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path: root/lib/hipe/icode/hipe_icode_range.erl
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%% -*- erlang-indent-level: 2 -*-
%%
%% %CopyrightBegin%
%%
%% Copyright Ericsson AB 2007-2016. All Rights Reserved.
%%
%% 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.
%%
%% %CopyrightEnd%
%%
%%%-------------------------------------------------------------------
%%% File    : hipe_icode_range.erl
%%% Author  : Per Gustafsson <[email protected]>
%%% Description : 
%%%
%%% Created : 12 Mar 2007 by Per Gustafsson <[email protected]>
%%%-------------------------------------------------------------------
-module(hipe_icode_range).

-export([cfg/4]).

%%=====================================================================
%% Icode Coordinator Behaviour Callbacks
%%=====================================================================

-export([replace_nones/1,
	 update__info/2, new__info/1, return__info/1,
	 return_none/0, return_none_args/2, return_any_args/2]).

%%=====================================================================

-import(erl_types, [t_any/0,
		    t_from_range_unsafe/2,
		    t_inf/2, t_integer/0,
		    t_to_string/1, t_to_tlist/1,
		    t_limit/2, t_none/0,
		    number_min/1, number_max/1]).

-include("hipe_icode.hrl").
-include("hipe_icode_primops.hrl").
-include("../main/hipe.hrl").
-include("../flow/cfg.hrl").
-include("../flow/hipe_bb.hrl").
-include("hipe_icode_type.hrl").

-type range_tuple() :: {'neg_inf' | integer(), 'pos_inf' | integer()}.
-type range_rep()   :: range_tuple() | 'empty'.
-type fun_name()    :: atom() | tuple().
-type inf_integer() :: 'neg_inf' | 'pos_inf' | integer().

-record(range, {range :: range_rep(),
		other :: boolean()}).
-type range() :: #range{}.

-record(ann,   {range :: range(),
                type  :: erl_types:erl_type(),
		count :: integer()}).
-type ann() :: #ann{}.

-type range_anno() :: {'range_anno', ann(), fun((ann()) -> string())}.
-type args_fun() :: fun((mfa(), cfg()) -> [range()]).
-type call_fun() :: fun((mfa(), [range()]) -> range()).
-type final_fun() :: fun((mfa(), [range()]) -> 'ok').
-type data() :: {mfa(), args_fun(), call_fun(), final_fun()}.
-type label() :: non_neg_integer().
-type info() :: gb_trees:tree().
-type work_list() :: {[label()], [label()], sets:set()}.
-type variable() :: #icode_variable{}.
-type annotated_variable() :: #icode_variable{}.
-type argument() :: #icode_const{} | variable().
-type three_range_fun()   :: fun((range(),range(),range()) -> range()).
-type instr_split_info()  :: {icode_instr(), [{label(),info()}]}.
-type last_instr_return() :: {instr_split_info(), range()}.

-record(state, {info_map = gb_trees:empty()	:: info(), 
		counter  = dict:new()		:: dict:dict(),
		cfg				:: cfg(), 
		liveness = gb_trees:empty()	:: gb_trees:tree(),
		ret_type			:: range(),
		lookup_fun			:: call_fun(),
		result_action			:: final_fun()}).
-type state() :: #state{}.

-define(WIDEN, 1).

-define(TAG_IMMED1_SIZE, 4).

-define(BITS, 64).

%%---------------------------------------------------------------------

-spec cfg(cfg(), mfa(), comp_options(), #comp_servers{}) -> cfg().

cfg(Cfg, MFA, Options, Servers) ->
  case proplists:get_bool(concurrent_comp, Options) of
    true ->
      concurrent_cfg(Cfg, MFA, Servers#comp_servers.range);
    false ->
      ordinary_cfg(Cfg, MFA)
  end.

-spec concurrent_cfg(cfg(), mfa(), pid()) -> cfg().

concurrent_cfg(Cfg, MFA, CompServer) ->
  CompServer ! {ready, {MFA, self()}},
  {ArgsFun, CallFun, FinalFun} = do_analysis(Cfg, MFA),
  Ans = do_rewrite(Cfg, MFA, ArgsFun, CallFun, FinalFun),
  CompServer ! {done_rewrite, MFA},
  Ans.

-spec do_analysis(cfg(), mfa()) -> {args_fun(), call_fun(), final_fun()}.

do_analysis(Cfg, MFA) ->
  receive
    {analyse, {ArgsFun, CallFun, FinalFun}} ->
      analyse(Cfg, {MFA, ArgsFun, CallFun, FinalFun}),
      do_analysis(Cfg, MFA);
    {done, {_NewArgsFun, _NewCallFun, _NewFinalFun} = T} ->
      T
  end.

-spec do_rewrite(cfg(), mfa(), args_fun(), call_fun(), final_fun()) -> cfg().

do_rewrite(Cfg, MFA, ArgsFun, CallFun, FinalFun) ->
  common_rewrite(Cfg, {MFA, ArgsFun, CallFun, FinalFun}).
 
-spec ordinary_cfg(cfg(), mfa()) -> cfg().

ordinary_cfg(Cfg, MFA) ->
  Data = make_data(Cfg,MFA),
  common_rewrite(Cfg, Data).
  
-spec common_rewrite(cfg(), data()) -> cfg().

common_rewrite(Cfg, Data) ->
  State = safe_analyse(Cfg, Data),
  State2 = rewrite_blocks(State),
  Cfg1 = state__cfg(State2),
  Cfg2 = hipe_icode_cfg:remove_unreachable_code(Cfg1),
  Cfg3 = convert_cfg_to_types(Cfg2),
  hipe_icode_type:specialize(Cfg3).

-spec make_data(cfg(), mfa()) -> data().

make_data(Cfg, {_M,_F,A}=MFA) ->
  NoArgs = 
    case hipe_icode_cfg:is_closure(Cfg) of
      true -> hipe_icode_cfg:closure_arity(Cfg)+1;
      false -> A
    end,
  Args = lists:duplicate(NoArgs, any_type()), 
  ArgsFun = fun(_,_) -> Args end,
  CallFun = fun(_,_) -> any_type() end,
  FinalFun = fun(_,_) -> ok end,
  {MFA, ArgsFun, CallFun, FinalFun}.

-spec analyse(cfg(), data()) -> 'ok'.

analyse(Cfg, Data) ->
  try 
    #state{} = safe_analyse(Cfg, Data),
    ok
  catch throw:no_input -> ok
  end.

-spec safe_analyse(cfg(), data()) -> state().

safe_analyse(CFG, Data={MFA,_,_,_}) ->
  State = state__init(CFG, Data),
  Work = init_work(State),
  NewState = analyse_blocks(State, Work),
  (state__result_action(NewState))(MFA, [state__ret_type(NewState)]),
  NewState.

-spec rewrite_blocks(state()) -> state().

rewrite_blocks(State) ->
  CFG = state__cfg(State),
  Start = hipe_icode_cfg:start_label(CFG),
  rewrite_blocks([Start], State, [Start]).

-spec rewrite_blocks([label()], state(), [label()]) -> state().

rewrite_blocks([Next|Rest], State, Visited) ->
  Info = state__info_in(State, Next),
  {NewState, NewLabels} = analyse_block(Next, Info, State, true),
  NewLabelsSet = ordsets:from_list(NewLabels),
  RealNew = ordsets:subtract(NewLabelsSet, Visited),
  NewVisited = ordsets:union([RealNew, Visited, [Next]]),
  NewWork = ordsets:union([RealNew, Rest]),
  rewrite_blocks(NewWork, NewState, NewVisited);
rewrite_blocks([], State, _) ->
  State.

-spec analyse_blocks(state(), work_list()) -> state().

analyse_blocks(State, Work) ->
  case get_work(Work) of
    fixpoint ->
      State;
    {Label, NewWork} ->
      Info = state__info_in(State, Label),
      {NewState, NewLabels}  = 
	try analyse_block(Label, Info, State, false)
	catch throw:none_range ->
	    {State, []}
	end,
      NewWork2 = add_work(NewWork, NewLabels),
      analyse_blocks(NewState, NewWork2)
  end.

-spec analyse_block(label(), info(), state(), boolean()) -> {state(), [label()]}.

analyse_block(Label, Info, State, Rewrite) ->
  BB = state__bb(State, Label),
  Code = hipe_bb:code(BB),
  {NewCode, InfoList, RetType} = 
    analyse_BB(Code, Info, [], Rewrite, state__lookup_fun(State)),
  State1 = state__bb_add(State, Label, hipe_bb:mk_bb(NewCode)),
  State2 = state__ret_type_update(State1, RetType),
  state__update_info(State2, InfoList, Rewrite).

-spec analyse_BB([icode_instr()], info(), [icode_instr()], boolean(), call_fun()) ->
	 {[icode_instr()], [{label(),info()}], range()}.

analyse_BB([Last], Info, Code, Rewrite, LookupFun) ->
  {{NewI, LabelInfoList}, RetType} =
    analyse_last_insn(Last, Info, Rewrite, LookupFun),
  {lists:reverse([NewI|Code]), LabelInfoList, RetType};
analyse_BB([Insn|InsnList], Info, Code, Rewrite, LookupFun) ->
  {NewInfo, NewI} = analyse_insn(Insn, Info, LookupFun), 
  analyse_BB(InsnList, NewInfo, [NewI|Code], Rewrite, LookupFun).

-spec analyse_insn(icode_instr(), info(), call_fun()) -> {info(), icode_instr()}.

analyse_insn(I, Info, LookupFun) ->
  %% io:format("~w Info: ~p~n", [I, Info]),
  NewI = handle_args(I,Info),
  FinalI = 
    case NewI of 
      #icode_call{} -> analyse_call(NewI, LookupFun);
      #icode_move{} -> analyse_move(NewI);
      #icode_phi{} -> analyse_phi(NewI);
      #icode_begin_handler{} -> analyse_begin_handler(NewI);
      #icode_comment{} -> NewI
    end,
  {enter_vals(FinalI, Info), FinalI}.

-spec handle_args(icode_instr(), info()) -> icode_instr().

handle_args(I, Info) ->
  WidenFun = fun update_three/3,
  handle_args(I, Info, WidenFun).

-spec handle_args(icode_instr(), info(), three_range_fun()) -> icode_instr().

handle_args(I, Info, WidenFun) ->
  Uses = hipe_icode:uses(I),
  PresentRanges = [lookup(V, Info) || V <- Uses],
  %% io:format("Uses: ~p~nRanges: ~p~n", [Uses, PresentRanges]),
  JoinFun = fun(Var, Range) -> update_info(Var, Range, WidenFun) end,
  NewUses = lists:zipwith(JoinFun, Uses, PresentRanges),
  hipe_icode:subst_uses(lists:zip(Uses, NewUses), I).

-spec join_info(ann(), range(), three_range_fun()) -> ann().

join_info(Ann = #ann{range = R1, type = Type, count = ?WIDEN}, R2, Fun) ->
  Ann#ann{range = Fun(R1, R2, range_from_simple_type(Type))};
join_info(Ann = #ann{range = R1, type = Type, count = C}, R2, _Fun) when C < ?WIDEN ->
  case join_three(R1, R2, range_from_simple_type(Type)) of
    R1 -> Ann;
    NewR -> Ann#ann{range = NewR, count = C+1}
  end.

-spec join_three(range(), range(), range()) -> range().

join_three(R1, R2, R3) ->
  inf(sup(R1, R2), R3).

-spec update_info(variable(), range()) -> annotated_variable().

update_info(Var, Range) ->
  update_info(Var, Range, fun update_three/3).

-spec update_info(variable(), range(), three_range_fun()) -> annotated_variable().

update_info(Arg, R, Fun) ->
  case hipe_icode:is_annotated_variable(Arg) of
    true ->
      Ann = hipe_icode:variable_annotation(Arg),
      hipe_icode:annotate_variable(Arg, update_info1(Ann, R, Fun));
    false ->
      Arg
  end.

-spec update_info1(any(), range(), three_range_fun()) -> range_anno().

update_info1({range_anno, Ann, _}, R2, Fun) ->
  make_range_anno(update_ann(Ann,R2,Fun));
update_info1({type_anno, Type, _}, R2, Fun) ->
  make_range_anno(update_ann(type_to_ann(Type), R2, Fun)).

update_ann(Ann = #ann{range = R1, type = Type, count = ?WIDEN}, R2, Fun) ->
  Ann#ann{range = Fun(R1,R2,range_from_simple_type(Type))};
update_ann(Ann = #ann{range = R1, type = Type, count = C}, R2, _Fun) ->
  case update_three(R1, R2, range_from_simple_type(Type)) of
    R1 -> Ann;
    NewR -> Ann#ann{range = NewR, count = C+1}
  end.

-spec type_to_ann(erl_types:erl_type()) -> ann().

type_to_ann(Type) ->
  #ann{range = range_from_simple_type(Type), type = t_limit(Type,1), count = 1}.

-spec make_range_anno(ann()) -> range_anno().

make_range_anno(Ann) ->
  {range_anno, Ann, fun pp_ann/1}. 

-spec update_three(range(), range(), range()) -> range().

update_three(_R1, R2, R3) ->
  inf(R2, R3).

-spec safe_widen(range(), range(), range()) -> range().

safe_widen(#range{range=Old}, #range{range=New}, T = #range{range=Wide}) ->
  ResRange =
    case {Old, New, Wide} of
      {{Min,Max1}, {Min,Max2}, {_,Max}} ->
	case inf_geq(OMax = next_up_limit(inf_max([Max1, Max2])), Max) of
	  true -> {Min,Max};
	  false -> {Min,OMax}
	end;
      {{Min1,Max}, {Min2,Max}, {Min,_}} ->
	case inf_geq(Min, OMin = next_down_limit(inf_min([Min1, Min2]))) of
	  true -> {Min,Max};
	  false -> {OMin,Max}
	end;
      {{Min1,Max1}, {Min2,Max2}, {Min,Max}} ->
	RealMax =
	  case inf_geq(OMax = next_up_limit(inf_max([Max1, Max2])), Max) of
	    true -> Max;
	    false -> OMax
	  end,
	RealMin = 
	  case inf_geq(Min, OMin = next_down_limit(inf_min([Min1, Min2]))) of
	    true -> Min;
	    false -> OMin
	  end,
	{RealMin, RealMax};
      _ ->
	Wide
    end,
  T#range{range = ResRange}.

-spec widen(range(), range(), range()) -> range().

widen(#range{range=Old}, #range{range=New}, T = #range{range=Wide}) ->
  ResRange =
    case {Old, New, Wide} of
      {{Min,_}, {Min,Max2}, {_,Max}} ->
	case inf_geq(OMax = next_up_limit(Max2), Max) of
	  true -> {Min,Max};
	  false -> {Min,OMax}
	end;
      {{_,Max}, {Min2,Max}, {Min,_}} ->
	case inf_geq(Min, OMin = next_down_limit(Min2)) of
	  true -> {Min,Max};
	  false -> {OMin,Max}
	end;
      {_, {Min2,Max2}, {Min,Max}} ->
	RealMax =
	  case inf_geq(OMax = next_up_limit(Max2), Max) of
	    true -> Max;
	    false -> OMax
	  end,
	RealMin = 
	  case inf_geq(Min, OMin = next_down_limit(Min2)) of
	    true -> Min;
	    false -> OMin
	  end,
	{RealMin, RealMax};
      _ ->
	Wide
    end,
  T#range{range = ResRange}.

-spec analyse_call(#icode_call{}, call_fun()) -> #icode_call{}.

analyse_call(Call, LookupFun) ->
  case hipe_icode:call_dstlist(Call) of
    [] ->
      Call;
    Dsts ->
      Args = hipe_icode:args(Call),
      Fun = hipe_icode:call_fun(Call),
      Type = hipe_icode:call_type(Call),
      DstRanges = analyse_call_or_enter_fun(Fun, Args, Type, LookupFun),
      NewDefs = [update_info(Var, R) || {Var,R} <- lists:zip(Dsts, DstRanges)],
      hipe_icode:subst_defines(lists:zip(Dsts, NewDefs), Call)
  end.

-spec analyse_move(#icode_move{}) -> #icode_move{}.

analyse_move(Move) ->
  Src = hipe_icode:move_src(Move),
  Dst = hipe_icode:move_dst(Move),
  Range = get_range_from_arg(Src),
  NewDst = update_info(Dst, Range),  
  hipe_icode:subst_defines([{Dst,NewDst}], Move).

-spec analyse_begin_handler(#icode_begin_handler{}) -> #icode_begin_handler{}.

analyse_begin_handler(Handler) ->
  SubstList =
    [{Dst, update_info(Dst, any_type())} ||
      Dst <- hipe_icode:begin_handler_dstlist(Handler)],
  hipe_icode:subst_defines(SubstList, Handler).

-spec analyse_phi(#icode_phi{}) -> #icode_phi{}.
    
analyse_phi(Phi) ->
  {_, Args} = lists:unzip(hipe_icode:phi_arglist(Phi)),
  Dst = hipe_icode:phi_dst(Phi),
  ArgRanges = get_range_from_args(Args),
  %% io:format("Phi-Arg_ranges: ~p ~n", [Arg_ranges]),
  DstRange = sup(ArgRanges),
  NewDst = update_info(Dst, DstRange, fun widen/3),  
  hipe_icode:subst_defines([{Dst, NewDst}], Phi).

-spec analyse_last_insn(icode_instr(), info(), boolean(), call_fun()) ->
	  last_instr_return().

analyse_last_insn(I, Info, Rewrite, LookupFun) ->
  %% io:format("~w Info: ~p~n",[I,Info]),
  NewI = handle_args(I, Info),
  %% io:format("~w -> ~w~n",[NewI,I]),
  case NewI of 
    #icode_return{} -> analyse_return(NewI, Info);
    #icode_enter{} -> analyse_enter(NewI, Info, LookupFun);
    #icode_switch_val{} ->
      {analyse_switch_val(NewI, Info, Rewrite), none_type()};
    #icode_if{} -> {analyse_if(NewI, Info, Rewrite), none_type()};
    #icode_goto{} -> {analyse_goto(NewI, Info), none_type()};	
    #icode_type{} -> {analyse_type(NewI, Info, Rewrite), none_type()};
    #icode_fail{} -> {analyse_fail(NewI, Info), none_type()};
    #icode_call{} -> {analyse_last_call(NewI, Info, LookupFun), none_type()};
    #icode_switch_tuple_arity{} ->
      {analyse_switch_tuple_arity(NewI, Info), none_type()};
    #icode_begin_try{} -> {analyse_begin_try(NewI, Info), none_type()}
  end.

-spec analyse_return(#icode_return{}, info()) -> last_instr_return().

analyse_return(Insn, _Info) ->
  [RetRange] = get_range_from_args(hipe_icode:return_vars(Insn)),
  {{Insn,[]}, RetRange}.

-spec analyse_enter(#icode_enter{}, info(), call_fun()) -> last_instr_return().
  
analyse_enter(Insn, _Info, LookupFun) ->
  Args = hipe_icode:args(Insn),
  Fun = hipe_icode:enter_fun(Insn),
  CallType = hipe_icode:enter_type(Insn),
  [RetRange] = analyse_call_or_enter_fun(Fun, Args, CallType, LookupFun),
  {{Insn,[]}, RetRange}.

-spec analyse_switch_val(#icode_switch_val{}, info(), boolean()) -> instr_split_info().

analyse_switch_val(Switch, Info, Rewrite) -> 
  Var = hipe_icode:switch_val_term(Switch),
  SwitchRange = get_range_from_arg(Var),
  Cases = hipe_icode:switch_val_cases(Switch),
  {FailRange, LabelRangeList} = get_range_label_list(Cases, SwitchRange, []),
  case range__is_none(FailRange) of
    true -> 
      InfoList = update_infos(Var, Info, LabelRangeList),
      if Rewrite -> {update_switch(Switch, LabelRangeList, false), InfoList};
	 true -> {Switch, InfoList}
      end;
    false ->
      FailLabel = hipe_icode:switch_val_fail_label(Switch),
      InfoList = update_infos(Var, Info, [{FailRange, FailLabel}|LabelRangeList]),
      if Rewrite -> {update_switch(Switch, LabelRangeList, true), InfoList};
	 true -> {Switch, InfoList}
      end
  end.

-spec update_infos(argument(), info(), [{range(),label()}]) -> [{label(),info()}].

update_infos(Arg, Info, [{Range, Label}|Rest]) ->
  [{Label,enter_define({Arg,Range},Info)} | update_infos(Arg, Info, Rest)];
update_infos(_, _, []) -> [].

-spec get_range_label_list([{argument(),label()}], range(), [{range(),label()}]) ->
	 {range(),[{range(),label()}]}.

get_range_label_list([{Val,Label}|Cases], SRange, Acc) ->
  VRange = get_range_from_arg(Val),
  None = none_type(),
  case inf(SRange, VRange) of
    None ->
      get_range_label_list(Cases, SRange, Acc);
    ResRange ->
      get_range_label_list(Cases, SRange, [{ResRange,Label}|Acc])
  end;
get_range_label_list([], SRange, Acc) ->
  {PointTypes, _} = lists:unzip(Acc),
  {remove_point_types(SRange, PointTypes), Acc}.

-spec update_switch(#icode_switch_val{}, [{range(),label()}], boolean()) ->
	 #icode_switch_val{}.

update_switch(Switch, LabelRangeList, KeepFail) ->
  S2 =
    case label_range_list_to_cases(LabelRangeList, []) of
      no_update ->
	Switch;
      Cases ->
	hipe_icode:switch_val_cases_update(Switch, Cases)
    end,
  if KeepFail -> S2;
     true -> S2
  end.

-spec label_range_list_to_cases([{range(),label()}], [{#icode_const{},label()}]) ->
	 'no_update' | [{#icode_const{},label()}].

label_range_list_to_cases([{#range{range={C,C},other=false},Label}|Rest],
			  Acc) when is_integer(C) -> 
  label_range_list_to_cases(Rest, [{hipe_icode:mk_const(C),Label}|Acc]);
label_range_list_to_cases([{_NotAConstantRange,_Label}|_Rest], _Acc) ->
  no_update;
label_range_list_to_cases([], Acc) ->
  lists:reverse(Acc).

-spec analyse_switch_tuple_arity(#icode_switch_tuple_arity{}, info()) ->
	 {#icode_switch_tuple_arity{}, [{label(),info()}]}.
  
analyse_switch_tuple_arity(Switch, Info) -> 
  Var = hipe_icode:switch_tuple_arity_term(Switch),
  NewInfo = enter_define({Var, get_range_from_arg(Var)}, Info),
  Cases = hipe_icode:switch_tuple_arity_cases(Switch),
  Fail = hipe_icode:switch_tuple_arity_fail_label(Switch),
  {_, Case_labels} = lists:unzip(Cases),
  Labels = [Fail|Case_labels],
  {Switch, [{Label,NewInfo} || Label <- Labels]}.

-spec analyse_goto(#icode_goto{}, info()) -> {#icode_goto{}, [{label(),info()},...]}.

analyse_goto(Insn, Info) ->
  GotoLabel = hipe_icode:goto_label(Insn),
  {Insn, [{GotoLabel,Info}]}.

-spec analyse_fail(#icode_fail{}, info()) -> {#icode_fail{}, [{label(),info()}]}.

analyse_fail(Fail, Info) ->
  case hipe_icode:fail_label(Fail) of
    [] -> {Fail, []};
    Label -> {Fail, [{Label,Info}]}
  end.

-spec analyse_begin_try(#icode_begin_try{}, info()) ->
	 {#icode_begin_try{}, [{label(),info()},...]}.

analyse_begin_try(Insn, Info) ->
  Label = hipe_icode:begin_try_label(Insn),
  Successor = hipe_icode:begin_try_successor(Insn),
  {Insn, [{Label,Info},{Successor,Info}]}.

-spec analyse_last_call(#icode_call{}, info(), call_fun()) ->
	 {#icode_call{}, [{label(),info()},...]}.

analyse_last_call(Call, Info, LookupFun) ->
  %% hipe_icode_pp:pp_block([Insn]),
  NewI = analyse_call(Call, LookupFun),
  Continuation = hipe_icode:call_continuation(Call),
  NewInfo = enter_vals(NewI, Info),
  case hipe_icode:call_fail_label(Call) of
    [] -> 
      {NewI, [{Continuation, NewInfo}]};
    Fail ->
      {NewI, [{Continuation, NewInfo}, {Fail, Info}]}
  end.

-spec analyse_if(#icode_if{}, info(), boolean()) ->
	 {#icode_goto{} | #icode_if{}, [{label(),info()}]}.

analyse_if(If, Info, Rewrite) ->
  case hipe_icode:if_args(If) of
    [_, _] = Args ->
      analyse_sane_if(If, Info, Args, get_range_from_args(Args), Rewrite);
    _ ->
      TrueLabel = hipe_icode:if_true_label(If),
      FalseLabel = hipe_icode:if_false_label(If),
      {If, [{TrueLabel, Info}, {FalseLabel, Info}]}
  end.

-spec analyse_sane_if(#icode_if{}, info(), [argument(),...],
		      [range(),...], boolean()) ->
	 {#icode_goto{} | #icode_if{}, [{label(), info()}]}.

analyse_sane_if(If, Info, [Arg1, Arg2], [Range1, Range2], Rewrite) ->
  {TrueRange1, TrueRange2, FalseRange1, FalseRange2} =
    case normalize_name(hipe_icode:if_op(If)) of
      '>' ->
	{TR2, TR1, FR2, FR1} = range_inequality_propagation(Range2, Range1),
	{TR1, TR2, FR1, FR2};
      '<' ->
	range_inequality_propagation(Range1, Range2);
      '>=' ->
	{FR1, FR2, TR1, TR2} = range_inequality_propagation(Range1, Range2),
	{TR1, TR2, FR1, FR2};
      '=<' ->
	{FR2, FR1, TR2, TR1} = range_inequality_propagation(Range2, Range1),
	{TR1, TR2, FR1, FR2};
      '=:=' ->
	{TR1, TR2, FR1, FR2} = range_equality_propagation(Range1, Range2),
	{TR1, TR2, FR1, FR2};
      '=/=' ->
	{FR1, FR2, TR1, TR2} = range_equality_propagation(Range1, Range2),
	{TR1, TR2, FR1, FR2};
      '==' ->
	{TR1, TR2, FR1, FR2} = range_equality_propagation(Range1, Range2),
	{set_other(TR1,other(Range1)), set_other(TR2,other(Range2)), FR1, FR2};
      '/=' ->
	{FR1, FR2, TR1, TR2} = range_equality_propagation(Range1, Range2),
	{TR1, TR2, set_other(FR1,other(Range1)), set_other(FR2,other(Range2))}
    end,
  %% io:format("TR1 = ~w\nTR2 = ~w\n", [TrueRange1, TrueRange2]),
  True =
    case lists:all(fun range__is_none/1, [TrueRange1, TrueRange2]) of
      true -> [];
      false ->
	TrueLabel = hipe_icode:if_true_label(If),
	TrueArgRanges = [{Arg1, TrueRange1}, {Arg2, TrueRange2}],
	TrueInfo = enter_defines(TrueArgRanges, Info),
	[{TrueLabel, TrueInfo}]
    end,
  %% io:format("FR1 = ~w\nFR2 = ~w\n", [FalseRange1, FalseRange2]),
  False =
    case lists:all(fun range__is_none/1, [FalseRange1, FalseRange2]) of
      true -> [];
      false ->
	FalseLabel = hipe_icode:if_false_label(If),
	FalseArgRanges = [{Arg1, FalseRange1}, {Arg2, FalseRange2}],
	FalseInfo = enter_defines(FalseArgRanges, Info),
	[{FalseLabel, FalseInfo}]
    end,
  UpdateInfo = True ++ False,
  NewIF =
    if Rewrite ->
	case UpdateInfo of
	  [] -> %% This is weird
	    If;
	  [{Label, _Info}] ->
	    hipe_icode:mk_goto(Label);
	  [_, _] ->
	    If
	end;
       true ->
	If
    end,
  {NewIF, UpdateInfo}.

-spec normalize_name(atom()) -> atom().

normalize_name(Name) ->
  case Name of
    'fixnum_eq'  -> '=:='; 
    'fixnum_neq' -> '=/=';
    'fixnum_gt'  -> '>';
    'fixnum_lt'  -> '<';
    'fixnum_ge'  -> '>=';
    'fixnum_le'  -> '=<';
    Name -> Name
  end.

-spec range_equality_propagation(range(), range()) ->
	  {range(), range(), range(), range()}.

range_equality_propagation(Range1, Range2) ->  
  TrueRange = inf(Range1, Range2),
  {FalseRange1, FalseRange2} =
    case {range(Range1), range(Range2)} of
      {{N,N}, {N,N}} ->
	{none_range(), none_range()};
      {{N1,N1}, {N2,N2}} ->
	{Range1, Range2};
      {{N,N}, _} ->
	{_,FR2} = compare_with_integer(N, Range2),
	{Range1, FR2};
      {_, {N,N}} ->
	{_,FR1} = compare_with_integer(N, Range1),
	{FR1, Range2};
      {_, _} ->
	{Range1, Range2}
    end,
  {TrueRange, TrueRange, FalseRange1, FalseRange2}.

-spec range_inequality_propagation(range(), range()) ->
	  {range(), range(), range(), range()}.

%% Range1 < Range2
range_inequality_propagation(Range1, Range2) ->
  R1_other = other(Range1),
  R2_other = other(Range2),
  {R1_true_range, R1_false_range, R2_true_range, R2_false_range} =
    case {range(Range1), range(Range2)} of
      {{N1,N1}, {N2,N2}} ->
	case inf_geq(N2,inf_add(N1,1)) of
	  true ->
	    {{N1,N1},empty,{N2,N2},empty};
	  false ->
	    {empty,{N1,N1},empty,{N2,N2}}
	  end;
      {{N1,N1}, {Min2,Max2}} ->
	case inf_geq(Min2,inf_add(N1,1)) of
	  true ->
	    {{N1,N1},empty,{inf_add(N1,1),Max2},empty};
	  false ->
	    case inf_geq(N1,Max2) of
	      true ->
		{empty,{N1,N1},empty,{Min2,N1}};
	      false ->
		{{N1,N1},{N1,N1},{inf_add(N1,1),Max2},{Min2,N1}}
	    end
	end;
      {{Min1,Max1}, {N2,N2}} ->
	case inf_geq(N2,inf_add(Max1,1)) of
	  true ->
	  {{Min1,inf_add(N2,-1)},empty,{N2,N2},empty};
	  false ->
	    case inf_geq(Min1,N2) of
	      true ->
		{empty,{N2,Max1},empty,{N2,N2}};
	      false ->
		{{Min1,inf_add(N2,-1)},{N2,Max1},{N2,N2},{N2,N2}}
	    end
	end;
      {empty, {Min2,Max2}} ->
	{empty,empty,{Min2,Max2},{Min2,Max2}};
      {{Min1,Max1}, empty} ->
	{{Min1,Max1},{Min1,Max1},empty,empty};
      {empty, empty} ->
	{empty,empty,empty,empty};
      {{Min1,Max1}, {Min2,Max2}} ->
	{{Min1,inf_min([Max1,inf_add(Max2,-1)])},
	 {inf_max([Min1,Min2]),Max1},
	 {inf_max([inf_add(Min1,1),Min2]),Max2},
	 {Min2,inf_min([Max1,Max2])}}
    end,
  {range_init(R1_true_range, R1_other),
   range_init(R2_true_range, R2_other),
   range_init(R1_false_range, R1_other),
   range_init(R2_false_range, R2_other)}.

-spec analyse_type(#icode_type{}, info(), boolean()) ->
	 {#icode_goto{} | #icode_type{}, [{label(),info()}]}.

analyse_type(Type, Info, Rewrite) ->
  TypeTest = hipe_icode:type_test(Type),
  [Arg|_] = hipe_icode:type_args(Type),
  OldVarRange = get_range_from_arg(Arg),
  {TrueRange, FalseRange} =
    case TypeTest of
      {integer, N} ->
	compare_with_integer(N, OldVarRange);
      integer ->
	{inf(any_range(), OldVarRange), inf(none_range(), OldVarRange)};
      number ->
	{OldVarRange, OldVarRange};
      _ ->
	{inf(none_range(), OldVarRange), OldVarRange}
    end,
  TrueLabel = hipe_icode:type_true_label(Type),
  FalseLabel = hipe_icode:type_false_label(Type),
  TrueInfo = enter_define({Arg, TrueRange}, Info),
  FalseInfo = enter_define({Arg, FalseRange}, Info),
  True =
    case range__is_none(TrueRange) of
      true -> [];
      false -> [{TrueLabel, TrueInfo}]
    end,
  False =
    case range__is_none(FalseRange) of
      true -> [];
      false -> [{FalseLabel, FalseInfo}]
    end,
  UpdateInfo = True ++ False,
  NewType =
    if Rewrite ->
	case UpdateInfo of
	  [] -> %% This is weird
	    Type;
	  [{Label,_Info}] ->
	    hipe_icode:mk_goto(Label);
	  [_, _] ->
	    Type
	end;
       true ->
	Type
    end,
  {NewType, True ++ False}.

-spec compare_with_integer(integer(), range()) -> {range(), range()}.

compare_with_integer(N, OldVarRange) ->
  TestRange = range_init({N, N}, false),
  TrueRange = inf(TestRange, OldVarRange),
  %% False range
  TempFalseRange = range__remove_constant(OldVarRange, TestRange),
  BetterRange = 
    case range(TempFalseRange) of
      {Min, Max} = MM ->
	New_small = inf_geq(Min, N),
	New_large = inf_geq(N, Max),
	if New_small and not New_large ->
	    {N + 1, Max};
	   New_large and not New_small ->
	    {Min, N - 1};
	   true -> 
	    MM
	end;
      Not_tuple ->
	Not_tuple
    end,
  FalseRange = range_init(BetterRange, other(TempFalseRange)),
  {TrueRange, FalseRange}.

%%== Ranges ==================================================================

-spec pp_ann(ann() | erl_types:erl_type()) -> string().

pp_ann(#ann{range = #range{range = R, other = false}}) ->
  pp_range(R);
pp_ann(#ann{range = #range{range = empty, other = true}, type = Type}) ->
  t_to_string(Type);
pp_ann(#ann{range = #range{range = R, other = true}, type = Type}) ->
  pp_range(R) ++ " | " ++ t_to_string(Type);
pp_ann(Type) ->
  t_to_string(Type).

-spec pp_range(range_rep()) -> nonempty_string().

pp_range(empty) ->
  "none";
pp_range({Min, Max}) ->
  val_to_string(Min) ++ ".." ++ val_to_string(Max).

-spec val_to_string('pos_inf' | 'neg_inf' | integer()) -> string().

val_to_string(pos_inf) -> "inf";
val_to_string(neg_inf) -> "-inf";
val_to_string(X) when is_integer(X) -> integer_to_list(X).

-spec range_from_type(erl_types:erl_type()) -> [range()].

range_from_type(Type) ->
  [range_from_simple_type(T) || T <- t_to_tlist(Type)].
  
-spec range_from_simple_type(erl_types:erl_type()) -> range().

range_from_simple_type(Type) ->
  None = t_none(),
  case t_inf(t_integer(), Type) of
    None ->
      #range{range = empty, other = true};
    Type ->
      Range = {number_min(Type), number_max(Type)},
      #range{range = Range, other = false};
    NewType ->
      Range = {number_min(NewType), number_max(NewType)},
      #range{range = Range, other = true}
  end.

-spec range_init(range_rep(), boolean()) -> range().

range_init({Min, Max} = Range, Other) ->
  case inf_geq(Max, Min) of
    true ->
      #range{range = Range, other = Other};
    false ->
      #range{range = empty, other = Other}
  end;
range_init(empty, Other) ->
  #range{range = empty, other = Other}.

-spec range(range()) -> range_rep().

range(#range{range = R}) -> R.

-spec other(range()) -> boolean().

other(#range{other = O}) -> O.

-spec set_other(range(), boolean()) -> range().

set_other(R, O) -> R#range{other = O}.

-spec range__min(range()) -> 'empty' | 'neg_inf' | integer().

range__min(#range{range = empty}) -> empty;
range__min(#range{range = {Min,_}}) -> Min.

-spec range__max(range()) -> 'empty' | 'pos_inf' | integer().

range__max(#range{range = empty}) -> empty;
range__max(#range{range = {_,Max}}) -> Max.

-spec range__is_none(range()) -> boolean().

range__is_none(#range{range = empty, other = false}) -> true;
range__is_none(#range{}) -> false.

-spec range__is_empty(range()) -> boolean().

range__is_empty(#range{range = empty}) -> true;
range__is_empty(#range{range = {_,_}}) -> false.

-spec remove_point_types(range(), [range()]) -> range().

remove_point_types(Range, Ranges) ->
  Sorted = lists:sort(Ranges),
  FoldFun = fun (R, Acc) -> range__remove_constant(Acc,R) end,
  Range1 = lists:foldl(FoldFun, Range, Sorted),
  lists:foldl(FoldFun, Range1, lists:reverse(Sorted)).

-spec range__remove_constant(range(), range()) -> range().

range__remove_constant(#range{range = {C, C}} = R, #range{range = {C, C}}) ->
  R#range{range = empty};
range__remove_constant(#range{range = {C, H}} = R, #range{range = {C, C}}) ->
  R#range{range = {C+1, H}};
range__remove_constant(#range{range = {L, C}} = R, #range{range = {C, C}}) ->
  R#range{range = {L, C-1}};
range__remove_constant(#range{} = R, #range{range = {C,C}}) ->
  R;
range__remove_constant(#range{} = R, _) ->
  R.

-spec any_type() -> range().

any_type() ->
  #range{range = any_r(), other = true}.

-spec any_range() -> range().

any_range() ->
  #range{range = any_r(), other = false}.

-spec none_range() -> range().

none_range() ->
  #range{range = empty, other = true}.

-spec none_type() -> range().

none_type() ->
  #range{range = empty, other = false}.

-spec any_r() -> {'neg_inf','pos_inf'}.

any_r() -> {neg_inf, pos_inf}.

-spec get_range_from_args([argument()]) -> [range()].
  
get_range_from_args(Args) ->
  [get_range_from_arg(Arg) || Arg <- Args].

-spec get_range_from_arg(argument()) -> range().

get_range_from_arg(Arg) ->
  case hipe_icode:is_const(Arg) of
    true ->
      Value = hipe_icode:const_value(Arg),
      case is_integer(Value) of
	true ->
	  #range{range = {Value, Value}, other = false};
	false ->
	  #range{range = empty, other = true}
      end;
    false ->
      case hipe_icode:is_annotated_variable(Arg) of
	true ->
	  case hipe_icode:variable_annotation(Arg) of
	    {range_anno, #ann{range = Range}, _} ->
	      Range;
	    {type_anno, Type, _} ->
	      range_from_simple_type(Type)
	  end;
	false ->
	  any_type()
      end
  end.

%% inf([R]) ->
%%   R;
%% inf([R1,R2|Rest]) ->
%%   inf([inf(R1,R2)|Rest]).

-spec inf(range(), range()) -> range().

inf(#range{range=R1, other=O1}, #range{range=R2, other=O2}) -> 
  #range{range=range_inf(R1,R2), other=other_inf(O1,O2)}.

-spec range_inf(range_rep(), range_rep()) -> range_rep().

range_inf(empty, _) -> empty;
range_inf(_, empty) -> empty;
range_inf({Min1,Max1}, {Min2,Max2}) ->
  NewMin = inf_max([Min1, Min2]),
  NewMax = inf_min([Max1, Max2]),
  case inf_geq(NewMax, NewMin) of
    true ->
      {NewMin, NewMax};
    false ->
      empty
  end.

-spec other_inf(boolean(), boolean()) -> boolean().

other_inf(O1, O2) -> O1 and O2.

-spec sup([range(),...]) -> range().

sup([R]) ->
  R;
sup([R1,R2|Rest]) ->
  sup([sup(R1, R2)|Rest]).

-spec sup(range(), range()) -> range().

sup(#range{range=R1,other=O1}, #range{range=R2,other=O2}) -> 
  #range{range=range_sup(R1,R2), other=other_sup(O1,O2)}.

-spec range_sup(range_rep(), range_rep()) -> range_rep().
	 
range_sup(empty, R) -> R;
range_sup(R, empty) -> R;
range_sup({Min1,Max1}, {Min2,Max2}) ->
  NewMin = inf_min([Min1,Min2]),
  NewMax = inf_max([Max1,Max2]),
  {NewMin,NewMax}.

-spec other_sup(boolean(), boolean()) -> boolean().

other_sup(O1, O2) -> O1 or O2.

%%== Call Support =============================================================

-spec analyse_call_or_enter_fun(fun_name(), [argument()],
				icode_call_type(), call_fun()) -> [range()].

analyse_call_or_enter_fun(Fun, Args, CallType, LookupFun) ->
  %%io:format("Fun: ~p~n Args: ~p~n CT: ~p~n LF: ~p~n", [Fun, Args, CallType, LookupFun]),
  case basic_type(Fun) of
    {bin, Operation} ->
      [Arg_range1,Arg_range2] = get_range_from_args(Args),
      A1_is_empty = range__is_empty(Arg_range1),
      A2_is_empty = range__is_empty(Arg_range2),
      case A1_is_empty orelse A2_is_empty of
	true ->
	  [none_type()];
	false ->
	  [Operation(Arg_range1, Arg_range2)]
      end;
    {unary, Operation} ->
      [Arg_range] = get_range_from_args(Args),
      case range__is_empty(Arg_range) of
	true ->
	  [none_type()];
	false ->
	  [Operation(Arg_range)]
      end;
    {fcall, MFA} ->
      case CallType of
	local ->
	  Range = LookupFun(MFA, get_range_from_args(Args)),
	  case range__is_none(Range) of
	    true ->
	      throw(none_range);
	    false ->
	      [Range]
	  end;
	remote ->
	  [any_type()]
      end;
    not_int ->
      [any_type()];
    not_analysed -> 
      [any_type()];
    {hipe_bs_primop, {bs_get_integer, Size, Flags}} ->
      {Min, Max} = analyse_bs_get_integer(Size, Flags, length(Args) =:= 1),
      [#range{range = {Min, Max}, other = false}, any_type()];
    {hipe_bs_primop, _} = Primop ->
      Type = hipe_icode_primops:type(Primop),
      range_from_type(Type)
  end.

-type bin_operation() :: fun((range(), range()) -> range()).
-type unary_operation() :: fun((range()) -> range()).

-spec basic_type(fun_name()) -> 'not_int' | 'not_analysed'
			     | {'bin', bin_operation()}
			     | {'unary', unary_operation()}
			     | {'fcall', mfa()} | {'hipe_bs_primop', _}.

%% Arithmetic operations
basic_type('+') -> {bin, fun(R1, R2) -> range_add(R1, R2) end};
basic_type('-') -> {bin, fun(R1, R2) -> range_sub(R1, R2) end};
basic_type('*') -> {bin, fun(R1, R2) -> range_mult(R1, R2) end};
basic_type('/') -> not_int;
basic_type('div') -> {bin, fun(R1, R2) -> range_div(R1, R2) end};
basic_type('rem') -> {bin, fun(R1, R2) -> range_rem(R1, R2) end};
basic_type('bor') -> {bin, fun(R1, R2) -> range_bor(R1, R2) end};
basic_type('band') -> {bin, fun(R1, R2) -> range_band(R1, R2) end};
basic_type('bxor') -> {bin, fun(R1, R2) -> range_bxor(R1, R2) end};
basic_type('bnot') -> {unary, fun(R1) -> range_bnot(R1) end};
basic_type('bsl') -> {bin, fun(R1, R2) -> range_bsl(R1, R2) end};
basic_type('bsr') -> {bin, fun(R1, R2) -> range_bsr(R1, R2) end};
%% unsafe_*
basic_type('unsafe_bor') ->  
  {bin, fun(R1, R2) -> range_bor(R1, R2) end};
basic_type('unsafe_band') ->
  {bin, fun(R1, R2) -> range_band(R1, R2) end};
basic_type('unsafe_bxor') ->
  {bin, fun(R1, R2) -> range_bxor(R1, R2) end};
basic_type('unsafe_bnot') ->
  {unary, fun(R1) -> range_bnot(R1) end};
basic_type('unsafe_bsl') ->
  {bin, fun(R1, R2) -> range_bsl(R1, R2) end};
basic_type('unsafe_bsr') ->
  {bin, fun(R1, R2) -> range_bsr(R1, R2) end};
basic_type('unsafe_add') ->
  {bin, fun(R1, R2) -> range_add(R1, R2) end};
basic_type('unsafe_sub') ->
  {bin, fun(R1, R2) -> range_sub(R1, R2) end};
basic_type('extra_unsafe_add') ->
  {bin, fun(R1, R2) -> range_add(R1, R2) end};
basic_type('extra_unsafe_sub') ->
  {bin, fun(R1, R2) -> range_sub(R1, R2) end};
%% Binaries
basic_type({hipe_bs_primop, _} = Primop) -> Primop;
%% Unknown, other
basic_type(call_fun) -> not_analysed;
basic_type(clear_timeout) -> not_analysed;
basic_type(redtest) -> not_analysed;
basic_type(set_timeout) -> not_analysed;
basic_type(#apply_N{}) -> not_analysed;
basic_type(#closure_element{}) -> not_analysed;
basic_type(#gc_test{}) -> not_analysed;
%% Message handling
basic_type(check_get_msg) -> not_analysed;
basic_type(next_msg) -> not_analysed;
basic_type(select_msg) -> not_analysed;
basic_type(suspend_msg) -> not_analysed;
%% Functions
basic_type(enter_fun) -> not_analysed;
basic_type(#mkfun{}) -> not_int;
basic_type({_M,_F,_A} = MFA) -> {fcall, MFA}; 
%% Floats
basic_type(conv_to_float) -> not_int;
basic_type(fclearerror) -> not_analysed;
basic_type(fcheckerror) -> not_analysed;
basic_type(fnegate) -> not_int;
basic_type(fp_add) -> not_int;
basic_type(fp_div) -> not_int;
basic_type(fp_mul) -> not_int;
basic_type(fp_sub) -> not_int;
basic_type(unsafe_tag_float) -> not_int;
basic_type(unsafe_untag_float) -> not_int;
%% Lists, tuples, records
basic_type(cons) -> not_int;
basic_type(mktuple) -> not_int;
basic_type(unsafe_hd) -> not_analysed;
basic_type(unsafe_tl) -> not_int;
basic_type(#element{}) -> not_analysed;
basic_type(#unsafe_element{}) -> not_analysed;
basic_type(#unsafe_update_element{}) -> not_analysed.

-spec analyse_bs_get_integer(integer(), integer(), boolean()) -> range_tuple().

analyse_bs_get_integer(Size, Flags, true) ->
  Signed = Flags band 4,
  case Signed =:= 0 of
    true ->
      {0, inf_add(inf_bsl(1, Size), -1)};	% return {Min, Max}
    false ->
      {inf_inv(inf_bsl(1, Size-1)), inf_add(inf_bsl(1, Size-1), -1)}
  end;
analyse_bs_get_integer(Size, Flags, false) when is_integer(Size),
						is_integer(Flags) ->
  any_r().

%%---------------------------------------------------------------------------
%% Range operations
%%---------------------------------------------------------------------------

%% Arithmetic

-spec range_add(range(), range()) -> range().

range_add(Range1, Range2) ->
  NewMin = inf_add(range__min(Range1), range__min(Range2)),
  NewMax = inf_add(range__max(Range1), range__max(Range2)),
  Other = other(Range1) orelse other(Range2),
  range_init({NewMin, NewMax}, Other).

-spec range_sub(range(), range()) -> range().

range_sub(Range1, Range2) ->
  Min_sub = inf_min([inf_inv(range__max(Range2)), 
		     inf_inv(range__min(Range2))]),
  Max_sub = inf_max([inf_inv(range__max(Range2)), 
		     inf_inv(range__min(Range2))]),
  NewMin = inf_add(range__min(Range1), Min_sub),
  NewMax = inf_add(range__max(Range1), Max_sub),
  Other = other(Range1) orelse other(Range2),
  range_init({NewMin, NewMax}, Other).

-spec range_mult(range(), range()) -> range().

range_mult(#range{range=empty, other=true}, _Range2) ->
  range_init(empty, true);
range_mult(_Range1, #range{range=empty, other=true}) ->
  range_init(empty, true);
range_mult(Range1, Range2) ->
  Min1 = range__min(Range1),
  Min2 = range__min(Range2),
  Max1 = range__max(Range1),
  Max2 = range__max(Range2),
  GreaterMin1 = inf_greater_zero(Min1),
  GreaterMin2 = inf_greater_zero(Min2),
  GreaterMax1 = inf_greater_zero(Max1),
  GreaterMax2 = inf_greater_zero(Max2),
  Range =
    if GreaterMin1 -> 
	if GreaterMin2 -> {inf_mult(Min1, Min2), inf_mult(Max1, Max2)};
	   GreaterMax2 -> {inf_mult(Min2, Max1), inf_mult(Max2, Max1)};
	   true        -> {inf_mult(Min2, Max1), inf_mult(Max2, Min1)}
	end;
       %% Column 1 or 2
       GreaterMin2 -> % Column 1 or 2 row 3
	range(range_mult(Range2, Range1));
       GreaterMax1 -> % Column 2 Row 1 or 2
	if GreaterMax2 -> % Column 2 Row 2
	    NewMin = inf_min([inf_mult(Min2, Max1), inf_mult(Max2, Min1)]),
	    NewMax = inf_max([inf_mult(Min2, Min1), inf_mult(Max2, Max1)]),
	    {NewMin, NewMax};
	   true -> % Column 2 Row 1
	    {inf_mult(Min2, Max1), inf_mult(Min2, Min1)}
	end;
       GreaterMax2 -> % Column 1 Row 2
	range(range_mult(Range2, Range1));
       true -> % Column 1 Row 1
	{inf_mult(Max1, Max2), inf_mult(Min2, Min1)}
    end,
  Other = other(Range1) orelse other(Range2),
  range_init(Range, Other).

-spec extreme_divisors(range()) -> range_tuple().

extreme_divisors(#range{range={0,0}}) -> {0,0};
extreme_divisors(#range{range={0,Max}}) -> {1,Max};
extreme_divisors(#range{range={Min,0}}) -> {Min,-1};
extreme_divisors(#range{range={Min,Max}}) ->
  case inf_geq(Min, 0) of 
    true -> {Min, Max};
    false -> % Min < 0
      case inf_geq(0, Max) of
	true -> {Min,Max}; % Max < 0
	false -> {-1,1} % Max > 0
      end
  end.

-spec range_div(range(), range()) -> range().

%% this is div, not /.
range_div(_, #range{range={0,0}}) ->
  range_init(empty, false);
range_div(#range{range=empty}, _) ->
  range_init(empty, false);
range_div(_, #range{range=empty}) ->
  range_init(empty, false);
range_div(Range1, Den) ->
  Min1 = range__min(Range1),
  Max1 = range__max(Range1),
  {Min2, Max2} = extreme_divisors(Den),
  Min_max_list = [inf_div(Min1, Min2), inf_div(Min1, Max2),
		  inf_div(Max1, Min2), inf_div(Max1, Max2)],
  range_init({inf_min(Min_max_list), inf_max(Min_max_list)}, false).

-spec range_rem(range(), range()) -> range().

range_rem(Range1, Range2) ->
  %% Range1 desides the sign of the answer.
  Min1 = range__min(Range1),
  Max1 = range__max(Range1),
  Min2 = range__min(Range2),
  Max2 = range__max(Range2),
  Min1_geq_zero = inf_geq(Min1, 0),
  Max1_leq_zero = inf_geq(0, Max1),
  Max_range2 = inf_max([inf_abs(Min2), inf_abs(Max2)]),
  Max_range2_leq_zero = inf_geq(0, Max_range2),
  New_min = 
    if Min1_geq_zero ->	0;
       Max_range2_leq_zero -> Max_range2;
       true -> inf_inv(Max_range2)
    end,
  New_max = 
    if Max1_leq_zero -> 0;
       Max_range2_leq_zero -> inf_inv(Max_range2);
       true -> Max_range2
    end,
  range_init({New_min, New_max}, false).

%%--- Bit operations ----------------------------

-spec range_bsr(range(), range()) -> range().

range_bsr(Range1, Range2=#range{range={Min, Max}}) -> 
  New_Range2 = range_init({inf_inv(Max), inf_inv(Min)}, other(Range2)), 
  Ans = range_bsl(Range1, New_Range2),
  %% io:format("bsr res:~w~nInput:= ~w~n", [Ans, {Range1,Range2}]),
  Ans.

-spec range_bsl(range(), range()) -> range().

range_bsl(Range1, Range2) ->
  Min1 = range__min(Range1),
  Min2 = range__min(Range2),
  Max1 = range__max(Range1),
  Max2 = range__max(Range2),
  Min1Geq0 = inf_geq(Min1, 0),
  Max1Less0 = not inf_geq(Max1, 0),
  MinMax =
    if Min1Geq0 ->
	{inf_bsl(Min1, Min2), inf_bsl(Max1, Max2)};
       true ->
	if Max1Less0 -> {inf_bsl(Min1, Max2), inf_bsl(Max1, Min2)};
	   true -> {inf_bsl(Min1, Max2), inf_bsl(Max1, Max2)}
	end
    end,
  range_init(MinMax, false).

-spec range_bnot(range()) -> range().

range_bnot(Range) ->
  Minus_one = range_init({-1,-1}, false),
  range_add(range_mult(Range, Minus_one), Minus_one).

-spec width(range_rep() | inf_integer()) -> 'pos_inf' | non_neg_integer().

width({Min, Max}) -> inf_max([width(Min), width(Max)]);
width(pos_inf) -> pos_inf;
width(neg_inf) -> pos_inf;
width(X) when is_integer(X), X >= 0 -> poswidth(X, 0);
width(X) when is_integer(X), X < 0 -> negwidth(X, 0).

-spec poswidth(non_neg_integer(), non_neg_integer()) -> non_neg_integer().

poswidth(X, N) ->
  case X < (1 bsl N) of
    true  -> N;
    false -> poswidth(X, N+1)
  end.

-spec negwidth(neg_integer(), non_neg_integer()) -> non_neg_integer().

negwidth(X, N) ->
  case X > (-1 bsl N) of
    true  -> N;
    false -> negwidth(X, N+1)
  end.

-spec range_band(range(), range()) -> range().

range_band(R1, R2) ->
  {_Min1, Max1} = MM1 = range(R1),
  {_Min2, Max2} = MM2 = range(R2),
  Width1 = width(MM1),
  Width2 = width(MM2),
  Range = 
    case {classify_range(R1), classify_range(R2)} of
      {minus_minus, minus_minus} ->
	Width = inf_max([Width1, Width2]),
	{inf_bsl(-1, Width), -1};
      {minus_minus, minus_plus} ->
	Width = inf_max([Width1, Width2]),
	{inf_bsl(-1, Width), Max2};
      {minus_minus, plus_plus} ->
	{0, Max2};
      {minus_plus,  minus_minus} ->
	Width = inf_max([Width1, Width2]),
	{inf_bsl(-1, Width), Max1};
      {minus_plus,  minus_plus} ->
	Width = inf_max([Width1, Width2]),
	{inf_bsl(-1, Width), inf_max([Max1, Max2])};
      {minus_plus,  plus_plus} ->
	{0, Max2};
      {plus_plus,   minus_minus} ->
	{0, Max1};
      {plus_plus,   minus_plus} ->
	{0, Max1};
      {plus_plus,   plus_plus} ->
	{0, inf_min([Max1, Max2])}
    end,
  range_init(Range, false).  

-spec range_bor(range(), range()) -> range().

range_bor(R1, R2) ->
  {Min1, _Max1} = MM1 = range(R1),
  {Min2, _Max2} = MM2 = range(R2),
  Width1 = width(MM1),
  Width2 = width(MM2),
  Range = 
    case {classify_range(R1), classify_range(R2)} of
      {minus_minus, minus_minus} ->
	{inf_max([Min1, Min2]), -1};
      {minus_minus, minus_plus} ->
	{Min1, -1};
      {minus_minus, plus_plus} ->
	{Min1, -1};
      {minus_plus,  minus_minus} ->
	{Min2, -1};
      {minus_plus,  minus_plus} ->
	Width = inf_max([Width1, Width2]),
	{inf_min([Min1, Min2]), inf_add(-1, inf_bsl(1, Width))};
      {minus_plus,  plus_plus} ->
	Width = inf_max([Width1, Width2]),
	{Min1, inf_add(-1, inf_bsl(1, Width))};
      {plus_plus,   minus_minus} ->
	{Min2, -1};
      {plus_plus,   minus_plus} ->
	Width = inf_max([Width1, Width2]),
	{Min2, inf_add(-1, inf_bsl(1, Width))};
      {plus_plus,   plus_plus} ->
	Width = inf_max([Width1, Width2]),
	{0, inf_add(-1, inf_bsl(1, Width))}
    end,
  range_init(Range, false).  

-spec classify_range(range()) -> 'minus_minus' | 'minus_plus' | 'plus_plus'.

classify_range(Range) ->
  case range(Range) of
    {neg_inf, Number} when is_integer(Number), Number < 0 -> minus_minus;
    {neg_inf, Number} when is_integer(Number), Number >= 0 -> minus_plus;
    {Number, pos_inf} when is_integer(Number), Number < 0 -> minus_plus;
    {Number, pos_inf} when is_integer(Number), Number >= 0 -> plus_plus;
    {neg_inf, pos_inf} -> minus_plus;
    {Number1,Number2} when is_integer(Number1), is_integer(Number2) ->
      classify_int_range(Number1, Number2)
  end.

-spec classify_int_range(integer(), integer()) ->
	  'minus_minus' | 'minus_plus' | 'plus_plus'.

classify_int_range(Number1, _Number2) when Number1 >= 0 ->
  plus_plus;
classify_int_range(_Number1, Number2) when Number2 < 0 ->
  minus_minus;
classify_int_range(_Number1, _Number2) ->
  minus_plus.
      
-spec range_bxor(range(), range()) -> range().

range_bxor(R1, R2) ->
  {Min1, Max1} = MM1 = range(R1),
  {Min2, Max2} = MM2 = range(R2),
  Width1 = width(MM1),
  Width2 = width(MM2),
  Range =
    case {classify_range(R1), classify_range(R2)} of
      {minus_minus, minus_minus} ->
	Width = inf_max([Width1, Width2]),
	{0, inf_add(-1, inf_bsl(1, Width))};
      {minus_minus, minus_plus} ->
	MinWidth = inf_max([Width1, width({0,Max2})]),
	MaxWidth = inf_max([Width1, width({Min2,-1})]),
	{inf_bsl(-1, MinWidth), inf_add(-1, inf_bsl(1, MaxWidth))};
      {minus_minus, plus_plus} ->
	Width = inf_max([Width1, Width2]),
	{inf_bsl(-1, Width), -1};
      {minus_plus,  minus_minus} ->
	MinWidth = inf_max([Width2,width({0,Max1})]),
	MaxWidth = inf_max([Width2,width({Min1,-1})]),
	{inf_bsl(-1, MinWidth), inf_add(-1, inf_bsl(1, MaxWidth))};
      {minus_plus,  minus_plus} ->
	Width = inf_max([Width1, Width2]),
	{inf_bsl(-1, Width), inf_add(-1, inf_bsl(1, Width))};
      {minus_plus,  plus_plus} ->
	MinWidth = inf_max([Width2,width({Min1,-1})]),
	MaxWidth = inf_max([Width2,width({0,Max1})]),
	{inf_bsl(-1, MinWidth), inf_add(-1, inf_bsl(1, MaxWidth))};
      {plus_plus,   minus_minus} ->
	Width = inf_max([Width1, Width2]),
	{inf_bsl(-1, Width), -1};
      {plus_plus,   minus_plus} ->
	MinWidth = inf_max([Width1,width({Min2,-1})]),
	MaxWidth = inf_max([Width1,width({0,Max2})]),
	{inf_bsl(-1, MinWidth), inf_add(-1, inf_bsl(1, MaxWidth))};
      {plus_plus,   plus_plus} ->
	Width = inf_max([Width1, Width2]),
	{0, inf_add(-1, inf_bsl(1, Width))}
    end,
  range_init(Range, false).  

%%---------------------------------------------------------------------------
%% Inf operations
%%---------------------------------------------------------------------------

-spec inf_max([inf_integer(),...]) -> inf_integer().

inf_max([H|T]) ->
  lists:foldl(fun (Elem, Max) ->
		  case inf_geq(Elem, Max) of
		    false -> Max;
		    true  -> Elem
		  end
	      end, H, T).

-spec inf_min([inf_integer(),...]) -> inf_integer().

inf_min([H|T]) ->
  lists:foldl(fun (Elem, Min) ->
		  case inf_geq(Elem, Min) of
		    true  -> Min;
		    false -> Elem
		  end
	      end, H, T).

-spec inf_abs(inf_integer()) -> 'pos_inf' | integer().

inf_abs(pos_inf) -> pos_inf;
inf_abs(neg_inf) -> pos_inf;
inf_abs(Number) when is_integer(Number), (Number < 0) -> - Number;
inf_abs(Number) when is_integer(Number) -> Number.

-spec inf_add(inf_integer(), inf_integer()) -> inf_integer().

inf_add(pos_inf, _Number) -> pos_inf;
inf_add(neg_inf, _Number) -> neg_inf;
inf_add(_Number, pos_inf) -> pos_inf;
inf_add(_Number, neg_inf) -> neg_inf;
inf_add(Number1, Number2) when is_integer(Number1), is_integer(Number2) ->
  Number1 + Number2.

-spec inf_inv(inf_integer()) -> inf_integer().

inf_inv(pos_inf) -> neg_inf;
inf_inv(neg_inf) -> pos_inf;
inf_inv(Number) -> -Number.

-spec inf_geq(inf_integer(), inf_integer()) -> boolean().

inf_geq(pos_inf, _) -> true;
inf_geq(_, pos_inf) -> false;
inf_geq(_, neg_inf) -> true;
inf_geq(neg_inf, _) -> false;
inf_geq(A, B) -> A >= B.

-spec inf_greater_zero(inf_integer()) -> boolean().

inf_greater_zero(pos_inf) -> true;
inf_greater_zero(neg_inf) -> false;
inf_greater_zero(Number) when is_integer(Number), Number >= 0 -> true;
inf_greater_zero(Number) when is_integer(Number), Number < 0 -> false.

-spec inf_div(inf_integer(), inf_integer()) -> inf_integer().

inf_div(Number, 0) ->
  Greater = inf_greater_zero(Number),
  if Greater -> pos_inf;
     true -> neg_inf
  end;
inf_div(pos_inf, Number) ->
  Greater = inf_greater_zero(Number),
  if Greater -> pos_inf;
     true -> neg_inf
  end;
inf_div(neg_inf, Number) ->
  Greater = inf_greater_zero(Number),
  if Greater -> neg_inf;
     true -> pos_inf
  end;
inf_div(Number, pos_inf) -> 
  Greater = inf_greater_zero(Number),
  if Greater -> pos_inf;
     true -> neg_inf
  end;
inf_div(Number, neg_inf) ->
  Greater = inf_greater_zero(Number),
  if Greater -> neg_inf;
     true -> pos_inf
  end;
inf_div(Number1, Number2) -> Number1 div Number2.

-spec inf_mult(inf_integer(), inf_integer()) -> inf_integer().

inf_mult(neg_inf, Number) -> 
  Greater = inf_greater_zero(Number), 
  if Greater -> neg_inf;
     true -> pos_inf
  end;
inf_mult(pos_inf, Number) -> 
  Greater = inf_greater_zero(Number),
  if Greater -> pos_inf;
     true -> neg_inf
  end;
inf_mult(Number, pos_inf) -> inf_mult(pos_inf, Number);
inf_mult(Number, neg_inf) -> inf_mult(neg_inf, Number);
inf_mult(Number1, Number2) -> Number1 * Number2.

-spec inf_bsl(inf_integer(), inf_integer()) -> inf_integer().

inf_bsl(pos_inf, _) -> pos_inf;
inf_bsl(neg_inf, _) -> neg_inf;
inf_bsl(Number, pos_inf) when is_integer(Number), Number >= 0 -> pos_inf;
inf_bsl(_, pos_inf) -> neg_inf;
inf_bsl(Number, neg_inf) when is_integer(Number), Number >= 0 -> 0;
inf_bsl(_Number, neg_inf) -> -1;
inf_bsl(Number1, Number2) when is_integer(Number1), is_integer(Number2) ->
  %% We can not shift left with a number which is not a fixnum. We
  %% don't have enough memory.
  Bits = ?BITS,
  if Number2 > (Bits bsl 1) -> inf_bsl(Number1, pos_inf);
     Number2 < (-Bits bsl 1) ->	inf_bsl(Number1, neg_inf);
     true -> Number1 bsl Number2
  end.

%% State

-spec state__init(cfg(), data()) -> state().

state__init(Cfg, {MFA, ArgsFun, CallFun, FinalFun}) ->
  Start = hipe_icode_cfg:start_label(Cfg),  
  Params = hipe_icode_cfg:params(Cfg),
  Ranges = ArgsFun(MFA, Cfg),
  %% io:format("MFA: ~w~nRanges: ~w~n", [MFA, Ranges]),
  Liveness =
    hipe_icode_ssa:ssa_liveness__analyze(hipe_icode_type:unannotate_cfg(Cfg)),
  case lists:any(fun range__is_none/1, Ranges) of
    true -> 
      FinalFun(MFA, [none_type()]),
      throw(no_input);
    false ->
      NewParams = lists:zipwith(fun update_info/2, Params, Ranges),
      NewCfg = hipe_icode_cfg:params_update(Cfg, NewParams),
      Info = enter_defines(NewParams, gb_trees:empty()),
      InfoMap = gb_trees:insert({Start, in}, Info, gb_trees:empty()),
      #state{info_map=InfoMap, cfg=NewCfg, liveness=Liveness,
	     ret_type=none_type(),
	     lookup_fun=CallFun, result_action=FinalFun}
  end.

-spec state__cfg(state()) -> cfg().

state__cfg(#state{cfg=Cfg}) ->
  Cfg.

-spec state__bb(state(), label()) -> bb().

state__bb(#state{cfg=Cfg}, Label) ->
  BB = hipe_icode_cfg:bb(Cfg, Label),
  true = hipe_bb:is_bb(BB), % Just an assert
  BB.
  
-spec state__bb_add(state(), label(), bb()) -> state().

state__bb_add(S=#state{cfg=Cfg}, Label, BB) ->
  NewCfg = hipe_icode_cfg:bb_add(Cfg, Label, BB),
  S#state{cfg=NewCfg}.

state__lookup_fun(#state{lookup_fun=LF}) -> LF.

state__result_action(#state{result_action=RA}) -> RA.

state__ret_type(#state{ret_type=RT}) -> RT.

state__ret_type_update(#state{ret_type=RT} = State, NewType) ->
  TotType = sup(RT, NewType),
  State#state{ret_type=TotType}.

state__info_in(S, Label) ->
  state__info(S, {Label, in}).

state__info(#state{info_map=IM}, Key) ->
  gb_trees:get(Key, IM).

state__update_info(State, LabelInfo, Rewrite) ->
  update_info(LabelInfo, State, [], Rewrite).

update_info([{Label,InfoIn}|Rest], State, LabelAcc, Rewrite) ->
  case state__info_in_update(State, Label, InfoIn) of
    fixpoint ->
      if Rewrite ->
	  update_info(Rest, State, [Label|LabelAcc], Rewrite);
	 true ->
	  update_info(Rest, State, LabelAcc, Rewrite)
      end;
    NewState ->
      update_info(Rest, NewState, [Label|LabelAcc], Rewrite)
  end;
update_info([], State, LabelAcc, _Rewrite) ->
  {State, LabelAcc}.

state__info_in_update(S=#state{info_map=IM,liveness=Liveness}, Label, Info) ->
  LabelIn = {Label, in},
  case gb_trees:lookup(LabelIn, IM) of
    none -> 
      LiveIn = hipe_icode_ssa:ssa_liveness__livein(Liveness, Label),
      NamesLiveIn = [hipe_icode:var_name(Var) || Var <- LiveIn,
						 hipe_icode:is_var(Var)],
      OldInfo = gb_trees:empty(),
      case join_info_in(NamesLiveIn, OldInfo, Info) of
	fixpoint -> 
	  S#state{info_map=gb_trees:insert(LabelIn, OldInfo, IM)};
	NewInfo ->
	  S#state{info_map=gb_trees:enter(LabelIn, NewInfo, IM)}
      end;
    {value, OldInfo} ->
      OldVars = gb_trees:keys(OldInfo),
      case join_info_in(OldVars, OldInfo, Info) of
	fixpoint -> 
	  fixpoint;
	NewInfo ->
	  S#state{info_map=gb_trees:update(LabelIn, NewInfo, IM)}
      end
  end.

join_info_in(Vars, OldInfo, NewInfo) ->
  case join_info_in(Vars, OldInfo, NewInfo, gb_trees:empty(), false) of
    {Res, true} -> Res;
    {_, false} -> fixpoint
  end.
  
join_info_in([Var|Left], Info1, Info2, Acc, Changed) ->
  Type1 = gb_trees:lookup(Var, Info1),
  Type2 = gb_trees:lookup(Var, Info2),
  case {Type1, Type2} of
    {none, none} ->
      NewTree = gb_trees:insert(Var, none_type(), Acc),
      join_info_in(Left, Info1, Info2, NewTree, true);
    {none, {value, Val}} ->
      NewTree = gb_trees:insert(Var, Val, Acc),
      join_info_in(Left, Info1, Info2, NewTree, true);
    {{value, Val}, none} ->
      NewTree = gb_trees:insert(Var, Val, Acc),
      join_info_in(Left, Info1, Info2, NewTree, Changed);
    {{value, Val}, {value, Val}} ->
      NewTree = gb_trees:insert(Var, Val, Acc),
      join_info_in(Left, Info1, Info2, NewTree, Changed);
    {{value, Val1}, {value, Val2}} ->
      {NewChanged, NewVal} = 
	case sup(Val1, Val2) of
	  Val1 ->
	    {Changed, Val1};
	  Val ->
	    {true, Val}
	end,
      NewTree = gb_trees:insert(Var, NewVal, Acc),
      join_info_in(Left, Info1, Info2, NewTree, NewChanged)
  end;
join_info_in([], _Info1, _Info2, Acc, NewChanged) ->
  {Acc, NewChanged}.

enter_defines([Def|Rest], Info) ->
  enter_defines(Rest, enter_define(Def, Info));
enter_defines([], Info) -> Info.

enter_define({PossibleVar, Range = #range{}}, Info) ->
  case hipe_icode:is_var(PossibleVar) of
    true -> 
      gb_trees:enter(hipe_icode:var_name(PossibleVar), Range, Info);
    false ->
      Info
  end;
enter_define(PossibleVar, Info) ->
  case hipe_icode:is_var(PossibleVar) of
    true -> 
      case hipe_icode:variable_annotation(PossibleVar) of
	{range_anno, #ann{range=Range}, _} ->
	   gb_trees:enter(hipe_icode:var_name(PossibleVar), Range, Info);
	_ ->
	  Info
      end;
    false ->
      Info
  end.

enter_vals(Ins, Info) ->
  NewInfo = enter_defines(hipe_icode:args(Ins), Info),
  enter_defines(hipe_icode:defines(Ins), NewInfo).

lookup(PossibleVar, Info) ->
  case hipe_icode:is_var(PossibleVar) of
    true -> 
      case gb_trees:lookup(hipe_icode:var_name(PossibleVar), Info) of
	none ->
	  none_type();
	{value, Val} ->
	  Val
      end;
    false ->
      none_type()
  end.

%% _________________________________________________________________
%%
%% The worklist.
%%

init_work(State) ->
  %% Labels = hipe_icode_cfg:reverse_postorder(state__cfg(State)),
  Labels = [hipe_icode_cfg:start_label(state__cfg(State))],
  {Labels, [], sets:from_list(Labels)}.

get_work({[Label|Left], List, Set}) ->
  NewWork = {Left, List, sets:del_element(Label, Set)},
  {Label, NewWork};
get_work({[], [], _Set}) ->
  fixpoint;
get_work({[], List, Set}) ->
  get_work({lists:reverse(List), [], Set}).

add_work(Work = {List1, List2, Set}, [Label|Left]) ->
  case sets:is_element(Label, Set) of
    true ->
      add_work(Work, Left);
    false ->
      %% io:format("Adding work: ~w\n", [Label]),
      add_work({List1, [Label|List2], sets:add_element(Label, Set)}, Left)
  end;
add_work(Work, []) ->
  Work.

convert_cfg_to_types(Cfg) ->
  Lbls = hipe_icode_cfg:reverse_postorder(Cfg),
  lists:foldl(fun convert_lbl_to_type/2, Cfg, Lbls).

convert_lbl_to_type(Lbl, Cfg) ->
  BB = hipe_icode_cfg:bb(Cfg, Lbl),
  Code = hipe_bb:code(BB),
  NewCode = [convert_instr_to_type(I) || I <- Code],
  hipe_icode_cfg:bb_add(Cfg, Lbl, hipe_bb:mk_bb(NewCode)).

convert_instr_to_type(I) ->
  Uses = hipe_icode:uses(I),
  UseSubstList = [{Use, convert_to_types(Use)} ||
		   Use <- Uses, hipe_icode:is_annotated_variable(Use)],
  NewI = hipe_icode:subst_uses(UseSubstList, I),
  Defs = hipe_icode:defines(NewI),
  DefSubstList = [{Def, convert_to_types(Def)} ||
		   Def <- Defs, hipe_icode:is_annotated_variable(Def)],
  hipe_icode:subst_defines(DefSubstList, NewI).

convert_to_types(VarOrReg) ->
 Annotation = 
    case hipe_icode:variable_annotation(VarOrReg) of
      {range_anno, Ann, _} ->
	{type_anno, convert_ann_to_types(Ann), fun erl_types:t_to_string/1};
      {type_anno, _, _} = TypeAnn ->
	TypeAnn
    end,
  hipe_icode:annotate_variable(VarOrReg, Annotation).

convert_ann_to_types(#ann{range=#range{range={Min,Max}, other=false}}) ->
  t_from_range_unsafe(Min, Max);
convert_ann_to_types(#ann{range=#range{range=empty, other=false}}) ->
  t_none();
convert_ann_to_types(#ann{range=#range{other=true}, type=Type}) ->
  Type.

%%=====================================================================
%% Icode Coordinator Callbacks
%%=====================================================================

-spec replace_nones([range()]) -> [range()].
replace_nones(Args) ->
  [replace_none(Arg) || Arg <- Args].

replace_none(Arg) ->
  case range__is_none(Arg) of
    true -> any_type();
    false -> Arg
  end.

-spec update__info([range()], [range()]) -> {boolean(), [ann()]}.
update__info(NewRanges, OldRanges) ->
  SupFun = fun (Ann, Range) -> 
	       join_info(Ann, Range, fun safe_widen/3)
	   end,
  EqFun = fun (X, Y) -> X =:= Y end,
  ResRanges = lists:zipwith(SupFun, OldRanges, NewRanges),
  Change = lists:zipwith(EqFun, ResRanges, OldRanges),
  {lists:all(fun (X) -> X end, Change), ResRanges}.

-spec new__info([range()]) -> [ann()].
new__info(NewRanges) ->
  [#ann{range=Range,count=1,type=t_any()} || Range <- NewRanges].

-spec return__info([ann()]) -> [range()].
return__info(Ranges) ->
  [Range || #ann{range=Range} <- Ranges].

-spec return_none() -> [range(),...].
return_none() ->
  [none_type()].

-spec return_none_args(cfg(), mfa()) -> [range()].
return_none_args(Cfg, {_M,_F,A}) ->
  NoArgs =
    case hipe_icode_cfg:is_closure(Cfg) of
      true -> hipe_icode_cfg:closure_arity(Cfg) + 1;
      false -> A
    end,
  lists:duplicate(NoArgs, none_type()).

-spec return_any_args(cfg(), mfa()) -> [range()].
return_any_args(Cfg, {_M,_F,A}) ->
  NoArgs = 
    case hipe_icode_cfg:is_closure(Cfg) of
      true -> hipe_icode_cfg:closure_arity(Cfg) + 1;
      false -> A
    end,
  lists:duplicate(NoArgs, any_type()).

%%=====================================================================

next_up_limit(X) when is_integer(X), X < 0 -> 0;
next_up_limit(X) when is_integer(X), X < 255 -> 255;
next_up_limit(X) when is_integer(X), X < 16#10ffff -> 16#10ffff;
next_up_limit(X) when is_integer(X), X < 16#7ffffff -> 16#7ffffff;
next_up_limit(X) when is_integer(X), X < 16#7fffffff -> 16#7fffffff;
next_up_limit(X) when is_integer(X), X < 16#ffffffff -> 16#ffffffff;
next_up_limit(X) when is_integer(X), X < 16#fffffffffff -> 16#fffffffffff;
next_up_limit(X) when is_integer(X), X < 16#7fffffffffffffff -> 16#7fffffffffffffff;
next_up_limit(_X) -> pos_inf.

next_down_limit(X) when is_integer(X), X > 0 -> 0;
next_down_limit(X) when is_integer(X), X > -256 -> -256;
next_down_limit(X) when is_integer(X), X > -16#10ffff -> -16#10ffff;
next_down_limit(X) when is_integer(X), X > -16#8000000 -> -16#8000000;
next_down_limit(X) when is_integer(X), X > -16#80000000 -> -16#80000000;
next_down_limit(X) when is_integer(X), X > -16#800000000000000 -> -16#800000000000000;
next_down_limit(_X) -> neg_inf.