into the assembler VM --------------------------------- |//----------------------------------------------------------------------- | |->vm_resume: // Setup C frame and resume thread. | // (lua_State *L, TValue *base, int nres1 = 0, ptrdiff_t ef = 0) | saveregs | move L, CARG1 | lw DISPATCH, L->glref // Setup pointer to dispatch table. | move BASE, CARG2 | lbu TMP1, L->status | sw L, SAVE_L | li PC, FRAME_CP | addiu TMP0, sp, CFRAME_RESUME | addiu DISPATCH, DISPATCH, GG_G2DISP | sw r0, SAVE_NRES | sw r0, SAVE_ERRF | sw CARG1, SAVE_PC // Any value outside of bytecode is ok. | sw r0, SAVE_CFRAME | beqz TMP1, >3 |. sw TMP0, L->cframe | | // Resume after yield (like a return). | sw L, DISPATCH_GL(cur_L)(DISPATCH) | move RA, BASE | lw BASE, L->base | li TISNUM, LJ_TISNUM // Setup type comparison constants. | lw TMP1, L->top | lw PC, FRAME_PC(BASE) | .FPU lui TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). | subu RD, TMP1, BASE | .FPU mtc1 TMP3, TOBIT | sb r0, L->status | .FPU cvt.d.s TOBIT, TOBIT | li_vmstate INTERP | addiu RD, RD, 8 | st_vmstate | move MULTRES, RD | andi TMP0, PC, FRAME_TYPE | beqz TMP0, ->BC_RET_Z |. li TISNIL, LJ_TNIL | b ->vm_return |. nop | |->vm_pcall: // Setup protected C frame and enter VM. | // (lua_State *L, TValue *base, int nres1, ptrdiff_t ef) | saveregs | sw CARG4, SAVE_ERRF | b >1 |. li PC, FRAME_CP | |->vm_call: // Setup C frame and enter VM. | // (lua_State *L, TValue *base, int nres1) | saveregs | li PC, FRAME_C | |1: // Entry point for vm_pcall above (PC = ftype). | lw TMP1, L:CARG1->cframe | move L, CARG1 | sw CARG3, SAVE_NRES | lw DISPATCH, L->glref // Setup pointer to dispatch table. | sw CARG1, SAVE_L | move BASE, CARG2 | addiu DISPATCH, DISPATCH, GG_G2DISP | sw CARG1, SAVE_PC // Any value outside of bytecode is ok. | sw TMP1, SAVE_CFRAME | sw sp, L->cframe // Add our C frame to cframe chain. | |3: // Entry point for vm_cpcall/vm_resume (BASE = base, PC = ftype). | sw L, DISPATCH_GL(cur_L)(DISPATCH) | lw TMP2, L->base // TMP2 = old base (used in vmeta_call). | li TISNUM, LJ_TISNUM // Setup type comparison constants. | .FPU lui TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). | lw TMP1, L->top | .FPU mtc1 TMP3, TOBIT | addu PC, PC, BASE | subu NARGS8:RC, TMP1, BASE | subu PC, PC, TMP2 // PC = frame delta + frame type | .FPU cvt.d.s TOBIT, TOBIT | li_vmstate INTERP | li TISNIL, LJ_TNIL | st_vmstate | |->vm_call_dispatch: | // TMP2 = old base, BASE = new base, RC = nargs*8, PC = caller PC | lw TMP0, FRAME_PC(BASE) | li AT, LJ_TFUNC | bne TMP0, AT, ->vmeta_call |. lw LFUNC:RB, FRAME_FUNC(BASE) | |->vm_call_dispatch_f: | ins_call | // BASE = new base, RB = func, RC = nargs*8, PC = caller PC | |->vm_cpcall: // Setup protected C frame, call C. | // (lua_State *L, lua_CFunction func, void *ud, lua_CPFunction cp) | saveregs | move L, CARG1 | lw TMP0, L:CARG1->stack | sw CARG1, SAVE_L | lw TMP1, L->top | lw DISPATCH, L->glref // Setup pointer to dispatch table. | sw CARG1, SAVE_PC // Any value outside of bytecode is ok. | subu TMP0, TMP0, TMP1 // Compute -savestack(L, L->top). | lw TMP1, L->cframe | addiu DISPATCH, DISPATCH, GG_G2DISP | sw TMP0, SAVE_NRES // Neg. delta means cframe w/o frame. | sw r0, SAVE_ERRF // No error function. | sw TMP1, SAVE_CFRAME | sw sp, L->cframe // Add our C frame to cframe chain. | sw L, DISPATCH_GL(cur_L)(DISPATCH) | jalr CARG4 // (lua_State *L, lua_CFunction func, void *ud) |. move CFUNCADDR, CARG4 | move BASE, CRET1 | bnez CRET1, <3 // Else continue with the call. |. li PC, FRAME_CP | b ->vm_leave_cp // No base? Just remove C frame. |. nop | |//----------------------------------------------------------------------- |//-- Metamethod handling ------------------------------------------------ |//----------------------------------------------------------------------- | |// The lj_meta_* functions (except for lj_meta_cat) don't reallocate the |// stack, so BASE doesn't need to be reloaded across these calls. | |//-- Continuation dispatch ---------------------------------------------- | |->cont_dispatch: | // BASE = meta base, RA = resultptr, RD = (nresults+1)*8 | lw TMP0, -16+LO(BASE) // Continuation. | move RB, BASE | move BASE, TMP2 // Restore caller BASE. | lw LFUNC:TMP1, FRAME_FUNC(TMP2) |.if FFI | sltiu AT, TMP0, 2 |.endif | lw PC, -16+HI(RB) // Restore PC from [cont|PC]. | addu TMP2, RA, RD |.if FFI | bnez AT, >1 |.endif |. sw TISNIL, -8+HI(TMP2) // Ensure one valid arg. | lw TMP1, LFUNC:TMP1->pc | // BASE = base, RA = resultptr, RB = meta base | jr TMP0 // Jump to continuation. |. lw KBASE, PC2PROTO(k)(TMP1) | |.if FFI |1: | bnez TMP0, ->cont_ffi_callback // cont = 1: return from FFI callback. | // cont = 0: tailcall from C function. |. addiu TMP1, RB, -16 | b ->vm_call_tail |. subu RC, TMP1, BASE |.endif | |->cont_cat: // RA = resultptr, RB = meta base | lw INS, -4(PC) | addiu CARG2, RB, -16 | lw SFRETHI, HI(RA) | lw SFRETLO, LO(RA) | decode_RB8a MULTRES, INS | decode_RA8a RA, INS | decode_RB8b MULTRES | decode_RA8b RA | addu TMP1, BASE, MULTRES | sw BASE, L->base | subu CARG3, CARG2, TMP1 | sw SFRETHI, HI(CARG2) | bne TMP1, CARG2, ->BC_CAT_Z |. sw SFRETLO, LO(CARG2) | addu RA, BASE, RA | sw SFRETHI, HI(RA) | b ->cont_nop |. sw SFRETLO, LO(RA) | |//-- Table indexing metamethods ----------------------------------------- | |->vmeta_tgets1: | addiu CARG3, DISPATCH, DISPATCH_GL(tmptv) | li TMP0, LJ_TSTR | sw STR:RC, LO(CARG3) | b >1 |. sw TMP0, HI(CARG3) | |->vmeta_tgets: | addiu CARG2, DISPATCH, DISPATCH_GL(tmptv) | li TMP0, LJ_TTAB | sw TAB:RB, LO(CARG2) | addiu CARG3, DISPATCH, DISPATCH_GL(tmptv2) | sw TMP0, HI(CARG2) | li TMP1, LJ_TSTR | sw STR:RC, LO(CARG3) | b >1 |. sw TMP1, HI(CARG3) | |->vmeta_tgetb: // TMP0 = index | addiu CARG3, DISPATCH, DISPATCH_GL(tmptv) | sw TMP0, LO(CARG3) | sw TISNUM, HI(CARG3) | |->vmeta_tgetv: |1: | load_got lj_meta_tget | sw BASE, L->base | sw PC, SAVE_PC | call_intern lj_meta_tget // (lua_State *L, TValue *o, TValue *k) |. move CARG1, L | // Returns TValue * (finished) or NULL (metamethod). | beqz CRET1, >3 |. addiu TMP1, BASE, -FRAME_CONT | lw SFARG1HI, HI(CRET1) | lw SFARG2HI, LO(CRET1) | ins_next1 | sw SFARG1HI, HI(RA) | sw SFARG2HI, LO(RA) | ins_next2 | |3: // Call __index metamethod. | // BASE = base, L->top = new base, stack = cont/func/t/k | lw BASE, L->top | sw PC, -16+HI(BASE) // [cont|PC] | subu PC, BASE, TMP1 | lw LFUNC:RB, FRAME_FUNC(BASE) // Guaranteed to be a function here. | b ->vm_call_dispatch_f |. li NARGS8:RC, 16 // 2 args for func(t, k). | |->vmeta_tgetr: | load_got lj_tab_getinth | call_intern lj_tab_getinth // (GCtab *t, int32_t key) |. nop | // Returns cTValue * or NULL. | beqz CRET1, ->BC_TGETR_Z |. move SFARG2HI, TISNIL | lw SFARG2HI, HI(CRET1) | b ->BC_TGETR_Z |. lw SFARG2LO, LO(CRET1) | |//----------------------------------------------------------------------- | |->vmeta_tsets1: | addiu CARG3, DISPATCH, DISPATCH_GL(tmptv) | li TMP0, LJ_TSTR | sw STR:RC, LO(CARG3) | b >1 |. sw TMP0, HI(CARG3) | |->vmeta_tsets: | addiu CARG2, DISPATCH, DISPATCH_GL(tmptv) | li TMP0, LJ_TTAB | sw TAB:RB, LO(CARG2) | addiu CARG3, DISPATCH, DISPATCH_GL(tmptv2) | sw TMP0, HI(CARG2) | li TMP1, LJ_TSTR | sw STR:RC, LO(CARG3) | b >1 |. sw TMP1, HI(CARG3) | |->vmeta_tsetb: // TMP0 = index | addiu CARG3, DISPATCH, DISPATCH_GL(tmptv) | sw TMP0, LO(CARG3) | sw TISNUM, HI(CARG3) | |->vmeta_tsetv: |1: | load_got lj_meta_tset | sw BASE, L->base | sw PC, SAVE_PC | call_intern lj_meta_tset // (lua_State *L, TValue *o, TValue *k) |. move CARG1, L | // Returns TValue * (finished) or NULL (metamethod). | lw SFARG1HI, HI(RA) | beqz CRET1, >3 |. lw SFARG1LO, LO(RA) | // NOBARRIER: lj_meta_tset ensures the table is not black. | ins_next1 | sw SFARG1HI, HI(CRET1) | sw SFARG1LO, LO(CRET1) | ins_next2 | |3: // Call __newindex metamethod. | // BASE = base, L->top = new base, stack = cont/func/t/k/(v) | addiu TMP1, BASE, -FRAME_CONT | lw BASE, L->top | sw PC, -16+HI(BASE) // [cont|PC] | subu PC, BASE, TMP1 | lw LFUNC:RB, FRAME_FUNC(BASE) // Guaranteed to be a function here. | sw SFARG1HI, 16+HI(BASE) // Copy value to third argument. | sw SFARG1LO, 16+LO(BASE) | b ->vm_call_dispatch_f |. li NARGS8:RC, 24 // 3 args for func(t, k, v) | |->vmeta_tsetr: | load_got lj_tab_setinth | sw BASE, L->base | sw PC, SAVE_PC | call_intern lj_tab_setinth // (lua_State *L, GCtab *t, int32_t key) |. move CARG1, L | // Returns TValue *. | b ->BC_TSETR_Z |. nop | |//-- Comparison metamethods --------------------------------------------- | |->vmeta_comp: | // RA/RD point to o1/o2. | move CARG2, RA | move CARG3, RD | load_got lj_meta_comp | addiu PC, PC, -4 | sw BASE, L->base | sw PC, SAVE_PC | decode_OP1 CARG4, INS | call_intern lj_meta_comp // (lua_State *L, TValue *o1, *o2, int op) |. move CARG1, L | // Returns 0/1 or TValue * (metamethod). |3: | sltiu AT, CRET1, 2 | beqz AT, ->vmeta_binop | negu TMP2, CRET1 |4: | lhu RD, OFS_RD(PC) | addiu PC, PC, 4 | lui TMP1, (-(BCBIAS_J*4 >> 16) & 65535) | sll RD, RD, 2 | addu RD, RD, TMP1 | and RD, RD, TMP2 | addu PC, PC, RD |->cont_nop: | ins_next | |->cont_ra: // RA = resultptr | lbu TMP1, -4+OFS_RA(PC) | lw SFRETHI, HI(RA) | lw SFRETLO, LO(RA) | sll TMP1, TMP1, 3 | addu TMP1, BASE, TMP1 | sw SFRETHI, HI(TMP1) | b ->cont_nop |. sw SFRETLO, LO(TMP1) | |->cont_condt: // RA = resultptr | lw TMP0, HI(RA) | sltiu AT, TMP0, LJ_TISTRUECOND | b <4 |. negu TMP2, AT // Branch if result is true. | |->cont_condf: // RA = resultptr | lw TMP0, HI(RA) | sltiu AT, TMP0, LJ_TISTRUECOND | b <4 |. addiu TMP2, AT, -1 // Branch if result is false. | |->vmeta_equal: | // SFARG1LO/SFARG2LO point to o1/o2. TMP0 is set to 0/1. | load_got lj_meta_equal | move CARG2, SFARG1LO | move CARG3, SFARG2LO | move CARG4, TMP0 | addiu PC, PC, -4 | sw BASE, L->base | sw PC, SAVE_PC | call_intern lj_meta_equal // (lua_State *L, GCobj *o1, *o2, int ne) |. move CARG1, L | // Returns 0/1 or TValue * (metamethod). | b <3 |. nop | |->vmeta_equal_cd: |.if FFI | load_got lj_meta_equal_cd | move CARG2, INS | addiu PC, PC, -4 | sw BASE, L->base | sw PC, SAVE_PC | call_intern lj_meta_equal_cd // (lua_State *L, BCIns op) |. move CARG1, L | // Returns 0/1 or TValue * (metamethod). | b <3 |. nop |.endif | |->vmeta_istype: | load_got lj_meta_istype | addiu PC, PC, -4 | sw BASE, L->base | srl CARG2, RA, 3 | srl CARG3, RD, 3 | sw PC, SAVE_PC | call_intern lj_meta_istype // (lua_State *L, BCReg ra, BCReg tp) |. move CARG1, L | b ->cont_nop |. nop | |//-- Arithmetic metamethods --------------------------------------------- | |->vmeta_unm: | move RC, RB | |->vmeta_arith: | load_got lj_meta_arith | decode_OP1 TMP0, INS | sw BASE, L->base | move CARG2, RA | sw PC, SAVE_PC | move CARG3, RB | move CARG4, RC | sw TMP0, ARG5 | call_intern lj_meta_arith // (lua_State *L, TValue *ra,*rb,*rc, BCReg op) |. move CARG1, L | // Returns NULL (finished) or TValue * (metamethod). | beqz CRET1, ->cont_nop |. nop | | // Call metamethod for binary op. |->vmeta_binop: | // BASE = old base, CRET1 = new base, stack = cont/func/o1/o2 | subu TMP1, CRET1, BASE | sw PC, -16+HI(CRET1) // [cont|PC] | move TMP2, BASE | addiu PC, TMP1, FRAME_CONT | move BASE, CRET1 | b ->vm_call_dispatch |. li NARGS8:RC, 16 // 2 args for func(o1, o2). | |->vmeta_len: | // CARG2 already set by BC_LEN. #if LJ_52 | move MULTRES, CARG1 #endif | load_got lj_meta_len | sw BASE, L->base | sw PC, SAVE_PC | call_intern lj_meta_len // (lua_State *L, TValue *o) |. move CARG1, L | // Returns NULL (retry) or TValue * (metamethod base). #if LJ_52 | bnez CRET1, ->vmeta_binop // Binop call for compatibility. |. nop | b ->BC_LEN_Z |. move CARG1, MULTRES #else | b ->vmeta_binop // Binop call for compatibility. |. nop #endif | |//-- Call metamethod ---------------------------------------------------- | |->vmeta_call: // Resolve and call __call metamethod. | // TMP2 = old base, BASE = new base, RC = nargs*8 | load_got lj_meta_call | sw TMP2, L->base // This is the callers base! | addiu CARG2, BASE, -8 | sw PC, SAVE_PC | addu CARG3, BASE, RC | move MULTRES, NARGS8:RC | call_intern lj_meta_call // (lua_State *L, TValue *func, TValue *top) |. move CARG1, L | lw LFUNC:RB, FRAME_FUNC(BASE) // Guaranteed to be a function here. | addiu NARGS8:RC, MULTRES, 8 // Got one more argument now. | ins_call | |->vmeta_callt: // Resolve __call for BC_CALLT. | // BASE = old base, RA = new base, RC = nargs*8 | load_got lj_meta_call | sw BASE, L->base | addiu CARG2, RA, -8 | sw PC, SAVE_PC | addu CARG3, RA, RC | move MULTRES, NARGS8:RC | call_intern lj_meta_call // (lua_State *L, TValue *func, TValue *top) |. move CARG1, L | lw TMP1, FRAME_PC(BASE) | lw LFUNC:RB, FRAME_FUNC(RA) // Guaranteed to be a function here. | b ->BC_CALLT_Z |. addiu NARGS8:RC, MULTRES, 8 // Got one more argument now. | |//-- Argument coercion for 'for' statement ------------------------------ | |->vmeta_for: | load_got lj_meta_for | sw BASE, L->base | move CARG2, RA | sw PC, SAVE_PC | move MULTRES, INS | call_intern lj_meta_for // (lua_State *L, TValue *base) |. move CARG1, L |.if JIT | decode_OP1 TMP0, MULTRES | li AT, BC_JFORI |.endif | decode_RA8a RA, MULTRES | decode_RD8a RD, MULTRES | decode_RA8b RA |.if JIT | beq TMP0, AT, =>BC_JFORI |. decode_RD8b RD | b =>BC_FORI |. nop |.else | b =>BC_FORI |. decode_RD8b RD |.endif | |//----------------------------------------------------------------------- |//-- Fast functions ----------------------------------------------------- |//----------------------------------------------------------------------- | |.macro .ffunc, name |->ff_ .. name: |.endmacro | |.macro .ffunc_1, name |->ff_ .. name: | lw SFARG1HI, HI(BASE) | beqz NARGS8:RC, ->fff_fallback |. lw SFARG1LO, LO(BASE) |.endmacro | |.macro .ffunc_2, name |->ff_ .. name: | sltiu AT, NARGS8:RC, 16 | lw SFARG1HI, HI(BASE) | bnez AT, ->fff_fallback |. lw SFARG2HI, 8+HI(BASE) | lw SFARG1LO, LO(BASE) | lw SFARG2LO, 8+LO(BASE) |.endmacro | |.macro .ffunc_n, name // Caveat: has delay slot! |->ff_ .. name: | lw SFARG1HI, HI(BASE) |.if FPU | ldc1 FARG1, 0(BASE) |.else | lw SFARG1LO, LO(BASE) |.endif | beqz NARGS8:RC, ->fff_fallback |. sltiu AT, SFARG1HI, LJ_TISNUM | beqz AT, ->fff_fallback |.endmacro | |.macro .ffunc_nn, name // Caveat: has delay slot! |->ff_ .. name: | sltiu AT, NARGS8:RC, 16 | lw SFARG1HI, HI(BASE) | bnez AT, ->fff_fallback |. lw SFARG2HI, 8+HI(BASE) | sltiu TMP0, SFARG1HI, LJ_TISNUM |.if FPU | ldc1 FARG1, 0(BASE) |.else | lw SFARG1LO, LO(BASE) |.endif | sltiu TMP1, SFARG2HI, LJ_TISNUM |.if FPU | ldc1 FARG2, 8(BASE) |.else | lw SFARG2LO, 8+LO(BASE) |.endif | and TMP0, TMP0, TMP1 | beqz TMP0, ->fff_fallback |.endmacro | |// Inlined GC threshold check. Caveat: uses TMP0 and TMP1 and has delay slot! |.macro ffgccheck | lw TMP0, DISPATCH_GL(gc.total)(DISPATCH) | lw TMP1, DISPATCH_GL(gc.threshold)(DISPATCH) | subu AT, TMP0, TMP1 | bgezal AT, ->fff_gcstep |.endmacro | |//-- Base library: checks ----------------------------------------------- | |.ffunc_1 assert | sltiu AT, SFARG1HI, LJ_TISTRUECOND | beqz AT, ->fff_fallback |. addiu RA, BASE, -8 | lw PC, FRAME_PC(BASE) | addiu RD, NARGS8:RC, 8 // Compute (nresults+1)*8. | addu TMP2, RA, NARGS8:RC | sw SFARG1HI, HI(RA) | addiu TMP1, BASE, 8 | beq BASE, TMP2, ->fff_res // Done if exactly 1 argument. |. sw SFARG1LO, LO(RA) |1: | lw SFRETHI, HI(TMP1) | lw SFRETLO, LO(TMP1) | sw SFRETHI, -8+HI(TMP1) | sw SFRETLO, -8+LO(TMP1) | bne TMP1, TMP2, <1 |. addiu TMP1, TMP1, 8 | b ->fff_res |. nop | |.ffunc type | lw SFARG1HI, HI(BASE) | beqz NARGS8:RC, ->fff_fallback |. sltiu TMP0, SFARG1HI, LJ_TISNUM | movn SFARG1HI, TISNUM, TMP0 | not TMP1, SFARG1HI | sll TMP1, TMP1, 3 | addu TMP1, CFUNC:RB, TMP1 | lw SFARG1HI, CFUNC:TMP1->upvalue[0].u32.hi | b ->fff_restv |. lw SFARG1LO, CFUNC:TMP1->upvalue[0].u32.lo | |//-- Base library: getters and setters --------------------------------- | |.ffunc_1 getmetatable | li AT, LJ_TTAB | bne SFARG1HI, AT, >6 |. li AT, LJ_TUDATA |1: // Field metatable must be at same offset for GCtab and GCudata! | lw TAB:SFARG1LO, TAB:SFARG1LO->metatable |2: | lw STR:RC, DISPATCH_GL(gcroot[GCROOT_MMNAME+MM_metatable])(DISPATCH) | beqz TAB:SFARG1LO, ->fff_restv |. li SFARG1HI, LJ_TNIL | lw TMP0, TAB:SFARG1LO->hmask | li SFARG1HI, LJ_TTAB // Use metatable as default result. | lw TMP1, STR:RC->sid | lw NODE:TMP2, TAB:SFARG1LO->node | and TMP1, TMP1, TMP0 // idx = str->sid & tab->hmask | sll TMP0, TMP1, 5 | sll TMP1, TMP1, 3 | subu TMP1, TMP0, TMP1 | addu NODE:TMP2, NODE:TMP2, TMP1 // node = tab->node + (idx*32-idx*8) | li AT, LJ_TSTR |3: // Rearranged logic, because we expect _not_ to find the key. | lw CARG4, offsetof(Node, key)+HI(NODE:TMP2) | lw TMP0, offsetof(Node, key)+LO(NODE:TMP2) | lw NODE:TMP3, NODE:TMP2->next | bne CARG4, AT, >4 |. lw CARG3, offsetof(Node, val)+HI(NODE:TMP2) | beq TMP0, STR:RC, >5 |. lw TMP1, offsetof(Node, val)+LO(NODE:TMP2) |4: | beqz NODE:TMP3, ->fff_restv // Not found, keep default result. |. move NODE:TMP2, NODE:TMP3 | b <3 |. nop |5: | beq CARG3, TISNIL, ->fff_restv // Ditto for nil value. |. nop | move SFARG1HI, CARG3 // Return value of mt.__metatable. | b ->fff_restv |. move SFARG1LO, TMP1 | |6: | beq SFARG1HI, AT, <1 |. sltu AT, TISNUM, SFARG1HI | movz SFARG1HI, TISNUM, AT | not TMP1, SFARG1HI | sll TMP1, TMP1, 2 | addu TMP1, DISPATCH, TMP1 | b <2 |. lw TAB:SFARG1LO, DISPATCH_GL(gcroot[GCROOT_BASEMT])(TMP1) | |.ffunc_2 setmetatable | // Fast path: no mt for table yet and not clearing the mt. | li AT, LJ_TTAB | bne SFARG1HI, AT, ->fff_fallback |. addiu SFARG2HI, SFARG2HI, -LJ_TTAB | lw TAB:TMP1, TAB:SFARG1LO->metatable | lbu TMP3, TAB:SFARG1LO->marked | or AT, SFARG2HI, TAB:TMP1 | bnez AT, ->fff_fallback |. andi AT, TMP3, LJ_GC_BLACK // isblack(table) | beqz AT, ->fff_restv |. sw TAB:SFARG2LO, TAB:SFARG1LO->metatable | barrierback TAB:SFARG1LO, TMP3, TMP0, ->fff_restv | |.ffunc rawget | lw CARG4, HI(BASE) | sltiu AT, NARGS8:RC, 16 | lw TAB:CARG2, LO(BASE) | load_got lj_tab_get | addiu CARG4, CARG4, -LJ_TTAB | or AT, AT, CARG4 | bnez AT, ->fff_fallback | addiu CARG3, BASE, 8 | call_intern lj_tab_get // (lua_State *L, GCtab *t, cTValue *key) |. move CARG1, L | // Returns cTValue *. | lw SFARG1HI, HI(CRET1) | b ->fff_restv |. lw SFARG1LO, LO(CRET1) | |//-- Base library: conversions ------------------------------------------ | |.ffunc tonumber | // Only handles the number case inline (without a base argument). | lw CARG1, HI(BASE) | xori AT, NARGS8:RC, 8 // Exactly one number argument. | sltu TMP0, TISNUM, CARG1 | or AT, AT, TMP0 | bnez AT, ->fff_fallback |. lw SFARG1HI, HI(BASE) | b ->fff_restv |. lw SFARG1LO, LO(BASE) | |.ffunc_1 tostring | // Only handles the string or number case inline. | li AT, LJ_TSTR | // A __tostring method in the string base metatable is ignored. | beq SFARG1HI, AT, ->fff_restv // String key? | // Handle numbers inline, unless a number base metatable is present. |. lw TMP1, DISPATCH_GL(gcroot[GCROOT_BASEMT_NUM])(DISPATCH) | sltu TMP0, TISNUM, SFARG1HI | or TMP0, TMP0, TMP1 | bnez TMP0, ->fff_fallback |. sw BASE, L->base // Add frame since C call can throw. | ffgccheck |. sw PC, SAVE_PC // Redundant (but a defined value). | load_got lj_strfmt_number | move CARG1, L | call_intern lj_strfmt_number // (lua_State *L, cTValue *o) |. move CARG2, BASE | // Returns GCstr *. | li SFARG1HI, LJ_TSTR | b ->fff_restv |. move SFARG1LO, CRET1 | |//-- Base library: iterators ------------------------------------------- | |.ffunc next | lw CARG2, HI(BASE) | lw TAB:CARG1, LO(BASE) | beqz NARGS8:RC, ->fff_fallback |. addu TMP2, BASE, NARGS8:RC | li AT, LJ_TTAB | sw TISNIL, HI(TMP2) // Set missing 2nd arg to nil. | bne CARG2, AT, ->fff_fallback |. lw PC, FRAME_PC(BASE) | load_got lj_tab_next | addiu CARG2, BASE, 8 | call_intern lj_tab_next // (GCtab *t, cTValue *key, TValue *o) |. addiu CARG3, BASE, -8 | // Returns 1=found, 0=end, -1=error. | addiu RA, BASE, -8 | bgtz CRET1, ->fff_res // Found key/value. |. li RD, (2+1)*8 | beqz CRET1, ->fff_restv // End of traversal: return nil. |. li SFARG1HI, LJ_TNIL | lw CFUNC:RB, FRAME_FUNC(BASE) | b ->fff_fallback // Invalid key. |. li RC, 2*8 | |.ffunc_1 pairs | li AT, LJ_TTAB | bne SFARG1HI, AT, ->fff_fallback |. lw PC, FRAME_PC(BASE) #if LJ_52 | lw TAB:TMP2, TAB:SFARG1LO->metatable | lw TMP0, CFUNC:RB->upvalue[0].u32.hi | lw TMP1, CFUNC:RB->upvalue[0].u32.lo | bnez TAB:TMP2, ->fff_fallback #else | lw TMP0, CFUNC:RB->upvalue[0].u32.hi | lw TMP1, CFUNC:RB->upvalue[0].u32.lo #endif |. addiu RA, BASE, -8 | sw TISNIL, 8+HI(BASE) | sw TMP0, HI(RA) | sw TMP1, LO(RA) | b ->fff_res |. li RD, (3+1)*8 | |.ffunc ipairs_aux | sltiu AT, NARGS8:RC, 16 | lw CARG3, HI(BASE) | lw TAB:CARG1, LO(BASE) | lw CARG4, 8+HI(BASE) | bnez AT, ->fff_fallback |. addiu CARG3, CARG3, -LJ_TTAB | xor CARG4, CARG4, TISNUM | and AT, CARG3, CARG4 | bnez AT, ->fff_fallback |. lw PC, FRAME_PC(BASE) | lw TMP2, 8+LO(BASE) | lw TMP0, TAB:CARG1->asize | lw TMP1, TAB:CARG1->array | addiu TMP2, TMP2, 1 | sw TISNUM, -8+HI(BASE) | sltu AT, TMP2, TMP0 | sw TMP2, -8+LO(BASE) | beqz AT, >2 // Not in array part? |. addiu RA, BASE, -8 | sll TMP3, TMP2, 3 | addu TMP3, TMP1, TMP3 | lw TMP1, HI(TMP3) | lw TMP2, LO(TMP3) |1: | beq TMP1, TISNIL, ->fff_res // End of iteration, return 0 results. |. li RD, (0+1)*8 | sw TMP1, 8+HI(RA) | sw TMP2, 8+LO(RA) | b ->fff_res |. li RD, (2+1)*8 | |2: // Check for empty hash part first. Otherwise call C function. | lw TMP0, TAB:CARG1->hmask | load_got lj_tab_getinth | beqz TMP0, ->fff_res |. li RD, (0+1)*8 | call_intern lj_tab_getinth // (GCtab *t, int32_t key) |. move CARG2, TMP2 | // Returns cTValue * or NULL. | beqz CRET1, ->fff_res |. li RD, (0+1)*8 | lw TMP1, HI(CRET1) | b <1 |. lw TMP2, LO(CRET1) | |.ffunc_1 ipairs | li AT, LJ_TTAB | bne SFARG1HI, AT, ->fff_fallback |. lw PC, FRAME_PC(BASE) #if LJ_52 | lw TAB:TMP2, TAB:SFARG1LO->metatable | lw TMP0, CFUNC:RB->upvalue[0].u32.hi | lw TMP1, CFUNC:RB->upvalue[0].u32.lo | bnez TAB:TMP2, ->fff_fallback #else | lw TMP0, CFUNC:RB->upvalue[0].u32.hi | lw TMP1, CFUNC:RB->upvalue[0].u32.lo #endif |. addiu RA, BASE, -8 | sw TISNUM, 8+HI(BASE) | sw r0, 8+LO(BASE) | sw TMP0, HI(RA) | sw TMP1, LO(RA) | b ->fff_res |. li RD, (3+1)*8 | |//-- Base library: catch errors ---------------------------------------- | |.ffunc pcall | lbu TMP3, DISPATCH_GL(hookmask)(DISPATCH) | beqz NARGS8:RC, ->fff_fallback | move TMP2, BASE | addiu BASE, BASE, 8 | // Remember active hook before pcall. | srl TMP3, TMP3, HOOK_ACTIVE_SHIFT | andi TMP3, TMP3, 1 | addiu PC, TMP3, 8+FRAME_PCALL | b ->vm_call_dispatch |. addiu NARGS8:RC, NARGS8:RC, -8 | |.ffunc xpcall | sltiu AT, NARGS8:RC, 16 | lw CARG4, 8+HI(BASE) | bnez AT, ->fff_fallback |. lw CARG3, 8+LO(BASE) | lw CARG1, LO(BASE) | lw CARG2, HI(BASE) | lbu TMP1, DISPATCH_GL(hookmask)(DISPATCH) | li AT, LJ_TFUNC | move TMP2, BASE | bne CARG4, AT, ->fff_fallback // Traceback must be a function. | addiu BASE, BASE, 16 | // Remember active hook before pcall. | srl TMP3, TMP3, HOOK_ACTIVE_SHIFT | sw CARG3, LO(TMP2) // Swap function and traceback. | sw CARG4, HI(TMP2) | andi TMP3, TMP3, 1 | sw CARG1, 8+LO(TMP2) | sw CARG2, 8+HI(TMP2) | addiu PC, TMP3, 16+FRAME_PCALL | b ->vm_call_dispatch |. addiu NARGS8:RC, NARGS8:RC, -16 | |//-- Coroutine library -------------------------------------------------- | |.macro coroutine_resume_wrap, resume |.if resume |.ffunc coroutine_resume | lw CARG3, HI(BASE) | beqz NARGS8:RC, ->fff_fallback |. lw CARG1, LO(BASE) | li AT, LJ_TTHREAD | bne CARG3, AT, ->fff_fallback |.else |.ffunc coroutine_wrap_aux | lw L:CARG1, CFUNC:RB->upvalue[0].gcr |.endif | lbu TMP0, L:CARG1->status | lw TMP1, L:CARG1->cframe | lw CARG2, L:CARG1->top | lw TMP2, L:CARG1->base | addiu TMP3, TMP0, -LUA_YIELD | bgtz TMP3, ->fff_fallback // st > LUA_YIELD? |. xor TMP2, TMP2, CARG2 | bnez TMP1, ->fff_fallback // cframe != 0? |. or AT, TMP2, TMP0 | lw TMP0, L:CARG1->maxstack | beqz AT, ->fff_fallback // base == top && st == 0? |. lw PC, FRAME_PC(BASE) | addu TMP2, CARG2, NARGS8:RC | sltu AT, TMP0, TMP2 | bnez AT, ->fff_fallback // Stack overflow? |. sw PC, SAVE_PC | sw BASE, L->base |1: |.if resume | addiu BASE, BASE, 8 // Keep resumed thread in stack for GC. | addiu NARGS8:RC, NARGS8:RC, -8 | addiu TMP2, TMP2, -8 |.endif | sw TMP2, L:CARG1->top | addu TMP1, BASE, NARGS8:RC | move CARG3, CARG2 | sw BASE, L->top |2: // Move args to coroutine. | lw SFRETHI, HI(BASE) | lw SFRETLO, LO(BASE) | sltu AT, BASE, TMP1 | beqz AT, >3 |. addiu BASE, BASE, 8 | sw SFRETHI, HI(CARG3) | sw SFRETLO, LO(CARG3) | b <2 |. addiu CARG3, CARG3, 8 |3: | bal ->vm_resume // (lua_State *L, TValue *base, 0, 0) |. move L:RA, L:CARG1 | // Returns thread status. |4: | lw TMP2, L:RA->base | sltiu AT, CRET1, LUA_YIELD+1 | lw TMP3, L:RA->top | li_vmstate INTERP | lw BASE, L->base | sw L, DISPATCH_GL(cur_L)(DISPATCH) | st_vmstate | beqz AT, >8 |. subu RD, TMP3, TMP2 | lw TMP0, L->maxstack | beqz RD, >6 // No results? |. addu TMP1, BASE, RD | sltu AT, TMP0, TMP1 | bnez AT, >9 // Need to grow stack? |. addu TMP3, TMP2, RD | sw TMP2, L:RA->top // Clear coroutine stack. | move TMP1, BASE |5: // Move results from coroutine. | lw SFRETHI, HI(TMP2) | lw SFRETLO, LO(TMP2) | addiu TMP2, TMP2, 8 | sltu AT, TMP2, TMP3 | sw SFRETHI, HI(TMP1) | sw SFRETLO, LO(TMP1) | bnez AT, <5 |. addiu TMP1, TMP1, 8 |6: | andi TMP0, PC, FRAME_TYPE |.if resume | li TMP1, LJ_TTRUE | addiu RA, BASE, -8 | sw TMP1, -8+HI(BASE) // Prepend true to results. | addiu RD, RD, 16 |.else | move RA, BASE | addiu RD, RD, 8 |.endif |7: | sw PC, SAVE_PC | beqz TMP0, ->BC_RET_Z |. move MULTRES, RD | b ->vm_return |. nop | |8: // Coroutine returned with error (at co->top-1). |.if resume | addiu TMP3, TMP3, -8 | li TMP1, LJ_TFALSE | lw SFRETHI, HI(TMP3) | lw SFRETLO, LO(TMP3) | sw TMP3, L:RA->top // Remove error from coroutine stack. | li RD, (2+1)*8 | sw TMP1, -8+HI(BASE) // Prepend false to results. | addiu RA, BASE, -8 | sw SFRETHI, HI(BASE) // Copy error message. | sw SFRETLO, LO(BASE) | b <7 |. andi TMP0, PC, FRAME_TYPE |.else | load_got lj_ffh_coroutine_wrap_err | move CARG2, L:RA | call_intern lj_ffh_coroutine_wrap_err // (lua_State *L, lua_State *co) |. move CARG1, L |.endif | |9: // Handle stack expansion on return from yield. | load_got lj_state_growstack | srl CARG2, RD, 3 | call_intern lj_state_growstack // (lua_State *L, int n) |. move CARG1, L | b <4 |. li CRET1, 0 |.endmacro | | coroutine_resume_wrap 1 // coroutine.resume | coroutine_resume_wrap 0 // coroutine.wrap | |.ffunc coroutine_yield | lw TMP0, L->cframe | addu TMP1, BASE, NARGS8:RC | sw BASE, L->base | andi TMP0, TMP0, CFRAME_RESUME | sw TMP1, L->top | beqz TMP0, ->fff_fallback |. li CRET1, LUA_YIELD | sw r0, L->cframe | b ->vm_leave_unw |. sb CRET1, L->status | |//-- Math library ------------------------------------------------------- | |.ffunc_1 math_abs | bne SFARG1HI, TISNUM, >1 |. sra TMP0, SFARG1LO, 31 | xor TMP1, SFARG1LO, TMP0 | subu SFARG1LO, TMP1, TMP0 | bgez SFARG1LO, ->fff_restv |. nop | lui SFARG1HI, 0x41e0 // 2^31 as a double. | b ->fff_restv |. li SFARG1LO, 0 |1: | sltiu AT, SFARG1HI, LJ_TISNUM | beqz AT, ->fff_fallback |. sll SFARG1HI, SFARG1HI, 1 | srl SFARG1HI, SFARG1HI, 1 |// fallthrough | |->fff_restv: | // SFARG1LO/SFARG1HI = TValue result. | lw PC, FRAME_PC(BASE) | sw SFARG1HI, -8+HI(BASE) | addiu RA, BASE, -8 | sw SFARG1LO, -8+LO(BASE) |->fff_res1: | // RA = results, PC = return. | li RD, (1+1)*8 |->fff_res: | // RA = results, RD = (nresults+1)*8, PC = return. | andi TMP0, PC, FRAME_TYPE | bnez TMP0, ->vm_return |. move MULTRES, RD | lw INS, -4(PC) | decode_RB8a RB, INS | decode_RB8b RB |5: | sltu AT, RD, RB | bnez AT, >6 // More results expected? |. decode_RA8a TMP0, INS | decode_RA8b TMP0 | ins_next1 | // Adjust BASE. KBASE is assumed to be set for the calling frame. | subu BASE, RA, TMP0 | ins_next2 | |6: // Fill up results with nil. | addu TMP1, RA, RD | addiu RD, RD, 8 | b <5 |. sw TISNIL, -8+HI(TMP1) | |.macro math_extern, func | .ffunc math_ .. func | lw SFARG1HI, HI(BASE) | beqz NARGS8:RC, ->fff_fallback |. load_got func | sltiu AT, SFARG1HI, LJ_TISNUM | beqz AT, ->fff_fallback |.if FPU |. ldc1 FARG1, 0(BASE) |.else |. lw SFARG1LO, LO(BASE) |.endif | call_extern |. nop | b ->fff_resn |. nop |.endmacro | |.macro math_extern2, func | .ffunc_nn math_ .. func |. load_got func | call_extern |. nop | b ->fff_resn |. nop |.endmacro | |// TODO: Return integer type if result is integer (own sf implementation). |.macro math_round, func |->ff_math_ .. func: | lw SFARG1HI, HI(BASE) | beqz NARGS8:RC, ->fff_fallback |. lw SFARG1LO, LO(BASE) | beq SFARG1HI, TISNUM, ->fff_restv |. sltu AT, SFARG1HI, TISNUM | beqz AT, ->fff_fallback |.if FPU |. ldc1 FARG1, 0(BASE) | bal ->vm_ .. func |.else |. load_got func | call_extern |.endif |. nop | b ->fff_resn |. nop |.endmacro | | math_round floor | math_round ceil | |.ffunc math_log | li AT, 8 | bne NARGS8:RC, AT, ->fff_fallback // Exactly 1 argument. |. lw SFARG1HI, HI(BASE) | sltiu AT, SFARG1HI, LJ_TISNUM | beqz AT, ->fff_fallback |. load_got log |.if FPU | call_extern |. ldc1 FARG1, 0(BASE) |.else | call_extern |. lw SFARG1LO, LO(BASE) |.endif | b ->fff_resn |. nop | | math_extern log10 | math_extern exp | math_extern sin | math_extern cos | math_extern tan | math_extern asin | math_extern acos | math_extern atan | math_extern sinh | math_extern cosh | math_extern tanh | math_extern2 pow | math_extern2 atan2 | math_extern2 fmod | |.if FPU |.ffunc_n math_sqrt |. sqrt.d FRET1, FARG1 |// fallthrough to ->fff_resn |.else | math_extern sqrt |.endif | |->fff_resn: | lw PC, FRAME_PC(BASE) | addiu RA, BASE, -8 |.if FPU | b ->fff_res1 |. sdc1 FRET1, -8(BASE) |.else | sw SFRETHI, -8+HI(BASE) | b ->fff_res1 |. sw SFRETLO, -8+LO(BASE) |.endif | | |.ffunc math_ldexp | sltiu AT, NARGS8:RC, 16 | lw SFARG1HI, HI(BASE) | bnez AT, ->fff_fallback |. lw CARG4, 8+HI(BASE) | bne CARG4, TISNUM, ->fff_fallback | load_got ldexp |. sltu AT, SFARG1HI, TISNUM | beqz AT, ->fff_fallback |.if FPU |. ldc1 FARG1, 0(BASE) |.else |. lw SFARG1LO, LO(BASE) |.endif | call_extern |. lw CARG3, 8+LO(BASE) | b ->fff_resn |. nop | |.ffunc_n math_frexp | load_got frexp | lw PC, FRAME_PC(BASE) | call_extern |. addiu CARG3, DISPATCH, DISPATCH_GL(tmptv) | lw TMP1, DISPATCH_GL(tmptv)(DISPATCH) | addiu RA, BASE, -8 |.if FPU | mtc1 TMP1, FARG2 | sdc1 FRET1, 0(RA) | cvt.d.w FARG2, FARG2 | sdc1 FARG2, 8(RA) |.else | sw SFRETLO, LO(RA) | sw SFRETHI, HI(RA) | sw TMP1, 8+LO(RA) | sw TISNUM, 8+HI(RA) |.endif | b ->fff_res |. li RD, (2+1)*8 | |.ffunc_n math_modf | load_got modf | lw PC, FRAME_PC(BASE) | call_extern |. addiu CARG3, BASE, -8 | addiu RA, BASE, -8 |.if FPU | sdc1 FRET1, 0(BASE) |.else | sw SFRETLO, LO(BASE) | sw SFRETHI, HI(BASE) |.endif | b ->fff_res |. li RD, (2+1)*8 | |.macro math_minmax, name, intins, ismax | .ffunc_1 name | addu TMP3, BASE, NARGS8:RC | bne SFARG1HI, TISNUM, >5 |. addiu TMP2, BASE, 8 |1: // Handle integers. |. lw SFARG2HI, HI(TMP2) | beq TMP2, TMP3, ->fff_restv |. lw SFARG2LO, LO(TMP2) | bne SFARG2HI, TISNUM, >3 |. slt AT, SFARG1LO, SFARG2LO | intins SFARG1LO, SFARG2LO, AT | b <1 |. addiu TMP2, TMP2, 8 | |3: // Convert intermediate result to number and continue with number loop. | sltiu AT, SFARG2HI, LJ_TISNUM | beqz AT, ->fff_fallback |.if FPU |. mtc1 SFARG1LO, FRET1 | cvt.d.w FRET1, FRET1 | b >7 |. ldc1 FARG1, 0(TMP2) |.else |. nop | bal ->vm_sfi2d_1 |. nop | b >7 |. nop |.endif | |5: |. sltiu AT, SFARG1HI, LJ_TISNUM | beqz AT, ->fff_fallback |.if FPU |. ldc1 FRET1, 0(BASE) |.endif | |6: // Handle numbers. |. lw SFARG2HI, HI(TMP2) |.if FPU | beq TMP2, TMP3, ->fff_resn |.else | beq TMP2, TMP3, ->fff_restv |.endif |. sltiu AT, SFARG2HI, LJ_TISNUM | beqz AT, >8 |.if FPU |. ldc1 FARG1, 0(TMP2) |.else |. lw SFARG2LO, LO(TMP2) |.endif |7: |.if FPU |.if ismax | c.olt.d FARG1, FRET1 |.else | c.olt.d FRET1, FARG1 |.endif | movf.d FRET1, FARG1 |.else |.if ismax | bal ->vm_sfcmpogt |.else | bal ->vm_sfcmpolt |.endif |. nop | movz SFARG1LO, SFARG2LO, CRET1 | movz SFARG1HI, SFARG2HI, CRET1 |.endif | b <6 |. addiu TMP2, TMP2, 8 | |8: // Convert integer to number and continue with number loop. | bne SFARG2HI, TISNUM, ->fff_fallback |.if FPU |. lwc1 FARG1, LO(TMP2) | b <7 |. cvt.d.w FARG1, FARG1 |.else |. nop | bal ->vm_sfi2d_2 |. nop | b <7 |. nop |.endif | |.endmacro | | math_minmax math_min, movz, 0 | math_minmax math_max, movn, 1 | |//-- String library ----------------------------------------------------- | |.ffunc string_byte // Only handle the 1-arg case here. | lw CARG3, HI(BASE) | lw STR:CARG1, LO(BASE) | xori AT, NARGS8:RC, 8 | addiu CARG3, CARG3, -LJ_TSTR | or AT, AT, CARG3 | bnez AT, ->fff_fallback // Need exactly 1 string argument. |. nop | lw TMP0, STR:CARG1->len | addiu RA, BASE, -8 | lw PC, FRAME_PC(BASE) | sltu RD, r0, TMP0 | lbu TMP1, STR:CARG1[1] // Access is always ok (NUL at end). | addiu RD, RD, 1 | sll RD, RD, 3 // RD = ((str->len != 0)+1)*8 | sw TISNUM, HI(RA) | b ->fff_res |. sw TMP1, LO(RA) | |.ffunc string_char // Only handle the 1-arg case here. | ffgccheck |. nop | lw CARG3, HI(BASE) | lw CARG1, LO(BASE) | li TMP1, 255 | xori AT, NARGS8:RC, 8 // Exactly 1 argument. | xor TMP0, CARG3, TISNUM // Integer. | sltu TMP1, TMP1, CARG1 // !(255 < n). | or AT, AT, TMP0 | or AT, AT, TMP1 | bnez AT, ->fff_fallback |. li CARG3, 1 | addiu CARG2, sp, ARG5_OFS | sb CARG1, ARG5 |->fff_newstr: | load_got lj_str_new | sw BASE, L->base | sw PC, SAVE_PC | call_intern lj_str_new // (lua_State *L, char *str, size_t l) |. move CARG1, L | // Returns GCstr *. | lw BASE, L->base |->fff_resstr: | move SFARG1LO, CRET1 | b ->fff_restv |. li SFARG1HI, LJ_TSTR | |.ffunc string_sub | ffgccheck |. nop | addiu AT, NARGS8:RC, -16 | lw CARG3, 16+HI(BASE) | lw TMP0, HI(BASE) | lw STR:CARG1, LO(BASE) | bltz AT, ->fff_fallback |. lw CARG2, 8+HI(BASE) | beqz AT, >1 |. li CARG4, -1 | bne CARG3, TISNUM, ->fff_fallback |. lw CARG4, 16+LO(BASE) |1: | bne CARG2, TISNUM, ->fff_fallback |. li AT, LJ_TSTR | bne TMP0, AT, ->fff_fallback |. lw CARG3, 8+LO(BASE) | lw CARG2, STR:CARG1->len | // STR:CARG1 = str, CARG2 = str->len, CARG3 = start, CARG4 = end | slt AT, CARG4, r0 | addiu TMP0, CARG2, 1 | addu TMP1, CARG4, TMP0 | slt TMP3, CARG3, r0 | movn CARG4, TMP1, AT // if (end < 0) end += len+1 | addu TMP1, CARG3, TMP0 | movn CARG3, TMP1, TMP3 // if (start < 0) start += len+1 | li TMP2, 1 | slt AT, CARG4, r0 | slt TMP3, r0, CARG3 | movn CARG4, r0, AT // if (end < 0) end = 0 | movz CARG3, TMP2, TMP3 // if (start < 1) start = 1 | slt AT, CARG2, CARG4 | movn CARG4, CARG2, AT // if (end > len) end = len | addu CARG2, STR:CARG1, CARG3 | subu CARG3, CARG4, CARG3 // len = end - start | addiu CARG2, CARG2, sizeof(GCstr)-1 | bgez CARG3, ->fff_newstr |. addiu CARG3, CARG3, 1 // len++ |->fff_emptystr: // Return empty string. | addiu STR:SFARG1LO, DISPATCH, DISPATCH_GL(strempty) | b ->fff_restv |. li SFARG1HI, LJ_TSTR | |.macro ffstring_op, name | .ffunc string_ .. name | ffgccheck |. nop | lw CARG3, HI(BASE) | lw STR:CARG2, LO(BASE) | beqz NARGS8:RC, ->fff_fallback |. li AT, LJ_TSTR | bne CARG3, AT, ->fff_fallback |. addiu SBUF:CARG1, DISPATCH, DISPATCH_GL(tmpbuf) | load_got lj_buf_putstr_ .. name | lw TMP0, SBUF:CARG1->b | sw L, SBUF:CARG1->L | sw BASE, L->base | sw TMP0, SBUF:CARG1->w | call_intern extern lj_buf_putstr_ .. name |. sw PC, SAVE_PC | load_got lj_buf_tostr | call_intern lj_buf_tostr |. move SBUF:CARG1, SBUF:CRET1 | b ->fff_resstr |. lw BASE, L->base |.endmacro | |ffstring_op reverse |ffstring_op lower |ffstring_op upper | |//-- Bit library -------------------------------------------------------- | |->vm_tobit_fb: | beqz TMP1, ->fff_fallback |.if FPU |. ldc1 FARG1, 0(BASE) | add.d FARG1, FARG1, TOBIT | jr ra |. mfc1 CRET1, FARG1 |.else |// FP number to bit conversion for soft-float. |->vm_tobit: | sll TMP0, SFARG1HI, 1 | lui AT, 0x0020 | addu TMP0, TMP0, AT | slt AT, TMP0, r0 | movz SFARG1LO, r0, AT | beqz AT, >2 |. li TMP1, 0x3e0 | not TMP1, TMP1 | sra TMP0, TMP0, 21 | subu TMP0, TMP1, TMP0 | slt AT, TMP0, r0 | bnez AT, >1 |. sll TMP1, SFARG1HI, 11 | lui AT, 0x8000 | or TMP1, TMP1, AT | srl AT, SFARG1LO, 21 | or TMP1, TMP1, AT | slt AT, SFARG1HI, r0 | beqz AT, >2 |. srlv SFARG1LO, TMP1, TMP0 | subu SFARG1LO, r0, SFARG1LO |2: | jr ra |. move CRET1, SFARG1LO |1: | addiu TMP0, TMP0, 21 | srlv TMP1, SFARG1LO, TMP0 | li AT, 20 | subu TMP0, AT, TMP0 | sll SFARG1LO, SFARG1HI, 12 | sllv AT, SFARG1LO, TMP0 | or SFARG1LO, TMP1, AT | slt AT, SFARG1HI, r0 | beqz AT, <2 |. nop | jr ra |. subu CRET1, r0, SFARG1LO |.endif | |.macro .ffunc_bit, name | .ffunc_1 bit_..name | beq SFARG1HI, TISNUM, >6 |. move CRET1, SFARG1LO | bal ->vm_tobit_fb |. sltu TMP1, SFARG1HI, TISNUM |6: |.endmacro | |.macro .ffunc_bit_op, name, ins | .ffunc_bit name | addiu TMP2, BASE, 8 | addu TMP3, BASE, NARGS8:RC |1: | lw SFARG1HI, HI(TMP2) | beq TMP2, TMP3, ->fff_resi |. lw SFARG1LO, LO(TMP2) |.if FPU | bne SFARG1HI, TISNUM, >2 |. addiu TMP2, TMP2, 8 | b <1 |. ins CRET1, CRET1, SFARG1LO |2: | ldc1 FARG1, -8(TMP2) | sltu TMP1, SFARG1HI, TISNUM | beqz TMP1, ->fff_fallback |. add.d FARG1, FARG1, TOBIT | mfc1 SFARG1LO, FARG1 | b <1 |. ins CRET1, CRET1, SFARG1LO |.else | beq SFARG1HI, TISNUM, >2 |. move CRET2, CRET1 | bal ->vm_tobit_fb |. sltu TMP1, SFARG1HI, TISNUM | move SFARG1LO, CRET2 |2: | ins CRET1, CRET1, SFARG1LO | b <1 |. addiu TMP2, TMP2, 8 |.endif |.endmacro | |.ffunc_bit_op band, and |.ffunc_bit_op bor, or |.ffunc_bit_op bxor, xor | |.ffunc_bit bswap | srl TMP0, CRET1, 24 | srl TMP2, CRET1, 8 | sll TMP1, CRET1, 24 | andi TMP2, TMP2, 0xff00 | or TMP0, TMP0, TMP1 | andi CRET1, CRET1, 0xff00 | or TMP0, TMP0, TMP2 | sll CRET1, CRET1, 8 | b ->fff_resi |. or CRET1, TMP0, CRET1 | |.ffunc_bit bnot | b ->fff_resi |. not CRET1, CRET1 | |.macro .ffunc_bit_sh, name, ins, shmod | .ffunc_2 bit_..name | beq SFARG1HI, TISNUM, >1 |. nop | bal ->vm_tobit_fb |. sltu TMP1, SFARG1HI, TISNUM | move SFARG1LO, CRET1 |1: | bne SFARG2HI, TISNUM, ->fff_fallback |. nop |.if shmod == 1 | li AT, 32 | subu TMP0, AT, SFARG2LO | sllv SFARG2LO, SFARG1LO, SFARG2LO | srlv SFARG1LO, SFARG1LO, TMP0 |.elif shmod == 2 | li AT, 32 | subu TMP0, AT, SFARG2LO | srlv SFARG2LO, SFARG1LO, SFARG2LO | sllv SFARG1LO, SFARG1LO, TMP0 |.endif | b ->fff_resi |. ins CRET1, SFARG1LO, SFARG2LO |.endmacro | |.ffunc_bit_sh lshift, sllv, 0 |.ffunc_bit_sh rshift, srlv, 0 |.ffunc_bit_sh arshift, srav, 0 |// Can't use rotrv, since it's only in MIPS32R2. |.ffunc_bit_sh rol, or, 1 |.ffunc_bit_sh ror, or, 2 | |.ffunc_bit tobit |->fff_resi: | lw PC, FRAME_PC(BASE) | addiu RA, BASE, -8 | sw TISNUM, -8+HI(BASE) | b ->fff_res1 |. sw CRET1, -8+LO(BASE) | |//----------------------------------------------------------------------- | |->fff_fallback: // Call fast function fallback handler. | // BASE = new base, RB = CFUNC, RC = nargs*8 | lw TMP3, CFUNC:RB->f | addu TMP1, BASE, NARGS8:RC | lw PC, FRAME_PC(BASE) // Fallback may overwrite PC. | addiu TMP0, TMP1, 8*LUA_MINSTACK | lw TMP2, L->maxstack | sw PC, SAVE_PC // Redundant (but a defined value). | sltu AT, TMP2, TMP0 | sw BASE, L->base | sw TMP1, L->top | bnez AT, >5 // Need to grow stack. |. move CFUNCADDR, TMP3 | jalr TMP3 // (lua_State *L) |. move CARG1, L | // Either throws an error, or recovers and returns -1, 0 or nresults+1. | lw BASE, L->base | sll RD, CRET1, 3 | bgtz CRET1, ->fff_res // Returned nresults+1? |. addiu RA, BASE, -8 |1: // Returned 0 or -1: retry fast path. | lw TMP0, L->top | lw LFUNC:RB, FRAME_FUNC(BASE) | bnez CRET1, ->vm_call_tail // Returned -1? |. subu NARGS8:RC, TMP0, BASE | ins_callt // Returned 0: retry fast path. | |// Reconstruct previous base for vmeta_call during tailcall. |->vm_call_tail: | andi TMP0, PC, FRAME_TYPE | li AT, -4 | bnez TMP0, >3 |. and TMP1, PC, AT | lbu TMP1, OFS_RA(PC) | sll TMP1, TMP1, 3 | addiu TMP1, TMP1, 8 |3: | b ->vm_call_dispatch // Resolve again for tailcall. |. subu TMP2, BASE, TMP1 | |5: // Grow stack for fallback handler. | load_got lj_state_growstack | li CARG2, LUA_MINSTACK | call_intern lj_state_growstack // (lua_State *L, int n) |. move CARG1, L | lw BASE, L->base | b <1 |. li CRET1, 0 // Force retry. | |->fff_gcstep: // Call GC step function. | // BASE = new base, RC = nargs*8 | move MULTRES, ra | load_got lj_gc_step | sw BASE, L->base | addu TMP0, BASE, NARGS8:RC | sw PC, SAVE_PC // Redundant (but a defined value). | sw TMP0, L->top | call_intern lj_gc_step // (lua_State *L) |. move CARG1, L | lw BASE, L->base | move ra, MULTRES | lw TMP0, L->top | lw CFUNC:RB, FRAME_FUNC(BASE) | jr ra |. subu NARGS8:RC, TMP0, BASE | |//----------------------------------------------------------------------- |//-- Special dispatch targets ------------------------------------------- |//----------------------------------------------------------------------- | |->vm_record: // Dispatch target for recording phase. |.if JIT | lbu TMP3, DISPATCH_GL(hookmask)(DISPATCH) | andi AT, TMP3, HOOK_VMEVENT // No recording while in vmevent. | bnez AT, >5 | // Decrement the hookcount for consistency, but always do the call. |. lw TMP2, DISPATCH_GL(hookcount)(DISPATCH) | andi AT, TMP3, HOOK_ACTIVE | bnez AT, >1 |. addiu TMP2, TMP2, -1 | andi AT, TMP3, LUA_MASKLINE|LUA_MASKCOUNT | beqz AT, >1 |. nop | b >1 |. sw TMP2, DISPATCH_GL(hookcount)(DISPATCH) |.endif | |->vm_rethook: // Dispatch target for return hooks. | lbu TMP3, DISPATCH_GL(hookmask)(DISPATCH) | andi AT, TMP3, HOOK_ACTIVE // Hook already active? | beqz AT, >1 |5: // Re-dispatch to static ins. |. lw AT, GG_DISP2STATIC(TMP0) // Assumes TMP0 holds DISPATCH+OP*4. | jr AT |. nop | |->vm_inshook: // Dispatch target for instr/line hooks. | lbu TMP3, DISPATCH_GL(hookmask)(DISPATCH) | lw TMP2, DISPATCH_GL(hookcount)(DISPATCH) | andi AT, TMP3, HOOK_ACTIVE // Hook already active? | bnez AT, <5 |. andi AT, TMP3, LUA_MASKLINE|LUA_MASKCOUNT | beqz AT, <5 |. addiu TMP2, TMP2, -1 | beqz TMP2, >1 |. sw TMP2, DISPATCH_GL(hookcount)(DISPATCH) | andi AT, TMP3, LUA_MASKLINE | beqz AT, <5 |1: |. load_got lj_dispatch_ins | sw MULTRES, SAVE_MULTRES | move CARG2, PC | sw BASE, L->base | // SAVE_PC must hold the _previous_ PC. The callee updates it with PC. | call_intern lj_dispatch_ins // (lua_State *L, const BCIns *pc) |. move CARG1, L |3: | lw BASE, L->base |4: // Re-dispatch to static ins. | lw INS, -4(PC) | decode_OP4a TMP1, INS | decode_OP4b TMP1 | addu TMP0, DISPATCH, TMP1 | decode_RD8a RD, INS | lw AT, GG_DISP2STATIC(TMP0) | decode_RA8a RA, INS | decode_RD8b RD | jr AT | decode_RA8b RA | |->cont_hook: // Continue from hook yield. | addiu PC, PC, 4 | b <4 |. lw MULTRES, -24+LO(RB) // Restore MULTRES for *M ins. | |->vm_hotloop: // Hot loop counter underflow. |.if JIT | lw LFUNC:TMP1, FRAME_FUNC(BASE) | addiu CARG1, DISPATCH, GG_DISP2J | sw PC, SAVE_PC | lw TMP1, LFUNC:TMP1->pc | move CARG2, PC | sw L, DISPATCH_J(L)(DISPATCH) | lbu TMP1, PC2PROTO(framesize)(TMP1) | load_got lj_trace_hot | sw BASE, L->base | sll TMP1, TMP1, 3 | addu TMP1, BASE, TMP1 | call_intern lj_trace_hot // (jit_State *J, const BCIns *pc) |. sw TMP1, L->top | b <3 |. nop |.endif | |->vm_callhook: // Dispatch target for call hooks. |.if JIT | b >1 |.endif |. move CARG2, PC | |->vm_hotcall: // Hot call counter underflow. |.if JIT | ori CARG2, PC, 1 |1: |.endif | load_got lj_dispatch_call | addu TMP0, BASE, RC | sw PC, SAVE_PC | sw BASE, L->base | subu RA, RA, BASE | sw TMP0, L->top | call_intern lj_dispatch_call // (lua_State *L, const BCIns *pc) |. move CARG1, L | // Returns ASMFunction. | lw BASE, L->base | lw TMP0, L->top | sw r0, SAVE_PC // Invalidate for subsequent line hook. | subu NARGS8:RC, TMP0, BASE | addu RA, BASE, RA | lw LFUNC:RB, FRAME_FUNC(BASE) | jr CRET1 |. lw INS, -4(PC) | |->cont_stitch: // Trace stitching. |.if JIT | // RA = resultptr, RB = meta base | lw INS, -4(PC) | lw TMP2, -24+LO(RB) // Save previous trace. | decode_RA8a RC, INS | addiu AT, MULTRES, -8 | decode_RA8b RC | beqz AT, >2 |. addu RC, BASE, RC // Call base. |1: // Move results down. | lw SFRETHI, HI(RA) | lw SFRETLO, LO(RA) | addiu AT, AT, -8 | addiu RA, RA, 8 | sw SFRETHI, HI(RC) | sw SFRETLO, LO(RC) | bnez AT, <1 |. addiu RC, RC, 8 |2: | decode_RA8a RA, INS | decode_RB8a RB, INS | decode_RA8b RA | decode_RB8b RB | addu RA, RA, RB | addu RA, BASE, RA |3: | sltu AT, RC, RA | bnez AT, >9 // More results wanted? |. nop | | lhu TMP3, TRACE:TMP2->traceno | lhu RD, TRACE:TMP2->link | beq RD, TMP3, ->cont_nop // Blacklisted. |. load_got lj_dispatch_stitch | bnez RD, =>BC_JLOOP // Jump to stitched trace. |. sll RD, RD, 3 | | // Stitch a new trace to the previous trace. | sw TMP3, DISPATCH_J(exitno)(DISPATCH) | sw L, DISPATCH_J(L)(DISPATCH) | sw BASE, L->base | addiu CARG1, DISPATCH, GG_DISP2J | call_intern lj_dispatch_stitch // (jit_State *J, const BCIns *pc) |. move CARG2, PC | b ->cont_nop |. lw BASE, L->base | |9: | sw TISNIL, HI(RC) | b <3 |. addiu RC, RC, 8 |.endif | |->vm_profhook: // Dispatch target for profiler hook. #if LJ_HASPROFILE | load_got lj_dispatch_profile | sw MULTRES, SAVE_MULTRES | move CARG2, PC | sw BASE, L->base | call_intern lj_dispatch_profile // (lua_State *L, const BCIns *pc) |. move CARG1, L | // HOOK_PROFILE is off again, so re-dispatch to dynamic instruction. | addiu PC, PC, -4 | b ->cont_nop |. lw BASE, L->base #endif | |//----------------------------------------------------------------------- |//-- Trace exit handler ------------------------------------------------- |//----------------------------------------------------------------------- | |.macro savex_, a, b |.if FPU | sdc1 f..a, 16+a*8(sp) | sw r..a, 16+32*8+a*4(sp) | sw r..b, 16+32*8+b*4(sp) |.else | sw r..a, 16+a*4(sp) | sw r..b, 16+b*4(sp) |.endif |.endmacro | |->vm_exit_handler: |.if JIT |.if FPU | addiu sp, sp, -(16+32*8+32*4) |.else | addiu sp, sp, -(16+32*4) |.endif | savex_ 0, 1 | savex_ 2, 3 | savex_ 4, 5 | savex_ 6, 7 | savex_ 8, 9 | savex_ 10, 11 | savex_ 12, 13 | savex_ 14, 15 | savex_ 16, 17 | savex_ 18, 19 | savex_ 20, 21 | savex_ 22, 23 | savex_ 24, 25 | savex_ 26, 27 |.if FPU | sdc1 f28, 16+28*8(sp) | sdc1 f30, 16+30*8(sp) | sw r28, 16+32*8+28*4(sp) | sw r30, 16+32*8+30*4(sp) | sw r0, 16+32*8+31*4(sp) // Clear RID_TMP. | addiu TMP2, sp, 16+32*8+32*4 // Recompute original value of sp. | sw TMP2, 16+32*8+29*4(sp) // Store sp in RID_SP |.else | sw r28, 16+28*4(sp) | sw r30, 16+30*4(sp) | sw r0, 16+31*4(sp) // Clear RID_TMP. | addiu TMP2, sp, 16+32*4 // Recompute original value of sp. | sw TMP2, 16+29*4(sp) // Store sp in RID_SP |.endif | li_vmstate EXIT | addiu DISPATCH, JGL, -GG_DISP2G-32768 | lw TMP1, 0(TMP2) // Load exit number. | st_vmstate | lw L, DISPATCH_GL(cur_L)(DISPATCH) | lw BASE, DISPATCH_GL(jit_base)(DISPATCH) | load_got lj_trace_exit | sw L, DISPATCH_J(L)(DISPATCH) | sw ra, DISPATCH_J(parent)(DISPATCH) // Store trace number. | sw BASE, L->base | sw TMP1, DISPATCH_J(exitno)(DISPATCH) // Store exit number. | addiu CARG1, DISPATCH, GG_DISP2J | sw r0, DISPATCH_GL(jit_base)(DISPATCH) | call_intern lj_trace_exit // (jit_State *J, ExitState *ex) |. addiu CARG2, sp, 16 | // Returns MULTRES (unscaled) or negated error code. | lw TMP1, L->cframe | li AT, -4 | lw BASE, L->base | and sp, TMP1, AT | lw PC, SAVE_PC // Get SAVE_PC. | b >1 |. sw L, SAVE_L // Set SAVE_L (on-trace resume/yield). |.endif |->vm_exit_interp: |.if JIT | // CRET1 = MULTRES or negated error code, BASE, PC and JGL set. | lw L, SAVE_L | addiu DISPATCH, JGL, -GG_DISP2G-32768 | sw BASE, L->base |1: | bltz CRET1, >9 // Check for error from exit. |. lw LFUNC:RB, FRAME_FUNC(BASE) | .FPU lui TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). | sll MULTRES, CRET1, 3 | li TISNIL, LJ_TNIL | li TISNUM, LJ_TISNUM // Setup type comparison constants. | sw MULTRES, SAVE_MULTRES | .FPU mtc1 TMP3, TOBIT | lw TMP1, LFUNC:RB->pc | sw r0, DISPATCH_GL(jit_base)(DISPATCH) | lw KBASE, PC2PROTO(k)(TMP1) | .FPU cvt.d.s TOBIT, TOBIT | // Modified copy of ins_next which handles function header dispatch, too. | lw INS, 0(PC) | addiu PC, PC, 4 | // Assumes TISNIL == ~LJ_VMST_INTERP == -1 | sw TISNIL, DISPATCH_GL(vmstate)(DISPATCH) | decode_OP4a TMP1, INS | decode_OP4b TMP1 | sltiu TMP2, TMP1, BC_FUNCF*4 | addu TMP0, DISPATCH, TMP1 | decode_RD8a RD, INS | lw AT, 0(TMP0) | decode_RA8a RA, INS | beqz TMP2, >2 |. decode_RA8b RA | jr AT |. decode_RD8b RD |2: | sltiu TMP2, TMP1, (BC_FUNCC+2)*4 // Fast function? | bnez TMP2, >3 |. lw TMP1, FRAME_PC(BASE) | // Check frame below fast function. | andi TMP0, TMP1, FRAME_TYPE | bnez TMP0, >3 // Trace stitching continuation? |. nop | // Otherwise set KBASE for Lua function below fast function. | lw TMP2, -4(TMP1) | decode_RA8a TMP0, TMP2 | decode_RA8b TMP0 | subu TMP1, BASE, TMP0 | lw LFUNC:TMP2, -8+FRAME_FUNC(TMP1) | lw TMP1, LFUNC:TMP2->pc | lw KBASE, PC2PROTO(k)(TMP1) |3: | addiu RC, MULTRES, -8 | jr AT |. addu RA, RA, BASE | |9: // Rethrow error from the right C frame. | load_got lj_err_trace | sub CARG2, r0, CRET1 | call_intern lj_err_trace // (lua_State *L, int errcode) |. move CARG1, L |.endif | |//----------------------------------------------------------------------- |//-- Math helper functions ---------------------------------------------- |//----------------------------------------------------------------------- | |// Hard-float round to integer. |// Modifies AT, TMP0, FRET1, FRET2, f4. Keeps all others incl. FARG1. |.macro vm_round_hf, func | lui TMP0, 0x4330 // Hiword of 2^52 (double). | mtc1 r0, f4 | mtc1 TMP0, f5 | abs.d FRET2, FARG1 // |x| | mfc1 AT, f13 | c.olt.d 0, FRET2, f4 | add.d FRET1, FRET2, f4 // (|x| + 2^52) - 2^52 | bc1f 0, >1 // Truncate only if |x| < 2^52. |. sub.d FRET1, FRET1, f4 | slt AT, AT, r0 |.if "func" == "ceil" | lui TMP0, 0xbff0 // Hiword of -1 (double). Preserves -0. |.else | lui TMP0, 0x3ff0 // Hiword of +1 (double). |.endif |.if "func" == "trunc" | mtc1 TMP0, f5 | c.olt.d 0, FRET2, FRET1 // |x| < result? | sub.d FRET2, FRET1, f4 | movt.d FRET1, FRET2, 0 // If yes, subtract +1. | neg.d FRET2, FRET1 | jr ra |. movn.d FRET1, FRET2, AT // Merge sign bit back in. |.else | neg.d FRET2, FRET1 | mtc1 TMP0, f5 | movn.d FRET1, FRET2, AT // Merge sign bit back in. |.if "func" == "ceil" | c.olt.d 0, FRET1, FARG1 // x > result? |.else | c.olt.d 0, FARG1, FRET1 // x < result? |.endif | sub.d FRET2, FRET1, f4 // If yes, subtract +-1. | jr ra |. movt.d FRET1, FRET2, 0 |.endif |1: | jr ra |. mov.d FRET1, FARG1 |.endmacro | |.macro vm_round, func |.if FPU | vm_round_hf, func |.endif |.endmacro | |->vm_floor: | vm_round floor |->vm_ceil: | vm_round ceil |->vm_trunc: |.if JIT | vm_round trunc |.endif | |// Soft-float integer to number conversion. |.macro sfi2d, AHI, ALO |.if not FPU | beqz ALO, >9 // Handle zero first. |. sra TMP0, ALO, 31 | xor TMP1, ALO, TMP0 | subu TMP1, TMP1, TMP0 // Absolute value in TMP1. | clz AHI, TMP1 | andi TMP0, TMP0, 0x800 // Mask sign bit. | li AT, 0x3ff+31-1 | sllv TMP1, TMP1, AHI // Align mantissa left with leading 1. | subu AHI, AT, AHI // Exponent - 1 in AHI. | sll ALO, TMP1, 21 | or AHI, AHI, TMP0 // Sign | Exponent. | srl TMP1, TMP1, 11 | sll AHI, AHI, 20 // Align left. | jr ra |. addu AHI, AHI, TMP1 // Add mantissa, increment exponent. |9: | jr ra |. li AHI, 0 |.endif |.endmacro | |// Input SFARG1LO. Output: SFARG1*. Temporaries: AT, TMP0, TMP1. |->vm_sfi2d_1: | sfi2d SFARG1HI, SFARG1LO | |// Input SFARG2LO. Output: SFARG2*. Temporaries: AT, TMP0, TMP1. |->vm_sfi2d_2: | sfi2d SFARG2HI, SFARG2LO | |// Soft-float comparison. Equivalent to c.eq.d. |// Input: SFARG*. Output: CRET1. Temporaries: AT, TMP0, TMP1. |->vm_sfcmpeq: |.if not FPU | sll AT, SFARG1HI, 1 | sll TMP0, SFARG2HI, 1 | or CRET1, SFARG1LO, SFARG2LO | or TMP1, AT, TMP0 | or TMP1, TMP1, CRET1 | beqz TMP1, >8 // Both args +-0: return 1. |. sltu CRET1, r0, SFARG1LO | lui TMP1, 0xffe0 | addu AT, AT, CRET1 | sltu CRET1, r0, SFARG2LO | sltu AT, TMP1, AT | addu TMP0, TMP0, CRET1 | sltu TMP0, TMP1, TMP0 | or TMP1, AT, TMP0 | bnez TMP1, >9 // Either arg is NaN: return 0; |. xor TMP0, SFARG1HI, SFARG2HI | xor TMP1, SFARG1LO, SFARG2LO | or AT, TMP0, TMP1 | jr ra |. sltiu CRET1, AT, 1 // Same values: return 1. |8: | jr ra |. li CRET1, 1 |9: | jr ra |. li CRET1, 0 |.endif | |// Soft-float comparison. Equivalent to c.ult.d and c.olt.d. |// Input: SFARG*. Output: CRET1. Temporaries: AT, TMP0, TMP1, CRET2. |->vm_sfcmpult: |.if not FPU | b >1 |. li CRET2, 1 |.endif | |->vm_sfcmpolt: |.if not FPU | li CRET2, 0 |1: | sll AT, SFARG1HI, 1 | sll TMP0, SFARG2HI, 1 | or CRET1, SFARG1LO, SFARG2LO | or TMP1, AT, TMP0 | or TMP1, TMP1, CRET1 | beqz TMP1, >8 // Both args +-0: return 0. |. sltu CRET1, r0, SFARG1LO | lui TMP1, 0xffe0 | addu AT, AT, CRET1 | sltu CRET1, r0, SFARG2LO | sltu AT, TMP1, AT | addu TMP0, TMP0, CRET1 | sltu TMP0, TMP1, TMP0 | or TMP1, AT, TMP0 | bnez TMP1, >9 // Either arg is NaN: return 0 or 1; |. and AT, SFARG1HI, SFARG2HI | bltz AT, >5 // Both args negative? |. nop | beq SFARG1HI, SFARG2HI, >8 |. sltu CRET1, SFARG1LO, SFARG2LO | jr ra |. slt CRET1, SFARG1HI, SFARG2HI |5: // Swap conditions if both operands are negative. | beq SFARG1HI, SFARG2HI, >8 |. sltu CRET1, SFARG2LO, SFARG1LO | jr ra |. slt CRET1, SFARG2HI, SFARG1HI |8: | jr ra |. nop |9: | jr ra |. move CRET1, CRET2 |.endif | |->vm_sfcmpogt: |.if not FPU | sll AT, SFARG2HI, 1 | sll TMP0, SFARG1HI, 1 | or CRET1, SFARG2LO, SFARG1LO | or TMP1, AT, TMP0 | or TMP1, TMP1, CRET1 | beqz TMP1, >8 // Both args +-0: return 0. |. sltu CRET1, r0, SFARG2LO | lui TMP1, 0xffe0 | addu AT, AT, CRET1 | sltu CRET1, r0, SFARG1LO | sltu AT, TMP1, AT | addu TMP0, TMP0, CRET1 | sltu TMP0, TMP1, TMP0 | or TMP1, AT, TMP0 | bnez TMP1, >9 // Either arg is NaN: return 0 or 1; |. and AT, SFARG2HI, SFARG1HI | bltz AT, >5 // Both args negative? |. nop | beq SFARG2HI, SFARG1HI, >8 |. sltu CRET1, SFARG2LO, SFARG1LO | jr ra |. slt CRET1, SFARG2HI, SFARG1HI |5: // Swap conditions if both operands are negative. | beq SFARG2HI, SFARG1HI, >8 |. sltu CRET1, SFARG1LO, SFARG2LO | jr ra |. slt CRET1, SFARG1HI, SFARG2HI |8: | jr ra |. nop |9: | jr ra |. li CRET1, 0 |.endif | |// Soft-float comparison. Equivalent to c.ole.d a, b or c.ole.d b, a. |// Input: SFARG*, TMP3. Output: CRET1. Temporaries: AT, TMP0, TMP1. |->vm_sfcmpolex: |.if not FPU | sll AT, SFARG1HI, 1 | sll TMP0, SFARG2HI, 1 | or CRET1, SFARG1LO, SFARG2LO | or TMP1, AT, TMP0 | or TMP1, TMP1, CRET1 | beqz TMP1, >8 // Both args +-0: return 1. |. sltu CRET1, r0, SFARG1LO | lui TMP1, 0xffe0 | addu AT, AT, CRET1 | sltu CRET1, r0, SFARG2LO | sltu AT, TMP1, AT | addu TMP0, TMP0, CRET1 | sltu TMP0, TMP1, TMP0 | or TMP1, AT, TMP0 | bnez TMP1, >9 // Either arg is NaN: return 0; |. and AT, SFARG1HI, SFARG2HI | xor AT, AT, TMP3 | bltz AT, >5 // Both args negative? |. nop | beq SFARG1HI, SFARG2HI, >6 |. sltu CRET1, SFARG2LO, SFARG1LO | jr ra |. slt CRET1, SFARG2HI, SFARG1HI |5: // Swap conditions if both operands are negative. | beq SFARG1HI, SFARG2HI, >6 |. sltu CRET1, SFARG1LO, SFARG2LO | slt CRET1, SFARG1HI, SFARG2HI |6: | jr ra |. nop |8: | jr ra |. li CRET1, 1 |9: | jr ra |. li CRET1, 0 |.endif | |.macro sfmin_max, name, fpcall |->vm_sf .. name: |.if JIT and not FPU | move TMP2, ra | bal ->fpcall |. nop | move TMP0, CRET1 | move SFRETHI, SFARG1HI | move SFRETLO, SFARG1LO | move ra, TMP2 | movz SFRETHI, SFARG2HI, TMP0 | jr ra |. movz SFRETLO, SFARG2LO, TMP0 |.endif |.endmacro | | sfmin_max min, vm_sfcmpolt | sfmin_max max, vm_sfcmpogt | |//----------------------------------------------------------------------- |//-- Miscellaneous functions -------------------------------------------- |//----------------------------------------------------------------------- | |.define NEXT_TAB, TAB:CARG1 |.define NEXT_IDX, CARG2 |.define NEXT_ASIZE, CARG3 |.define NEXT_NIL, CARG4 |.define NEXT_TMP0, r12 |.define NEXT_TMP1, r13 |.define NEXT_TMP2, r14 |.define NEXT_RES_VK, CRET1 |.define NEXT_RES_IDX, CRET2 |.define NEXT_RES_PTR, sp |.define NEXT_RES_VAL_I, 0(sp) |.define NEXT_RES_VAL_IT, 4(sp) |.define NEXT_RES_KEY_I, 8(sp) |.define NEXT_RES_KEY_IT, 12(sp) | |// TValue *lj_vm_next(GCtab *t, uint32_t idx) |// Next idx returned in CRET2. |->vm_next: |.if JIT and ENDIAN_LE | lw NEXT_ASIZE, NEXT_TAB->asize | lw NEXT_TMP0, NEXT_TAB->array | li NEXT_NIL, LJ_TNIL |1: // Traverse array part. | sltu AT, NEXT_IDX, NEXT_ASIZE | sll NEXT_TMP1, NEXT_IDX, 3 | beqz AT, >5 |. addu NEXT_TMP1, NEXT_TMP0, NEXT_TMP1 | lw NEXT_TMP2, 4(NEXT_TMP1) | sw NEXT_IDX, NEXT_RES_KEY_I | beq NEXT_TMP2, NEXT_NIL, <1 |. addiu NEXT_IDX, NEXT_IDX, 1 | lw NEXT_TMP0, 0(NEXT_TMP1) | li AT, LJ_TISNUM | sw NEXT_TMP2, NEXT_RES_VAL_IT | sw AT, NEXT_RES_KEY_IT | sw NEXT_TMP0, NEXT_RES_VAL_I | move NEXT_RES_VK, NEXT_RES_PTR | jr ra |. move NEXT_RES_IDX, NEXT_IDX | |5: // Traverse hash part. | subu NEXT_RES_IDX, NEXT_IDX, NEXT_ASIZE | lw NODE:NEXT_RES_VK, NEXT_TAB->node | sll NEXT_TMP2, NEXT_RES_IDX, 5 | lw NEXT_TMP0, NEXT_TAB->hmask | sll AT, NEXT_RES_IDX, 3 | subu AT, NEXT_TMP2, AT | addu NODE:NEXT_RES_VK, NODE:NEXT_RES_VK, AT |6: | sltu AT, NEXT_TMP0, NEXT_RES_IDX | bnez AT, >8 |. nop | lw NEXT_TMP2, NODE:NEXT_RES_VK->val.it | bne NEXT_TMP2, NEXT_NIL, >9 |. addiu NEXT_RES_IDX, NEXT_RES_IDX, 1 | // Skip holes in hash part. | b <6 |. addiu NODE:NEXT_RES_VK, NODE:NEXT_RES_VK, sizeof(Node) | |8: // End of iteration. Set the key to nil (not the value). | sw NEXT_NIL, NEXT_RES_KEY_IT | move NEXT_RES_VK, NEXT_RES_PTR |9: | jr ra |. addu NEXT_RES_IDX, NEXT_RES_IDX, NEXT_ASIZE |.endif | |//----------------------------------------------------------------------- |//-- FFI helper functions ----------------------------------------------- |//----------------------------------------------------------------------- | |// Handler for callback functions. Callback slot number in r1, g in r2. |->vm_ffi_callback: |.if FFI |.type CTSTATE, CTState, PC | saveregs | lw CTSTATE, GL:r2->ctype_state | addiu DISPATCH, r2, GG_G2DISP | load_got lj_ccallback_enter | sw r1, CTSTATE->cb.slot | sw CARG1, CTSTATE->cb.gpr[0] | sw CARG2, CTSTATE->cb.gpr[1] | .FPU sdc1 FARG1, CTSTATE->cb.fpr[0] | sw CARG3, CTSTATE->cb.gpr[2] | sw CARG4, CTSTATE->cb.gpr[3] | .FPU sdc1 FARG2, CTSTATE->cb.fpr[1] | addiu TMP0, sp, CFRAME_SPACE+16 | sw TMP0, CTSTATE->cb.stack | sw r0, SAVE_PC // Any value outside of bytecode is ok. | move CARG2, sp | call_intern lj_ccallback_enter // (CTState *cts, void *cf) |. move CARG1, CTSTATE | // Returns lua_State *. | lw BASE, L:CRET1->base | lw RC, L:CRET1->top | li TISNUM, LJ_TISNUM // Setup type comparison constants. | move L, CRET1 | .FPU lui TMP3, 0x59c0 // TOBIT = 2^52 + 2^51 (float). | lw LFUNC:RB, FRAME_FUNC(BASE) | .FPU mtc1 TMP3, TOBIT | li_vmstate INTERP | li TISNIL, LJ_TNIL | subu RC, RC, BASE | st_vmstate | .FPU cvt.d.s TOBIT, TOBIT | ins_callt |.endif | |->cont_ffi_callback: // Return from FFI callback. |.if FFI | load_got lj_ccallback_leave | lw CTSTATE, DISPATCH_GL(ctype_state)(DISPATCH) | sw BASE, L->base | sw RB, L->top | sw L, CTSTATE->L | move CARG2, RA | call_intern lj_ccallback_leave // (CTState *cts, TValue *o) |. move CARG1, CTSTATE | .FPU ldc1 FRET1, CTSTATE->cb.fpr[0] | lw CRET1, CTSTATE->cb.gpr[0] | .FPU ldc1 FRET2, CTSTATE->cb.fpr[1] | b ->vm_leave_unw |. lw CRET2, CTSTATE->cb.gpr[1] |.endif | |->vm_ffi_call: // Call C function via FFI. | // Caveat: needs special frame unwinding, see below. |.if FFI | .type CCSTATE, CCallState, CARG1 | lw TMP1, CCSTATE->spadj | lbu CARG2, CCSTATE->nsp | move TMP2, sp | subu sp, sp, TMP1 | sw ra, -4(TMP2) | sll CARG2, CARG2, 2 | sw r16, -8(TMP2) | sw CCSTATE, -12(TMP2) | move r16, TMP2 | addiu TMP1, CCSTATE, offsetof(CCallState, stack) | addiu TMP2, sp, 16 | beqz CARG2, >2 |. addu TMP3, TMP1, CARG2 |1: | lw TMP0, 0(TMP1) | addiu TMP1, TMP1, 4 | sltu AT, TMP1, TMP3 | sw TMP0, 0(TMP2) | bnez AT, <1 |. addiu TMP2, TMP2, 4 |2: | lw CFUNCADDR, CCSTATE->func | lw CARG2, CCSTATE->gpr[1] | lw CARG3, CCSTATE->gpr[2] | lw CARG4, CCSTATE->gpr[3] | .FPU ldc1 FARG1, CCSTATE->fpr[0] | .FPU ldc1 FARG2, CCSTATE->fpr[1] | jalr CFUNCADDR |. lw CARG1, CCSTATE->gpr[0] // Do this last, since CCSTATE is CARG1. | lw CCSTATE:TMP1, -12(r16) | lw TMP2, -8(r16) | lw ra, -4(r16) | sw CRET1, CCSTATE:TMP1->gpr[0] | sw CRET2, CCSTATE:TMP1->gpr[1] |.if FPU | sdc1 FRET1, CCSTATE:TMP1->fpr[0] | sdc1 FRET2, CCSTATE:TMP1->fpr[1] |.else | sw CARG1, CCSTATE:TMP1->gpr[2] // Soft-float: complex double .im part. | sw CARG2, CCSTATE:TMP1->gpr[3] |.endif | move sp, r16 | jr ra |. move r16, TMP2 |.endif |// Note: vm_ffi_call must be the last function in this object file! | |//----------------------------------------------------------------------- } /* Generate the code for a single instruction. */ static void build_ins(BuildCtx *ctx, BCOp op, int defop) { int vk = 0; |=>defop: switch (op) { /* -- Comparison ops ---------------------------------------------------- */ /* Remember: all ops branch for a true comparison, fall through otherwise. */ case BC_ISLT: case BC_ISGE: case BC_ISLE: case BC_ISGT: | // RA = src1*8, RD = src2*8, JMP with RD = target |.macro bc_comp, FRA, FRD, RAHI, RALO, RDHI, RDLO, movop, fmovop, fcomp, sfcomp | addu RA, BASE, RA | addu RD, BASE, RD | lw RAHI, HI(RA) | lw RDHI, HI(RD) | lhu TMP2, OFS_RD(PC) | addiu PC, PC, 4 | bne RAHI, TISNUM, >2 |. lw RALO, LO(RA) | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) | lw RDLO, LO(RD) | bne RDHI, TISNUM, >5 |. decode_RD4b TMP2 | slt AT, SFARG1LO, SFARG2LO | addu TMP2, TMP2, TMP3 | movop TMP2, r0, AT |1: | addu PC, PC, TMP2 | ins_next | |2: // RA is not an integer. | sltiu AT, RAHI, LJ_TISNUM | beqz AT, ->vmeta_comp |. lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) | sltiu AT, RDHI, LJ_TISNUM |.if FPU | ldc1 FRA, 0(RA) | ldc1 FRD, 0(RD) |.else | lw RDLO, LO(RD) |.endif | beqz AT, >4 |. decode_RD4b TMP2 |3: // RA and RD are both numbers. |.if FPU | fcomp f20, f22 | addu TMP2, TMP2, TMP3 | b <1 |. fmovop TMP2, r0 |.else | bal sfcomp |. addu TMP2, TMP2, TMP3 | b <1 |. movop TMP2, r0, CRET1 |.endif | |4: // RA is a number, RD is not a number. | bne RDHI, TISNUM, ->vmeta_comp | // RA is a number, RD is an integer. Convert RD to a number. |.if FPU |. lwc1 FRD, LO(RD) | b <3 |. cvt.d.w FRD, FRD |.else |. nop |.if "RDHI" == "SFARG1HI" | bal ->vm_sfi2d_1 |.else | bal ->vm_sfi2d_2 |.endif |. nop | b <3 |. nop |.endif | |5: // RA is an integer, RD is not an integer | sltiu AT, RDHI, LJ_TISNUM | beqz AT, ->vmeta_comp | // RA is an integer, RD is a number. Convert RA to a number. |.if FPU |. mtc1 RALO, FRA | ldc1 FRD, 0(RD) | b <3 | cvt.d.w FRA, FRA |.else |. nop |.if "RAHI" == "SFARG1HI" | bal ->vm_sfi2d_1 |.else | bal ->vm_sfi2d_2 |.endif |. nop | b <3 |. nop |.endif |.endmacro | if (op == BC_ISLT) { | bc_comp f20, f22, SFARG1HI, SFARG1LO, SFARG2HI, SFARG2LO, movz, movf, c.olt.d, ->vm_sfcmpolt } else if (op == BC_ISGE) { | bc_comp f20, f22, SFARG1HI, SFARG1LO, SFARG2HI, SFARG2LO, movn, movt, c.olt.d, ->vm_sfcmpolt } else if (op == BC_ISLE) { | bc_comp f22, f20, SFARG2HI, SFARG2LO, SFARG1HI, SFARG1LO, movn, movt, c.ult.d, ->vm_sfcmpult } else { | bc_comp f22, f20, SFARG2HI, SFARG2LO, SFARG1HI, SFARG1LO, movz, movf, c.ult.d, ->vm_sfcmpult } break; case BC_ISEQV: case BC_ISNEV: vk = op == BC_ISEQV; | // RA = src1*8, RD = src2*8, JMP with RD = target | addu RA, BASE, RA | addiu PC, PC, 4 | addu RD, BASE, RD | lw SFARG1HI, HI(RA) | lhu TMP2, -4+OFS_RD(PC) | lw SFARG2HI, HI(RD) | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) | sltu AT, TISNUM, SFARG1HI | sltu TMP0, TISNUM, SFARG2HI | or AT, AT, TMP0 if (vk) { | beqz AT, ->BC_ISEQN_Z } else { | beqz AT, ->BC_ISNEN_Z } |. decode_RD4b TMP2 | // Either or both types are not numbers. | lw SFARG1LO, LO(RA) | lw SFARG2LO, LO(RD) | addu TMP2, TMP2, TMP3 |.if FFI | li TMP3, LJ_TCDATA | beq SFARG1HI, TMP3, ->vmeta_equal_cd |.endif |. sltiu AT, SFARG1HI, LJ_TISPRI // Not a primitive? |.if FFI | beq SFARG2HI, TMP3, ->vmeta_equal_cd |.endif |. xor TMP3, SFARG1LO, SFARG2LO // Same tv? | xor SFARG2HI, SFARG2HI, SFARG1HI // Same type? | sltiu TMP0, SFARG1HI, LJ_TISTABUD+1 // Table or userdata? | movz TMP3, r0, AT // Ignore tv if primitive. | movn TMP0, r0, SFARG2HI // Tab/ud and same type? | or AT, SFARG2HI, TMP3 // Same type && (pri||same tv). | movz TMP0, r0, AT | beqz TMP0, >1 // Done if not tab/ud or not same type or same tv. if (vk) { |. movn TMP2, r0, AT } else { |. movz TMP2, r0, AT } | // Different tables or userdatas. Need to check __eq metamethod. | // Field metatable must be at same offset for GCtab and GCudata! | lw TAB:TMP1, TAB:SFARG1LO->metatable | beqz TAB:TMP1, >1 // No metatable? |. nop | lbu TMP1, TAB:TMP1->nomm | andi TMP1, TMP1, 1<1 // Or 'no __eq' flag set? |. nop | b ->vmeta_equal // Handle __eq metamethod. |. li TMP0, 1-vk // ne = 0 or 1. |1: | addu PC, PC, TMP2 | ins_next break; case BC_ISEQS: case BC_ISNES: vk = op == BC_ISEQS; | // RA = src*8, RD = str_const*8 (~), JMP with RD = target | addu RA, BASE, RA | addiu PC, PC, 4 | lw TMP0, HI(RA) | srl RD, RD, 1 | lw STR:TMP3, LO(RA) | subu RD, KBASE, RD | lhu TMP2, -4+OFS_RD(PC) |.if FFI | li AT, LJ_TCDATA | beq TMP0, AT, ->vmeta_equal_cd |.endif |. lw STR:TMP1, -4(RD) // KBASE-4-str_const*4 | addiu TMP0, TMP0, -LJ_TSTR | decode_RD4b TMP2 | xor TMP1, STR:TMP1, STR:TMP3 | or TMP0, TMP0, TMP1 | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) | addu TMP2, TMP2, TMP3 if (vk) { | movn TMP2, r0, TMP0 } else { | movz TMP2, r0, TMP0 } | addu PC, PC, TMP2 | ins_next break; case BC_ISEQN: case BC_ISNEN: vk = op == BC_ISEQN; | // RA = src*8, RD = num_const*8, JMP with RD = target | addu RA, BASE, RA | addu RD, KBASE, RD | lw SFARG1HI, HI(RA) | lw SFARG2HI, HI(RD) | lhu TMP2, OFS_RD(PC) | addiu PC, PC, 4 | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) | decode_RD4b TMP2 if (vk) { |->BC_ISEQN_Z: } else { |->BC_ISNEN_Z: } | bne SFARG1HI, TISNUM, >3 |. lw SFARG1LO, LO(RA) | lw SFARG2LO, LO(RD) | addu TMP2, TMP2, TMP3 | bne SFARG2HI, TISNUM, >6 |. xor AT, SFARG1LO, SFARG2LO if (vk) { | movn TMP2, r0, AT |1: | addu PC, PC, TMP2 |2: } else { | movz TMP2, r0, AT |1: |2: | addu PC, PC, TMP2 } | ins_next | |3: // RA is not an integer. | sltiu AT, SFARG1HI, LJ_TISNUM |.if FFI | beqz AT, >8 |.else | beqz AT, <2 |.endif |. addu TMP2, TMP2, TMP3 | sltiu AT, SFARG2HI, LJ_TISNUM |.if FPU | ldc1 f20, 0(RA) | ldc1 f22, 0(RD) |.endif | beqz AT, >5 |. lw SFARG2LO, LO(RD) |4: // RA and RD are both numbers. |.if FPU | c.eq.d f20, f22 | b <1 if (vk) { |. movf TMP2, r0 } else { |. movt TMP2, r0 } |.else | bal ->vm_sfcmpeq |. nop | b <1 if (vk) { |. movz TMP2, r0, CRET1 } else { |. movn TMP2, r0, CRET1 } |.endif | |5: // RA is a number, RD is not a number. |.if FFI | bne SFARG2HI, TISNUM, >9 |.else | bne SFARG2HI, TISNUM, <2 |.endif | // RA is a number, RD is an integer. Convert RD to a number. |.if FPU |. lwc1 f22, LO(RD) | b <4 |. cvt.d.w f22, f22 |.else |. nop | bal ->vm_sfi2d_2 |. nop | b <4 |. nop |.endif | |6: // RA is an integer, RD is not an integer | sltiu AT, SFARG2HI, LJ_TISNUM |.if FFI | beqz AT, >9 |.else | beqz AT, <2 |.endif | // RA is an integer, RD is a number. Convert RA to a number. |.if FPU |. mtc1 SFARG1LO, f20 | ldc1 f22, 0(RD) | b <4 | cvt.d.w f20, f20 |.else |. nop | bal ->vm_sfi2d_1 |. nop | b <4 |. nop |.endif | |.if FFI |8: | li AT, LJ_TCDATA | bne SFARG1HI, AT, <2 |. nop | b ->vmeta_equal_cd |. nop |9: | li AT, LJ_TCDATA | bne SFARG2HI, AT, <2 |. nop | b ->vmeta_equal_cd |. nop |.endif break; case BC_ISEQP: case BC_ISNEP: vk = op == BC_ISEQP; | // RA = src*8, RD = primitive_type*8 (~), JMP with RD = target | addu RA, BASE, RA | srl TMP1, RD, 3 | lw TMP0, HI(RA) | lhu TMP2, OFS_RD(PC) | not TMP1, TMP1 | addiu PC, PC, 4 |.if FFI | li AT, LJ_TCDATA | beq TMP0, AT, ->vmeta_equal_cd |.endif |. xor TMP0, TMP0, TMP1 | decode_RD4b TMP2 | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) | addu TMP2, TMP2, TMP3 if (vk) { | movn TMP2, r0, TMP0 } else { | movz TMP2, r0, TMP0 } | addu PC, PC, TMP2 | ins_next break; /* -- Unary test and copy ops ------------------------------------------- */ case BC_ISTC: case BC_ISFC: case BC_IST: case BC_ISF: | // RA = dst*8 or unused, RD = src*8, JMP with RD = target | addu RD, BASE, RD | lhu TMP2, OFS_RD(PC) | lw TMP0, HI(RD) | addiu PC, PC, 4 if (op == BC_IST || op == BC_ISF) { | sltiu TMP0, TMP0, LJ_TISTRUECOND | decode_RD4b TMP2 | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) | addu TMP2, TMP2, TMP3 if (op == BC_IST) { | movz TMP2, r0, TMP0 } else { | movn TMP2, r0, TMP0 } | addu PC, PC, TMP2 } else { | sltiu TMP0, TMP0, LJ_TISTRUECOND | lw SFRETHI, HI(RD) | lw SFRETLO, LO(RD) if (op == BC_ISTC) { | beqz TMP0, >1 } else { | bnez TMP0, >1 } |. addu RA, BASE, RA | decode_RD4b TMP2 | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) | addu TMP2, TMP2, TMP3 | sw SFRETHI, HI(RA) | sw SFRETLO, LO(RA) | addu PC, PC, TMP2 |1: } | ins_next break; case BC_ISTYPE: | // RA = src*8, RD = -type*8 | addu TMP2, BASE, RA | srl TMP1, RD, 3 | lw TMP0, HI(TMP2) | ins_next1 | addu AT, TMP0, TMP1 | bnez AT, ->vmeta_istype |. ins_next2 break; case BC_ISNUM: | // RA = src*8, RD = -(TISNUM-1)*8 | addu TMP2, BASE, RA | lw TMP0, HI(TMP2) | ins_next1 | sltiu AT, TMP0, LJ_TISNUM | beqz AT, ->vmeta_istype |. ins_next2 break; /* -- Unary ops --------------------------------------------------------- */ case BC_MOV: | // RA = dst*8, RD = src*8 | addu RD, BASE, RD | addu RA, BASE, RA | lw SFRETHI, HI(RD) | lw SFRETLO, LO(RD) | ins_next1 | sw SFRETHI, HI(RA) | sw SFRETLO, LO(RA) | ins_next2 break; case BC_NOT: | // RA = dst*8, RD = src*8 | addu RD, BASE, RD | addu RA, BASE, RA | lw TMP0, HI(RD) | li TMP1, LJ_TFALSE | sltiu TMP0, TMP0, LJ_TISTRUECOND | addiu TMP1, TMP0, LJ_TTRUE | ins_next1 | sw TMP1, HI(RA) | ins_next2 break; case BC_UNM: | // RA = dst*8, RD = src*8 | addu RB, BASE, RD | lw SFARG1HI, HI(RB) | addu RA, BASE, RA | bne SFARG1HI, TISNUM, >2 |. lw SFARG1LO, LO(RB) | lui TMP1, 0x8000 | beq SFARG1LO, TMP1, ->vmeta_unm // Meta handler deals with -2^31. |. negu SFARG1LO, SFARG1LO |1: | ins_next1 | sw SFARG1HI, HI(RA) | sw SFARG1LO, LO(RA) | ins_next2 |2: | sltiu AT, SFARG1HI, LJ_TISNUM | beqz AT, ->vmeta_unm |. lui TMP1, 0x8000 | b <1 |. xor SFARG1HI, SFARG1HI, TMP1 break; case BC_LEN: | // RA = dst*8, RD = src*8 | addu CARG2, BASE, RD | addu RA, BASE, RA | lw TMP0, HI(CARG2) | lw CARG1, LO(CARG2) | li AT, LJ_TSTR | bne TMP0, AT, >2 |. li AT, LJ_TTAB | lw CRET1, STR:CARG1->len |1: | ins_next1 | sw TISNUM, HI(RA) | sw CRET1, LO(RA) | ins_next2 |2: | bne TMP0, AT, ->vmeta_len |. nop #if LJ_52 | lw TAB:TMP2, TAB:CARG1->metatable | bnez TAB:TMP2, >9 |. nop |3: #endif |->BC_LEN_Z: | load_got lj_tab_len | call_intern lj_tab_len // (GCtab *t) |. nop | // Returns uint32_t (but less than 2^31). | b <1 |. nop #if LJ_52 |9: | lbu TMP0, TAB:TMP2->nomm | andi TMP0, TMP0, 1<vmeta_len |. nop #endif break; /* -- Binary ops -------------------------------------------------------- */ |.macro fpmod, a, b, c | bal ->vm_floor // floor(b/c) |. div.d FARG1, b, c | mul.d a, FRET1, c | sub.d a, b, a // b - floor(b/c)*c |.endmacro |.macro sfpmod | addiu sp, sp, -16 | | load_got __divdf3 | sw SFARG1HI, HI(sp) | sw SFARG1LO, LO(sp) | sw SFARG2HI, 8+HI(sp) | call_extern |. sw SFARG2LO, 8+LO(sp) | | load_got floor | move SFARG1HI, SFRETHI | call_extern |. move SFARG1LO, SFRETLO | | load_got __muldf3 | move SFARG1HI, SFRETHI | move SFARG1LO, SFRETLO | lw SFARG2HI, 8+HI(sp) | call_extern |. lw SFARG2LO, 8+LO(sp) | | load_got __subdf3 | lw SFARG1HI, HI(sp) | lw SFARG1LO, LO(sp) | move SFARG2HI, SFRETHI | call_extern |. move SFARG2LO, SFRETLO | | addiu sp, sp, 16 |.endmacro |.macro ins_arithpre, label ||vk = ((int)op - BC_ADDVN) / (BC_ADDNV-BC_ADDVN); | // RA = dst*8, RB = src1*8, RC = src2*8 | num_const*8 ||switch (vk) { ||case 0: | decode_RB8a RB, INS | decode_RB8b RB | decode_RDtoRC8 RC, RD | // RA = dst*8, RB = src1*8, RC = num_const*8 | addu RB, BASE, RB |.if "label" ~= "none" | b label |.endif |. addu RC, KBASE, RC || break; ||case 1: | decode_RB8a RC, INS | decode_RB8b RC | decode_RDtoRC8 RB, RD | // RA = dst*8, RB = num_const*8, RC = src1*8 | addu RC, BASE, RC |.if "label" ~= "none" | b label |.endif |. addu RB, KBASE, RB || break; ||default: | decode_RB8a RB, INS | decode_RB8b RB | decode_RDtoRC8 RC, RD | // RA = dst*8, RB = src1*8, RC = src2*8 | addu RB, BASE, RB |.if "label" ~= "none" | b label |.endif |. addu RC, BASE, RC || break; ||} |.endmacro | |.macro ins_arith, intins, fpins, fpcall, label | ins_arithpre none | |.if "label" ~= "none" |label: |.endif | | lw SFARG1HI, HI(RB) | lw SFARG2HI, HI(RC) | |.if "intins" ~= "div" | | // Check for two integers. | lw SFARG1LO, LO(RB) | bne SFARG1HI, TISNUM, >5 |. lw SFARG2LO, LO(RC) | bne SFARG2HI, TISNUM, >5 | |.if "intins" == "addu" |. intins CRET1, SFARG1LO, SFARG2LO | xor TMP1, CRET1, SFARG1LO // ((y^a) & (y^b)) < 0: overflow. | xor TMP2, CRET1, SFARG2LO | and TMP1, TMP1, TMP2 | bltz TMP1, ->vmeta_arith |. addu RA, BASE, RA |.elif "intins" == "subu" |. intins CRET1, SFARG1LO, SFARG2LO | xor TMP1, CRET1, SFARG1LO // ((y^a) & (a^b)) < 0: overflow. | xor TMP2, SFARG1LO, SFARG2LO | and TMP1, TMP1, TMP2 | bltz TMP1, ->vmeta_arith |. addu RA, BASE, RA |.elif "intins" == "mult" |. intins SFARG1LO, SFARG2LO | mflo CRET1 | mfhi TMP2 | sra TMP1, CRET1, 31 | bne TMP1, TMP2, ->vmeta_arith |. addu RA, BASE, RA |.else |. load_got lj_vm_modi | beqz SFARG2LO, ->vmeta_arith |. addu RA, BASE, RA |.if ENDIAN_BE | move CARG1, SFARG1LO |.endif | call_extern |. move CARG2, SFARG2LO |.endif | | ins_next1 | sw TISNUM, HI(RA) | sw CRET1, LO(RA) |3: | ins_next2 | |.elif not FPU | | lw SFARG1LO, LO(RB) | lw SFARG2LO, LO(RC) | |.endif | |5: // Check for two numbers. | .FPU ldc1 f20, 0(RB) | sltiu AT, SFARG1HI, LJ_TISNUM | sltiu TMP0, SFARG2HI, LJ_TISNUM | .FPU ldc1 f22, 0(RC) | and AT, AT, TMP0 | beqz AT, ->vmeta_arith |. addu RA, BASE, RA | |.if FPU | fpins FRET1, f20, f22 |.elif "fpcall" == "sfpmod" | sfpmod |.else | load_got fpcall | call_extern |. nop |.endif | | ins_next1 |.if not FPU | sw SFRETHI, HI(RA) |.endif |.if "intins" ~= "div" | b <3 |.endif |.if FPU |. sdc1 FRET1, 0(RA) |.else |. sw SFRETLO, LO(RA) |.endif |.if "intins" == "div" | ins_next2 |.endif | |.endmacro case BC_ADDVN: case BC_ADDNV: case BC_ADDVV: | ins_arith addu, add.d, __adddf3, none break; case BC_SUBVN: case BC_SUBNV: case BC_SUBVV: | ins_arith subu, sub.d, __subdf3, none break; case BC_MULVN: case BC_MULNV: case BC_MULVV: | ins_arith mult, mul.d, __muldf3, none break; case BC_DIVVN: | ins_arith div, div.d, __divdf3, ->BC_DIVVN_Z break; case BC_DIVNV: case BC_DIVVV: | ins_arithpre ->BC_DIVVN_Z break; case BC_MODVN: | ins_arith modi, fpmod, sfpmod, ->BC_MODVN_Z break; case BC_MODNV: case BC_MODVV: | ins_arithpre ->BC_MODVN_Z break; case BC_POW: | ins_arithpre none | lw SFARG1HI, HI(RB) | lw SFARG2HI, HI(RC) | sltiu AT, SFARG1HI, LJ_TISNUM | sltiu TMP0, SFARG2HI, LJ_TISNUM | and AT, AT, TMP0 | load_got pow | beqz AT, ->vmeta_arith |. addu RA, BASE, RA |.if FPU | ldc1 FARG1, 0(RB) | ldc1 FARG2, 0(RC) |.else | lw SFARG1LO, LO(RB) | lw SFARG2LO, LO(RC) |.endif | call_extern |. nop | ins_next1 |.if FPU | sdc1 FRET1, 0(RA) |.else | sw SFRETHI, HI(RA) | sw SFRETLO, LO(RA) |.endif | ins_next2 break; case BC_CAT: | // RA = dst*8, RB = src_start*8, RC = src_end*8 | decode_RB8a RB, INS | decode_RB8b RB | decode_RDtoRC8 RC, RD | subu CARG3, RC, RB | sw BASE, L->base | addu CARG2, BASE, RC | move MULTRES, RB |->BC_CAT_Z: | load_got lj_meta_cat | srl CARG3, CARG3, 3 | sw PC, SAVE_PC | call_intern lj_meta_cat // (lua_State *L, TValue *top, int left) |. move CARG1, L | // Returns NULL (finished) or TValue * (metamethod). | bnez CRET1, ->vmeta_binop |. lw BASE, L->base | addu RB, BASE, MULTRES | lw SFRETHI, HI(RB) | lw SFRETLO, LO(RB) | addu RA, BASE, RA | ins_next1 | sw SFRETHI, HI(RA) | sw SFRETLO, LO(RA) | ins_next2 break; /* -- Constant ops ------------------------------------------------------ */ case BC_KSTR: | // RA = dst*8, RD = str_const*8 (~) | srl TMP1, RD, 1 | subu TMP1, KBASE, TMP1 | ins_next1 | lw TMP0, -4(TMP1) // KBASE-4-str_const*4 | addu RA, BASE, RA | li TMP2, LJ_TSTR | sw TMP0, LO(RA) | sw TMP2, HI(RA) | ins_next2 break; case BC_KCDATA: |.if FFI | // RA = dst*8, RD = cdata_const*8 (~) | srl TMP1, RD, 1 | subu TMP1, KBASE, TMP1 | ins_next1 | lw TMP0, -4(TMP1) // KBASE-4-cdata_const*4 | addu RA, BASE, RA | li TMP2, LJ_TCDATA | sw TMP0, LO(RA) | sw TMP2, HI(RA) | ins_next2 |.endif break; case BC_KSHORT: | // RA = dst*8, RD = int16_literal*8 | sra RD, INS, 16 | addu RA, BASE, RA | ins_next1 | sw TISNUM, HI(RA) | sw RD, LO(RA) | ins_next2 break; case BC_KNUM: | // RA = dst*8, RD = num_const*8 | addu RD, KBASE, RD | addu RA, BASE, RA | lw SFRETHI, HI(RD) | lw SFRETLO, LO(RD) | ins_next1 | sw SFRETHI, HI(RA) | sw SFRETLO, LO(RA) | ins_next2 break; case BC_KPRI: | // RA = dst*8, RD = primitive_type*8 (~) | srl TMP1, RD, 3 | addu RA, BASE, RA | not TMP0, TMP1 | ins_next1 | sw TMP0, HI(RA) | ins_next2 break; case BC_KNIL: | // RA = base*8, RD = end*8 | addu RA, BASE, RA | sw TISNIL, HI(RA) | addiu RA, RA, 8 | addu RD, BASE, RD |1: | sw TISNIL, HI(RA) | slt AT, RA, RD | bnez AT, <1 |. addiu RA, RA, 8 | ins_next_ break; /* -- Upvalue and function ops ------------------------------------------ */ case BC_UGET: | // RA = dst*8, RD = uvnum*8 | lw LFUNC:RB, FRAME_FUNC(BASE) | srl RD, RD, 1 | addu RD, RD, LFUNC:RB | lw UPVAL:RB, LFUNC:RD->uvptr | ins_next1 | lw TMP1, UPVAL:RB->v | lw SFRETHI, HI(TMP1) | lw SFRETLO, LO(TMP1) | addu RA, BASE, RA | sw SFRETHI, HI(RA) | sw SFRETLO, LO(RA) | ins_next2 break; case BC_USETV: | // RA = uvnum*8, RD = src*8 | lw LFUNC:RB, FRAME_FUNC(BASE) | srl RA, RA, 1 | addu RD, BASE, RD | addu RA, RA, LFUNC:RB | lw UPVAL:RB, LFUNC:RA->uvptr | lw SFRETHI, HI(RD) | lw SFRETLO, LO(RD) | lbu TMP3, UPVAL:RB->marked | lw CARG2, UPVAL:RB->v | andi TMP3, TMP3, LJ_GC_BLACK // isblack(uv) | lbu TMP0, UPVAL:RB->closed | sw SFRETHI, HI(CARG2) | sw SFRETLO, LO(CARG2) | li AT, LJ_GC_BLACK|1 | or TMP3, TMP3, TMP0 | beq TMP3, AT, >2 // Upvalue is closed and black? |. addiu TMP2, SFRETHI, -(LJ_TNUMX+1) |1: | ins_next | |2: // Check if new value is collectable. | sltiu AT, TMP2, LJ_TISGCV - (LJ_TNUMX+1) | beqz AT, <1 // tvisgcv(v) |. nop | lbu TMP3, GCOBJ:SFRETLO->gch.marked | andi TMP3, TMP3, LJ_GC_WHITES // iswhite(v) | beqz TMP3, <1 |. load_got lj_gc_barrieruv | // Crossed a write barrier. Move the barrier forward. | call_intern lj_gc_barrieruv // (global_State *g, TValue *tv) |. addiu CARG1, DISPATCH, GG_DISP2G | b <1 |. nop break; case BC_USETS: | // RA = uvnum*8, RD = str_const*8 (~) | lw LFUNC:RB, FRAME_FUNC(BASE) | srl RA, RA, 1 | srl TMP1, RD, 1 | addu RA, RA, LFUNC:RB | subu TMP1, KBASE, TMP1 | lw UPVAL:RB, LFUNC:RA->uvptr | lw STR:TMP1, -4(TMP1) // KBASE-4-str_const*4 | lbu TMP2, UPVAL:RB->marked | lw CARG2, UPVAL:RB->v | lbu TMP3, STR:TMP1->marked | andi AT, TMP2, LJ_GC_BLACK // isblack(uv) | lbu TMP2, UPVAL:RB->closed | li TMP0, LJ_TSTR | sw STR:TMP1, LO(CARG2) | bnez AT, >2 |. sw TMP0, HI(CARG2) |1: | ins_next | |2: // Check if string is white and ensure upvalue is closed. | beqz TMP2, <1 |. andi AT, TMP3, LJ_GC_WHITES // iswhite(str) | beqz AT, <1 |. load_got lj_gc_barrieruv | // Crossed a write barrier. Move the barrier forward. | call_intern lj_gc_barrieruv // (global_State *g, TValue *tv) |. addiu CARG1, DISPATCH, GG_DISP2G | b <1 |. nop break; case BC_USETN: | // RA = uvnum*8, RD = num_const*8 | lw LFUNC:RB, FRAME_FUNC(BASE) | srl RA, RA, 1 | addu RD, KBASE, RD | addu RA, RA, LFUNC:RB | lw UPVAL:RB, LFUNC:RA->uvptr | lw SFRETHI, HI(RD) | lw SFRETLO, LO(RD) | lw TMP1, UPVAL:RB->v | ins_next1 | sw SFRETHI, HI(TMP1) | sw SFRETLO, LO(TMP1) | ins_next2 break; case BC_USETP: | // RA = uvnum*8, RD = primitive_type*8 (~) | lw LFUNC:RB, FRAME_FUNC(BASE) | srl RA, RA, 1 | srl TMP0, RD, 3 | addu RA, RA, LFUNC:RB | not TMP0, TMP0 | lw UPVAL:RB, LFUNC:RA->uvptr | ins_next1 | lw TMP1, UPVAL:RB->v | sw TMP0, HI(TMP1) | ins_next2 break; case BC_UCLO: | // RA = level*8, RD = target | lw TMP2, L->openupval | branch_RD // Do this first since RD is not saved. | load_got lj_func_closeuv | sw BASE, L->base | beqz TMP2, >1 |. move CARG1, L | call_intern lj_func_closeuv // (lua_State *L, TValue *level) |. addu CARG2, BASE, RA | lw BASE, L->base |1: | ins_next break; case BC_FNEW: | // RA = dst*8, RD = proto_const*8 (~) (holding function prototype) | srl TMP1, RD, 1 | load_got lj_func_newL_gc | subu TMP1, KBASE, TMP1 | lw CARG3, FRAME_FUNC(BASE) | lw CARG2, -4(TMP1) // KBASE-4-tab_const*4 | sw BASE, L->base | sw PC, SAVE_PC | // (lua_State *L, GCproto *pt, GCfuncL *parent) | call_intern lj_func_newL_gc |. move CARG1, L | // Returns GCfuncL *. | lw BASE, L->base | li TMP0, LJ_TFUNC | ins_next1 | addu RA, BASE, RA | sw LFUNC:CRET1, LO(RA) | sw TMP0, HI(RA) | ins_next2 break; /* -- Table ops --------------------------------------------------------- */ case BC_TNEW: case BC_TDUP: | // RA = dst*8, RD = (hbits|asize)*8 | tab_const*8 (~) | lw TMP0, DISPATCH_GL(gc.total)(DISPATCH) | lw TMP1, DISPATCH_GL(gc.threshold)(DISPATCH) | sw BASE, L->base | sw PC, SAVE_PC | sltu AT, TMP0, TMP1 | beqz AT, >5 |1: if (op == BC_TNEW) { | load_got lj_tab_new | srl CARG2, RD, 3 | andi CARG2, CARG2, 0x7ff | li TMP0, 0x801 | addiu AT, CARG2, -0x7ff | srl CARG3, RD, 14 | movz CARG2, TMP0, AT | // (lua_State *L, int32_t asize, uint32_t hbits) | call_intern lj_tab_new |. move CARG1, L | // Returns Table *. } else { | load_got lj_tab_dup | srl TMP1, RD, 1 | subu TMP1, KBASE, TMP1 | move CARG1, L | call_intern lj_tab_dup // (lua_State *L, Table *kt) |. lw CARG2, -4(TMP1) // KBASE-4-str_const*4 | // Returns Table *. } | lw BASE, L->base | ins_next1 | addu RA, BASE, RA | li TMP0, LJ_TTAB | sw TAB:CRET1, LO(RA) | sw TMP0, HI(RA) | ins_next2 |5: | load_got lj_gc_step_fixtop | move MULTRES, RD | call_intern lj_gc_step_fixtop // (lua_State *L) |. move CARG1, L | b <1 |. move RD, MULTRES break; case BC_GGET: | // RA = dst*8, RD = str_const*8 (~) case BC_GSET: | // RA = src*8, RD = str_const*8 (~) | lw LFUNC:TMP2, FRAME_FUNC(BASE) | srl TMP1, RD, 1 | subu TMP1, KBASE, TMP1 | lw TAB:RB, LFUNC:TMP2->env | lw STR:RC, -4(TMP1) // KBASE-4-str_const*4 if (op == BC_GGET) { | b ->BC_TGETS_Z } else { | b ->BC_TSETS_Z } |. addu RA, BASE, RA break; case BC_TGETV: | // RA = dst*8, RB = table*8, RC = key*8 | decode_RB8a RB, INS | decode_RB8b RB | decode_RDtoRC8 RC, RD | addu CARG2, BASE, RB | addu CARG3, BASE, RC | lw TMP1, HI(CARG2) | lw TMP2, HI(CARG3) | lw TAB:RB, LO(CARG2) | li AT, LJ_TTAB | bne TMP1, AT, ->vmeta_tgetv |. addu RA, BASE, RA | bne TMP2, TISNUM, >5 |. lw RC, LO(CARG3) | lw TMP0, TAB:RB->asize | lw TMP1, TAB:RB->array | sltu AT, RC, TMP0 | sll TMP2, RC, 3 | beqz AT, ->vmeta_tgetv // Integer key and in array part? |. addu TMP2, TMP1, TMP2 | lw SFRETHI, HI(TMP2) | beq SFRETHI, TISNIL, >2 |. lw SFRETLO, LO(TMP2) |1: | ins_next1 | sw SFRETHI, HI(RA) | sw SFRETLO, LO(RA) | ins_next2 | |2: // Check for __index if table value is nil. | lw TAB:TMP2, TAB:RB->metatable | beqz TAB:TMP2, <1 // No metatable: done. |. nop | lbu TMP0, TAB:TMP2->nomm | andi TMP0, TMP0, 1<vmeta_tgetv |. nop | |5: | li AT, LJ_TSTR | bne TMP2, AT, ->vmeta_tgetv |. nop | b ->BC_TGETS_Z // String key? |. nop break; case BC_TGETS: | // RA = dst*8, RB = table*8, RC = str_const*4 (~) | decode_RB8a RB, INS | decode_RB8b RB | addu CARG2, BASE, RB | decode_RC4a RC, INS | lw TMP0, HI(CARG2) | decode_RC4b RC | li AT, LJ_TTAB | lw TAB:RB, LO(CARG2) | subu CARG3, KBASE, RC | lw STR:RC, -4(CARG3) // KBASE-4-str_const*4 | bne TMP0, AT, ->vmeta_tgets1 |. addu RA, BASE, RA |->BC_TGETS_Z: | // TAB:RB = GCtab *, STR:RC = GCstr *, RA = dst*8 | lw TMP0, TAB:RB->hmask | lw TMP1, STR:RC->sid | lw NODE:TMP2, TAB:RB->node | and TMP1, TMP1, TMP0 // idx = str->sid & tab->hmask | sll TMP0, TMP1, 5 | sll TMP1, TMP1, 3 | subu TMP1, TMP0, TMP1 | addu NODE:TMP2, NODE:TMP2, TMP1 // node = tab->node + (idx*32-idx*8) |1: | lw CARG1, offsetof(Node, key)+HI(NODE:TMP2) | lw TMP0, offsetof(Node, key)+LO(NODE:TMP2) | lw NODE:TMP1, NODE:TMP2->next | lw SFRETHI, offsetof(Node, val)+HI(NODE:TMP2) | addiu CARG1, CARG1, -LJ_TSTR | xor TMP0, TMP0, STR:RC | or AT, CARG1, TMP0 | bnez AT, >4 |. lw TAB:TMP3, TAB:RB->metatable | beq SFRETHI, TISNIL, >5 // Key found, but nil value? |. lw SFRETLO, offsetof(Node, val)+LO(NODE:TMP2) |3: | ins_next1 | sw SFRETHI, HI(RA) | sw SFRETLO, LO(RA) | ins_next2 | |4: // Follow hash chain. | bnez NODE:TMP1, <1 |. move NODE:TMP2, NODE:TMP1 | // End of hash chain: key not found, nil result. | |5: // Check for __index if table value is nil. | beqz TAB:TMP3, <3 // No metatable: done. |. li SFRETHI, LJ_TNIL | lbu TMP0, TAB:TMP3->nomm | andi TMP0, TMP0, 1<vmeta_tgets |. nop break; case BC_TGETB: | // RA = dst*8, RB = table*8, RC = index*8 | decode_RB8a RB, INS | decode_RB8b RB | addu CARG2, BASE, RB | decode_RDtoRC8 RC, RD | lw CARG1, HI(CARG2) | li AT, LJ_TTAB | lw TAB:RB, LO(CARG2) | addu RA, BASE, RA | bne CARG1, AT, ->vmeta_tgetb |. srl TMP0, RC, 3 | lw TMP1, TAB:RB->asize | lw TMP2, TAB:RB->array | sltu AT, TMP0, TMP1 | beqz AT, ->vmeta_tgetb |. addu RC, TMP2, RC | lw SFRETHI, HI(RC) | beq SFRETHI, TISNIL, >5 |. lw SFRETLO, LO(RC) |1: | ins_next1 | sw SFRETHI, HI(RA) | sw SFRETLO, LO(RA) | ins_next2 | |5: // Check for __index if table value is nil. | lw TAB:TMP2, TAB:RB->metatable | beqz TAB:TMP2, <1 // No metatable: done. |. nop | lbu TMP1, TAB:TMP2->nomm | andi TMP1, TMP1, 1<vmeta_tgetb // Caveat: preserve TMP0 and CARG2! |. nop break; case BC_TGETR: | // RA = dst*8, RB = table*8, RC = key*8 | decode_RB8a RB, INS | decode_RB8b RB | decode_RDtoRC8 RC, RD | addu RB, BASE, RB | addu RC, BASE, RC | lw TAB:CARG1, LO(RB) | lw CARG2, LO(RC) | addu RA, BASE, RA | lw TMP0, TAB:CARG1->asize | lw TMP1, TAB:CARG1->array | sltu AT, CARG2, TMP0 | sll TMP2, CARG2, 3 | beqz AT, ->vmeta_tgetr // In array part? |. addu CRET1, TMP1, TMP2 | lw SFARG2HI, HI(CRET1) | lw SFARG2LO, LO(CRET1) |->BC_TGETR_Z: | ins_next1 | sw SFARG2HI, HI(RA) | sw SFARG2LO, LO(RA) | ins_next2 break; case BC_TSETV: | // RA = src*8, RB = table*8, RC = key*8 | decode_RB8a RB, INS | decode_RB8b RB | decode_RDtoRC8 RC, RD | addu CARG2, BASE, RB | addu CARG3, BASE, RC | lw TMP1, HI(CARG2) | lw TMP2, HI(CARG3) | lw TAB:RB, LO(CARG2) | li AT, LJ_TTAB | bne TMP1, AT, ->vmeta_tsetv |. addu RA, BASE, RA | bne TMP2, TISNUM, >5 |. lw RC, LO(CARG3) | lw TMP0, TAB:RB->asize | lw TMP1, TAB:RB->array | sltu AT, RC, TMP0 | sll TMP2, RC, 3 | beqz AT, ->vmeta_tsetv // Integer key and in array part? |. addu TMP1, TMP1, TMP2 | lw TMP0, HI(TMP1) | lbu TMP3, TAB:RB->marked | lw SFRETHI, HI(RA) | beq TMP0, TISNIL, >3 |. lw SFRETLO, LO(RA) |1: | andi AT, TMP3, LJ_GC_BLACK // isblack(table) | sw SFRETHI, HI(TMP1) | bnez AT, >7 |. sw SFRETLO, LO(TMP1) |2: | ins_next | |3: // Check for __newindex if previous value is nil. | lw TAB:TMP2, TAB:RB->metatable | beqz TAB:TMP2, <1 // No metatable: done. |. nop | lbu TMP2, TAB:TMP2->nomm | andi TMP2, TMP2, 1<vmeta_tsetv |. nop | |5: | li AT, LJ_TSTR | bne TMP2, AT, ->vmeta_tsetv |. nop | b ->BC_TSETS_Z // String key? |. nop | |7: // Possible table write barrier for the value. Skip valiswhite check. | barrierback TAB:RB, TMP3, TMP0, <2 break; case BC_TSETS: | // RA = src*8, RB = table*8, RC = str_const*8 (~) | decode_RB8a RB, INS | decode_RB8b RB | addu CARG2, BASE, RB | decode_RC4a RC, INS | lw TMP0, HI(CARG2) | decode_RC4b RC | li AT, LJ_TTAB | subu CARG3, KBASE, RC | lw TAB:RB, LO(CARG2) | lw STR:RC, -4(CARG3) // KBASE-4-str_const*4 | bne TMP0, AT, ->vmeta_tsets1 |. addu RA, BASE, RA |->BC_TSETS_Z: | // TAB:RB = GCtab *, STR:RC = GCstr *, RA = BASE+src*8 | lw TMP0, TAB:RB->hmask | lw TMP1, STR:RC->sid | lw NODE:TMP2, TAB:RB->node | sb r0, TAB:RB->nomm // Clear metamethod cache. | and TMP1, TMP1, TMP0 // idx = str->sid & tab->hmask | sll TMP0, TMP1, 5 | sll TMP1, TMP1, 3 | subu TMP1, TMP0, TMP1 | addu NODE:TMP2, NODE:TMP2, TMP1 // node = tab->node + (idx*32-idx*8) |.if FPU | ldc1 f20, 0(RA) |.else | lw SFRETHI, HI(RA) | lw SFRETLO, LO(RA) |.endif |1: | lw CARG1, offsetof(Node, key)+HI(NODE:TMP2) | lw TMP0, offsetof(Node, key)+LO(NODE:TMP2) | li AT, LJ_TSTR | lw NODE:TMP1, NODE:TMP2->next | bne CARG1, AT, >5 |. lw CARG2, offsetof(Node, val)+HI(NODE:TMP2) | bne TMP0, STR:RC, >5 |. lbu TMP3, TAB:RB->marked | beq CARG2, TISNIL, >4 // Key found, but nil value? |. lw TAB:TMP0, TAB:RB->metatable |2: | andi AT, TMP3, LJ_GC_BLACK // isblack(table) |.if FPU | bnez AT, >7 |. sdc1 f20, NODE:TMP2->val |.else | sw SFRETHI, NODE:TMP2->val.u32.hi | bnez AT, >7 |. sw SFRETLO, NODE:TMP2->val.u32.lo |.endif |3: | ins_next | |4: // Check for __newindex if previous value is nil. | beqz TAB:TMP0, <2 // No metatable: done. |. nop | lbu TMP0, TAB:TMP0->nomm | andi TMP0, TMP0, 1<vmeta_tsets |. nop | |5: // Follow hash chain. | bnez NODE:TMP1, <1 |. move NODE:TMP2, NODE:TMP1 | // End of hash chain: key not found, add a new one | | // But check for __newindex first. | lw TAB:TMP2, TAB:RB->metatable | beqz TAB:TMP2, >6 // No metatable: continue. |. addiu CARG3, DISPATCH, DISPATCH_GL(tmptv) | lbu TMP0, TAB:TMP2->nomm | andi TMP0, TMP0, 1<vmeta_tsets // 'no __newindex' flag NOT set: check. |. li AT, LJ_TSTR |6: | load_got lj_tab_newkey | sw STR:RC, LO(CARG3) | sw AT, HI(CARG3) | sw BASE, L->base | move CARG2, TAB:RB | sw PC, SAVE_PC | call_intern lj_tab_newkey // (lua_State *L, GCtab *t, TValue *k |. move CARG1, L | // Returns TValue *. | lw BASE, L->base |.if FPU | b <3 // No 2nd write barrier needed. |. sdc1 f20, 0(CRET1) |.else | lw SFARG1HI, HI(RA) | lw SFARG1LO, LO(RA) | sw SFARG1HI, HI(CRET1) | b <3 // No 2nd write barrier needed. |. sw SFARG1LO, LO(CRET1) |.endif | |7: // Possible table write barrier for the value. Skip valiswhite check. | barrierback TAB:RB, TMP3, TMP0, <3 break; case BC_TSETB: | // RA = src*8, RB = table*8, RC = index*8 | decode_RB8a RB, INS | decode_RB8b RB | addu CARG2, BASE, RB | decode_RDtoRC8 RC, RD | lw CARG1, HI(CARG2) | li AT, LJ_TTAB | lw TAB:RB, LO(CARG2) | addu RA, BASE, RA | bne CARG1, AT, ->vmeta_tsetb |. srl TMP0, RC, 3 | lw TMP1, TAB:RB->asize | lw TMP2, TAB:RB->array | sltu AT, TMP0, TMP1 | beqz AT, ->vmeta_tsetb |. addu RC, TMP2, RC | lw TMP1, HI(RC) | lbu TMP3, TAB:RB->marked | beq TMP1, TISNIL, >5 |1: |. lw SFRETHI, HI(RA) | lw SFRETLO, LO(RA) | andi AT, TMP3, LJ_GC_BLACK // isblack(table) | sw SFRETHI, HI(RC) | bnez AT, >7 |. sw SFRETLO, LO(RC) |2: | ins_next | |5: // Check for __newindex if previous value is nil. | lw TAB:TMP2, TAB:RB->metatable | beqz TAB:TMP2, <1 // No metatable: done. |. nop | lbu TMP1, TAB:TMP2->nomm | andi TMP1, TMP1, 1<vmeta_tsetb // Caveat: preserve TMP0 and CARG2! |. nop | |7: // Possible table write barrier for the value. Skip valiswhite check. | barrierback TAB:RB, TMP3, TMP0, <2 break; case BC_TSETR: | // RA = dst*8, RB = table*8, RC = key*8 | decode_RB8a RB, INS | decode_RB8b RB | decode_RDtoRC8 RC, RD | addu CARG1, BASE, RB | addu CARG3, BASE, RC | lw TAB:CARG2, LO(CARG1) | lw CARG3, LO(CARG3) | lbu TMP3, TAB:CARG2->marked | lw TMP0, TAB:CARG2->asize | lw TMP1, TAB:CARG2->array | andi AT, TMP3, LJ_GC_BLACK // isblack(table) | bnez AT, >7 |. addu RA, BASE, RA |2: | sltu AT, CARG3, TMP0 | sll TMP2, CARG3, 3 | beqz AT, ->vmeta_tsetr // In array part? |. addu CRET1, TMP1, TMP2 |->BC_TSETR_Z: | lw SFARG1HI, HI(RA) | lw SFARG1LO, LO(RA) | ins_next1 | sw SFARG1HI, HI(CRET1) | sw SFARG1LO, LO(CRET1) | ins_next2 | |7: // Possible table write barrier for the value. Skip valiswhite check. | barrierback TAB:CARG2, TMP3, CRET1, <2 break; case BC_TSETM: | // RA = base*8 (table at base-1), RD = num_const*8 (start index) | addu RA, BASE, RA |1: | addu TMP3, KBASE, RD | lw TAB:CARG2, -8+LO(RA) // Guaranteed to be a table. | addiu TMP0, MULTRES, -8 | lw TMP3, LO(TMP3) // Integer constant is in lo-word. | beqz TMP0, >4 // Nothing to copy? |. srl CARG3, TMP0, 3 | addu CARG3, CARG3, TMP3 | lw TMP2, TAB:CARG2->asize | sll TMP1, TMP3, 3 | lbu TMP3, TAB:CARG2->marked | lw CARG1, TAB:CARG2->array | sltu AT, TMP2, CARG3 | bnez AT, >5 |. addu TMP2, RA, TMP0 | addu TMP1, TMP1, CARG1 | andi TMP0, TMP3, LJ_GC_BLACK // isblack(table) |3: // Copy result slots to table. | lw SFRETHI, HI(RA) | lw SFRETLO, LO(RA) | addiu RA, RA, 8 | sltu AT, RA, TMP2 | sw SFRETHI, HI(TMP1) | sw SFRETLO, LO(TMP1) | bnez AT, <3 |. addiu TMP1, TMP1, 8 | bnez TMP0, >7 |. nop |4: | ins_next | |5: // Need to resize array part. | load_got lj_tab_reasize | sw BASE, L->base | sw PC, SAVE_PC | move BASE, RD | call_intern lj_tab_reasize // (lua_State *L, GCtab *t, int nasize) |. move CARG1, L | // Must not reallocate the stack. | move RD, BASE | b <1 |. lw BASE, L->base // Reload BASE for lack of a saved register. | |7: // Possible table write barrier for any value. Skip valiswhite check. | barrierback TAB:CARG2, TMP3, TMP0, <4 break; /* -- Calls and vararg handling ----------------------------------------- */ case BC_CALLM: | // RA = base*8, (RB = (nresults+1)*8,) RC = extra_nargs*8 | decode_RDtoRC8 NARGS8:RC, RD | b ->BC_CALL_Z |. addu NARGS8:RC, NARGS8:RC, MULTRES break; case BC_CALL: | // RA = base*8, (RB = (nresults+1)*8,) RC = (nargs+1)*8 | decode_RDtoRC8 NARGS8:RC, RD |->BC_CALL_Z: | move TMP2, BASE | addu BASE, BASE, RA | li AT, LJ_TFUNC | lw TMP0, HI(BASE) | lw LFUNC:RB, LO(BASE) | addiu BASE, BASE, 8 | bne TMP0, AT, ->vmeta_call |. addiu NARGS8:RC, NARGS8:RC, -8 | ins_call break; case BC_CALLMT: | // RA = base*8, (RB = 0,) RC = extra_nargs*8 | addu NARGS8:RD, NARGS8:RD, MULTRES // BC_CALLT gets RC from RD. | // Fall through. Assumes BC_CALLT follows. break; case BC_CALLT: | // RA = base*8, (RB = 0,) RC = (nargs+1)*8 | addu RA, BASE, RA | li AT, LJ_TFUNC | lw TMP0, HI(RA) | lw LFUNC:RB, LO(RA) | move NARGS8:RC, RD | lw TMP1, FRAME_PC(BASE) | addiu RA, RA, 8 | bne TMP0, AT, ->vmeta_callt |. addiu NARGS8:RC, NARGS8:RC, -8 |->BC_CALLT_Z: | andi TMP0, TMP1, FRAME_TYPE // Caveat: preserve TMP0 until the 'or'. | lbu TMP3, LFUNC:RB->ffid | bnez TMP0, >7 |. xori TMP2, TMP1, FRAME_VARG |1: | sw LFUNC:RB, FRAME_FUNC(BASE) // Copy function down, but keep PC. | sltiu AT, TMP3, 2 // (> FF_C) Calling a fast function? | move TMP2, BASE | beqz NARGS8:RC, >3 |. move TMP3, NARGS8:RC |2: | lw SFRETHI, HI(RA) | lw SFRETLO, LO(RA) | addiu RA, RA, 8 | addiu TMP3, TMP3, -8 | sw SFRETHI, HI(TMP2) | sw SFRETLO, LO(TMP2) | bnez TMP3, <2 |. addiu TMP2, TMP2, 8 |3: | or TMP0, TMP0, AT | beqz TMP0, >5 |. nop |4: | ins_callt | |5: // Tailcall to a fast function with a Lua frame below. | lw INS, -4(TMP1) | decode_RA8a RA, INS | decode_RA8b RA | subu TMP1, BASE, RA | lw LFUNC:TMP1, -8+FRAME_FUNC(TMP1) | lw TMP1, LFUNC:TMP1->pc | b <4 |. lw KBASE, PC2PROTO(k)(TMP1) // Need to prepare KBASE. | |7: // Tailcall from a vararg function. | andi AT, TMP2, FRAME_TYPEP | bnez AT, <1 // Vararg frame below? |. subu TMP2, BASE, TMP2 // Relocate BASE down. | move BASE, TMP2 | lw TMP1, FRAME_PC(TMP2) | b <1 |. andi TMP0, TMP1, FRAME_TYPE break; case BC_ITERC: | // RA = base*8, (RB = (nresults+1)*8, RC = (nargs+1)*8 ((2+1)*8)) | move TMP2, BASE | addu BASE, BASE, RA | li AT, LJ_TFUNC | lw TMP1, -24+HI(BASE) | lw LFUNC:RB, -24+LO(BASE) | lw SFARG1HI, -16+HI(BASE) | lw SFARG1LO, -16+LO(BASE) | lw SFARG2HI, -8+HI(BASE) | lw SFARG2LO, -8+LO(BASE) | sw TMP1, HI(BASE) // Copy callable. | sw LFUNC:RB, LO(BASE) | sw SFARG1HI, 8+HI(BASE) // Copy state. | sw SFARG1LO, 8+LO(BASE) | sw SFARG2HI, 16+HI(BASE) // Copy control var. | sw SFARG2LO, 16+LO(BASE) | addiu BASE, BASE, 8 | bne TMP1, AT, ->vmeta_call |. li NARGS8:RC, 16 // Iterators get 2 arguments. | ins_call break; case BC_ITERN: |.if JIT and ENDIAN_LE | hotloop |.endif |->vm_IITERN: | // RA = base*8, (RB = (nresults+1)*8, RC = (nargs+1)*8 (2+1)*8) | addu RA, BASE, RA | lw TAB:RB, -16+LO(RA) | lw RC, -8+LO(RA) // Get index from control var. | lw TMP0, TAB:RB->asize | lw TMP1, TAB:RB->array | addiu PC, PC, 4 |1: // Traverse array part. | sltu AT, RC, TMP0 | beqz AT, >5 // Index points after array part? |. sll TMP3, RC, 3 | addu TMP3, TMP1, TMP3 | lw SFARG1HI, HI(TMP3) | lw SFARG1LO, LO(TMP3) | lhu RD, -4+OFS_RD(PC) | sw TISNUM, HI(RA) | sw RC, LO(RA) | beq SFARG1HI, TISNIL, <1 // Skip holes in array part. |. addiu RC, RC, 1 | sw SFARG1HI, 8+HI(RA) | sw SFARG1LO, 8+LO(RA) | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) | decode_RD4b RD | addu RD, RD, TMP3 | sw RC, -8+LO(RA) // Update control var. | addu PC, PC, RD |3: | ins_next | |5: // Traverse hash part. | lw TMP1, TAB:RB->hmask | subu RC, RC, TMP0 | lw TMP2, TAB:RB->node |6: | sltu AT, TMP1, RC // End of iteration? Branch to ITERL+1. | bnez AT, <3 |. sll TMP3, RC, 5 | sll RB, RC, 3 | subu TMP3, TMP3, RB | addu NODE:TMP3, TMP3, TMP2 | lw SFARG1HI, NODE:TMP3->val.u32.hi | lw SFARG1LO, NODE:TMP3->val.u32.lo | lhu RD, -4+OFS_RD(PC) | beq SFARG1HI, TISNIL, <6 // Skip holes in hash part. |. addiu RC, RC, 1 | lw SFARG2HI, NODE:TMP3->key.u32.hi | lw SFARG2LO, NODE:TMP3->key.u32.lo | lui TMP3, (-(BCBIAS_J*4 >> 16) & 65535) | sw SFARG1HI, 8+HI(RA) | sw SFARG1LO, 8+LO(RA) | addu RC, RC, TMP0 | decode_RD4b RD | addu RD, RD, TMP3 | sw SFARG2HI, HI(RA) | sw SFARG2LO, LO(RA) | addu PC, PC, RD | b <3 |. sw RC, -8+LO(RA) // Update control var. break; case BC_ISNEXT: | // RA = base*8, RD = target (points to ITERN) | addu RA, BASE, RA | srl TMP0, RD, 1 | lw CARG1, -24+HI(RA) | lw CFUNC:CARG2, -24+LO(RA) | addu TMP0, PC, TMP0 | lw CARG3, -16+HI(RA) | lw CARG4, -8+HI(RA) | li AT, LJ_TFUNC | bne CARG1, AT, >5 |. lui TMP2, (-(BCBIAS_J*4 >> 16) & 65535) | lbu CARG2, CFUNC:CARG2->ffid | addiu CARG3, CARG3, -LJ_TTAB | addiu CARG4, CARG4, -LJ_TNIL | or CARG3, CARG3, CARG4 | addiu CARG2, CARG2, -FF_next_N | or CARG2, CARG2, CARG3 | bnez CARG2, >5 |. lui TMP1, (LJ_KEYINDEX >> 16) | addu PC, TMP0, TMP2 | ori TMP1, TMP1, (LJ_KEYINDEX & 0xffff) | sw r0, -8+LO(RA) // Initialize control var. | sw TMP1, -8+HI(RA) |1: | ins_next |5: // Despecialize bytecode if any of the checks fail. | li TMP3, BC_JMP | li TMP1, BC_ITERC | sb TMP3, -4+OFS_OP(PC) | addu PC, TMP0, TMP2 |.if JIT | lb TMP0, OFS_OP(PC) | li AT, BC_ITERN | bne TMP0, AT, >6 |. lhu TMP2, OFS_RD(PC) |.endif | b <1 |. sb TMP1, OFS_OP(PC) |.if JIT |6: // Unpatch JLOOP. | lw TMP0, DISPATCH_J(trace)(DISPATCH) | sll TMP2, TMP2, 2 | addu TMP0, TMP0, TMP2 | lw TRACE:TMP2, 0(TMP0) | lw TMP0, TRACE:TMP2->startins | li AT, -256 | and TMP0, TMP0, AT | or TMP0, TMP0, TMP1 | b <1 |. sw TMP0, 0(PC) |.endif break; case BC_VARG: | // RA = base*8, RB = (nresults+1)*8, RC = numparams*8 | lw TMP0, FRAME_PC(BASE) | decode_RDtoRC8 RC, RD | decode_RB8a RB, INS | addu RC, BASE, RC | decode_RB8b RB | addu RA, BASE, RA | addiu RC, RC, FRAME_VARG | addu TMP2, RA, RB | addiu TMP3, BASE, -8 // TMP3 = vtop | subu RC, RC, TMP0 // RC = vbase | // Note: RC may now be even _above_ BASE if nargs was < numparams. | beqz RB, >5 // Copy all varargs? |. subu TMP1, TMP3, RC | addiu TMP2, TMP2, -16 |1: // Copy vararg slots to destination slots. | lw CARG1, HI(RC) | sltu AT, RC, TMP3 | lw CARG2, LO(RC) | addiu RC, RC, 8 | movz CARG1, TISNIL, AT | sw CARG1, HI(RA) | sw CARG2, LO(RA) | sltu AT, RA, TMP2 | bnez AT, <1 |. addiu RA, RA, 8 |3: | ins_next | |5: // Copy all varargs. | lw TMP0, L->maxstack | blez TMP1, <3 // No vararg slots? |. li MULTRES, 8 // MULTRES = (0+1)*8 | addu TMP2, RA, TMP1 | sltu AT, TMP0, TMP2 | bnez AT, >7 |. addiu MULTRES, TMP1, 8 |6: | lw SFRETHI, HI(RC) | lw SFRETLO, LO(RC) | addiu RC, RC, 8 | sw SFRETHI, HI(RA) | sw SFRETLO, LO(RA) | sltu AT, RC, TMP3 | bnez AT, <6 // More vararg slots? |. addiu RA, RA, 8 | b <3 |. nop | |7: // Grow stack for varargs. | load_got lj_state_growstack | sw RA, L->top | subu RA, RA, BASE | sw BASE, L->base | subu BASE, RC, BASE // Need delta, because BASE may change. | sw PC, SAVE_PC | srl CARG2, TMP1, 3 | call_intern lj_state_growstack // (lua_State *L, int n) |. move CARG1, L | move RC, BASE | lw BASE, L->base | addu RA, BASE, RA | addu RC, BASE, RC | b <6 |. addiu TMP3, BASE, -8 break; /* -- Returns ----------------------------------------------------------- */ case BC_RETM: | // RA = results*8, RD = extra_nresults*8 | addu RD, RD, MULTRES // MULTRES >= 8, so RD >= 8. | // Fall through. Assumes BC_RET follows. break; case BC_RET: | // RA = results*8, RD = (nresults+1)*8 | lw PC, FRAME_PC(BASE) | addu RA, BASE, RA | move MULTRES, RD |1: | andi TMP0, PC, FRAME_TYPE | bnez TMP0, ->BC_RETV_Z |. xori TMP1, PC, FRAME_VARG | |->BC_RET_Z: | // BASE = base, RA = resultptr, RD = (nresults+1)*8, PC = return | lw INS, -4(PC) | addiu TMP2, BASE, -8 | addiu RC, RD, -8 | decode_RA8a TMP0, INS | decode_RB8a RB, INS | decode_RA8b TMP0 | decode_RB8b RB | addu TMP3, TMP2, RB | beqz RC, >3 |. subu BASE, TMP2, TMP0 |2: | lw SFRETHI, HI(RA) | lw SFRETLO, LO(RA) | addiu RA, RA, 8 | addiu RC, RC, -8 | sw SFRETHI, HI(TMP2) | sw SFRETLO, LO(TMP2) | bnez RC, <2 |. addiu TMP2, TMP2, 8 |3: | addiu TMP3, TMP3, -8 |5: | sltu AT, TMP2, TMP3 | bnez AT, >6 |. lw LFUNC:TMP1, FRAME_FUNC(BASE) | ins_next1 | lw TMP1, LFUNC:TMP1->pc | lw KBASE, PC2PROTO(k)(TMP1) | ins_next2 | |6: // Fill up results with nil. | sw TISNIL, HI(TMP2) | b <5 |. addiu TMP2, TMP2, 8 | |->BC_RETV_Z: // Non-standard return case. | andi TMP2, TMP1, FRAME_TYPEP | bnez TMP2, ->vm_return |. nop | // Return from vararg function: relocate BASE down. | subu BASE, BASE, TMP1 | b <1 |. lw PC, FRAME_PC(BASE) break; case BC_RET0: case BC_RET1: | // RA = results*8, RD = (nresults+1)*8 | lw PC, FRAME_PC(BASE) | addu RA, BASE, RA | move MULTRES, RD | andi TMP0, PC, FRAME_TYPE | bnez TMP0, ->BC_RETV_Z |. xori TMP1, PC, FRAME_VARG | | lw INS, -4(PC) | addiu TMP2, BASE, -8 if (op == BC_RET1) { | lw SFRETHI, HI(RA) | lw SFRETLO, LO(RA) } | decode_RB8a RB, INS | decode_RA8a RA, INS | decode_RB8b RB | decode_RA8b RA if (op == BC_RET1) { | sw SFRETHI, HI(TMP2) | sw SFRETLO, LO(TMP2) } | subu BASE, TMP2, RA |5: | sltu AT, RD, RB | bnez AT, >6 |. lw LFUNC:TMP1, FRAME_FUNC(BASE) | ins_next1 | lw TMP1, LFUNC:TMP1->pc | lw KBASE, PC2PROTO(k)(TMP1) | ins_next2 | |6: // Fill up results with nil. | addiu TMP2, TMP2, 8 | addiu RD, RD, 8 | b <5 if (op == BC_RET1) { |. sw TISNIL, HI(TMP2) } else { |. sw TISNIL, -8+HI(TMP2) } break; /* -- Loops and branches ------------------------------------------------ */ case BC_FORL: |.if JIT | hotloop |.endif | // Fall through. Assumes BC_IFORL follows. break; case BC_JFORI: case BC_JFORL: #if !LJ_HASJIT break; #endif case BC_FORI: case BC_IFORL: | // RA = base*8, RD = target (after end of loop or start of loop) vk = (op == BC_IFORL || op == BC_JFORL); | addu RA, BASE, RA | lw SFARG1HI, FORL_IDX*8+HI(RA) | lw SFARG1LO, FORL_IDX*8+LO(RA) if (op != BC_JFORL) { | srl RD, RD, 1 | lui TMP2, (-(BCBIAS_J*4 >> 16) & 65535) | addu TMP2, RD, TMP2 } if (!vk) { | lw SFARG2HI, FORL_STOP*8+HI(RA) | lw SFARG2LO, FORL_STOP*8+LO(RA) | bne SFARG1HI, TISNUM, >5 |. lw SFRETHI, FORL_STEP*8+HI(RA) | xor AT, SFARG2HI, TISNUM | lw SFRETLO, FORL_STEP*8+LO(RA) | xor TMP0, SFRETHI, TISNUM | or AT, AT, TMP0 | bnez AT, ->vmeta_for |. slt AT, SFRETLO, r0 | slt CRET1, SFARG2LO, SFARG1LO | slt TMP1, SFARG1LO, SFARG2LO | movn CRET1, TMP1, AT } else { | bne SFARG1HI, TISNUM, >5 |. lw SFARG2LO, FORL_STEP*8+LO(RA) | lw SFRETLO, FORL_STOP*8+LO(RA) | move TMP3, SFARG1LO | addu SFARG1LO, SFARG1LO, SFARG2LO | xor TMP0, SFARG1LO, TMP3 | xor TMP1, SFARG1LO, SFARG2LO | and TMP0, TMP0, TMP1 | slt TMP1, SFARG1LO, SFRETLO | slt CRET1, SFRETLO, SFARG1LO | slt AT, SFARG2LO, r0 | slt TMP0, TMP0, r0 // ((y^a) & (y^b)) < 0: overflow. | movn CRET1, TMP1, AT | or CRET1, CRET1, TMP0 } |1: if (op == BC_FORI) { | movz TMP2, r0, CRET1 | addu PC, PC, TMP2 } else if (op == BC_JFORI) { | addu PC, PC, TMP2 | lhu RD, -4+OFS_RD(PC) } else if (op == BC_IFORL) { | movn TMP2, r0, CRET1 | addu PC, PC, TMP2 } if (vk) { | sw SFARG1HI, FORL_IDX*8+HI(RA) | sw SFARG1LO, FORL_IDX*8+LO(RA) } | ins_next1 | sw SFARG1HI, FORL_EXT*8+HI(RA) | sw SFARG1LO, FORL_EXT*8+LO(RA) |2: if (op == BC_JFORI) { | beqz CRET1, =>BC_JLOOP |. decode_RD8b RD } else if (op == BC_JFORL) { | beqz CRET1, =>BC_JLOOP } | ins_next2 | |5: // FP loop. |.if FPU if (!vk) { | ldc1 f0, FORL_IDX*8(RA) | ldc1 f2, FORL_STOP*8(RA) | sltiu TMP0, SFARG1HI, LJ_TISNUM | sltiu TMP1, SFARG2HI, LJ_TISNUM | sltiu AT, SFRETHI, LJ_TISNUM | and TMP0, TMP0, TMP1 | and AT, AT, TMP0 | beqz AT, ->vmeta_for |. slt TMP3, SFRETHI, r0 | c.ole.d 0, f0, f2 | c.ole.d 1, f2, f0 | li CRET1, 1 | movt CRET1, r0, 0 | movt AT, r0, 1 | b <1 |. movn CRET1, AT, TMP3 } else { | ldc1 f0, FORL_IDX*8(RA) | ldc1 f4, FORL_STEP*8(RA) | ldc1 f2, FORL_STOP*8(RA) | lw SFARG2HI, FORL_STEP*8+HI(RA) | add.d f0, f0, f4 | c.ole.d 0, f0, f2 | c.ole.d 1, f2, f0 | slt TMP3, SFARG2HI, r0 | li CRET1, 1 | li AT, 1 | movt CRET1, r0, 0 | movt AT, r0, 1 | movn CRET1, AT, TMP3 if (op == BC_IFORL) { | movn TMP2, r0, CRET1 | addu PC, PC, TMP2 } | sdc1 f0, FORL_IDX*8(RA) | ins_next1 | b <2 |. sdc1 f0, FORL_EXT*8(RA) } |.else if (!vk) { | sltiu TMP0, SFARG1HI, LJ_TISNUM | sltiu TMP1, SFARG2HI, LJ_TISNUM | sltiu AT, SFRETHI, LJ_TISNUM | and TMP0, TMP0, TMP1 | and AT, AT, TMP0 | beqz AT, ->vmeta_for |. nop | bal ->vm_sfcmpolex |. move TMP3, SFRETHI | b <1 |. nop } else { | lw SFARG2HI, FORL_STEP*8+HI(RA) | load_got __adddf3 | call_extern |. sw TMP2, ARG5 | lw SFARG2HI, FORL_STOP*8+HI(RA) | lw SFARG2LO, FORL_STOP*8+LO(RA) | move SFARG1HI, SFRETHI | move SFARG1LO, SFRETLO | bal ->vm_sfcmpolex |. lw TMP3, FORL_STEP*8+HI(RA) if ( op == BC_JFORL ) { | lhu RD, -4+OFS_RD(PC) | lw TMP2, ARG5 | b <1 |. decode_RD8b RD } else { | b <1 |. lw TMP2, ARG5 } } |.endif break; case BC_ITERL: |.if JIT | hotloop |.endif | // Fall through. Assumes BC_IITERL follows. break; case BC_JITERL: #if !LJ_HASJIT break; #endif case BC_IITERL: | // RA = base*8, RD = target | addu RA, BASE, RA | lw TMP1, HI(RA) | beq TMP1, TISNIL, >1 // Stop if iterator returned nil. |. lw TMP2, LO(RA) if (op == BC_JITERL) { | sw TMP1, -8+HI(RA) | b =>BC_JLOOP |. sw TMP2, -8+LO(RA) } else { | branch_RD // Otherwise save control var + branch. | sw TMP1, -8+HI(RA) | sw TMP2, -8+LO(RA) } |1: | ins_next break; case BC_LOOP: | // RA = base*8, RD = target (loop extent) | // Note: RA/RD is only used by trace recorder to determine scope/extent | // This opcode does NOT jump, it's only purpose is to detect a hot loop. |.if JIT | hotloop |.endif | // Fall through. Assumes BC_ILOOP follows. break; case BC_ILOOP: | // RA = base*8, RD = target (loop extent) | ins_next break; case BC_JLOOP: |.if JIT | // RA = base*8 (ignored), RD = traceno*8 | lw TMP1, DISPATCH_J(trace)(DISPATCH) | srl RD, RD, 1 | li AT, 0 | addu TMP1, TMP1, RD | // Traces on MIPS don't store the trace number, so use 0. | sw AT, DISPATCH_GL(vmstate)(DISPATCH) | lw TRACE:TMP2, 0(TMP1) | sw BASE, DISPATCH_GL(jit_base)(DISPATCH) | lw TMP2, TRACE:TMP2->mcode | sw L, DISPATCH_GL(tmpbuf.L)(DISPATCH) | jr TMP2 |. addiu JGL, DISPATCH, GG_DISP2G+32768 |.endif break; case BC_JMP: | // RA = base*8 (only used by trace recorder), RD = target | branch_RD | ins_next break; /* -- Function headers -------------------------------------------------- */ case BC_FUNCF: |.if JIT | hotcall |.endif case BC_FUNCV: /* NYI: compiled vararg functions. */ | // Fall through. Assumes BC_IFUNCF/BC_IFUNCV follow. break; case BC_JFUNCF: #if !LJ_HASJIT break; #endif case BC_IFUNCF: | // BASE = new base, RA = BASE+framesize*8, RB = LFUNC, RC = nargs*8 | lw TMP2, L->maxstack | lbu TMP1, -4+PC2PROTO(numparams)(PC) | lw KBASE, -4+PC2PROTO(k)(PC) | sltu AT, TMP2, RA | bnez AT, ->vm_growstack_l |. sll TMP1, TMP1, 3 if (op != BC_JFUNCF) { | ins_next1 } |2: | sltu AT, NARGS8:RC, TMP1 // Check for missing parameters. | bnez AT, >3 |. addu AT, BASE, NARGS8:RC if (op == BC_JFUNCF) { | decode_RD8a RD, INS | b =>BC_JLOOP |. decode_RD8b RD } else { | ins_next2 } | |3: // Clear missing parameters. | sw TISNIL, HI(AT) | b <2 |. addiu NARGS8:RC, NARGS8:RC, 8 break; case BC_JFUNCV: #if !LJ_HASJIT break; #endif | NYI // NYI: compiled vararg functions break; /* NYI: compiled vararg functions. */ case BC_IFUNCV: | // BASE = new base, RA = BASE+framesize*8, RB = LFUNC, RC = nargs*8 | addu TMP1, BASE, RC | lw TMP2, L->maxstack | addu TMP0, RA, RC | sw LFUNC:RB, LO(TMP1) // Store copy of LFUNC. | addiu TMP3, RC, 8+FRAME_VARG | sltu AT, TMP0, TMP2 | lw KBASE, -4+PC2PROTO(k)(PC) | beqz AT, ->vm_growstack_l |. sw TMP3, HI(TMP1) // Store delta + FRAME_VARG. | lbu TMP2, -4+PC2PROTO(numparams)(PC) | move RA, BASE | move RC, TMP1 | ins_next1 | beqz TMP2, >3 |. addiu BASE, TMP1, 8 |1: | lw TMP0, HI(RA) | lw TMP3, LO(RA) | sltu AT, RA, RC // Less args than parameters? | move CARG1, TMP0 | movz TMP0, TISNIL, AT // Clear missing parameters. | movn CARG1, TISNIL, AT // Clear old fixarg slot (help the GC). | sw TMP3, 8+LO(TMP1) | addiu TMP2, TMP2, -1 | sw TMP0, 8+HI(TMP1) | addiu TMP1, TMP1, 8 | sw CARG1, HI(RA) | bnez TMP2, <1 |. addiu RA, RA, 8 |3: | ins_next2 break; case BC_FUNCC: case BC_FUNCCW: | // BASE = new base, RA = BASE+framesize*8, RB = CFUNC, RC = nargs*8 if (op == BC_FUNCC) { | lw CFUNCADDR, CFUNC:RB->f } else { | lw CFUNCADDR, DISPATCH_GL(wrapf)(DISPATCH) } | addu TMP1, RA, NARGS8:RC | lw TMP2, L->maxstack | addu RC, BASE, NARGS8:RC | sw BASE, L->base | sltu AT, TMP2, TMP1 | sw RC, L->top | li_vmstate C if (op == BC_FUNCCW) { | lw CARG2, CFUNC:RB->f } | bnez AT, ->vm_growstack_c // Need to grow stack. |. move CARG1, L | jalr CFUNCADDR // (lua_State *L [, lua_CFunction f]) |. st_vmstate | // Returns nresults. | lw BASE, L->base | sll RD, CRET1, 3 | lw TMP1, L->top | li_vmstate INTERP | lw PC, FRAME_PC(BASE) // Fetch PC of caller. | subu RA, TMP1, RD // RA = L->top - nresults*8 | sw L, DISPATCH_GL(cur_L)(DISPATCH) | b ->vm_returnc |. st_vmstate break; /* ---------------------------------------------------------------------- */ default: fprintf(stderr, "Error: undefined opcode BC_%s\n", bc_names[op]); exit(2); break; } } static int build_backend(BuildCtx *ctx) { int op; dasm_growpc(Dst, BC__MAX); build_subroutines(ctx); |.code_op for (op = 0; op < BC__MAX; op++) build_ins(ctx, (BCOp)op, op); return BC__MAX; } /* Emit pseudo frame-info for all assembler functions. */ static void emit_asm_debug(BuildCtx *ctx) { int fcofs = (int)((uint8_t *)ctx->glob[GLOB_vm_ffi_call] - ctx->code); int i; switch (ctx->mode) { case BUILD_elfasm: fprintf(ctx->fp, "\t.section .debug_frame,\"\",@progbits\n"); fprintf(ctx->fp, ".Lframe0:\n" "\t.4byte .LECIE0-.LSCIE0\n" ".LSCIE0:\n" "\t.4byte 0xffffffff\n" "\t.byte 0x1\n" "\t.string \"\"\n" "\t.uleb128 0x1\n" "\t.sleb128 -4\n" "\t.byte 31\n" "\t.byte 0xc\n\t.uleb128 29\n\t.uleb128 0\n" "\t.align 2\n" ".LECIE0:\n\n"); fprintf(ctx->fp, ".LSFDE0:\n" "\t.4byte .LEFDE0-.LASFDE0\n" ".LASFDE0:\n" "\t.4byte .Lframe0\n" "\t.4byte .Lbegin\n" "\t.4byte %d\n" "\t.byte 0xe\n\t.uleb128 %d\n" "\t.byte 0x9f\n\t.sleb128 1\n" "\t.byte 0x9e\n\t.sleb128 2\n", fcofs, CFRAME_SIZE); for (i = 23; i >= 16; i--) fprintf(ctx->fp, "\t.byte %d\n\t.uleb128 %d\n", 0x80+i, 26-i); #if !LJ_SOFTFP for (i = 30; i >= 20; i -= 2) fprintf(ctx->fp, "\t.byte %d\n\t.uleb128 %d\n", 0x80+32+i, 42-i); #endif fprintf(ctx->fp, "\t.align 2\n" ".LEFDE0:\n\n"); #if LJ_HASFFI fprintf(ctx->fp, ".LSFDE1:\n" "\t.4byte .LEFDE1-.LASFDE1\n" ".LASFDE1:\n" "\t.4byte .Lframe0\n" "\t.4byte lj_vm_ffi_call\n" "\t.4byte %d\n" "\t.byte 0x9f\n\t.uleb128 1\n" "\t.byte 0x90\n\t.uleb128 2\n" "\t.byte 0xd\n\t.uleb128 0x10\n" "\t.align 2\n" ".LEFDE1:\n\n", (int)ctx->codesz - fcofs); #endif #if !LJ_NO_UNWIND fprintf(ctx->fp, "\t.section .eh_frame,\"aw\",@progbits\n"); fprintf(ctx->fp, "\t.globl lj_err_unwind_dwarf\n" ".Lframe1:\n" "\t.4byte .LECIE1-.LSCIE1\n" ".LSCIE1:\n" "\t.4byte 0\n" "\t.byte 0x1\n" "\t.string \"zPR\"\n" "\t.uleb128 0x1\n" "\t.sleb128 -4\n" "\t.byte 31\n" "\t.uleb128 6\n" /* augmentation length */ "\t.byte 0\n" "\t.4byte lj_err_unwind_dwarf\n" "\t.byte 0\n" "\t.byte 0xc\n\t.uleb128 29\n\t.uleb128 0\n" "\t.align 2\n" ".LECIE1:\n\n"); fprintf(ctx->fp, ".LSFDE2:\n" "\t.4byte .LEFDE2-.LASFDE2\n" ".LASFDE2:\n" "\t.4byte .LASFDE2-.Lframe1\n" "\t.4byte .Lbegin\n" "\t.4byte %d\n" "\t.uleb128 0\n" /* augmentation length */ "\t.byte 0xe\n\t.uleb128 %d\n" "\t.byte 0x9f\n\t.sleb128 1\n" "\t.byte 0x9e\n\t.sleb128 2\n", fcofs, CFRAME_SIZE); for (i = 23; i >= 16; i--) fprintf(ctx->fp, "\t.byte %d\n\t.uleb128 %d\n", 0x80+i, 26-i); #if !LJ_SOFTFP for (i = 30; i >= 20; i -= 2) fprintf(ctx->fp, "\t.byte %d\n\t.uleb128 %d\n", 0x80+32+i, 42-i); #endif fprintf(ctx->fp, "\t.align 2\n" ".LEFDE2:\n\n"); #if LJ_HASFFI fprintf(ctx->fp, ".Lframe2:\n" "\t.4byte .LECIE2-.LSCIE2\n" ".LSCIE2:\n" "\t.4byte 0\n" "\t.byte 0x1\n" "\t.string \"zR\"\n" "\t.uleb128 0x1\n" "\t.sleb128 -4\n" "\t.byte 31\n" "\t.uleb128 1\n" /* augmentation length */ "\t.byte 0\n" "\t.byte 0xc\n\t.uleb128 29\n\t.uleb128 0\n" "\t.align 2\n" ".LECIE2:\n\n"); fprintf(ctx->fp, ".LSFDE3:\n" "\t.4byte .LEFDE3-.LASFDE3\n" ".LASFDE3:\n" "\t.4byte .LASFDE3-.Lframe2\n" "\t.4byte lj_vm_ffi_call\n" "\t.4byte %d\n" "\t.uleb128 0\n" /* augmentation length */ "\t.byte 0x9f\n\t.uleb128 1\n" "\t.byte 0x90\n\t.uleb128 2\n" "\t.byte 0xd\n\t.uleb128 0x10\n" "\t.align 2\n" ".LEFDE3:\n\n", (int)ctx->codesz - fcofs); #endif #endif break; default: break; } }