%% -*- erlang-indent-level: 4 -*- %% %% 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. %% %% @copyright 2000-2006 Richard Carlsson %% @author Richard Carlsson %% @doc Translation from Core Erlang to HiPE Icode. %% TODO: annotate Icode leaf functions as such. %% TODO: add a pass to remove unnecessary reduction tests %% TODO: generate branch prediction info? -module(cerl_to_icode). -define(NO_UNUSED, true). -export([module/1, module/2]). -ifndef(NO_UNUSED). -export([function/3, function/4]). -endif. %% Added in an attempt to suppress message by Dialyzer, but I run into %% an internal compiler error in the old inliner and commented it out. %% The inlining is performed manually instead :-( - Kostis %% -compile({inline, [{error_fun_value,1}]}). %% --------------------------------------------------------------------- %% Macros and records %% Icode primitive operation names -include("../icode/hipe_icode_primops.hrl"). -define(OP_REDTEST, redtest). -define(OP_CONS, cons). -define(OP_TUPLE, mktuple). -define(OP_ELEMENT, {erlang,element,2}). %% This has an MFA name -define(OP_UNSAFE_HD, unsafe_hd). -define(OP_UNSAFE_TL, unsafe_tl). -define(OP_UNSAFE_ELEMENT(N), #unsafe_element{index=N}). -define(OP_UNSAFE_SETELEMENT(N), #unsafe_update_element{index=N}). -define(OP_CHECK_GET_MESSAGE, check_get_msg). -define(OP_NEXT_MESSAGE, next_msg). -define(OP_SELECT_MESSAGE, select_msg). -define(OP_SET_TIMEOUT, set_timeout). -define(OP_CLEAR_TIMEOUT, clear_timeout). -define(OP_WAIT_FOR_MESSAGE, suspend_msg). -define(OP_APPLY_FIXARITY(N), #apply_N{arity=N}). -define(OP_MAKE_FUN(M, F, A, U, I), #mkfun{mfa={M,F,A}, magic_num=U, index=I}). -define(OP_FUN_ELEMENT(N), #closure_element{n=N}). -define(OP_BS_CONTEXT_TO_BINARY, {hipe_bs_primop,bs_context_to_binary}). %% Icode conditional tests -define(TEST_EQ, '=='). -define(TEST_NE, '/='). -define(TEST_EXACT_EQ, '=:='). -define(TEST_EXACT_NE, '=/='). -define(TEST_LT, '<'). -define(TEST_GT, '>'). -define(TEST_LE, '=<'). -define(TEST_GE, '>='). -define(TEST_WAIT_FOR_MESSAGE_OR_TIMEOUT, suspend_msg_timeout). %% Icode type tests -define(TYPE_ATOM(X), {atom, X}). -define(TYPE_INTEGER(X), {integer, X}). -define(TYPE_FIXNUM(X), {integer, X}). % for now -define(TYPE_CONS, cons). -define(TYPE_NIL, nil). -define(TYPE_IS_N_TUPLE(N), {tuple, N}). -define(TYPE_IS_ATOM, atom). -define(TYPE_IS_BIGNUM, bignum). -define(TYPE_IS_BINARY, binary). -define(TYPE_IS_FIXNUM, fixnum). -define(TYPE_IS_FLOAT, float). -define(TYPE_IS_FUNCTION, function). -define(TYPE_IS_INTEGER, integer). -define(TYPE_IS_LIST, list). -define(TYPE_IS_NUMBER, number). -define(TYPE_IS_PID, pid). -define(TYPE_IS_PORT, port). -define(TYPE_IS_RECORD(Atom_, Size_), {record, Atom_, Size_}). -define(TYPE_IS_REFERENCE, reference). -define(TYPE_IS_TUPLE, tuple). %% Record definitions -record('receive', {loop}). -record(cerl_to_icode__var, {name}). -record('fun', {label, vars}). -record(ctxt, {final = false :: boolean(), effect = false :: boolean(), fail = [], % [] or fail-to label class = expr :: 'expr' | 'guard', line = 0 :: erl_anno:line(), % current line number 'receive' :: 'undefined' | #'receive'{} }). %% --------------------------------------------------------------------- %% Code %% @spec module(Module::cerl()) -> [{mfa(), icode()}] %% @equiv module(Module, []) -spec module(cerl:c_module()) -> [{mfa(), hipe_icode:icode()}]. module(E) -> module(E, []). %% @spec module(Module::cerl(), Options::[term()]) -> [{mfa(), icode()}] %% %% cerl() = cerl:c_module() %% icode() = hipe_icode:icode() %% %% @doc Transforms a Core Erlang module to linear HiPE Icode. The result %% is a list of Icode function definitions. Currently, no options are %% available. %% %%

This function first calls the {@link cerl_hipeify:transform/2} %% function on the module.

%% %%

Note: Except for the module name, which is included in the header %% of each Icode function definition, the remaining information (exports %% and attributes) associated with the module definition is not included %% in the resulting Icode.

%% %% @see function/4 %% @see cerl_hipeify:transform/1 -spec module(cerl:c_module(), [term()]) -> [{mfa(), hipe_icode:icode()}]. module(E, Options) -> module_1(cerl_hipeify:transform(E, Options), Options). module_1(E, Options) -> M = cerl:atom_val(cerl:module_name(E)), if is_atom(M) -> ok; true -> error_msg("bad module name: ~P.", [M, 5]), throw(error) end, S0 = init(M), S1 = s__set_pmatch(proplists:get_value(pmatch, Options), S0), S2 = s__set_bitlevel_binaries(proplists:get_value( bitlevel_binaries, Options), S1), {Icode, _} = lists:mapfoldl(fun function_definition/2, S2, cerl:module_defs(E)), Icode. %% For now, we simply assume that all function bodies should have degree %% one (i.e., return exactly one value). We clear the code ackumulator %% before we start compiling each function. function_definition({V, F}, S) -> S1 = s__set_code([], S), {Icode, S2} = function_1(cerl:var_name(V), F, 1, S1), {{icode_icode_name(Icode), Icode}, S2}. init(Module) -> reset_label_counter(), s__new(Module). %% @spec function(Module::atom(), Name::atom(), Function::cerl()) -> %% icode() %% @equiv function(Module, Name, Fun, 1) -ifndef(NO_UNUSED). function(Module, Name, Fun) -> function(Module, Name, Fun, 1). -endif. % NO_UNUSED %% @clear %% @spec function(Module::atom(), Name::{atom(), integer()}, %% Fun::cerl(), Degree::integer()) -> icode() %% %% @doc Transforms a Core Erlang function to a HiPE Icode function %% definition. `Fun' must represent a fun-expression, which may not %% contain free variables. `Module' and `Name' specify the module and %% function name of the resulting Icode function. Note that the arity %% part of `Name' is not necessarily equivalent to the number of %% parameters of `Fun' (this can happen e.g., for lifted closure %% functions). %% %%

`Degree' specifies the number of values the function is expected %% to return; this is typically 1 (one); cf. {@link function/3}.

%% %%

Notes: %%

%% %%

Important: This function does not handle occurrences of %% fun-expressions in the body of `Fun', nor `apply'-expressions whose %% operators are not locally bound function variables. These must be %% transformed away before this function is called, by closure %% conversion ({@link cerl_cconv}) using the `make_fun' and `call_fun' %% primitive operations to create and apply functional values.

%% %%

`receive'-expressions are expected to have a particular %% form: %%

%% %% @see function/3 -include("cerl_hipe_primops.hrl"). %% Main translation function: -ifndef(NO_UNUSED). function(Module, Name, Fun, Degree) -> S = init(Module), {Icode, _} = function_1(Name, Fun, Degree, S), Icode. -endif. % NO_UNUSED %% @clear function_1(Name, Fun, Degree, S) -> reset_var_counter(), LowV = max_var(), LowL = max_label(), %% Create input variables for the function parameters, and a list of %% target variables for the result of the function. Args = cerl:fun_vars(Fun), IcodeArity = length(Args), Vs = make_vars(IcodeArity), Vs1 = make_vars(IcodeArity), % input variable temporaries Ts = make_vars(Degree), %% Initialise environment and context. Env = bind_vars(Args, Vs, env__new()), %% TODO: if the function returns no values, we can use effect mode Ctxt = #ctxt{final = true, effect = false}, %% Each basic block must begin with a label. Note that we %% immediately transfer the input parameters to local variables, for %% our self-recursive calling convention. Start = new_label(), Local = new_label(), S1 = add_code([icode_label(Start)] ++ make_moves(Vs, Vs1) ++ [icode_label(Local)], s__set_function(Name, S)), S2 = expr(cerl:fun_body(Fun), Ts, Ctxt, Env, s__set_local_entry({Local, Vs}, S1)), %% This creates an Icode function definition. The ranges of used %% variables and labels below should be nonempty. Note that the %% input variables for the Icode function are `Vs1', which will be %% transferred to `Vs' (see above). HighV = new_var(), % assure nonempty range HighL = max_label(), Closure = lists:member(closure, cerl:get_ann(Fun)), Module = s__get_module(S2), Code = s__get_code(S2), Function = icode_icode(Module, Name, Vs1, Closure, Code, {LowV, HighV}, {LowL, HighL}), if Closure -> {_, OrigArity} = lists:keyfind(closure_orig_arity, 1, cerl:get_ann(Fun)), {hipe_icode:icode_closure_arity_update(Function, OrigArity), S2}; true -> {Function, S2} end. %% --------------------------------------------------------------------- %% Main expression handler expr(E, Ts, Ctxt, Env, S0) -> %% Insert source code position information case get_line(cerl:get_ann(E)) of none -> expr_1(E, Ts, Ctxt, Env, S0); Line when Line > Ctxt#ctxt.line -> Txt = "Line: " ++ integer_to_list(Line), S1 = add_code([icode_comment(Txt)], S0), expr_1(E, Ts, Ctxt#ctxt{line = Line}, Env, S1); _ -> expr_1(E, Ts, Ctxt, Env, S0) end. expr_1(E, Ts, Ctxt, Env, S) -> case cerl:type(E) of var -> expr_var(E, Ts, Ctxt, Env, S); literal -> expr_literal(E, Ts, Ctxt, S); values -> expr_values(E, Ts, Ctxt, Env, S); tuple -> %% (The unit tuple `{}' is a literal, handled above.) expr_tuple(E, Ts, Ctxt, Env, S); cons -> expr_cons(E, Ts, Ctxt, Env, S); 'let' -> expr_let(E, Ts, Ctxt, Env, S); seq -> expr_seq(E, Ts, Ctxt, Env, S); apply -> expr_apply(E, Ts, Ctxt, Env, S); call -> expr_call(E, Ts, Ctxt, Env, S); primop -> expr_primop(E, Ts, Ctxt, Env, S); 'case' -> expr_case(E, Ts, Ctxt, Env, S); 'receive' -> expr_receive(E, Ts, Ctxt, Env, S); 'try' -> expr_try(E, Ts, Ctxt, Env, S); binary -> expr_binary(E, Ts, Ctxt, Env, S); letrec -> expr_letrec(E, Ts, Ctxt, Env, S); 'fun' -> error_msg("cannot handle fun-valued expressions; " "must be closure converted."), throw(error) end. %% This is for when we need new target variables for all of the %% expressions in the list, and evaluate them for value in a %% non-tail-call context. expr_list(Es, Ctxt, Env, S) -> Ctxt1 = Ctxt#ctxt{effect = false, final = false}, lists:mapfoldl(fun (E0, S0) -> V = make_var(), {V, expr(E0, [V], Ctxt1, Env, S0)} end, S, Es). %% This is for when we already have the target variables. It is expected %% that each expression in the list has degree one, so the result can be %% assigned to the corresponding variable. exprs([E | Es], [V | Vs], Ctxt, Env, S) -> S1 = expr(E, [V], Ctxt, Env, S), exprs(Es, Vs, Ctxt, Env, S1); exprs([], [], _Ctxt, _Env, S) -> S; exprs([], _, _Ctxt, _Env, S) -> warning_low_degree(), S; exprs(_, [], _Ctxt, _Env, _S) -> error_high_degree(), throw(error). get_line([L | _As]) when is_integer(L) -> L; get_line([_ | As]) -> get_line(As); get_line([]) -> none. %% --------------------------------------------------------------------- %% Variables expr_var(_E, _Ts, #ctxt{effect = true}, _Env, S) -> S; expr_var(E, Ts, Ctxt, Env, S) -> Name = cerl:var_name(E), case env__lookup(Name, Env) of error -> %% Either an undefined variable or an attempt to use a local %% function name as a value. case Name of {N,A} when is_atom(N), is_integer(A) -> %% error_fun_value(Name); error_msg("cannot handle fun-values outside call context; " "must be closure converted: ~P.", [Name, 5]), throw(error); _ -> error_msg("undefined variable: ~P.", [Name, 5]), throw(error) end; {ok, #cerl_to_icode__var{name = V}} -> case Ctxt#ctxt.final of false -> glue([V], Ts, S); true -> add_return([V], S) end; {ok, #'fun'{}} -> %% A letrec-defined function name, used as a value. %% error_fun_value(Name) error_msg("cannot handle fun-values outside call context; " "must be closure converted: ~P.", [Name, 5]), throw(error) end. %% The function has been inlined manually above to suppress message by Dialyzer %% error_fun_value(Name) -> %% error_msg("cannot handle fun-values outside call context; " %% "must be closure converted: ~P.", %% [Name, 5]), %% throw(error). %% --------------------------------------------------------------------- %% This handles all constants, both atomic and compound: expr_literal(_E, _Ts, #ctxt{effect = true}, S) -> S; expr_literal(E, [V] = Ts, Ctxt, S) -> Code = [icode_move(V, icode_const(cerl:concrete(E)))], maybe_return(Ts, Ctxt, add_code(Code, S)); expr_literal(E, Ts, _Ctxt, _S) -> error_degree_mismatch(length(Ts), E), throw(error). %% --------------------------------------------------------------------- %% Multiple value aggregate expr_values(E, Ts, #ctxt{effect = true} = Ctxt, Env, S) -> {_, S1} = exprs(cerl:values_es(E), Ts, Ctxt#ctxt{final = false}, Env, S), S1; expr_values(E, Ts, Ctxt, Env, S) -> S1 = exprs(cerl:values_es(E), Ts, Ctxt#ctxt{final = false}, Env, S), maybe_return(Ts, Ctxt, S1). %% --------------------------------------------------------------------- %% Nonconstant tuples expr_tuple(E, _Ts, #ctxt{effect = true} = Ctxt, Env, S) -> {_Vs, S1} = expr_list(cerl:tuple_es(E), Ctxt, Env, S), S1; expr_tuple(E, [_V] = Ts, Ctxt, Env, S) -> {Vs, S1} = expr_list(cerl:tuple_es(E), Ctxt, Env, S), add_code(make_op(?OP_TUPLE, Ts, Vs, Ctxt), S1); expr_tuple(E, Ts, _Ctxt, _Env, _S) -> error_degree_mismatch(length(Ts), E), throw(error). %% --------------------------------------------------------------------- %% Nonconstant cons cells expr_cons(E, _Ts, #ctxt{effect = true} = Ctxt, Env, S) -> {_Vs, S1} = expr_list([cerl:cons_hd(E), cerl:cons_tl(E)], Ctxt, Env, S), S1; expr_cons(E, [_V] = Ts, Ctxt, Env, S) -> {Vs, S1} = expr_list([cerl:cons_hd(E), cerl:cons_tl(E)], Ctxt, Env, S), add_code(make_op(?OP_CONS, Ts, Vs, Ctxt), S1); expr_cons(E, Ts, _Ctxt, _Env, _S) -> error_degree_mismatch(length(Ts), E), throw(error). %% --------------------------------------------------------------------- %% Let-expressions %% We want to make sure we are not easily tricked by expressions hidden %% in contexts like "let X = Expr in X"; this should not destroy tail %% call properties. expr_let(E, Ts, Ctxt, Env, S) -> F = fun (BF, CtxtF, EnvF, SF) -> expr(BF, Ts, CtxtF, EnvF, SF) end, expr_let_1(E, F, Ctxt, Env, S). expr_let_1(E, F, Ctxt, Env, S) -> E1 = cerl_lib:reduce_expr(E), case cerl:is_c_let(E1) of true -> expr_let_2(E1, F, Ctxt, Env, S); false -> %% Redispatch the new expression. F(E1, Ctxt, Env, S) end. expr_let_2(E, F, Ctxt, Env, S) -> Vars = cerl:let_vars(E), Vs = make_vars(length(Vars)), S1 = expr(cerl:let_arg(E), Vs, Ctxt#ctxt{effect = false, final = false}, Env, S), Env1 = bind_vars(Vars, Vs, Env), F(cerl:let_body(E), Ctxt, Env1, S1). %% --------------------------------------------------------------------- %% Sequencing %% To compile a sequencing operator, we generate code for effect only %% for the first expression (the "argument") and then use the %% surrounding context for the second expression (the "body"). Note that %% we always create a new dummy target variable; this is necessary for %% many ICode operations, even if the result is not used. expr_seq(E, Ts, Ctxt, Env, S) -> F = fun (BF, CtxtF, EnvF, SF) -> expr(BF, Ts, CtxtF, EnvF, SF) end, expr_seq_1(E, F, Ctxt, Env, S). expr_seq_1(E, F, Ctxt, Env, S) -> Ctxt1 = Ctxt#ctxt{effect = true, final = false}, S1 = expr(cerl:seq_arg(E), [make_var()], Ctxt1, Env, S), F(cerl:seq_body(E), Ctxt, Env, S1). %% --------------------------------------------------------------------- %% Binaries -record(sz_var, {code, sz}). -record(sz_const, {code, sz}). expr_binary(E, [V]=Ts, Ctxt, Env, S) -> Offset = make_reg(), Base = make_reg(), Segs = cerl:binary_segments(E), S1 = case do_size_code(Segs, S, Env, Ctxt) of #sz_const{code = S0, sz = Size} -> Primop = {hipe_bs_primop, {bs_init, Size, 0}}, add_code([icode_call_primop([V, Base, Offset], Primop, [])], S0); #sz_var{code = S0, sz = SizeVar} -> Primop = {hipe_bs_primop, {bs_init, 0}}, add_code([icode_call_primop([V, Base, Offset], Primop, [SizeVar])], S0) end, Vars = make_vars(length(Segs)), S2 = binary_segments(Segs, Vars, Ctxt, Env, S1, false, Base, Offset), S3 = case s__get_bitlevel_binaries(S2) of true -> POp = {hipe_bs_primop, bs_final}, add_code([icode_call_primop([V], POp, [V, Offset])], S2); false -> S2 end, maybe_return(Ts, Ctxt, S3). do_size_code(Segs, S, Env, Ctxt) -> case do_size_code(Segs, S, Env, cerl:c_int(0), [], []) of {[], [], Const, S1} -> #sz_const{code = S1, sz = ((cerl:concrete(Const) + 7) div 8)}; {Pairs, Bins, Const, S1} -> V1 = make_var(), S2 = add_code([icode_move(V1, icode_const(cerl:int_val(Const)))], S1), {S3, SizeVar} = create_size_code(Pairs, Bins, Ctxt, V1, S2), #sz_var{code = S3, sz = SizeVar} end. do_size_code([Seg|Rest], S, Env, Const, Pairs, Bins) -> Size = cerl:bitstr_size(Seg), Unit = cerl:bitstr_unit(Seg), Val = cerl:bitstr_val(Seg), case calculate_size(Unit, Size, false, Env, S) of {all,_, _, S} -> Binary = make_var(), S1 = expr(Val, [Binary], #ctxt{final=false}, Env, S), do_size_code(Rest, S1, Env, Const, Pairs, [{all,Binary}|Bins]); {NewVal, [], S, _} -> do_size_code(Rest, S, Env, add_val(NewVal, Const), Pairs, Bins); {UnitVal, [Var], S1, _} -> do_size_code(Rest, S1, Env, Const, [{UnitVal,Var}|Pairs], Bins) end; do_size_code([], S, _Env, Const, Pairs, Bins) -> {Pairs, Bins, Const, S}. add_val(NewVal, Const) -> cerl:c_int(NewVal + cerl:concrete(Const)). create_size_code([{UnitVal, Var}|Rest], Bins, Ctxt, Old, S0) -> Dst = make_var(), S = make_bs_add(UnitVal, Old, Var, Dst, Ctxt, S0), create_size_code(Rest, Bins, Ctxt, Dst, S); create_size_code([], Bins, Ctxt, Old, S0) -> Dst = make_var(), S = make_bs_bits_to_bytes(Old, Dst, Ctxt, S0), create_size_code(Bins, Ctxt, Dst, S). create_size_code([{all,Bin}|Rest], Ctxt, Old, S0) -> Dst = make_var(), S = make_binary_size(Old, Bin, Dst, Ctxt, S0), create_size_code(Rest, Ctxt, Dst, S); create_size_code([], _Ctxt, Dst, S) -> {S, Dst}. make_bs_add(Unit, Old, Var, Dst, #ctxt{fail=FL, class=guard}, S0) -> SL1 = new_label(), SL2 = new_label(), SL3 = new_label(), Temp = make_var(), add_code([icode_if('>=', [Var, icode_const(0)], SL1, FL), icode_label(SL1), icode_guardop([Temp], '*', [Var, icode_const(Unit)], SL2, FL), icode_label(SL2), icode_guardop([Dst], '+', [Temp, Old], SL3, FL), icode_label(SL3)], S0); make_bs_add(Unit, Old, Var, Dst, _Ctxt, S0) -> SL = new_label(), FL = new_label(), Temp = make_var(), add_code([icode_if('>=', [Var, icode_const(0)], SL, FL), icode_label(FL), icode_fail([icode_const(badarg)], error), icode_label(SL), icode_call_primop([Temp], '*', [Var, icode_const(Unit)]), icode_call_primop([Dst], '+', [Temp, Old])], S0). make_bs_bits_to_bytes(Old, Dst, #ctxt{fail=FL, class=guard}, S0) -> SL = new_label(), add_code([icode_guardop([Dst], 'bsl', [Old, icode_const(3)], SL, FL), icode_label(SL)], S0); make_bs_bits_to_bytes(Old, Dst, _Ctxt, S0) -> add_code([icode_call_primop([Dst], 'bsl', [Old, icode_const(3)])], S0). make_binary_size(Old, Bin, Dst, #ctxt{fail=FL, class=guard}, S0) -> SL1 = new_label(), SL2 = new_label(), add_code([icode_guardop([Dst], {erlang, byte_size, 1}, [Bin], SL1, FL), icode_label(SL1), icode_guardop([Dst], '+', [Old, Dst], SL2, FL), icode_label(SL2)], S0); make_binary_size(Old, Bin, Dst, _Ctxt, S0) -> add_code([icode_call_primop([Dst], {erlang, byte_size, 1}, [Bin]), icode_call_primop([Dst], '+', [Old, Dst])], S0). binary_segments(SegList, TList, Ctxt=#ctxt{}, Env, S, Align, Base, Offset) -> case do_const_segs(SegList, TList, S, Align, Base, Offset) of {[Seg|Rest], [T|Ts], S1} -> {S2, NewAlign} = bitstr(Seg, [T], Ctxt, Env, S1, Align, Base, Offset), binary_segments(Rest, Ts, Ctxt, Env, S2, NewAlign, Base, Offset); {[], [], S1} -> S1 end. do_const_segs(SegList, TList, S, _Align, Base, Offset) -> case get_segs(SegList, TList, [], 0, {[], SegList, TList}) of {[], SegList, TList} -> {SegList, TList, S}; {ConstSegs, RestSegs, RestT} -> String = create_string(ConstSegs, <<>>, 0), Name = {bs_put_string, String, length(String)}, Primop = {hipe_bs_primop, Name}, {RestSegs, RestT, add_code([icode_call_primop([Offset], Primop, [Base, Offset])], S)} end. get_segs([Seg|Rest], [_|RestT], Acc, AccSize, BestPresent) -> Size = cerl:bitstr_size(Seg), Unit = cerl:bitstr_unit(Seg), Val = cerl:bitstr_val(Seg), case allowed(Size, Unit, Val, AccSize) of {true, NewAccSize} -> case Acc of [] -> get_segs(Rest, RestT, [Seg|Acc], NewAccSize, BestPresent); _ -> get_segs(Rest, RestT, [Seg|Acc], NewAccSize, {lists:reverse([Seg|Acc]), Rest, RestT}) end; {possible, NewAccSize} -> get_segs(Rest, RestT, [Seg|Acc], NewAccSize, BestPresent); false -> BestPresent end; get_segs([], [], _Acc, _AccSize, Best) -> Best. create_string([Seg|Rest], Bin, TotalSize) -> Size = cerl:bitstr_size(Seg), Unit = cerl:bitstr_unit(Seg), NewSize = cerl:int_val(Size) * cerl:int_val(Unit), LitVal = cerl:concrete(cerl:bitstr_val(Seg)), LiteralFlags = cerl:bitstr_flags(Seg), FlagVal = translate_flags(LiteralFlags, []), NewTotalSize = NewSize + TotalSize, Pad = (8 - NewTotalSize rem 8) rem 8, NewBin = case cerl:concrete(cerl:bitstr_type(Seg)) of integer -> case {FlagVal band 2, FlagVal band 4} of {2, 4} -> <>; {0, 4} -> <>; {2, 0} -> <>; {0, 0} -> <> end; float -> case FlagVal band 2 of 2 -> <>; 0 -> <> end end, create_string(Rest, NewBin, NewTotalSize); create_string([], Bin, _Size) -> binary_to_list(Bin). allowed(Size, Unit, Val, AccSize) -> case {cerl:is_c_int(Size), cerl:is_literal(Val)} of {true, true} -> NewAccSize = cerl:int_val(Size) * cerl:int_val(Unit) + AccSize, case NewAccSize rem 8 of 0 -> {true, NewAccSize}; _ -> {possible, NewAccSize} end; _ -> false end. bitstr(E, Ts, Ctxt, Env, S, Align, Base, Offset) -> Size = cerl:bitstr_size(E), Unit = cerl:bitstr_unit(E), LiteralFlags = cerl:bitstr_flags(E), Val = cerl:bitstr_val(E), Type = cerl:concrete(cerl:bitstr_type(E)), S0 = expr(Val, Ts, Ctxt#ctxt{final = false, effect = false}, Env, S), ConstInfo = get_const_info(Val, Type), Flags = translate_flags(LiteralFlags, Align), SizeInfo = calculate_size(Unit, Size, false, Env, S0), bitstr_gen_op(Ts, Ctxt, SizeInfo, ConstInfo, Type, Flags, Base, Offset). bitstr_gen_op([V], #ctxt{fail=FL, class=guard}, SizeInfo, ConstInfo, Type, Flags, Base, Offset) -> SL = new_label(), case SizeInfo of {all, NewUnit, NewAlign, S1} -> Type = binary, Name = {bs_put_binary_all, NewUnit, Flags}, Primop = {hipe_bs_primop, Name}, {add_code([icode_guardop([Offset], Primop, [V, Base, Offset], SL, FL), icode_label(SL)], S1), NewAlign}; {NewUnit, NewArgs, S1, NewAlign} -> Args = [V|NewArgs] ++ [Base, Offset], Name = case Type of integer -> {bs_put_integer, NewUnit, Flags, ConstInfo}; float -> {bs_put_float, NewUnit, Flags, ConstInfo}; binary -> {bs_put_binary, NewUnit, Flags} end, Primop = {hipe_bs_primop, Name}, {add_code([icode_guardop([Offset], Primop, Args, SL, FL), icode_label(SL)], S1), NewAlign} end; bitstr_gen_op([V], _Ctxt, SizeInfo, ConstInfo, Type, Flags, Base, Offset) -> case SizeInfo of {all, NewUnit, NewAlign, S} -> Type = binary, Name = {bs_put_binary_all, NewUnit, Flags}, Primop = {hipe_bs_primop, Name}, {add_code([icode_call_primop([Offset], Primop, [V, Base, Offset])], S), NewAlign}; {NewUnit, NewArgs, S, NewAlign} -> Args = [V|NewArgs] ++ [Base, Offset], Name = case Type of integer -> {bs_put_integer, NewUnit, Flags, ConstInfo}; float -> {bs_put_float, NewUnit, Flags, ConstInfo}; binary -> {bs_put_binary, NewUnit, Flags} end, Primop = {hipe_bs_primop, Name}, {add_code([icode_call_primop([Offset], Primop, Args)], S), NewAlign} end. %% --------------------------------------------------------------------- %% Apply-expressions %% Note that the arity of the called function only depends on the length %% of the argument list; the arity stated by the function name is %% ignored. expr_apply(E, Ts, Ctxt, Env, S) -> Op = cerl_lib:reduce_expr(cerl:apply_op(E)), {Vs, S1} = expr_list(cerl:apply_args(E), Ctxt, Env, S), case cerl:is_c_var(Op) of true -> case cerl:var_name(Op) of {N, A} = V when is_atom(N), is_integer(A) -> case env__lookup(V, Env) of error -> %% Assumed to be a function in the %% current module; we don't check. add_local_call(V, Vs, Ts, Ctxt, S1); {ok, #'fun'{label = L, vars = Vs1}} -> %% Call to a local letrec-bound function. add_letrec_call(L, Vs1, Vs, Ctxt, S1); {ok, #cerl_to_icode__var{}} -> error_msg("cannot call via variable; must " "be closure converted: ~P.", [V, 5]), throw(error) end; _ -> error_nonlocal_application(Op), throw(error) end; false -> error_nonlocal_application(Op), throw(error) end. %% --------------------------------------------------------------------- %% Call-expressions %% Unless we know the module and function names statically, we have to %% go through the meta-call operator for a static number of arguments. expr_call(E, Ts, Ctxt, Env, S) -> Module = cerl_lib:reduce_expr(cerl:call_module(E)), Name = cerl_lib:reduce_expr(cerl:call_name(E)), case cerl:is_c_atom(Module) and cerl:is_c_atom(Name) of true -> M = cerl:atom_val(Module), F = cerl:atom_val(Name), {Vs, S1} = expr_list(cerl:call_args(E), Ctxt, Env, S), add_code(make_call(M, F, Ts, Vs, Ctxt), S1); false -> Args = cerl:call_args(E), N = length(Args), {Vs, S1} = expr_list([Module, Name | Args], Ctxt, Env, S), add_code(make_op(?OP_APPLY_FIXARITY(N), Ts, Vs, Ctxt), S1) end. %% --------------------------------------------------------------------- %% Primop calls %% Core Erlang primop calls are generally mapped directly to Icode %% primop calls, with a few exceptions (listed above), which are %% expanded inline, sometimes depending on context. Note that primop %% calls do not have specialized tail-call forms. expr_primop(E, Ts, Ctxt, Env, S) -> Name = cerl:atom_val(cerl:primop_name(E)), As = cerl:primop_args(E), Arity = length(As), expr_primop_0(Name, Arity, As, E, Ts, Ctxt, Env, S). expr_primop_0(Name, Arity, As, E, Ts, #ctxt{effect = true} = Ctxt, Env, S) -> case is_safe_op(Name, Arity) of true -> %% Just drop the operation; cf. 'expr_values(...)'. {_, S1} = expr_list(As, Ctxt, Env, S), S1; false -> expr_primop_1(Name, Arity, As, E, Ts, Ctxt#ctxt{effect = false}, Env, S) end; expr_primop_0(Name, Arity, As, E, Ts, Ctxt, Env, S) -> expr_primop_1(Name, Arity, As, E, Ts, Ctxt, Env, S). %% Some primops must be caught before their arguments are visited. expr_primop_1(?PRIMOP_MAKE_FUN, 6, As, _E, Ts, Ctxt, Env, S) -> primop_make_fun(As, Ts, Ctxt, Env, S); expr_primop_1(?PRIMOP_APPLY_FUN, 2, As, _E, Ts, Ctxt, Env, S) -> primop_apply_fun(As, Ts, Ctxt, Env, S); expr_primop_1(?PRIMOP_FUN_ELEMENT, 2, As, _E, Ts, Ctxt, Env, S) -> primop_fun_element(As, Ts, Ctxt, Env, S); expr_primop_1(?PRIMOP_DSETELEMENT, 3, As, _E, Ts, Ctxt, Env, S) -> primop_dsetelement(As, Ts, Ctxt, Env, S); expr_primop_1(?PRIMOP_RECEIVE_SELECT, 0, _As, _E, Ts, Ctxt, _Env, S) -> primop_receive_select(Ts, Ctxt, S); expr_primop_1(?PRIMOP_RECEIVE_NEXT, 0, _As, _E, _Ts, Ctxt, _Env, S) -> primop_receive_next(Ctxt, S); %%expr_primop_1(?PRIMOP_IDENTITY, 1, [A], _E, Ts, Ctxt, Env, S) -> %% expr(A, Ts, Ctxt, Env, S); % used for unary plus expr_primop_1(?PRIMOP_NEG, 1, [A], _, Ts, Ctxt, Env, S) -> E = cerl:c_primop(cerl:c_atom('-'), [cerl:c_int(0), A]), expr_primop(E, Ts, Ctxt, Env, S); expr_primop_1(?PRIMOP_GOTO_LABEL, 1, [A], _, _Ts, _Ctxt, _Env, S) -> primop_goto_label(A, S); expr_primop_1(?PRIMOP_REDUCTION_TEST, 0, [], _, _Ts, Ctxt, _Env, S) -> primop_reduction_test(Ctxt, S); expr_primop_1(Name, Arity, As, E, Ts, Ctxt, Env, S) -> case is_pure_op_aux(Name, Arity) of true -> boolean_expr(E, Ts, Ctxt, Env, S); false -> {Vs, S1} = expr_list(As, Ctxt, Env, S), expr_primop_2(Name, Arity, Vs, Ts, Ctxt, S1) end. expr_primop_2(?PRIMOP_ELEMENT, 2, Vs, Ts, Ctxt, S) -> add_code(make_op(?OP_ELEMENT, Ts, Vs, Ctxt), S); expr_primop_2(?PRIMOP_BS_CONTEXT_TO_BINARY, 1, Vs, Ts, Ctxt, S) -> add_code(make_op(?OP_BS_CONTEXT_TO_BINARY, Ts, Vs, Ctxt), S); expr_primop_2(?PRIMOP_EXIT, 1, [V], _Ts, Ctxt, S) -> add_exit(V, Ctxt, S); expr_primop_2(?PRIMOP_THROW, 1, [V], _Ts, Ctxt, S) -> add_throw(V, Ctxt, S); expr_primop_2(?PRIMOP_ERROR, 1, [V], _Ts, Ctxt, S) -> add_error(V, Ctxt, S); expr_primop_2(?PRIMOP_ERROR, 2, [V, F], _Ts, Ctxt, S) -> add_error(V, F, Ctxt, S); expr_primop_2(?PRIMOP_RETHROW, 2, [E, V], _Ts, Ctxt, S) -> add_rethrow(E, V, Ctxt, S); expr_primop_2(Name, _Arity, Vs, Ts, Ctxt, S) -> %% Other ops are assumed to be recognized by the backend. add_code(make_op(Name, Ts, Vs, Ctxt), S). %% All of M, F, and A must be literals with the right types. %% V must represent a proper list. primop_make_fun([M, F, A, H, I, V] = As, [_T] = Ts, Ctxt, Env, S) -> case cerl:is_c_atom(M) and cerl:is_c_atom(F) and cerl:is_c_int(A) and cerl:is_c_int(H) and cerl:is_c_int(I) and cerl:is_c_list(V) of true -> Module = cerl:atom_val(M), Name = cerl:atom_val(F), Arity = cerl:int_val(A), Hash = cerl:int_val(H), Index = cerl:int_val(I), {Vs, S1} = expr_list(cerl:list_elements(V), Ctxt, Env, S), add_code(make_op(?OP_MAKE_FUN(Module, Name, Arity, Hash, Index), Ts, Vs, Ctxt), S1); false -> error_primop_badargs(?PRIMOP_MAKE_FUN, As), throw(error) end. %% V must represent a proper list. primop_apply_fun([F, V] = As, [_T] = Ts, Ctxt, Env, S) -> case cerl:is_c_list(V) of true -> %% Note that the closure itself is passed as the last value. {Vs, S1} = expr_list(cerl:list_elements(V) ++ [F], Ctxt, Env, S), case Ctxt#ctxt.final of false -> add_code([icode_call_fun(Ts, Vs)], S1); true -> add_code([icode_enter_fun(Vs)], S1) end; false -> error_primop_badargs(?PRIMOP_APPLY_FUN, As), throw(error) end. primop_fun_element([N, F] = As, Ts, Ctxt, Env, S) -> case cerl:is_c_int(N) of true -> V = make_var(), S1 = expr(F, [V], Ctxt#ctxt{final = false, effect = false}, Env, S), add_code(make_op(?OP_FUN_ELEMENT(cerl:int_val(N)), Ts, [V], Ctxt), S1); false -> error_primop_badargs(?PRIMOP_FUN_ELEMENT, As), throw(error) end. primop_goto_label(A, S) -> {Label,S1} = s__get_label(A, S), add_code([icode_goto(Label)], S1). is_goto(E) -> case cerl:type(E) of primop -> Name = cerl:atom_val(cerl:primop_name(E)), As = cerl:primop_args(E), Arity = length(As), case {Name, Arity} of {?PRIMOP_GOTO_LABEL, 1} -> true; _ -> false end; _ -> false end. primop_reduction_test(Ctxt, S) -> add_code(make_op(?OP_REDTEST, [], [], Ctxt), S). primop_dsetelement([N | As1] = As, Ts, Ctxt, Env, S) -> case cerl:is_c_int(N) of true -> {Vs, S1} = expr_list(As1, Ctxt, Env, S), add_code(make_op(?OP_UNSAFE_SETELEMENT(cerl:int_val(N)), Ts, Vs, Ctxt), S1); false -> error_primop_badargs(?PRIMOP_DSETELEMENT, As), throw(error) end. %% --------------------------------------------------------------------- %% Try-expressions: %% We want to rewrite trivial things like `try A of X -> B catch ...', %% where A is safe, into a simple let-binding `let X = A in B', avoiding %% unnecessary try-blocks. (The `let' might become further simplified.) expr_try(E, Ts, Ctxt, Env, S) -> F = fun (BF, CtxtF, EnvF, SF) -> expr(BF, Ts, CtxtF, EnvF, SF) end, expr_try_1(E, F, Ctxt, Env, S). expr_try_1(E, F, Ctxt, Env, S) -> A = cerl:try_arg(E), case is_safe_expr(A) of true -> E1 = cerl:c_let(cerl:try_vars(E), A, cerl:try_body(E)), expr_let_1(E1, F, Ctxt, Env, S); false -> expr_try_2(E, F, Ctxt, Env, S) end. %% TODO: maybe skip begin_try/end_try and just use fail-labels... expr_try_2(E, F, Ctxt, Env, S) -> Cont = new_continuation_label(Ctxt), Catch = new_label(), Next = new_label(), S1 = add_code([icode_begin_try(Catch,Next),icode_label(Next)], S), Vars = cerl:try_vars(E), Vs = make_vars(length(Vars)), Ctxt1 = Ctxt#ctxt{final = false}, S2 = expr(cerl:try_arg(E), Vs, Ctxt1, Env, S1), Env1 = bind_vars(Vars, Vs, Env), S3 = add_code([icode_end_try()], S2), S4 = F(cerl:try_body(E), Ctxt, Env1, S3), S5 = add_continuation_jump(Cont, Ctxt, S4), EVars = cerl:try_evars(E), EVs = make_vars(length(EVars)), Env2 = bind_vars(EVars, EVs, Env), S6 = add_code([icode_label(Catch), icode_begin_handler(EVs)], S5), S7 = F(cerl:try_handler(E), Ctxt, Env2, S6), add_continuation_label(Cont, Ctxt, S7). %% --------------------------------------------------------------------- %% Letrec-expressions (local goto-labels) %% We only handle letrec-functions as continuations. The fun-bodies are %% always compiled in the same context as the main letrec-body. Note %% that we cannot propagate "advanced" contexts like boolean-compilation %% into the letrec body like we do for ordinary lets or seqs, since the %% context for an individual local function would be depending on the %% contexts of its call sites. expr_letrec(E, Ts, Ctxt, Env, S) -> Ds = cerl:letrec_defs(E), Env1 = add_defs(Ds, Env), S1 = expr(cerl:letrec_body(E), Ts, Ctxt, Env1, S), Next = new_continuation_label(Ctxt), S2 = add_continuation_jump(Next, Ctxt, S1), S3 = defs(Ds, Ts, Ctxt, Env1, S2), add_continuation_label(Next, Ctxt, S3). add_defs([{V, _F} | Ds], Env) -> {_, A} = cerl:var_name(V), Vs = make_vars(A), L = new_label(), Env1 = bind_fun(V, L, Vs, Env), add_defs(Ds, Env1); add_defs([], Env) -> Env. defs([{V, F} | Ds], Ts, Ctxt, Env, S) -> Name = cerl:var_name(V), #'fun'{label = L, vars = Vs} = env__get(Name, Env), S1 = add_code([icode_label(L)], S), Env1 = bind_vars(cerl:fun_vars(F), Vs, Env), S2 = expr(cerl:fun_body(F), Ts, Ctxt, Env1, S1), defs(Ds, Ts, Ctxt, Env, S2); defs([], _Ts, _Ctxt, _Env, S) -> S. %% --------------------------------------------------------------------- %% Receive-expressions %% There may only be exactly one clause, which must be a trivial %% catch-all with exactly one (variable) pattern. Each message will be %% read from the mailbox and bound to the pattern variable; the body of %% the clause must do the switching and call either of the primops %% `receive_select/0' or `receive_next/0'. expr_receive(E, Ts, Ctxt, Env, S) -> F = fun (BF, CtxtF, EnvF, SF) -> expr(BF, Ts, CtxtF, EnvF, SF) end, expr_receive_1(E, F, Ctxt, Env, S). expr_receive_1(E, F, Ctxt, Env, S) -> case cerl:receive_clauses(E) of [C] -> case cerl:clause_pats(C) of [_] -> case cerl_clauses:is_catchall(C) of true -> expr_receive_2(C, E, F, Ctxt, Env, S); false -> error_msg("receive-expression clause " "must be a catch-all."), throw(error) end; _ -> error_msg("receive-expression clause must " "have exactly one pattern."), throw(error) end; _ -> error_msg("receive-expressions must have " "exactly one clause."), throw(error) end. %% There are a number of primitives to do the work involved in receiving %% messages: %% %% if-tests: suspend_msg_timeout() %% %% primops: V = check_get_msg() %% select_msg() %% next_msg() %% set_timeout(T) %% clear_timeout() %% suspend_msg() %% %% `check_get_msg' tests if the mailbox is empty or not, and if not it %% reads the message currently pointed to by the implicit message pointer. %% `select_msg' removes the current message from the mailbox, resets the %% message pointer and clears any timeout. `next_msg' advances the %% message pointer but does nothing else. `set_timeout(T)' sets up the %% timeout mechanism *unless it is already set*. `suspend_msg' suspends %% until a message has arrived and does not check for timeout. The test %% `suspend_msg_timeout' suspends the process and upon resuming %% execution selects the `true' branch if a message has arrived and the %% `false' branch otherwise. `clear_timeout' resets the message pointer %% when a timeout has occurred (the name is somewhat misleading). %% %% Note: the receiving of a message must be performed so that the %% message pointer is always reset when the receive is done; thus, all %% paths must go through either `select_msg' or `clear_timeout'. %% Recall that the `final' and `effect' context flags distribute over %% the clauses *and* the timeout action (but not over the %% timeout-expression, which is always executed for its value). %% This is the code we generate for a full receive: %% %% Loop: check_get_msg(Match, Wait) %% Wait: set_timeout %% suspend_msg_timeout(Loop, Timeout) %% Timeout: clear_timeout %% TIMEOUT-ACTION %% goto Next %% Match: RECEIVE-CLAUSES(Loop, Next) %% Next: ... %% %% For a receive with infinity timout, we generate %% %% Wait: suspend_msg %% goto Loop %% %% For a receive with zero timout, we generate %% %% Wait: clear_timeout %% TIMEOUT-ACTION %% goto Next expr_receive_2(C, E, F, Ctxt, Env, S0) -> Expiry = cerl_lib:reduce_expr(cerl:receive_timeout(E)), After = case cerl:is_literal(Expiry) of true -> cerl:concrete(Expiry); false -> undefined end, T = make_var(), % T will hold the timeout value %% It would be harmless to generate code for `infinity', but we %% might as well avoid it if we can. S1 = if After =:= 'infinity' -> S0; true -> expr(Expiry, [T], Ctxt#ctxt{final = false, effect = false}, Env, S0) end, %% This is the top of the receive-loop, which checks if the %% mailbox is empty, and otherwise reads the next message. Loop = new_label(), Wait = new_label(), Match = new_label(), V = make_var(), S2 = add_code([icode_label(Loop), icode_call_primop([V], ?OP_CHECK_GET_MESSAGE, [], Match, Wait), icode_label(Wait)], S1), %% The wait-for-message section looks a bit different depending on %% whether we actually need to set a timer or not. Ctxt0 = #ctxt{}, S3 = case After of 'infinity' -> %% Only wake up when we get new messages, and never %% execute the expiry body. add_code(make_op(?OP_WAIT_FOR_MESSAGE, [], [], Ctxt0) ++ [icode_goto(Loop)], S2); 0 -> %% Zero limit - reset the message pointer (this is what %% "clear timeout" does) and execute the expiry body. add_code(make_op(?OP_CLEAR_TIMEOUT, [], [], Ctxt0), S2); _ -> %% Other value - set the timer (if it is already set, %% nothing is changed) and wait for a message or %% timeout. Reset the message pointer upon timeout. Timeout = new_label(), add_code(make_op(?OP_SET_TIMEOUT, [], [T], Ctxt0) ++ [make_if(?TEST_WAIT_FOR_MESSAGE_OR_TIMEOUT, [], Loop, Timeout), icode_label(Timeout)] ++ make_op(?OP_CLEAR_TIMEOUT, [], [], Ctxt0), S2) end, %% We never generate code for the expiry body if the timeout value %% is 'infinity' (and thus we know that it will not be used), mainly %% because in this case it is possible (and legal) for the expiry %% body to not have the expected degree. (Typically, it produces a %% single constant value such as 'true', while the clauses may be %% producing 2 or more values.) Next = new_continuation_label(Ctxt), S4 = if After =:= 'infinity' -> S3; true -> add_continuation_jump(Next, Ctxt, F(cerl:receive_action(E), Ctxt, Env, S3)) end, %% When we compile the primitive operations that select the current %% message or loop to try the next message (see the functions %% 'primop_receive_next' and 'primop_receive_select'), we will use %% the receive-loop label in the context (i.e., that of the nearest %% enclosing receive expression). Ctxt1 = Ctxt#ctxt{'receive' = #'receive'{loop = Loop}}, %% The pattern variable of the clause will be mapped to `V', which %% holds the message, so it can be accessed in the clause body: S5 = clauses([C], F, [V], Ctxt1, Env, add_code([icode_label(Match)], S4)), add_continuation_label(Next, Ctxt, S5). %% Primops supporting "expanded" receive-expressions on the Core level: primop_receive_next(#ctxt{'receive' = R} = Ctxt, S0) -> case R of #'receive'{loop = Loop} -> %% Note that this has the same "problem" as the fail %% instruction (see the 'add_fail' function), namely, that %% it unexpectedly ends a basic block. The solution is the %% same - add a dummy label if necessary. S1 = add_code(make_op(?OP_NEXT_MESSAGE, [], [], #ctxt{}) ++ [icode_goto(Loop)], S0), add_new_continuation_label(Ctxt, S1); _ -> error_not_in_receive(?PRIMOP_RECEIVE_NEXT), throw(error) end. primop_receive_select(Ts, #ctxt{'receive' = R} = Ctxt, S) -> case R of #'receive'{} -> add_code(make_op(?OP_SELECT_MESSAGE, Ts, [], Ctxt), S); _ -> error_not_in_receive(?PRIMOP_RECEIVE_SELECT), throw(error) end. %% --------------------------------------------------------------------- %% Case expressions %% Typically, pattern matching compilation has split all switches into %% separate groups of tuples, integers, atoms, etc., where each such %% switch over a group of constructors is protected by a type test. %% Thus, it is straightforward to generate switch instructions. (If no %% pattern matching compilation has been done, we don't care about %% efficiency anyway, so we don't spend any extra effort here.) expr_case(E, Ts, Ctxt, Env, S) -> F = fun (BF, CtxtF, EnvF, SF) -> expr(BF, Ts, CtxtF, EnvF, SF) end, expr_case_1(E, F, Ctxt, Env, S). expr_case_1(E, F, Ctxt, Env, S) -> Cs = cerl:case_clauses(E), A = cerl:case_arg(E), case cerl_lib:is_bool_switch(Cs) of true -> %% An if-then-else with a known boolean argument {True, False} = cerl_lib:bool_switch_cases(Cs), bool_switch(A, True, False, F, Ctxt, Env, S); false -> Vs = make_vars(cerl:clause_arity(hd(Cs))), Ctxt1 = Ctxt#ctxt{final = false, effect = false}, S1 = expr(A, Vs, Ctxt1, Env, S), expr_case_2(Vs, Cs, F, Ctxt, Env, S1) end. %% Switching on a value expr_case_2(Vs, Cs, F, Ctxt, Env, S1) -> case is_constant_switch(Cs) of true -> switch_val_clauses(Cs, F, Vs, Ctxt, Env, S1); false -> case is_tuple_switch(Cs) of true -> switch_tuple_clauses(Cs, F, Vs, Ctxt, Env, S1); false -> case is_binary_switch(Cs, S1) of true -> switch_binary_clauses(Cs, F, Vs, Ctxt, Env, S1); false -> clauses(Cs, F, Vs, Ctxt, Env, S1) end end end. %% Check if a list of clauses represents a switch over a number (more %% than 1) of constants (integers or atoms), or tuples (whose elements %% are all variables) is_constant_switch(Cs) -> is_switch(Cs, fun (P) -> (cerl:type(P) =:= literal) andalso (is_integer(cerl:concrete(P)) orelse is_atom(cerl:concrete(P))) end). is_tuple_switch(Cs) -> is_switch(Cs, fun (P) -> cerl:is_c_tuple(P) andalso all_vars(cerl:tuple_es(P)) end). is_binary_switch(Cs, S) -> case s__get_pmatch(S) of False when False =:= false; False =:= undefined -> false; Other when Other =:= duplicate_all; Other =:= no_duplicates; Other =:= true-> is_binary_switch1(Cs, 0) end. is_binary_switch1([C|Cs], N) -> case cerl:clause_pats(C) of [P] -> case cerl:is_c_binary(P) of true -> is_binary_switch1(Cs, N + 1); false -> %% The final clause may be a catch-all. Cs =:= [] andalso N > 0 andalso cerl:type(P) =:= var end; _ -> false end; is_binary_switch1([], N) -> N > 0. all_vars([E | Es]) -> case cerl:is_c_var(E) of true -> all_vars(Es); false -> false end; all_vars([]) -> true. is_switch(Cs, F) -> is_switch(Cs, F, 0). is_switch([C | Cs], F, N) -> case cerl_lib:is_simple_clause(C) of true -> [P] = cerl:clause_pats(C), case F(P) of true -> is_switch(Cs, F, N + 1); false -> %% The final clause may be a catch-all. Cs =:= [] andalso N > 1 andalso cerl:type(P) =:= var end; false -> false end; is_switch([], _F, N) -> N > 1. switch_val_clauses(Cs, F, Vs, Ctxt, Env, S) -> switch_clauses(Cs, F, Vs, Ctxt, Env, fun (P) -> cerl:concrete(P) end, fun icode_switch_val/4, fun val_clause_body/9, S). val_clause_body(_N, _V, C, F, Next, _Fail, Ctxt, Env, S) -> clause_body(C, F, Next, Ctxt, Env, S). switch_tuple_clauses(Cs, F, Vs, Ctxt, Env, S) -> switch_clauses(Cs, F, Vs, Ctxt, Env, fun (P) -> cerl:tuple_arity(P) end, fun icode_switch_tuple_arity/4, fun tuple_clause_body/9, S). tuple_clause_body(N, V, C, F, Next, Fail, Ctxt, Env, S0) -> Vs = make_vars(N), S1 = tuple_elements(Vs, V, S0), Es = cerl:tuple_es(hd(cerl:clause_pats(C))), {Env1, S2} = patterns(Es, Vs, Fail, Env, S1), clause_body(C, F, Next, Ctxt, Env1, S2). switch_clauses(Cs, F, [V], Ctxt, Env, GetVal, Switch, Body, S0) -> Cs1 = [switch_clause(C, GetVal) || C <- Cs], Cases = [{Val, L} || {Val, L, _} <- Cs1], Default = [C || {default, C} <- Cs1], Fail = new_label(), S1 = add_code([Switch(V, Fail, length(Cases), Cases)], S0), Next = new_continuation_label(Ctxt), S3 = case Default of [] -> add_default_case(Fail, Ctxt, S1); [C] -> %% Bind the catch-all variable (this always succeeds) {Env1, S2} = patterns(cerl:clause_pats(C), [V], Fail, Env, S1), clause_body(C, F, Next, Ctxt, Env1, add_code([icode_label(Fail)], S2)) end, S4 = switch_cases(Cs1, V, F, Next, Fail, Ctxt, Env, Body, S3), add_continuation_label(Next, Ctxt, S4). switch_clause(C, F) -> [P] = cerl:clause_pats(C), L = new_label(), case cerl:type(P) of var -> {default, C}; _ -> {icode_const(F(P)), L, C} end. switch_binary_clauses(Cs, F, Vs, Ctxt, Env, S) -> {Bins, Default} = get_binary_clauses(Cs), Fail = new_label(), Next = new_continuation_label(Ctxt), S1 = binary_match(Bins, F, Vs, Next, Fail, Ctxt, Env, S), S2 = case Default of [] -> add_default_case(Fail, Ctxt, S1); [C] -> clause_body(C, F, Next, Ctxt, Env, add_code([icode_label(Fail)], S1)) end, add_continuation_label(Next, Ctxt, S2). get_binary_clauses(Cs) -> get_binary_clauses(Cs, []). get_binary_clauses([C|Cs], Acc) -> [P] = cerl:clause_pats(C), case cerl:is_c_binary(P) of true -> get_binary_clauses(Cs, [C|Acc]); false -> {lists:reverse(Acc),[C]} end; get_binary_clauses([], Acc) -> {lists:reverse(Acc),[]}. switch_cases([{N, L, C} | Cs], V, F, Next, Fail, Ctxt, Env, Body, S0) -> S1 = add_code([icode_label(L)], S0), S2 = Body(icode_const_val(N), V, C, F, Next, Fail, Ctxt, Env, S1), switch_cases(Cs, V, F, Next, Fail, Ctxt, Env, Body, S2); switch_cases([_ | Cs], V, F, Next, Fail, Ctxt, Env, Body, S) -> switch_cases(Cs, V, F, Next, Fail, Ctxt, Env, Body, S); switch_cases([], _V, _F, _Next, _Fail, _Ctxt, _Env, _Body, S) -> S. %% Recall that the `final' and `effect' context flags distribute over %% the clause bodies. clauses(Cs, F, Vs, Ctxt, Env, S) -> Next = new_continuation_label(Ctxt), S1 = clauses_1(Cs, F, Vs, undefined, Next, Ctxt, Env, S), add_continuation_label(Next, Ctxt, S1). clauses_1([C | Cs], F, Vs, Fail, Next, Ctxt, Env, S) -> case cerl_clauses:is_catchall(C) of true -> %% The fail label will not actually be used in this case. clause(C, F, Vs, Fail, Next, Ctxt, Env, S); false -> %% The previous `Fail' is not used here. Fail1 = new_label(), S1 = clause(C, F, Vs, Fail1, Next, Ctxt, Env, S), S2 = add_code([icode_label(Fail1)], S1), clauses_1(Cs, F, Vs, Fail1, Next, Ctxt, Env, S2) end; clauses_1([], _F, _Vs, Fail, _Next, Ctxt, _Env, S) -> if Fail =:= undefined -> L = new_label(), add_default_case(L, Ctxt, S); true -> add_code([icode_goto(Fail)], S) % use existing label end. %% The exact behaviour if all clauses fail is undefined; we generate an %% 'internal_error' exception if this happens, which is safe and will %% not get in the way of later analyses. (Continuing execution after the %% `case', as in a C `switch' statement, would add a new possible path %% to the program, which could destroy program properties.) Note that %% this code is only generated if some previous stage has created a %% switch over clauses without a final catch-all; this could be both %% legal and non-redundant, e.g. if the last clause does pattern %% matching to extract components of a (known) constructor. The %% generated default-case code *should* be unreachable, but we need it %% in order to have a safe fail-label. add_default_case(L, Ctxt, S) -> S1 = add_code([icode_label(L)], S), add_error(icode_const(internal_error), Ctxt, S1). clause(C, F, Vs, Fail, Next, Ctxt, Env, S) -> G = cerl:clause_guard(C), case cerl_clauses:eval_guard(G) of {value, true} -> {Env1, S1} = patterns(cerl:clause_pats(C), Vs, Fail, Env, S), clause_body(C, F, Next, Ctxt, Env1, S1); {value, false} -> add_code([icode_goto(Fail)], S); _ -> {Env1, S1} = patterns(cerl:clause_pats(C), Vs, Fail, Env, S), Succ = new_label(), Ctxt1 = Ctxt#ctxt{final = false, fail = Fail, class = guard}, S2 = boolean(G, Succ, Fail, Ctxt1, Env1, S1), S3 = add_code([icode_label(Succ)], S2), clause_body(C, F, Next, Ctxt, Env1, S3) end. clause_body(C, F, Next, Ctxt, Env, S) -> %% This check is inserted as a goto is always final case is_goto(cerl:clause_body(C)) of true -> F(cerl:clause_body(C), Ctxt, Env, S); false -> S1 = F(cerl:clause_body(C), Ctxt, Env, S), add_continuation_jump(Next, Ctxt, S1) end. patterns([P | Ps], [V | Vs], Fail, Env, S) -> {Env1, S1} = pattern(P, V, Fail, Env, S), patterns(Ps, Vs, Fail, Env1, S1); patterns([], [], _, Env, S) -> {Env, S}. pattern(P, V, Fail, Env, S) -> case cerl:type(P) of var -> {bind_var(P, V, Env), S}; alias -> {Env1, S1} = pattern(cerl:alias_pat(P), V, Fail, Env, S), {bind_var(cerl:alias_var(P), V, Env1), S1}; literal -> {Env, literal_pattern(P, V, Fail, S)}; cons -> cons_pattern(P, V, Fail, Env, S); tuple -> tuple_pattern(P, V, Fail, Env, S); binary -> binary_pattern(P, V, Fail, Env, S) end. literal_pattern(P, V, Fail, S) -> L = new_label(), S1 = literal_pattern_1(P, V, Fail, L, S), add_code([icode_label(L)], S1). literal_pattern_1(P, V, Fail, Next, S) -> case cerl:concrete(P) of X when is_atom(X) -> add_code([make_type([V], ?TYPE_ATOM(X), Next, Fail)], S); X when is_integer(X) -> add_code([make_type([V], ?TYPE_INTEGER(X), Next, Fail)], S); X when is_float(X) -> V1 = make_var(), L = new_label(), %% First doing an "is float" test here might allow later %% stages to use a specialized equality test. add_code([make_type([V], ?TYPE_IS_FLOAT, L, Fail), icode_label(L), icode_move(V1, icode_const(X)), make_if(?TEST_EQ, [V, V1], Next, Fail)], S); [] -> add_code([make_type([V], ?TYPE_NIL, Next, Fail)], S); X -> %% Compound constants are compared with the generic exact %% equality test. V1 = make_var(), add_code([icode_move(V1, icode_const(X)), make_if(?TEST_EXACT_EQ, [V, V1], Next, Fail)], S) end. cons_pattern(P, V, Fail, Env, S) -> V1 = make_var(), V2 = make_var(), Next = new_label(), Ctxt = #ctxt{}, S1 = add_code([make_type([V], ?TYPE_CONS, Next, Fail), icode_label(Next)] ++ make_op(?OP_UNSAFE_HD, [V1], [V], Ctxt) ++ make_op(?OP_UNSAFE_TL, [V2], [V], Ctxt), S), patterns([cerl:cons_hd(P), cerl:cons_tl(P)], [V1, V2], Fail, Env, S1). tuple_pattern(P, V, Fail, Env, S) -> Es = cerl:tuple_es(P), N = length(Es), Vs = make_vars(N), Next = new_label(), S1 = add_code([make_type([V], ?TYPE_IS_N_TUPLE(N), Next, Fail), icode_label(Next)], S), S2 = tuple_elements(Vs, V, S1), patterns(Es, Vs, Fail, Env, S2). tuple_elements(Vs, V, S) -> tuple_elements(Vs, V, #ctxt{}, 1, S). tuple_elements([V1 | Vs], V0, Ctxt, N, S) -> Code = make_op(?OP_UNSAFE_ELEMENT(N), [V1], [V0], Ctxt), tuple_elements(Vs, V0, Ctxt, N + 1, add_code(Code, S)); tuple_elements([], _, _, _, S) -> S. binary_pattern(P, V, Fail, Env, S) -> L1 = new_label(), Segs = cerl:binary_segments(P), Arity = length(Segs), Vars = make_vars(Arity), MS = make_var(), Primop1 = {hipe_bs_primop, {bs_start_match,0}}, S1 = add_code([icode_guardop([MS], Primop1, [V], L1, Fail), icode_label(L1)],S), {Env1,S2} = bin_seg_patterns(Segs, Vars, MS, Fail, Env, S1, false), L2 = new_label(), Primop2 = {hipe_bs_primop, {bs_test_tail, 0}}, {Env1, add_code([icode_guardop([], Primop2, [MS], L2, Fail), icode_label(L2)], S2)}. bin_seg_patterns([Seg|Rest], [T|Ts], MS, Fail, Env, S, Align) -> {{NewEnv, S1}, NewAlign} = bin_seg_pattern(Seg, T, MS, Fail, Env, S, Align), bin_seg_patterns(Rest, Ts, MS, Fail, NewEnv, S1, NewAlign); bin_seg_patterns([], [], _MS, _Fail, Env, S, _Align) -> {Env, S}. bin_seg_pattern(P, V, MS, Fail, Env, S, Align) -> L = new_label(), Size = cerl:bitstr_size(P), Unit = cerl:bitstr_unit(P), Type = cerl:concrete(cerl:bitstr_type(P)), LiteralFlags = cerl:bitstr_flags(P), T = cerl:bitstr_val(P), Flags = translate_flags(LiteralFlags, Align), case calculate_size(Unit, Size, false, Env, S) of {all, NewUnit, NewAlign, S0} -> Type = binary, Name = {bs_get_binary_all_2, NewUnit, Flags}, Primop = {hipe_bs_primop, Name}, S1 = add_code([icode_guardop([V,MS], Primop, [MS], L, Fail), icode_label(L)], S0), {pattern(T, V, Fail, Env, S1), NewAlign}; {NewUnit, Args, S0, NewAlign} -> Name = case Type of integer -> {bs_get_integer, NewUnit, Flags}; float -> {bs_get_float, NewUnit, Flags}; binary -> {bs_get_binary, NewUnit, Flags} end, Primop = {hipe_bs_primop, Name}, S1 = add_code([icode_guardop([V,MS], Primop, [MS|Args], L, Fail), icode_label(L)], S0), {pattern(T, V, Fail, Env, S1), NewAlign} end. %% --------------------------------------------------------------------- %% Boolean expressions %% This generates code for a boolean expression (such as "primop %% 'and'(X, Y)") in a normal expression context, when an actual `true' %% or `false' value is to be computed. We set up a default fail-label %% for generating a `badarg' error, unless we are in a guard. boolean_expr(E, [V], Ctxt=#ctxt{class = guard}, Env, S) -> {Code, True, False} = make_bool_glue(V), S1 = boolean(E, True, False, Ctxt, Env, S), add_code(Code, S1); boolean_expr(E, [V] = Ts, Ctxt, Env, S) -> {Code, True, False} = make_bool_glue(V), Fail = new_label(), Cont = new_continuation_label(Ctxt), Ctxt1 = Ctxt#ctxt{final = false, effect = false, fail = Fail}, S1 = boolean(E, True, False, Ctxt1, Env, S), S2 = maybe_return(Ts, Ctxt, add_code(Code, S1)), S3 = add_continuation_jump(Cont, Ctxt, S2), S4 = add_code([icode_label(Fail)], S3), S5 = add_error(icode_const(badarg), Ctxt, S4), % can add dummy label S6 = add_continuation_jump(Cont, Ctxt, S5), % avoid empty basic block add_continuation_label(Cont, Ctxt, S6); boolean_expr(_, [], _Ctxt, _Env, _S) -> error_high_degree(), throw(error); boolean_expr(_, _, _Ctxt, _Env, _S) -> error_low_degree(), throw(error). %% This is for when we expect a boolean result in jumping code context, %% but are not sure what the expression will produce, or we know that %% the result is not a boolean and we just want error handling. expect_boolean_value(E, True, False, Ctxt, Env, S) -> V = make_var(), S1 = expr(E, [V], Ctxt#ctxt{final = false}, Env, S), case Ctxt#ctxt.fail of [] -> %% No fail-label set - this means we are *sure* that the %% result can only be 'true' or 'false'. add_code([make_type([V], ?TYPE_ATOM(true), True, False)], S1); Fail -> Next = new_label(), add_code([make_type([V], ?TYPE_ATOM(true), True, Next), icode_label(Next), make_type([V], ?TYPE_ATOM(false), False, Fail)], S1) end. %% This generates code for a case-switch with exactly one 'true' branch %% and one 'false' branch, and no other branches (not even a catch-all). %% Note that E must be guaranteed to produce a boolean value for such a %% switch to have been generated. bool_switch(E, TrueExpr, FalseExpr, F, Ctxt, Env, S) -> Cont = new_continuation_label(Ctxt), True = new_label(), False = new_label(), Ctxt1 = Ctxt#ctxt{final = false, effect = false}, S1 = boolean(E, True, False, Ctxt1, Env, S), S2 = add_code([icode_label(True)], S1), S3 = F(TrueExpr, Ctxt, Env, S2), S4 = add_continuation_jump(Cont, Ctxt, S3), S5 = add_code([icode_label(False)], S4), S6 = F(FalseExpr, Ctxt, Env, S5), add_continuation_label(Cont, Ctxt, S6). %% This generates jumping code for booleans. If the fail-label is set, %% it tells where to go in case a value turns out not to be a boolean. %% In strict boolean expressions, we set a flag to be checked if %% necessary after both branches have been evaluated. An alternative %% would be to duplicate the code for the second argument, for each %% value ('true' or 'false') of the first argument. %% (Note that subexpressions are checked repeatedly to see if they are %% safe - this is quadratic, but I don't expect booleans to be very %% deeply nested.) %% Note that 'and', 'or' and 'xor' are strict (like all primops)! boolean(E0, True, False, Ctxt, Env, S) -> E = cerl_lib:reduce_expr(E0), case cerl:type(E) of literal -> case cerl:concrete(E) of true -> add_code([icode_goto(True)], S); false -> add_code([icode_goto(False)], S); _ -> expect_boolean_value(E, True, False, Ctxt, Env, S) end; values -> case cerl:values_es(E) of [E1] -> boolean(E1, True, False, Ctxt, Env, S); _ -> error_msg("degree mismatch - expected boolean: ~P", [E, 10]), throw(error) end; primop -> Name = cerl:atom_val(cerl:primop_name(E)), As = cerl:primop_args(E), Arity = length(As), case {Name, Arity} of {?PRIMOP_NOT, 1} -> %% `not' simply switches true and false labels. [A] = As, boolean(A, False, True, Ctxt, Env, S); {?PRIMOP_AND, 2} -> strict_and(As, True, False, Ctxt, Env, S); {?PRIMOP_OR, 2} -> strict_or(As, True, False, Ctxt, Env, S); {?PRIMOP_XOR, 2} -> %% `xor' always needs to evaluate both arguments strict_xor(As, True, False, Ctxt, Env, S); _ -> case is_comp_op(Name, Arity) of true -> comparison(Name, As, True, False, Ctxt, Env, S); false -> case is_type_test(Name, Arity) of true -> type_test(Name, As, True, False, Ctxt, Env, S); false -> expect_boolean_value(E, True, False, Ctxt, Env, S) end end end; 'case' -> %% Propagate boolean handling into clause bodies. %% (Note that case switches assume fallthrough code in the %% clause bodies, so we must add a dummy label as needed.) F = fun (BF, CtxtF, EnvF, SF) -> SF1 = boolean(BF, True, False, CtxtF, EnvF, SF), add_new_continuation_label(CtxtF, SF1) end, S1 = expr_case_1(E, F, Ctxt, Env, S), %% Add a final goto if necessary, to compensate for the %% final continuation label of the case-expression. This %% should be unreachable, so the value does not matter. add_continuation_jump(False, Ctxt, S1); seq -> %% Propagate boolean handling into body. F = fun (BF, CtxtF, EnvF, SF) -> boolean(BF, True, False, CtxtF, EnvF, SF) end, expr_seq_1(E, F, Ctxt, Env, S); 'let' -> %% Propagate boolean handling into body. Note that we have %% called 'cerl_lib:reduce_expr/1' above. F = fun (BF, CtxtF, EnvF, SF) -> boolean(BF, True, False, CtxtF, EnvF, SF) end, expr_let_1(E, F, Ctxt, Env, S); 'try' -> case Ctxt#ctxt.class of guard -> %% This *must* be a "protected" guard expression on %% the form "try E of X -> X catch <...> -> 'false'" %% (we could of course test if the handler body is %% the atom 'false', etc.). Ctxt1 = Ctxt#ctxt{fail = False}, boolean(cerl:try_arg(E), True, False, Ctxt1, Env, S); _ -> %% Propagate boolean handling into the handler and body %% (see propagation into case switches for comparison) F = fun (BF, CtxtF, EnvF, SF) -> boolean(BF, True, False, CtxtF, EnvF, SF) end, S1 = expr_try_1(E, F, Ctxt, Env, S), add_continuation_jump(False, Ctxt, S1) end; _ -> %% This handles everything else, including cases that are %% known to not return a boolean. expect_boolean_value(E, True, False, Ctxt, Env, S) end. strict_and([A, B], True, False, Ctxt, Env, S) -> V = make_var(), {Glue, True1, False1} = make_bool_glue(V), S1 = boolean(A, True1, False1, Ctxt, Env, S), S2 = add_code(Glue, S1), Test = new_label(), S3 = boolean(B, Test, False, Ctxt, Env, S2), add_code([icode_label(Test), make_bool_test(V, True, False)], S3). strict_or([A, B], True, False, Ctxt, Env, S) -> V = make_var(), {Glue, True1, False1} = make_bool_glue(V), S1 = boolean(A, True1, False1, Ctxt, Env, S), S2 = add_code(Glue, S1), Test = new_label(), S3 = boolean(B, True, Test, Ctxt, Env, S2), add_code([icode_label(Test), make_bool_test(V, True, False)], S3). strict_xor([A, B], True, False, Ctxt, Env, S) -> V = make_var(), {Glue, True1, False1} = make_bool_glue(V), S1 = boolean(A, True1, False1, Ctxt, Env, S), S2 = add_code(Glue, S1), Test1 = new_label(), Test2 = new_label(), S3 = boolean(B, Test1, Test2, Ctxt, Env, S2), add_code([icode_label(Test1), make_bool_test(V, False, True), icode_label(Test2), make_bool_test(V, True, False)], S3). %% Primitive comparison operations are inline expanded as conditional %% branches when part of a boolean expression, rather than made into %% primop or guardop calls. Note that Without type information, we %% cannot reduce equality tests like `Expr == true' to simply `Expr' %% (and `Expr == false' to `not Expr'), because we are not sure that %% Expr will yield a boolean - if it does not, the result of the %% comparison should be `false'. comparison(Name, As, True, False, Ctxt, Env, S) -> {Vs, S1} = expr_list(As, Ctxt, Env, S), Test = comp_test(Name), add_code([make_if(Test, Vs, True, False)], S1). comp_test(?PRIMOP_EQ) -> ?TEST_EQ; comp_test(?PRIMOP_NE) -> ?TEST_NE; comp_test(?PRIMOP_EXACT_EQ) -> ?TEST_EXACT_EQ; comp_test(?PRIMOP_EXACT_NE) -> ?TEST_EXACT_NE; comp_test(?PRIMOP_LT) -> ?TEST_LT; comp_test(?PRIMOP_GT) -> ?TEST_GT; comp_test(?PRIMOP_LE) -> ?TEST_LE; comp_test(?PRIMOP_GE) -> ?TEST_GE. type_test(?PRIMOP_IS_RECORD, [T, A, N], True, False, Ctxt, Env, S) -> is_record_test(T, A, N, True, False, Ctxt, Env, S); type_test(Name, [A], True, False, Ctxt, Env, S) -> V = make_var(), S1 = expr(A, [V], Ctxt#ctxt{final = false, effect = false}, Env, S), Test = type_test(Name), add_code([make_type([V], Test, True, False)], S1). %% It turned out to be easiest to generate Icode directly for this. is_record_test(T, A, N, True, False, Ctxt, Env, S) -> case cerl:is_c_atom(A) andalso cerl:is_c_int(N) andalso (cerl:concrete(N) > 0) of true -> V = make_var(), Ctxt1 = Ctxt#ctxt{final = false, effect = false}, S1 = expr(T, [V], Ctxt1, Env, S), Atom = cerl:concrete(A), Size = cerl:concrete(N), add_code([make_type([V], ?TYPE_IS_RECORD(Atom, Size), True, False)], S1); false -> error_primop_badargs(?PRIMOP_IS_RECORD, [T, A, N]), throw(error) end. type_test(?PRIMOP_IS_ATOM) -> ?TYPE_IS_ATOM; type_test(?PRIMOP_IS_BIGNUM) -> ?TYPE_IS_BIGNUM; type_test(?PRIMOP_IS_BINARY) -> ?TYPE_IS_BINARY; type_test(?PRIMOP_IS_FIXNUM) -> ?TYPE_IS_FIXNUM; type_test(?PRIMOP_IS_FLOAT) -> ?TYPE_IS_FLOAT; type_test(?PRIMOP_IS_FUNCTION) -> ?TYPE_IS_FUNCTION; type_test(?PRIMOP_IS_INTEGER) -> ?TYPE_IS_INTEGER; type_test(?PRIMOP_IS_LIST) -> ?TYPE_IS_LIST; type_test(?PRIMOP_IS_NUMBER) -> ?TYPE_IS_NUMBER; type_test(?PRIMOP_IS_PID) -> ?TYPE_IS_PID; type_test(?PRIMOP_IS_PORT) -> ?TYPE_IS_PORT; type_test(?PRIMOP_IS_REFERENCE) -> ?TYPE_IS_REFERENCE; type_test(?PRIMOP_IS_TUPLE) -> ?TYPE_IS_TUPLE. is_comp_op(?PRIMOP_EQ, 2) -> true; is_comp_op(?PRIMOP_NE, 2) -> true; is_comp_op(?PRIMOP_EXACT_EQ, 2) -> true; is_comp_op(?PRIMOP_EXACT_NE, 2) -> true; is_comp_op(?PRIMOP_LT, 2) -> true; is_comp_op(?PRIMOP_GT, 2) -> true; is_comp_op(?PRIMOP_LE, 2) -> true; is_comp_op(?PRIMOP_GE, 2) -> true; is_comp_op(Op, A) when is_atom(Op), is_integer(A) -> false. is_bool_op(?PRIMOP_AND, 2) -> true; is_bool_op(?PRIMOP_OR, 2) -> true; is_bool_op(?PRIMOP_XOR, 2) -> true; is_bool_op(?PRIMOP_NOT, 1) -> true; is_bool_op(Op, A) when is_atom(Op), is_integer(A) -> false. is_type_test(?PRIMOP_IS_ATOM, 1) -> true; is_type_test(?PRIMOP_IS_BIGNUM, 1) -> true; is_type_test(?PRIMOP_IS_BINARY, 1) -> true; is_type_test(?PRIMOP_IS_FIXNUM, 1) -> true; is_type_test(?PRIMOP_IS_FLOAT, 1) -> true; is_type_test(?PRIMOP_IS_FUNCTION, 1) -> true; is_type_test(?PRIMOP_IS_INTEGER, 1) -> true; is_type_test(?PRIMOP_IS_LIST, 1) -> true; is_type_test(?PRIMOP_IS_NUMBER, 1) -> true; is_type_test(?PRIMOP_IS_PID, 1) -> true; is_type_test(?PRIMOP_IS_PORT, 1) -> true; is_type_test(?PRIMOP_IS_REFERENCE, 1) -> true; is_type_test(?PRIMOP_IS_TUPLE, 1) -> true; is_type_test(?PRIMOP_IS_RECORD, 3) -> true; is_type_test(Op, A) when is_atom(Op), is_integer(A) -> false. %% --------------------------------------------------------------------- %% Utility functions bind_var(V, Name, Env) -> env__bind(cerl:var_name(V), #cerl_to_icode__var{name = Name}, Env). bind_vars([V | Vs], [X | Xs], Env) -> bind_vars(Vs, Xs, bind_var(V, X, Env)); bind_vars([], [], Env) -> Env. bind_fun(V, L, Vs, Env) -> env__bind(cerl:var_name(V), #'fun'{label = L, vars = Vs}, Env). add_code(Code, S) -> s__add_code(Code, S). %% This inserts code when necessary for assigning the targets in the %% first list to those in the second. glue([V1 | Vs1], [V2 | Vs2], S) -> if V1 =:= V2 -> S; true -> glue(Vs1, Vs2, add_code([icode_move(V2, V1)], S)) end; glue([], [], S) -> S; glue([], _, S) -> warning_low_degree(), S; glue(_, [], _) -> error_high_degree(), throw(error). make_moves([V1 | Vs1], [V2 | Vs2]) -> [icode_move(V1, V2) | make_moves(Vs1, Vs2)]; make_moves([], []) -> []. %% If the context signals `final', we generate a return instruction, %% otherwise nothing happens. maybe_return(Ts, Ctxt, S) -> case Ctxt#ctxt.final of false -> S; true -> add_return(Ts, S) end. add_return(Ts, S) -> add_code([icode_return(Ts)], S). new_continuation_label(Ctxt) -> case Ctxt#ctxt.final of false -> new_label(); true -> undefined end. add_continuation_label(Label, Ctxt, S) -> case Ctxt#ctxt.final of false -> add_code([icode_label(Label)], S); true -> S end. add_continuation_jump(Label, Ctxt, S) -> case Ctxt#ctxt.final of false -> add_code([icode_goto(Label)], S); true -> S end. %% This is used to insert a new dummy label (if necessary) when %% a block is ended suddenly; cf. add_fail. add_new_continuation_label(Ctxt, S) -> add_continuation_label(new_continuation_label(Ctxt), Ctxt, S). add_local_call({Name, _Arity} = V, Vs, Ts, Ctxt, S) -> Module = s__get_module(S), case Ctxt#ctxt.final of false -> add_code([icode_call_local(Ts, Module, Name, Vs)], S); true -> Self = s__get_function(S), if V =:= Self -> %% Self-recursive tail call: {Label, Vs1} = s__get_local_entry(S), add_code(make_moves(Vs1, Vs) ++ [icode_goto(Label)], S); true -> add_code([icode_enter_local(Module, Name, Vs)], S) end end. %% Note that this has the same "problem" as the fail instruction (see %% the 'add_fail' function), namely, that it unexpectedly ends a basic %% block. The solution is the same - add a dummy label if necessary. add_letrec_call(Label, Vs1, Vs, Ctxt, S) -> S1 = add_code(make_moves(Vs1, Vs) ++ [icode_goto(Label)], S), add_new_continuation_label(Ctxt, S1). add_exit(V, Ctxt, S) -> add_fail([V], exit, Ctxt, S). add_throw(V, Ctxt, S) -> add_fail([V], throw, Ctxt, S). add_error(V, Ctxt, S) -> add_fail([V], error, Ctxt, S). add_error(V, F, Ctxt, S) -> add_fail([V, F], error, Ctxt, S). add_rethrow(E, V, Ctxt, S) -> add_fail([E, V], rethrow, Ctxt, S). %% Failing is special, because it can "suddenly" end the basic block, %% even though the context was expecting the code to fall through, for %% instance when you have a call to 'exit(X)' that is not in a tail call %% context. In those cases a dummy label must therefore be added after %% the fail instruction, to start a new (but unreachable) basic block. add_fail(Vs, Class, Ctxt, S0) -> S1 = add_code([icode_fail(Vs, Class)], S0), add_new_continuation_label(Ctxt, S1). %% We must add continuation- and fail-labels if we are in a guard context. make_op(Name, Ts, As, Ctxt) -> case Ctxt#ctxt.final of false -> case Ctxt#ctxt.class of guard -> Next = new_label(), [icode_guardop(Ts, Name, As, Next, Ctxt#ctxt.fail), icode_label(Next)]; _ -> [icode_call_primop(Ts, Name, As)] end; true -> [icode_enter_primop(Name, As)] end. make_call(M, F, Ts, As, Ctxt) -> case Ctxt#ctxt.final of false -> case Ctxt#ctxt.class of guard -> Next = new_label(), [icode_call_remote(Ts, M, F, As, Next, Ctxt#ctxt.fail, true), icode_label(Next)]; _ -> [icode_call_remote(Ts, M, F, As)] end; true -> %% A final call can't be in a guard anyway [icode_enter_remote(M, F, As)] end. %% Recognize useless tests that always go to the same label. This often %% happens as an artefact of the translation. make_if(_, _, Label, Label) -> icode_goto(Label); make_if(Test, As, True, False) -> icode_if(Test, As, True, False). make_type(_, _, Label, Label) -> icode_goto(Label); make_type(Vs, Test, True, False) -> icode_type(Vs, Test, True, False). %% Creating glue code with true/false target labels for assigning a %% corresponding 'true'/'false' value to a specific variable. Used as %% glue between boolean jumping code and boolean values. make_bool_glue(V) -> make_bool_glue(V, true, false). make_bool_glue(V, T, F) -> False = new_label(), True = new_label(), Next = new_label(), Code = [icode_label(False), icode_move(V, icode_const(F)), icode_goto(Next), icode_label(True), icode_move(V, icode_const(T)), icode_label(Next)], {Code, True, False}. make_bool_test(V, True, False) -> make_type([V], ?TYPE_ATOM(true), True, False). %% Checking if an expression is safe is_safe_expr(E) -> cerl_lib:is_safe_expr(E, fun function_check/2). function_check(safe, {Name, Arity}) -> is_safe_op(Name, Arity); function_check(safe, {Module, Name, Arity}) -> erl_bifs:is_safe(Module, Name, Arity); function_check(pure, {Name, Arity}) -> is_pure_op(Name, Arity); function_check(pure, {Module, Name, Arity}) -> erl_bifs:is_pure(Module, Name, Arity); function_check(_, _) -> false. %% There are very few really safe operations (sigh!). If we have type %% information, several operations could be rewritten into specialized %% safe versions, such as '+'/2 -> add_integer/2. is_safe_op(N, A) -> is_comp_op(N, A) orelse is_type_test(N, A). is_pure_op(?PRIMOP_ELEMENT, 2) -> true; is_pure_op(?PRIMOP_MAKE_FUN, 6) -> true; is_pure_op(?PRIMOP_FUN_ELEMENT, 2) -> true; is_pure_op(?PRIMOP_ADD, 2) -> true; is_pure_op(?PRIMOP_SUB, 2) -> true; is_pure_op(?PRIMOP_NEG, 1) -> true; is_pure_op(?PRIMOP_MUL, 2) -> true; is_pure_op(?PRIMOP_DIV, 2) -> true; is_pure_op(?PRIMOP_INTDIV, 2) -> true; is_pure_op(?PRIMOP_REM, 2) -> true; is_pure_op(?PRIMOP_BAND, 2) -> true; is_pure_op(?PRIMOP_BOR, 2) -> true; is_pure_op(?PRIMOP_BXOR, 2) -> true; is_pure_op(?PRIMOP_BNOT, 1) -> true; is_pure_op(?PRIMOP_BSL, 2) -> true; is_pure_op(?PRIMOP_BSR, 2) -> true; is_pure_op(?PRIMOP_EXIT, 1) -> true; is_pure_op(?PRIMOP_THROW, 1) -> true; is_pure_op(?PRIMOP_ERROR, 1) -> true; is_pure_op(?PRIMOP_ERROR, 2) -> true; is_pure_op(?PRIMOP_RETHROW, 2) -> true; is_pure_op(N, A) -> is_pure_op_aux(N, A). is_pure_op_aux(N, A) -> is_bool_op(N, A) orelse is_comp_op(N, A) orelse is_type_test(N, A). translate_flags(Flags, Align) -> translate_flags1(cerl:concrete(Flags), Align). translate_flags1([A|Rest], Align) -> case A of signed -> 4 + translate_flags1(Rest, Align); little -> 2 + translate_flags1(Rest, Align); native -> case hipe_rtl_arch:endianess() of little -> 2 + translate_flags1(Rest, Align); big -> translate_flags1(Rest, Align) end; _ -> translate_flags1(Rest, Align) end; translate_flags1([], Align) -> case Align of 0 -> 1; _ -> 0 end. get_const_info(Val, integer) -> case {cerl:is_c_var(Val), cerl:is_c_int(Val)} of {true, _} -> var; {_, true} -> pass; _ -> fail end; get_const_info(Val, float) -> case {cerl:is_c_var(Val), cerl:is_c_float(Val)} of {true, _} -> var; {_, true} -> pass; _ -> fail end; get_const_info(_Val, _Type) -> []. calculate_size(Unit, Var, Align, Env, S) -> case cerl:is_c_atom(Var) of true -> {cerl:atom_val(Var), cerl:concrete(Unit), Align, S}; false -> case cerl:is_c_int(Var) of true -> NewVal = cerl:concrete(Var) * cerl:concrete(Unit), NewAlign = case Align of false -> false %% Currently, all uses of the function are %% with "Aligned == false", and this case %% is commented out to shut up Dialyzer. %% _ -> %% (NewVal+Align) band 7 end, {NewVal, [], S, NewAlign}; false -> NewSize = make_var(), S1 = expr(Var, [NewSize], #ctxt{final=false}, Env, S), NewAlign = case cerl:concrete(Unit) band 7 of 0 -> Align; _ -> false end, {cerl:concrete(Unit), [NewSize], S1, NewAlign} end end. %% --------------------------------------------------------------------- %% Environment (abstract datatype) env__new() -> rec_env:empty(). env__bind(Key, Val, Env) -> rec_env:bind(Key, Val, Env). env__lookup(Key, Env) -> rec_env:lookup(Key, Env). env__get(Key, Env) -> rec_env:get(Key, Env). %% env__new_integer_keys(N, Env) -> %% rec_env:new_keys(N, Env). %% --------------------------------------------------------------------- %% State (abstract datatype) -record(state, {module, function, local, labels=gb_trees:empty(), code = [], pmatch=true, bitlevel_binaries=false}). s__new(Module) -> #state{module = Module}. s__get_module(S) -> S#state.module. s__set_function(Name, S) -> S#state{function = Name}. s__get_function(S) -> S#state.function. s__set_local_entry(Info, S) -> S#state{local = Info}. s__get_local_entry(S) -> S#state.local. %% Generated code is kept in reverse order, to make adding fast. s__set_code(Code, S) -> S#state{code = lists:reverse(Code)}. s__get_code(S) -> lists:reverse(S#state.code). s__add_code(Code, S) -> S#state{code = lists:reverse(Code, S#state.code)}. s__get_label(Ref, S) -> Labels = S#state.labels, case gb_trees:lookup(Ref, Labels) of none -> Label = new_label(), S1 = S#state{labels=gb_trees:enter(Ref, Label, Labels)}, {Label, S1}; {value, Label} -> {Label,S} end. s__set_pmatch(V, S) -> S#state{pmatch = V}. s__get_pmatch(S) -> S#state.pmatch. s__set_bitlevel_binaries(true, S) -> S#state{bitlevel_binaries = true}; s__set_bitlevel_binaries(_, S) -> S#state{bitlevel_binaries = false}. s__get_bitlevel_binaries(S) -> S#state.bitlevel_binaries. %% --------------------------------------------------------------------- %%% Match label State %-record(mstate,{labels=gb_trees:empty()}). %get_correct_label(Alias, MState=#mstate{labels=Labels}) -> % case gb_trees:lookup(Alias, Labels) of % none -> % LabelName=new_label(), % {LabelName, MState#mstate{labels=gb_trees:insert(Alias, LabelName, Labels)}}; % {value, LabelName} -> % {LabelName, MState} % end. %% --------------------------------------------------------------------- %% General utilities reset_var_counter() -> hipe_gensym:set_var(0). reset_label_counter() -> hipe_gensym:set_label(0). new_var() -> hipe_gensym:get_next_var(). new_label() -> hipe_gensym:get_next_label(). max_var() -> hipe_gensym:get_var(). max_label() -> hipe_gensym:get_label(). make_var() -> icode_var(new_var()). make_vars(N) when N > 0 -> [make_var() | make_vars(N - 1)]; make_vars(0) -> []. make_reg() -> icode_reg(new_var()). %% --------------------------------------------------------------------- %% ICode interface icode_icode(M, {F, A}, Vs, Closure, C, V, L) -> MFA = {M, F, A}, hipe_icode:mk_icode(MFA, Vs, Closure, false, C, V, L). icode_icode_name(Icode) -> hipe_icode:icode_fun(Icode). icode_comment(S) -> hipe_icode:mk_comment(S). icode_var(V) -> hipe_icode:mk_var(V). icode_reg(V) -> hipe_icode:mk_reg(V). icode_label(L) -> hipe_icode:mk_label(L). icode_move(V, D) -> hipe_icode:mk_move(V, D). icode_const(X) -> hipe_icode:mk_const(X). icode_const_val(X) -> hipe_icode:const_value(X). icode_call_local(Ts, M, N, Vs) -> hipe_icode:mk_call(Ts, M, N, Vs, local). icode_call_remote(Ts, M, N, Vs) -> hipe_icode:mk_call(Ts, M, N, Vs, remote). icode_call_remote(Ts, M, N, Vs, Cont, Fail, Guard) -> hipe_icode:mk_call(Ts, M, N, Vs, remote, Cont, Fail, Guard). icode_enter_local(M, N, Vs) -> hipe_icode:mk_enter(M, N, Vs, local). icode_enter_remote(M, N, Vs) -> hipe_icode:mk_enter(M, N, Vs, remote). icode_call_fun(Ts, Vs) -> icode_call_primop(Ts, call_fun, Vs). icode_enter_fun(Vs) -> icode_enter_primop(enter_fun, Vs). icode_begin_try(L,Cont) -> hipe_icode:mk_begin_try(L,Cont). icode_end_try() -> hipe_icode:mk_end_try(). icode_begin_handler(Ts) -> hipe_icode:mk_begin_handler(Ts). icode_goto(L) -> hipe_icode:mk_goto(L). icode_return(Ts) -> hipe_icode:mk_return(Ts). icode_fail(Vs, C) -> hipe_icode:mk_fail(Vs, C). icode_guardop(Ts, Name, As, Succ, Fail) -> hipe_icode:mk_guardop(Ts, Name, As, Succ, Fail). icode_call_primop(Ts, Name, As) -> hipe_icode:mk_primop(Ts, Name, As). icode_call_primop(Ts, Name, As, Succ, Fail) -> hipe_icode:mk_primop(Ts, Name, As, Succ, Fail). icode_enter_primop(Name, As) -> hipe_icode:mk_enter_primop(Name, As). icode_if(Test, As, True, False) -> hipe_icode:mk_if(Test, As, True, False). icode_type(Test, As, True, False) -> hipe_icode:mk_type(Test, As, True, False). icode_switch_val(Arg, Fail, Length, Cases) -> hipe_icode:mk_switch_val(Arg, Fail, Length, Cases). icode_switch_tuple_arity(Arg, Fail, Length, Cases) -> SortedCases = lists:keysort(1, Cases), %% imitate BEAM compiler - Kostis hipe_icode:mk_switch_tuple_arity(Arg, Fail, Length, SortedCases). %% --------------------------------------------------------------------- %% Error reporting error_not_in_receive(Name) -> error_msg("primitive operation `~w' missing receive-context.", [Name]). low_degree() -> "degree of expression less than expected.". warning_low_degree() -> warning_msg(low_degree()). error_low_degree() -> error_msg(low_degree()). error_high_degree() -> error_msg("degree of expression greater than expected."). error_degree_mismatch(N, E) -> error_msg("expression does not have expected degree (~w): ~P.", [N, E, 10]). error_nonlocal_application(Op) -> error_msg("application operator not a local function: ~P.", [Op, 10]). error_primop_badargs(Op, As) -> error_msg("bad arguments to `~w' operation: ~P.", [Op, As, 15]). %% internal_error_msg(S) -> %% internal_error_msg(S, []). %% internal_error_msg(S, Vs) -> %% error_msg(lists:concat(["Internal error: ", S]), Vs). error_msg(S) -> error_msg(S, []). error_msg(S, Vs) -> error_logger:error_msg(lists:concat([?MODULE, ": ", S, "\n"]), Vs). warning_msg(S) -> warning_msg(S, []). warning_msg(S, Vs) -> info_msg(lists:concat(["warning: ", S]), Vs). %% info_msg(S) -> %% info_msg(S, []). info_msg(S, Vs) -> error_logger:info_msg(lists:concat([?MODULE, ": ", S, "\n"]), Vs). %% -------------------------------------------------------------------------- %% Binary stuff binary_match([Clause|Clauses], F, [V], Next, Fail, Ctxt, Env, S) -> Guard = cerl:clause_guard(Clause), Body = cerl:clause_body(Clause), [Pat] = cerl:clause_pats(Clause), {FL,S1} = s__get_label(translate_label_primop(Guard),S), {Env1,S2} = binary_pattern(Pat,V,FL,Env,S1), S3 = F(Body, Ctxt, Env1, S2), S4 = add_continuation_jump(Next, Ctxt, S3), S5 = add_code([icode_label(FL)], S4), binary_match(Clauses, F, [V], Next, Fail, Ctxt, Env, S5); binary_match([], _F, _, _Next, Fail, _Ctxt, _Env, S) -> add_code([icode_goto(Fail)], S). translate_label_primop(LabelPrimop) -> ?PRIMOP_SET_LABEL = cerl:atom_val(cerl:primop_name(LabelPrimop)), [Ref] = cerl:primop_args(LabelPrimop), Ref.