lib/luajit/src/lj_iropt.h - trafficserver - Git at Google

 /*
 ** Common header for IR emitter and optimizations.
 ** Copyright (C) 2005-2015 Mike Pall. See Copyright Notice in luajit.h
 */

 #ifndef _LJ_IROPT_H
 #define _LJ_IROPT_H

 #include <stdarg.h>

 #include "lj_obj.h"
 #include "lj_jit.h"

 #if LJ_HASJIT
 /* IR emitter. */
 LJ_FUNC void LJ_FASTCALL lj_ir_growtop(jit_State *J);
 LJ_FUNC TRef LJ_FASTCALL lj_ir_emit(jit_State *J);

 /* Save current IR in J->fold.ins, but do not emit it (yet). */
 static LJ_AINLINE void lj_ir_set_(jit_State *J, uint16_t ot, IRRef1 a, IRRef1 b)
 {
   J->fold.ins.ot = ot; J->fold.ins.op1 = a; J->fold.ins.op2 = b;
 }

 #define lj_ir_set(J, ot, a, b) \
   lj_ir_set_(J, (uint16_t)(ot), (IRRef1)(a), (IRRef1)(b))

 /* Get ref of next IR instruction and optionally grow IR.
 ** Note: this may invalidate all IRIns*!
 */
 static LJ_AINLINE IRRef lj_ir_nextins(jit_State *J)
 {
   IRRef ref = J->cur.nins;
   if (LJ_UNLIKELY(ref >= J->irtoplim)) lj_ir_growtop(J);
   J->cur.nins = ref + 1;
   return ref;
 }

 /* Interning of constants. */
 LJ_FUNC TRef LJ_FASTCALL lj_ir_kint(jit_State *J, int32_t k);
 LJ_FUNC void lj_ir_k64_freeall(jit_State *J);
 LJ_FUNC TRef lj_ir_k64(jit_State *J, IROp op, cTValue *tv);
 LJ_FUNC cTValue *lj_ir_k64_find(jit_State *J, uint64_t u64);
 LJ_FUNC TRef lj_ir_knum_u64(jit_State *J, uint64_t u64);
 LJ_FUNC TRef lj_ir_knumint(jit_State *J, lua_Number n);
 LJ_FUNC TRef lj_ir_kint64(jit_State *J, uint64_t u64);
 LJ_FUNC TRef lj_ir_kgc(jit_State *J, GCobj *o, IRType t);
 LJ_FUNC TRef lj_ir_kptr_(jit_State *J, IROp op, void *ptr);
 LJ_FUNC TRef lj_ir_knull(jit_State *J, IRType t);
 LJ_FUNC TRef lj_ir_kslot(jit_State *J, TRef key, IRRef slot);

 #if LJ_64
 #define lj_ir_kintp(J, k)	lj_ir_kint64(J, (uint64_t)(k))
 #else
 #define lj_ir_kintp(J, k)	lj_ir_kint(J, (int32_t)(k))
 #endif

 static LJ_AINLINE TRef lj_ir_knum(jit_State *J, lua_Number n)
 {
   TValue tv;
   tv.n = n;
   return lj_ir_knum_u64(J, tv.u64);
 }

 #define lj_ir_kstr(J, str)	lj_ir_kgc(J, obj2gco((str)), IRT_STR)
 #define lj_ir_ktab(J, tab)	lj_ir_kgc(J, obj2gco((tab)), IRT_TAB)
 #define lj_ir_kfunc(J, func)	lj_ir_kgc(J, obj2gco((func)), IRT_FUNC)
 #define lj_ir_kptr(J, ptr)	lj_ir_kptr_(J, IR_KPTR, (ptr))
 #define lj_ir_kkptr(J, ptr)	lj_ir_kptr_(J, IR_KKPTR, (ptr))

 /* Special FP constants. */
 #define lj_ir_knum_zero(J)	lj_ir_knum_u64(J, U64x(00000000,00000000))
 #define lj_ir_knum_one(J)	lj_ir_knum_u64(J, U64x(3ff00000,00000000))
 #define lj_ir_knum_tobit(J)	lj_ir_knum_u64(J, U64x(43380000,00000000))

 /* Special 128 bit SIMD constants. */
 #define lj_ir_knum_abs(J)	lj_ir_k64(J, IR_KNUM, LJ_KSIMD(J, LJ_KSIMD_ABS))
 #define lj_ir_knum_neg(J)	lj_ir_k64(J, IR_KNUM, LJ_KSIMD(J, LJ_KSIMD_NEG))

 /* Access to constants. */
 LJ_FUNC void lj_ir_kvalue(lua_State *L, TValue *tv, const IRIns *ir);

 /* Convert IR operand types. */
 LJ_FUNC TRef LJ_FASTCALL lj_ir_tonumber(jit_State *J, TRef tr);
 LJ_FUNC TRef LJ_FASTCALL lj_ir_tonum(jit_State *J, TRef tr);
 LJ_FUNC TRef LJ_FASTCALL lj_ir_tostr(jit_State *J, TRef tr);

 /* Miscellaneous IR ops. */
 LJ_FUNC int lj_ir_numcmp(lua_Number a, lua_Number b, IROp op);
 LJ_FUNC int lj_ir_strcmp(GCstr *a, GCstr *b, IROp op);
 LJ_FUNC void lj_ir_rollback(jit_State *J, IRRef ref);

 /* Emit IR instructions with on-the-fly optimizations. */
 LJ_FUNC TRef LJ_FASTCALL lj_opt_fold(jit_State *J);
 LJ_FUNC TRef LJ_FASTCALL lj_opt_cse(jit_State *J);
 LJ_FUNC TRef LJ_FASTCALL lj_opt_cselim(jit_State *J, IRRef lim);

 /* Special return values for the fold functions. */
 enum {
   NEXTFOLD,		/* Couldn't fold, pass on. */
   RETRYFOLD,		/* Retry fold with modified fins. */
   KINTFOLD,		/* Return ref for int constant in fins->i. */
   FAILFOLD,		/* Guard would always fail. */
   DROPFOLD,		/* Guard eliminated. */
   MAX_FOLD
 };

 #define INTFOLD(k)	((J->fold.ins.i = (k)), (TRef)KINTFOLD)
 #define INT64FOLD(k)	(lj_ir_kint64(J, (k)))
 #define CONDFOLD(cond)	((TRef)FAILFOLD + (TRef)(cond))
 #define LEFTFOLD	(J->fold.ins.op1)
 #define RIGHTFOLD	(J->fold.ins.op2)
 #define CSEFOLD		(lj_opt_cse(J))
 #define EMITFOLD	(lj_ir_emit(J))

 /* Load/store forwarding. */
 LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_aload(jit_State *J);
 LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_hload(jit_State *J);
 LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_uload(jit_State *J);
 LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_fload(jit_State *J);
 LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_xload(jit_State *J);
 LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_tab_len(jit_State *J);
 LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_hrefk(jit_State *J);
 LJ_FUNC int LJ_FASTCALL lj_opt_fwd_href_nokey(jit_State *J);
 LJ_FUNC int LJ_FASTCALL lj_opt_fwd_tptr(jit_State *J, IRRef lim);
 LJ_FUNC int lj_opt_fwd_wasnonnil(jit_State *J, IROpT loadop, IRRef xref);

 /* Dead-store elimination. */
 LJ_FUNC TRef LJ_FASTCALL lj_opt_dse_ahstore(jit_State *J);
 LJ_FUNC TRef LJ_FASTCALL lj_opt_dse_ustore(jit_State *J);
 LJ_FUNC TRef LJ_FASTCALL lj_opt_dse_fstore(jit_State *J);
 LJ_FUNC TRef LJ_FASTCALL lj_opt_dse_xstore(jit_State *J);

 /* Narrowing. */
 LJ_FUNC TRef LJ_FASTCALL lj_opt_narrow_convert(jit_State *J);
 LJ_FUNC TRef LJ_FASTCALL lj_opt_narrow_index(jit_State *J, TRef key);
 LJ_FUNC TRef LJ_FASTCALL lj_opt_narrow_toint(jit_State *J, TRef tr);
 LJ_FUNC TRef LJ_FASTCALL lj_opt_narrow_tobit(jit_State *J, TRef tr);
 #if LJ_HASFFI
 LJ_FUNC TRef LJ_FASTCALL lj_opt_narrow_cindex(jit_State *J, TRef key);
 #endif
 LJ_FUNC TRef lj_opt_narrow_arith(jit_State *J, TRef rb, TRef rc,
 				 TValue *vb, TValue *vc, IROp op);
 LJ_FUNC TRef lj_opt_narrow_unm(jit_State *J, TRef rc, TValue *vc);
 LJ_FUNC TRef lj_opt_narrow_mod(jit_State *J, TRef rb, TRef rc, TValue *vc);
 LJ_FUNC TRef lj_opt_narrow_pow(jit_State *J, TRef rb, TRef rc, TValue *vc);
 LJ_FUNC IRType lj_opt_narrow_forl(jit_State *J, cTValue *forbase);

 /* Optimization passes. */
 LJ_FUNC void lj_opt_dce(jit_State *J);
 LJ_FUNC int lj_opt_loop(jit_State *J);
 #if LJ_SOFTFP || (LJ_32 && LJ_HASFFI)
 LJ_FUNC void lj_opt_split(jit_State *J);
 #else
 #define lj_opt_split(J)		UNUSED(J)
 #endif
 LJ_FUNC void lj_opt_sink(jit_State *J);

 #endif

 #endif
	/*
	** Common header for IR emitter and optimizations.
	** Copyright (C) 2005-2015 Mike Pall. See Copyright Notice in luajit.h
	*/

	#ifndef _LJ_IROPT_H
	#define _LJ_IROPT_H

	#include <stdarg.h>

	#include "lj_obj.h"
	#include "lj_jit.h"

	#if LJ_HASJIT
	/* IR emitter. */
	LJ_FUNC void LJ_FASTCALL lj_ir_growtop(jit_State *J);
	LJ_FUNC TRef LJ_FASTCALL lj_ir_emit(jit_State *J);

	/* Save current IR in J->fold.ins, but do not emit it (yet). */
	static LJ_AINLINE void lj_ir_set_(jit_State *J, uint16_t ot, IRRef1 a, IRRef1 b)
	{
	J->fold.ins.ot = ot; J->fold.ins.op1 = a; J->fold.ins.op2 = b;
	}

	#define lj_ir_set(J, ot, a, b) \
	lj_ir_set_(J, (uint16_t)(ot), (IRRef1)(a), (IRRef1)(b))

	/* Get ref of next IR instruction and optionally grow IR.
	** Note: this may invalidate all IRIns*!
	*/
	static LJ_AINLINE IRRef lj_ir_nextins(jit_State *J)
	{
	IRRef ref = J->cur.nins;
	if (LJ_UNLIKELY(ref >= J->irtoplim)) lj_ir_growtop(J);
	J->cur.nins = ref + 1;
	return ref;
	}

	/* Interning of constants. */
	LJ_FUNC TRef LJ_FASTCALL lj_ir_kint(jit_State *J, int32_t k);
	LJ_FUNC void lj_ir_k64_freeall(jit_State *J);
	LJ_FUNC TRef lj_ir_k64(jit_State J, IROp op, cTValue tv);
	LJ_FUNC cTValue lj_ir_k64_find(jit_State J, uint64_t u64);
	LJ_FUNC TRef lj_ir_knum_u64(jit_State *J, uint64_t u64);
	LJ_FUNC TRef lj_ir_knumint(jit_State *J, lua_Number n);
	LJ_FUNC TRef lj_ir_kint64(jit_State *J, uint64_t u64);
	LJ_FUNC TRef lj_ir_kgc(jit_State J, GCobj o, IRType t);
	LJ_FUNC TRef lj_ir_kptr_(jit_State J, IROp op, void ptr);
	LJ_FUNC TRef lj_ir_knull(jit_State *J, IRType t);
	LJ_FUNC TRef lj_ir_kslot(jit_State *J, TRef key, IRRef slot);

	#if LJ_64
	#define lj_ir_kintp(J, k) lj_ir_kint64(J, (uint64_t)(k))
	#else
	#define lj_ir_kintp(J, k) lj_ir_kint(J, (int32_t)(k))
	#endif

	static LJ_AINLINE TRef lj_ir_knum(jit_State *J, lua_Number n)
	{
	TValue tv;
	tv.n = n;
	return lj_ir_knum_u64(J, tv.u64);
	}

	#define lj_ir_kstr(J, str) lj_ir_kgc(J, obj2gco((str)), IRT_STR)
	#define lj_ir_ktab(J, tab) lj_ir_kgc(J, obj2gco((tab)), IRT_TAB)
	#define lj_ir_kfunc(J, func) lj_ir_kgc(J, obj2gco((func)), IRT_FUNC)
	#define lj_ir_kptr(J, ptr) lj_ir_kptr_(J, IR_KPTR, (ptr))
	#define lj_ir_kkptr(J, ptr) lj_ir_kptr_(J, IR_KKPTR, (ptr))

	/* Special FP constants. */
	#define lj_ir_knum_zero(J) lj_ir_knum_u64(J, U64x(00000000,00000000))
	#define lj_ir_knum_one(J) lj_ir_knum_u64(J, U64x(3ff00000,00000000))
	#define lj_ir_knum_tobit(J) lj_ir_knum_u64(J, U64x(43380000,00000000))

	/* Special 128 bit SIMD constants. */
	#define lj_ir_knum_abs(J) lj_ir_k64(J, IR_KNUM, LJ_KSIMD(J, LJ_KSIMD_ABS))
	#define lj_ir_knum_neg(J) lj_ir_k64(J, IR_KNUM, LJ_KSIMD(J, LJ_KSIMD_NEG))

	/* Access to constants. */
	LJ_FUNC void lj_ir_kvalue(lua_State L, TValue tv, const IRIns *ir);

	/* Convert IR operand types. */
	LJ_FUNC TRef LJ_FASTCALL lj_ir_tonumber(jit_State *J, TRef tr);
	LJ_FUNC TRef LJ_FASTCALL lj_ir_tonum(jit_State *J, TRef tr);
	LJ_FUNC TRef LJ_FASTCALL lj_ir_tostr(jit_State *J, TRef tr);

	/* Miscellaneous IR ops. */
	LJ_FUNC int lj_ir_numcmp(lua_Number a, lua_Number b, IROp op);
	LJ_FUNC int lj_ir_strcmp(GCstr a, GCstr b, IROp op);
	LJ_FUNC void lj_ir_rollback(jit_State *J, IRRef ref);

	/* Emit IR instructions with on-the-fly optimizations. */
	LJ_FUNC TRef LJ_FASTCALL lj_opt_fold(jit_State *J);
	LJ_FUNC TRef LJ_FASTCALL lj_opt_cse(jit_State *J);
	LJ_FUNC TRef LJ_FASTCALL lj_opt_cselim(jit_State *J, IRRef lim);

	/* Special return values for the fold functions. */
	enum {
	NEXTFOLD, /* Couldn't fold, pass on. */
	RETRYFOLD, /* Retry fold with modified fins. */
	KINTFOLD, /* Return ref for int constant in fins->i. */
	FAILFOLD, /* Guard would always fail. */
	DROPFOLD, /* Guard eliminated. */
	MAX_FOLD
	};

	#define INTFOLD(k) ((J->fold.ins.i = (k)), (TRef)KINTFOLD)
	#define INT64FOLD(k) (lj_ir_kint64(J, (k)))
	#define CONDFOLD(cond) ((TRef)FAILFOLD + (TRef)(cond))
	#define LEFTFOLD (J->fold.ins.op1)
	#define RIGHTFOLD (J->fold.ins.op2)
	#define CSEFOLD (lj_opt_cse(J))
	#define EMITFOLD (lj_ir_emit(J))

	/* Load/store forwarding. */
	LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_aload(jit_State *J);
	LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_hload(jit_State *J);
	LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_uload(jit_State *J);
	LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_fload(jit_State *J);
	LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_xload(jit_State *J);
	LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_tab_len(jit_State *J);
	LJ_FUNC TRef LJ_FASTCALL lj_opt_fwd_hrefk(jit_State *J);
	LJ_FUNC int LJ_FASTCALL lj_opt_fwd_href_nokey(jit_State *J);
	LJ_FUNC int LJ_FASTCALL lj_opt_fwd_tptr(jit_State *J, IRRef lim);
	LJ_FUNC int lj_opt_fwd_wasnonnil(jit_State *J, IROpT loadop, IRRef xref);

	/* Dead-store elimination. */
	LJ_FUNC TRef LJ_FASTCALL lj_opt_dse_ahstore(jit_State *J);
	LJ_FUNC TRef LJ_FASTCALL lj_opt_dse_ustore(jit_State *J);
	LJ_FUNC TRef LJ_FASTCALL lj_opt_dse_fstore(jit_State *J);
	LJ_FUNC TRef LJ_FASTCALL lj_opt_dse_xstore(jit_State *J);

	/* Narrowing. */
	LJ_FUNC TRef LJ_FASTCALL lj_opt_narrow_convert(jit_State *J);
	LJ_FUNC TRef LJ_FASTCALL lj_opt_narrow_index(jit_State *J, TRef key);
	LJ_FUNC TRef LJ_FASTCALL lj_opt_narrow_toint(jit_State *J, TRef tr);
	LJ_FUNC TRef LJ_FASTCALL lj_opt_narrow_tobit(jit_State *J, TRef tr);
	#if LJ_HASFFI
	LJ_FUNC TRef LJ_FASTCALL lj_opt_narrow_cindex(jit_State *J, TRef key);
	#endif
	LJ_FUNC TRef lj_opt_narrow_arith(jit_State *J, TRef rb, TRef rc,
	TValue vb, TValue vc, IROp op);
	LJ_FUNC TRef lj_opt_narrow_unm(jit_State J, TRef rc, TValue vc);
	LJ_FUNC TRef lj_opt_narrow_mod(jit_State J, TRef rb, TRef rc, TValue vc);
	LJ_FUNC TRef lj_opt_narrow_pow(jit_State J, TRef rb, TRef rc, TValue vc);
	LJ_FUNC IRType lj_opt_narrow_forl(jit_State J, cTValue forbase);

	/* Optimization passes. */
	LJ_FUNC void lj_opt_dce(jit_State *J);
	LJ_FUNC int lj_opt_loop(jit_State *J);
	#if LJ_SOFTFP \|\| (LJ_32 && LJ_HASFFI)
	LJ_FUNC void lj_opt_split(jit_State *J);
	#else
	#define lj_opt_split(J) UNUSED(J)
	#endif
	LJ_FUNC void lj_opt_sink(jit_State *J);

	#endif

	#endif