%% -*- erlang-indent-level: 2 -*-
%%
%% Licensed under the Apache License, Version 2.0 (the "License");
%% you may not use this file except in compliance with the License.
%% You may obtain a copy of the License at
%%
%% http://www.apache.org/licenses/LICENSE-2.0
%%
%% Unless required by applicable law or agreed to in writing, software
%% distributed under the License is distributed on an "AS IS" BASIS,
%% WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
%% See the License for the specific language governing permissions and
%% limitations under the License.
-ifdef(HIPE_AMD64).
-define(HIPE_X86_SUBST, hipe_amd64_subst).
-else.
-define(HIPE_X86_SUBST, hipe_x86_subst).
-endif.
-module(?HIPE_X86_SUBST).
-export([insn_temps/2]).
-include("../x86/hipe_x86.hrl").
%% These should be moved to hipe_x86 and exported
-type temp() :: #x86_temp{}.
-type oper() :: temp() | #x86_imm{} | #x86_mem{}.
-type mfarec() :: #x86_mfa{}.
-type prim() :: #x86_prim{}.
-type funv() :: mfarec() | prim() | temp().
-type insn() :: tuple(). % for now
-type subst_fun() :: fun((temp()) -> temp()).
%% @doc Maps over the temporaries in an instruction
-spec insn_temps(subst_fun(), insn()) -> insn().
insn_temps(SubstTemp, I) ->
O = fun(O) -> oper_temps(SubstTemp, O) end,
case I of
#alu {src=S, dst=D} -> I#alu {src=O(S), dst=O(D)};
#cmovcc {src=S, dst=D} -> I#cmovcc {src=O(S), dst=O(D)};
#cmp {src=S, dst=D} -> I#cmp {src=O(S), dst=O(D)};
#fmove {src=S, dst=D} -> I#fmove {src=O(S), dst=O(D)};
#fp_binop{src=S, dst=D} -> I#fp_binop{src=O(S), dst=O(D)};
#imul {src=S, temp=T} -> I#imul {src=O(S), temp=O(T)};
#lea {mem=M, temp=T} -> I#lea {mem=O(M), temp=O(T)};
#move {src=S, dst=D} -> I#move {src=O(S), dst=O(D)};
#movsx {src=S, dst=D} -> I#movsx {src=O(S), dst=O(D)};
#movzx {src=S, dst=D} -> I#movzx {src=O(S), dst=O(D)};
#shift {src=S, dst=D} -> I#shift {src=O(S), dst=O(D)};
#test {src=S, dst=D} -> I#test {src=O(S), dst=O(D)};
#fp_unop{arg=A} -> I#fp_unop{arg=O(A)};
#move64 {dst=D} -> I#move64 {dst=O(D)};
#push {src=S} -> I#push {src=O(S)};
#pop {dst=D} -> I#pop {dst=O(D)};
#jmp_switch{temp=T, jtab=J} ->
I#jmp_switch{temp=O(T), jtab=jtab_temps(SubstTemp, J)};
#pseudo_call{'fun'=F} ->
I#pseudo_call{'fun'=funv_temps(SubstTemp, F)};
#pseudo_tailcall{'fun'=F, stkargs=Stk} ->
I#pseudo_tailcall{'fun'=funv_temps(SubstTemp, F),
stkargs=lists:map(O, Stk)};
#comment{} -> I;
#jmp_label{} -> I;
#pseudo_tailcall_prepare{} -> I;
#pseudo_jcc{} -> I;
#ret{} -> I
end.
-spec oper_temps(subst_fun(), oper()) -> oper().
oper_temps(_SubstTemp, I=#x86_imm{}) -> I;
oper_temps(SubstTemp, T=#x86_temp{}) -> SubstTemp(T);
oper_temps(SubstTemp, M=#x86_mem{base=Base,off=Off}) ->
M#x86_mem{base=oper_temps(SubstTemp, Base),
off =oper_temps(SubstTemp, Off)}.
-spec funv_temps(subst_fun(), funv()) -> funv().
funv_temps(_SubstTemp, MFA=#x86_mfa{}) -> MFA;
funv_temps(_SubstTemp, P=#x86_prim{}) -> P;
funv_temps(SubstTemp, T=#x86_temp{}) -> SubstTemp(T).
%% TODO: Undo this ifdeffery at the source (make jtab an #x86_imm{} on x86)
-ifdef(HIPE_AMD64).
jtab_temps(SubstTemp, T=#x86_temp{}) -> SubstTemp(T).
-else.
jtab_temps(_SubstTemp, DataLbl) when is_integer(DataLbl) -> DataLbl.
-endif.