%-----------------------------------------------------------------------------% % vim: ft=mercury ts=4 sw=4 et %-----------------------------------------------------------------------------% % Copyright (C) 1997-2007 The University of Melbourne. % This file may only be copied under the terms of the GNU General % Public License - see the file COPYING in the Mercury distribution. %-----------------------------------------------------------------------------% % % File: term_util.m. % Main author: crs. % % This module: % % - defines the types used by termination analysis % - defines some utility predicates % %-----------------------------------------------------------------------------% :- module transform_hlds.term_util. :- interface. :- import_module hlds.hlds_goal. :- import_module hlds.hlds_module. :- import_module hlds.hlds_pred. :- import_module parse_tree.prog_data. :- import_module transform_hlds.term_errors. :- import_module transform_hlds.term_norm. :- import_module bag. :- import_module bool. :- import_module list. :- import_module map. :- import_module maybe. :- import_module unit. %-----------------------------------------------------------------------------% % % The `arg_size_info' and `termination_info' structures % % The types `arg_size_info' and `termination_info' hold information about % procedures which is used for termination analysis. These types are stored % as fields in the HLDS proc_info. For intermodule analysis, the information % is written out as `pragma termination_info(...)' declarations in the `.opt' % and `.trans_opt' files. The module prog_data.m defines types similar to % these two (but without the `list(termination_error_context)') which are used % when parsing `termination_info' pragmas. % The arg size info defines an upper bound on the difference between the % sizes of the output arguments of a procedure and the sizes of the input % arguments: % % | input arguments | + constant >= | output arguments | % % where | | represents a semilinear norm. % :- type arg_size_info == generic_arg_size_info(termination_error_contexts). :- type termination_info == generic_termination_info(unit, termination_error_contexts). % The type `used_args' holds a mapping which specifies for each procedure % which of its arguments are used. % :- type used_args == map(pred_proc_id, list(bool)). :- type pass_info ---> pass_info( functor_info, int, % Max number of errors to gather. int % Max number of paths to analyze. ). %-----------------------------------------------------------------------------% % This predicate partitions the arguments of a call into a list of input % variables and a list of output variables. % :- pred partition_call_args(module_info::in, list(mer_mode)::in, list(prog_var)::in, bag(prog_var)::out, bag(prog_var)::out) is det. % Given a list of variables from a unification, this predicate divides the % list into a bag of input variables, and a bag of output variables. % :- pred split_unification_vars(list(prog_var)::in, list(uni_mode)::in, module_info::in, bag(prog_var)::out, bag(prog_var)::out) is det. % Used to create lists of boolean values, which are used for used_args. % make_bool_list(HeadVars, BoolIn, BoolOut) creates a bool list which is % (length(HeadVars) - length(BoolIn)) `no' followed by BoolIn. This is % used to set the used args for compiler generated predicates. The no's % at the start are because the Type infos are not used. length(BoolIn) % should equal the arity of the predicate, and the difference in length % between the arity of the procedure and the arity of the predicate is % the number of typeinfos. % :- pred make_bool_list(list(_T)::in, list(bool)::in, list(bool)::out) is det. % Removes variables from the InVarBag that are not used in the call. % remove_unused_args(InVarBag0, VarList, BoolList, InVarBag) VarList and % BoolList are corresponding lists. Any variable in VarList that has a % `no' in the corresponding place in the BoolList is removed from % InVarBag. % :- pred remove_unused_args(bag(prog_var)::in, list(prog_var)::in, list(bool)::in, bag(prog_var)::out) is det. % This predicate sets the argument size info of a given a list of % procedures. % :- pred set_pred_proc_ids_arg_size_info(list(pred_proc_id)::in, arg_size_info::in, module_info::in, module_info::out) is det. % This predicate sets the termination info of a given a list of % procedures. % :- pred set_pred_proc_ids_termination_info(list(pred_proc_id)::in, termination_info::in, module_info::in, module_info::out) is det. :- pred lookup_proc_termination_info(module_info::in, pred_proc_id::in, maybe(termination_info)::out) is det. :- pred lookup_proc_arg_size_info(module_info::in, pred_proc_id::in, maybe(arg_size_info)::out) is det. % Succeeds if one or more variables in the list are higher order. % :- pred horder_vars(list(prog_var)::in, vartypes::in) is semidet. :- pred get_context_from_scc(list(pred_proc_id)::in, module_info::in, prog_context::out) is det. % Succeeds if the termination status of a procedure is known. % :- pred is_termination_known(module_info::in, pred_proc_id::in) is semidet. % Succeeds if the foreign proc attributes imply that a procedure is % terminating. % :- pred attributes_imply_termination(pragma_foreign_proc_attributes::in) is semidet. % pred_proc_id_terminates(ModuleInfo, PPId): % % Succeeds iff the procedure given by 'PPId' has been proven to terminate. % :- pred pred_proc_id_terminates(module_info::in, pred_proc_id::in) is semidet. % Succeed if all arguments of the given procedure of the given predicate % are either input or zero size. % :- pred all_args_input_or_zero_size(module_info::in, pred_info::in, proc_info::in) is semidet. %-----------------------------------------------------------------------------% % Convert a pragma_termination_info into a termination_info, by adding the % appropriate context. % :- pred add_context_to_termination_info(maybe(pragma_termination_info)::in, prog_context::in, maybe(termination_info)::out) is det. % Convert a pragma_arg_size_info into a arg_size_info, by adding the % appropriate context. % :- pred add_context_to_arg_size_info(maybe(pragma_arg_size_info)::in, prog_context::in, maybe(arg_size_info)::out) is det. %-----------------------------------------------------------------------------% %-----------------------------------------------------------------------------% :- implementation. :- import_module check_hlds.inst_match. :- import_module check_hlds.mode_util. :- import_module libs.compiler_util. :- import_module parse_tree.prog_type. :- import_module pair. %-----------------------------------------------------------------------------% %-----------------------------------------------------------------------------% partition_call_args(ModuleInfo, ArgModes, Args, InVarsBag, OutVarsBag) :- partition_call_args_2(ModuleInfo, ArgModes, Args, InVars, OutVars), bag.from_list(InVars, InVarsBag), bag.from_list(OutVars, OutVarsBag). :- pred partition_call_args_2(module_info::in, list(mer_mode)::in, list(prog_var)::in, list(prog_var)::out, list(prog_var)::out) is det. partition_call_args_2(_, [], [], [], []). partition_call_args_2(_, [], [_ | _], _, _) :- unexpected(this_file, "partition_call_args_2/5: unmatched variables."). partition_call_args_2(_, [_ | _], [], _, _) :- unexpected(this_file, "partition_call_args_2/5: unmatched variables."). partition_call_args_2(ModuleInfo, [ArgMode | ArgModes], [Arg | Args], InputArgs, OutputArgs) :- partition_call_args_2(ModuleInfo, ArgModes, Args, InputArgs1, OutputArgs1), ( mode_is_input(ModuleInfo, ArgMode) -> InputArgs = [Arg | InputArgs1], OutputArgs = OutputArgs1 ; mode_is_output(ModuleInfo, ArgMode) -> InputArgs = InputArgs1, OutputArgs = [Arg | OutputArgs1] ; InputArgs = InputArgs1, OutputArgs = OutputArgs1 ). % For these next two predicates (split_unification_vars and % partition_call_args) there is a problem of what needs to be done for % partially instantiated data structures. The correct answer is that the % system shoud use a norm such that the size of the uninstantiated parts % of a partially instantiated structure have no effect on the size of the % data structure according to the norm. For example when finding the size % of a list-skeleton, list-length norm should be used. Therefore, the % size of any term must be given by: % % sizeof(term) = constant + sum of the size of each % (possibly partly) instantiated subterm. % % It is probably easiest to implement this by modifying term_weights. The % current implementation does not correctly handle partially instantiated % data structures. % split_unification_vars([], Modes, _, Vars, Vars) :- bag.init(Vars), ( Modes = [] ; Modes = [_|_], unexpected(this_file, "split_unification_vars/5: unmatched variables.") ). split_unification_vars([Arg | Args], Modes, ModuleInfo, InVars, OutVars):- ( Modes = [UniMode | UniModes] -> split_unification_vars(Args, UniModes, ModuleInfo, InVars0, OutVars0), UniMode = ((_VarInit - ArgInit) -> (_VarFinal - ArgFinal)), ( inst_is_bound(ModuleInfo, ArgInit) -> % Variable is an input variable bag.insert(InVars0, Arg, InVars), OutVars = OutVars0 ; inst_is_free(ModuleInfo, ArgInit), inst_is_bound(ModuleInfo, ArgFinal) -> % Variable is an output variable InVars = InVars0, bag.insert(OutVars0, Arg, OutVars) ; InVars = InVars0, OutVars = OutVars0 ) ; unexpected(this_file, "split_unification_vars/5: unmatched variables.") ). %-----------------------------------------------------------------------------% make_bool_list(HeadVars0, Bools, Out) :- list.length(Bools, Arity), ( list.drop(Arity, HeadVars0, HeadVars1) -> HeadVars = HeadVars1 ; unexpected(this_file, "make_bool_list/3: unmatched variables.") ), make_bool_list_2(HeadVars, Bools, Out). :- pred make_bool_list_2(list(_T)::in, list(bool)::in, list(bool)::out) is det. make_bool_list_2([], Bools, Bools). make_bool_list_2([ _ | Vars ], Bools, [no | Out]) :- make_bool_list_2(Vars, Bools, Out). remove_unused_args(Vars, [], [], Vars). remove_unused_args(Vars, [], [_X | _Xs], Vars) :- unexpected(this_file, "remove_unused_args/4: unmatched variables."). remove_unused_args(Vars, [_X | _Xs], [], Vars) :- unexpected(this_file, "remove_unused_args/4: unmatched variables."). remove_unused_args(Vars0, [ Arg | Args ], [ UsedVar | UsedVars ], Vars) :- ( % The variable is used, so leave it UsedVar = yes, remove_unused_args(Vars0, Args, UsedVars, Vars) ; % The variable is not used in producing output vars, so don't include % it as an input variable. UsedVar = no, bag.delete(Vars0, Arg, Vars1), remove_unused_args(Vars1, Args, UsedVars, Vars) ). %-----------------------------------------------------------------------------% set_pred_proc_ids_arg_size_info([], _ArgSize, !ModuleInfo). set_pred_proc_ids_arg_size_info([PPId | PPIds], ArgSize, !ModuleInfo) :- PPId = proc(PredId, ProcId), module_info_preds(!.ModuleInfo, PredTable0), map.lookup(PredTable0, PredId, PredInfo0), pred_info_get_procedures(PredInfo0, ProcTable0), map.lookup(ProcTable0, ProcId, ProcInfo0), proc_info_set_maybe_arg_size_info(yes(ArgSize), ProcInfo0, ProcInfo), map.det_update(ProcTable0, ProcId, ProcInfo, ProcTable), pred_info_set_procedures(ProcTable, PredInfo0, PredInfo), map.det_update(PredTable0, PredId, PredInfo, PredTable), module_info_set_preds(PredTable, !ModuleInfo), set_pred_proc_ids_arg_size_info(PPIds, ArgSize, !ModuleInfo). set_pred_proc_ids_termination_info([], _Termination, !ModuleInfo). set_pred_proc_ids_termination_info([PPId | PPIds], Termination, !ModuleInfo) :- PPId = proc(PredId, ProcId), module_info_preds(!.ModuleInfo, PredTable0), map.lookup(PredTable0, PredId, PredInfo0), pred_info_get_procedures(PredInfo0, ProcTable0), map.lookup(ProcTable0, ProcId, ProcInfo0), proc_info_set_maybe_termination_info(yes(Termination), ProcInfo0, ProcInfo), map.det_update(ProcTable0, ProcId, ProcInfo, ProcTable), pred_info_set_procedures(ProcTable, PredInfo0, PredInfo), map.det_update(PredTable0, PredId, PredInfo, PredTable), module_info_set_preds(PredTable, !ModuleInfo), set_pred_proc_ids_termination_info(PPIds, Termination, !ModuleInfo). lookup_proc_termination_info(ModuleInfo, PPId, MaybeTermination) :- module_info_pred_proc_info(ModuleInfo, PPId, _, ProcInfo), proc_info_get_maybe_termination_info(ProcInfo, MaybeTermination). lookup_proc_arg_size_info(ModuleInfo, PPId, MaybeArgSize) :- module_info_pred_proc_info(ModuleInfo, PPId, _, ProcInfo), proc_info_get_maybe_arg_size_info(ProcInfo, MaybeArgSize). horder_vars([Arg | Args], VarType) :- ( map.lookup(VarType, Arg, Type), type_is_higher_order(Type) ; horder_vars(Args, VarType) ). %-----------------------------------------------------------------------------% get_context_from_scc(SCC, ModuleInfo, Context) :- ( SCC = [proc(PredId, _) | _], module_info_pred_info(ModuleInfo, PredId, PredInfo), pred_info_get_context(PredInfo, Context) ; SCC = [], unexpected(this_file, "get_context_from_scc/3: empty SCC.") ). %-----------------------------------------------------------------------------% add_context_to_termination_info(no, _, no). add_context_to_termination_info(yes(cannot_loop(_)), _, yes(cannot_loop(unit))). add_context_to_termination_info(yes(can_loop(_)), Context, yes(can_loop([Context - imported_pred]))). add_context_to_arg_size_info(no, _, no). add_context_to_arg_size_info(yes(finite(A, B)), _, yes(finite(A, B))). add_context_to_arg_size_info(yes(infinite(_)), Context, yes(infinite([Context - imported_pred]))). %-----------------------------------------------------------------------------% is_termination_known(ModuleInfo, PPId) :- module_info_pred_proc_info(ModuleInfo, PPId, _, ProcInfo), proc_info_get_maybe_termination_info(ProcInfo, yes(_)). attributes_imply_termination(Attributes) :- ( get_terminates(Attributes) = proc_terminates ; get_terminates(Attributes) = depends_on_mercury_calls, get_may_call_mercury(Attributes) = proc_will_not_call_mercury ). %-----------------------------------------------------------------------------% pred_proc_id_terminates(ModuleInfo, PPId) :- module_info_pred_proc_info(ModuleInfo, PPId, _, ProcInfo), proc_info_get_maybe_termination_info(ProcInfo, TerminationInfo), TerminationInfo = yes(cannot_loop(_)). %-----------------------------------------------------------------------------% all_args_input_or_zero_size(ModuleInfo, PredInfo, ProcInfo) :- pred_info_get_arg_types(PredInfo, TypeList), proc_info_get_argmodes(ProcInfo, ModeList), all_args_input_or_zero_size_2(TypeList, ModeList, ModuleInfo). :- pred all_args_input_or_zero_size_2(list(mer_type)::in, list(mer_mode)::in, module_info::in) is semidet. all_args_input_or_zero_size_2([], [], _). all_args_input_or_zero_size_2([], [_|_], _) :- unexpected(this_file, "all_args_input_or_size_2/3 - unmatched lists."). all_args_input_or_zero_size_2([_|_], [], _) :- unexpected(this_file, "all_args_input_or_size_2/3 - unmatched lists."). all_args_input_or_zero_size_2([Type | Types], [Mode | Modes], ModuleInfo) :- ( mode_is_input(ModuleInfo, Mode) -> % The variable is an input variables, so its size is irrelevant. all_args_input_or_zero_size_2(Types, Modes, ModuleInfo) ; term_norm.zero_size_type(ModuleInfo, Type), all_args_input_or_zero_size_2(Types, Modes, ModuleInfo) ). %-----------------------------------------------------------------------------% :- func this_file = string. this_file = "term_util.m". %-----------------------------------------------------------------------------% :- end_module term_util. %-----------------------------------------------------------------------------%