diff options
Diffstat (limited to 'lib')
-rw-r--r-- | lib/compiler/src/beam_type.erl | 474 |
1 files changed, 275 insertions, 199 deletions
diff --git a/lib/compiler/src/beam_type.erl b/lib/compiler/src/beam_type.erl index b83ed17b55..646480f596 100644 --- a/lib/compiler/src/beam_type.erl +++ b/lib/compiler/src/beam_type.erl @@ -17,14 +17,15 @@ %% %% %CopyrightEnd% %% -%% Purpose : Type-based optimisations. +%% Purpose: Type-based optimisations. See the comment for verified_type/1 +%% the very end of this file for a description of the types in the +%% type database. -module(beam_type). -export([module/2]). --import(lists, [filter/2,foldl/3,keyfind/3,member/2, - reverse/1,reverse/2,sort/1]). +-import(lists, [foldl/3,member/2,reverse/1,reverse/2,sort/1]). -define(UNICODE_INT, {integer,{0,16#10FFFF}}). @@ -229,7 +230,7 @@ simplify_float_1([{set,[D0],[A0],{alloc,_,{gc_bif,'-',{f,0}}}}=I|Is]=Is0, {D,Rs} = find_dest(D0, Rs1), Areg = fetch_reg(A, Rs), Acc = [{set,[D],[Areg],{bif,fnegate,{f,0}}}|clearerror(Acc1)], - Ts = tdb_update([{D0,float}], Ts0), + Ts = tdb_store(D0, float, Ts0), simplify_float_1(Is, Ts, Rs, Acc); _Other -> Ts = update(I, Ts0), @@ -252,7 +253,7 @@ simplify_float_1([{set,[D0],[A0,B0],{alloc,_,{gc_bif,Op0,{f,0}}}}=I|Is]=Is0, Areg = fetch_reg(A, Rs), Breg = fetch_reg(B, Rs), Acc = [{set,[D],[Areg,Breg],{bif,Op,{f,0}}}|clearerror(Acc2)], - Ts = tdb_update([{D0,float}], Ts0), + Ts = tdb_store(D0, float, Ts0), simplify_float_1(Is, Ts, Rs, Acc) end; simplify_float_1([{set,_,_,{try_catch,_,_}}=I|Is]=Is0, _Ts, Rs0, Acc0) -> @@ -425,104 +426,94 @@ update({'%anno',_}, Ts) -> Ts; update({set,[D],[S],move}, Ts) -> tdb_copy(S, D, Ts); -update({set,[D],[{integer,I},Reg],{bif,element,_}}, Ts0) -> - tdb_update([{Reg,{tuple,min_size,I,[]}},{D,kill}], Ts0); -update({set,[D],[_Index,Reg],{bif,element,_}}, Ts0) -> - tdb_update([{Reg,{tuple,min_size,0,[]}},{D,kill}], Ts0); -update({set,[D],Args,{bif,N,_}}, Ts0) -> +update({set,[D],[Index,Reg],{bif,element,_}}, Ts0) -> + MinSize = case Index of + {integer,I} -> I; + _ -> 0 + end, + Ts = tdb_meet(Reg, {tuple,min_size,MinSize,[]}, Ts0), + tdb_store(D, any, Ts); +update({set,[D],Args,{bif,N,_}}, Ts) -> Ar = length(Args), BoolOp = erl_internal:new_type_test(N, Ar) orelse erl_internal:comp_op(N, Ar) orelse erl_internal:bool_op(N, Ar), - case BoolOp of - true -> - tdb_update([{D,boolean}], Ts0); - false -> - tdb_update([{D,kill}], Ts0) - end; + Type = case BoolOp of + true -> boolean; + false -> unary_op_type(N) + end, + tdb_store(D, Type, Ts); update({set,[D],[S],{get_tuple_element,0}}, Ts) -> - tdb_update([{D,{tuple_element,S,0}}], Ts); + tdb_store(D, {tuple_element,S,0}, Ts); update({set,[D],[S],{alloc,_,{gc_bif,float,{f,0}}}}, Ts0) -> %% Make sure we reject non-numeric literal argument. case possibly_numeric(S) of - true -> tdb_update([{D,float}], Ts0); - false -> Ts0 + true -> tdb_store(D, float, Ts0); + false -> Ts0 end; update({set,[D],[S1,S2],{alloc,_,{gc_bif,'band',{f,0}}}}, Ts) -> - case keyfind(integer, 1, [S1,S2]) of - {integer,N} -> - update_band(N, D, Ts); - false -> - tdb_update([{D,integer}], Ts) - end; -update({set,[D],[S1,S2],{alloc,_,{gc_bif,'/',{f,0}}}}, Ts0) -> + Type = band_type(S1, S2, Ts), + tdb_store(D, Type, Ts); +update({set,[D],[S1,S2],{alloc,_,{gc_bif,'/',{f,0}}}}, Ts) -> %% Make sure we reject non-numeric literals. case possibly_numeric(S1) andalso possibly_numeric(S2) of - true -> tdb_update([{D,float}], Ts0); - false -> Ts0 + true -> tdb_store(D, float, Ts); + false -> Ts end; update({set,[D],[S1,S2],{alloc,_,{gc_bif,Op,{f,0}}}}, Ts0) -> case op_type(Op) of integer -> - tdb_update([{D,integer}], Ts0); - {float,_} -> - case {tdb_find(S1, Ts0),tdb_find(S2, Ts0)} of - {float,_} -> tdb_update([{D,float}], Ts0); - {_,float} -> tdb_update([{D,float}], Ts0); - {_,_} -> tdb_update([{D,kill}], Ts0) - end; - unknown -> - tdb_update([{D,kill}], Ts0) - end; -update({set,[],_Src,_Op}, Ts0) -> Ts0; -update({set,[D],_Src,_Op}, Ts0) -> - tdb_update([{D,kill}], Ts0); + tdb_store(D, integer, Ts0); + {float,_} -> + case {tdb_find(S1, Ts0),tdb_find(S2, Ts0)} of + {float,_} -> tdb_store(D, float, Ts0); + {_,float} -> tdb_store(D, float, Ts0); + {_,_} -> tdb_store(D, any, Ts0) + end; + Type -> + tdb_store(D, Type, Ts0) + end; +update({set,[D],[_],{alloc,_,{gc_bif,Op,{f,0}}}}, Ts) -> + tdb_store(D, unary_op_type(Op), Ts); +update({set,[],_Src,_Op}, Ts) -> + Ts; +update({set,[D],_Src,_Op}, Ts) -> + tdb_store(D, any, Ts); update({kill,D}, Ts) -> - tdb_update([{D,kill}], Ts); + tdb_store(D, any, Ts); %% Instructions outside of blocks. -update({test,is_float,_Fail,[Src]}, Ts0) -> - tdb_update([{Src,float}], Ts0); -update({test,test_arity,_Fail,[Src,Arity]}, Ts0) -> - tdb_update([{Src,{tuple,exact_size,Arity,[]}}], Ts0); -update({test,is_map,_Fail,[Src]}, Ts0) -> - tdb_update([{Src,map}], Ts0); +update({test,test_arity,_Fail,[Src,Arity]}, Ts) -> + tdb_meet(Src, {tuple,exact_size,Arity,[]}, Ts); update({get_map_elements,_,Src,{list,Elems0}}, Ts0) -> + Ts1 = tdb_meet(Src, map, Ts0), {_Ss,Ds} = beam_utils:split_even(Elems0), - Elems = [{Dst,kill} || Dst <- Ds], - tdb_update([{Src,map}|Elems], Ts0); -update({test,is_nonempty_list,_Fail,[Src]}, Ts0) -> - tdb_update([{Src,nonempty_list}], Ts0); -update({test,is_eq_exact,_,[Reg,{atom,_}=Atom]}, Ts) -> - case tdb_find(Reg, Ts) of - error -> - Ts; - {tuple_element,TupleReg,0} -> - tdb_update([{TupleReg,{tuple,min_size,1,[Atom]}}], Ts); - _ -> - Ts - end; + foldl(fun(Dst, A) -> tdb_store(Dst, any, A) end, Ts1, Ds); +update({test,is_eq_exact,_,[Reg,{atom,_}=Atom]}, Ts0) -> + Ts = case tdb_find_source_tuple(Reg, Ts0) of + {source_tuple,TupleReg} -> + tdb_meet(TupleReg, {tuple,min_size,1,[Atom]}, Ts0); + none -> + Ts0 + end, + tdb_meet(Reg, Atom, Ts); update({test,is_record,_Fail,[Src,Tag,{integer,Arity}]}, Ts) -> - tdb_update([{Src,{tuple,exact_size,Arity,[Tag]}}], Ts); + tdb_meet(Src, {tuple,exact_size,Arity,[Tag]}, Ts); %% Binaries and binary matching. -update({test,is_binary,_Fail,[Src]}, Ts0) -> - tdb_update([{Src,{binary,8}}], Ts0); -update({test,is_bitstr,_Fail,[Src]}, Ts0) -> - tdb_update([{Src,{binary,1}}], Ts0); update({test,bs_get_integer2,_,_,Args,Dst}, Ts) -> - tdb_update([{Dst,get_bs_integer_type(Args)}], Ts); + tdb_store(Dst, get_bs_integer_type(Args), Ts); update({test,bs_get_utf8,_,_,_,Dst}, Ts) -> - tdb_update([{Dst,?UNICODE_INT}], Ts); + tdb_store(Dst, ?UNICODE_INT, Ts); update({test,bs_get_utf16,_,_,_,Dst}, Ts) -> - tdb_update([{Dst,?UNICODE_INT}], Ts); + tdb_store(Dst, ?UNICODE_INT, Ts); update({test,bs_get_utf32,_,_,_,Dst}, Ts) -> - tdb_update([{Dst,?UNICODE_INT}], Ts); + tdb_store(Dst, ?UNICODE_INT, Ts); update({bs_init,_,{bs_init2,_,_},_,_,Dst}, Ts) -> - tdb_update([{Dst,{binary,8}}], Ts); + tdb_store(Dst, {binary,8}, Ts); update({bs_init,_,_,_,_,Dst}, Ts) -> - tdb_update([{Dst,{binary,1}}], Ts); + tdb_store(Dst, {binary,1}, Ts); update({bs_put,_,_,_}, Ts) -> Ts; update({bs_save2,_,_}, Ts) -> @@ -530,21 +521,31 @@ update({bs_save2,_,_}, Ts) -> update({bs_restore2,_,_}, Ts) -> Ts; update({bs_context_to_binary,Dst}, Ts) -> - tdb_update([{Dst,kill}], Ts); -update({test,bs_start_match2,_,_,[Src,_],Dst}, Ts) -> - Type = case tdb_find(Src, Ts) of - {binary,_}=Type0 -> Type0; - _ -> {binary,1} - end, - tdb_update([{Dst,Type}], Ts); + tdb_store(Dst, {binary,1}, Ts); +update({test,bs_start_match2,_,_,[Src,_],Dst}, Ts0) -> + Ts = tdb_meet(Src, {binary,1}, Ts0), + tdb_copy(Src, Dst, Ts); update({test,bs_get_binary2,_,_,[_,_,Unit,_],Dst}, Ts) -> true = is_integer(Unit), %Assertion. - tdb_update([{Dst,{binary,Unit}}], Ts); + tdb_store(Dst, {binary,Unit}, Ts); update({test,bs_get_float2,_,_,_,Dst}, Ts) -> - tdb_update([{Dst,float}], Ts); + tdb_store(Dst, float, Ts); update({test,bs_test_unit,_,[Src,Unit]}, Ts) -> - tdb_update([{Src,{binary,Unit}}], Ts); - + tdb_meet(Src, {binary,Unit}, Ts); + +%% Other test instructions +update({test,Test,_Fail,[Src]}, Ts) -> + Type = case Test of + is_binary -> {binary,8}; + is_bitstr -> {binary,1}; + is_boolean -> boolean; + is_float -> float; + is_integer -> integer; + is_map -> map; + is_nonempty_list -> nonempty_list; + _ -> any + end, + tdb_meet(Src, Type, Ts); update({test,_Test,_Fail,_Other}, Ts) -> Ts; @@ -552,7 +553,7 @@ update({test,_Test,_Fail,_Other}, Ts) -> update({call_ext,Ar,{extfunc,math,Math,Ar}}, Ts) -> case is_math_bif(Math, Ar) of - true -> tdb_update([{{x,0},float}], Ts); + true -> tdb_store({x,0}, float, Ts); false -> tdb_kill_xregs(Ts) end; update({call_ext,3,{extfunc,erlang,setelement,3}}, Ts0) -> @@ -569,7 +570,7 @@ update({call_ext,3,{extfunc,erlang,setelement,3}}, Ts0) -> %% first element of the tuple. {tuple,SzKind,Sz,[]} end, - tdb_update([{{x,0},T}], Ts); + tdb_store({x,0}, T, Ts); _ -> Ts end; @@ -585,20 +586,27 @@ update({'%',_}, Ts) -> Ts; %% The instruction is unknown. Kill all information. update(_I, _Ts) -> tdb_new(). -update_band(N, Reg, Ts) -> - Type = update_band_1(N, 0), - tdb_update([{Reg,Type}], Ts). +band_type({integer,Int}, Other, Ts) -> + band_type_1(Int, Other, Ts); +band_type(Other, {integer,Int}, Ts) -> + band_type_1(Int, Other, Ts); +band_type(_, _, _) -> integer. + +band_type_1(Int, OtherSrc, Ts) -> + Type = band_type_2(Int, 0), + OtherType = tdb_find(OtherSrc, Ts), + meet(Type, OtherType). -update_band_1(N, Bits) when Bits < 64 -> +band_type_2(N, Bits) when Bits < 64 -> case 1 bsl Bits of P when P =:= N + 1 -> {integer,{0,N}}; P when P > N + 1 -> integer; _ -> - update_band_1(N, Bits+1) + band_type_2(N, Bits+1) end; -update_band_1(_, _) -> +band_type_2(_, _) -> %% Negative or large positive number. Give up. integer. @@ -722,7 +730,15 @@ op_type('bxor') -> integer; op_type('bsl') -> integer; op_type('bsr') -> integer; op_type('div') -> integer; -op_type(_) -> unknown. +op_type(_) -> any. + +unary_op_type(bit_size) -> integer; +unary_op_type(byte_size) -> integer; +unary_op_type(length) -> integer; +unary_op_type(map_size) -> integer; +unary_op_type(size) -> integer; +unary_op_type(tuple_size) -> integer; +unary_op_type(_) -> any. flush(Rs, [{set,[_],[_,_,_],{bif,is_record,_}}|_]=Is0, Acc0) -> Acc = flush_all(Rs, Is0, Acc0), @@ -805,41 +821,39 @@ checkerror_1([], OrigIs) -> OrigIs. checkerror_2(OrigIs) -> [{set,[],[],fcheckerror}|OrigIs]. -%%% Routines for maintaining a type database. The type database +%%% Routines for maintaining a type database. The type database %%% associates type information with registers. %%% -%%% {tuple,min_size,Size,First} means that the corresponding register contains -%%% a tuple with *at least* Size elements (conversely, exact_size means that it -%%% contains a tuple with *exactly* Size elements). An tuple with unknown size -%%% is represented as {tuple,min_size,0,[]}. First is either [] (meaning that -%%% the tuple's first element is unknown) or [FirstElement] (the contents of -%%% the first element). -%%% -%%% 'float' means that the register contains a float. -%%% -%%% 'integer' or {integer,{Min,Max}} that the register contains an -%%% integer. -%%% -%%% {binary,Unit} means that the register contains a binary/bitstring aligned -%%% to unit Unit. +%%% See the comment for verified_type/1 at the end of module for +%%% a description of the possible types. %% tdb_new() -> EmptyDataBase %% Creates a new, empty type database. tdb_new() -> []. -%% tdb_find(Register, Db) -> Information|error +%% tdb_find(Register, Db) -> Type %% Returns type information or the atom error if there is no type %% information available for Register. +%% +%% See the comment for verified_type/1 at the end of module for +%% a description of the possible types. -tdb_find({x,_}=K, Ts) -> tdb_find_1(K, Ts); -tdb_find({y,_}=K, Ts) -> tdb_find_1(K, Ts); -tdb_find(_, _) -> error. +tdb_find(Reg, Ts) -> + case tdb_find_raw(Reg, Ts) of + {tuple_element,_,_} -> any; + Type -> Type + end. -tdb_find_1(K, Ts) -> - case orddict:find(K, Ts) of - {ok,Val} -> Val; - error -> error +%% tdb_find_source_tuple(Register, Ts) -> {source_tuple,Register} | 'none'. +%% Find the tuple whose first element was fetched to the register Register. + +tdb_find_source_tuple(Reg, Ts) -> + case tdb_find_raw(Reg, Ts) of + {tuple_element,Src,0} -> + {source_tuple,Src}; + _ -> + none end. %% tdb_copy(Source, Dest, Db) -> Db' @@ -847,9 +861,9 @@ tdb_find_1(K, Ts) -> %% as the Source. tdb_copy({Tag,_}=S, D, Ts) when Tag =:= x; Tag =:= y -> - case tdb_find(S, Ts) of - error -> orddict:erase(D, Ts); - Type -> orddict:store(D, Type, Ts) + case tdb_find_raw(S, Ts) of + any -> orddict:erase(D, Ts); + Type -> orddict:store(D, Type, Ts) end; tdb_copy(Literal, D, Ts) -> Type = case Literal of @@ -861,14 +875,53 @@ tdb_copy(Literal, D, Ts) -> {literal,Tuple} when tuple_size(Tuple) >= 1 -> Lit = tag_literal(element(1, Tuple)), {tuple,exact_size,tuple_size(Tuple),[Lit]}; - _ -> term + _ -> any end, - if - Type =:= term -> - orddict:erase(D, Ts); - true -> - verify_type(Type), - orddict:store(D, Type, Ts) + tdb_store(D, verified_type(Type), Ts). + +%% tdb_store(Register, Type, Ts0) -> Ts. +%% Store a new type for register Register. Return the update type +%% database. Use this function when a new value is assigned to +%% a register. +%% +%% See the comment for verified_type/1 at the end of module for +%% a description of the possible types. + +tdb_store(Reg, any, Ts) -> + orddict:erase(Reg, Ts); +tdb_store(Reg, Type, Ts) -> + orddict:store(Reg, verified_type(Type), Ts). + +%% tdb_meet(Register, Type, Ts0) -> Ts. +%% Update information of a register that is used as the source for an +%% instruction. The type Type will be combined using the meet operation +%% with the previous type information for the register, resulting in +%% narrower (more specific) type. +%% +%% For example, if the previous type is {tuple,min_size,2,[]} and the +%% the new type is {tuple,exact_size,5,[]}, the meet of the types will +%% be {tuple,exact_size,5,[]}. +%% +%% See the comment for verified_type/1 at the end of module for +%% a description of the possible types. + +tdb_meet(Reg, NewType, Ts) -> + Update = fun(Type0) -> meet(Type0, NewType) end, + orddict:update(Reg, Update, NewType, Ts). + +%%% +%%% Here follows internal helper functions for accessing and +%%% updating the type database. +%%% + +tdb_find_raw({x,_}=K, Ts) -> tdb_find_raw_1(K, Ts); +tdb_find_raw({y,_}=K, Ts) -> tdb_find_raw_1(K, Ts); +tdb_find_raw(_, _) -> any. + +tdb_find_raw_1(K, Ts) -> + case orddict:find(K, Ts) of + {ok,Val} -> Val; + error -> any end. tag_literal(A) when is_atom(A) -> {atom,A}; @@ -877,45 +930,6 @@ tag_literal(I) when is_integer(I) -> {integer,I}; tag_literal([]) -> nil; tag_literal(Lit) -> {literal,Lit}. -%% tdb_update([UpdateOp], Db) -> NewDb -%% UpdateOp = {Register,kill}|{Register,NewInfo} -%% Updates a type database. If a 'kill' operation is given, the type -%% information for that register will be removed from the database. -%% A kill operation takes precedence over other operations for the same -%% register (i.e. [{{x,0},kill},{{x,0},{tuple,min_size,5,[]}}] means that the -%% the existing type information, if any, will be discarded, and the -%% the '{tuple,min_size,5,[]}' information ignored. -%% -%% If NewInfo information is given and there exists information about -%% the register, the old and new type information will be merged. -%% For instance, {tuple,min_size,5,_} and {tuple,min_size,10,_} will be merged -%% to produce {tuple,min_size,10,_}. - -tdb_update(Uis0, Ts0) -> - Uis1 = filter(fun ({{x,_},_Op}) -> true; - ({{y,_},_Op}) -> true; - (_) -> false - end, Uis0), - tdb_update1(lists:sort(Uis1), Ts0). - -tdb_update1([{Key,kill}|Ops], [{K,_Old}|_]=Db) when Key < K -> - tdb_update1(remove_key(Key, Ops), Db); -tdb_update1([{Key,Type}=New|Ops], [{K,_Old}|_]=Db) when Key < K -> - verify_type(Type), - [New|tdb_update1(Ops, Db)]; -tdb_update1([{Key,kill}|Ops], [{Key,_}|Db]) -> - tdb_update1(remove_key(Key, Ops), Db); -tdb_update1([{Key,NewInfo}|Ops], [{Key,OldInfo}|Db]) -> - [{Key,merge_type_info(NewInfo, OldInfo)}|tdb_update1(Ops, Db)]; -tdb_update1([{_,_}|_]=Ops, [Old|Db]) -> - [Old|tdb_update1(Ops, Db)]; -tdb_update1([{Key,kill}|Ops], []) -> - tdb_update1(remove_key(Key, Ops), []); -tdb_update1([{_,Type}=New|Ops], []) -> - verify_type(Type), - [New|tdb_update1(Ops, [])]; -tdb_update1([], Db) -> Db. - %% tdb_kill_xregs(Db) -> NewDb %% Kill all information about x registers. Also kill all tuple_element %% dependencies from y registers to x registers. @@ -924,44 +938,106 @@ tdb_kill_xregs([{{x,_},_Type}|Db]) -> tdb_kill_xregs(Db); tdb_kill_xregs([{{y,_},{tuple_element,{x,_},_}}|Db]) -> tdb_kill_xregs(Db); tdb_kill_xregs([Any|Db]) -> [Any|tdb_kill_xregs(Db)]; tdb_kill_xregs([]) -> []. - -remove_key(Key, [{Key,_Op}|Ops]) -> remove_key(Key, Ops); -remove_key(_, Ops) -> Ops. -merge_type_info(I, I) -> I; -merge_type_info({tuple,min_size,Sz1,Same}, {tuple,min_size,Sz2,Same}=Max) when Sz1 < Sz2 -> +%% meet(Type1, Type2) -> Type +%% Returns the "meet" of Type1 and Type2. The meet is a narrower +%% type than Type1 and Type2. For example: +%% +%% meet(integer, {integer,{0,3}}) -> {integer,{0,3}} +%% +%% The meet for two different types result in 'none', which is +%% the bottom element for our type lattice: +%% +%% meet(integer, map) -> none + +meet(T, T) -> + T; +meet({integer,_}=T, integer) -> + T; +meet(integer, {integer,_}=T) -> + T; +meet({integer,{Min1,Max1}}, {integer,{Min2,Max2}}) -> + {integer,{max(Min1, Min2),min(Max1, Max2)}}; +meet({tuple,min_size,Sz1,Same}, {tuple,min_size,Sz2,Same}=Max) when Sz1 < Sz2 -> Max; -merge_type_info({tuple,min_size,Sz1,Same}=Max, {tuple,min_size,Sz2,Same}) when Sz1 > Sz2 -> +meet({tuple,min_size,Sz1,Same}=Max, {tuple,min_size,Sz2,Same}) when Sz1 > Sz2 -> Max; -merge_type_info({tuple,exact_size,_,Same}=Exact, {tuple,_,_,Same}) -> +meet({tuple,exact_size,_,Same}=Exact, {tuple,_,_,Same}) -> Exact; -merge_type_info({tuple,_,_,Same},{tuple,exact_size,_,Same}=Exact) -> +meet({tuple,_,_,Same},{tuple,exact_size,_,Same}=Exact) -> Exact; -merge_type_info({tuple,SzKind1,Sz1,[]}, {tuple,_SzKind2,_Sz2,First}=Tuple2) -> - merge_type_info({tuple,SzKind1,Sz1,First}, Tuple2); -merge_type_info({tuple,_SzKind1,_Sz1,First}=Tuple1, {tuple,SzKind2,Sz2,_}) -> - merge_type_info(Tuple1, {tuple,SzKind2,Sz2,First}); -merge_type_info(integer, {integer,_}) -> - integer; -merge_type_info({integer,_}, integer) -> - integer; -merge_type_info({integer,{Min1,Max1}}, {integer,{Min2,Max2}}) -> - {integer,{max(Min1, Min2),min(Max1, Max2)}}; -merge_type_info({binary,U1}, {binary,U2}) -> +meet({tuple,SzKind1,Sz1,[]}, {tuple,_SzKind2,_Sz2,First}=Tuple2) -> + meet({tuple,SzKind1,Sz1,First}, Tuple2); +meet({tuple,_SzKind1,_Sz1,First}=Tuple1, {tuple,SzKind2,Sz2,_}) -> + meet(Tuple1, {tuple,SzKind2,Sz2,First}); +meet({binary,U1}, {binary,U2}) -> {binary,max(U1, U2)}; -merge_type_info(NewType, _) -> - verify_type(NewType), - NewType. - -verify_type({atom,_}) -> ok; -verify_type({binary,U}) when is_integer(U) -> ok; -verify_type(boolean) -> ok; -verify_type(integer) -> ok; -verify_type({integer,{Min,Max}}) - when is_integer(Min), is_integer(Max) -> ok; -verify_type(map) -> ok; -verify_type(nonempty_list) -> ok; -verify_type({tuple,_,Sz,[]}) when is_integer(Sz) -> ok; -verify_type({tuple,_,Sz,[_]}) when is_integer(Sz) -> ok; -verify_type({tuple_element,_,_}) -> ok; -verify_type(float) -> ok. +meet(T1, T2) -> + case is_any(T1) of + true -> + verified_type(T2); + false -> + case is_any(T2) of + true -> + verified_type(T1); + false -> + none %The bottom element. + end + end. + +is_any(any) -> true; +is_any({tuple_element,_,_}) -> true; +is_any(_) -> false. + +%% verified_type(Type) -> Type +%% Returns the passed in type if it is one of the defined types. +%% Crashes if there is anything wrong with the type. +%% +%% Here are all possible types: +%% +%% any Any Erlang term (top element for the type lattice). +%% +%% {atom,Atom} The specific atom Atom. +%% {binary,Unit} Binary/bitstring aligned to unit Unit. +%% boolean 'true' | 'false' +%% float Floating point number. +%% integer Integer. +%% {integer,{Min,Max}} Integer in the inclusive range Min through Max. +%% map Map. +%% nonempty_list Nonempty list. +%% {tuple,_,_,_} Tuple (see below). +%% +%% none No type (bottom element for the type lattice). +%% +%% {tuple,min_size,Size,First} means that the corresponding register +%% contains a tuple with *at least* Size elements (conversely, +%% {tuple,exact_size,Size,First} means that it contains a tuple with +%% *exactly* Size elements). An tuple with unknown size is +%% represented as {tuple,min_size,0,[]}. First is either [] (meaning +%% that the tuple's first element is unknown) or [FirstElement] (the +%% contents of the first element). +%% +%% There is also a pseudo-type called {tuple_element,_,_}: +%% +%% {tuple_element,SrcTuple,ElementNumber} +%% +%% that does not provide any information about the type of the +%% register itself, but provides a link back to the source tuple that +%% the register got its value from. +%% +%% Note that {tuple_element,_,_} will *never* be returned by tdb_find/2. +%% Use tdb_find_source_tuple/2 to locate the source tuple for a register. + +verified_type(any=T) -> T; +verified_type({atom,_}=T) -> T; +verified_type({binary,U}=T) when is_integer(U) -> T; +verified_type(boolean=T) -> T; +verified_type(integer=T) -> T; +verified_type({integer,{Min,Max}}=T) + when is_integer(Min), is_integer(Max) -> T; +verified_type(map=T) -> T; +verified_type(nonempty_list=T) -> T; +verified_type({tuple,_,Sz,[]}=T) when is_integer(Sz) -> T; +verified_type({tuple,_,Sz,[_]}=T) when is_integer(Sz) -> T; +verified_type({tuple_element,_,_}=T) -> T; +verified_type(float=T) -> T. |