Joshua Wise's Git repositories - snipe.git/blame_incremental

Commit	Line	Data
	1	(* L3 Compiler
	2	* Assembly code generator for fake x86 assembly
	3	* Author: Joshua Wise <jwise@andrew.cmu.edu>
	4	* Author: Chris Lu <czl@andrew.cmu.edu>
	5	*)
	6
	7	signature CODEGEN =
	8	sig
	9	val codegen : Tree.stm list -> x86.insn list
	10	end
	11
	12	structure Codegen :> CODEGEN =
	13	struct
	14	structure T = Tree
	15	structure X = x86
	16
	17	(* effect : T.exp -> bool
	18	* true iff the given expression has an effect.
	19	*)
	20	fun effect (T.BINOP(T.DIV, _, _)) = true
	21	\| effect (T.BINOP(T.MOD, _, _)) = true
	22	\| effect (T.CALL _) = true
	23	\| effect (T.BINOP(_, a, b)) = (effect a) orelse (effect b)
	24	\| effect (T.UNOP (_, a)) = effect a
	25	\| effect _ = false
	26
	27	(* hasfixed : T.exp -> bool
	28	* true iff the given expression has an hasfixed. Somewhat like effect, hmm?
	29	*)
	30	fun hasfixed (T.BINOP(T.DIV, _, _)) = true
	31	\| hasfixed (T.BINOP(T.MOD, _, _)) = true
	32	\| hasfixed (T.BINOP(T.LSH, _, _)) = true
	33	\| hasfixed (T.BINOP(T.RSH, _, _)) = true
	34	\| hasfixed (T.CALL _) = true
	35	\| hasfixed (T.BINOP(_, a, b)) = (hasfixed a) orelse (hasfixed b)
	36	\| hasfixed (T.UNOP (_, a)) = hasfixed a
	37	\| hasfixed _ = false
	38
	39	(* munch_exp : prex86oper -> T.exp -> prex86insn list *)
	40	(* munch_exp d e
	41	* generates instructions to achieve d <- e
	42	* d must be TEMP(t) or REG(r)
	43	*)
	44	fun munch_exp d (T.CONST(n)) = [X.MOV(d, X.CONST n)]
	45	\| munch_exp d (T.TEMP(t)) = [X.MOV(d, X.TEMP t)]
	46	\| munch_exp d (T.ARG(0)) = [X.MOV(d, X.REG X.EDI)]
	47	\| munch_exp d (T.ARG(1)) = [X.MOV(d, X.REG X.ESI)]
	48	\| munch_exp d (T.ARG(2)) = [X.MOV(d, X.REG X.EDX)]
	49	\| munch_exp d (T.ARG(3)) = [X.MOV(d, X.REG X.ECX)]
	50	\| munch_exp d (T.ARG(4)) = [X.MOV(d, X.REG X.R8D)]
	51	\| munch_exp d (T.ARG(5)) = [X.MOV(d, X.REG X.R9D)]
	52	\| munch_exp d (T.ARG(t)) = [X.MOV(d, X.STACKARG (t - 6))]
	53	\| munch_exp d (T.CALL(name, l)) = (* Scary demons live here. *)
	54	let
	55	val nargs = length l
	56	val nstack = if (nargs <= 6)
	57	then 0
	58	else nargs - 6
	59	val stackb = nstack * 8
	60	fun argdest 1 = X.REG X.EDI
	61	\| argdest 2 = X.REG X.ESI
	62	\| argdest 3 = X.REG X.EDX
	63	\| argdest 4 = X.REG X.ECX
	64	\| argdest 5 = X.REG X.R8D
	65	\| argdest 6 = X.REG X.R9D
	66	\| argdest n = X.REL (X.RSP, (~(stackb - 8 * (n - 7))))
	67
	68	val dests = List.tabulate (nargs, fn x => argdest (x+1))
	69	val hf = List.map hasfixed l
	70	val (d_hf, exps_hf) = ListPair.unzip (ListPair.foldr
	71	(fn (a,b,c) => if b then a::c else c)
	72	nil
	73	(ListPair.zip (dests,l), hf)
	74	)
	75	val (d_nohf, exps_nohf) = ListPair.unzip (ListPair.foldr
	76	(fn (a,b,c) => if b then c else a::c)
	77	nil
	78	(ListPair.zip (dests,l), hf)
	79	)
	80	val temps = List.tabulate (List.length d_hf, fn x => Temp.new(Int.toString x ^ " arg"))
	81	val argevals_hf = List.map
	82	(fn (t,exp) => munch_exp (X.TEMP t) exp)
	83	(ListPair.zip (temps, exps_hf))
	84	val argpushes = List.map
	85	(fn (dest, t) => [(X.MOV (dest, X.TEMP t))])
	86	(ListPair.zip (d_hf, temps))
	87	val argevals_nohf = List.map
	88	(fn (d,exp) => munch_exp d exp)
	89	(ListPair.zip (d_nohf, exps_nohf))
	90	in
	91	List.concat argevals_hf @
	92	List.concat argpushes @
	93	List.concat argevals_nohf @
	94	[ X.SIZE (X.Qword, X.SUB (X.REG X.RSP, X.CONST (Word32.fromInt stackb))),
	95	X.CALL (name, nargs),
	96	X.SIZE (X.Qword, X.ADD (X.REG X.RSP, X.CONST (Word32.fromInt stackb))),
	97	X.MOV (d, X.REG X.EAX) ] (* Finally! *)
	98	end
	99	\| munch_exp d (T.BINOP(T.ADD, e1, T.CONST 0w0)) = munch_exp d e1
	100	\| munch_exp d (T.BINOP(T.ADD, T.CONST 0w0, e1)) = munch_exp d e1
	101	\| munch_exp d (T.BINOP(T.ADD, e1, T.CONST n)) = (munch_exp d e1) @ [X.ADD(d, X.CONST n)]
	102	\| munch_exp d (T.BINOP(T.ADD, T.CONST n, e1)) = (munch_exp d e1) @ [X.ADD(d, X.CONST n)]
	103	\| munch_exp d (T.BINOP(T.ADD, e1, T.TEMP t)) = (munch_exp d e1) @ [X.ADD(d, X.TEMP t)]
	104	\| munch_exp d (T.BINOP(T.ADD, T.TEMP t, e2)) = (munch_exp d e2) @ [X.ADD(d, X.TEMP t)]
	105	\| munch_exp d (T.BINOP(T.ADD, e1, e2)) =
	106	let
	107	val t1 = X.TEMP (Temp.new ("add"))
	108	in
	109	(munch_exp d e1) @ (munch_exp t1 e2) @ [X.ADD(d, t1)]
	110	end
	111	\| munch_exp d (T.BINOP(T.SUB, T.CONST 0w0, e1)) = (munch_exp d e1) @ [X.NEG d]
	112	\| munch_exp d (T.BINOP(T.SUB, e1, T.CONST 0w0)) = munch_exp d e1
	113	\| munch_exp d (T.BINOP(T.SUB, e1, T.CONST(n))) = (munch_exp d e1) @ [X.SUB(d, X.CONST n)]
	114	\| munch_exp d (T.BINOP(T.SUB, e1, T.TEMP t)) = (munch_exp d e1) @ [X.SUB(d, X.TEMP t)]
	115	\| munch_exp d (T.BINOP(T.SUB, e1, e2)) =
	116	let
	117	val t1 = X.TEMP (Temp.new ("sub"))
	118	in
	119	(munch_exp d e1) @ (munch_exp t1 e2) @ [X.SUB(d, t1)]
	120	end
	121	\| munch_exp d (T.BINOP(T.MUL, T.TEMP t, T.CONST n)) = [X.IMUL3(d, X.TEMP t, n)]
	122	\| munch_exp d (T.BINOP(T.MUL, T.CONST n, T.TEMP t)) = [X.IMUL3(d, X.TEMP t, n)]
	123	\| munch_exp d (T.BINOP(T.MUL, e1, T.CONST 0w1)) = munch_exp d e1
	124	\| munch_exp d (T.BINOP(T.MUL, T.CONST 0w1, e1)) = munch_exp d e1
	125	\| munch_exp d (T.BINOP(T.MUL, e1, T.CONST n)) = (munch_exp d e1) @ [X.IMUL(d, X.CONST n)]
	126	\| munch_exp d (T.BINOP(T.MUL, T.CONST n, e1)) = (munch_exp d e1) @ [X.IMUL(d, X.CONST n)]
	127	\| munch_exp d (T.BINOP(T.MUL, e1, e2)) =
	128	let
	129	val t1 = X.TEMP (Temp.new ("mul"))
	130	in
	131	(munch_exp d e1) @ (munch_exp t1 e2) @ [X.IMUL(d, t1)]
	132	end
	133	\| munch_exp d (T.BINOP(T.DIV, e1, e2)) =
	134	let
	135	val t1 = X.TEMP (Temp.new ("div"))
	136	in
	137	(munch_exp t1 e1) @ (munch_exp d e2) @
	138	[X.MOV (X.REG X.EAX, t1), X.CLTD, X.IDIV d, X.MOV (d, X.REG X.EAX)]
	139	end
	140	\| munch_exp d (T.BINOP(T.MOD, e1, e2)) =
	141	let
	142	val t1 = X.TEMP (Temp.new ("mod"))
	143	in
	144	(munch_exp t1 e1) @ (munch_exp d e2) @
	145	[X.MOV (X.REG X.EAX, t1), X.CLTD, X.IDIV d, X.MOV (d, X.REG X.EDX)]
	146	end
	147	\| munch_exp d (T.BINOP(T.LSH, e1, T.CONST n)) = (munch_exp d e1) @ [X.SAL (d, X.CONST (n mod 0w32))]
	148	\| munch_exp d (T.BINOP(T.LSH, e1, T.TEMP t)) = (munch_exp d e1) @ [X.MOV (X.REG X.ECX, X.TEMP t), X.SAL (d, X.REG X.ECX)]
	149	\| munch_exp d (T.BINOP(T.LSH, e1, e2)) =
	150	let
	151	val t = X.TEMP (Temp.new ("lsh"))
	152	in
	153	(munch_exp d e1) @ (munch_exp t e2) @ [X.MOV (X.REG X.ECX, t), X.SAL (d, X.REG X.ECX)]
	154	end
	155	\| munch_exp d (T.BINOP(T.RSH, e1, T.CONST n)) = (munch_exp d e1) @ [X.SAR (d, X.CONST (n mod 0w32))]
	156	\| munch_exp d (T.BINOP(T.RSH, e1, T.TEMP t)) = (munch_exp d e1) @ [X.MOV (X.REG X.ECX, X.TEMP t), X.SAR (d, X.REG X.ECX)]
	157	\| munch_exp d (T.BINOP(T.RSH, e1, e2)) =
	158	let
	159	val t = X.TEMP (Temp.new ("rsh"))
	160	in
	161	(munch_exp d e1) @ (munch_exp t e2) @ [X.MOV (X.REG X.ECX, t), X.SAR (d, X.REG X.ECX)]
	162	end
	163	\| munch_exp d (T.BINOP(T.BITAND, T.CONST n, e1)) = (munch_exp d e1) @ [X.AND (d, X.CONST n)]
	164	\| munch_exp d (T.BINOP(T.BITAND, e1, T.CONST n)) = (munch_exp d e1) @ [X.AND (d, X.CONST n)]
	165	\| munch_exp d (T.BINOP(T.BITAND, T.TEMP t, e1)) = (munch_exp d e1) @ [X.AND (d, X.TEMP t)]
	166	\| munch_exp d (T.BINOP(T.BITAND, e1, T.TEMP t)) = (munch_exp d e1) @ [X.AND (d, X.TEMP t)]
	167	\| munch_exp d (T.BINOP(T.BITAND, e1, e2)) =
	168	let
	169	val t1 = X.TEMP (Temp.new ("bitand"))
	170	in
	171	(munch_exp d e1) @ (munch_exp t1 e2) @ [X.AND(d, t1)]
	172	end
	173	\| munch_exp d (T.BINOP(T.BITOR, T.CONST n, e1)) = (munch_exp d e1) @ [X.OR (d, X.CONST n)]
	174	\| munch_exp d (T.BINOP(T.BITOR, e1, T.CONST n)) = (munch_exp d e1) @ [X.OR (d, X.CONST n)]
	175	\| munch_exp d (T.BINOP(T.BITOR, T.TEMP t, e1)) = (munch_exp d e1) @ [X.OR (d, X.TEMP t)]
	176	\| munch_exp d (T.BINOP(T.BITOR, e1, T.TEMP t)) = (munch_exp d e1) @ [X.OR (d, X.TEMP t)]
	177	\| munch_exp d (T.BINOP(T.BITOR, e1, e2)) =
	178	let
	179	val t1 = X.TEMP (Temp.new ("bitor"))
	180	in
	181	(munch_exp d e1) @ (munch_exp t1 e2) @ [X.OR(d, t1)]
	182	end
	183	\| munch_exp d (T.BINOP(T.BITXOR, T.CONST n, e1)) = (munch_exp d e1) @ [X.XOR (d, X.CONST n)]
	184	\| munch_exp d (T.BINOP(T.BITXOR, e1, T.CONST n)) = (munch_exp d e1) @ [X.XOR (d, X.CONST n)]
	185	\| munch_exp d (T.BINOP(T.BITXOR, T.TEMP t, e1)) = (munch_exp d e1) @ [X.XOR (d, X.TEMP t)]
	186	\| munch_exp d (T.BINOP(T.BITXOR, e1, T.TEMP t)) = (munch_exp d e1) @ [X.XOR (d, X.TEMP t)]
	187	\| munch_exp d (T.BINOP(T.BITXOR, e1, e2)) =
	188	let
	189	val t1 = X.TEMP (Temp.new ("bitxor"))
	190	in
	191	(munch_exp d e1) @ (munch_exp t1 e2) @ [X.XOR(d, t1)]
	192	end
	193	\| munch_exp d (a as T.BINOP(T.LOGAND, e1, e2)) =
	194	let
	195	val (insn1, pos1, neg1) = munch_cond e1
	196	val (insn2, pos2, neg2) = munch_cond e2
	197	val t1 = X.TEMP (Temp.new("logand 1"))
	198	val t2 = X.TEMP (Temp.new("logand 2"))
	199	val l = Label.new ()
	200	in
	201	if (effect e2 orelse (length insn2 > 10))
	202	then (insn1) @
	203	[X.SETcc(pos1, t1), X.Jcc (neg1, l)] @
	204	(insn2) @
	205	[X.SETcc(pos2, t1), X.LABEL l, X.MOVZB(d, t1)]
	206	else insn1 @ [X.SETcc (pos1, t1)] @ insn2 @ [X.SETcc (pos2, t2), X.SIZE(X.Byte, X.AND(t1, t2)), X.MOVZB(d, t1)]
	207	end
	208	\| munch_exp d (a as T.BINOP(T.LOGOR, e1, e2)) =
	209	let
	210	val (insn1, pos1, neg1) = munch_cond e1
	211	val (insn2, pos2, neg2) = munch_cond e2
	212	val t1 = X.TEMP (Temp.new("logor 1"))
	213	val t2 = X.TEMP (Temp.new("logor 2"))
	214	val l = Label.new ()
	215	in
	216	if (effect e2 orelse (length insn2 > 10))
	217	then (insn1) @
	218	[X.SETcc(pos1, t1), X.Jcc (pos1, l)] @
	219	(insn2) @
	220	[X.SETcc(pos2, t1), X.LABEL l, X.MOVZB(d, t1)]
	221	else insn1 @ [X.SETcc (pos1, t1)] @ insn2 @ [X.SETcc (pos2, t2), X.SIZE(X.Byte, X.OR(t1, t2)), X.MOVZB(d, t1)]
	222	end
	223	\| munch_exp d (a as T.BINOP(T.EQ, _, _)) =
	224	let val (insns, pos, neg) = munch_cond a in insns @ [X.SETcc (pos, d), X.MOVZB(d, d)] end
	225	\| munch_exp d (a as T.BINOP(T.NEQ, _, _)) =
	226	let val (insns, pos, neg) = munch_cond a in insns @ [X.SETcc (pos, d), X.MOVZB(d, d)] end
	227	\| munch_exp d (a as T.BINOP(T.LE, _, _)) =
	228	let val (insns, pos, neg) = munch_cond a in insns @ [X.SETcc (pos, d), X.MOVZB(d, d)] end
	229	\| munch_exp d (a as T.BINOP(T.LT, _, _)) =
	230	let val (insns, pos, neg) = munch_cond a in insns @ [X.SETcc (pos, d), X.MOVZB(d, d)] end
	231	\| munch_exp d (a as T.BINOP(T.GE, _, _)) =
	232	let val (insns, pos, neg) = munch_cond a in insns @ [X.SETcc (pos, d), X.MOVZB(d, d)] end
	233	\| munch_exp d (a as T.BINOP(T.GT, _, _)) =
	234	let val (insns, pos, neg) = munch_cond a in insns @ [X.SETcc (pos, d), X.MOVZB(d, d)] end
	235	\| munch_exp d (T.UNOP(T.NEG, T.CONST n)) = [X.MOV (d, X.CONST (~n))]
	236	\| munch_exp d (T.UNOP(T.NEG, e1)) = (munch_exp d e1) @ [X.NEG d]
	237	\| munch_exp d (T.UNOP(T.BITNOT, T.CONST n)) = [X.MOV (d, X.CONST (Word32.notb n))]
	238	\| munch_exp d (T.UNOP(T.BITNOT, e1)) = (munch_exp d e1) @ [X.NOT d]
	239	\| munch_exp d (T.UNOP(T.BANG, T.CONST n)) = if (n = 0w0) then [X.MOV (d, X.CONST 0w1)] else [X.MOV (d, X.CONST 0w0)]
	240	\| munch_exp d (T.UNOP(T.BANG, e)) =
	241	let
	242	val (insns, pos, neg) = munch_cond e
	243	in
	244	insns @ [X.SETcc (neg, d), X.MOVZB(d, d)]
	245	end
	246	(* munch_cond : T.exp -> X.insn list * X.cond * X.cond
	247	* munch_cond stm generates code to set flags, and then returns a conditional
	248	* to test if the expression was true and for if it was false.
	249	*)
	250	and munch_cond (T.UNOP (T.BANG, e)) =
	251	let
	252	val (insns, pos, neg) = munch_cond e
	253	in
	254	(insns, neg, pos)
	255	end
	256	\| munch_cond (T.BINOP(T.NEQ, T.TEMP t, T.CONST n)) = ([X.CMP(X.TEMP t, X.CONST n)], X.NE, X.E)
	257	\| munch_cond (T.BINOP(T.NEQ, T.CONST n, T.TEMP t)) = ([X.CMP(X.TEMP t, X.CONST n)], X.NE, X.E)
	258	\| munch_cond (T.BINOP(T.NEQ, T.CONST n, e1)) =
	259	let val t = X.TEMP (Temp.new ("const neq")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.NE, X.E) end
	260	\| munch_cond (T.BINOP(T.NEQ, e1, T.CONST n)) =
	261	let val t = X.TEMP (Temp.new ("const neq")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.NE, X.E) end
	262	\| munch_cond (T.BINOP(T.NEQ, T.TEMP t, e1)) =
	263	let val t1 = X.TEMP (Temp.new ("const neq")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.NE, X.E) end
	264	\| munch_cond (T.BINOP(T.NEQ, e1, T.TEMP t)) =
	265	let val t1 = X.TEMP (Temp.new ("const neq")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.NE, X.E) end
	266	\| munch_cond (T.BINOP(T.NEQ, e1, e2)) =
	267	let
	268	val t1 = X.TEMP (Temp.new ("var neq 1"))
	269	val t2 = X.TEMP (Temp.new ("var neq 2"))
	270	in
	271	(munch_exp t1 e1 @ munch_exp t2 e2 @
	272	[X.CMP(t1, t2)], X.NE, X.E)
	273	end
	274	\| munch_cond (T.BINOP(T.EQ, T.TEMP t, T.CONST n)) = ([X.CMP(X.TEMP t, X.CONST n)], X.E, X.NE)
	275	\| munch_cond (T.BINOP(T.EQ, T.CONST n, T.TEMP t)) = ([X.CMP(X.TEMP t, X.CONST n)], X.E, X.NE)
	276	\| munch_cond (T.BINOP(T.EQ, T.CONST n, e1)) =
	277	let val t = X.TEMP (Temp.new ("const eq")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.E, X.NE) end
	278	\| munch_cond (T.BINOP(T.EQ, e1, T.CONST n)) =
	279	let val t = X.TEMP (Temp.new ("const eq")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.E, X.NE) end
	280	\| munch_cond (T.BINOP(T.EQ, T.TEMP t, e1)) =
	281	let val t1 = X.TEMP (Temp.new ("const eq")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.E, X.NE) end
	282	\| munch_cond (T.BINOP(T.EQ, e1, T.TEMP t)) =
	283	let val t1 = X.TEMP (Temp.new ("const eq")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.E, X.NE) end
	284	\| munch_cond (T.BINOP(T.EQ, e1, e2)) =
	285	let
	286	val t1 = X.TEMP (Temp.new ("var eq 1"))
	287	val t2 = X.TEMP (Temp.new ("var eq 2"))
	288	in
	289	(munch_exp t1 e1 @ munch_exp t2 e2 @
	290	[X.CMP(t1, t2)], X.E, X.NE)
	291	end
	292	\| munch_cond (T.BINOP(T.LE, T.TEMP t, T.CONST n)) = ([X.CMP(X.TEMP t, X.CONST n)], X.LE, X.G)
	293	\| munch_cond (T.BINOP(T.LE, T.CONST n, T.TEMP t)) = ([X.CMP(X.TEMP t, X.CONST n)], X.GE, X.L)
	294	\| munch_cond (T.BINOP(T.LE, T.CONST n, e1)) =
	295	let val t = X.TEMP (Temp.new ("const le")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.GE, X.L) end
	296	\| munch_cond (T.BINOP(T.LE, e1, T.CONST n)) =
	297	let val t = X.TEMP (Temp.new ("const le")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.LE, X.G) end
	298	\| munch_cond (T.BINOP(T.LE, T.TEMP t, e1)) =
	299	let val t1 = X.TEMP (Temp.new ("const le")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.GE, X.L) end
	300	\| munch_cond (T.BINOP(T.LE, e1, T.TEMP t)) =
	301	let val t1 = X.TEMP (Temp.new ("const le")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.LE, X.G) end
	302	\| munch_cond (T.BINOP(T.LE, e1, e2)) =
	303	let
	304	val t1 = X.TEMP (Temp.new ("var le 1"))
	305	val t2 = X.TEMP (Temp.new ("var le 2"))
	306	in
	307	(munch_exp t1 e1 @ munch_exp t2 e2 @
	308	[X.CMP(t1, t2)], X.LE, X.G)
	309	end
	310	\| munch_cond (T.BINOP(T.LT, T.TEMP t, T.CONST n)) = ([X.CMP(X.TEMP t, X.CONST n)], X.L, X.GE)
	311	\| munch_cond (T.BINOP(T.LT, T.CONST n, T.TEMP t)) = ([X.CMP(X.TEMP t, X.CONST n)], X.G, X.LE)
	312	\| munch_cond (T.BINOP(T.LT, T.CONST n, e1)) =
	313	let val t = X.TEMP (Temp.new ("const lt")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.G, X.LE) end
	314	\| munch_cond (T.BINOP(T.LT, e1, T.CONST n)) =
	315	let val t = X.TEMP (Temp.new ("const lt")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.L, X.GE) end
	316	\| munch_cond (T.BINOP(T.LT, T.TEMP t, e1)) =
	317	let val t1 = X.TEMP (Temp.new ("const lt")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.G, X.LE) end
	318	\| munch_cond (T.BINOP(T.LT, e1, T.TEMP t)) =
	319	let val t1 = X.TEMP (Temp.new ("const lt")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.L, X.GE) end
	320	\| munch_cond (T.BINOP(T.LT, e1, e2)) =
	321	let
	322	val t1 = X.TEMP (Temp.new ("var lt 1"))
	323	val t2 = X.TEMP (Temp.new ("var lt 2"))
	324	in
	325	(munch_exp t1 e1 @ munch_exp t2 e2 @
	326	[X.CMP(t1, t2)], X.L, X.GE)
	327	end
	328	\| munch_cond (T.BINOP(T.GT, T.TEMP t, T.CONST n)) = ([X.CMP(X.TEMP t, X.CONST n)], X.G, X.LE)
	329	\| munch_cond (T.BINOP(T.GT, T.CONST n, T.TEMP t)) = ([X.CMP(X.TEMP t, X.CONST n)], X.L, X.GE)
	330	\| munch_cond (T.BINOP(T.GT, e1, T.CONST n)) =
	331	let val t = X.TEMP (Temp.new ("const gt")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.G, X.LE) end
	332	\| munch_cond (T.BINOP(T.GT, T.CONST n, e1)) =
	333	let val t = X.TEMP (Temp.new ("const gt")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.L, X.GE) end
	334	\| munch_cond (T.BINOP(T.GT, e1, T.TEMP t)) =
	335	let val t1 = X.TEMP (Temp.new ("const gt")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.G, X.LE) end
	336	\| munch_cond (T.BINOP(T.GT, T.TEMP t, e1)) =
	337	let val t1 = X.TEMP (Temp.new ("const gt")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.L, X.GE) end
	338	\| munch_cond (T.BINOP(T.GT, e1, e2)) =
	339	let
	340	val t1 = X.TEMP (Temp.new ("var gt 1"))
	341	val t2 = X.TEMP (Temp.new ("var gt 2"))
	342	in
	343	(munch_exp t1 e1 @ munch_exp t2 e2 @
	344	[X.CMP(t1, t2)], X.G, X.LE)
	345	end
	346	\| munch_cond (T.BINOP(T.GE, T.TEMP t, T.CONST n)) = ([X.CMP(X.TEMP t, X.CONST n)], X.GE, X.L)
	347	\| munch_cond (T.BINOP(T.GE, T.CONST n, T.TEMP t)) = ([X.CMP(X.TEMP t, X.CONST n)], X.LE, X.G)
	348	\| munch_cond (T.BINOP(T.GE, e1, T.CONST n)) =
	349	let val t = X.TEMP (Temp.new ("const ge")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.GE, X.L) end
	350	\| munch_cond (T.BINOP(T.GE, T.CONST n, e1)) =
	351	let val t = X.TEMP (Temp.new ("const ge")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.LE, X.G) end
	352	\| munch_cond (T.BINOP(T.GE, e1, T.TEMP t)) =
	353	let val t1 = X.TEMP (Temp.new ("const ge")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.GE, X.L) end
	354	\| munch_cond (T.BINOP(T.GE, T.TEMP t, e1)) =
	355	let val t1 = X.TEMP (Temp.new ("const ge")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.LE, X.G) end
	356	\| munch_cond (T.BINOP(T.GE, e1, e2)) =
	357	let
	358	val t1 = X.TEMP (Temp.new ("var ge 1"))
	359	val t2 = X.TEMP (Temp.new ("var ge 2"))
	360	in
	361	(munch_exp t1 e1 @ munch_exp t2 e2 @
	362	[X.CMP(t1, t2)], X.GE, X.L)
	363	end
	364	\| munch_cond (T.BINOP(T.LOGOR, e1, e2)) =
	365	let
	366	val (insn1, pos1, neg1) = munch_cond e1
	367	val (insn2, pos2, neg2) = munch_cond e2
	368	val t1 = X.TEMP (Temp.new("logor c 1"))
	369	val t2 = X.TEMP (Temp.new("logor c 2"))
	370	val l = Label.new ()
	371	in
	372	if (effect e2 orelse (length insn2 > 10))
	373	then ((insn1) @
	374	[X.SETcc (pos1, t1), X.Jcc (pos1, l)] @
	375	(insn2) @
	376	[X.SETcc (pos2, t1), X.LABEL l, X.SIZE (X.Byte, X.TEST (t1, t1))],
	377	X.NE, X.E)
	378	else (insn1 @ [X.SETcc (pos1, t1)] @ insn2 @ [X.SETcc (pos2, t2), X.SIZE(X.Byte, X.OR(t1, t2))], X.NE, X.E)
	379	end
	380	\| munch_cond (T.BINOP(T.LOGAND, e1, e2)) =
	381	let
	382	val (insn1, pos1, neg1) = munch_cond e1
	383	val (insn2, pos2, neg2) = munch_cond e2
	384	val t1 = X.TEMP (Temp.new("logand c 1"))
	385	val t2 = X.TEMP (Temp.new("logand c 2"))
	386	val l = Label.new ()
	387	in
	388	if (effect e2 orelse (length insn2 > 10))
	389	then ((insn1) @
	390	[X.SETcc (pos1, t1), X.Jcc (neg1, l)] @
	391	(insn2) @
	392	[X.SETcc (pos2, t1), X.LABEL l, X.SIZE (X.Byte, X.TEST (t1, t1))],
	393	X.NE, X.E)
	394	else (insn1 @ [X.SETcc (pos1, t1)] @ insn2 @ [X.SETcc (pos2, t2), X.SIZE(X.Byte, X.AND(t1, t2))], X.NE, X.E)
	395	end
	396	\| munch_cond e =
	397	let
	398	val t = X.TEMP (Temp.new ("munch c"))
	399	in
	400	(munch_exp t e @ [ X.TEST (t,t) ], X.NE, X.E)
	401	end
	402
	403	(* munch_stm : T.stm -> X.insn list *)
	404	(* munch_stm stm generates code to execute stm *)
	405	fun munch_stm (T.MOVE (T.TEMP t, a as T.TEMP _)) = munch_exp (X.TEMP t) a
	406	\| munch_stm (T.MOVE (T.TEMP t, a as T.CONST _)) = munch_exp (X.TEMP t) a
	407	\| munch_stm (T.MOVE (T.TEMP t, a as T.ARG _)) = munch_exp (X.TEMP t) a
	408	\| munch_stm (T.MOVE (T.TEMP t, a as T.CALL _)) = munch_exp (X.TEMP t) a
	409	\| munch_stm (T.MOVE(T.TEMP t1, e2)) =
	410	let
	411	val t = Temp.new ("assign")
	412	in
	413	munch_exp (X.TEMP t) e2
	414	@ [X.MOV(X.TEMP t1, X.TEMP t)]
	415	end
	416	\| munch_stm (T.MOVE(_, _)) =
	417	raise ErrorMsg.InternalError "Incorrect first operand for T.MOVE?"
	418	\| munch_stm (T.RETURN(e)) =
	419	let
	420	val t = Temp.new ("retval")
	421	in
	422	munch_exp (X.TEMP t) e
	423	@ [X.MOV(X.REG X.EAX, X.TEMP t), X.RET]
	424	end
	425	\| munch_stm (T.LABEL(l)) = [X.LABEL l]
	426	\| munch_stm (T.JUMP(l)) = [X.JMP l]
	427	\| munch_stm (T.JUMPIFN(e, l)) =
	428	let
	429	val (insns, pos, neg) = munch_cond e
	430	in
	431	insns @ [X.Jcc (neg, l)]
	432	end
	433
	434	fun codegen nil = nil
	435	\| codegen (stm::stms) = munch_stm stm @ codegen stms
	436	end

1

(* L3 Compiler

2

* Assembly code generator for fake x86 assembly

3

* Author: Joshua Wise <jwise@andrew.cmu.edu>

4

* Author: Chris Lu <czl@andrew.cmu.edu>

*)

signature CODEGEN =

sig

val codegen : Tree.stm list -> x86.insn list

10

end

11

12

structure Codegen :> CODEGEN =

struct

structure T = Tree

structure X = x86

(* effect : T.exp -> bool

18

* true iff the given expression has an effect.

19

*)

20

fun effect (T.BINOP(T.DIV, _, _)) = true

21

| effect (T.BINOP(T.MOD, _, _)) = true

22

| effect (T.CALL _) = true

23

| effect (T.BINOP(_, a, b)) = (effect a) orelse (effect b)

24

| effect (T.UNOP (_, a)) = effect a

25

| effect _ = false

26

27

(* hasfixed : T.exp -> bool

28

* true iff the given expression has an hasfixed. Somewhat like effect, hmm?

29

*)

30

fun hasfixed (T.BINOP(T.DIV, _, _)) = true

31

| hasfixed (T.BINOP(T.MOD, _, _)) = true

32

| hasfixed (T.BINOP(T.LSH, _, _)) = true

33

| hasfixed (T.BINOP(T.RSH, _, _)) = true

34

| hasfixed (T.CALL _) = true

35

| hasfixed (T.BINOP(_, a, b)) = (hasfixed a) orelse (hasfixed b)

36

| hasfixed (T.UNOP (_, a)) = hasfixed a

37

| hasfixed _ = false

38

39

(* munch_exp : prex86oper -> T.exp -> prex86insn list *)

40

(* munch_exp d e

41

* generates instructions to achieve d <- e

42

* d must be TEMP(t) or REG(r)

43

*)

44

fun munch_exp d (T.CONST(n)) = [X.MOV(d, X.CONST n)]

45

| munch_exp d (T.TEMP(t)) = [X.MOV(d, X.TEMP t)]

46

| munch_exp d (T.ARG(0)) = [X.MOV(d, X.REG X.EDI)]

47

| munch_exp d (T.ARG(1)) = [X.MOV(d, X.REG X.ESI)]

48

| munch_exp d (T.ARG(2)) = [X.MOV(d, X.REG X.EDX)]

49

| munch_exp d (T.ARG(3)) = [X.MOV(d, X.REG X.ECX)]

50

| munch_exp d (T.ARG(4)) = [X.MOV(d, X.REG X.R8D)]

51

| munch_exp d (T.ARG(5)) = [X.MOV(d, X.REG X.R9D)]

52

| munch_exp d (T.ARG(t)) = [X.MOV(d, X.STACKARG (t - 6))]

53

| munch_exp d (T.CALL(name, l)) = (* Scary demons live here. *)

54

let

55

val nargs = length l

56

val nstack = if (nargs <= 6)

57

then 0

58

else nargs - 6

59

val stackb = nstack * 8

60

fun argdest 1 = X.REG X.EDI

61

| argdest 2 = X.REG X.ESI

62

| argdest 3 = X.REG X.EDX

63

| argdest 4 = X.REG X.ECX

64

| argdest 5 = X.REG X.R8D

65

| argdest 6 = X.REG X.R9D

66

| argdest n = X.REL (X.RSP, (~(stackb - 8 * (n - 7))))

67

68

val dests = List.tabulate (nargs, fn x => argdest (x+1))

69

val hf = List.map hasfixed l

70

val (d_hf, exps_hf) = ListPair.unzip (ListPair.foldr

71

(fn (a,b,c) => if b then a::c else c)

72

nil

73

(ListPair.zip (dests,l), hf)

74

)

75

val (d_nohf, exps_nohf) = ListPair.unzip (ListPair.foldr

76

(fn (a,b,c) => if b then c else a::c)

77

nil

78

(ListPair.zip (dests,l), hf)

79

)

80

val temps = List.tabulate (List.length d_hf, fn x => Temp.new(Int.toString x ^ " arg"))

81

val argevals_hf = List.map

82

(fn (t,exp) => munch_exp (X.TEMP t) exp)

83

(ListPair.zip (temps, exps_hf))

84

val argpushes = List.map

85

(fn (dest, t) => [(X.MOV (dest, X.TEMP t))])

86

(ListPair.zip (d_hf, temps))

87

val argevals_nohf = List.map

88

(fn (d,exp) => munch_exp d exp)

89

(ListPair.zip (d_nohf, exps_nohf))

90

in

91

List.concat argevals_hf @

92

List.concat argpushes @

93

List.concat argevals_nohf @

94

[ X.SIZE (X.Qword, X.SUB (X.REG X.RSP, X.CONST (Word32.fromInt stackb))),

95

X.CALL (name, nargs),

96

X.SIZE (X.Qword, X.ADD (X.REG X.RSP, X.CONST (Word32.fromInt stackb))),

97

X.MOV (d, X.REG X.EAX) ] (* Finally! *)

98

end

99

| munch_exp d (T.BINOP(T.ADD, e1, T.CONST 0w0)) = munch_exp d e1

100

| munch_exp d (T.BINOP(T.ADD, T.CONST 0w0, e1)) = munch_exp d e1

101

| munch_exp d (T.BINOP(T.ADD, e1, T.CONST n)) = (munch_exp d e1) @ [X.ADD(d, X.CONST n)]

102

| munch_exp d (T.BINOP(T.ADD, T.CONST n, e1)) = (munch_exp d e1) @ [X.ADD(d, X.CONST n)]

103

| munch_exp d (T.BINOP(T.ADD, e1, T.TEMP t)) = (munch_exp d e1) @ [X.ADD(d, X.TEMP t)]

104

| munch_exp d (T.BINOP(T.ADD, T.TEMP t, e2)) = (munch_exp d e2) @ [X.ADD(d, X.TEMP t)]

105

| munch_exp d (T.BINOP(T.ADD, e1, e2)) =

106

let

107

val t1 = X.TEMP (Temp.new ("add"))

108

in

109

(munch_exp d e1) @ (munch_exp t1 e2) @ [X.ADD(d, t1)]

110

end

111

| munch_exp d (T.BINOP(T.SUB, T.CONST 0w0, e1)) = (munch_exp d e1) @ [X.NEG d]

112

| munch_exp d (T.BINOP(T.SUB, e1, T.CONST 0w0)) = munch_exp d e1

113

| munch_exp d (T.BINOP(T.SUB, e1, T.CONST(n))) = (munch_exp d e1) @ [X.SUB(d, X.CONST n)]

114

| munch_exp d (T.BINOP(T.SUB, e1, T.TEMP t)) = (munch_exp d e1) @ [X.SUB(d, X.TEMP t)]

115

| munch_exp d (T.BINOP(T.SUB, e1, e2)) =

116

let

117

val t1 = X.TEMP (Temp.new ("sub"))

118

in

119

(munch_exp d e1) @ (munch_exp t1 e2) @ [X.SUB(d, t1)]

120

end

121

| munch_exp d (T.BINOP(T.MUL, T.TEMP t, T.CONST n)) = [X.IMUL3(d, X.TEMP t, n)]

122

| munch_exp d (T.BINOP(T.MUL, T.CONST n, T.TEMP t)) = [X.IMUL3(d, X.TEMP t, n)]

123

| munch_exp d (T.BINOP(T.MUL, e1, T.CONST 0w1)) = munch_exp d e1

124

| munch_exp d (T.BINOP(T.MUL, T.CONST 0w1, e1)) = munch_exp d e1

125

| munch_exp d (T.BINOP(T.MUL, e1, T.CONST n)) = (munch_exp d e1) @ [X.IMUL(d, X.CONST n)]

126

| munch_exp d (T.BINOP(T.MUL, T.CONST n, e1)) = (munch_exp d e1) @ [X.IMUL(d, X.CONST n)]

127

| munch_exp d (T.BINOP(T.MUL, e1, e2)) =

128

let

129

val t1 = X.TEMP (Temp.new ("mul"))

130

in

131

(munch_exp d e1) @ (munch_exp t1 e2) @ [X.IMUL(d, t1)]

132

end

133

| munch_exp d (T.BINOP(T.DIV, e1, e2)) =

134

let

135

val t1 = X.TEMP (Temp.new ("div"))

136

in

137

(munch_exp t1 e1) @ (munch_exp d e2) @

138

[X.MOV (X.REG X.EAX, t1), X.CLTD, X.IDIV d, X.MOV (d, X.REG X.EAX)]

139

end

140

| munch_exp d (T.BINOP(T.MOD, e1, e2)) =

141

let

142

val t1 = X.TEMP (Temp.new ("mod"))

143

in

144

(munch_exp t1 e1) @ (munch_exp d e2) @

145

[X.MOV (X.REG X.EAX, t1), X.CLTD, X.IDIV d, X.MOV (d, X.REG X.EDX)]

146

end

147

| munch_exp d (T.BINOP(T.LSH, e1, T.CONST n)) = (munch_exp d e1) @ [X.SAL (d, X.CONST (n mod 0w32))]

148

| munch_exp d (T.BINOP(T.LSH, e1, T.TEMP t)) = (munch_exp d e1) @ [X.MOV (X.REG X.ECX, X.TEMP t), X.SAL (d, X.REG X.ECX)]

149

| munch_exp d (T.BINOP(T.LSH, e1, e2)) =

150

let

151

val t = X.TEMP (Temp.new ("lsh"))

152

in

153

(munch_exp d e1) @ (munch_exp t e2) @ [X.MOV (X.REG X.ECX, t), X.SAL (d, X.REG X.ECX)]

154

end

155

| munch_exp d (T.BINOP(T.RSH, e1, T.CONST n)) = (munch_exp d e1) @ [X.SAR (d, X.CONST (n mod 0w32))]

156

| munch_exp d (T.BINOP(T.RSH, e1, T.TEMP t)) = (munch_exp d e1) @ [X.MOV (X.REG X.ECX, X.TEMP t), X.SAR (d, X.REG X.ECX)]

157

| munch_exp d (T.BINOP(T.RSH, e1, e2)) =

158

let

159

val t = X.TEMP (Temp.new ("rsh"))

160

in

161

(munch_exp d e1) @ (munch_exp t e2) @ [X.MOV (X.REG X.ECX, t), X.SAR (d, X.REG X.ECX)]

162

end

163

| munch_exp d (T.BINOP(T.BITAND, T.CONST n, e1)) = (munch_exp d e1) @ [X.AND (d, X.CONST n)]

164

| munch_exp d (T.BINOP(T.BITAND, e1, T.CONST n)) = (munch_exp d e1) @ [X.AND (d, X.CONST n)]

165

| munch_exp d (T.BINOP(T.BITAND, T.TEMP t, e1)) = (munch_exp d e1) @ [X.AND (d, X.TEMP t)]

166

| munch_exp d (T.BINOP(T.BITAND, e1, T.TEMP t)) = (munch_exp d e1) @ [X.AND (d, X.TEMP t)]

167

| munch_exp d (T.BINOP(T.BITAND, e1, e2)) =

168

let

169

val t1 = X.TEMP (Temp.new ("bitand"))

170

in

171

(munch_exp d e1) @ (munch_exp t1 e2) @ [X.AND(d, t1)]

172

end

173

| munch_exp d (T.BINOP(T.BITOR, T.CONST n, e1)) = (munch_exp d e1) @ [X.OR (d, X.CONST n)]

174

| munch_exp d (T.BINOP(T.BITOR, e1, T.CONST n)) = (munch_exp d e1) @ [X.OR (d, X.CONST n)]

175

| munch_exp d (T.BINOP(T.BITOR, T.TEMP t, e1)) = (munch_exp d e1) @ [X.OR (d, X.TEMP t)]

176

| munch_exp d (T.BINOP(T.BITOR, e1, T.TEMP t)) = (munch_exp d e1) @ [X.OR (d, X.TEMP t)]

177

| munch_exp d (T.BINOP(T.BITOR, e1, e2)) =

178

let

179

val t1 = X.TEMP (Temp.new ("bitor"))

180

in

181

(munch_exp d e1) @ (munch_exp t1 e2) @ [X.OR(d, t1)]

182

end

183

| munch_exp d (T.BINOP(T.BITXOR, T.CONST n, e1)) = (munch_exp d e1) @ [X.XOR (d, X.CONST n)]

184

| munch_exp d (T.BINOP(T.BITXOR, e1, T.CONST n)) = (munch_exp d e1) @ [X.XOR (d, X.CONST n)]

185

| munch_exp d (T.BINOP(T.BITXOR, T.TEMP t, e1)) = (munch_exp d e1) @ [X.XOR (d, X.TEMP t)]

186

| munch_exp d (T.BINOP(T.BITXOR, e1, T.TEMP t)) = (munch_exp d e1) @ [X.XOR (d, X.TEMP t)]

187

| munch_exp d (T.BINOP(T.BITXOR, e1, e2)) =

188

let

189

val t1 = X.TEMP (Temp.new ("bitxor"))

190

in

191

(munch_exp d e1) @ (munch_exp t1 e2) @ [X.XOR(d, t1)]

192

end

193

| munch_exp d (a as T.BINOP(T.LOGAND, e1, e2)) =

194

let

195

val (insn1, pos1, neg1) = munch_cond e1

196

val (insn2, pos2, neg2) = munch_cond e2

197

val t1 = X.TEMP (Temp.new("logand 1"))

198

val t2 = X.TEMP (Temp.new("logand 2"))

199

val l = Label.new ()

200

in

201

if (effect e2 orelse (length insn2 > 10))

202

then (insn1) @

203

[X.SETcc(pos1, t1), X.Jcc (neg1, l)] @

204

(insn2) @

205

[X.SETcc(pos2, t1), X.LABEL l, X.MOVZB(d, t1)]

206

else insn1 @ [X.SETcc (pos1, t1)] @ insn2 @ [X.SETcc (pos2, t2), X.SIZE(X.Byte, X.AND(t1, t2)), X.MOVZB(d, t1)]

207

end

208

| munch_exp d (a as T.BINOP(T.LOGOR, e1, e2)) =

209

let

210

val (insn1, pos1, neg1) = munch_cond e1

211

val (insn2, pos2, neg2) = munch_cond e2

212

val t1 = X.TEMP (Temp.new("logor 1"))

213

val t2 = X.TEMP (Temp.new("logor 2"))

214

val l = Label.new ()

215

in

216

if (effect e2 orelse (length insn2 > 10))

217

then (insn1) @

218

[X.SETcc(pos1, t1), X.Jcc (pos1, l)] @

219

(insn2) @

220

[X.SETcc(pos2, t1), X.LABEL l, X.MOVZB(d, t1)]

221

else insn1 @ [X.SETcc (pos1, t1)] @ insn2 @ [X.SETcc (pos2, t2), X.SIZE(X.Byte, X.OR(t1, t2)), X.MOVZB(d, t1)]

222

end

223

| munch_exp d (a as T.BINOP(T.EQ, _, _)) =

224

let val (insns, pos, neg) = munch_cond a in insns @ [X.SETcc (pos, d), X.MOVZB(d, d)] end

225

| munch_exp d (a as T.BINOP(T.NEQ, _, _)) =

226

let val (insns, pos, neg) = munch_cond a in insns @ [X.SETcc (pos, d), X.MOVZB(d, d)] end

227

| munch_exp d (a as T.BINOP(T.LE, _, _)) =

228

let val (insns, pos, neg) = munch_cond a in insns @ [X.SETcc (pos, d), X.MOVZB(d, d)] end

229

| munch_exp d (a as T.BINOP(T.LT, _, _)) =

230

let val (insns, pos, neg) = munch_cond a in insns @ [X.SETcc (pos, d), X.MOVZB(d, d)] end

231

| munch_exp d (a as T.BINOP(T.GE, _, _)) =

232

let val (insns, pos, neg) = munch_cond a in insns @ [X.SETcc (pos, d), X.MOVZB(d, d)] end

233

| munch_exp d (a as T.BINOP(T.GT, _, _)) =

234

let val (insns, pos, neg) = munch_cond a in insns @ [X.SETcc (pos, d), X.MOVZB(d, d)] end

235

| munch_exp d (T.UNOP(T.NEG, T.CONST n)) = [X.MOV (d, X.CONST (~n))]

236

| munch_exp d (T.UNOP(T.NEG, e1)) = (munch_exp d e1) @ [X.NEG d]

237

| munch_exp d (T.UNOP(T.BITNOT, T.CONST n)) = [X.MOV (d, X.CONST (Word32.notb n))]

238

| munch_exp d (T.UNOP(T.BITNOT, e1)) = (munch_exp d e1) @ [X.NOT d]

239

| munch_exp d (T.UNOP(T.BANG, T.CONST n)) = if (n = 0w0) then [X.MOV (d, X.CONST 0w1)] else [X.MOV (d, X.CONST 0w0)]

240

| munch_exp d (T.UNOP(T.BANG, e)) =

241

let

242

val (insns, pos, neg) = munch_cond e

243

in

244

insns @ [X.SETcc (neg, d), X.MOVZB(d, d)]

245

end

246

(* munch_cond : T.exp -> X.insn list * X.cond * X.cond

247

* munch_cond stm generates code to set flags, and then returns a conditional

248

* to test if the expression was true and for if it was false.

249

*)

250

and munch_cond (T.UNOP (T.BANG, e)) =

251

let

252

val (insns, pos, neg) = munch_cond e

in

(insns, neg, pos)

end

| munch_cond (T.BINOP(T.NEQ, T.TEMP t, T.CONST n)) = ([X.CMP(X.TEMP t, X.CONST n)], X.NE, X.E)

257

| munch_cond (T.BINOP(T.NEQ, T.CONST n, T.TEMP t)) = ([X.CMP(X.TEMP t, X.CONST n)], X.NE, X.E)

258

| munch_cond (T.BINOP(T.NEQ, T.CONST n, e1)) =

259

let val t = X.TEMP (Temp.new ("const neq")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.NE, X.E) end

260

| munch_cond (T.BINOP(T.NEQ, e1, T.CONST n)) =

261

let val t = X.TEMP (Temp.new ("const neq")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.NE, X.E) end

262

| munch_cond (T.BINOP(T.NEQ, T.TEMP t, e1)) =

263

let val t1 = X.TEMP (Temp.new ("const neq")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.NE, X.E) end

264

| munch_cond (T.BINOP(T.NEQ, e1, T.TEMP t)) =

265

let val t1 = X.TEMP (Temp.new ("const neq")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.NE, X.E) end

266

| munch_cond (T.BINOP(T.NEQ, e1, e2)) =

267

let

268

val t1 = X.TEMP (Temp.new ("var neq 1"))

269

val t2 = X.TEMP (Temp.new ("var neq 2"))

270

in

271

(munch_exp t1 e1 @ munch_exp t2 e2 @

272

[X.CMP(t1, t2)], X.NE, X.E)

273

end

274

| munch_cond (T.BINOP(T.EQ, T.TEMP t, T.CONST n)) = ([X.CMP(X.TEMP t, X.CONST n)], X.E, X.NE)

275

| munch_cond (T.BINOP(T.EQ, T.CONST n, T.TEMP t)) = ([X.CMP(X.TEMP t, X.CONST n)], X.E, X.NE)

276

| munch_cond (T.BINOP(T.EQ, T.CONST n, e1)) =

277

let val t = X.TEMP (Temp.new ("const eq")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.E, X.NE) end

278

| munch_cond (T.BINOP(T.EQ, e1, T.CONST n)) =

279

let val t = X.TEMP (Temp.new ("const eq")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.E, X.NE) end

280

| munch_cond (T.BINOP(T.EQ, T.TEMP t, e1)) =

281

let val t1 = X.TEMP (Temp.new ("const eq")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.E, X.NE) end

282

| munch_cond (T.BINOP(T.EQ, e1, T.TEMP t)) =

283

let val t1 = X.TEMP (Temp.new ("const eq")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.E, X.NE) end

284

| munch_cond (T.BINOP(T.EQ, e1, e2)) =

285

let

286

val t1 = X.TEMP (Temp.new ("var eq 1"))

287

val t2 = X.TEMP (Temp.new ("var eq 2"))

288

in

289

(munch_exp t1 e1 @ munch_exp t2 e2 @

290

[X.CMP(t1, t2)], X.E, X.NE)

291

end

292

| munch_cond (T.BINOP(T.LE, T.TEMP t, T.CONST n)) = ([X.CMP(X.TEMP t, X.CONST n)], X.LE, X.G)

293

| munch_cond (T.BINOP(T.LE, T.CONST n, T.TEMP t)) = ([X.CMP(X.TEMP t, X.CONST n)], X.GE, X.L)

294

| munch_cond (T.BINOP(T.LE, T.CONST n, e1)) =

295

let val t = X.TEMP (Temp.new ("const le")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.GE, X.L) end

296

| munch_cond (T.BINOP(T.LE, e1, T.CONST n)) =

297

let val t = X.TEMP (Temp.new ("const le")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.LE, X.G) end

298

| munch_cond (T.BINOP(T.LE, T.TEMP t, e1)) =

299

let val t1 = X.TEMP (Temp.new ("const le")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.GE, X.L) end

300

| munch_cond (T.BINOP(T.LE, e1, T.TEMP t)) =

301

let val t1 = X.TEMP (Temp.new ("const le")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.LE, X.G) end

302

| munch_cond (T.BINOP(T.LE, e1, e2)) =

303

let

304

val t1 = X.TEMP (Temp.new ("var le 1"))

305

val t2 = X.TEMP (Temp.new ("var le 2"))

306

in

307

(munch_exp t1 e1 @ munch_exp t2 e2 @

308

[X.CMP(t1, t2)], X.LE, X.G)

309

end

310

| munch_cond (T.BINOP(T.LT, T.TEMP t, T.CONST n)) = ([X.CMP(X.TEMP t, X.CONST n)], X.L, X.GE)

311

| munch_cond (T.BINOP(T.LT, T.CONST n, T.TEMP t)) = ([X.CMP(X.TEMP t, X.CONST n)], X.G, X.LE)

312

| munch_cond (T.BINOP(T.LT, T.CONST n, e1)) =

313

let val t = X.TEMP (Temp.new ("const lt")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.G, X.LE) end

314

| munch_cond (T.BINOP(T.LT, e1, T.CONST n)) =

315

let val t = X.TEMP (Temp.new ("const lt")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.L, X.GE) end

316

| munch_cond (T.BINOP(T.LT, T.TEMP t, e1)) =

317

let val t1 = X.TEMP (Temp.new ("const lt")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.G, X.LE) end

318

| munch_cond (T.BINOP(T.LT, e1, T.TEMP t)) =

319

let val t1 = X.TEMP (Temp.new ("const lt")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.L, X.GE) end

320

| munch_cond (T.BINOP(T.LT, e1, e2)) =

321

let

322

val t1 = X.TEMP (Temp.new ("var lt 1"))

323

val t2 = X.TEMP (Temp.new ("var lt 2"))

324

in

325

(munch_exp t1 e1 @ munch_exp t2 e2 @

326

[X.CMP(t1, t2)], X.L, X.GE)

327

end

328

| munch_cond (T.BINOP(T.GT, T.TEMP t, T.CONST n)) = ([X.CMP(X.TEMP t, X.CONST n)], X.G, X.LE)

329

| munch_cond (T.BINOP(T.GT, T.CONST n, T.TEMP t)) = ([X.CMP(X.TEMP t, X.CONST n)], X.L, X.GE)

330

| munch_cond (T.BINOP(T.GT, e1, T.CONST n)) =

331

let val t = X.TEMP (Temp.new ("const gt")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.G, X.LE) end

332

| munch_cond (T.BINOP(T.GT, T.CONST n, e1)) =

333

let val t = X.TEMP (Temp.new ("const gt")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.L, X.GE) end

334

| munch_cond (T.BINOP(T.GT, e1, T.TEMP t)) =

335

let val t1 = X.TEMP (Temp.new ("const gt")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.G, X.LE) end

336

| munch_cond (T.BINOP(T.GT, T.TEMP t, e1)) =

337

let val t1 = X.TEMP (Temp.new ("const gt")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.L, X.GE) end

338

| munch_cond (T.BINOP(T.GT, e1, e2)) =

339

let

340

val t1 = X.TEMP (Temp.new ("var gt 1"))

341

val t2 = X.TEMP (Temp.new ("var gt 2"))

342

in

343

(munch_exp t1 e1 @ munch_exp t2 e2 @

344

[X.CMP(t1, t2)], X.G, X.LE)

345

end

346

| munch_cond (T.BINOP(T.GE, T.TEMP t, T.CONST n)) = ([X.CMP(X.TEMP t, X.CONST n)], X.GE, X.L)

347

| munch_cond (T.BINOP(T.GE, T.CONST n, T.TEMP t)) = ([X.CMP(X.TEMP t, X.CONST n)], X.LE, X.G)

348

| munch_cond (T.BINOP(T.GE, e1, T.CONST n)) =

349

let val t = X.TEMP (Temp.new ("const ge")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.GE, X.L) end

350

| munch_cond (T.BINOP(T.GE, T.CONST n, e1)) =

351

let val t = X.TEMP (Temp.new ("const ge")) in (munch_exp t e1 @ [X.CMP(t, X.CONST n)], X.LE, X.G) end

352

| munch_cond (T.BINOP(T.GE, e1, T.TEMP t)) =

353

let val t1 = X.TEMP (Temp.new ("const ge")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.GE, X.L) end

354

| munch_cond (T.BINOP(T.GE, T.TEMP t, e1)) =

355

let val t1 = X.TEMP (Temp.new ("const ge")) in (munch_exp t1 e1 @ [X.CMP(t1, X.TEMP t)], X.LE, X.G) end

356

| munch_cond (T.BINOP(T.GE, e1, e2)) =

357

let

358

val t1 = X.TEMP (Temp.new ("var ge 1"))

359

val t2 = X.TEMP (Temp.new ("var ge 2"))

360

in

361

(munch_exp t1 e1 @ munch_exp t2 e2 @

362

[X.CMP(t1, t2)], X.GE, X.L)

363

end

364

| munch_cond (T.BINOP(T.LOGOR, e1, e2)) =

365

let

366

val (insn1, pos1, neg1) = munch_cond e1

367

val (insn2, pos2, neg2) = munch_cond e2

368

val t1 = X.TEMP (Temp.new("logor c 1"))

369

val t2 = X.TEMP (Temp.new("logor c 2"))

370

val l = Label.new ()

371

in

372

if (effect e2 orelse (length insn2 > 10))

373

then ((insn1) @

374

[X.SETcc (pos1, t1), X.Jcc (pos1, l)] @

375

(insn2) @

376

[X.SETcc (pos2, t1), X.LABEL l, X.SIZE (X.Byte, X.TEST (t1, t1))],

377

X.NE, X.E)

378

else (insn1 @ [X.SETcc (pos1, t1)] @ insn2 @ [X.SETcc (pos2, t2), X.SIZE(X.Byte, X.OR(t1, t2))], X.NE, X.E)

379

end

380

| munch_cond (T.BINOP(T.LOGAND, e1, e2)) =

381

let

382

val (insn1, pos1, neg1) = munch_cond e1

383

val (insn2, pos2, neg2) = munch_cond e2

384

val t1 = X.TEMP (Temp.new("logand c 1"))

385

val t2 = X.TEMP (Temp.new("logand c 2"))

386

val l = Label.new ()

387

in

388

if (effect e2 orelse (length insn2 > 10))

389

then ((insn1) @

390

[X.SETcc (pos1, t1), X.Jcc (neg1, l)] @

391

(insn2) @

392

[X.SETcc (pos2, t1), X.LABEL l, X.SIZE (X.Byte, X.TEST (t1, t1))],

393

X.NE, X.E)

394

else (insn1 @ [X.SETcc (pos1, t1)] @ insn2 @ [X.SETcc (pos2, t2), X.SIZE(X.Byte, X.AND(t1, t2))], X.NE, X.E)

end

| munch_cond e =

let

val t = X.TEMP (Temp.new ("munch c"))

399

in

400

(munch_exp t e @ [ X.TEST (t,t) ], X.NE, X.E)

401

end

402

403

(* munch_stm : T.stm -> X.insn list *)

404

(* munch_stm stm generates code to execute stm *)

405

fun munch_stm (T.MOVE (T.TEMP t, a as T.TEMP _)) = munch_exp (X.TEMP t) a

406

| munch_stm (T.MOVE (T.TEMP t, a as T.CONST _)) = munch_exp (X.TEMP t) a

407

| munch_stm (T.MOVE (T.TEMP t, a as T.ARG _)) = munch_exp (X.TEMP t) a

408

| munch_stm (T.MOVE (T.TEMP t, a as T.CALL _)) = munch_exp (X.TEMP t) a

409

| munch_stm (T.MOVE(T.TEMP t1, e2)) =

410

let

411

val t = Temp.new ("assign")

412

in

413

munch_exp (X.TEMP t) e2

414

@ [X.MOV(X.TEMP t1, X.TEMP t)]

415

end

416

| munch_stm (T.MOVE(_, _)) =

417

raise ErrorMsg.InternalError "Incorrect first operand for T.MOVE?"

418

| munch_stm (T.RETURN(e)) =

419

let

420

val t = Temp.new ("retval")

421

in

422

munch_exp (X.TEMP t) e

423

@ [X.MOV(X.REG X.EAX, X.TEMP t), X.RET]

424

end

425

| munch_stm (T.LABEL(l)) = [X.LABEL l]

426

| munch_stm (T.JUMP(l)) = [X.JMP l]

427

| munch_stm (T.JUMPIFN(e, l)) =

428

let

429

val (insns, pos, neg) = munch_cond e

430

in

431

insns @ [X.Jcc (neg, l)]

432

end

433

434

fun codegen nil = nil

435

| codegen (stm::stms) = munch_stm stm @ codegen stms

436

end