diff options
Diffstat (limited to 'lib')
-rw-r--r-- | lib/compiler/src/sys_core_fold.erl | 4 | ||||
-rw-r--r-- | lib/compiler/src/v3_core.erl | 3 | ||||
-rw-r--r-- | lib/compiler/test/warnings_SUITE.erl | 9 | ||||
-rw-r--r-- | lib/syntax_tools/src/erl_prettypr.erl | 26 | ||||
-rw-r--r-- | lib/syntax_tools/src/erl_syntax.erl | 257 |
5 files changed, 270 insertions, 29 deletions
diff --git a/lib/compiler/src/sys_core_fold.erl b/lib/compiler/src/sys_core_fold.erl index d1eec9e347..9ce6bb48bf 100644 --- a/lib/compiler/src/sys_core_fold.erl +++ b/lib/compiler/src/sys_core_fold.erl @@ -305,6 +305,10 @@ expr(#c_let{}=Let, Ctxt, Sub) -> %% Now recursively re-process the new expression. expr(Expr, Ctxt, sub_new_preserve_types(Sub)) end; +expr(#c_letrec{body=#c_var{}}=Letrec, effect, _Sub) -> + %% This is named fun in an 'effect' context. Warn and ignore. + add_warning(Letrec, useless_building), + void(); expr(#c_letrec{defs=Fs0,body=B0}=Letrec, Ctxt, Sub) -> Fs1 = map(fun ({Name,Fb}) -> {Name,expr(Fb, {letrec,Ctxt}, Sub)} diff --git a/lib/compiler/src/v3_core.erl b/lib/compiler/src/v3_core.erl index e30bfa729c..59863f52ec 100644 --- a/lib/compiler/src/v3_core.erl +++ b/lib/compiler/src/v3_core.erl @@ -2088,7 +2088,8 @@ cexpr(#ifun{anno=#a{us=Us0}=A0,name={named,Name},fc=#iclause{pats=Ps}}=Fun0, RecVar = #c_var{name={Name,length(Ps)}}, Let = #c_let{vars=[#c_var{name=Name}],arg=RecVar,body=Body}, CFun1 = CFun0#c_fun{body=Let}, - Letrec = #c_letrec{defs=[{RecVar,CFun1}], + Letrec = #c_letrec{anno=A0#a.anno, + defs=[{RecVar,CFun1}], body=RecVar}, {Letrec,[],Us1,St1} end; diff --git a/lib/compiler/test/warnings_SUITE.erl b/lib/compiler/test/warnings_SUITE.erl index 7186956603..16d15a59e5 100644 --- a/lib/compiler/test/warnings_SUITE.erl +++ b/lib/compiler/test/warnings_SUITE.erl @@ -390,6 +390,10 @@ effect(Config) when is_list(Config) -> <<X:8>>; unused_fun -> fun() -> {ok,X} end; + unused_named_fun -> + fun F(0) -> 1; + F(N) -> N*F(N-1) + end; unused_atom -> ignore; %no warning unused_nil -> @@ -484,8 +488,9 @@ effect(Config) when is_list(Config) -> {22,sys_core_fold,{no_effect,{erlang,is_integer,1}}}, {24,sys_core_fold,useless_building}, {26,sys_core_fold,useless_building}, - {32,sys_core_fold,{no_effect,{erlang,'=:=',2}}}, - {34,sys_core_fold,{no_effect,{erlang,get_cookie,0}}}]}}], + {28,sys_core_fold,useless_building}, + {36,sys_core_fold,{no_effect,{erlang,'=:=',2}}}, + {38,sys_core_fold,{no_effect,{erlang,get_cookie,0}}}]}}], ?line [] = run(Config, Ts), ok. diff --git a/lib/syntax_tools/src/erl_prettypr.erl b/lib/syntax_tools/src/erl_prettypr.erl index 1ffcf31134..4d6e88f58b 100644 --- a/lib/syntax_tools/src/erl_prettypr.erl +++ b/lib/syntax_tools/src/erl_prettypr.erl @@ -892,6 +892,32 @@ lay_2(Node, Ctxt) -> beside(floating(text(".")), D2)), maybe_parentheses(D3, Prec, Ctxt); + map_expr -> + {PrecL, Prec, _} = inop_prec('#'), + Ctxt1 = reset_prec(Ctxt), + D1 = par(seq(erl_syntax:map_expr_fields(Node), + floating(text(",")), Ctxt1, fun lay/2)), + D2 = beside(text("#{"), beside(D1, floating(text("}")))), + D3 = case erl_syntax:map_expr_argument(Node) of + none -> + D2; + A -> + beside(lay(A, set_prec(Ctxt, PrecL)), D2) + end, + maybe_parentheses(D3, Prec, Ctxt); + + map_field_assoc -> + Ctxt1 = reset_prec(Ctxt), + D1 = lay(erl_syntax:map_field_assoc_name(Node), Ctxt1), + D2 = lay(erl_syntax:map_field_assoc_value(Node), Ctxt1), + par([D1, floating(text("=>")), D2], Ctxt1#ctxt.break_indent); + + map_field_exact -> + Ctxt1 = reset_prec(Ctxt), + D1 = lay(erl_syntax:map_field_exact_name(Node), Ctxt1), + D2 = lay(erl_syntax:map_field_exact_value(Node), Ctxt1), + par([D1, floating(text(":=")), D2], Ctxt1#ctxt.break_indent); + rule -> %% Comments on the name will be repeated; cf. %% `function'. diff --git a/lib/syntax_tools/src/erl_syntax.erl b/lib/syntax_tools/src/erl_syntax.erl index 93187fa018..2f4c9ac309 100644 --- a/lib/syntax_tools/src/erl_syntax.erl +++ b/lib/syntax_tools/src/erl_syntax.erl @@ -220,6 +220,16 @@ macro/2, macro_arguments/1, macro_name/1, + map_expr/1, + map_expr/2, + map_expr_argument/1, + map_expr_fields/1, + map_field_assoc/2, + map_field_assoc_name/1, + map_field_assoc_value/1, + map_field_exact/2, + map_field_exact_name/1, + map_field_exact_value/1, match_expr/2, match_expr_body/1, match_expr_pattern/1, @@ -580,11 +590,12 @@ type(Node) -> {lc, _, _, _} -> list_comp; {bc, _, _, _} -> binary_comp; {match, _, _, _} -> match_expr; + {map, _, _, _} -> map_expr; + {map, _, _} -> map_expr; + {map_field_assoc, _, _, _} -> map_field_assoc; + {map_field_exact, _, _, _} -> map_field_exact; {op, _, _, _, _} -> infix_expr; {op, _, _, _} -> prefix_expr; - {map,_,_} -> map; - {map_field_assoc,_,_,_} -> map_field_assoc; - {map_field_exact,_,_,_} -> map_field_exact; {record, _, _, _, _} -> record_expr; {record, _, _, _} -> record_expr; {record_field, _, _, _, _} -> record_access; @@ -1913,26 +1924,206 @@ atom_literal(Node) -> %% ===================================================================== +%% @equiv map_expr(none, Fields) -map_elements(Node) -> +-spec map_expr([syntaxTree()]) -> syntaxTree(). + +map_expr(Fields) -> + map_expr(none, Fields). + + +%% ===================================================================== +%% @doc Creates an abstract map expression. If `Fields' is +%% `[F1, ..., Fn]', then if `Argument' is `none', the result represents +%% "<code>#{<em>F1</em>, ..., <em>Fn</em>}</code>", +%% otherwise it represents +%% "<code><em>Argument</em>#{<em>F1</em>, ..., <em>Fn</em>}</code>". +%% +%% @see map_expr/1 +%% @see map_expr_argument/1 +%% @see map_expr_fields/1 +%% @see map_field_assoc/2 +%% @see map_field_exact/2 + +-record(map_expr, {argument :: 'none' | syntaxTree(), + fields :: [syntaxTree()]}). + +%% `erl_parse' representation: +%% +%% {map, Pos, Fields} +%% {map, Pos, Argument, Fields} + +-spec map_expr('none' | syntaxTree(), [syntaxTree()]) -> syntaxTree(). + +map_expr(Argument, Fields) -> + tree(map_expr, #map_expr{argument = Argument, fields = Fields}). + +revert_map_expr(Node) -> + Pos = get_pos(Node), + Argument = map_expr_argument(Node), + Fields = map_expr_fields(Node), + case Argument of + none -> + {map, Pos, Fields}; + _ -> + {map, Pos, Argument, Fields} + end. + + +%% ===================================================================== +%% @doc Returns the argument subtree of a `map_expr' node, if any. If `Node' +%% represents "<code>#{...}</code>", `none' is returned. +%% Otherwise, if `Node' represents "<code><em>Argument</em>#{...}</code>", +%% `Argument' is returned. +%% +%% @see map_expr/3 + +-spec map_expr_argument(syntaxTree()) -> 'none' | syntaxTree(). + +map_expr_argument(Node) -> case unwrap(Node) of - {map, _, List} -> - List; - Node1 -> - data(Node1) + {map, _, _} -> + none; + {map, _, Argument, _} -> + Argument; + Node1 -> + (data(Node1))#map_expr.argument end. -map_field_elements({_,_,K,V}) -> - [K,V]. -map(List) -> - tree(map, List). +%% ===================================================================== +%% @doc Returns the list of field subtrees of a `map_expr' node. +%% +%% @see map_expr/3 + +-spec map_expr_fields(syntaxTree()) -> [syntaxTree()]. + +map_expr_fields(Node) -> + case unwrap(Node) of + {map, _, Fields} -> + Fields; + {map, _, _, Fields} -> + Fields; + Node1 -> + (data(Node1))#map_expr.fields + end. + -map_field_assoc(List) -> - tree(map_field_assoc, List). +%% ===================================================================== +%% @doc Creates an abstract map assoc field. The result represents +%% "<code><em>Name</em> => <em>Value</em></code>". +%% +%% @see map_field_assoc_name/1 +%% @see map_field_assoc_value/1 +%% @see map_expr/3 + +-record(map_field_assoc, {name :: syntaxTree(), value :: syntaxTree()}). + +%% `erl_parse' representation: +%% +%% {map_field_assoc, Pos, Name, Value} + +-spec map_field_assoc(syntaxTree(), syntaxTree()) -> syntaxTree(). + +map_field_assoc(Name, Value) -> + tree(map_field_assoc, #map_field_assoc{name = Name, value = Value}). + +revert_map_field_assoc(Node) -> + Pos = get_pos(Node), + Name = map_field_assoc_name(Node), + Value = map_field_assoc_value(Node), + {map_field_assoc, Pos, Name, Value}. + + +%% ===================================================================== +%% @doc Returns the name subtree of a `map_field_assoc' node. +%% +%% @see map_field_assoc/2 + +-spec map_field_assoc_name(syntaxTree()) -> syntaxTree(). + +map_field_assoc_name(Node) -> + case Node of + {map_field_assoc, _, Name, _} -> + Name; + _ -> + (data(Node))#map_field_assoc.name + end. + + +%% ===================================================================== +%% @doc Returns the value subtree of a `map_field_assoc' node. +%% +%% @see map_field_assoc/2 + +-spec map_field_assoc_value(syntaxTree()) -> syntaxTree(). + +map_field_assoc_value(Node) -> + case Node of + {map_field_assoc, _, _, Value} -> + Value; + _ -> + (data(Node))#map_field_assoc.name + end. + + +%% ===================================================================== +%% @doc Creates an abstract map exact field. The result represents +%% "<code><em>Name</em> := <em>Value</em></code>". +%% +%% @see map_field_exact_name/1 +%% @see map_field_exact_value/1 +%% @see map_expr/3 + +-record(map_field_exact, {name :: syntaxTree(), value :: syntaxTree()}). + +%% `erl_parse' representation: +%% +%% {map_field_exact, Pos, Name, Value} + +-spec map_field_exact(syntaxTree(), syntaxTree()) -> syntaxTree(). + +map_field_exact(Name, Value) -> + tree(map_field_exact, #map_field_exact{name = Name, value = Value}). + +revert_map_field_exact(Node) -> + Pos = get_pos(Node), + Name = map_field_exact_name(Node), + Value = map_field_exact_value(Node), + {map_field_exact, Pos, Name, Value}. + + +%% ===================================================================== +%% @doc Returns the name subtree of a `map_field_exact' node. +%% +%% @see map_field_exact/2 + +-spec map_field_exact_name(syntaxTree()) -> syntaxTree(). + +map_field_exact_name(Node) -> + case Node of + {map_field_exact, _, Name, _} -> + Name; + _ -> + (data(Node))#map_field_exact.name + end. + + +%% ===================================================================== +%% @doc Returns the value subtree of a `map_field_exact' node. +%% +%% @see map_field_exact/2 + +-spec map_field_exact_value(syntaxTree()) -> syntaxTree(). + +map_field_exact_value(Node) -> + case Node of + {map_field_exact, _, _, Value} -> + Value; + _ -> + (data(Node))#map_field_exact.name + end. -map_field_exact(List) -> - tree(map_field_exact, List). %% ===================================================================== %% @doc Creates an abstract tuple. If `Elements' is @@ -6117,6 +6308,12 @@ revert_root(Node) -> revert_list(Node); list_comp -> revert_list_comp(Node); + map_expr -> + revert_map_expr(Node); + map_field_assoc -> + revert_map_field_assoc(Node); + map_field_exact -> + revert_map_field_exact(Node); match_expr -> revert_match_expr(Node); module_qualifier -> @@ -6358,6 +6555,19 @@ subtrees(T) -> As -> [[macro_name(T)], As] end; + map_expr -> + case map_expr_argument(T) of + none -> + [map_expr_fields(T)]; + V -> + [[V], map_expr_fields(T)] + end; + map_field_assoc -> + [[map_field_assoc_name(T)], + [map_field_assoc_value(T)]]; + map_field_exact -> + [[map_field_exact_name(T)], + [map_field_exact_value(T)]]; match_expr -> [[match_expr_pattern(T)], [match_expr_body(T)]]; @@ -6421,12 +6631,6 @@ subtrees(T) -> try_expr_clauses(T), try_expr_handlers(T), try_expr_after(T)]; - map -> - [map_elements(T)]; - map_field_assoc -> - [map_field_elements(T)]; - map_field_exact -> - [map_field_elements(T)]; tuple -> [tuple_elements(T)] end @@ -6502,6 +6706,10 @@ make_tree(list, [P, [S]]) -> list(P, S); make_tree(list_comp, [[T], B]) -> list_comp(T, B); make_tree(macro, [[N]]) -> macro(N); make_tree(macro, [[N], A]) -> macro(N, A); +make_tree(map_expr, [Fs]) -> map_expr(Fs); +make_tree(map_expr, [[E], Fs]) -> map_expr(E, Fs); +make_tree(map_field_assoc, [[K], [V]]) -> map_field_assoc(K, V); +make_tree(map_field_exact, [[K], [V]]) -> map_field_exact(K, V); make_tree(match_expr, [[P], [E]]) -> match_expr(P, E); make_tree(named_fun_expr, [[N], C]) -> named_fun_expr(N, C); make_tree(module_qualifier, [[M], [N]]) -> module_qualifier(M, N); @@ -6522,10 +6730,7 @@ make_tree(record_index_expr, [[T], [F]]) -> make_tree(rule, [[N], C]) -> rule(N, C); make_tree(size_qualifier, [[N], [A]]) -> size_qualifier(N, A); make_tree(try_expr, [B, C, H, A]) -> try_expr(B, C, H, A); -make_tree(tuple, [E]) -> tuple(E); -make_tree(map, [E]) -> map(E); -make_tree(map_field_assoc, [E]) -> map_field_assoc(E); -make_tree(map_field_exact, [E]) -> map_field_exact(E). +make_tree(tuple, [E]) -> tuple(E). %% ===================================================================== |