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|
open Ir
let remap_register_reg sb r =
try
Hashtbl.find sb r
with Not_found ->
r
let remap_register_expr sb = function
| E_Reg r -> E_Reg (remap_register_reg sb r)
| e -> e
let remap_register_instr sb = function
| I_Add (r0, r1, r2) ->
let r0 = remap_register_reg sb r0 in
let r1 = remap_register_expr sb r1 in
let r2 = remap_register_expr sb r2 in
I_Add (r0, r1, r2)
| I_Sub (r0, r1, r2) ->
let r0 = remap_register_reg sb r0 in
let r1 = remap_register_expr sb r1 in
let r2 = remap_register_expr sb r2 in
I_Sub (r0, r1, r2)
| I_Div (r0, r1, r2) ->
let r0 = remap_register_reg sb r0 in
let r1 = remap_register_expr sb r1 in
let r2 = remap_register_expr sb r2 in
I_Div (r0, r1, r2)
| I_Rem (r0, r1, r2) ->
let r0 = remap_register_reg sb r0 in
let r1 = remap_register_expr sb r1 in
let r2 = remap_register_expr sb r2 in
I_Rem (r0, r1, r2)
| I_Mul(r0, r1, r2) ->
let r0 = remap_register_reg sb r0 in
let r1 = remap_register_expr sb r1 in
let r2 = remap_register_expr sb r2 in
I_Mul (r0, r1, r2)
| I_And(r0, r1, r2) ->
let r0 = remap_register_reg sb r0 in
let r1 = remap_register_expr sb r1 in
let r2 = remap_register_expr sb r2 in
I_And(r0, r1, r2)
| I_Or(r0, r1, r2) ->
let r0 = remap_register_reg sb r0 in
let r1 = remap_register_expr sb r1 in
let r2 = remap_register_expr sb r2 in
I_Or(r0, r1, r2)
| I_Xor(r0, r1, r2) ->
let r0 = remap_register_reg sb r0 in
let r1 = remap_register_expr sb r1 in
let r2 = remap_register_expr sb r2 in
I_Xor(r0, r1, r2)
| I_LoadArray(r0, r1, r2) ->
let r0 = remap_register_reg sb r0 in
let r1 = remap_register_expr sb r1 in
let r2 = remap_register_expr sb r2 in
I_LoadArray(r0, r1, r2)
| I_StoreArray(r0, r1, r2) ->
let r0 = remap_register_expr sb r0 in
let r1 = remap_register_expr sb r1 in
let r2 = remap_register_expr sb r2 in
I_StoreArray(r0, r1, r2)
| I_LoadMem(r0, r1, r2) ->
let r0 = remap_register_reg sb r0 in
let r1 = remap_register_expr sb r1 in
let r2 = remap_register_expr sb r2 in
I_LoadMem(r0, r1, r2)
| I_StoreMem(r0, r1, r2) ->
let r0 = remap_register_expr sb r0 in
let r1 = remap_register_expr sb r1 in
let r2 = remap_register_expr sb r2 in
I_StoreMem(r0, r1, r2)
| I_Concat(r0, r1, r2) ->
let r0 = remap_register_reg sb r0 in
let r1 = remap_register_expr sb r1 in
let r2 = remap_register_expr sb r2 in
I_Concat(r0, r1, r2)
| I_Neg(r0, r1) ->
let r0 = remap_register_reg sb r0 in
let r1 = remap_register_expr sb r1 in
I_Neg(r0, r1)
| I_Not(r0, r1) ->
let r0 = remap_register_reg sb r0 in
let r1 = remap_register_expr sb r1 in
I_Not(r0, r1)
| I_Move(r0, r1) ->
let r0 = remap_register_reg sb r0 in
let r1 = remap_register_expr sb r1 in
I_Move(r0, r1)
| I_Length(r0, r1) ->
let r0 = remap_register_reg sb r0 in
let r1 = remap_register_expr sb r1 in
I_Length(r0, r1)
| I_NewArray(r0, r1) ->
let r0 = remap_register_reg sb r0 in
let r1 = remap_register_expr sb r1 in
I_NewArray(r0, r1)
| I_Set(r0, cond, r1, r2) ->
let r0 = remap_register_reg sb r0 in
let r1 = remap_register_expr sb r1 in
let r2 = remap_register_expr sb r2 in
I_Set(r0, cond, r1, r2)
| I_LoadVar(r0, i) ->
let r0 = remap_register_reg sb r0 in
I_LoadVar(r0, i)
| I_StoreVar(i, r0) ->
let r0 = remap_register_expr sb r0 in
I_StoreVar(i, r0)
| I_LoadStack(r0, i) ->
let r0 = remap_register_reg sb r0 in
I_LoadStack(r0, i)
| I_StoreStack(i, r0) ->
let r0 = remap_register_expr sb r0 in
I_StoreStack(i, r0)
| I_StackAlloc i ->
I_StackAlloc i
| I_StackFree i ->
I_StackFree i
| I_Use rs ->
I_Use (List.map (remap_register_reg sb) rs)
| I_Def rs ->
I_Def (List.map (remap_register_reg sb) rs)
| I_Call (rs, procid, args, kills) ->
let rs = List.map (remap_register_reg sb) rs in
let args = List.map (remap_register_expr sb) args in
let kills = List.map (remap_register_reg sb) kills in
I_Call (rs, procid, args, kills)
let subst_expr rmap = function
| (E_Reg r) as e ->
begin match RegMap.find_opt r rmap with
| None -> e
| Some e -> e
end
| e -> e
let subst_expr_instr sb = function
| I_Add (r0, r1, r2) ->
let r1 = subst_expr sb r1 in
let r2 = subst_expr sb r2 in
I_Add (r0, r1, r2)
| I_Sub (r0, r1, r2) ->
let r1 = subst_expr sb r1 in
let r2 = subst_expr sb r2 in
I_Sub (r0, r1, r2)
| I_Div (r0, r1, r2) ->
let r1 = subst_expr sb r1 in
let r2 = subst_expr sb r2 in
I_Div (r0, r1, r2)
| I_Rem (r0, r1, r2) ->
let r1 = subst_expr sb r1 in
let r2 = subst_expr sb r2 in
I_Rem (r0, r1, r2)
| I_Mul(r0, r1, r2) ->
let r1 = subst_expr sb r1 in
let r2 = subst_expr sb r2 in
I_Mul (r0, r1, r2)
| I_And(r0, r1, r2) ->
let r1 = subst_expr sb r1 in
let r2 = subst_expr sb r2 in
I_And(r0, r1, r2)
| I_Or(r0, r1, r2) ->
let r1 = subst_expr sb r1 in
let r2 = subst_expr sb r2 in
I_Or(r0, r1, r2)
| I_Xor(r0, r1, r2) ->
let r1 = subst_expr sb r1 in
let r2 = subst_expr sb r2 in
I_Xor(r0, r1, r2)
| I_LoadArray(r0, r1, r2) ->
let r1 = subst_expr sb r1 in
let r2 = subst_expr sb r2 in
I_LoadArray(r0, r1, r2)
| I_StoreArray(r0, r1, r2) ->
let r0 = subst_expr sb r0 in
let r1 = subst_expr sb r1 in
let r2 = subst_expr sb r2 in
I_StoreArray(r0, r1, r2)
| I_LoadMem(r0, r1, r2) ->
let r1 = subst_expr sb r1 in
let r2 = subst_expr sb r2 in
I_LoadMem(r0, r1, r2)
| I_StoreMem(r0, r1, r2) ->
let r0 = subst_expr sb r0 in
let r1 = subst_expr sb r1 in
let r2 = subst_expr sb r2 in
I_StoreMem(r0, r1, r2)
| I_Concat(r0, r1, r2) ->
let r1 = subst_expr sb r1 in
let r2 = subst_expr sb r2 in
I_Concat(r0, r1, r2)
| I_Neg(r0, r1) ->
let r1 = subst_expr sb r1 in
I_Neg(r0, r1)
| I_Not(r0, r1) ->
let r1 = subst_expr sb r1 in
I_Not(r0, r1)
| I_Move(r0, r1) ->
let r1 = subst_expr sb r1 in
I_Move(r0, r1)
| I_Length(r0, r1) ->
let r1 = subst_expr sb r1 in
I_Length(r0, r1)
| I_NewArray(r0, r1) ->
let r1 = subst_expr sb r1 in
I_NewArray(r0, r1)
| I_Set(r0, cond, r1, r2) ->
let r1 = subst_expr sb r1 in
let r2 = subst_expr sb r2 in
I_Set(r0, cond, r1, r2)
| I_LoadVar(r0, i) ->
I_LoadVar(r0, i)
| I_StoreVar(i, r0) ->
let r0 = subst_expr sb r0 in
I_StoreVar(i, r0)
| I_LoadStack(r0, i) ->
I_LoadStack(r0, i)
| I_StoreStack(i, r0) ->
let r0 = subst_expr sb r0 in
I_StoreStack(i, r0)
| I_StackAlloc i ->
I_StackAlloc i
| I_StackFree i ->
I_StackFree i
| I_Use rs ->
I_Use rs
| I_Def rs ->
I_Def rs
| I_Call (rs, procid, args, kills) ->
let args = List.map (subst_expr sb) args in
I_Call (rs, procid, args, kills)
let remap_label_label sb l =
try
Hashtbl.find sb l
with Not_found ->
l
let remap_label_terminator sb = function
| T_Jump l ->
T_Jump (remap_label_label sb l)
| T_Branch (cond, r0, r1, lt, lf) ->
T_Branch (cond, r0, r1, remap_label_label sb lt, remap_label_label sb lf)
| t ->
t
let remap_register_terminator sb = function
| T_Return xs ->
let xs = List.map (remap_register_expr sb) xs in
T_Return xs
| T_Branch (cond, r0, r1, l1, l2) ->
let r0 = remap_register_expr sb r0 in
let r1 = remap_register_expr sb r1 in
T_Branch (cond, r0, r1, l1, l2)
| T_Jump l ->
T_Jump l
let subst_expr_terminator sb = function
| T_Return xs ->
let xs = List.map (subst_expr sb) xs in
T_Return xs
| T_Branch (cond, r0, r1, l1, l2) ->
let r0 = subst_expr sb r0 in
let r1 = subst_expr sb r1 in
T_Branch (cond, r0, r1, l1, l2)
| T_Jump l ->
T_Jump l
let defined_registers_instr = function
| I_Add (r0, _, _)
| I_Sub (r0, _, _)
| I_Div (r0, _, _)
| I_Mul (r0, _, _)
| I_And (r0, _, _)
| I_Or (r0, _, _)
| I_Xor (r0, _, _)
| I_LoadArray (r0, _, _)
| I_LoadMem (r0, _, _)
| I_Concat (r0, _, _)
| I_Not (r0, _)
| I_Move (r0, _)
| I_Length (r0, _)
| I_NewArray (r0, _)
| I_Neg (r0, _)
| I_Set (r0, _, _, _)
| I_Rem (r0, _, _)
| I_LoadStack (r0, _)
| I_LoadVar (r0, _) ->
[r0]
| I_Call (outs, _, _, kills) ->
outs @ kills
| I_Use _
| I_StoreVar _
| I_StoreStack _
| I_StackAlloc _
| I_StackFree _
| I_StoreMem _
| I_StoreArray _ ->
[]
| I_Def rs ->
rs
let defined_registers_terminator _ = []
let used_registers_instr = function
| I_Add (_, r0, r1)
| I_Sub (_, r0, r1)
| I_Div (_, r0, r1)
| I_Mul (_, r0, r1)
| I_And (_, r0, r1)
| I_Or (_, r0, r1)
| I_Xor (_, r0, r1)
| I_LoadArray (_, r0, r1)
| I_LoadMem (_, r0, r1)
| I_Concat (_, r0, r1)
| I_Set (_, _, r0, r1)
| I_Rem (_, r0, r1) ->
List.flatten @@ List.map reglist_of_expr [r0;r1]
| I_Not (_, r0)
| I_Move (_, r0)
| I_Length (_, r0)
| I_NewArray (_, r0)
| I_StoreVar (_, r0)
| I_StoreStack (_, r0)
| I_Neg (_, r0) ->
reglist_of_expr r0
| I_Call (_, _, args, _) ->
List.flatten @@ List.map reglist_of_expr args
| I_Def _
| I_StackAlloc _
| I_StackFree _
| I_LoadStack _
| I_LoadVar _ ->
[]
| I_StoreArray (r0, r1, r2)
| I_StoreMem (r0, r1, r2) ->
List.flatten @@ List.map reglist_of_expr [r0; r1; r2]
| I_Use rs ->
rs
let used_registers_terminator = function
| T_Branch (_, r0, r1, _, _) ->
List.flatten @@ List.map reglist_of_expr [r0;r1]
| T_Return args ->
List.flatten @@ List.map reglist_of_expr args
| T_Jump _ ->
[]
let remap_registers_proc sb proc =
let cfg = (cfg_of_procedure proc) in
let remap_block (l, body, terminator) =
let body = List.map (remap_register_instr sb) body in
let terminator = remap_register_terminator sb terminator in
(l, body, terminator)
in
let update_blocks (l, body, terminator) =
ControlFlowGraph.set_block2 cfg l body terminator
in
let blocks = ControlFlowGraph.blocklist2 cfg in
let blocks = List.map remap_block blocks in
List.iter update_blocks blocks
let string_of_expr = function
| E_Reg r -> string_of_reg r
| E_Int i -> Int32.to_string i
let string_of_label = function
| Label i -> Format.sprintf "L%u" i
let string_of_procid = function
| Procid l -> Format.sprintf "%s" l
let string_of_reglist xs =
Format.sprintf "[%s]" (String.concat ", " @@ List.map string_of_reg xs)
let string_of_labellist xs =
Format.sprintf "[%s]" (String.concat ", " @@ List.map string_of_label xs)
let string_of_exprlist xs =
Format.sprintf "[%s]" (String.concat ", " @@ List.map string_of_expr xs)
let string_of_expr_regmap k =
let f (k, v) = Format.sprintf "%s=%s" (string_of_reg k) (string_of_expr v) in
String.concat "; " @@ List.of_seq @@ Seq.map f @@ RegMap.to_seq k
let string_of_instr = function
| I_Add (r0, e0, e1) ->
Format.sprintf "add %s, %s, %s"
(string_of_reg r0)
(string_of_expr e0)
(string_of_expr e1)
| I_Sub (r0, e0, e1) ->
Format.sprintf "sub %s, %s, %s"
(string_of_reg r0)
(string_of_expr e0)
(string_of_expr e1)
| I_Div (r0, e0, e1) ->
Format.sprintf "div %s, %s, %s"
(string_of_reg r0)
(string_of_expr e0)
(string_of_expr e1)
| I_Rem (r0, e0, e1) ->
Format.sprintf "rem %s, %s, %s"
(string_of_reg r0)
(string_of_expr e0)
(string_of_expr e1)
| I_Mul (r0, e0, e1) ->
Format.sprintf "mul %s, %s, %s"
(string_of_reg r0)
(string_of_expr e0)
(string_of_expr e1)
| I_And (r0, e0, e1) ->
Format.sprintf "and %s, %s, %s"
(string_of_reg r0)
(string_of_expr e0)
(string_of_expr e1)
| I_Or (r0, e0, e1) ->
Format.sprintf "or %s, %s, %s"
(string_of_reg r0)
(string_of_expr e0)
(string_of_expr e1)
| I_Xor (r0, e0, e1) ->
Format.sprintf "xor %s, %s, %s"
(string_of_reg r0)
(string_of_expr e0)
(string_of_expr e1)
| I_LoadArray (r0, e0, e1) ->
Format.sprintf "loadarray %s, %s, %s // %s = %s[%s]"
(string_of_reg r0)
(string_of_expr e0)
(string_of_expr e1)
(string_of_reg r0)
(string_of_expr e0)
(string_of_expr e1)
| I_LoadMem (r0, e0, e1) ->
Format.sprintf "loadmem %s, %s, %s // %s = mem[%s + %s]"
(string_of_reg r0)
(string_of_expr e0)
(string_of_expr e1)
(string_of_reg r0)
(string_of_expr e0)
(string_of_expr e1)
| I_StoreArray (r0, e0, e1) ->
Format.sprintf "storearray %s, %s, %s // %s[%s] = %s"
(string_of_expr r0)
(string_of_expr e0)
(string_of_expr e1)
(string_of_expr r0)
(string_of_expr e0)
(string_of_expr e1)
| I_StoreMem (r0, e0, e1) ->
Format.sprintf "storemem %s, %s, %s // mem[%s + %s] = %s"
(string_of_expr r0)
(string_of_expr e0)
(string_of_expr e1)
(string_of_expr r0)
(string_of_expr e0)
(string_of_expr e1)
| I_Concat (r0, e0, e1) ->
Format.sprintf "concat %s, %s, %s"
(string_of_reg r0)
(string_of_expr e0)
(string_of_expr e1)
| I_Neg (r0, e0) ->
Format.sprintf "neg %s, %s"
(string_of_reg r0)
(string_of_expr e0)
| I_Not (r0, e0) ->
Format.sprintf "not %s, %s"
(string_of_reg r0)
(string_of_expr e0)
| I_Length (r0, e0) ->
Format.sprintf "length %s, %s"
(string_of_reg r0)
(string_of_expr e0)
| I_Move (r0, e0) ->
Format.sprintf "move %s, %s"
(string_of_reg r0)
(string_of_expr e0)
| I_NewArray (r0, e0) ->
Format.sprintf "newarray %s, %s"
(string_of_reg r0)
(string_of_expr e0)
| I_Call (rs, p, xs, kill) ->
Format.sprintf "call %s, %s, %s, kill %s"
(string_of_reglist rs)
(string_of_procid p)
(string_of_exprlist xs)
(string_of_reglist kill)
| I_Set (rr, cond, r0, r1) ->
Format.sprintf "set %s, %s, %s, %s"
(string_of_reg rr)
(string_of_cond cond)
(string_of_expr r0)
(string_of_expr r1)
| I_StoreVar (i0, e0) ->
Format.sprintf "storevar %s, %s"
(string_of_int i0)
(string_of_expr e0)
| I_LoadVar (r0, i0) ->
Format.sprintf "loadvar %s, %s"
(string_of_reg r0)
(string_of_int i0)
| I_StoreStack (i0, e0) ->
Format.sprintf "storestack %s, %s"
(string_of_int i0)
(string_of_expr e0)
| I_LoadStack (r0, i0) ->
Format.sprintf "loadstack %s, %s"
(string_of_reg r0)
(string_of_int i0)
| I_StackAlloc (i0) ->
Format.sprintf "stackalloc %s"
(Int32.to_string i0)
| I_StackFree (i0) ->
Format.sprintf "stackfree %s"
(Int32.to_string i0)
| I_Use rs ->
Format.sprintf "use %s" (string_of_reglist rs)
| I_Def rs ->
Format.sprintf "def %s" (string_of_reglist rs)
let string_of_terminator = function
| T_Branch (cond, r0, r1, l1, l2) ->
Format.sprintf "branch %s, %s, %s, %s, %s"
(string_of_cond cond)
(string_of_expr r0)
(string_of_expr r1)
(string_of_label l1)
(string_of_label l2)
| T_Jump (l) ->
Format.sprintf "jump %s"
(string_of_label l)
| T_Return xs ->
Format.sprintf "return %s"
(string_of_exprlist xs)
let indented_string_of_instr i = " " ^ (string_of_instr i)
let indented_string_of_terminator i = " " ^ (string_of_terminator i)
let string_of_block_body cfg label body =
String.concat "\n"
[ Format.sprintf "%s:" (string_of_label label)
; Format.sprintf " cfg successors: %s"
(string_of_labellist @@ ControlFlowGraph.successors cfg label)
; Format.sprintf " cfg predecessors: %s"
(string_of_labellist @@ ControlFlowGraph.predecessors cfg label)
; String.concat "\n" (List.map indented_string_of_instr body)
]
let string_of_block cfg k v =
let terminator = match ControlFlowGraph.terminator_safe cfg k with
| None -> "<<no terminator>>"
| Some t -> indented_string_of_terminator t
in
String.concat "\n"
[ string_of_block_body cfg k v
; terminator
]
let string_of_blockmap cfg =
let f xs (k, v) = string_of_block cfg k v :: xs in
let items = Seq.fold_left (fun xs x -> x::xs) [] (Hashtbl.to_seq @@ ControlFlowGraph.blockmap cfg) in
let items = List.sort compare items in
String.concat "\n" @@ List.rev @@ List.fold_left f [] items
let string_of_cfg cfg =
String.concat "\n"
[ Format.sprintf " cfg entry point: %s" (string_of_label @@ ControlFlowGraph.entry_label cfg)
; Format.sprintf " cfg entry point successors: %s"
(string_of_labellist @@ ControlFlowGraph.successors cfg @@ ControlFlowGraph.entry_label cfg)
; Format.sprintf " cfg exit point: %s" (string_of_label @@ ControlFlowGraph.exit_label cfg)
; Format.sprintf " cfg exit point predecessors : %s"
(string_of_labellist @@ ControlFlowGraph.predecessors cfg @@ ControlFlowGraph.exit_label cfg)
; string_of_blockmap cfg
]
let string_of_procedure (Procedure {procid; cfg; frame_size; formal_parameters; _}) =
String.concat "\n"
[ "////////////////////////////////////// "
; Format.sprintf "procedure %s" (string_of_procid procid)
; Format.sprintf " frame size: %u" frame_size
; Format.sprintf " formal parameters: %u" formal_parameters
; string_of_cfg cfg
]
let string_of_module_definition xs =
String.concat "\n" @@ List.map string_of_procedure xs
let string_of_program (Program {procedures; _}) =
String.concat "\n" @@ List.map string_of_procedure procedures
|
