implementation module type import StdEnv,StdOverloadedList,compare_types import syntax, typesupport, check, analtypes, overloading, unitype, refmark, predef, utilities, compare_constructor import genericsupport :: TypeInput = ! { ti_common_defs :: !{# CommonDefs } , ti_functions :: !{# {# FunType }} , ti_main_dcl_module_n :: !Int , ti_expand_newtypes :: !Bool } :: TypeState = { ts_fun_env :: !.{! FunctionType} , ts_var_store :: !TempVarId , ts_attr_store :: !TempAttrId , ts_var_heap :: !.VarHeap , ts_type_heaps :: !.TypeHeaps , ts_expr_heap :: !.ExpressionHeap , ts_generic_heap :: !.GenericHeap , ts_td_infos :: !.TypeDefInfos , ts_cons_variables :: ![TempVarId] , ts_exis_variables :: ![(CoercionPosition, [TempAttrId])] , ts_error :: !.ErrorAdmin , ts_fun_defs :: !.{#FunDef} } :: TypeCoercion = { tc_demanded :: !AType , tc_offered :: !AType , tc_position :: !CoercionPosition , tc_coercible :: !Bool } :: SharedAttribute = { sa_attr_nr :: !Int , sa_position :: !Expression } :: Requirements = { req_overloaded_calls :: ![ExprInfoPtr] , req_type_coercions :: ![TypeCoercion] , req_type_coercion_groups:: ![TypeCoercionGroup] , req_attr_coercions :: ![AttrCoercion] , req_case_and_let_exprs :: ![ExprInfoPtr] } :: TypeCoercionGroup = { tcg_type_coercions :: ![TypeCoercion] , tcg_position :: !Position } instance toString BoundVar where toString varid = varid.var_ident.id_name class arraySubst type :: !type !u:{!Type} -> (!Bool,!type, !u:{! Type}) instance arraySubst AType where arraySubst atype=:{at_type} subst # (changed, at_type, subst) = arraySubst at_type subst | changed = (True, { atype & at_type = at_type }, subst) = (False, atype, subst) instance arraySubst Type where arraySubst tv=:(TempV tv_number) subst # (type, subst) = subst![tv_number] = case type of TE -> (False,tv, subst) _ # (_, type, subst) = arraySubst type subst -> (True, type, subst) arraySubst type=:(arg_type --> res_type) subst # (changed, (arg_type, res_type), subst) = arraySubst (arg_type, res_type) subst | changed = (changed, arg_type --> res_type, subst) = (False, type, subst) arraySubst type=:(TA cons_id cons_args) subst # (changed, cons_args, subst) = arraySubst cons_args subst | changed = (True, TA cons_id cons_args, subst) = (False,type, subst) arraySubst type=:(TAS cons_id cons_args strictness) subst # (changed, cons_args, subst) = arraySubst cons_args subst | changed = (True, TAS cons_id cons_args strictness, subst) = (False,type, subst) arraySubst tcv=:(TempCV tv_number :@: types) subst # (type, subst) = subst![tv_number] = case type of TE # (changed,types, subst) = arraySubst types subst | changed -> (True, TempCV tv_number :@: types, subst) -> (False, tcv, subst) _ # (_, (type, types), subst) = arraySubst (type, types) subst (ok, simplified_type) = simplifyTypeApplication type types | ok -> (True, simplified_type, subst) -> (False, tcv, subst) arraySubst tcv=:((cv=:CV _) :@: types) subst // should occur only for A. type variables # (changed,types, subst) = arraySubst types subst | changed = (True, cv :@: types, subst) = (False, tcv, subst) arraySubst type=:(TArrow1 arg_type) subst # (changed, arg_type, subst) = arraySubst arg_type subst | changed = (changed, TArrow1 arg_type, subst) = (False, type, subst) arraySubst tfa_type=:(TFA vars type) subst # (changed, type, subst) = arraySubst type subst | changed = (changed, TFA vars type, subst) = (False, tfa_type, subst) arraySubst tfac_type=:(TFAC vars type contexts) subst # (changed, new_type, subst) = arraySubst type subst | changed # (changed,new_contexts,subst) = arraySubst contexts subst | changed = (True, TFAC vars new_type new_contexts, subst) = (True, TFAC vars new_type contexts, subst) # (changed,new_contexts,subst) = arraySubst contexts subst | changed = (True, TFAC vars type new_contexts, subst) = (False, tfac_type, subst) arraySubst type subst = (False, type, subst) instance arraySubst (a,b) | arraySubst a & arraySubst b where arraySubst (x,y) subst # (changed_x, x, subst) = arraySubst x subst (changed_y, y, subst) = arraySubst y subst = (changed_x || changed_y, (x,y), subst) instance arraySubst [a] | arraySubst a where arraySubst [] subst = (False, [], subst) arraySubst t=:[type : types ] subst # (changed, (type, types), subst) = arraySubst (type, types) subst | changed = (True, [type : types ], subst) = (False, t, subst) instance arraySubst TempSymbolType where arraySubst tst=:{tst_args,tst_result,tst_context} subst # (changed, (tst_args, (tst_result, tst_context)), subst) = arraySubst (tst_args, (tst_result, tst_context)) subst | changed = (True, {tst & tst_args = tst_args, tst_result = tst_result, tst_context = tst_context}, subst) = (False, tst, subst) instance arraySubst TypeContext where arraySubst tc=:{tc_types} subst # (changed, tc_types, subst) = arraySubst tc_types subst | changed = (True,{ tc & tc_types = tc_types}, subst) = (False, tc, subst) instance arraySubst (VarContexts TypeContext) where arraySubst var_context=:(VarContext arg_n context arg_atype var_contexts) subst # (changed,new_context,subst) = arraySubst context subst | changed # (changed,new_arg_atype,subst) = arraySubst arg_atype subst | changed # (changed,new_var_contexts,subst) = arraySubst var_contexts subst | changed = (True,VarContext arg_n new_context new_arg_atype new_var_contexts,subst) = (True,VarContext arg_n new_context new_arg_atype var_contexts,subst) # (changed,new_var_contexts,subst) = arraySubst var_contexts subst | changed = (True,VarContext arg_n new_context arg_atype new_var_contexts,subst) = (True,VarContext arg_n new_context arg_atype var_contexts,subst) # (changed,new_arg_atype,subst) = arraySubst arg_atype subst | changed # (changed,new_var_contexts,subst) = arraySubst var_contexts subst | changed = (True,VarContext arg_n context new_arg_atype new_var_contexts,subst) = (True,VarContext arg_n context new_arg_atype var_contexts,subst) # (changed,new_var_contexts,subst) = arraySubst var_contexts subst | changed = (True,VarContext arg_n context arg_atype new_var_contexts,subst) = (False,var_context,subst) arraySubst NoVarContexts subst = (False,NoVarContexts,subst) instance arraySubst CaseType where arraySubst ct=:{ct_pattern_type, ct_result_type, ct_cons_types} subst # (changed, (ct_pattern_type, (ct_result_type, ct_cons_types)), subst) = arraySubst (ct_pattern_type, (ct_result_type, ct_cons_types)) subst | changed = (True,{ ct & ct_pattern_type = ct_pattern_type, ct_result_type = ct_result_type, ct_cons_types = ct_cons_types }, subst) = (False, ct, subst) class containsTypeVariable a :: !Int !a !{!Type} -> Bool instance containsTypeVariable [a] | containsTypeVariable a where containsTypeVariable var_id [elem:list] subst = containsTypeVariable var_id elem subst || containsTypeVariable var_id list subst containsTypeVariable var_id [] _ = False instance containsTypeVariable AType where containsTypeVariable var_id {at_type} subst = containsTypeVariable var_id at_type subst instance containsTypeVariable Type where containsTypeVariable var_id (TempV tv_number) subst # type = subst.[tv_number] | isIndirection type = containsTypeVariable var_id type subst = tv_number == var_id containsTypeVariable var_id (arg_type --> res_type) subst = containsTypeVariable var_id arg_type subst || containsTypeVariable var_id res_type subst containsTypeVariable var_id (TA cons_id cons_args) subst = containsTypeVariable var_id cons_args subst containsTypeVariable var_id (TAS cons_id cons_args _) subst = containsTypeVariable var_id cons_args subst containsTypeVariable var_id (type :@: types) subst = containsTypeVariable var_id type subst || containsTypeVariable var_id types subst containsTypeVariable var_id (TArrow1 arg_type) subst = containsTypeVariable var_id arg_type subst containsTypeVariable _ _ _ = False instance containsTypeVariable ConsVariable where containsTypeVariable var_id (TempCV tv_number) subst # type = subst.[tv_number] | isIndirection type = containsTypeVariable var_id type subst = tv_number == var_id containsTypeVariable var_id _ _ = False type_error =: "Type error" type_error_format =: { form_properties = cNoProperties, form_attr_position = No } cannotUnify t1 t2 position=:(CP_Expression expr) common_defs err=:{ea_loc=[ip:_]} = case tryToOptimizePosition expr of Yes (id_name, line) # err = pushErrorAdmin { ip & ip_ident.id_name = id_name, ip_line = line } err err = errorHeading type_error err err = popErrorAdmin err err = { err & ea_file = err.ea_file <<< " cannot unify demanded type with offered type:\n" } err = { err & ea_file = err.ea_file <<< " " <:: (type_error_format, t1, No) <<< '\n' } err = { err & ea_file = err.ea_file <<< " " <:: (type_error_format, t2, No) <<< '\n' } -> err _ -> cannot_unify t1 t2 position common_defs err cannotUnify t1 t2 position common_defs err = cannot_unify t1 t2 position common_defs err cannot_unify t1 t2 position common_defs err # (err=:{ea_file}) = errorHeading type_error err ea_file = case position of CP_FunArg _ _ -> ea_file <<< "\"" <<< position <<< "\"" CP_SymbArgAndExpression {symb_kind=SK_Constructor {glob_module,glob_object},symb_ident} arg_n expression #! type_index = common_defs.[glob_module].com_cons_defs.[glob_object].cons_type_index -> case common_defs.[glob_module].com_type_defs.[type_index].td_rhs of RecordType {rt_fields} # field_name = rt_fields.[arg_n-1].fs_ident.id_name record_name = symb_ident.id_name record_name = if (record_name.[0]=='_') (record_name % (1,size record_name-1)) record_name -> ea_file <<< "\"" <<< "field " <<< field_name <<< " of " <<< record_name <<< " : " <<< CP_Expression expression <<< "\"" _ -> ea_file <<< "\"" <<< position <<< "\"" CP_SymbArgAndExpression _ _ _ -> ea_file <<< "\"" <<< position <<< "\"" CP_LiftedFunArg _ _ -> ea_file <<< "\"" <<< position <<< "\"" CP_Expression _ -> ea_file <<< " near " <<< position <<< " :" _ -> ea_file ea_file = ea_file <<< " cannot unify demanded type with offered type:\n" ea_file = ea_file <<< " " <:: (type_error_format, t1, No) <<< "\n" ea_file = ea_file <<< " " <:: (type_error_format, t2, No) <<< "\n" = { err & ea_file = ea_file} existentialError position=:(CP_Expression expr) err=:{ea_loc=[ip:_]} = case tryToOptimizePosition expr of Yes (id_name, line) # err = pushErrorAdmin { ip & ip_ident.id_name = id_name, ip_line = line } err err = errorHeading type_error err err = popErrorAdmin err -> { err & ea_file = err.ea_file <<< " attribute variable could not be universally quantified"<<< '\n' } _ # err = errorHeading type_error err -> { err & ea_file = err.ea_file <<< " attribute variable could not be universally quantified"<<< '\n' } tryToOptimizePosition (Case {case_ident=Yes {id_name}}) = optBeautifulizeIdent id_name tryToOptimizePosition (App {app_symb={symb_ident}}) = optBeautifulizeIdent symb_ident.id_name tryToOptimizePosition (fun @ _) = tryToOptimizePosition fun tryToOptimizePosition _ = No isIndirection TE = False isIndirection type = True class unify a :: !a !a !TypeInput !*{! Type} !*TypeHeaps -> (!Bool, !*{! Type}, !*TypeHeaps) instance unify (a, b) | unify a & unify b where unify (t1x, t1y) (t2x, t2y) modules subst heaps # (succ, subst, heaps) = unify t1y t2y modules subst heaps | succ = unify t1x t2x modules subst heaps = (False, subst, heaps) instance unify [a] | unify a where unify [t1 : ts1] [t2 : ts2] modules subst heaps = unify (t1,ts1) (t2,ts2) modules subst heaps unify [] [] modules subst heaps = (True, subst, heaps) unify _ _ modules subst heaps = (False, subst, heaps) instance unify AType where unify t1 t2 modules subst heaps = unifyTypes t1.at_type t1.at_attribute t2.at_type t2.at_attribute modules subst heaps unifyTypes :: !Type !TypeAttribute !Type !TypeAttribute !TypeInput !*{! Type} !*TypeHeaps -> (!Bool, !*{! Type}, !*TypeHeaps) unifyTypes tv=:(TempV tv_number) attr1 type2 attr2 modules subst heaps # (type1, subst) = subst![tv_number] | isIndirection type1 = unifyTypes type1 attr1 type2 attr2 modules subst heaps = unify_variable_with_type tv_number type2 attr2 subst modules heaps where unify_variable_with_type :: Int Type TypeAttribute *{!Type} TypeInput *TypeHeaps -> (!Bool,!*{!Type},!*TypeHeaps) unify_variable_with_type tv_number1 tv=:(TempV tv_number2) attr subst modules heaps # (type2, subst) = subst![tv_number2] | isIndirection type2 = unify_variable_with_type tv_number1 type2 attr subst modules heaps | tv_number1 == tv_number2 = (True, subst, heaps) = (True, { subst & [tv_number1] = tv}, heaps) unify_variable_with_type tv_number type attr subst modules heaps | containsTypeVariable tv_number type subst # (succ, type, heaps) = tryToExpandInUnify type attr modules heaps | succ = unify_variable_with_type tv_number type attr subst modules heaps = (False, subst, heaps) = (True, { subst & [tv_number] = type},heaps) unifyTypes type attr1 tv=:(TempV _) attr2 modules subst heaps = unifyTypes tv attr2 type attr1 modules subst heaps unifyTypes t1=:(TB tb1) attr1 t2=:(TB tb2) attr2 modules subst heaps | tb1 == tb2 = (True, subst, heaps) = (False, subst, heaps) unifyTypes t1=:(TA cons_id1 cons_args1) attr1 t2=:(TA cons_id2 cons_args2) attr2 modules subst heaps | cons_id1 == cons_id2 = unify cons_args1 cons_args2 modules subst heaps = expandAndUnifyTypes t1 attr1 t2 attr2 modules subst heaps unifyTypes t1=:(TA cons_id1 cons_args1) attr1 t2=:(TAS cons_id2 cons_args2 _) attr2 modules subst heaps | cons_id1 == cons_id2 = unify cons_args1 cons_args2 modules subst heaps = expandAndUnifyTypes t1 attr1 t2 attr2 modules subst heaps unifyTypes t1=:(TAS cons_id1 cons_args1 _) attr1 t2=:(TA cons_id2 cons_args2) attr2 modules subst heaps | cons_id1 == cons_id2 = unify cons_args1 cons_args2 modules subst heaps = expandAndUnifyTypes t1 attr1 t2 attr2 modules subst heaps unifyTypes t1=:(TAS cons_id1 cons_args1 _) attr1 t2=:(TAS cons_id2 cons_args2 _) attr2 modules subst heaps | cons_id1 == cons_id2 = unify cons_args1 cons_args2 modules subst heaps = expandAndUnifyTypes t1 attr1 t2 attr2 modules subst heaps unifyTypes (arg_type1 --> res_type1) attr1 (arg_type2 --> res_type2) attr2 modules subst heaps = unify (arg_type1,res_type1) (arg_type2,res_type2) modules subst heaps unifyTypes TArrow attr1 TArrow attr2 modules subst heaps = (True, subst, heaps) unifyTypes (TArrow1 t1) attr1 (TArrow1 t2) attr2 modules subst heaps = unify t1 t2 modules subst heaps unifyTypes (cons_var :@: types) attr1 type2 attr2 modules subst heaps # (_, type2, heaps) = tryToExpandInUnify type2 attr2 modules heaps = unifyTypeApplications cons_var attr1 types type2 attr2 modules subst heaps unifyTypes type1 attr1 (cons_var :@: types) attr2 modules subst heaps # (_, type1, heaps) = tryToExpandInUnify type1 attr1 modules heaps = unifyTypeApplications cons_var attr2 types type1 attr1 modules subst heaps unifyTypes t1=:(TempQV qv_number1) attr1 t2=:(TempQV qv_number2) attr2 modules subst heaps = (qv_number1 == qv_number2, subst, heaps) unifyTypes (TempQV qv_number) attr1 type attr2 modules subst heaps = (False, subst, heaps) unifyTypes type attr1 (TempQV qv_number1) attr2 modules subst heaps = (False, subst, heaps) unifyTypes t1=:(TempQDV qv_number1) attr1 t2=:(TempQDV qv_number2) attr2 modules subst heaps = (qv_number1 == qv_number2, subst, heaps) unifyTypes (TempQDV qv_number) attr1 type attr2 modules subst heaps = (False, subst, heaps) unifyTypes type attr1 (TempQDV qv_number1) attr2 modules subst heaps = (False, subst, heaps) unifyTypes type1 attr1 type2 attr2 modules subst heaps # (succ1, type1, heaps) = tryToExpandInUnify type1 attr1 modules heaps (succ2, type2, heaps) = tryToExpandInUnify type2 attr2 modules heaps | succ1 || succ2 = unifyTypes type1 attr1 type2 attr2 modules subst heaps = (False, subst, heaps) expandAndUnifyTypes t1 attr1 t2 attr2 modules subst heaps # (succ1, t1, heaps) = tryToExpandInUnify t1 attr1 modules heaps (succ2, t2, heaps) = tryToExpandInUnify t2 attr2 modules heaps | succ1 || succ2 = unifyTypes t1 attr1 t2 attr2 modules subst heaps = (False, subst, heaps) tryToExpandInUnify :: !Type !TypeAttribute !TypeInput !*TypeHeaps -> (!Bool, !Type, !*TypeHeaps) tryToExpandInUnify type=:(TA {type_index={glob_object,glob_module}} type_args) type_attr type_input type_heaps #! type_def = type_input.ti_common_defs.[glob_module].com_type_defs.[glob_object] = case type_def.td_rhs of SynType {at_type} # (expanded_type, type_heaps) = substituteType type_def.td_attribute type_attr type_def.td_args type_args at_type type_heaps -> (True, expanded_type, type_heaps) NewType {ds_index} | type_input.ti_expand_newtypes # {cons_type={st_args=[{at_type}:_]}} = type_input.ti_common_defs.[glob_module].com_cons_defs.[ds_index]; # (expanded_type, type_heaps) = substituteType type_def.td_attribute type_attr type_def.td_args type_args at_type type_heaps -> (True, expanded_type, type_heaps) _ -> (False, type, type_heaps) tryToExpandInUnify type=:(TAS {type_index={glob_object,glob_module}} type_args _) type_attr type_input type_heaps #! type_def = type_input.ti_common_defs.[glob_module].com_type_defs.[glob_object] = case type_def.td_rhs of SynType {at_type} # (expanded_type, type_heaps) = substituteType type_def.td_attribute type_attr type_def.td_args type_args at_type type_heaps -> (True, expanded_type, type_heaps) NewType {ds_index} | type_input.ti_expand_newtypes # {cons_type={st_args=[{at_type}:_]}} = type_input.ti_common_defs.[glob_module].com_cons_defs.[ds_index]; # (expanded_type, type_heaps) = substituteType type_def.td_attribute type_attr type_def.td_args type_args at_type type_heaps -> (True, expanded_type, type_heaps) _ -> (False, type, type_heaps) tryToExpandInUnify type type_attr modules type_heaps = (False, type, type_heaps) tryToExpand :: !Type !TypeAttribute !{# CommonDefs} !*TypeHeaps -> (!Bool, !Type, !*TypeHeaps) tryToExpand type=:(TA {type_index={glob_object,glob_module}} type_args) type_attr ti_common_defs type_heaps #! type_def = ti_common_defs.[glob_module].com_type_defs.[glob_object] = case type_def.td_rhs of SynType {at_type} # (expanded_type, type_heaps) = substituteType type_def.td_attribute type_attr type_def.td_args type_args at_type type_heaps -> (True, expanded_type, type_heaps) _ -> (False, type, type_heaps) tryToExpand type=:(TAS {type_index={glob_object,glob_module}} type_args _) type_attr ti_common_defs type_heaps #! type_def = ti_common_defs.[glob_module].com_type_defs.[glob_object] = case type_def.td_rhs of SynType {at_type} # (expanded_type, type_heaps) = substituteType type_def.td_attribute type_attr type_def.td_args type_args at_type type_heaps -> (True, expanded_type, type_heaps) _ -> (False, type, type_heaps) tryToExpand type type_attr modules type_heaps = (False, type, type_heaps) simplifyTypeApplication :: !Type ![AType] -> (!Bool, !Type) simplifyTypeApplication (TA type_cons=:{type_arity} cons_args) type_args = (True, TA { type_cons & type_arity = type_arity + length type_args } (cons_args ++ type_args)) simplifyTypeApplication (TAS type_cons=:{type_arity} cons_args strictness) type_args = (True, TAS { type_cons & type_arity = type_arity + length type_args } (cons_args ++ type_args) strictness) simplifyTypeApplication (cons_var :@: types) type_args = (True, cons_var :@: (types ++ type_args)) simplifyTypeApplication (TempV tv_number) type_args = (True, TempCV tv_number :@: type_args) simplifyTypeApplication (TempQV tv_number) type_args = (True, TempQCV tv_number :@: type_args) simplifyTypeApplication (TempQDV tv_number) type_args = (True, TempQCDV tv_number :@: type_args) simplifyTypeApplication TArrow [type1, type2] = (True, type1 --> type2) simplifyTypeApplication TArrow [type] = (True, TArrow1 type) simplifyTypeApplication (TArrow1 type1) [type2] = (True, type1 --> type2) simplifyTypeApplication type type_args = (False, type) unifyTypeApplications cv=:(TempCV tv_number) attr1 type_args type2 attr2 modules subst heaps # (type1, subst) = subst![tv_number] | isIndirection type1 # (ok, simplified_type) = simplifyTypeApplication type1 type_args | ok = unifyTypes simplified_type attr1 type2 attr2 modules subst heaps = (False, subst, heaps) = unifyCVwithType cv type_args type2 modules subst heaps unifyTypeApplications cv=:(TempQCV tv_number) attr1 type_args type2 attr2 modules subst heaps = unifyCVwithType cv type_args type2 modules subst heaps unifyTypeApplications cv=:(TempQCDV tv_number) attr1 type_args type2 attr2 modules subst heaps = unifyCVwithType cv type_args type2 modules subst heaps unifyCVwithType cv1 type_args1 type=:(cv2 :@: type_args2) modules subst heaps = case cv2 of TempCV tv_number2 # (type2, subst) = subst![tv_number2] | isIndirection type2 # (ok, simplified_type) = simplifyTypeApplication type2 type_args2 | ok -> unifyCVwithType cv1 type_args1 simplified_type modules subst heaps -> (False, subst, heaps) -> unifyCVApplicationwithCVApplication cv1 type_args1 cv2 type_args2 modules subst heaps TempQCV tv_number2 -> unifyCVApplicationwithCVApplication cv1 type_args1 cv2 type_args2 modules subst heaps TempQCDV tv_number2 -> unifyCVApplicationwithCVApplication cv1 type_args1 cv2 type_args2 modules subst heaps unifyCVwithType cv type_args type=:(TA type_cons cons_args) modules subst heaps # diff = type_cons.type_arity - length type_args | diff >= 0 # (succ, subst, heaps) = unify type_args (drop diff cons_args) modules subst heaps | succ = unifyTypes (toTV cv) TA_Multi (TA { type_cons & type_arity = diff } (take diff cons_args)) TA_Multi modules subst heaps = (False, subst, heaps) = (False, subst, heaps) unifyCVwithType cv type_args type=:(TAS type_cons cons_args strictness) modules subst heaps # diff = type_cons.type_arity - length type_args | diff >= 0 # (succ, subst, heaps) = unify type_args (drop diff cons_args) modules subst heaps | succ = unifyTypes (toTV cv) TA_Multi (TAS { type_cons & type_arity = diff } (take diff cons_args) strictness) TA_Multi modules subst heaps = (False, subst, heaps) = (False, subst, heaps) unifyCVwithType cv [type_arg1, type_arg2] type=:(atype1 --> atype2) modules subst heaps # (succ, subst, heaps) = unify (type_arg1, type_arg2) (atype1, atype2) modules subst heaps | succ = unifyTypes (toTV cv) TA_Multi TArrow TA_Multi modules subst heaps = (False, subst, heaps) unifyCVwithType cv [type_arg] type=:(atype1 --> atype2) modules subst heaps # (succ, subst, heaps) = unify type_arg atype2 modules subst heaps | succ = unifyTypes (toTV cv) TA_Multi (TArrow1 atype1) TA_Multi modules subst heaps = (False, subst, heaps) unifyCVwithType cv [] type=:(atype1 --> atype2) modules subst heaps = unifyTypes (toTV cv) TA_Multi type TA_Multi modules subst heaps unifyCVwithType cv [type_arg] type=:(TArrow1 atype) modules subst heaps # (succ, subst, heaps) = unify type_arg atype modules subst heaps | succ = unifyTypes (toTV cv) TA_Multi TArrow TA_Multi modules subst heaps = (False, subst, heaps) unifyCVwithType cv [] type=:(TArrow1 atype) modules subst heaps = unifyTypes (toTV cv) TA_Multi type TA_Multi modules subst heaps unifyCVwithType cv [] TArrow modules subst heaps = unifyTypes (toTV cv) TA_Multi TArrow TA_Multi modules subst heaps unifyCVwithType cv type_args type modules subst heaps = (False, subst, heaps) unifyCVApplicationwithCVApplication cv1 type_args1 cv2 type_args2 modules subst heaps # arity1 = length type_args1 arity2 = length type_args2 diff = arity1 - arity2 | diff == 0 # (succ, subst) = unify_cv_with_cv cv1 cv2 subst | succ = unify type_args1 type_args2 modules subst heaps = (False, subst, heaps) | diff < 0 # diff = 0 - diff (succ, subst, heaps) = unifyTypes (toTV cv1) TA_Multi (cv2 :@: take diff type_args2) TA_Multi modules subst heaps | succ = unify type_args1 (drop diff type_args2) modules subst heaps = (False, subst, heaps) # (succ, subst, heaps) = unifyTypes (cv1 :@: take diff type_args1) TA_Multi (toTV cv2) TA_Multi modules subst heaps | succ = unify (drop diff type_args1) type_args2 modules subst heaps = (False, subst, heaps) where unify_cv_with_cv (TempCV tv_number1) (TempCV tv_number2) subst | tv_number1 == tv_number2 = (True, subst) = (True, {subst & [tv_number1] = TempV tv_number2}) unify_cv_with_cv (TempCV tv_number1) (TempQCV tv_number2) subst | tv_number1 == tv_number2 = (True, subst) = (True, {subst & [tv_number1] = TempQV tv_number2}) unify_cv_with_cv (TempCV tv_number1) (TempQCDV tv_number2) subst | tv_number1 == tv_number2 = (True, subst) = (True, {subst & [tv_number1] = TempQDV tv_number2}) unify_cv_with_cv (TempQCV tv_number1) (TempCV tv_number2) subst | tv_number1 == tv_number2 = (True, subst) = (True, {subst & [tv_number2] = TempQV tv_number1}) unify_cv_with_cv (TempQCV tv_number1) (TempQCV tv_number2) subst | tv_number1 == tv_number2 = (True, subst) = (False, subst) unify_cv_with_cv (TempQCV tv_number1) (TempQCDV tv_number2) subst | tv_number1 == tv_number2 = (True, subst) = (False, subst) unify_cv_with_cv (TempQCDV tv_number1) (TempCV tv_number2) subst | tv_number1 == tv_number2 = (True, subst) = (True, {subst & [tv_number2] = TempQDV tv_number1}) unify_cv_with_cv (TempQCDV tv_number1) (TempQCV tv_number2) subst | tv_number1 == tv_number2 = (True, subst) = (False, subst) unify_cv_with_cv (TempQCDV tv_number1) (TempQCDV tv_number2) subst | tv_number1 == tv_number2 = (True, subst) = (False, subst) toTV (TempCV temp_var_id) = TempV temp_var_id toTV (TempQCV temp_var_id) = TempQV temp_var_id toTV (TempQCDV temp_var_id) = TempQDV temp_var_id instance fromInt TypeAttribute where fromInt AttrUni = TA_Unique fromInt AttrMulti = TA_Multi fromInt av_number = TA_TempVar av_number class freshCopy a :: !a !*TypeHeaps -> (!a, !*TypeHeaps) instance freshCopy [a] | freshCopy a where freshCopy l ls = mapSt freshCopy l ls freshCopyOfAttributeVar {av_ident,av_info_ptr} attr_var_heap # (av_info, attr_var_heap) = readPtr av_info_ptr attr_var_heap = case av_info of AVI_Attr attr -> (attr, attr_var_heap) _ -> abort ("freshCopyOfAttributeVar (type,icl)" ---> (av_ident,av_info_ptr)) freshCopyOfTypeAttribute (TA_Var avar) attr_var_heap = freshCopyOfAttributeVar avar attr_var_heap freshCopyOfTypeAttribute (TA_RootVar avar) attr_var_heap = freshCopyOfAttributeVar avar attr_var_heap freshCopyOfTypeAttribute TA_None attr_var_heap = (TA_Multi, attr_var_heap) freshCopyOfTypeAttribute TA_Unique attr_var_heap = (TA_Unique, attr_var_heap) freshCopyOfTypeAttribute attr attr_var_heap = (attr, attr_var_heap) cIsExistential :== True cIsNotExistential :== False freshCopyOfTypeVariable {tv_ident,tv_info_ptr} type_heaps=:{th_vars} # (TVI_Type fresh_var, th_vars) = readPtr tv_info_ptr th_vars = (fresh_var, { type_heaps & th_vars = th_vars }) freshConsVariable {tv_info_ptr} type_var_heap # (tv_info, type_var_heap) = readPtr tv_info_ptr type_var_heap = (to_constructor_variable tv_info, type_var_heap) where to_constructor_variable (TVI_Type fresh_type) = case fresh_type of TempV temp_var_id -> TempCV temp_var_id TempQV temp_var_id -> TempQCV temp_var_id TempQDV temp_var_id -> TempQCDV temp_var_id TV var -> CV var _ -> abort "type.icl: to_constructor_variable, fresh_type\n" ---> fresh_type to_constructor_variable tvi = abort "type.icl: to_constructor_variable, tvi\n" ---> tvi instance freshCopy AType where freshCopy type=:{at_type, at_attribute} type_heaps=:{th_attrs} # (fresh_attribute, th_attrs) = freshCopyOfTypeAttribute at_attribute th_attrs (fresh_type, type_heaps) = freshCopy at_type { type_heaps & th_attrs = th_attrs } = ({ type & at_type = fresh_type, at_attribute = fresh_attribute }, type_heaps) instance freshCopy Type where freshCopy (TV tv) type_heaps = freshCopyOfTypeVariable tv type_heaps freshCopy (TA cons_id=:{type_index={glob_object,glob_module}} cons_args) type_heaps # (cons_args, type_heaps) = freshCopy cons_args type_heaps = (TA cons_id cons_args, type_heaps) freshCopy (TAS cons_id=:{type_index={glob_object,glob_module}} cons_args strictness) type_heaps # (cons_args, type_heaps) = freshCopy cons_args type_heaps = (TAS cons_id cons_args strictness, type_heaps) freshCopy (arg_type --> res_type) type_heaps # (arg_type, type_heaps) = freshCopy arg_type type_heaps (res_type, type_heaps) = freshCopy res_type type_heaps = (arg_type --> res_type, type_heaps) freshCopy (CV tv :@: types) type_heaps # (fresh_types, type_heaps) = freshCopy types type_heaps # (fresh_cons_var, th_vars) = freshConsVariable tv type_heaps.th_vars = (fresh_cons_var :@: fresh_types, {type_heaps & th_vars = th_vars}) freshCopy (cv :@: types) type_heaps # (fresh_types, type_heaps) = freshCopy types type_heaps = (cv :@: fresh_types, type_heaps) freshCopy (TArrow1 arg_type) type_heaps # (arg_type, type_heaps) = freshCopy arg_type type_heaps = (TArrow1 arg_type, type_heaps) freshCopy (TFA vars type) type_heaps = freshCopyOfTFAType vars type type_heaps freshCopy (TFAC vars type context) type_heaps = freshCopyOfTFACType vars type context type_heaps freshCopy type type_heaps = (type, type_heaps) freshCopyOfTFAType vars type type_heaps # (fresh_vars, type_heaps) = bind_TFA_vars_and_attrs vars type_heaps (type, type_heaps) = freshCopy type type_heaps type_heaps = clear_binding_of_TFA_vars_and_attrs fresh_vars type_heaps = (TFA fresh_vars type, type_heaps) freshCopyOfTFACType vars type contexts type_heaps # (fresh_vars, type_heaps) = bind_TFA_vars_and_attrs vars type_heaps (type, type_heaps) = freshCopy type type_heaps (contexts, type_heaps) = freshTypeContexts_no_fresh_context_vars contexts type_heaps type_heaps = clear_binding_of_TFA_vars_and_attrs fresh_vars type_heaps = (TFAC fresh_vars type contexts, type_heaps) bind_TFA_vars_and_attrs vars type_heaps = foldSt bind_var_and_attr vars ([], type_heaps) where bind_var_and_attr atv=:{atv_attribute, atv_variable = tv=:{tv_info_ptr}} (fresh_vars, type_heaps=:{th_vars,th_attrs}) # (fresh_vars, th_attrs) = bind_attr atv_attribute atv (fresh_vars, th_attrs) = (fresh_vars, {type_heaps & th_vars = th_vars <:= (tv_info_ptr, TVI_Type (TV tv)), th_attrs = th_attrs}) bind_attr var=:(TA_Var {av_info_ptr}) atv (fresh_vars, attr_heap) # (av_info, attr_heap) = readPtr av_info_ptr attr_heap = case av_info of AVI_Empty -> ([atv : fresh_vars], attr_heap <:= (av_info_ptr, AVI_Attr var)) AVI_Attr (TA_TempVar _) -> ([{ atv & atv_attribute = TA_Multi } : fresh_vars], attr_heap) bind_attr attr atv (fresh_vars, attr_heap) = ([atv : fresh_vars], attr_heap) clear_binding_of_TFA_vars_and_attrs fresh_vars type_heaps = foldSt clear_binding_of_var_and_attr fresh_vars type_heaps where clear_binding_of_var_and_attr {atv_attribute, atv_variable = tv=:{tv_info_ptr}} type_heaps=:{th_vars,th_attrs} = { type_heaps & th_vars = th_vars <:= (tv_info_ptr, TVI_Empty), th_attrs = clear_attr atv_attribute th_attrs } clear_attr var=:(TA_Var {av_info_ptr}) attr_heap = attr_heap <:= (av_info_ptr, AVI_Empty) clear_attr attr attr_heap = attr_heap freshExistentialVariables type_variables var_store attr_store type_heaps = foldSt fresh_existential_variable type_variables ([], var_store, attr_store, type_heaps) where fresh_existential_variable {atv_variable={tv_info_ptr},atv_attribute} (exi_attr_vars, var_store, attr_store, type_heaps =: {th_vars, th_attrs}) # th_vars = th_vars <:= (tv_info_ptr, TVI_Type (TempQV var_store)) # var_store = inc var_store # (exi_attr_vars, attr_store, th_attrs) = fresh_existential_attribute atv_attribute (exi_attr_vars, attr_store, th_attrs) = (exi_attr_vars, var_store, attr_store, { type_heaps & th_vars = th_vars, th_attrs = th_attrs }) fresh_existential_attribute (TA_Var {av_info_ptr}) (exi_attr_vars, attr_store, attr_heap) = ([ attr_store : exi_attr_vars ], inc attr_store, attr_heap <:= (av_info_ptr, AVI_Attr (TA_TempVar attr_store))) fresh_existential_attribute attr state = state fresh_type_variables :: [ATypeVar] *(*TypeVarHeap,Int) -> *(!*TypeVarHeap,!Int); fresh_type_variables type_variables state = foldSt (\{atv_variable={tv_info_ptr}} (var_heap, var_store) -> (var_heap <:= (tv_info_ptr, TVI_Type (TempV var_store)), inc var_store)) type_variables state fresh_attributes :: [AttributeVar] *(*AttrVarHeap,Int) -> *(!*AttrVarHeap,!Int); fresh_attributes attributes state = foldSt (\{av_info_ptr} (attr_heap, attr_store) -> (attr_heap <:= (av_info_ptr, AVI_Attr (TA_TempVar attr_store)), inc attr_store)) attributes state fresh_environment :: [AttrInequality] [AttrCoercion] *AttrVarHeap -> *(![AttrCoercion],!*AttrVarHeap); fresh_environment inequalities attr_env attr_heap = foldSt fresh_inequality inequalities (attr_env, attr_heap) where fresh_inequality {ai_demanded,ai_offered} (attr_env, attr_heap) # (AVI_Attr dem_temp_attr, attr_heap) = readPtr ai_demanded.av_info_ptr attr_heap (AVI_Attr off_temp_attr, attr_heap) = readPtr ai_offered.av_info_ptr attr_heap = case dem_temp_attr of TA_TempVar dem_attr_var -> case off_temp_attr of TA_TempVar off_attr_var | is_new_ineqality dem_attr_var off_attr_var attr_env -> ([{ac_demanded = dem_attr_var, ac_offered = off_attr_var} : attr_env ], attr_heap) -> (attr_env, attr_heap) _ -> (attr_env, attr_heap) _ -> (attr_env, attr_heap) is_new_ineqality dem_attr_var off_attr_var [{ac_demanded, ac_offered} : attr_env] = (dem_attr_var <> ac_demanded || off_attr_var <> ac_offered) && is_new_ineqality dem_attr_var off_attr_var attr_env is_new_ineqality dem_attr_var off_attr_var [] = True freshAlgebraicType :: !GlobalIndex ![AlgebraicPattern] !{#CommonDefs} !*TypeState -> (![[AType]],!AType,![AttrCoercion],[(DefinedSymbol,[TypeContext])],!TypeRhs,!*TypeState) freshAlgebraicType {gi_module,gi_index} patterns common_defs ts=:{ts_var_store,ts_attr_store,ts_type_heaps,ts_exis_variables} # {td_rhs,td_args,td_attrs} = common_defs.[gi_module].com_type_defs.[gi_index] # (th_vars, ts_var_store) = fresh_type_variables td_args (ts_type_heaps.th_vars, ts_var_store) (th_attrs, ts_attr_store) = fresh_attributes td_attrs (ts_type_heaps.th_attrs, ts_attr_store) ts_type_heaps = { ts_type_heaps & th_vars = th_vars, th_attrs = th_attrs } (cons_types, alg_type, attr_env, constructor_contexts, ts_var_store, ts_attr_store, ts_type_heaps, ts_exis_variables) = fresh_symbol_types patterns common_defs td_attrs td_args ts_var_store ts_attr_store ts_type_heaps ts_exis_variables = (cons_types, alg_type, attr_env, constructor_contexts, td_rhs, { ts & ts_var_store = ts_var_store, ts_attr_store = ts_attr_store, ts_type_heaps = ts_type_heaps, ts_exis_variables = ts_exis_variables }) where fresh_symbol_types [{ap_symbol={glob_object,glob_module},ap_expr}] common_defs td_attrs td_args var_store attr_store type_heaps all_exis_variables # {cons_type = {st_args,st_attr_env,st_result,st_context}, cons_exi_vars, cons_number, cons_type_index} = common_defs.[glob_module].com_cons_defs.[glob_object.ds_index] | cons_number <> -3 # (exis_variables, var_store, attr_store, type_heaps) = freshExistentialVariables cons_exi_vars var_store attr_store type_heaps (attr_env, th_attrs) = fresh_environment st_attr_env [] type_heaps.th_attrs (result_type, type_heaps) = freshCopy st_result { type_heaps & th_attrs = th_attrs } (fresh_args, type_heaps) = freshCopy st_args type_heaps all_exis_variables = add_exis_variables ap_expr exis_variables all_exis_variables | isEmpty st_context = ([fresh_args], result_type, attr_env, [], var_store, attr_store, type_heaps, all_exis_variables) # (context, type_heaps) = freshTypeContexts_no_fresh_context_vars st_context type_heaps // fresh_context_vars are created later = ([fresh_args], result_type, attr_env, [(glob_object,context)], var_store, attr_store, type_heaps, all_exis_variables) # extension_type = common_defs.[glob_module].com_type_defs.[cons_type_index] th_vars = copy_type_variables extension_type.td_args td_args type_heaps.th_vars th_attrs = copy_attributes extension_type.td_attrs td_attrs type_heaps.th_attrs type_heaps & th_vars = th_vars, th_attrs = th_attrs # (exis_variables, var_store, attr_store, type_heaps) = freshExistentialVariables cons_exi_vars var_store attr_store type_heaps (attr_env, th_attrs) = fresh_environment st_attr_env [] type_heaps.th_attrs (result_type, type_heaps) = freshCopy st_result { type_heaps & th_attrs = th_attrs } (fresh_args, type_heaps) = freshCopy st_args type_heaps all_exis_variables = add_exis_variables ap_expr exis_variables all_exis_variables | isEmpty st_context = ([fresh_args], result_type, attr_env, [], var_store, attr_store, type_heaps, all_exis_variables) # (context, type_heaps) = freshTypeContexts_no_fresh_context_vars st_context type_heaps // fresh_context_vars are created later = ([fresh_args], result_type, attr_env, [(glob_object,context)], var_store, attr_store, type_heaps, all_exis_variables) fresh_symbol_types [{ap_symbol={glob_object,glob_module},ap_expr} : patterns] common_defs td_attrs td_args var_store attr_store type_heaps all_exis_variables # (cons_types, result_type, attr_env, constructor_contexts, var_store, attr_store, type_heaps, all_exis_variables) = fresh_symbol_types patterns common_defs td_attrs td_args var_store attr_store type_heaps all_exis_variables # {cons_type = {st_args,st_attr_env,st_context}, cons_exi_vars,cons_number, cons_type_index} = common_defs.[glob_module].com_cons_defs.[glob_object.ds_index] | cons_number <> -3 # (exis_variables, var_store, attr_store, type_heaps) = freshExistentialVariables cons_exi_vars var_store attr_store type_heaps (attr_env, th_attrs) = fresh_environment st_attr_env attr_env type_heaps.th_attrs (fresh_args, type_heaps) = freshCopy st_args { type_heaps & th_attrs = th_attrs } all_exis_variables = add_exis_variables ap_expr exis_variables all_exis_variables | isEmpty st_context = ([fresh_args : cons_types], result_type, attr_env, constructor_contexts, var_store, attr_store, type_heaps, all_exis_variables) # (context, type_heaps) = freshTypeContexts_no_fresh_context_vars st_context type_heaps // fresh_context_vars are created later = ([fresh_args : cons_types], result_type, attr_env, [(glob_object,context):constructor_contexts], var_store, attr_store, type_heaps, all_exis_variables) # extension_type = common_defs.[glob_module].com_type_defs.[cons_type_index] th_vars = copy_type_variables extension_type.td_args td_args type_heaps.th_vars th_attrs = copy_attributes extension_type.td_attrs td_attrs type_heaps.th_attrs type_heaps & th_vars = th_vars, th_attrs = th_attrs # (exis_variables, var_store, attr_store, type_heaps) = freshExistentialVariables cons_exi_vars var_store attr_store type_heaps (attr_env, th_attrs) = fresh_environment st_attr_env attr_env type_heaps.th_attrs (fresh_args, type_heaps) = freshCopy st_args { type_heaps & th_attrs = th_attrs } all_exis_variables = add_exis_variables ap_expr exis_variables all_exis_variables | isEmpty st_context = ([fresh_args : cons_types], result_type, attr_env, constructor_contexts, var_store, attr_store, type_heaps, all_exis_variables) # (context, type_heaps) = freshTypeContexts_no_fresh_context_vars st_context type_heaps // fresh_context_vars are created later = ([fresh_args : cons_types], result_type, attr_env, [(glob_object,context):constructor_contexts], var_store, attr_store, type_heaps, all_exis_variables) add_exis_variables expr [] exis_variables = exis_variables add_exis_variables expr new_exis_variables exis_variables = [(CP_Expression expr, new_exis_variables) : exis_variables] copy_type_variables [dest_type_var:dest_type_vars] [source_type_var:source_type_vars] th_vars # (tv_info/*TVI_Type (TempV type_var_number)*/,th_vars) = readPtr source_type_var.atv_variable.tv_info_ptr th_vars # th_vars = writePtr dest_type_var.atv_variable.tv_info_ptr tv_info th_vars = copy_type_variables dest_type_vars source_type_vars th_vars copy_type_variables [] [] th_vars = th_vars copy_attributes [dest_attr:dest_attrs] [source_attr:source_attrs] th_attrs # (av_info/*AVI_Attr (TA_TempVar attr_number)*/,th_attrs) = readPtr source_attr.av_info_ptr th_attrs # th_attrs = writePtr dest_attr.av_info_ptr av_info th_attrs = copy_attributes dest_attrs source_attrs th_attrs copy_attributes [] [] th_attrs = th_attrs create_fresh_context_vars [(cons_symbol,contexts):constructor_contexts] var_heap # (constructor_contexts,var_heap) = create_fresh_context_vars constructor_contexts var_heap # (contexts,var_heap) = mapSt fresh_type_context_var contexts var_heap = ([(cons_symbol,contexts):constructor_contexts],var_heap); where fresh_type_context_var tc var_heap # (new_info_ptr, var_heap) = newPtr VI_Empty var_heap = ({tc & tc_var = new_info_ptr}, var_heap) create_fresh_context_vars [] var_heap = ([],var_heap) fresh_overloaded_list_type [{ap_symbol}:patterns] pd_cons_symbol pd_nil_symbol decons_u_index nil_u_index stdStrictLists_index pos functions common_defs ts | ap_symbol.glob_module==cPredefinedModuleIndex | ap_symbol.glob_object.ds_index==pd_cons_symbol-FirstConstructorPredefinedSymbolIndex # (argument_types,result_type,tst_context,tst_attr_env,ts) = make_cons_type_from_decons_type stdStrictLists_index decons_u_index common_defs ts = case patterns of [] -> ([argument_types],result_type,tst_context,tst_attr_env,ts) [pattern=:{ap_symbol}] | ap_symbol.glob_module==cPredefinedModuleIndex && ap_symbol.glob_object.ds_index==pd_nil_symbol-FirstConstructorPredefinedSymbolIndex -> ([argument_types,[]],result_type,tst_context,tst_attr_env,ts) | ap_symbol.glob_object.ds_index==pd_nil_symbol-FirstConstructorPredefinedSymbolIndex = case patterns of [] # {ft_type,ft_ident,ft_type_ptr,ft_specials} = functions.[stdStrictLists_index].[nil_u_index] # (fun_type_copy, ts) = determineSymbolTypeOfFunction pos ft_ident 0 ft_type ft_type_ptr common_defs ts {tst_args,tst_result,tst_context,tst_attr_env}=fun_type_copy -> ([tst_args],tst_result,tst_context,tst_attr_env,ts) [pattern=:{ap_symbol}] | ap_symbol.glob_module==cPredefinedModuleIndex && ap_symbol.glob_object.ds_index==pd_cons_symbol-FirstConstructorPredefinedSymbolIndex # (argument_types,result_type,tst_context,tst_attr_env,ts) = make_cons_type_from_decons_type stdStrictLists_index decons_u_index common_defs ts -> ([[],argument_types],result_type,tst_context,tst_attr_env,ts) = abort "fresh_overloaded_list_type" where make_cons_type_from_decons_type stdStrictLists_index decons_u_index common_defs ts # {me_ident,me_type,me_type_ptr} = common_defs.[stdStrictLists_index].com_member_defs.[decons_u_index] (fun_type_copy,ts) = determineSymbolTypeOfFunction pos me_ident 1 me_type me_type_ptr common_defs ts {tst_args,tst_lifted,tst_result,tst_context,tst_attr_env}=fun_type_copy # result_type = case tst_args of [t] -> t # argument_types = case tst_result.at_type of TA _ args=:[arg1,arg2] -> args TAS _ args=:[arg1,arg2] _ -> args = (argument_types,result_type,tst_context,tst_attr_env,ts) freshOverloadedListType :: !OverloadedListType !CoercionPosition ![AlgebraicPattern] !{#CommonDefs} !{#{#FunType }} !*TypeState -> (![[AType]],!AType,![TypeContext],![AttrCoercion],!*TypeState) freshOverloadedListType (UnboxedList _ stdStrictLists_index decons_u_index nil_u_index) pos patterns common_defs functions ts = fresh_overloaded_list_type patterns PD_UnboxedConsSymbol PD_UnboxedNilSymbol decons_u_index nil_u_index stdStrictLists_index pos functions common_defs ts freshOverloadedListType (UnboxedTailStrictList _ stdStrictLists_index decons_u_index nil_u_index) pos patterns common_defs functions ts = fresh_overloaded_list_type patterns PD_UnboxedTailStrictConsSymbol PD_UnboxedTailStrictNilSymbol decons_u_index nil_u_index stdStrictLists_index pos functions common_defs ts freshOverloadedListType (OverloadedList _ stdStrictLists_index decons_u_index nil_u_index) pos patterns common_defs functions ts = fresh_overloaded_list_type patterns PD_OverloadedConsSymbol PD_OverloadedNilSymbol decons_u_index nil_u_index stdStrictLists_index pos functions common_defs ts cWithFreshContextVars :== True cWithoutFreshContextVars :== False freshSymbolType :: !(Optional CoercionPosition) !Bool !SymbolType {#u:CommonDefs} !*TypeState -> (!TempSymbolType,!*TypeState) freshSymbolType is_appl fresh_context_vars {st_vars,st_args,st_result,st_context,st_attr_vars,st_attr_env,st_arity} common_defs ts=:{ts_var_store,ts_attr_store,ts_type_heaps,ts_var_heap,ts_cons_variables,ts_exis_variables} # (th_vars, ts_var_store) = fresh_type_variables st_vars (ts_type_heaps.th_vars, ts_var_store) (th_attrs, ts_attr_store) = fresh_attributes st_attr_vars (ts_type_heaps.th_attrs, ts_attr_store) (attr_env, th_attrs) = freshEnvironment st_attr_env th_attrs type_heaps = {ts_type_heaps & th_vars = th_vars, th_attrs = th_attrs} (tst_args,var_contexts,ts_var_store,ts_attr_store,ts_exis_variables,type_heaps,ts_var_heap) = fresh_arg_types is_appl st_args ts_var_store ts_attr_store ts_exis_variables type_heaps ts_var_heap (tst_result, type_heaps) = freshCopy st_result type_heaps (tst_context, (type_heaps, ts_var_heap)) = freshTypeContexts fresh_context_vars st_context (type_heaps, ts_var_heap) type_heaps = {type_heaps & th_attrs = clear_attributes st_attr_vars type_heaps.th_attrs} // to do collect cons variables in contexts in TFAC of arguments cons_variables = foldSt (collect_cons_variables_in_tc common_defs) tst_context [] tst = {tst_args=tst_args, tst_result=tst_result, tst_context=tst_context, tst_var_contexts=var_contexts, tst_attr_env=attr_env, tst_arity=st_arity, tst_lifted=0} = (tst, {ts & ts_var_store = ts_var_store, ts_attr_store = ts_attr_store, ts_type_heaps = type_heaps, ts_var_heap = ts_var_heap, ts_cons_variables = cons_variables ++ ts_cons_variables, ts_exis_variables = ts_exis_variables}) where fresh_type_variables :: [TypeVar] !(!*TypeVarHeap, !Int) -> (!*TypeVarHeap, !Int) fresh_type_variables type_variables state = foldSt fresh_type_variable type_variables state where fresh_type_variable {tv_info_ptr} (var_heap, var_store) = (var_heap <:= (tv_info_ptr, TVI_Type (TempV var_store)), inc var_store) fresh_attributes :: [AttributeVar] !(!*AttrVarHeap, !Int) -> (!*AttrVarHeap, !Int) fresh_attributes attributes state = foldSt fresh_attribute attributes state where fresh_attribute {av_info_ptr} (attr_heap, attr_store) = (attr_heap <:= (av_info_ptr, AVI_Attr (TA_TempVar attr_store)), inc attr_store) clear_attributes :: [AttributeVar] !*AttrVarHeap -> *AttrVarHeap clear_attributes attributes attr_heap = foldSt clear_attribute attributes attr_heap where clear_attribute {av_info_ptr} attr_heap = attr_heap <:= (av_info_ptr, AVI_Empty) collect_cons_variables_in_tc common_defs tc=:{tc_class=TCClass {glob_module,glob_object={ds_index}}, tc_types} collected_cons_vars # {class_cons_vars} = common_defs.[glob_module].com_class_defs.[ds_index] = collect_cons_variables tc_types class_cons_vars collected_cons_vars collect_cons_variables_in_tc common_defs tc=:{tc_class=TCGeneric {gtc_class}} collected_cons_vars = collect_cons_variables_in_tc common_defs {tc & tc_class=TCClass gtc_class} collected_cons_vars collect_cons_variables [] class_cons_vars collected_cons_vars = collected_cons_vars collect_cons_variables [type : tc_types] class_cons_vars collected_cons_vars | class_cons_vars bitand 1 == 0 = collect_cons_variables tc_types (class_cons_vars >> 1) collected_cons_vars = case type of TempV temp_var_id -> collect_cons_variables tc_types (class_cons_vars >> 1) (add_variable temp_var_id collected_cons_vars) _ -> collect_cons_variables tc_types (class_cons_vars >> 1) collected_cons_vars add_variable new_var_id [] = [new_var_id] add_variable new_var_id vars=:[var_id : var_ids] | new_var_id == var_id = vars = [var_id : add_variable new_var_id var_ids] fresh_arg_types No arg_types var_store attr_store exis_variables type_heaps var_heap # (arg_types, type_heaps) = mapSt fresh_arg_type arg_types type_heaps = (arg_types,NoVarContexts,var_store, attr_store, exis_variables, type_heaps, var_heap) where fresh_arg_type at=:{at_attribute, at_type = TFA vars type} type_heaps # (fresh_attribute, th_attrs) = freshCopyOfTypeAttribute at_attribute type_heaps.th_attrs (at_type, type_heaps) = freshCopyOfTFAType vars type {type_heaps & th_attrs = th_attrs} = ({at & at_attribute = fresh_attribute, at_type = at_type}, type_heaps) fresh_arg_type at=:{at_attribute, at_type = TFAC vars type contexts} type_heaps # (fresh_attribute, th_attrs) = freshCopyOfTypeAttribute at_attribute type_heaps.th_attrs (at_type, type_heaps) = freshCopyOfTFACType vars type contexts {type_heaps & th_attrs = th_attrs} = ({at & at_attribute = fresh_attribute, at_type = at_type}, type_heaps) fresh_arg_type at type_heaps = freshCopy at type_heaps fresh_arg_types (Yes pos) arg_types var_store attr_store exis_variables type_heaps var_heap = fresh_arg_types pos arg_types NoVarContexts 0 var_store attr_store exis_variables type_heaps var_heap where fresh_arg_types :: p ![AType] (VarContexts TypeContext) !Int Int Int [(p,[Int])] *TypeHeaps *VarHeap -> *(![AType],!(VarContexts TypeContext), !Int,!Int,![(p,[Int])],!*TypeHeaps,!*VarHeap) fresh_arg_types pos [arg_type:arg_types] var_contexts arg_n var_store attr_store exis_variables type_heaps var_heap # (arg_types,var_contexts,var_store,attr_store,exis_variables,type_heaps,var_heap) = fresh_arg_types pos arg_types var_contexts (arg_n+1) var_store attr_store exis_variables type_heaps var_heap # (arg_type,var_contexts,var_store,attr_store,exis_variables,type_heaps,var_heap) = fresh_arg_type pos arg_type var_contexts arg_n var_store attr_store exis_variables type_heaps var_heap = ([arg_type:arg_types],var_contexts,var_store,attr_store,exis_variables,type_heaps,var_heap) fresh_arg_types pos [] var_contexts arg_n var_store attr_store exis_variables type_heaps var_heap = ([],var_contexts,var_store,attr_store,exis_variables,type_heaps,var_heap) fresh_arg_type :: p !AType (VarContexts TypeContext) !Int Int Int [(p,[Int])] *TypeHeaps *VarHeap -> *(!AType,!(VarContexts TypeContext), !Int,!Int,![(p,[Int])],!*TypeHeaps,!*VarHeap) fresh_arg_type pos at=:{at_attribute, at_type = TFA vars type} var_contexts arg_n var_store attr_store exis_variables type_heaps var_heap # (fresh_attribute, th_attrs) = freshCopyOfTypeAttribute at_attribute type_heaps.th_attrs (var_store, attr_store, new_exis_variables, bound_attr_vars, type_heaps) = fresh_vars_and_attrs vars var_store attr_store {type_heaps & th_attrs = th_attrs} (fresh_type, type_heaps) = freshCopy type type_heaps type_heaps = {type_heaps & th_vars = clear_binding_of_type_vars vars type_heaps.th_vars, th_attrs = clear_binding_of_attr_vars bound_attr_vars type_heaps.th_attrs} exis_variables = addToExistentialVariables pos new_exis_variables exis_variables at = {at & at_attribute = fresh_attribute, at_type = fresh_type} = (at,var_contexts,var_store,attr_store,exis_variables,type_heaps,var_heap) fresh_arg_type pos at=:{at_attribute, at_type = TFAC vars type contexts} var_contexts arg_n var_store attr_store exis_variables type_heaps var_heap # (fresh_attribute, th_attrs) = freshCopyOfTypeAttribute at_attribute type_heaps.th_attrs (var_store, attr_store, new_exis_variables, bound_attr_vars, type_heaps) = fresh_vars_and_attrs vars var_store attr_store {type_heaps & th_attrs = th_attrs} (fresh_type, type_heaps) = freshCopy type type_heaps (fresh_context, (type_heaps,var_heap)) = freshTypeContexts fresh_context_vars contexts (type_heaps,var_heap) type_heaps = {type_heaps & th_vars = clear_binding_of_type_vars vars type_heaps.th_vars, th_attrs = clear_binding_of_attr_vars bound_attr_vars type_heaps.th_attrs} exis_variables = addToExistentialVariables pos new_exis_variables exis_variables at = {at & at_attribute = fresh_attribute, at_type = fresh_type} var_contexts = VarContext arg_n fresh_context at var_contexts = (at,var_contexts,var_store,attr_store,exis_variables,type_heaps,var_heap) fresh_arg_type _ at var_contexts arg_n var_store attr_store exis_variables type_heaps var_heap # (fresh_at,type_heaps) = freshCopy at type_heaps = (fresh_at,var_contexts,var_store,attr_store,exis_variables,type_heaps,var_heap) fresh_vars_and_attrs vars var_store attr_store type_heaps = foldSt fresh_var_and_attr vars (var_store, attr_store, [], [], type_heaps) where fresh_var_and_attr {atv_attribute, atv_variable = tv=:{tv_info_ptr}} (var_store, attr_store, exis_variables, bound_attr_vars, type_heaps) # (attr_store, exis_variables, bound_attr_vars, th_attrs) = fresh_attr atv_attribute (attr_store, exis_variables, bound_attr_vars, type_heaps.th_attrs) = (inc var_store, attr_store, exis_variables, bound_attr_vars, {type_heaps & th_vars = type_heaps.th_vars <:= (tv_info_ptr, TVI_Type (TempQV var_store)), th_attrs = th_attrs}) where fresh_attr var=:(TA_Var {av_info_ptr}) (attr_store, exis_variables, bound_attr_vars, attr_heap) # (av_info, attr_heap) = readPtr av_info_ptr attr_heap = case av_info of AVI_Empty -> (inc attr_store, [attr_store : exis_variables], [av_info_ptr : bound_attr_vars], attr_heap <:= (av_info_ptr, AVI_Attr (TA_TempVar attr_store))) AVI_Attr (TA_TempVar _) -> (attr_store, exis_variables, bound_attr_vars, attr_heap) fresh_attr attr state = state clear_binding_of_type_vars vars th_vars = foldSt clear_binding_of_type_var vars th_vars where clear_binding_of_type_var {atv_variable = {tv_info_ptr}} type_var_heap = type_var_heap <:= (tv_info_ptr, TVI_Empty) clear_binding_of_attr_vars bound_attr_vars th_attrs = foldSt clear_binding_of_attr_var bound_attr_vars th_attrs where clear_binding_of_attr_var av_info_ptr attr_var_heap = attr_var_heap <:= (av_info_ptr, AVI_Empty) addToExistentialVariables pos [] exis_variables = exis_variables addToExistentialVariables pos new_exis_variables exis_variables = [(pos, new_exis_variables) : exis_variables] freshInequality :: AttrInequality *AttrVarHeap -> (!AttrCoercion,!*AttrVarHeap); freshInequality {ai_demanded,ai_offered} attr_heap # (av_dem_info, attr_heap) = readPtr ai_demanded.av_info_ptr attr_heap (av_off_info, attr_heap) = readPtr ai_offered.av_info_ptr attr_heap (AVI_Attr (TA_TempVar dem_attr_var)) = av_dem_info (AVI_Attr (TA_TempVar off_attr_var)) = av_off_info = ({ac_demanded = dem_attr_var, ac_offered = off_attr_var}, attr_heap) freshEnvironment [ineq : ineqs] attr_heap # (fresh_ineq, attr_heap) = freshInequality ineq attr_heap (fresh_env, attr_heap) = freshEnvironment ineqs attr_heap = ([fresh_ineq : fresh_env], attr_heap) freshEnvironment [] attr_heap = ([], attr_heap) freshTypeContexts :: Bool [TypeContext] *(*TypeHeaps,*VarHeap) -> *(![TypeContext],!*(!*TypeHeaps,!*VarHeap)) freshTypeContexts fresh_context_vars tcs cs_and_var_heap = mapSt (fresh_type_context fresh_context_vars) tcs cs_and_var_heap where fresh_type_context fresh_context_vars tc=:{tc_types} (type_heaps, var_heap) # (tc_types, type_heaps) = fresh_context_types tc_types type_heaps | fresh_context_vars # (new_info_ptr, var_heap) = newPtr VI_Empty var_heap = ({ tc & tc_types = tc_types, tc_var = new_info_ptr }, (type_heaps, var_heap)) = ({ tc & tc_types = tc_types}, (type_heaps, var_heap)) freshTypeContexts_no_fresh_context_vars tcs type_heaps = mapSt fresh_type_context tcs type_heaps where fresh_type_context tc=:{tc_types} type_heaps # (tc_types, type_heaps) = fresh_context_types tc_types type_heaps = ({tc & tc_types = tc_types}, type_heaps) fresh_context_types tc_types type_heaps = mapSt fresh_context_type tc_types type_heaps where fresh_context_type (CV tv :@: types) type_heaps=:{th_vars} # (fresh_cons_var, th_vars) = freshConsVariable tv th_vars (types, type_heaps) = freshCopy types { type_heaps & th_vars = th_vars } = (fresh_cons_var :@: types, type_heaps) fresh_context_type type type_heaps = freshCopy type type_heaps freshAttributedVariable :: !u:TypeState -> (!AType, !u:TypeState) freshAttributedVariable ts=:{ts_var_store,ts_attr_store} = ({ at_attribute = TA_TempVar ts_attr_store, at_type = TempV ts_var_store }, {ts & ts_var_store = inc ts_var_store, ts_attr_store = inc ts_attr_store}) freshNonUniqueVariable :: !u:TypeState -> (!AType, !u:TypeState) freshNonUniqueVariable ts=:{ts_var_store} = ({ at_attribute = TA_Multi, at_type = TempV ts_var_store }, {ts & ts_var_store = inc ts_var_store}) freshAttribute :: !u:TypeState -> (!TypeAttribute, !u:TypeState) freshAttribute ts=:{ts_attr_store} = (TA_TempVar ts_attr_store, {ts & ts_attr_store = inc ts_attr_store}) :: PropState = { prop_type_heaps :: !.TypeHeaps , prop_td_infos :: !.TypeDefInfos , prop_attr_vars :: ![AttributeVar] , prop_attr_env :: ![AttrInequality] , prop_error :: !.Optional .ErrorAdmin } attribute_error attr_var No = No attribute_error attr_var (Yes err) # err = errorHeading "Type error" err = Yes { err & ea_file = err.ea_file <<< "* attribute expected instead of attribute variable:" <<< attr_var <<< '\n' } determine_attribute_of_cons :: !TypeAttribute ![AType] Int !*AttrVarHeap ![AttributeVar] ![AttrInequality] !*(Optional *ErrorAdmin) -> (!TypeAttribute,Int,!*AttrVarHeap,![AttributeVar],![AttrInequality],!* Optional *ErrorAdmin ) determine_attribute_of_cons TA_Unique cons_args prop_class attr_var_heap attr_vars attr_env ps_error = (TA_Unique, prop_class >> length cons_args, attr_var_heap, attr_vars, attr_env, ps_error) determine_attribute_of_cons cons_attr cons_args prop_class attr_var_heap attr_vars attr_env ps_error # (cumm_attr, prop_attrs, prop_class) = determine_cummulative_attribute cons_args TA_Multi [] prop_class (comb_attr, attr_var_heap, attr_vars, attr_env, ps_error) = combine_attributes cons_attr cumm_attr prop_attrs attr_var_heap attr_vars attr_env ps_error = (comb_attr, prop_class, attr_var_heap, attr_vars, attr_env, ps_error) where determine_cummulative_attribute [] cumm_attr attr_vars prop_class = (cumm_attr, attr_vars, prop_class) determine_cummulative_attribute [{at_attribute} : types] cumm_attr attr_vars prop_class | prop_class bitand 1 == 0 = determine_cummulative_attribute types cumm_attr attr_vars (prop_class >> 1) = case at_attribute of TA_Unique -> (TA_Unique, [], prop_class >> length types) TA_Multi -> determine_cummulative_attribute types cumm_attr attr_vars (prop_class >> 1) TA_Var attr_var -> determine_cummulative_attribute types at_attribute [attr_var : attr_vars] (prop_class >> 1) TA_RootVar attr_var -> determine_cummulative_attribute types at_attribute [attr_var : attr_vars] (prop_class >> 1) TA_MultiOfPropagatingConsVar -> determine_cummulative_attribute types cumm_attr attr_vars (prop_class >> 1) _ -> abort ("determine_cummulative_attribute" ---> at_attribute) combine_attributes (TA_Var attr_var) cumm_attr prop_vars attr_var_heap attr_vars attr_env ps_error = case cumm_attr of TA_Unique -> (TA_Unique, attr_var_heap, attr_vars, attr_env, attribute_error attr_var ps_error) TA_Multi -> (TA_Var attr_var, attr_var_heap, attr_vars, attr_env, ps_error) TA_Var _ -> (TA_Var attr_var, attr_var_heap, attr_vars, foldSt (new_inequality attr_var) prop_vars attr_env, ps_error) _ -> abort ("combine_attributes" ---> cumm_attr) where new_inequality off_attr_var dem_attr_var inequals | is_new_inequality off_attr_var dem_attr_var inequals = inequals ++ [{ ai_demanded = dem_attr_var, ai_offered = off_attr_var }] = inequals is_new_inequality off_attr_var dem_attr_var [inequal : iequals] | dem_attr_var.av_info_ptr == inequal.ai_demanded.av_info_ptr && off_attr_var.av_info_ptr == inequal.ai_offered.av_info_ptr = False = is_new_inequality off_attr_var dem_attr_var iequals is_new_inequality off_attr_var dem_attr_var [] = True combine_attributes _ (TA_Var var) prop_vars attr_var_heap attr_vars attr_env ps_error # (new_attr_ptr, attr_var_heap) = newPtr AVI_Empty attr_var_heap new_attr_var = { var & av_info_ptr = new_attr_ptr } = (TA_Var new_attr_var, attr_var_heap, [new_attr_var : attr_vars], mapAppend (\ai_demanded -> { ai_demanded = ai_demanded, ai_offered = new_attr_var }) prop_vars attr_env, ps_error) combine_attributes cons_attr TA_Unique _ attr_var_heap attr_vars attr_env ps_error = (TA_Unique, attr_var_heap, attr_vars, attr_env, ps_error) combine_attributes cons_attr _ _ attr_var_heap attr_vars attr_env ps_error = (cons_attr, attr_var_heap, attr_vars, attr_env, ps_error) addPropagationAttributesToAType :: {#CommonDefs} !AType !*PropState -> *(!AType,!*PropState); addPropagationAttributesToAType modules type ps # (_, type, prop_class, ps) = add_propagation_attributes_to_AType modules type ps = (type, ps) addPropagationAttributesToATypes :: {#CommonDefs} ![AType] !*PropState -> (![AType],!*PropState) addPropagationAttributesToATypes modules types ps = mapSt (addPropagationAttributesToAType modules) types ps add_propagation_attributes_to_AType :: {#CommonDefs} !AType !*PropState -> *(!Bool, !AType,Int,!*PropState); add_propagation_attributes_to_AType modules type=:{at_type = TA cons_id=:{type_index={glob_object,glob_module},type_ident} cons_args, at_attribute} ps # (cons_args_m, cons_args_r, props, ps=:{prop_td_infos,prop_type_heaps,prop_attr_vars,prop_attr_env,prop_error}) = add_propagation_attributes_to_atypes modules cons_args ps (prop_class, th_vars, prop_td_infos) = propClassification glob_object glob_module props modules prop_type_heaps.th_vars prop_td_infos | cons_args_m # (at_attribute, prop_class, th_attrs, prop_attr_vars, prop_attr_env, prop_error) = determine_attribute_of_cons at_attribute cons_args_r prop_class prop_type_heaps.th_attrs prop_attr_vars prop_attr_env prop_error prop_type_heaps & th_vars = th_vars, th_attrs = th_attrs ps & prop_attr_vars = prop_attr_vars, prop_td_infos = prop_td_infos, prop_attr_env = prop_attr_env, prop_type_heaps = prop_type_heaps, prop_error = prop_error = (True, {type & at_type = TA cons_id cons_args_r, at_attribute = at_attribute}, prop_class, ps) # (at_attribute_r, prop_class, th_attrs, prop_attr_vars, prop_attr_env, prop_error) = determine_attribute_of_cons at_attribute cons_args prop_class prop_type_heaps.th_attrs prop_attr_vars prop_attr_env prop_error prop_type_heaps & th_vars = th_vars, th_attrs = th_attrs ps & prop_attr_vars = prop_attr_vars, prop_td_infos = prop_td_infos, prop_attr_env = prop_attr_env, prop_type_heaps = prop_type_heaps, prop_error = prop_error | not (equal_attribute at_attribute at_attribute_r) = (True, {type & at_attribute = at_attribute_r}, prop_class, ps) = (False, type, prop_class, ps) add_propagation_attributes_to_AType modules type=:{at_type = TAS cons_id=:{type_index={glob_object,glob_module},type_ident} cons_args strictness, at_attribute} ps # (cons_args_m, cons_args_r, props, ps=:{prop_td_infos,prop_type_heaps,prop_attr_vars,prop_attr_env,prop_error}) = add_propagation_attributes_to_atypes modules cons_args ps (prop_class, th_vars, prop_td_infos) = propClassification glob_object glob_module props modules prop_type_heaps.th_vars prop_td_infos | cons_args_m # (at_attribute, prop_class, th_attrs, prop_attr_vars, prop_attr_env, prop_error) = determine_attribute_of_cons at_attribute cons_args_r prop_class prop_type_heaps.th_attrs prop_attr_vars prop_attr_env prop_error prop_type_heaps & th_vars = th_vars, th_attrs = th_attrs ps & prop_attr_vars = prop_attr_vars, prop_td_infos = prop_td_infos, prop_attr_env = prop_attr_env, prop_type_heaps = prop_type_heaps, prop_error = prop_error = (True, {type & at_type = TAS cons_id cons_args_r strictness, at_attribute = at_attribute}, prop_class, ps) # (at_attribute_r, prop_class, th_attrs, prop_attr_vars, prop_attr_env, prop_error) = determine_attribute_of_cons at_attribute cons_args prop_class prop_type_heaps.th_attrs prop_attr_vars prop_attr_env prop_error prop_type_heaps & th_vars = th_vars, th_attrs = th_attrs ps & prop_attr_vars = prop_attr_vars, prop_td_infos = prop_td_infos, prop_attr_env = prop_attr_env, prop_type_heaps = prop_type_heaps, prop_error = prop_error | not (equal_attribute at_attribute at_attribute_r) = (True, {type & at_attribute = at_attribute_r}, prop_class, ps) = (False, type, prop_class, ps) add_propagation_attributes_to_AType modules type=:{at_type} ps # (at_type_m, at_type_r, ps) = addPropagationAttributesToType modules at_type ps | at_type_m = (True, {type & at_type = at_type_r}, NoPropClass, ps) = (False, type, NoPropClass, ps) addPropagationAttributesToType :: {#CommonDefs} !Type !*PropState -> *(!Bool,!Type,!*PropState); addPropagationAttributesToType modules type=:(arg_type --> res_type) ps # (arg_type_m, arg_type_r, _, ps) = add_propagation_attributes_to_AType modules arg_type ps # (res_type_m, res_type_r, _, ps) = add_propagation_attributes_to_AType modules res_type ps | arg_type_m | res_type_m = (True, arg_type_r --> res_type_r, ps) = (True, arg_type_r --> res_type, ps) | res_type_m = (True, arg_type --> res_type_r, ps) = (False, type, ps) addPropagationAttributesToType modules type=:(type_var :@: types) ps # (types_m, types_r, ps) = add_propagation_attributes_to_ATypes modules types ps | types_m = (True, type_var :@: types_r, ps) = (False, type, ps) addPropagationAttributesToType modules type=:(TArrow1 arg_type) ps # (arg_type_m, arg_type_r, _, ps) = add_propagation_attributes_to_AType modules arg_type ps | arg_type_m = (True, TArrow1 arg_type_r, ps) = (False, type, ps) addPropagationAttributesToType modules type ps = (False, type, ps) add_propagation_attributes_to_atypes :: {#CommonDefs} ![AType] !*PropState -> (!Bool,![AType],[Int],!*PropState) add_propagation_attributes_to_atypes modules atypes=:[atype : atypes_t] ps # (atype_m, atype_r, prop_class, ps) = add_propagation_attributes_to_AType modules atype ps (atypes_t_m, atypes_t_r, prop_classes, ps) = add_propagation_attributes_to_atypes modules atypes_t ps prop_classes = [prop_class : prop_classes] | atype_m | atypes_t_m = (True, [atype_r : atypes_t_r], prop_classes, ps) = (True, [atype_r : atypes_t], prop_classes, ps) | atypes_t_m = (True, [atype : atypes_t_r], prop_classes, ps) = (False, atypes, prop_classes, ps) add_propagation_attributes_to_atypes modules [] ps = (False, [], [], ps) add_propagation_attributes_to_ATypes :: {#CommonDefs} ![AType] !*PropState -> (!Bool,![AType],!*PropState) add_propagation_attributes_to_ATypes modules atypes=:[atype : atypes_t] ps # (atype_m, atype_r, _, ps) = add_propagation_attributes_to_AType modules atype ps (atypes_t_m, atypes_t_r, ps) = add_propagation_attributes_to_ATypes modules atypes_t ps | atype_m | atypes_t_m = (True, [atype_r : atypes_t_r], ps) = (True, [atype_r : atypes_t], ps) | atypes_t_m = (True, [atype : atypes_t_r], ps) = (False, atypes, ps) add_propagation_attributes_to_ATypes modules [] ps = (False, [], ps) equal_attribute TA_Multi TA_Multi = True equal_attribute TA_Unique TA_Unique = True equal_attribute (TA_Var av1) (TA_Var av2) = av1.av_info_ptr == av2.av_info_ptr equal_attribute _ _ = False :: Base :== {! AType} currySymbolType st=:{tst_args,tst_arity,tst_result,tst_attr_env} req_arity ts=:{ts_attr_store} | tst_arity == req_arity = (st, ts) # (tst_args, rest_args, is_unique) = split_args req_arity tst_args | is_unique # (type, _, _) = buildCurriedType rest_args tst_result TA_Unique [] 0 = ({ st & tst_args = tst_args, tst_arity = req_arity, tst_result = type }, ts) # (type, tst_attr_env, ts_attr_store) = buildCurriedType rest_args tst_result (TA_TempVar ts_attr_store) (build_attr_env ts_attr_store tst_args tst_attr_env) (inc ts_attr_store) = ({ st & tst_args = tst_args, tst_arity = req_arity, tst_result = type, tst_attr_env = tst_attr_env }, { ts & ts_attr_store = ts_attr_store }) where split_args 0 args = ([], args, False) split_args n [atype=:{at_attribute} : args] # (left, right, is_unique) = split_args (dec n) args = ([ atype : left ], right, is_unique || attr_is_unique at_attribute) attr_is_unique TA_Unique = True attr_is_unique _ = False build_attr_env cum_attr_var [] attr_env = attr_env build_attr_env cum_attr_var [{at_attribute=(TA_TempVar attr_var)} : args] attr_env = build_attr_env cum_attr_var args [{ ac_demanded = attr_var, ac_offered = cum_attr_var } : attr_env] build_attr_env cum_attr_var [_ : args] attr_env = build_attr_env cum_attr_var args attr_env emptyIdent =: { id_name = "", id_info = nilPtr } buildCurriedType [] type cum_attr attr_env attr_store = (type, attr_env, attr_store) buildCurriedType [at=:{at_attribute}:ats] type cum_attr attr_env attr_store # (next_cum_attr, attr_env, attr_store) = combine_attributes at_attribute cum_attr attr_env attr_store (res_type, attr_env, attr_store) = buildCurriedType ats type next_cum_attr attr_env attr_store = ({at_attribute = cum_attr , at_type = at --> res_type }, attr_env, attr_store) where combine_attributes TA_Unique cum_attr attr_env attr_store = (TA_Unique, attr_env, attr_store) combine_attributes (TA_TempVar attr_var) (TA_TempVar cum_attr_var) attr_env attr_store = (TA_TempVar attr_store, [{ ac_demanded = cum_attr_var,ac_offered = attr_store },{ ac_demanded = attr_var,ac_offered = attr_store }:attr_env], inc attr_store) combine_attributes (TA_TempVar _) cum_attr attr_env attr_store = (cum_attr, attr_env, attr_store) combine_attributes _ (TA_TempVar cum_attr_var) attr_env attr_store = (TA_TempVar attr_store, [{ ac_demanded = cum_attr_var,ac_offered = attr_store }:attr_env], inc attr_store) combine_attributes _ cum_attr attr_env attr_store = (cum_attr, attr_env, attr_store) determineSymbolTypeOfFunction :: CoercionPosition Ident Int SymbolType (Ptr VarInfo) {#CommonDefs} *TypeState -> *(!TempSymbolType,!*TypeState); determineSymbolTypeOfFunction pos ident act_arity st=:{st_args,st_result,st_attr_vars,st_attr_env} type_ptr common_defs ts=:{ts_var_heap} # (type_info, ts_var_heap) = readPtr type_ptr ts_var_heap ts = {ts & ts_var_heap = ts_var_heap} = case type_info of VI_PropagationType symb_type # (copy_symb_type, ts) = freshSymbolType (Yes pos) cWithFreshContextVars symb_type common_defs ts -> currySymbolType copy_symb_type act_arity ts _ # (st_args, ps) = addPropagationAttributesToATypes common_defs st_args { prop_type_heaps = ts.ts_type_heaps, prop_td_infos = ts.ts_td_infos, prop_attr_vars = st_attr_vars, prop_attr_env = st_attr_env, prop_error = Yes ts.ts_error} (st_result, {prop_type_heaps,prop_td_infos,prop_attr_vars,prop_error = Yes ts_error,prop_attr_env}) = addPropagationAttributesToAType common_defs st_result ps st = { st & st_args = st_args, st_result = st_result, st_attr_vars = prop_attr_vars, st_attr_env = prop_attr_env } # (copy_symb_type, ts) = freshSymbolType (Yes pos) cWithFreshContextVars st common_defs { ts & ts_type_heaps = prop_type_heaps, ts_td_infos = prop_td_infos, ts_error = ts_error, ts_var_heap = ts.ts_var_heap <:= (type_ptr, VI_PropagationType st) } -> currySymbolType copy_symb_type act_arity ts standardFieldSelectorType pos {glob_object={ds_ident,ds_index},glob_module} {ti_common_defs} ts=:{ts_var_store,ts_attr_store,ts_type_heaps,ts_exis_variables} # (st=:{sd_type,sd_exi_vars}) = ti_common_defs.[glob_module].com_selector_defs.[ds_index] (new_exis_variables, ts_var_store, ts_attr_store, ts_type_heaps) = freshExistentialVariables sd_exi_vars ts_var_store ts_attr_store ts_type_heaps ts_exis_variables = addToExistentialVariables pos new_exis_variables ts_exis_variables ts = { ts & ts_type_heaps = ts_type_heaps, ts_var_store = ts_var_store, ts_attr_store = ts_attr_store, ts_exis_variables = ts_exis_variables } = freshSymbolType (Yes pos) cWithFreshContextVars sd_type ti_common_defs ts standardTupleSelectorType pos {ds_index} arg_nr {ti_common_defs} ts #! {cons_type} = ti_common_defs.[cPredefinedModuleIndex].com_cons_defs.[ds_index] = freshSymbolType (Yes pos) cWithFreshContextVars { cons_type & st_args = [cons_type.st_result], st_result = cons_type.st_args !! arg_nr } ti_common_defs ts standardRhsConstructorType pos index mod arity {ti_common_defs} ts # {cons_type=ct=:{st_vars,st_attr_vars}, cons_exi_vars } = ti_common_defs.[mod].com_cons_defs.[index] (st_vars, st_attr_vars) = foldSt add_vars_and_attr cons_exi_vars (st_vars, st_attr_vars) cons_type = { ct & st_vars = st_vars, st_attr_vars = st_attr_vars } (fresh_type, ts) = freshSymbolType (Yes pos) cWithFreshContextVars cons_type ti_common_defs ts = currySymbolType fresh_type arity ts where add_vars_and_attr {atv_variable, atv_attribute} (type_variables, attr_variables) = ([ atv_variable : type_variables ], add_attr_var atv_attribute attr_variables) add_attr_var (TA_Var avar) attr_variables = [ avar : attr_variables ] add_attr_var attr attr_variables = attr_variables standardLhsConstructorType pos index mod {ti_common_defs} ts=:{ts_var_store,ts_attr_store,ts_type_heaps,ts_exis_variables} # {cons_ident, cons_type, cons_exi_vars } = ti_common_defs.[mod].com_cons_defs.[index] (new_exis_variables, ts_var_store, ts_attr_store, ts_type_heaps) = freshExistentialVariables cons_exi_vars ts_var_store ts_attr_store ts_type_heaps ts_exis_variables = addToExistentialVariables pos new_exis_variables ts_exis_variables ts = { ts & ts_type_heaps = ts_type_heaps, ts_var_store = ts_var_store, ts_attr_store = ts_attr_store, ts_exis_variables = ts_exis_variables } = freshSymbolType No cWithFreshContextVars cons_type ti_common_defs ts :: ReferenceMarking :== Bool cIsRecursive :== True cIsNotRecursive :== False storeAttribute (Yes expt_ptr) type_attribute symbol_heap = symbol_heap <:= (expt_ptr, EI_Attribute (toInt type_attribute)) storeAttribute No type_attribute symbol_heap = symbol_heap getSymbolType :: CoercionPosition TypeInput SymbIdent Int *TypeState -> *(!TempSymbolType,![Special],!*TypeState); getSymbolType pos ti=:{ti_functions,ti_common_defs,ti_main_dcl_module_n} {symb_kind = SK_Function {glob_module,glob_object}, symb_ident} n_app_args ts | glob_module == ti_main_dcl_module_n | glob_object>=size ts.ts_fun_env = abort symb_ident.id_name; # (fun_type, ts) = ts!ts_fun_env.[glob_object] = case fun_type of UncheckedType fun_type # (fun_type_copy, ts) = currySymbolType fun_type n_app_args ts -> (fun_type_copy, [], ts) SpecifiedType fun_type lifted_arg_types _ # (fun_type_copy=:{tst_args,tst_arity}, ts) = freshSymbolType (Yes pos) cWithoutFreshContextVars fun_type ti_common_defs ts (fun_type_copy, ts) = currySymbolType { fun_type_copy & tst_args = lifted_arg_types ++ fun_type_copy.tst_args, tst_arity = tst_arity + length lifted_arg_types } n_app_args ts -> (fun_type_copy, [], ts) CheckedType fun_type # (fun_type_copy, ts) = freshSymbolType (Yes pos) cWithFreshContextVars fun_type ti_common_defs ts (fun_type_copy,ts) = currySymbolType fun_type_copy n_app_args ts -> (fun_type_copy, [], ts) _ -> abort ("getSymbolType: SK_Function "+++toString symb_ident+++" "+++toString glob_object) // -> abort "getSymbolType (type.icl)" ---> (symb_ident, glob_object, fun_type) # {ft_type,ft_type_ptr,ft_specials} = ti_functions.[glob_module].[glob_object] | glob_module>=size ti_functions || glob_object>=size ti_functions.[glob_module] = abort (toString glob_module+++" "+++toString glob_object+++" "+++toString ti_main_dcl_module_n+++" "+++symb_ident.id_name); # (fun_type_copy, ts) = determineSymbolTypeOfFunction pos symb_ident n_app_args ft_type ft_type_ptr ti_common_defs ts = (fun_type_copy, get_specials ft_specials, ts) where get_specials (FSP_ContextTypes specials) = specials get_specials FSP_None = [] getSymbolType pos ti {symb_kind = SK_Constructor {glob_module,glob_object}} n_app_args ts # (fresh_cons_type, ts) = standardRhsConstructorType pos glob_object glob_module n_app_args ti ts = (fresh_cons_type, [], ts) getSymbolType pos ti {symb_kind = SK_NewTypeConstructor {gi_module,gi_index}} n_app_args ts # (fresh_cons_type, ts) = standardRhsConstructorType pos gi_index gi_module n_app_args ti ts = (fresh_cons_type, [], ts) getSymbolType pos ti=:{ti_functions,ti_common_defs,ti_main_dcl_module_n} {symb_kind = SK_LocalMacroFunction glob_object, symb_ident} n_app_args ts | glob_object>=size ts.ts_fun_env = abort symb_ident.id_name; # (fun_type, ts) = ts!ts_fun_env.[glob_object] = case fun_type of UncheckedType fun_type # (fun_type_copy, ts) = currySymbolType fun_type n_app_args ts -> (fun_type_copy, [], ts) SpecifiedType fun_type lifted_arg_types _ # (fun_type_copy=:{tst_args,tst_arity}, ts) = freshSymbolType (Yes pos) cWithoutFreshContextVars fun_type ti_common_defs ts (fun_type_copy, ts) = currySymbolType { fun_type_copy & tst_args = lifted_arg_types ++ fun_type_copy.tst_args, tst_arity = tst_arity + length lifted_arg_types } n_app_args ts -> (fun_type_copy, [], ts) CheckedType fun_type # (fun_type_copy, ts) = freshSymbolType (Yes pos) cWithFreshContextVars fun_type ti_common_defs ts (fun_type_copy,ts) = currySymbolType fun_type_copy n_app_args ts -> (fun_type_copy, [], ts) _ -> abort ("getSymbolType SK_LocalMacroFunction: "+++toString symb_ident+++" " +++toString glob_object) // -> abort "getSymbolType (type.icl)" ---> (symb_ident, glob_object, fun_type) getSymbolType pos ti=:{ti_common_defs} {symb_kind = SK_OverloadedFunction {glob_module,glob_object}} n_app_args ts # {me_ident, me_type,me_type_ptr} = ti_common_defs.[glob_module].com_member_defs.[glob_object] (fun_type_copy, ts) = determineSymbolTypeOfFunction pos me_ident n_app_args me_type me_type_ptr ti_common_defs ts = (fun_type_copy, [], ts) getSymbolType pos ti=:{ti_common_defs} symbol=:{symb_ident, symb_kind = SK_Generic gen_glob kind} n_app_args ts # (opt_member_glob, ts_generic_heap) = getGenericMember gen_glob kind ti_common_defs ts.ts_generic_heap # ts = { ts & ts_generic_heap = ts_generic_heap } = case opt_member_glob of No # empty_atype={at_type=TE,at_attribute=TA_Multi} t_args=[empty_atype \\ _ <- [1..n_app_args]] empty_tst = {tst_args=t_args, tst_arity=n_app_args, tst_lifted=0, tst_result=empty_atype, tst_context=[], tst_var_contexts=NoVarContexts, tst_attr_env=[]} ts_error = checkError ("no generic instances of " +++ toString symb_ident +++ " for kind") kind ts.ts_error -> (empty_tst, [], {ts & ts_error = ts_error}) Yes member_glob -> getSymbolType pos ti {symbol & symb_kind = SK_OverloadedFunction member_glob} n_app_args ts class requirements a :: !TypeInput !a !(!u:Requirements, !*TypeState) -> (!AType, !Optional ExprInfoPtr, !(!u:Requirements, !*TypeState)) instance requirements BoundVar where requirements ti {var_ident,var_info_ptr,var_expr_ptr} (reqs, ts) # (var_info, ts_var_heap) = readPtr var_info_ptr ts.ts_var_heap ts = {ts & ts_var_heap = ts_var_heap} = case var_info of VI_Type type _ -> (type, Yes var_expr_ptr, (reqs, ts)) VI_FAType vars type _ # ts = bind_vars_and_attrs vars ts (fresh_type, ts_type_heaps) = freshCopy type ts.ts_type_heaps ts_type_heaps = clear_vars_and_attrs vars ts_type_heaps -> (fresh_type, Yes var_expr_ptr, (reqs, {ts & ts_type_heaps = ts_type_heaps})) VI_FATypeC vars type contexts _ # ts = bind_vars_and_attrs vars ts (fresh_type, ts_type_heaps) = freshCopy type ts.ts_type_heaps (contexts,(ts_type_heaps,ts_var_heap)) = freshTypeContexts True contexts (ts_type_heaps,ts.ts_var_heap) ts_type_heaps = clear_vars_and_attrs vars ts_type_heaps {ts_expr_heap} = ts (new_var_expr_ptr,ts_expr_heap) = newPtr EI_Empty ts_expr_heap reqs = {reqs & req_overloaded_calls = [var_expr_ptr : reqs.req_overloaded_calls]} symbol = {symb_ident=var_ident,symb_kind=SK_TFACVar new_var_expr_ptr} ts_expr_heap = ts_expr_heap <:= (var_expr_ptr,EI_Overloaded {oc_symbol=symbol,oc_context=contexts,oc_specials=[]}) ts = {ts & ts_type_heaps=ts_type_heaps,ts_expr_heap=ts_expr_heap,ts_var_heap=ts_var_heap} -> (fresh_type, Yes new_var_expr_ptr, (reqs, ts)) _ -> abort "requirements BoundVar " // ---> (var_ident <<- var_info)) where bind_vars_and_attrs vars ts = foldSt bind_var_and_attr vars ts where bind_var_and_attr {atv_attribute, atv_variable = {tv_info_ptr}} ts=:{ts_var_store, ts_attr_store, ts_type_heaps} # (ts_attr_store, th_attrs) = bind_attr atv_attribute (ts_attr_store, ts_type_heaps.th_attrs) = { ts & ts_var_store = inc ts_var_store, ts_attr_store = ts_attr_store, ts_type_heaps = { ts_type_heaps & th_vars = ts_type_heaps.th_vars <:= (tv_info_ptr, TVI_Type (TempV ts_var_store)), th_attrs = th_attrs }} bind_attr (TA_Var {av_info_ptr}) (attr_store, attr_heap) = (inc attr_store, attr_heap <:= (av_info_ptr, AVI_Attr (TA_TempVar attr_store))) bind_attr attr attr_heap = attr_heap clear_vars_and_attrs vars ts_type_heaps = foldSt clear_var_and_attr vars ts_type_heaps where clear_var_and_attr {atv_attribute, atv_variable = {tv_info_ptr}} th=:{th_vars,th_attrs} # th_attrs = clear_attr atv_attribute th_attrs = { th & th_vars = th_vars <:= (tv_info_ptr, TVI_Empty), th_attrs = th_attrs } clear_attr (TA_Var {av_info_ptr}) attr_heap = attr_heap <:= (av_info_ptr, AVI_Empty) clear_attr attr attr_heap = attr_heap instance requirements App where requirements ti app=:{app_symb,app_args,app_info_ptr} (reqs=:{req_attr_coercions}, ts) # ({tst_attr_env,tst_args,tst_result,tst_context,tst_var_contexts}, specials, ts) = getSymbolType (CP_Expression (App app)) ti app_symb (length app_args) ts reqs = {reqs & req_attr_coercions = tst_attr_env ++ req_attr_coercions} (n_lifted_arguments,fun_args,ts) = get_n_lifted_arguments app_symb.symb_kind ti.ti_main_dcl_module_n ts (reqs, ts) = requirements_of_lifted_and_normal_args ti app_symb (1-n_lifted_arguments) fun_args app_args tst_args (reqs, ts) | case tst_var_contexts of NoVarContexts -> True; _ -> False | isEmpty tst_context = (tst_result, No, (reqs, ts)) # app_info = EI_Overloaded {oc_symbol=app_symb, oc_context=tst_context, oc_specials=specials} = (tst_result, No, ({reqs & req_overloaded_calls = [app_info_ptr : reqs.req_overloaded_calls]}, {ts & ts_expr_heap = ts.ts_expr_heap <:= (app_info_ptr,app_info)})) // special not yet implemented # app_info = EI_OverloadedWithVarContexts {ocvc_symbol=app_symb, ocvc_context=tst_context, ocvc_var_contexts=tst_var_contexts} = (tst_result, No, ({reqs & req_overloaded_calls = [app_info_ptr : reqs.req_overloaded_calls]}, {ts & ts_expr_heap = ts.ts_expr_heap <:= (app_info_ptr,app_info)})) where get_n_lifted_arguments :: !SymbKind !Int !*TypeState -> (!Int,![FreeVar],!*TypeState) get_n_lifted_arguments (SK_Function {glob_module,glob_object}) main_dcl_module_n ts | glob_module == main_dcl_module_n # ({fun_lifted,fun_body=TransformedBody {tb_args}},ts) = ts!ts_fun_defs.[glob_object] = (fun_lifted,tb_args,ts) = (0,[],ts) get_n_lifted_arguments (SK_LocalMacroFunction glob_object) _ ts # ({fun_lifted,fun_body=TransformedBody {tb_args}},ts) = ts!ts_fun_defs.[glob_object] = (fun_lifted,tb_args,ts) get_n_lifted_arguments _ _ ts = (0,[],ts) requirements_of_lifted_and_normal_args :: !TypeInput SymbIdent !Int ![FreeVar] ![Expression] ![AType] !(!u:Requirements, !*TypeState) -> (!u:Requirements, !*TypeState) requirements_of_lifted_and_normal_args ti fun_ident arg_nr _ exprs lts reqs_ts | arg_nr>0 = requirements_of_args ti fun_ident arg_nr exprs lts reqs_ts requirements_of_lifted_and_normal_args ti fun_ident arg_nr [{fv_ident}:fun_args] [expr:exprs] [lt:lts] reqs_ts # (e_type, opt_expr_ptr, (reqs, ts)) = requirements ti expr reqs_ts #! type_coercion = {tc_demanded = lt, tc_offered = e_type, tc_position = CP_LiftedFunArg fun_ident.symb_ident fv_ident, tc_coercible = True} # req_type_coercions = [type_coercion : reqs.req_type_coercions] ts_expr_heap = storeAttribute opt_expr_ptr lt.at_attribute ts.ts_expr_heap = requirements_of_lifted_and_normal_args ti fun_ident (arg_nr+1) fun_args exprs lts ({reqs & req_type_coercions = req_type_coercions}, {ts & ts_expr_heap = ts_expr_heap}) requirements_of_args :: !TypeInput SymbIdent !Int ![Expression] ![AType] !(!u:Requirements, !*TypeState) -> (!u:Requirements, !*TypeState) requirements_of_args ti _ _ [] [] reqs_ts = reqs_ts requirements_of_args ti fun_ident arg_nr [expr:exprs] [lt:lts] reqs_ts # (e_type, opt_expr_ptr, (reqs, ts)) = requirements ti expr reqs_ts #! type_coercion = {tc_demanded = lt, tc_offered = e_type, tc_position = CP_SymbArgAndExpression fun_ident arg_nr expr, tc_coercible = True} # req_type_coercions = [type_coercion : reqs.req_type_coercions] ts_expr_heap = storeAttribute opt_expr_ptr lt.at_attribute ts.ts_expr_heap = requirements_of_args ti fun_ident (arg_nr+1) exprs lts ({reqs & req_type_coercions = req_type_coercions}, {ts & ts_expr_heap = ts_expr_heap}) instance requirements Case where requirements ti {case_expr,case_guards,case_default,case_info_ptr,case_default_pos} reqs_ts # (expr_type, opt_expr_ptr, (reqs, ts)) = requirements ti case_expr reqs_ts (fresh_v, ts) = freshAttributedVariable ts (case_info, reqs_ts) = requirements_of_guarded_expressions case_guards case_expr case_info_ptr ti expr_type opt_expr_ptr fresh_v reqs ts (reqs, ts) = requirements_of_default ti case_default case_default_pos fresh_v reqs_ts ts = {ts & ts_expr_heap = ts.ts_expr_heap <:= (case_info_ptr, case_info)} = (fresh_v, No, ({reqs & req_case_and_let_exprs = [case_info_ptr : reqs.req_case_and_let_exprs]}, ts)) where requirements_of_guarded_expressions (AlgebraicPatterns alg_type patterns) match_expr case_info_ptr ti=:{ti_common_defs} pattern_type opt_pattern_ptr goal_type reqs ts # (cons_types, result_type, new_attr_env,constructor_contexts,td_rhs,ts) = freshAlgebraicType alg_type patterns ti_common_defs ts ts_var_heap = update_case_variable match_expr td_rhs cons_types alg_type ts.ts_var_heap (used_cons_types, (reqs, ts)) = requirements_of_algebraic_patterns ti patterns cons_types goal_type [] (reqs, {ts & ts_var_heap = ts_var_heap}) ts_expr_heap = storeAttribute opt_pattern_ptr result_type.at_attribute ts.ts_expr_heap (position, ts_var_heap) = getPositionOfExpr match_expr ts.ts_var_heap reqs = {reqs & req_type_coercions = [{tc_demanded = result_type,tc_offered = pattern_type, tc_position = position, tc_coercible = True} : reqs.req_type_coercions], req_attr_coercions = new_attr_env ++ reqs.req_attr_coercions} | isEmpty constructor_contexts # case_info = EI_CaseType {ct_pattern_type = pattern_type, ct_result_type = goal_type, ct_cons_types = reverse used_cons_types} = (case_info, (reqs, {ts & ts_expr_heap = ts_expr_heap, ts_var_heap = ts_var_heap})) # (constructor_contexts,ts_var_heap) = create_fresh_context_vars constructor_contexts ts_var_heap case_info = EI_CaseTypeWithContexts {ct_pattern_type = pattern_type, ct_result_type = goal_type, ct_cons_types = reverse used_cons_types} constructor_contexts reqs = {reqs & req_overloaded_calls = [case_info_ptr : reqs.req_overloaded_calls]} = (case_info, (reqs, {ts & ts_expr_heap = ts_expr_heap, ts_var_heap = ts_var_heap})) requirements_of_guarded_expressions (BasicPatterns bas_type patterns) match_expr case_info_ptr ti pattern_type opt_pattern_ptr goal_type reqs ts # (attr_bas_type, ts) = attributedBasicType bas_type ts (reqs, ts) = requirements_of_basic_patterns ti patterns goal_type (reqs, ts) ts_expr_heap = storeAttribute opt_pattern_ptr attr_bas_type.at_attribute ts.ts_expr_heap reqs = {reqs & req_type_coercions = [{tc_demanded = attr_bas_type,tc_offered = pattern_type, tc_position = CP_Expression match_expr, tc_coercible = True} : reqs.req_type_coercions]} case_info = EI_CaseType {ct_pattern_type = pattern_type, ct_result_type = goal_type, ct_cons_types = []} = (case_info, (reqs, {ts & ts_expr_heap = ts_expr_heap})) requirements_of_guarded_expressions (OverloadedListPatterns alg_type decons_expr=:(App {app_symb,app_info_ptr}) patterns) match_expr case_info_ptr ti=:{ti_common_defs,ti_functions} pattern_type opt_pattern_ptr goal_type reqs ts # (position, ts_var_heap) = getPositionOfExpr match_expr ts.ts_var_heap # ts = {ts & ts_var_heap = ts_var_heap} # (cons_types, result_type, context, new_attr_env, ts) = freshOverloadedListType alg_type position patterns ti_common_defs ti_functions ts (used_cons_types, (reqs, ts)) = requirements_of_algebraic_patterns ti patterns cons_types goal_type [] (reqs, ts) ts_expr_heap = storeAttribute opt_pattern_ptr result_type.at_attribute ts.ts_expr_heap type_coercions = [{tc_demanded = result_type,tc_offered = pattern_type, tc_position = position,tc_coercible = True} : reqs.req_type_coercions] ts_expr_heap = writePtr app_info_ptr (EI_Overloaded {oc_symbol = app_symb, oc_context = context, oc_specials = []/*specials*/ }) ts_expr_heap reqs = {reqs & req_type_coercions = type_coercions,req_attr_coercions = new_attr_env ++ reqs.req_attr_coercions, req_overloaded_calls = [app_info_ptr : reqs.req_overloaded_calls]} case_info = EI_CaseType {ct_pattern_type = pattern_type, ct_result_type = goal_type, ct_cons_types = reverse used_cons_types} = (case_info,(reqs,{ts & ts_expr_heap = ts_expr_heap})) requirements_of_guarded_expressions (NewTypePatterns alg_type patterns) match_expr case_info_ptr ti=:{ti_common_defs} pattern_type opt_pattern_ptr goal_type reqs ts # (cons_types, result_type, new_attr_env,constructor_contexts,td_rhs,ts) = freshAlgebraicType alg_type patterns ti_common_defs ts ts_var_heap = update_case_variable match_expr td_rhs cons_types alg_type ts.ts_var_heap (used_cons_types, (reqs, ts)) = requirements_of_algebraic_patterns ti patterns cons_types goal_type [] (reqs, { ts & ts_var_heap = ts_var_heap } ) ts_expr_heap = storeAttribute opt_pattern_ptr result_type.at_attribute ts.ts_expr_heap (position, ts_var_heap) = getPositionOfExpr match_expr ts.ts_var_heap reqs = {reqs & req_type_coercions = [{tc_demanded = result_type,tc_offered = pattern_type, tc_position = position, tc_coercible = True} : reqs.req_type_coercions], req_attr_coercions = new_attr_env ++ reqs.req_attr_coercions} case_info = EI_CaseType {ct_pattern_type = pattern_type, ct_result_type = goal_type, ct_cons_types = reverse used_cons_types} = (case_info, (reqs, { ts & ts_expr_heap = ts_expr_heap, ts_var_heap = ts_var_heap })) requirements_of_guarded_expressions (DynamicPatterns dynamic_patterns) match_expr case_info_ptr ti pattern_type opt_pattern_ptr goal_type reqs ts # dyn_type = { at_type = TB BT_Dynamic, at_attribute = TA_Multi } (used_dyn_types, (reqs, ts)) = requirements_of_dynamic_patterns ti goal_type dynamic_patterns [] (reqs,ts) ts_expr_heap = storeAttribute opt_pattern_ptr TA_Multi ts.ts_expr_heap reqs = {reqs & req_type_coercions = [{tc_demanded = dyn_type, tc_offered = pattern_type, tc_position = CP_Expression match_expr, tc_coercible = True} : reqs.req_type_coercions]} case_info = EI_CaseType {ct_pattern_type = pattern_type, ct_result_type = goal_type, ct_cons_types = reverse used_dyn_types} = (case_info, (reqs, { ts & ts_expr_heap = ts_expr_heap })) requirements_of_algebraic_patterns ti [] cons_types goal_type used_cons_types reqs_ts = (used_cons_types, reqs_ts) requirements_of_algebraic_patterns ti [alg_pattern=:{ap_position}:alg_patterns] [cons_arg_types : cons_types] goal_type used_cons_types reqs_ts = requirements_of_algebraic_patterns ti alg_patterns cons_types goal_type [cons_arg_types : used_cons_types] (possibly_accumulate_reqs_in_new_group ap_position (requirements_of_algebraic_pattern ti alg_pattern cons_arg_types goal_type) reqs_ts ) where requirements_of_algebraic_pattern ti {ap_symbol, ap_vars, ap_expr} cons_arg_types goal_type (reqs, ts) # var_heap = makeBase ap_symbol.glob_object.ds_ident ap_vars cons_arg_types ts.ts_var_heap (res_type, opt_expr_ptr, (reqs, ts)) = requirements ti ap_expr (reqs, {ts & ts_var_heap = var_heap}) ts_expr_heap = storeAttribute opt_expr_ptr res_type.at_attribute ts.ts_expr_heap = ({reqs & req_type_coercions = [ { tc_demanded = goal_type, tc_offered = res_type, tc_position = CP_Expression ap_expr, tc_coercible = True } : reqs.req_type_coercions]}, {ts & ts_expr_heap = ts_expr_heap}) requirements_of_basic_patterns _ [] goal_type reqs_ts = reqs_ts requirements_of_basic_patterns ti [{bp_expr, bp_position}:gs] goal_type reqs_ts = requirements_of_basic_patterns ti gs goal_type (possibly_accumulate_reqs_in_new_group bp_position (requirements_of_basic_pattern ti bp_expr goal_type) reqs_ts ) requirements_of_basic_pattern ti bp_expr goal_type reqs_ts # (res_type, opt_expr_ptr, (reqs, ts)) = requirements ti bp_expr reqs_ts ts_expr_heap = storeAttribute opt_expr_ptr res_type.at_attribute ts.ts_expr_heap = ({ reqs & req_type_coercions = [ { tc_demanded = goal_type, tc_offered = res_type, tc_position = CP_Expression bp_expr, tc_coercible = True } : reqs.req_type_coercions] }, { ts & ts_expr_heap = ts_expr_heap }) requirements_of_dynamic_patterns ti goal_type [] used_dyn_types reqs_ts = (used_dyn_types, reqs_ts) requirements_of_dynamic_patterns ti goal_type [dp=:{dp_position, dp_type} : dps] used_dyn_types (reqs, ts=:{ts_expr_heap}) # (EI_TempDynamicPattern _ _ _ _ dyn_type dyn_context dyn_expr_ptr type_code_symbol, ts_expr_heap) = readPtr dp_type ts_expr_heap (reqs_ts) = possibly_accumulate_reqs_in_new_group dp_position (requirements_of_dynamic_pattern dyn_type dyn_context dyn_expr_ptr type_code_symbol ti goal_type dp) (reqs, { ts & ts_expr_heap = ts_expr_heap}) = requirements_of_dynamic_patterns ti goal_type dps [ [dyn_type] : used_dyn_types ] reqs_ts requirements_of_dynamic_pattern dyn_type dyn_context dyn_expr_ptr type_code_symbol ti goal_type {dp_var={fv_info_ptr},dp_rhs} (reqs, ts=:{ts_expr_heap, ts_var_heap}) # ts_var_heap = addToBase fv_info_ptr dyn_type VITI_Empty ts_var_heap (dp_rhs_type, opt_expr_ptr, (reqs, ts)) = requirements ti dp_rhs (reqs, { ts & ts_expr_heap = ts_expr_heap, ts_var_heap = ts_var_heap }) ts_expr_heap = storeAttribute opt_expr_ptr dp_rhs_type.at_attribute ts.ts_expr_heap type_coercion = { tc_demanded = goal_type, tc_offered = dp_rhs_type, tc_position = CP_Expression dp_rhs, tc_coercible = True } | isEmpty dyn_context # reqs = {reqs & req_type_coercions = [ type_coercion : reqs.req_type_coercions]} = (reqs, { ts & ts_expr_heap = ts_expr_heap }) # reqs = { reqs & req_type_coercions = [ type_coercion : reqs.req_type_coercions], req_overloaded_calls = [dyn_expr_ptr : reqs.req_overloaded_calls ]} = (reqs, { ts & ts_expr_heap = ts_expr_heap <:= (dyn_expr_ptr, EI_Overloaded {oc_symbol = type_code_symbol, oc_context = dyn_context, oc_specials = []})}) requirements_of_default ti (Yes expr) case_default_pos goal_type reqs_ts = possibly_accumulate_reqs_in_new_group case_default_pos (reqs_of_default ti expr goal_type) reqs_ts requirements_of_default ti No _ goal_type reqs_ts = reqs_ts reqs_of_default ti expr goal_type reqs_ts # (res_type, opt_expr_ptr, (reqs, ts)) = requirements ti expr reqs_ts ts_expr_heap = storeAttribute opt_expr_ptr res_type.at_attribute ts.ts_expr_heap = ({ reqs & req_type_coercions = [ { tc_demanded = goal_type, tc_offered = res_type, tc_position = CP_Expression expr, tc_coercible = True } : reqs.req_type_coercions] }, { ts & ts_expr_heap = ts_expr_heap }) update_case_variable (Var {var_ident,var_info_ptr}) (RecordType {rt_constructor={ds_index}}) [cons_type] {gi_module} var_heap # (var_info, var_heap) = readPtr var_info_ptr var_heap = case var_info of VI_Type type type_info -> var_heap <:= (var_info_ptr, VI_Type type (VITI_PatternType cons_type gi_module ds_index type_info)) VI_FAType vars type type_info -> var_heap <:= (var_info_ptr, VI_FAType vars type (VITI_PatternType cons_type gi_module ds_index type_info)) _ -> abort "update_case_variable" // ---> (var_ident <<- var_info)) update_case_variable expr td_rhs cons_types alg_type var_heap = var_heap instance requirements Let where requirements ti {let_lazy_binds, let_strict_binds, let_expr, let_info_ptr, let_expr_position } (reqs, ts) # let_binds = let_strict_binds ++ let_lazy_binds (rev_var_types, ts) = make_base let_binds [] ts var_types = reverse rev_var_types (reqs, ts) = requirements_of_binds let_binds var_types NoPos [] reqs ts (res_type, opt_expr_ptr, (reqs, ts)) = requirements_of_let_expr let_expr_position ti let_expr (reqs, ts) ts_expr_heap = writePtr let_info_ptr (EI_LetType var_types) ts.ts_expr_heap = (res_type, opt_expr_ptr, ({reqs & req_case_and_let_exprs = [let_info_ptr : reqs.req_case_and_let_exprs]},{ts & ts_expr_heap = ts_expr_heap})) where make_base [{lb_src, lb_dst={fv_ident, fv_info_ptr}}:bs] var_types ts=:{ts_var_heap} # (v, ts) = freshAttributedVariable ts optional_position = if (is_rare_name fv_ident) (VITI_Coercion (CP_Expression lb_src)) VITI_Empty = make_base bs [v:var_types] { ts & ts_var_heap = writePtr fv_info_ptr (VI_Type v optional_position) ts.ts_var_heap } make_base [] var_types ts = (var_types, ts) requirements_of_binds [] bts last_position new_type_coercions reqs ts # reqs=add_new_group last_position new_type_coercions reqs = (reqs,ts) requirements_of_binds [{lb_src, lb_position}:bs] [b_type:bts] last_position new_type_coercions reqs ts | is_same_position lb_position last_position # (new_type_coercions,reqs,ts) = add_requirements_of_bind_to_group lb_src b_type new_type_coercions reqs ts = requirements_of_binds bs bts last_position new_type_coercions reqs ts # reqs=add_new_group last_position new_type_coercions reqs # new_type_coercions=[] # (new_type_coercions,reqs,ts) = add_requirements_of_bind_to_group_or_list lb_position lb_src b_type new_type_coercions reqs ts = requirements_of_binds bs bts lb_position new_type_coercions reqs ts where is_same_position (LinePos _ line_nr1) (LinePos _ line_nr2) = line_nr1==line_nr2 is_same_position (FunPos _ line_nr1 _) (FunPos _ line_nr2 _) = line_nr1==line_nr2 is_same_position _ _ = False add_requirements_of_bind_to_group_or_list NoPos lb_src b_type new_type_coercions reqs ts # (reqs,ts) = requirements_of_bind b_type ti lb_src (reqs,ts) = (new_type_coercions,reqs,ts) add_requirements_of_bind_to_group_or_list _ lb_src b_type new_type_coercions reqs ts = add_requirements_of_bind_to_group lb_src b_type new_type_coercions reqs ts add_requirements_of_bind_to_group lb_src b_type new_type_coercions reqs ts # old_req_type_coercions=reqs.req_type_coercions # reqs = {reqs & req_type_coercions=new_type_coercions} # (reqs,ts) = requirements_of_bind b_type ti lb_src (reqs,ts) # new_type_coercions=reqs.req_type_coercions # reqs = {reqs & req_type_coercions=old_req_type_coercions} = (new_type_coercions,reqs,ts) requirements_of_bind b_type ti lb_src reqs_ts # (exp_type, opt_expr_ptr, (reqs, ts)) = requirements ti lb_src reqs_ts ts_expr_heap = storeAttribute opt_expr_ptr b_type.at_attribute ts.ts_expr_heap req_type_coercions = [ { tc_demanded = b_type, tc_offered = exp_type, tc_position = CP_Expression lb_src, tc_coercible = True } : reqs.req_type_coercions ] = ({ reqs & req_type_coercions = req_type_coercions }, { ts & ts_expr_heap = ts_expr_heap }) add_new_group position [] reqs = reqs add_new_group position new_type_coercions reqs = { reqs & req_type_coercion_groups = [{ tcg_type_coercions = new_type_coercions, tcg_position = position } : reqs.req_type_coercion_groups]} requirements_of_let_expr NoPos ti let_expr reqs_ts = requirements ti let_expr reqs_ts requirements_of_let_expr let_expr_position ti let_expr (reqs=:{req_type_coercions=old_req_type_coercions}, ts) # reqs_with_empty_accu = { reqs & req_type_coercions = [] } (res_type, opt_expr_ptr, (reqs_with_new_group_in_accu, ts)) = requirements ti let_expr (reqs_with_empty_accu, ts) new_group = { tcg_type_coercions = reqs_with_new_group_in_accu.req_type_coercions, tcg_position = let_expr_position } reqs_with_new_group = { reqs_with_new_group_in_accu & req_type_coercion_groups = [new_group:reqs_with_new_group_in_accu.req_type_coercion_groups], req_type_coercions = old_req_type_coercions } = (res_type, opt_expr_ptr, (reqs_with_new_group, ts)) instance requirements DynamicExpr where requirements ti {dyn_expr,dyn_info_ptr} (reqs, ts=:{ts_expr_heap}) # (EI_TempDynamicType _ _ dyn_type dyn_context univ_contexts dyn_expr_ptr type_code_symbol, ts_expr_heap) = readPtr dyn_info_ptr ts_expr_heap (dyn_expr_type, opt_expr_ptr, (reqs, ts)) = requirements ti dyn_expr (reqs, { ts & ts_expr_heap = ts_expr_heap }) ts_expr_heap = storeAttribute opt_expr_ptr dyn_expr_type.at_attribute ts.ts_expr_heap type_coercion = { tc_demanded = dyn_type, tc_offered = dyn_expr_type, tc_position = CP_Expression dyn_expr, tc_coercible = True } atype = {at_type = TB BT_Dynamic, at_attribute = TA_Multi} type_coercions = [type_coercion : reqs.req_type_coercions] | isEmpty dyn_context | isEmpty univ_contexts = (atype, No, ({reqs & req_type_coercions = type_coercions}, {ts & ts_expr_heap = ts_expr_heap})) # var_contexts = VarContext 0 univ_contexts dyn_expr_type NoVarContexts # dyn_expr_info = EI_OverloadedWithVarContexts {ocvc_symbol=type_code_symbol, ocvc_context=dyn_context, ocvc_var_contexts=var_contexts} = (atype, No, ({reqs & req_type_coercions = type_coercions, req_overloaded_calls = [dyn_expr_ptr : reqs.req_overloaded_calls]}, {ts & ts_expr_heap = ts_expr_heap <:= (dyn_expr_ptr, dyn_expr_info)})) | isEmpty univ_contexts # dyn_expr_info = EI_Overloaded {oc_symbol = type_code_symbol, oc_context = dyn_context, oc_specials = []} = (atype, No, ({reqs & req_type_coercions = type_coercions, req_overloaded_calls = [dyn_expr_ptr : reqs.req_overloaded_calls]}, {ts & ts_expr_heap = ts_expr_heap <:= (dyn_expr_ptr, dyn_expr_info)})) # var_contexts = VarContext 0 univ_contexts dyn_expr_type NoVarContexts # dyn_expr_info = EI_OverloadedWithVarContexts {ocvc_symbol=type_code_symbol, ocvc_context=dyn_context, ocvc_var_contexts=var_contexts} = (atype, No, ({reqs & req_type_coercions = type_coercions, req_overloaded_calls = [dyn_expr_ptr : reqs.req_overloaded_calls]}, {ts & ts_expr_heap = ts_expr_heap <:= (dyn_expr_ptr, dyn_expr_info)})) instance requirements Expression where requirements ti (Var var) reqs_ts = requirements ti var reqs_ts requirements ti (App app) reqs_ts = requirements ti app reqs_ts requirements ti (function @ args) reqs_ts # (off_fun_type, opt_fun_expr_ptr, reqs_ts) = requirements ti function reqs_ts (rev_off_arg_types, (reqs, ts)) = requirements_of_list ti args [] reqs_ts (alpha, ts) = freshAttributedVariable ts (fun_type, req_type_coercions, ts) = apply_type rev_off_arg_types alpha reqs.req_type_coercions function ts ts_expr_heap = storeAttribute opt_fun_expr_ptr fun_type.at_attribute ts.ts_expr_heap = (alpha, No, ({ reqs & req_type_coercions = [{ tc_demanded = fun_type, tc_offered = off_fun_type, tc_position = CP_Expression function, tc_coercible = True } : req_type_coercions ]}, { ts & ts_expr_heap = ts_expr_heap })) where requirements_of_list _ [] rev_list_types reqs_ts = (rev_list_types, reqs_ts) requirements_of_list ti [expr:exprs] rev_list_types reqs_ts # (e_type, opt_expr_ptr, reqs_ts) = requirements ti expr reqs_ts = requirements_of_list ti exprs [(opt_expr_ptr,e_type) : rev_list_types] reqs_ts apply_type [] res_type type_coercions function ts = (res_type, type_coercions, ts) apply_type [(opt_expr_ptr,type) : types] res_type type_coercions function ts # (type, type_coercions, ts) = determine_demanded_type type opt_expr_ptr type_coercions function ts (u, ts) = freshAttribute ts = apply_type types { at_attribute = u, at_type = type --> res_type } type_coercions function ts determine_demanded_type :: !AType !(Optional ExprInfoPtr) ![TypeCoercion] !Expression !*TypeState -> (!AType, ![TypeCoercion], !*TypeState) determine_demanded_type type (Yes expr_ptr) type_coercions expr ts # (dem_type, ts) = freshAttributedVariable ts ts_expr_heap = writePtr expr_ptr (EI_Attribute (toInt dem_type.at_attribute)) ts.ts_expr_heap = (dem_type, [ { tc_demanded = dem_type, tc_offered = type, tc_position = CP_Expression expr, tc_coercible = True } : type_coercions ], { ts & ts_expr_heap = ts_expr_heap }) determine_demanded_type type No type_coercions expr ts = (type, type_coercions, ts) requirements ti (Case kees) reqs_ts = requirements ti kees reqs_ts requirements ti (Let lad) reqs_ts = requirements ti lad reqs_ts requirements ti (DynamicExpr dienamic) reqs_ts = requirements ti dienamic reqs_ts requirements ti (Selection selector_kind expr selectors) reqs_ts # (expr_type, opt_expr_ptr, (reqs, ts)) = requirements ti expr reqs_ts = case selector_kind of NormalSelector # (_, result_type, reqs_ts) = requirementsOfSelectors ti No expr selectors True expr_type expr (reqs, ts) -> (result_type, opt_expr_ptr, reqs_ts) UniqueSelector # (var, ts) = freshAttributedVariable ts (_, result_type, (reqs, ts)) = requirementsOfSelectors ti No expr selectors False var expr (reqs, ts) non_unique_type_var = { at_attribute = TA_Multi, at_type = TempV ts.ts_var_store } req_type_coercions = [ { tc_demanded = non_unique_type_var, tc_offered = result_type, tc_position = CP_Expression expr, tc_coercible = False }, { tc_demanded = var, tc_offered = expr_type, tc_position = CP_Expression expr, tc_coercible = True } : reqs.req_type_coercions] result_type = { at_type = TA tuple2TypeSymbIdent [non_unique_type_var,var], at_attribute = TA_Unique } -> (result_type, No, ({ reqs & req_type_coercions = req_type_coercions }, {ts & ts_var_store = inc ts.ts_var_store, ts_expr_heap = storeAttribute opt_expr_ptr TA_Multi ts.ts_expr_heap})) UniqueSelectorUniqueElementResult # (var, ts) = freshAttributedVariable ts (_, selection_type, (reqs, ts)) = requirementsOfSelectors ti No expr selectors True /*False*/ var expr (reqs, ts) req_type_coercions = [ { tc_demanded = var, tc_offered = expr_type, tc_position = CP_Expression expr, tc_coercible = True } : reqs.req_type_coercions] result_type = { at_type = TA tuple2TypeSymbIdent [selection_type,var], at_attribute = TA_Unique } -> (result_type, No, ({ reqs & req_type_coercions = req_type_coercions }, {ts & ts_expr_heap = storeAttribute opt_expr_ptr selection_type.at_attribute ts.ts_expr_heap})) UniqueSingleArraySelector -> case selectors of [selector] # (_, result_type, reqs_ts) = requirementsOfSelector ti No expr selector True False expr_type expr (reqs, ts) -> (result_type, opt_expr_ptr, reqs_ts) UniqueSingleArraySelectorUniqueElementResult -> case selectors of [selector] # (_, result_type, reqs_ts) = requirementsOfSelector ti No expr selector True True expr_type expr (reqs, ts) -> (result_type, opt_expr_ptr, reqs_ts) requirements ti (Update composite_expr selectors elem_expr) reqs_ts # (composite_expr_type, opt_composite_expr_ptr, reqs_ts) = requirements ti composite_expr reqs_ts (has_array_selection, result_type, (reqs, ts)) = requirementsOfSelectors ti (Yes elem_expr) composite_expr selectors True composite_expr_type composite_expr reqs_ts | has_array_selection # ts = { ts & ts_expr_heap = storeAttribute opt_composite_expr_ptr TA_Unique ts.ts_expr_heap } = (composite_expr_type, No, (reqs, ts)) = (composite_expr_type, opt_composite_expr_ptr, (reqs, ts)) requirements ti (RecordUpdate {glob_module,glob_object={ds_index,ds_arity}} expression expressions) (reqs, ts) # cp = CP_Expression expression (rhs, ts) = standardRhsConstructorType cp ds_index glob_module ds_arity ti ts (expression_type, opt_expr_ptr, reqs_ts) = requirements ti expression (reqs, ts) (lhs_args, reqs_ts) = determine_record_type cp ds_index glob_module ti expression expression_type opt_expr_ptr reqs_ts (reqs, ts) = requirements_of_fields ti expression expressions rhs.tst_args lhs_args reqs_ts // ts = { ts & ts_expr_heap = storeAttribute opt_expr_ptr lhs_result.at_attribute ts.ts_expr_heap } // coercion = { tc_demanded = lhs_result, tc_offered = expression_type, tc_position = CP_Expression expression, tc_coercible = True } // = (rhs.tst_result, No, ({ reqs & req_attr_coercions = rhs.tst_attr_env ++ lhs_attr_env ++ reqs.req_attr_coercions, ts)) = (rhs.tst_result, No, ({ reqs & req_attr_coercions = rhs.tst_attr_env ++ reqs.req_attr_coercions }, ts)) // req_type_coercions = [ coercion : reqs.req_type_coercions ]}, ts)) where requirements_of_fields ti expression [] _ _ reqs_ts = reqs_ts requirements_of_fields ti expression [field : fields] [dem_type : dem_types] [off_type : off_types] reqs_ts # reqs_ts = requirements_of_field ti expression field dem_type off_type reqs_ts = requirements_of_fields ti expression fields dem_types off_types reqs_ts requirements_of_field ti expression {bind_src=NoBind expr_ptr} dem_field_type off_field_type (reqs=:{req_type_coercions}, ts) # ts = { ts & ts_expr_heap = ts.ts_expr_heap <:= (expr_ptr, EI_Attribute (toInt dem_field_type.at_attribute)) } coercion = { tc_demanded = dem_field_type, tc_offered = off_field_type, tc_position = CP_Expression expression, tc_coercible = True } = ({ reqs & req_type_coercions = [ coercion : req_type_coercions ]}, ts) requirements_of_field ti _ {bind_src} dem_field_type _ reqs_ts # (expr_type, opt_expr_ptr, (reqs, ts)) = requirements ti bind_src reqs_ts ts = { ts & ts_expr_heap = storeAttribute opt_expr_ptr dem_field_type.at_attribute ts.ts_expr_heap } coercion = { tc_demanded = dem_field_type, tc_offered = expr_type, tc_position = CP_Expression bind_src, tc_coercible = True } = ({ reqs & req_type_coercions = [ coercion : reqs.req_type_coercions ]}, ts) determine_record_type cp cons_index mod_index ti (Var var) expression_type opt_expr_ptr (reqs, ts=:{ts_var_heap}) # (type_info, ts_var_heap) = getTypeInfoOfVariable var ts_var_heap ts = { ts & ts_var_heap = ts_var_heap} = case type_info of VITI_PatternType arg_types module_index constructor_index _ | cons_index==constructor_index && mod_index==module_index -> (arg_types, (reqs, ts)) VITI_PatternType arg_types module_index constructor_index _ | cons_index==constructor_index && mod_index==module_index -> (arg_types, (reqs, ts)) _ -> new_lhs_constructor_type cp cons_index mod_index ti expression_type opt_expr_ptr (reqs, ts) determine_record_type cp cons_index mod_index ti _ expression_type opt_expr_ptr reqs_ts = new_lhs_constructor_type cp cons_index mod_index ti expression_type opt_expr_ptr reqs_ts new_lhs_constructor_type cp cons_index mod_index ti expression_type opt_expr_ptr (reqs, ts) # (lhs, ts) = standardLhsConstructorType cp cons_index mod_index ti ts ts = { ts & ts_expr_heap = storeAttribute opt_expr_ptr lhs.tst_result.at_attribute ts.ts_expr_heap } coercion = { tc_demanded = lhs.tst_result, tc_offered = expression_type, tc_position = cp, tc_coercible = True } req_type_coercions = [ coercion : reqs.req_type_coercions ] req_attr_coercions = lhs.tst_attr_env ++ reqs.req_attr_coercions = (lhs.tst_args, ({ reqs & req_type_coercions = req_type_coercions, req_attr_coercions = req_attr_coercions }, ts)) requirements ti (TupleSelect tuple_symbol arg_nr expr) (reqs=:{req_attr_coercions}, ts) # (position, ts_var_heap) = getPositionOfExpr expr ts.ts_var_heap ({tst_args = [argtype:_], tst_result, tst_attr_env}, ts) = standardTupleSelectorType position tuple_symbol arg_nr ti { ts & ts_var_heap = ts_var_heap } (e_type, opt_expr_ptr, (reqs, ts)) = requirements ti expr ({ reqs & req_attr_coercions = tst_attr_env ++ req_attr_coercions }, ts) req_type_coercions = [{ tc_demanded = argtype, tc_offered = e_type, tc_position = position, tc_coercible = True } : reqs.req_type_coercions ] ts_expr_heap = storeAttribute opt_expr_ptr argtype.at_attribute ts.ts_expr_heap = (tst_result, No, ({ reqs & req_type_coercions = req_type_coercions }, { ts & ts_expr_heap = ts_expr_heap })) requirements _ (BasicExpr basic_val) (reqs, ts) # basic_type = typeOfBasicValue basic_val # (type, ts) = attributedBasicType basic_type ts = (type, No, (reqs, ts)) where typeOfBasicValue :: !BasicValue -> Box Type typeOfBasicValue (BVI _) = basicIntType typeOfBasicValue (BVInt _) = basicIntType typeOfBasicValue (BVC _) = basicCharType typeOfBasicValue (BVB _) = basicBoolType typeOfBasicValue (BVR _) = basicRealType typeOfBasicValue (BVS _) = basicStringType attributedBasicType {box=type} ts=:{ts_attr_store} = ({ at_attribute = TA_TempVar ts_attr_store, at_type = type}, {ts & ts_attr_store = inc ts_attr_store}) requirements ti (MatchExpr {glob_object={ds_arity,ds_index,ds_ident},glob_module} expr) reqs_ts=:(reqs, ts) | glob_module==cPredefinedModuleIndex && (let pd_cons_index=ds_index+FirstConstructorPredefinedSymbolIndex in pd_cons_index==PD_UnboxedConsSymbol || pd_cons_index==PD_UnboxedTailStrictConsSymbol || pd_cons_index==PD_OverloadedConsSymbol) = requirements ti expr reqs_ts # cp = CP_Expression expr ({tst_result,tst_args,tst_attr_env}, ts) = standardLhsConstructorType cp ds_index glob_module ti ts ts = if (Any is_TFAC tst_args) {ts & ts_error = checkError ds_ident "selection not allowed for constructor with universally quantified context" ts.ts_error} ts (e_type, opt_expr_ptr, (reqs, ts)) = requirements ti expr (reqs, ts) reqs = { reqs & req_attr_coercions = tst_attr_env ++ reqs.req_attr_coercions, req_type_coercions = [{ tc_demanded = tst_result, tc_offered = e_type, tc_position = cp, tc_coercible = True } : reqs.req_type_coercions ] } ts = { ts & ts_expr_heap = storeAttribute opt_expr_ptr tst_result.at_attribute ts.ts_expr_heap } | ds_arity>1 // ds_arity == -2 for newtype # tuple_type = MakeTypeSymbIdent { glob_object = PD_Arity2TupleTypeIndex+(ds_arity-2), glob_module = cPredefinedModuleIndex } predefined_idents.[PD_Arity2TupleType+(ds_arity-2)] ds_arity = ({ at_type = TA tuple_type tst_args, at_attribute = TA_Unique }, No, (reqs, ts)) = ( hd tst_args, No, (reqs, ts)) where is_TFAC {at_type=TFAC _ _ _} = True is_TFAC _ = False requirements ti (IsConstructor expr {glob_object={ds_arity,ds_index,ds_ident},glob_module} _ _ _ _) (reqs,ts) # cp = CP_Expression expr ({tst_result,tst_args,tst_attr_env}, ts) = standardLhsConstructorType cp ds_index glob_module ti ts (e_type, opt_expr_ptr, (reqs, ts)) = requirements ti expr (reqs,ts) reqs = { reqs & req_attr_coercions = tst_attr_env ++ reqs.req_attr_coercions, req_type_coercions = [{ tc_demanded = tst_result, tc_offered = e_type, tc_position = cp, tc_coercible = True } : reqs.req_type_coercions ] } ts_attr_store = ts.ts_attr_store bool_type = { at_attribute = TA_TempVar ts_attr_store, at_type = basicBoolType.box} ts & ts_attr_store = inc ts_attr_store, ts_expr_heap = storeAttribute opt_expr_ptr tst_result.at_attribute ts.ts_expr_heap = (bool_type, No, (reqs, ts)) requirements _ (AnyCodeExpr _ _ _) (reqs, ts) # (fresh_v, ts) = freshAttributedVariable ts = (fresh_v, No, (reqs, ts)) requirements _ (ABCCodeExpr _ _) (reqs, ts) # (fresh_v, ts) = freshAttributedVariable ts = (fresh_v, No, (reqs, ts)) requirements ti (TypeSignature make_fresh_type_function expr) (reqs, ts) # {ts_var_store,ts_attr_store} = ts (type,ts_var_store,ts_attr_store) = make_fresh_type_function ts_var_store ts_attr_store ts = {ts & ts_var_store=ts_var_store,ts_attr_store=ts_attr_store} (e_type, opt_expr_ptr, (reqs, ts)) = requirements ti expr (reqs, ts) new_coercion = {tc_demanded=type, tc_offered=e_type, tc_position=CP_Expression expr, tc_coercible=True} reqs = { reqs & req_type_coercions = [new_coercion : reqs.req_type_coercions ] } ts = { ts & ts_expr_heap = storeAttribute opt_expr_ptr type.at_attribute ts.ts_expr_heap } = (type, No, (reqs, ts)) requirements _ expr reqs_ts = (abort ("Error in requirements\n" ---> expr), No, reqs_ts) :: Box a = { box :: !a} basicIntType =: {box=TB BT_Int} basicCharType =: {box=TB BT_Char} basicBoolType =: {box=TB BT_Bool} basicRealType =: {box=TB BT_Real} basicStringType =: {box=TA (MakeTypeSymbIdent { glob_object = PD_StringTypeIndex, glob_module = cPredefinedModuleIndex } predefined_idents.[PD_StringType] 0) []} tuple2TypeSymbIdent =: MakeTypeSymbIdent { glob_object = PD_Arity2TupleTypeIndex, glob_module = cPredefinedModuleIndex } predefined_idents.[PD_Arity2TupleType] 2 requirementsOfSelectors ti opt_expr expr [selector] tc_coercible sel_expr_type sel_expr reqs_ts = requirementsOfSelector ti opt_expr expr selector tc_coercible False sel_expr_type sel_expr reqs_ts requirementsOfSelectors ti opt_expr expr [selector : selectors] tc_coercible sel_expr_type sel_expr reqs_ts # (has_array_selection, result_type, reqs_ts) = requirementsOfSelector ti No expr selector tc_coercible False sel_expr_type sel_expr reqs_ts # (have_array_selection, result_type, reqs_ts) = requirementsOfSelectors ti opt_expr expr selectors tc_coercible result_type sel_expr reqs_ts = (has_array_selection || have_array_selection, result_type, reqs_ts) requirementsOfSelector ti _ expr (RecordSelection field _) tc_coercible change_uselect sel_expr_type sel_expr (reqs, ts ) # ({tst_args, tst_result, tst_attr_env}, ts) = standardFieldSelectorType (CP_Expression sel_expr) field ti ts req_type_coercions = [{ tc_demanded = hd tst_args, tc_offered = sel_expr_type, tc_position = CP_Expression sel_expr, tc_coercible = tc_coercible } : reqs.req_type_coercions ] = (False, tst_result, ({ reqs & req_type_coercions = req_type_coercions }, ts)) requirementsOfSelector ti opt_expr expr (ArraySelection {glob_object = {ds_ident,ds_index},glob_module} expr_ptr index_expr) tc_coercible change_uselect sel_expr_type sel_expr (reqs, ts) # {me_type} = ti.ti_common_defs.[glob_module].com_member_defs.[ds_index] ({tst_attr_env,tst_args,tst_result,tst_context}, ts) = freshSymbolType (Yes (CP_Expression expr)) cWithFreshContextVars me_type ti.ti_common_defs ts # (tst_args, tst_result, ts) = if change_uselect (change_uselect_attributes tst_args tst_result ts) (tst_args, tst_result, ts) (dem_array_type, dem_index_type, rest_type) = array_and_index_type tst_args reqs ={ reqs & req_attr_coercions = tst_attr_env ++ reqs.req_attr_coercions} (index_type, opt_expr_ptr, (reqs, ts)) = requirements ti index_expr (reqs, ts) ts_expr_heap = storeAttribute opt_expr_ptr dem_index_type.at_attribute ts.ts_expr_heap reqs = { reqs & req_type_coercions = [{ tc_demanded = dem_index_type, tc_offered = index_type, tc_position = CP_Expression expr, tc_coercible = True }, { tc_demanded = dem_array_type, tc_offered = sel_expr_type, tc_position = CP_Expression sel_expr, tc_coercible = tc_coercible } : reqs.req_type_coercions ]} (reqs, ts) = requirements_of_update ti opt_expr rest_type (reqs, { ts & ts_expr_heap = ts_expr_heap }) | isEmpty tst_context = (True, tst_result, (reqs, ts)) = (True, tst_result, ({ reqs & req_overloaded_calls = [expr_ptr : reqs.req_overloaded_calls ]}, { ts & ts_expr_heap = ts.ts_expr_heap <:= (expr_ptr, EI_Overloaded {oc_symbol = { symb_ident = ds_ident, symb_kind = SK_OverloadedFunction {glob_module = glob_module, glob_object = ds_index}}, oc_context = tst_context, oc_specials = [] })})) where array_and_index_type [array_type, index_type : rest_type ] = (array_type, index_type, rest_type) requirements_of_update ti No _ reqs_ts = reqs_ts requirements_of_update ti (Yes elem_expr) [ elem_type : _ ] reqs_ts # (elem_expr_type, opt_elem_expr_ptr, (reqs, ts)) = requirements ti elem_expr reqs_ts ts = { ts & ts_expr_heap = storeAttribute opt_elem_expr_ptr elem_type.at_attribute ts.ts_expr_heap } reqs = { reqs & req_type_coercions = [{ tc_demanded = elem_type, tc_offered = elem_expr_type, tc_position = CP_Expression elem_expr, tc_coercible = True } : reqs.req_type_coercions ]} = (reqs, ts) /* change uselect :: !u:(a e) !Int -> ( e, !u:(a e)) | uselect_u e to uselect :: !u:(a .e) !Int -> (.e, !u:(a .e)) | uselect_u e (necessary for uselects in updates) */ change_uselect_attributes :: [AType] AType u:TypeState -> ([AType], AType, u:TypeState) change_uselect_attributes args=:[arg_array=:{at_type=aa :@: [ae]}, arg_int] result=:{at_type=TA tuple_symb [result_element, result_array=:{at_type=ra :@: [re]}]} ts # (attribute, ts) = freshAttribute ts # args = [{arg_array & at_type = aa :@: [{ae & at_attribute = attribute}]}, arg_int] # result = {result & at_type = TA tuple_symb [{result_element & at_attribute = attribute}, {result_array & at_type=ra :@: [{re & at_attribute = attribute}]}]} = (args, result, ts) change_uselect_attributes args=:[arg_array=:{at_type=aa :@: [ae]}, arg_int] result=:{at_type=TAS tuple_symb [result_element, result_array=:{at_type=ra :@: [re]}] strictness} ts # (attribute, ts) = freshAttribute ts # args = [{arg_array & at_type = aa :@: [{ae & at_attribute = attribute}]}, arg_int] # result = {result & at_type = TAS tuple_symb [{result_element & at_attribute = attribute}, {result_array & at_type=ra :@: [{re & at_attribute = attribute}]}] strictness} = (args, result, ts) change_uselect_attributes _ _ ts = abort "type.icl, change_uselect_attributes: wrong type for uselect" possibly_accumulate_reqs_in_new_group position state_transition reqs_ts :== possibly_accumulate_reqs position reqs_ts where possibly_accumulate_reqs NoPos reqs_ts = state_transition reqs_ts possibly_accumulate_reqs position (reqs=:{req_type_coercions=old_req_type_coercions}, ts) # reqs_with_empty_accu = { reqs & req_type_coercions = [] } (reqs_with_new_group_in_accu, ts) = state_transition (reqs_with_empty_accu, ts) new_group = { tcg_type_coercions = reqs_with_new_group_in_accu.req_type_coercions, tcg_position = position } reqs_with_new_group = { reqs_with_new_group_in_accu & req_type_coercion_groups = [new_group:reqs_with_new_group_in_accu.req_type_coercion_groups], req_type_coercions = old_req_type_coercions } = (reqs_with_new_group, ts) makeBase id=:{id_name} l1 l2 vh // | length l1 <> length l2 // = abort ("makeBase!!! " +++ id_name +++ toString (length l1) +++ toString (length l2)) = makeBase2 id 1 l1 l2 vh where makeBase2 fun_or_cons_ident arg_nr [{fv_ident, fv_info_ptr} : vars] [type : types] ts_var_heap | is_rare_name fv_ident # ts_var_heap = addToBase fv_info_ptr type (VITI_Coercion (CP_FunArg fun_or_cons_ident arg_nr)) ts_var_heap = makeBase2 fun_or_cons_ident (arg_nr+1) vars types ts_var_heap # ts_var_heap = addToBase fv_info_ptr type VITI_Empty ts_var_heap = makeBase2 fun_or_cons_ident (arg_nr+1) vars types ts_var_heap makeBase2 _ _ [] [] ts_var_heap = ts_var_heap makeBase2 {id_name} _ _ _ ts_var_heap = abort ("makeBase!!! "+++id_name) addToBase info_ptr atype=:{at_type = TFA atvs type} optional_position ts_var_heap = ts_var_heap <:= (info_ptr, VI_FAType atvs {atype & at_type = type} optional_position) addToBase info_ptr atype=:{at_type = TFAC atvs type contexts} optional_position ts_var_heap = ts_var_heap <:= (info_ptr, VI_FATypeC atvs {atype & at_type = type} contexts optional_position) addToBase info_ptr type optional_position ts_var_heap = ts_var_heap <:= (info_ptr, VI_Type type optional_position) attributedBasicType (BT_String string_type) ts=:{ts_attr_store} = ({ at_attribute = TA_TempVar ts_attr_store, at_type = string_type}, {ts & ts_attr_store = inc ts_attr_store}) attributedBasicType bas_type ts=:{ts_attr_store} = ({ at_attribute = TA_TempVar ts_attr_store, at_type = TB bas_type}, {ts & ts_attr_store = inc ts_attr_store}) unify_coercions [{tc_demanded,tc_offered,tc_position}:coercions] ti subst heaps err # (succ, subst, heaps) = unify tc_demanded tc_offered ti subst heaps | succ = unify_coercions coercions ti subst heaps err # (_, subst_demanded, subst) = arraySubst tc_demanded subst (_, subst_offered, subst) = arraySubst tc_offered subst = (subst, heaps, cannotUnify subst_demanded subst_offered tc_position ti.ti_common_defs err) unify_coercions [] ti subst heaps err = (subst, heaps, err) InitFunEnv :: !Int -> *{! FunctionType} InitFunEnv nr_of_fun_defs = createArray nr_of_fun_defs EmptyFunctionType CreateInitialSymbolTypes start_index common_defs [] defs_and_state = defs_and_state CreateInitialSymbolTypes start_index common_defs [fun : funs] (pre_def_symbols, ts) # (fd, ts) = ts!ts_fun_defs.[fun] (pre_def_symbols, ts) = initial_symbol_type (start_index == fun) common_defs fd (pre_def_symbols, ts) = CreateInitialSymbolTypes start_index common_defs funs (pre_def_symbols, ts) where initial_symbol_type is_start_rule common_defs {fun_type=Yes ft=:{st_arity,st_args,st_result,st_attr_vars,st_attr_env},fun_ident,fun_lifted,fun_info={fi_dynamics},fun_pos} (pre_def_symbols, ts=:{ts_type_heaps,ts_expr_heap,ts_td_infos,ts_error}) # fe_location = newPosition fun_ident fun_pos ts_error = setErrorAdmin fe_location ts_error (st_args, ps) = addPropagationAttributesToATypes common_defs st_args { prop_type_heaps = ts_type_heaps, prop_td_infos = ts_td_infos, prop_attr_vars = st_attr_vars, prop_attr_env = st_attr_env, prop_error = Yes ts_error} (st_result, {prop_type_heaps,prop_td_infos,prop_attr_vars,prop_error = Yes ts_error,prop_attr_env}) = addPropagationAttributesToAType common_defs st_result ps ft_with_prop = { ft & st_args = st_args, st_result = st_result, st_attr_vars = prop_attr_vars, st_attr_env = prop_attr_env } (th_vars, ts_expr_heap) = clear_dynamics fi_dynamics (prop_type_heaps.th_vars, ts.ts_expr_heap) (fresh_fun_type, ts) = freshSymbolType No cWithoutFreshContextVars ft_with_prop common_defs {ts & ts_type_heaps={prop_type_heaps & th_vars=th_vars}, ts_expr_heap=ts_expr_heap, ts_td_infos=prop_td_infos, ts_error=ts_error} // (lifted_args, ts) = fresh_non_unique_type_variables fun_lifted [] ts (lifted_args, ts) = fresh_attributed_type_variables fun_lifted [] ts (ts_var_store, ts_type_heaps, ts_var_heap, ts_expr_heap, pre_def_symbols) = fresh_dynamics fi_dynamics (ts.ts_var_store, ts.ts_type_heaps, ts.ts_var_heap, ts.ts_expr_heap, pre_def_symbols) = (pre_def_symbols, { ts & ts_fun_env = { ts.ts_fun_env & [fun] = SpecifiedType ft_with_prop lifted_args {fresh_fun_type & tst_arity = st_arity + fun_lifted, tst_args = lifted_args ++ fresh_fun_type.tst_args, tst_lifted = fun_lifted}}, ts_var_heap = ts_var_heap, ts_var_store = ts_var_store, ts_expr_heap = ts_expr_heap, ts_type_heaps = ts_type_heaps }) initial_symbol_type is_start_rule common_defs {fun_arity, fun_lifted, fun_info = {fi_dynamics}, fun_kind} (pre_def_symbols, ts) # (st_gen, ts) = create_general_symboltype is_start_rule (fun_kind == FK_Caf) fun_arity fun_lifted ts ts_type_heaps = ts.ts_type_heaps (th_vars, ts_expr_heap) = clear_dynamics fi_dynamics (ts_type_heaps.th_vars, ts.ts_expr_heap) (ts_var_store, ts_type_heaps, ts_var_heap, ts_expr_heap, pre_def_symbols) = fresh_dynamics fi_dynamics (ts.ts_var_store, { ts_type_heaps & th_vars = th_vars }, ts.ts_var_heap, ts_expr_heap, pre_def_symbols) = (pre_def_symbols, { ts & ts_fun_env = {ts.ts_fun_env & [fun] = UncheckedType st_gen}, ts_var_store = ts_var_store, ts_expr_heap = ts_expr_heap, ts_type_heaps = ts_type_heaps, ts_var_heap = ts_var_heap}) create_general_symboltype :: !Bool !Bool !Int !Int !*TypeState -> (!TempSymbolType, !*TypeState) create_general_symboltype is_start_rule is_caf nr_of_args nr_of_lifted_args ts | is_start_rule && nr_of_args > 0 # (tst_args, ts) = fresh_attributed_type_variables (nr_of_args - 1) [{at_attribute = TA_Unique, /*at_annotation = AN_Strict,*/ at_type = TB BT_World }] ts (tst_result, ts) = (if is_caf freshNonUniqueVariable freshAttributedVariable) ts = ({tst_args=tst_args, tst_arity=1, tst_result=tst_result, tst_context=[], tst_var_contexts=NoVarContexts, tst_attr_env=[], tst_lifted=0}, ts) # (tst_args, ts) = fresh_attributed_type_variables nr_of_args [] ts (tst_args, ts) = fresh_attributed_type_variables nr_of_lifted_args tst_args ts (tst_result, ts) = (if is_caf freshNonUniqueVariable freshAttributedVariable) ts = ({tst_args=tst_args, tst_arity=nr_of_args + nr_of_lifted_args, tst_result=tst_result, tst_context=[], tst_var_contexts=NoVarContexts, tst_attr_env=[], tst_lifted=0}, ts) fresh_attributed_type_variables :: !Int ![AType] !*TypeState -> (![AType], !*TypeState) fresh_attributed_type_variables n vars ts | n == 0 = (vars, ts) # (var, ts) = freshAttributedVariable ts = fresh_attributed_type_variables (dec n) [var : vars] ts /* fresh_non_unique_type_variables :: !Int ![AType] !*TypeState -> (![AType], !*TypeState) fresh_non_unique_type_variables n vars ts | n == 0 = (vars, ts) # (var, ts) = freshNonUniqueVariable ts = fresh_non_unique_type_variables (dec n) [var : vars] ts */ fresh_dynamics dyn_ptrs state = foldSt fresh_dynamic dyn_ptrs state where fresh_dynamic dyn_ptr (var_store, type_heaps, var_heap, expr_heap, predef_symbols) # (dyn_info, expr_heap) = readPtr dyn_ptr expr_heap = case dyn_info of EI_Dynamic opt_dyn_type=:(Yes {dt_uni_vars,dt_type,dt_global_vars,dt_contexts}) loc_dynamics # (th_vars, var_store) = fresh_existential_attributed_variables dt_uni_vars (type_heaps.th_vars, var_store) (th_vars, var_store) = fresh_type_variables dt_global_vars (th_vars, var_store) (tdt_type, type_heaps) = freshCopy dt_type { type_heaps & th_vars = th_vars } (fresh_univ_contexts, (type_heaps,var_heap)) = freshTypeContexts True dt_contexts (type_heaps,var_heap) (contexts, expr_ptr, type_code_symbol, (var_heap, expr_heap, type_var_heap, predef_symbols)) = determine_context_and_expr_ptr dt_global_vars (var_heap, expr_heap, type_heaps.th_vars, predef_symbols) dyn_info = EI_TempDynamicType opt_dyn_type loc_dynamics tdt_type contexts fresh_univ_contexts expr_ptr type_code_symbol -> fresh_local_dynamics loc_dynamics (var_store, { type_heaps & th_vars = type_var_heap }, var_heap, expr_heap <:= (dyn_ptr, dyn_info), predef_symbols) EI_Dynamic No loc_dynamics # fresh_var = TempV var_store tdt_type = { at_attribute = TA_Multi, at_type = fresh_var } ({pds_module,pds_def},predef_symbols) = predef_symbols![PD_TypeCodeClass] pds_ident = predefined_idents.[PD_TypeCodeClass] tc_class_symb = {glob_module = pds_module, glob_object = {ds_ident = pds_ident, ds_arity = 1, ds_index = pds_def }} (pds, predef_symbols) = predef_symbols![PD_TypeCodeMember] ({pds_module,pds_def},predef_symbols) = predef_symbols![PD_TypeCodeMember] pds_ident = predefined_idents.[PD_TypeCodeMember] tc_member_symb = { symb_ident = pds_ident, symb_kind = SK_OverloadedFunction {glob_module = pds_module, glob_object = pds_def }} (new_var_ptr, var_heap) = newPtr VI_Empty var_heap context = {tc_class = TCClass tc_class_symb, tc_types = [fresh_var], tc_var = new_var_ptr} (expr_ptr, expr_heap) = newPtr EI_Empty expr_heap dyn_info = EI_TempDynamicType No loc_dynamics tdt_type [context] [] expr_ptr tc_member_symb -> fresh_local_dynamics loc_dynamics (inc var_store, type_heaps, var_heap, expr_heap <:= (dyn_ptr, dyn_info), predef_symbols) EI_DynamicTypeWithVars loc_type_vars dt=:{dt_uni_vars,dt_type,dt_global_vars,dt_contexts} loc_dynamics # (fresh_vars, (th_vars, var_store)) = fresh_existential_dynamic_pattern_variables loc_type_vars (type_heaps.th_vars, var_store) (th_vars, var_store) = fresh_type_variables dt_global_vars (th_vars, var_store) (tdt_type, type_heaps) = fresh_universal_vars_type_and_contexts dt_uni_vars dt_type dt_contexts {type_heaps & th_vars = th_vars} (contexts, expr_ptr, type_code_symbol, (var_heap, expr_heap, type_var_heap, predef_symbols)) = determine_context_and_expr_ptr dt_global_vars (var_heap, expr_heap, type_heaps.th_vars, predef_symbols) expr_heap = expr_heap <:= (dyn_ptr, EI_TempDynamicPattern loc_type_vars dt loc_dynamics fresh_vars tdt_type contexts expr_ptr type_code_symbol) -> fresh_local_dynamics loc_dynamics (var_store, { type_heaps & th_vars = type_var_heap }, var_heap, expr_heap, predef_symbols) where fresh_universal_vars_type_and_contexts [] at [] type_heaps = freshCopy at type_heaps fresh_universal_vars_type_and_contexts uni_vars at=:{at_attribute,at_type} [] type_heaps # (fresh_attribute, th_attrs) = freshCopyOfTypeAttribute at_attribute type_heaps.th_attrs (at_type, type_heaps) = freshCopyOfTFAType uni_vars at_type {type_heaps & th_attrs = th_attrs} = ({at & at_attribute = fresh_attribute, at_type = at_type}, type_heaps) fresh_universal_vars_type_and_contexts uni_vars at=:{at_attribute,at_type} contexts type_heaps # (fresh_attribute, th_attrs) = freshCopyOfTypeAttribute at_attribute type_heaps.th_attrs (at_type, type_heaps) = freshCopyOfTFACType uni_vars at_type contexts {type_heaps & th_attrs = th_attrs} = ({at & at_attribute = fresh_attribute, at_type = at_type}, type_heaps) EI_UnmarkedDynamic _ _ -> (var_store, type_heaps, var_heap, expr_heap, predef_symbols) where fresh_local_dynamics loc_dynamics state = foldSt fresh_dynamic loc_dynamics state determine_context_and_expr_ptr global_vars (var_heap, expr_heap, type_var_heap, predef_symbols) # ({pds_module,pds_def},predef_symbols) = predef_symbols![PD_TypeCodeClass] # pds_ident = predefined_idents.[PD_TypeCodeClass] tc_class_symb = {glob_module = pds_module, glob_object = {ds_ident = pds_ident, ds_arity = 1, ds_index = pds_def }} ({pds_module,pds_def},predef_symbols) = predef_symbols![PD_TypeCodeMember] pds_ident = predefined_idents.[PD_TypeCodeMember] tc_member_symb = { symb_ident = pds_ident, symb_kind = SK_TypeCode} (contexts, (var_heap, type_var_heap)) = mapSt (build_type_context tc_class_symb) global_vars (var_heap, type_var_heap) (expr_ptr, expr_heap) = newPtr EI_Empty expr_heap = (contexts, expr_ptr, tc_member_symb, (var_heap, expr_heap, type_var_heap, predef_symbols)) where build_type_context tc_class_symb {tv_info_ptr} (var_heap, type_var_heap) # (TVI_Type fresh_var, type_var_heap) = readPtr tv_info_ptr type_var_heap (new_var_ptr, var_heap) = newPtr VI_Empty var_heap = ({tc_class = TCClass tc_class_symb, tc_types = [fresh_var], tc_var = new_var_ptr}, (var_heap, type_var_heap)) fresh_existential_attributed_variables type_variables state = foldSt (\{atv_variable={tv_info_ptr}} (var_heap, var_store) -> (var_heap <:= (tv_info_ptr, TVI_Type (TempQV var_store)), inc var_store)) type_variables state fresh_existential_dynamic_pattern_variables type_variables state = mapSt (\{tv_info_ptr} (var_heap, var_store) -> (var_store, (var_heap <:= (tv_info_ptr, TVI_Type (TempQDV var_store)), inc var_store))) type_variables state fresh_type_variables type_variables state = foldSt fresh_type_variable type_variables state fresh_type_variable {tv_info_ptr} (var_heap, var_store) # (var_info, var_heap) = readPtr tv_info_ptr var_heap = case var_info of TVI_Empty -> (var_heap <:= (tv_info_ptr, TVI_Type (TempV var_store)), inc var_store) _ -> (var_heap, var_store) clear_dynamics dyn_ptrs heaps = foldSt clear_dynamic dyn_ptrs heaps where clear_dynamic dyn_ptr (var_heap, expr_heap) # (dyn_info, expr_heap) = readPtr dyn_ptr expr_heap = case dyn_info of EI_Dynamic (Yes {dt_global_vars}) loc_dynamics -> clear_local_dynamics loc_dynamics (clear_type_vars dt_global_vars var_heap, expr_heap) EI_Dynamic No loc_dynamics -> clear_local_dynamics loc_dynamics (var_heap, expr_heap) EI_DynamicTypeWithVars loc_type_vars {dt_global_vars} loc_dynamics -> clear_local_dynamics loc_dynamics (clear_type_vars dt_global_vars var_heap, expr_heap) EI_UnmarkedDynamic _ _ -> (var_heap, expr_heap) clear_local_dynamics loc_dynamics state = foldSt clear_dynamic loc_dynamics state clear_type_vars type_vars var_heap = foldSt (\{tv_info_ptr} -> writePtr tv_info_ptr TVI_Empty) type_vars var_heap specification_error type type1 err # err = errorHeading "Type error" err format = { form_properties = cAttributed, form_attr_position = No} # err = { err & ea_file = err.ea_file <<< "derived type conflicts with specified type:" <<< '\n' } # format = { form_properties = cAttributed, form_attr_position = No} # err = { err & ea_file = err.ea_file <<< " " <:: (format, type, Yes initialTypeVarBeautifulizer) <<< '\n' } # format = { form_properties = cAttributed, form_attr_position = No} # err = { err & ea_file = err.ea_file <<< " " <:: (format, type1, Yes initialTypeVarBeautifulizer) <<< '\n' } = err cleanUpAndCheckFunctionTypes [] _ _ start_index _ defs type_contexts coercion_env attr_partition type_var_env attr_var_env (out, ts) = (out, ts) cleanUpAndCheckFunctionTypes [fun:funs] [{fe_requirements={req_case_and_let_exprs}}:reqs] dict_types start_index list_inferred_types defs type_contexts coercion_env attr_partition type_var_env attr_var_env (out, ts) # (fd, ts) = ts!ts_fun_defs.[fun] dict_ptrs = get_dict_ptrs fun dict_types (type_var_env, attr_var_env, out, ts) = clean_up_and_check_function_type fd fun (start_index == fun) list_inferred_types defs type_contexts (dict_ptrs ++ req_case_and_let_exprs) coercion_env attr_partition type_var_env attr_var_env out ts = cleanUpAndCheckFunctionTypes funs reqs dict_types start_index list_inferred_types defs type_contexts coercion_env attr_partition type_var_env attr_var_env (out, ts) where get_dict_ptrs fun_index [] = [] get_dict_ptrs fun_index [(index, ptrs) : dict_types] | fun_index == index = ptrs = get_dict_ptrs fun_index dict_types clean_up_and_check_function_type {fun_ident,fun_kind,fun_pos,fun_type = opt_fun_type} fun is_start_rule list_inferred_types defs type_contexts type_ptrs coercion_env attr_partition type_var_env attr_var_env out ts # (env_type, ts) = ts!ts_fun_env.[fun] # ts = { ts & ts_error = setErrorAdmin (newPosition fun_ident fun_pos) ts.ts_error} = case env_type of ExpandedType fun_type tmp_fun_type exp_fun_type # (clean_fun_type, type_var_env, attr_var_env, ts_type_heaps, ts_var_heap, ts_expr_heap, ts_error) = cleanUpSymbolType is_start_rule cSpecifiedType exp_fun_type type_contexts type_ptrs coercion_env attr_partition type_var_env attr_var_env ts.ts_type_heaps ts.ts_var_heap ts.ts_expr_heap ts.ts_error ts_error = check_caf_context (newPosition fun_ident fun_pos) fun_kind clean_fun_type ts_error | ts_error.ea_ok # (ts_fun_env, attr_var_env, ts_type_heaps, ts_expr_heap, ts_error) = check_function_type fun_type tmp_fun_type clean_fun_type type_ptrs defs ts.ts_fun_env attr_var_env ts_type_heaps ts_expr_heap ts_error -> (type_var_env, attr_var_env, out, {ts & ts_type_heaps = ts_type_heaps, ts_var_heap = ts_var_heap, ts_expr_heap = ts_expr_heap, ts_fun_env = ts_fun_env, ts_error = ts_error}) -> (type_var_env, attr_var_env, out, {ts & ts_type_heaps = ts_type_heaps, ts_var_heap = ts_var_heap, ts_expr_heap = ts_expr_heap, ts_error = ts_error}) UncheckedType exp_fun_type # (clean_fun_type, type_var_env, attr_var_env, ts_type_heaps, ts_var_heap, ts_expr_heap, ts_error) = cleanUpSymbolType is_start_rule cDerivedType exp_fun_type type_contexts type_ptrs coercion_env attr_partition type_var_env attr_var_env ts.ts_type_heaps ts.ts_var_heap ts.ts_expr_heap ts.ts_error ts_error = check_caf_context (newPosition fun_ident fun_pos) fun_kind clean_fun_type ts_error th_attrs = ts_type_heaps.th_attrs (out, th_attrs) = case list_inferred_types of No -> (out, th_attrs) Yes show_attributes # form = { form_properties = if show_attributes cAttributed cNoProperties, form_attr_position = No } // out = out <<< show_attributes <<< "\n" (printable_type, th_attrs) = case show_attributes of True -> beautifulizeAttributes clean_fun_type th_attrs _ -> (clean_fun_type, th_attrs) -> (out <<< fun_ident <<< " :: " <:: (form, printable_type, Yes initialTypeVarBeautifulizer) <<< '\n', th_attrs) ts_fun_env = { ts.ts_fun_env & [fun] = CheckedType clean_fun_type } -> (type_var_env, attr_var_env, out, { ts & ts_type_heaps = { ts_type_heaps & th_attrs = th_attrs }, ts_var_heap = ts_var_heap, ts_expr_heap = ts_expr_heap, ts_fun_env = ts_fun_env, ts_error = ts_error }) check_function_type fun_type tmp_fun_type=:{tst_lifted} clean_fun_type=:{st_arity, st_args, st_vars, st_attr_vars, st_context} type_ptrs defs fun_env attr_var_env type_heaps expr_heap error # (equi, attr_var_env, type_heaps) = equivalent clean_fun_type tmp_fun_type (length fun_type.st_context) defs attr_var_env type_heaps | equi # type_with_lifted_arg_types = addLiftedArgumentsToSymbolType fun_type tst_lifted st_args st_vars st_attr_vars st_context (type_heaps, expr_heap) = updateExpressionTypes clean_fun_type type_with_lifted_arg_types type_ptrs type_heaps expr_heap = ({fun_env & [fun] = CheckedType type_with_lifted_arg_types}, attr_var_env, type_heaps, expr_heap, error) # (printable_type, th_attrs) = beautifulizeAttributes clean_fun_type type_heaps.th_attrs # (printable_type1, th_attrs) = beautifulizeAttributes fun_type th_attrs = (fun_env, attr_var_env, { type_heaps & th_attrs = th_attrs }, expr_heap, specification_error printable_type printable_type1 error) where add_lifted_arg_types arity_diff args1 args2 | arity_diff > 0 = take arity_diff args2 ++ args1 = args1 check_caf_context position FK_Caf {st_context=[_:_]} error = checkErrorWithIdentPos position "CAF cannot be overloaded" error check_caf_context _ _ _ error = error addLiftedArgumentsToSymbolType st=:{st_arity,st_args,st_args_strictness,st_vars,st_attr_vars,st_context} nr_of_lifted_arguments new_args new_vars new_attrs new_context = { st & st_args = take nr_of_lifted_arguments new_args ++ st_args, st_args_strictness = insert_n_lazy_values_at_beginning nr_of_lifted_arguments st_args_strictness, st_vars = st_vars ++ drop (length st_vars) new_vars, st_attr_vars = (take (length new_attrs - length st_attr_vars) new_attrs) ++ st_attr_vars, st_arity = st_arity + nr_of_lifted_arguments,st_context = take (length new_context - length st_context) new_context ++ st_context } :: FunctionRequirements = { fe_requirements :: !Requirements , fe_context :: !Optional [TypeContext] , fe_index :: !Index , fe_location :: !IdentPos } typeProgram :: !{! Group} !Int !*{# FunDef} !IndexRange !(Optional Bool) !CommonDefs ![!GlobalInstanceIndex!] !{# DclModule} !NumberSet !*TypeDefInfos !*Heaps !*PredefinedSymbols !*File !*File -> (!Bool, !*{# FunDef}, !ArrayAndListInstances, !{# CommonDefs}, !{# {# FunType} }, !*TypeDefInfos,!*Heaps,!*PredefinedSymbols,!*File,!*File) typeProgram comps main_dcl_module_n fun_defs specials list_inferred_types icl_defs icl_imported_instances dcl_modules used_module_numbers td_infos heaps=:{hp_var_heap, hp_expression_heap, hp_type_heaps,hp_generic_heap} predef_symbols file out #! fun_env_size = size fun_defs # ts_error = {ea_file = file, ea_loc = [], ea_ok = True } ti_common_defs = {{dcl_common \\ {dcl_common} <-: dcl_modules } & [main_dcl_module_n] = icl_defs } ti_functions = {dcl_functions \\ {dcl_functions} <-: dcl_modules } class_instances = { { IT_Empty \\ i <- [0 .. dec (size com_class_defs)] } \\ {com_class_defs} <-: ti_common_defs } state = collect_imported_instances icl_imported_instances ti_common_defs ts_error class_instances hp_type_heaps.th_vars td_infos (ts_error, class_instances, th_vars, td_infos) = collect_and_check_instances (size icl_defs.com_instance_defs) ti_common_defs state ts = { ts_fun_env = InitFunEnv fun_env_size, ts_var_heap = hp_var_heap, ts_expr_heap = hp_expression_heap, ts_generic_heap = hp_generic_heap, ts_var_store = 0, ts_attr_store = FirstAttrVar, ts_cons_variables = [], ts_exis_variables = [], ts_type_heaps = { hp_type_heaps & th_vars = th_vars }, ts_td_infos = td_infos, ts_error = ts_error, ts_fun_defs=fun_defs } ti = { ti_common_defs = ti_common_defs, ti_functions = ti_functions,ti_main_dcl_module_n=main_dcl_module_n, ti_expand_newtypes = False } special_instances = { si_next_array_member_index = fun_env_size, si_array_instances = [], si_list_instances = [], si_tail_strict_list_instances = [] } # (type_error, predef_symbols, special_instances, out, ts) = type_components list_inferred_types 0 comps class_instances ti (False, predef_symbols, special_instances, out, ts) (fun_defs,ts_fun_env) = update_function_types 0 comps ts.ts_fun_env ts.ts_fun_defs (type_error, predef_symbols, special_instances,out, {ts_td_infos,ts_fun_env,ts_error,ts_var_heap, ts_expr_heap, ts_type_heaps, ts_generic_heap,ts_fun_defs}) = type_instances list_inferred_types specials.ir_from specials.ir_to class_instances ti (type_error, predef_symbols, special_instances, out, { ts & ts_fun_env = ts_fun_env,ts_fun_defs=fun_defs }) (array_first_instance_indices,list_first_instance_indices,tail_strict_list_first_instance_indices,fun_defs,predef_symbols,ts_type_heaps,ts_error) = create_special_instances special_instances fun_env_size ti_common_defs ts_fun_defs predef_symbols ts_type_heaps ts_error array_and_list_instances = { ali_array_first_instance_indices=array_first_instance_indices, ali_list_first_instance_indices=list_first_instance_indices, ali_tail_strict_list_first_instance_indices=tail_strict_list_first_instance_indices, ali_instances_range={ ir_from = fun_env_size, ir_to = special_instances.si_next_array_member_index } } # ts_var_heap = clear_var_heap ti_functions ti_common_defs ts_var_heap = (not type_error, fun_defs, array_and_list_instances, ti_common_defs, ti_functions, ts_td_infos, {hp_var_heap = ts_var_heap, hp_expression_heap = ts_expr_heap, hp_type_heaps = ts_type_heaps, hp_generic_heap=ts_generic_heap }, predef_symbols, ts_error.ea_file, out) where collect_imported_instances [!{gii_module_n,gii_instance_n}:imported_instances!] common_defs error class_instances type_var_heap td_infos # (error, class_instances, type_var_heap, td_infos) = update_instances_of_class common_defs gii_module_n gii_instance_n (error, class_instances, type_var_heap, td_infos) = collect_imported_instances imported_instances common_defs error class_instances type_var_heap td_infos collect_imported_instances [!!] common_defs error class_instances type_var_heap td_infos = (error, class_instances, type_var_heap, td_infos) collect_and_check_instances nr_of_instances common_defs state = iFoldSt (update_instances_of_class common_defs main_dcl_module_n) 0 nr_of_instances state update_instances_of_class common_defs mod_index ins_index (error, class_instances, type_var_heap, td_infos) #!{ins_class_index={gi_module,gi_index},ins_type={it_types},ins_pos} = common_defs.[mod_index].com_instance_defs.[ins_index] (instances, class_instances) = class_instances![gi_module,gi_index] (error, instances) = insert it_types ins_index mod_index common_defs error instances class_instances = {class_instances & [gi_module,gi_index]=instances} (error, type_var_heap, td_infos) = check_types_of_instances ins_pos common_defs gi_module gi_index it_types (error, type_var_heap, td_infos) = (error, class_instances, type_var_heap, td_infos) where insert :: ![Type] !Index !Index !{# CommonDefs } !*ErrorAdmin !*InstanceTree -> (!*ErrorAdmin, !*InstanceTree) insert ins_types new_ins_index new_ins_module modules error IT_Empty = (error, IT_Node {glob_object = new_ins_index,glob_module = new_ins_module} IT_Empty IT_Empty) insert ins_types new_ins_index new_ins_module modules error (IT_Node ins=:{glob_object,glob_module} it_less it_greater) #! {ins_type={it_types}} = modules.[glob_module].com_instance_defs.[glob_object] # cmp = ins_types =< it_types | cmp == Smaller # (error, it_less) = insert ins_types new_ins_index new_ins_module modules error it_less = (error, IT_Node ins it_less it_greater) | cmp == Greater # (error, it_greater) = insert ins_types new_ins_index new_ins_module modules error it_greater = (error, IT_Node ins it_less it_greater) | ins.glob_object==new_ins_index && ins.glob_module==new_ins_module = (error, IT_Node ins it_less it_greater) = (checkError ins_types " instance is overlapping" error, IT_Node ins it_less it_greater) check_types_of_instances ins_pos common_defs class_module class_index types state # {class_cons_vars} = common_defs.[class_module].com_class_defs.[class_index] = check_instances_of_constructor_variables ins_pos common_defs class_cons_vars 0 types state where check_instances_of_constructor_variables ins_pos common_defs cons_vars arg_nr [type : types] state | cons_vars bitand (1 << arg_nr) <> 0 # state = check_type_of_constructor_variable ins_pos common_defs type state = check_instances_of_constructor_variables ins_pos common_defs cons_vars (arg_nr+1) types state = check_instances_of_constructor_variables ins_pos common_defs cons_vars (arg_nr+1) types state check_instances_of_constructor_variables ins_pos common_defs cons_vars arg_nr [] state = state check_type_of_constructor_variable ins_pos common_defs type=:(TA {type_index={glob_module,glob_object},type_arity} types) (error, type_var_heap, td_infos) = check_type_of_constructor_variable_for_TA glob_module glob_object type_arity types ins_pos common_defs type error type_var_heap td_infos check_type_of_constructor_variable ins_pos common_defs type=:(TAS {type_index={glob_module,glob_object},type_arity} types _) (error, type_var_heap, td_infos) = check_type_of_constructor_variable_for_TA glob_module glob_object type_arity types ins_pos common_defs type error type_var_heap td_infos check_type_of_constructor_variable ins_pos common_defs type=:(arg_type --> result_type) (error, type_var_heap, td_infos) = (checkErrorWithIdentPos (newPosition empty_id ins_pos) " instance type should be coercible" error, type_var_heap, td_infos) //AA.. /* // ??? not sure if it is correct check_type_of_constructor_variable ins_pos common_defs TArrow (error, type_var_heap, td_infos) = (checkErrorWithIdentPos (newPosition empty_id ins_pos) " instance type should be coercible" error, type_var_heap, td_infos) check_type_of_constructor_variable ins_pos common_defs type=:(TArrow1 arg_type) (error, type_var_heap, td_infos) = (checkErrorWithIdentPos (newPosition empty_id ins_pos) " instance type should be coercible" error, type_var_heap, td_infos) */ //..AA check_type_of_constructor_variable ins_pos common_defs type=:(cv :@: types) (error, type_var_heap, td_infos) = (checkError (newPosition empty_id ins_pos) " instance type should be coercible" error, type_var_heap, td_infos) check_type_of_constructor_variable ins_pos common_defs type state = state check_type_of_constructor_variable_for_TA glob_module glob_object type_arity types ins_pos common_defs type error type_var_heap td_infos # {td_arity,td_ident} = common_defs.[glob_module].com_type_defs.[glob_object] ({tdi_properties,tdi_cons_vars}, td_infos) = td_infos![glob_module].[glob_object] | tdi_properties bitand cIsNonCoercible == 0 # ({sc_neg_vect}, type_var_heap, td_infos) = signClassification glob_object glob_module [TopSignClass \\ cv <- tdi_cons_vars ] common_defs type_var_heap td_infos = (check_sign type (sc_neg_vect >> type_arity) (td_arity - type_arity) error, type_var_heap, td_infos) = (checkErrorWithIdentPos (newPosition empty_id ins_pos) " instance type should be coercible" error, type_var_heap, td_infos) where check_sign type neg_signs arg_nr error | arg_nr == 0 = error | neg_signs bitand 1 == 0 = check_sign type (neg_signs >> 1) (dec arg_nr) error = checkError type " all arguments of an instance type should have a non-negative sign" error type_instances list_inferred_types ir_from ir_to class_instances ti funs_and_state | ir_from == ir_to = funs_and_state # funs_and_state = type_component list_inferred_types [ir_from] class_instances ti funs_and_state = type_instances list_inferred_types (inc ir_from) ir_to class_instances ti funs_and_state type_components list_inferred_types group_index comps class_instances ti funs_and_state | group_index == size comps = funs_and_state #! comp = comps.[group_index] # funs_and_state = type_component list_inferred_types comp.group_members class_instances ti funs_and_state = type_components list_inferred_types (inc group_index) comps class_instances ti funs_and_state /* show_component comp fun_defs = foldSt show_fun comp ([], fun_defs) where show_fun fun_index (names, fun_defs) # ({fun_ident}, fun_defs) = fun_defs![fun_index] = ([fun_ident : names], fun_defs) */ get_index_of_start_rule predef_symbols # ({pds_def, pds_module}, predef_symbols) = predef_symbols![PD_Start] | pds_def <> NoIndex && pds_module == main_dcl_module_n = (pds_def, predef_symbols) = (NoIndex, predef_symbols) type_component list_inferred_types comp class_instances ti=:{ti_common_defs} (type_error, predef_symbols, special_instances, out, ts) # (start_index, predef_symbols) = get_index_of_start_rule predef_symbols // # (functions, fun_defs) = show_component comp fun_defs # (predef_symbols, ts) = CreateInitialSymbolTypes start_index ti_common_defs comp (predef_symbols, ts) | not ts.ts_error.ea_ok = (True, predef_symbols, special_instances, out, create_erroneous_function_types comp { ts & ts_var_store = 0, ts_attr_store = FirstAttrVar, ts_cons_variables = [], ts_exis_variables = [], ts_error = { ts.ts_error & ea_ok = True } }) # (fun_reqs, ts) = type_functions comp ti ts #! nr_of_type_variables = ts.ts_var_store # (subst, ts_type_heaps, ts_error) = unify_requirements_of_functions fun_reqs ti (createArray nr_of_type_variables TE) ts.ts_type_heaps ts.ts_error | not ts_error.ea_ok = (True, predef_symbols, special_instances, out, create_erroneous_function_types comp { ts & ts_type_heaps = ts_type_heaps, ts_error = { ts_error & ea_ok = True }, ts_var_store = 0, ts_attr_store = FirstAttrVar, ts_cons_variables = [], ts_exis_variables = []}) # {ts_attr_store,ts_var_heap,ts_var_store,ts_expr_heap,ts_td_infos,ts_cons_variables,ts_exis_variables} = ts (cons_var_vects, subst) = determine_cons_variables ts_cons_variables (createArray (inc (BITINDEX nr_of_type_variables)) 0, subst) (subst, nr_of_attr_vars, ts_type_heaps, ts_td_infos) = liftSubstitution subst ti_common_defs cons_var_vects ts_attr_store ts_type_heaps ts_td_infos coer_demanded ={{ CT_Empty \\ i <- [0 .. nr_of_attr_vars - 1] } & [AttrUni] = CT_Unique } coer_offered = {{ CT_Empty \\ i <- [0 .. nr_of_attr_vars - 1] } & [AttrMulti] = CT_NonUnique } coercion_env = build_initial_coercion_env fun_reqs {coer_demanded = coer_demanded, coer_offered = coer_offered } (over_info, (subst, ts_expr_heap)) = collect_and_expand_overloaded_calls fun_reqs [] (subst, ts_expr_heap) (contexts, coercion_env, local_pattern_variables, dict_types, {os_type_heaps, os_var_heap, os_symbol_heap, os_generic_heap, os_predef_symbols, os_special_instances, os_error}) = tryToSolveOverloading over_info main_dcl_module_n ti_common_defs class_instances coercion_env { os_type_heaps = ts_type_heaps, os_var_heap = ts_var_heap, os_symbol_heap = ts_expr_heap, os_generic_heap = ts.ts_generic_heap, os_predef_symbols = predef_symbols, os_error = ts_error, os_special_instances = special_instances } dcl_modules //ts = {ts & ts_generic_heap = os_generic_heap} | not os_error.ea_ok = (True, os_predef_symbols, os_special_instances, out, create_erroneous_function_types comp { ts & ts_type_heaps = os_type_heaps, ts_error = { os_error & ea_ok = True }, ts_var_store = 0, ts_attr_store = FirstAttrVar, ts_cons_variables = [], ts_exis_variables = [], ts_td_infos = ts_td_infos, ts_expr_heap = os_symbol_heap, ts_var_heap = os_var_heap,ts_generic_heap=os_generic_heap}) # (fun_defs, coercion_env, subst, ts_td_infos, os_var_heap, os_symbol_heap, os_error) = makeSharedReferencesNonUnique comp ts.ts_fun_defs coercion_env subst ts_td_infos os_var_heap os_symbol_heap os_error # (subst, coercions, ts_td_infos, ts_type_heaps, ts_error) = build_coercion_env fun_reqs subst coercion_env ti_common_defs cons_var_vects ts_td_infos os_type_heaps os_error (subst, ts_fun_env) = expand_function_types comp subst ts.ts_fun_env ({coer_offered,coer_demanded},ts_error,ts_fun_env) = foldSt (add_unicity_of_essentially_unique_types_for_function ti_common_defs) comp (coercions,ts_error,ts_fun_env) (attr_partition, coer_demanded) = partitionateAttributes coer_offered coer_demanded (coer_demanded, ts_error) = check_existential_attributes ts_exis_variables attr_partition coer_demanded ts_error attr_var_env = createArray nr_of_attr_vars TA_None var_env = { subst & [i] = TE \\ i <- [0..dec ts_var_store]} ts = {ts & ts_error = ts_error, ts_fun_env = ts_fun_env, ts_type_heaps = ts_type_heaps, ts_td_infos = ts_td_infos, ts_var_heap = os_var_heap, ts_expr_heap = os_symbol_heap,ts_generic_heap=os_generic_heap,ts_fun_defs=fun_defs} (out, ts) = cleanUpAndCheckFunctionTypes comp fun_reqs dict_types start_index list_inferred_types ti_common_defs contexts coer_demanded attr_partition var_env attr_var_env (out,ts) | not ts.ts_error.ea_ok = (True, os_predef_symbols, os_special_instances, out, create_erroneous_function_types comp { ts & ts_var_store = 0, ts_attr_store = FirstAttrVar, ts_cons_variables = [], ts_exis_variables = [], ts_error = { ts.ts_error & ea_ok = True }}) # ts_type_heaps = ts.ts_type_heaps type_code_info = { tci_type_var_heap = ts_type_heaps.th_vars, tci_attr_var_heap = ts_type_heaps.th_attrs, tci_dcl_modules = dcl_modules, tci_common_defs = ti_common_defs } (fun_defs, ts_fun_env, ts_expr_heap, {tci_type_var_heap,tci_attr_var_heap}, ts_var_heap, ts_error, os_predef_symbols) = removeOverloadedFunctions comp local_pattern_variables main_dcl_module_n ts.ts_fun_defs ts.ts_fun_env ts.ts_expr_heap type_code_info ts.ts_var_heap ts.ts_error os_predef_symbols = ( type_error || not ts_error.ea_ok, os_predef_symbols, os_special_instances, out, { ts & ts_var_store = 0, ts_attr_store = FirstAttrVar, ts_cons_variables = [], ts_exis_variables = [], ts_expr_heap = ts_expr_heap, ts_error = { ts_error & ea_ok = True }, ts_var_heap = ts_var_heap, ts_type_heaps = { ts_type_heaps & th_vars = tci_type_var_heap, th_attrs = tci_attr_var_heap }, ts_fun_env = ts_fun_env, ts_fun_defs=fun_defs}) where add_unicity_of_essentially_unique_types_for_function ti_common_defs fun (coercions,ts_error,ts_fun_env) # (env_type, ts_fun_env) = ts_fun_env![fun] = case env_type of ExpandedType _ _ _ -> (coercions,ts_error,ts_fun_env) UncheckedType {tst_args, tst_result} # (coercions,ts_error) = foldSt (foldATypeSt (add_unicity_of_essentially_unique_type ti_common_defs) (\x st -> st)) [tst_result:tst_args] (coercions,ts_error) -> (coercions,ts_error,ts_fun_env) add_unicity_of_essentially_unique_type common_defs {at_attribute=TA_TempVar av_number, at_type=TA {type_index} _} (coercions,ts_error) # {td_attribute,td_ident} = common_defs.[type_index.glob_module].com_type_defs.[type_index.glob_object] = case td_attribute of TA_Unique // the type is essentially unique # (ok,coercions) = tryToMakeUnique av_number coercions | ok -> (coercions,ts_error) -> (coercions,type_not_unique_error td_ident ts_error) _ -> (coercions,ts_error) add_unicity_of_essentially_unique_type common_defs {at_attribute=TA_TempVar av_number, at_type=TAS {type_index} _ _} (coercions,ts_error) # {td_attribute,td_ident} = common_defs.[type_index.glob_module].com_type_defs.[type_index.glob_object] = case td_attribute of TA_Unique // the type is essentially unique # (ok,coercions) = tryToMakeUnique av_number coercions | ok -> (coercions,ts_error) -> (coercions,type_not_unique_error td_ident ts_error) _ -> (coercions,ts_error) add_unicity_of_essentially_unique_type _ _ coercions_and_ts_error = coercions_and_ts_error type_not_unique_error type_name err # err = errorHeading "Uniqueness error " err = {err & ea_file = err.ea_file <<< "* annotated type " <<< type_name <<< " occurs non unique in inferred function type"<<< '\n'} unify_requirements_of_functions :: ![FunctionRequirements] !TypeInput !*{!Type} !*TypeHeaps !*ErrorAdmin -> (!*{!Type},!*TypeHeaps,!*ErrorAdmin) unify_requirements_of_functions [{fe_requirements={req_type_coercion_groups},fe_location={ip_ident}} : reqs_list] ti subst heaps ts_error # (subst, heaps, ts_error) = foldSt (unify_requirements_within_one_position ip_ident ti) req_type_coercion_groups (subst, heaps, ts_error) = unify_requirements_of_functions reqs_list ti subst heaps ts_error unify_requirements_of_functions [] ti subst heaps ts_error = (subst, heaps, ts_error) unify_requirements_within_one_position :: !Ident !TypeInput !TypeCoercionGroup !(*{!Type}, !*TypeHeaps, !*ErrorAdmin) -> (*{!Type}, !*TypeHeaps, !*ErrorAdmin) unify_requirements_within_one_position _ ti {tcg_type_coercions, tcg_position=NoPos} (subst, heaps, ts_error) = unify_coercions tcg_type_coercions ti subst heaps ts_error unify_requirements_within_one_position fun_ident ti {tcg_type_coercions, tcg_position} (subst, heaps, ts_error) # ts_error = setErrorAdmin (newPosition fun_ident tcg_position) ts_error = unify_coercions tcg_type_coercions ti subst heaps ts_error build_initial_coercion_env [{fe_requirements={req_attr_coercions},fe_location} : reqs_list] coercion_env = build_initial_coercion_env reqs_list (add_to_initial_coercion_env req_attr_coercions coercion_env) build_initial_coercion_env [] coercion_env = coercion_env add_to_initial_coercion_env [{ac_offered,ac_demanded} : attr_coercions] coercion_env = add_to_initial_coercion_env attr_coercions (newInequality ac_offered ac_demanded coercion_env) add_to_initial_coercion_env [] coercion_env = coercion_env determine_cons_variables variables vect_and_subst = foldSt determine_cons_variable variables vect_and_subst where determine_cons_variable tv_number (bitvects, subst) # (type, subst) = subst![tv_number] = case type of TE -> (set_bit tv_number bitvects, subst) // ---> ("determine_cons_variable1", tv_number) TempV var_number -> (set_bit var_number bitvects, subst) // ---> ("determine_cons_variable2", var_number) _ -> (bitvects, subst) build_coercion_env :: [FunctionRequirements] *{!Type} *Coercions {#CommonDefs} {#Int} *{#*{#TypeDefInfo}} *TypeHeaps !*ErrorAdmin -> (!.{!Type},!.Coercions,!.{#.{#TypeDefInfo}},!.TypeHeaps,!.ErrorAdmin); build_coercion_env [{fe_requirements={req_type_coercion_groups},fe_location={ip_ident}} : reqs_list] subst coercion_env common_defs cons_var_vects type_signs type_var_heap error # (subst, coercion_env, type_signs, type_var_heap, error) = foldSt (build_coercion_env_for_alternative ip_ident common_defs cons_var_vects) req_type_coercion_groups (subst, coercion_env, type_signs, type_var_heap, error) = build_coercion_env reqs_list subst coercion_env common_defs cons_var_vects type_signs type_var_heap error build_coercion_env [] subst coercion_env common_defs cons_var_vects type_signs type_var_heap error = (subst, coercion_env, type_signs, type_var_heap, error) build_coercion_env_for_alternative fun_ident common_defs cons_var_vects {tcg_position, tcg_type_coercions} (subst, coercion_env, type_signs, type_var_heap, error) # error = setErrorAdmin (newPosition fun_ident tcg_position) error = add_to_coercion_env tcg_type_coercions subst coercion_env common_defs cons_var_vects type_signs type_var_heap error add_to_coercion_env [{tc_offered,tc_demanded,tc_coercible,tc_position} : attr_coercions] subst coercion_env common_defs cons_var_vects type_signs type_var_heap error # (opt_error_info, subst, coercion_env, type_signs, type_var_heap) = determineAttributeCoercions tc_offered tc_demanded tc_coercible False subst coercion_env common_defs cons_var_vects type_signs type_var_heap (coercion_env, error) = case opt_error_info of No -> (coercion_env, error) Yes (positions, exp_off_type) # (error=:{ea_file}) = errorHeading "Uniqueness error" error (coercion_env, copy_coercion_env) = copyCoercions coercion_env format = { form_properties = cMarkAttribute, form_attr_position = Yes (reverse positions, copy_coercion_env) } ea_file = case tc_position of CP_FunArg _ _ -> ea_file <<< "\"" <<< tc_position <<< "\" " CP_SymbArgAndExpression _ _ _ -> ea_file <<< "\"" <<< tc_position <<< "\" " CP_LiftedFunArg _ _ -> ea_file <<< "\"" <<< tc_position <<< "\" " _ -> ea_file ea_file = ea_file <<< "attribute at position indicated by ^ could not be coerced " <:: (format, exp_off_type, Yes initialTypeVarBeautifulizer) <<< '\n' -> (coercion_env, { error & ea_file = ea_file }) = add_to_coercion_env attr_coercions subst coercion_env common_defs cons_var_vects type_signs type_var_heap error add_to_coercion_env [] subst coercion_env common_defs cons_var_vects type_signs type_var_heap error = (subst, coercion_env, type_signs, type_var_heap, error) check_existential_attributes ts_exis_variables partition coercions ts_error = foldSt (check_existential_attributes_at_pos partition) ts_exis_variables (coercions, ts_error) where check_existential_attributes_at_pos partition (pos, attr_vars) (coercions, ts_error) # (ok, coercions) = checkExistentionalAttributeVars attr_vars partition coercions | ok = (coercions, ts_error) = (coercions, existentialError pos ts_error) collect_and_expand_overloaded_calls [] calls subst_and_heap = (calls, subst_and_heap) collect_and_expand_overloaded_calls [{fe_context=Yes context, fe_requirements={req_overloaded_calls,req_case_and_let_exprs}, fe_location, fe_index}:reqs] calls (subst, expr_heap) # (_, context, subst) = arraySubst context subst subst_expr_heap = expand_case_or_let_types req_case_and_let_exprs (subst, expr_heap) = collect_and_expand_overloaded_calls reqs [(Yes context, req_overloaded_calls, fe_location, fe_index) : calls] (foldSt expand_type_contexts req_overloaded_calls subst_expr_heap) collect_and_expand_overloaded_calls [{fe_context, fe_requirements={req_overloaded_calls,req_case_and_let_exprs}, fe_location, fe_index}:reqs] calls subst_expr_heap # subst_expr_heap = expand_case_or_let_types req_case_and_let_exprs subst_expr_heap = collect_and_expand_overloaded_calls reqs [(fe_context, req_overloaded_calls, fe_location, fe_index) : calls] (foldSt expand_type_contexts req_overloaded_calls subst_expr_heap) expand_type_contexts over_info_ptr (subst, expr_heap) = case readPtr over_info_ptr expr_heap of (EI_Overloaded info, expr_heap) # (changed,oc_context,subst) = arraySubst info.oc_context subst | changed -> (subst,expr_heap <:= (over_info_ptr, EI_Overloaded {info & oc_context = oc_context})) -> (subst,expr_heap) (EI_OverloadedWithVarContexts info, expr_heap) # (changed,ocvc_context,subst) = arraySubst info.ocvc_context subst | changed # (changed2,ocvc_var_contexts,subst) = arraySubst info.ocvc_var_contexts subst | changed2 # expr_heap = expr_heap <:= (over_info_ptr, EI_OverloadedWithVarContexts {info & ocvc_context=ocvc_context,ocvc_var_contexts=ocvc_var_contexts}) -> (subst,expr_heap) # expr_heap = expr_heap <:= (over_info_ptr, EI_OverloadedWithVarContexts {info & ocvc_context=ocvc_context}) -> (subst,expr_heap) # (changed,ocvc_var_contexts,subst) = arraySubst info.ocvc_var_contexts subst | changed # expr_heap = expr_heap <:= (over_info_ptr, EI_OverloadedWithVarContexts {info & ocvc_var_contexts=ocvc_var_contexts}) -> (subst,expr_heap) -> (subst,expr_heap) (EI_CaseTypeWithContexts case_type contexts, expr_heap) # (changed,contexts,subst) = expand_constructor_contexts contexts subst | changed # expr_heap = expr_heap <:= (over_info_ptr, EI_CaseTypeWithContexts case_type contexts) -> (subst,expr_heap) -> (subst,expr_heap) expand_constructor_contexts [context=:(cons_symbol,cons_context):contexts] subst # (changed1,expanded_contexts,subst) = expand_constructor_contexts contexts subst | changed1 # (changed2,cons_context,subst) = arraySubst cons_context subst | changed2 = (True,[(cons_symbol,cons_context):expanded_contexts],subst) = (True,[context:expanded_contexts],subst) # (changed2,cons_context,subst) = arraySubst cons_context subst | changed2 = (True,[(cons_symbol,cons_context):contexts],subst) = (False,[context:contexts],subst) expand_constructor_contexts [] subst = (False,[],subst) expand_case_or_let_types info_ptrs subst_expr_heap = foldSt expand_case_or_let_type info_ptrs subst_expr_heap expand_case_or_let_type info_ptr (subst, expr_heap) = case (readPtr info_ptr expr_heap) of (EI_CaseType case_type, expr_heap) # (changed, case_type, subst) = arraySubst case_type subst | changed -> (subst, expr_heap <:= (info_ptr, EI_CaseType case_type)) -> (subst, expr_heap) (EI_LetType let_type, expr_heap) # (changed, let_type, subst) = arraySubst let_type subst | changed -> (subst, expr_heap <:= (info_ptr, EI_LetType let_type)) -> (subst, expr_heap) (EI_CaseTypeWithContexts case_type contexts, expr_heap) # (changed, case_type, subst) = arraySubst case_type subst | changed -> (subst, expr_heap <:= (info_ptr, EI_CaseTypeWithContexts case_type contexts)) -> (subst, expr_heap) expand_function_types :: ![Int] !*{!Type} *{! FunctionType} -> (!*{!Type}, *{! FunctionType}) expand_function_types [fun : funs] subst ts_fun_env # (fun_type, ts_fun_env) = ts_fun_env![fun] = case fun_type of UncheckedType tst # (_, exp_tst, subst) = arraySubst tst subst -> expand_function_types funs subst { ts_fun_env & [fun] = UncheckedType exp_tst} SpecifiedType ft _ tst # (_, exp_tst, subst) = arraySubst tst subst -> expand_function_types funs subst { ts_fun_env & [fun] = ExpandedType ft tst exp_tst} expand_function_types [] subst ts_fun_env = (subst, ts_fun_env) update_function_types :: !Index !{!Group} !*{!FunctionType} !*{#FunDef} -> (!*{#FunDef}, !*{!FunctionType}) update_function_types group_index comps fun_env fun_defs | group_index == size comps = (fun_defs, fun_env) #! comp = comps.[group_index] # (fun_defs, fun_env) = update_function_types_in_component comp.group_members fun_env fun_defs = update_function_types (inc group_index) comps fun_env fun_defs where update_function_types_in_component :: ![Index] !*{!FunctionType} !*{#FunDef} -> (!*{#FunDef}, !*{!FunctionType}) update_function_types_in_component [fun_index : funs] fun_env fun_defs # (CheckedType checked_fun_type, fun_env) = fun_env![fun_index] # (fd, fun_defs) = fun_defs![fun_index] = case fd.fun_type of No -> update_function_types_in_component funs fun_env { fun_defs & [fun_index] = { fd & fun_type = Yes checked_fun_type }} Yes fun_type # nr_of_lifted_arguments = checked_fun_type.st_arity - fun_type.st_arity | nr_of_lifted_arguments > 0 # fun_type = addLiftedArgumentsToSymbolType fun_type nr_of_lifted_arguments checked_fun_type.st_args checked_fun_type.st_vars checked_fun_type.st_attr_vars checked_fun_type.st_context -> update_function_types_in_component funs fun_env { fun_defs & [fun_index] = { fd & fun_type = Yes fun_type }} -> update_function_types_in_component funs fun_env fun_defs update_function_types_in_component [] fun_env fun_defs = (fun_defs, fun_env) type_functions group ti ts = mapSt (type_function ti) group ts type_function ti fun_index ts=:{ts_fun_env, ts_var_heap, ts_error, ts_fun_defs} # (fd, ts_fun_defs) = ts_fun_defs![fun_index] (type, ts_fun_env) = ts_fun_env![fun_index] {fun_ident,fun_arity,fun_body=TransformedBody {tb_args,tb_rhs},fun_pos, fun_info, fun_type} = fd temp_fun_type = type_of type ts_var_heap = makeBase fun_ident tb_args temp_fun_type.tst_args ts_var_heap fe_location = newPosition fun_ident fun_pos ts_error = setErrorAdmin fe_location ts_error // ts = { ts & ts_var_heap = ts_var_heap, ts_error = ts_error} ts = { ts & ts_var_heap = ts_var_heap, ts_error = ts_error, ts_fun_defs = ts_fun_defs, ts_fun_env = ts_fun_env} reqs = { req_overloaded_calls = [], req_type_coercion_groups = [], req_type_coercions = [], req_attr_coercions = [], req_case_and_let_exprs = [] } (rhs_type, rhs_expr_ptr, (rhs_reqs, ts)) = requirements ti tb_rhs (reqs, ts) req_type_coercions = [{tc_demanded = temp_fun_type.tst_result,tc_offered = rhs_type, tc_position = CP_Expression tb_rhs, tc_coercible = True} : rhs_reqs.req_type_coercions ] ts_expr_heap = storeAttribute rhs_expr_ptr temp_fun_type.tst_result.at_attribute ts.ts_expr_heap type_coercion_group_from_accu = { tcg_type_coercions = req_type_coercions, tcg_position = fun_pos } req_type_coercion_groups = [type_coercion_group_from_accu:rhs_reqs.req_type_coercion_groups] = ( { fe_location = fe_location, fe_context = if (has_option fun_type) (Yes temp_fun_type.tst_context) No, fe_index = fun_index, fe_requirements = { rhs_reqs & req_type_coercions = [], req_type_coercion_groups = req_type_coercion_groups } }, {ts & ts_expr_heap = ts_expr_heap}) where has_option (Yes _) = True has_option No = False type_of (UncheckedType tst) = tst type_of (SpecifiedType _ _ tst) = tst create_special_instances {si_array_instances,si_list_instances,si_tail_strict_list_instances,si_next_array_member_index} fun_env_size common_defs fun_defs predef_symbols type_heaps error # fun_defs = add_extra_elements_to_fun_def_array (si_next_array_member_index-fun_env_size) fun_defs with add_extra_elements_to_fun_def_array n_new_elements fun_defs | n_new_elements==0 = fun_defs # dummy_fun_def = { fun_ident = {id_name="",id_info=nilPtr},fun_arity=0,fun_priority=NoPrio,fun_body=NoBody,fun_type=No,fun_pos=NoPos, fun_kind=FK_Unknown,fun_lifted=0,fun_info = {fi_calls=[],fi_group_index=0,fi_def_level=NotALevel,fi_free_vars=[],fi_local_vars=[],fi_dynamics=[],fi_properties=0}} = {createArray (size fun_defs+n_new_elements) dummy_fun_def & [i]=fun_defs.[i] \\ i<-[0..size fun_defs-1]} (array_first_instance_indices,fun_defs, predef_symbols, type_heaps, error) = convert_array_instances si_array_instances common_defs fun_defs predef_symbols type_heaps error (list_first_instance_indices,fun_defs, predef_symbols, type_heaps, error) = convert_list_instances si_list_instances PD_UListClass common_defs fun_defs predef_symbols type_heaps error (tail_strict_list_first_instance_indices,fun_defs, predef_symbols, type_heaps, error) = convert_list_instances si_tail_strict_list_instances PD_UTSListClass common_defs fun_defs predef_symbols type_heaps error array_first_instance_indices = first_instance_indices si_array_instances = (array_first_instance_indices,list_first_instance_indices,tail_strict_list_first_instance_indices,fun_defs,predef_symbols,type_heaps,error) where convert_array_instances array_instances common_defs fun_defs predef_symbols type_heaps error | isEmpty array_instances = ([],fun_defs, predef_symbols, type_heaps, error) # ({pds_module,pds_def},predef_symbols) = predef_symbols![PD_UnboxedArrayType] # pds_ident = predefined_idents.[PD_UnboxedArrayType] unboxed_array_type = TA (MakeTypeSymbIdent { glob_object = pds_def, glob_module = pds_module } pds_ident 0) [] ({pds_module,pds_def},predef_symbols) = predef_symbols![PD_ArrayClass] {class_members} = common_defs.[pds_module].com_class_defs.[pds_def] array_members = common_defs.[pds_module].com_member_defs (offset_table, _, predef_symbols) = arrayFunOffsetToPD_IndexTable array_members predef_symbols (fun_defs, type_heaps, error) = foldSt (convert_array_instance class_members array_members unboxed_array_type offset_table) array_instances (fun_defs, type_heaps, error) array_first_instance_indices = first_instance_indices array_instances = (array_first_instance_indices,fun_defs, predef_symbols, type_heaps, error) where convert_array_instance class_members array_members unboxed_array_type offset_table {ai_record,ai_members} funs_heaps_and_error = create_instance_types class_members array_members unboxed_array_type offset_table (TA ai_record []) (size class_members) funs_heaps_and_error where first_instance_index=ai_members.[0].cim_index create_instance_types :: {#DefinedSymbol} {#MemberDef} Type {#Int} Type !Int !(!*{#FunDef}, !*TypeHeaps, !*ErrorAdmin) -> (!*{#FunDef}, !*TypeHeaps, !*ErrorAdmin); create_instance_types members array_members unboxed_array_type offset_table record_type member_index funs_heaps_and_error | member_index == 0 = funs_heaps_and_error # member_index = dec member_index funs_heaps_and_error = create_instance_type members array_members unboxed_array_type offset_table record_type member_index funs_heaps_and_error = create_instance_types members array_members unboxed_array_type offset_table record_type member_index funs_heaps_and_error create_instance_type members array_members unboxed_array_type offset_table record_type member_index (fun_defs, type_heaps, error) # {me_type,me_ident,me_class_vars,me_pos} = array_members.[members.[member_index].ds_index] (instance_type, _, type_heaps, _, error) = determineTypeOfMemberInstance me_type me_class_vars {it_vars = [], it_attr_vars = [], it_context = [], it_types = [unboxed_array_type, record_type]} SP_None type_heaps No error instance_type = makeElemTypeOfArrayFunctionStrict instance_type member_index offset_table fun_index = first_instance_index+member_index fun = { fun_ident = me_ident , fun_arity = me_type.st_arity , fun_priority = NoPrio , fun_body = NoBody , fun_type = Yes instance_type , fun_pos = me_pos , fun_kind = FK_Unknown , fun_lifted = 0 , fun_info = EmptyFunInfo } = ({fun_defs & [fun_index]=fun}, type_heaps, error) convert_list_instances list_instances predef_list_class_index common_defs fun_defs predef_symbols type_heaps error | isEmpty list_instances = ([],fun_defs, predef_symbols, type_heaps, error) # ({pds_module,pds_def},predef_symbols) = predef_symbols![predef_list_class_index] {class_members} = common_defs.[pds_module].com_class_defs.[pds_def] list_members = common_defs.[pds_module].com_member_defs (fun_defs, type_heaps, error) = foldSt (convert_list_instance class_members list_members) list_instances (fun_defs, type_heaps, error) list_first_instance_indices = first_instance_indices list_instances = (list_first_instance_indices,fun_defs, predef_symbols, type_heaps, error) where convert_list_instance class_members list_members {ai_record,ai_members} funs_heaps_and_error = create_instance_types class_members list_members (TA ai_record []) (size class_members) funs_heaps_and_error where first_instance_index=ai_members.[0].cim_index create_instance_types :: {#DefinedSymbol} {#MemberDef} Type !Int !(!*{#FunDef}, !*TypeHeaps, !*ErrorAdmin) -> (!*{#FunDef}, !*TypeHeaps, !*ErrorAdmin) create_instance_types members list_members record_type member_index funs_heaps_and_error | member_index == 0 = funs_heaps_and_error # member_index = dec member_index funs_heaps_and_error = create_instance_type members list_members record_type member_index funs_heaps_and_error = create_instance_types members list_members record_type member_index funs_heaps_and_error create_instance_type members list_members record_type member_index (fun_defs, type_heaps, error) # {me_type,me_ident,me_class_vars,me_pos} = list_members.[members.[member_index].ds_index] (instance_type, _, type_heaps, _, error) = determineTypeOfMemberInstance me_type me_class_vars {it_vars = [], it_attr_vars = [], it_context = [], it_types = [record_type]} SP_None type_heaps No error fun_index = first_instance_index+member_index fun = { fun_ident = me_ident , fun_arity = me_type.st_arity , fun_priority = NoPrio , fun_body = NoBody , fun_type = Yes instance_type , fun_pos = me_pos , fun_kind = FK_Unknown , fun_lifted = 0 , fun_info = {EmptyFunInfo & fi_properties=FI_IsUnboxedListOfRecordsConsOrNil} } = ({fun_defs & [fun_index]=fun}, type_heaps, error) first_instance_indices instances = [ai_members.[0].cim_index \\ {ai_members}<-instances] create_erroneous_function_types group ts = foldSt create_erroneous_function_type group ts create_erroneous_function_type fun ts # (env_type, ts) = ts!ts_fun_env.[fun] = case env_type of ExpandedType fun_type tmp_fun_type exp_fun_type # (fun_type, ts_type_heaps) = extendSymbolType fun_type tmp_fun_type.tst_lifted ts.ts_type_heaps -> { ts & ts_type_heaps = ts_type_heaps, ts_fun_env = { ts.ts_fun_env & [fun] = CheckedType fun_type }} UncheckedType tmp_fun_type # (clean_fun_type, ts_type_heaps) = cleanSymbolType tmp_fun_type.tst_arity ts.ts_type_heaps -> { ts & ts_type_heaps = ts_type_heaps, ts_fun_env = { ts.ts_fun_env & [fun] = CheckedType clean_fun_type }} SpecifiedType fun_type _ tmp_fun_type # (fun_type, ts_type_heaps) = extendSymbolType fun_type tmp_fun_type.tst_lifted ts.ts_type_heaps -> { ts & ts_type_heaps = ts_type_heaps, ts_fun_env = { ts.ts_fun_env & [fun] = CheckedType fun_type }} CheckedType _ -> ts clear_var_heap fun_types common_defs var_heap # var_heap = mapArraySt clear_functions_in_module fun_types var_heap = mapArraySt clear_members_in_module common_defs var_heap where clear_functions_in_module module_types var_heap = mapArraySt clear_function module_types var_heap clear_function {ft_type_ptr} var_heap | isNilPtr ft_type_ptr = var_heap = var_heap <:= (ft_type_ptr, VI_Empty) clear_members_in_module common_def var_heap = mapArraySt clear_member common_def.com_member_defs var_heap clear_member {me_type_ptr} var_heap | isNilPtr me_type_ptr = var_heap = var_heap <:= (me_type_ptr, VI_Empty) mapArraySt f a s :== map_a_st 0 a s where map_a_st i a st | i==size a = st # (ai, a) = a![i] = map_a_st (i+1) a (f ai st) is_rare_name {id_name} :== id_name.[0]=='_' getPositionOfExpr expr=:(Var var) var_heap # (type_info, var_heap) = getTypeInfoOfVariable var var_heap = case type_info of VITI_Coercion position -> (position, var_heap) VITI_PatternType _ _ _ (VITI_Coercion position) -> (position, var_heap) _ -> (CP_Expression expr, var_heap) getPositionOfExpr expr var_heap = (CP_Expression expr, var_heap) getTypeInfoOfVariable {var_info_ptr} var_heap # (var_info, var_heap) = readPtr var_info_ptr var_heap = case var_info of VI_Type _ type_info -> (type_info, var_heap) VI_FAType _ _ type_info -> (type_info, var_heap) VI_FATypeC _ _ _ type_info -> (type_info, var_heap) empty_id =: { id_name = "", id_info = nilPtr } instance <<< (Ptr a) where (<<<) file ptr = file <<< ptrToInt ptr instance <<< AttrCoercion where (<<<) file {ac_demanded,ac_offered} = file <<< "AttrCoercion: " <<< ac_demanded <<< '~' <<< ac_offered instance <<< TypeCoercion where (<<<) file {tc_demanded,tc_offered} = file <<< "TypeCoercion: " <<< tc_demanded <<< '~' <<< tc_offered instance <<< TypeContext where (<<<) file co = file <<< "TypeContext: (tc_class)=" <<< co.tc_class <<< " (tc_var)=" <<< ptrToInt co.tc_var <<< " (tc_types)=" <<< " " <<< co.tc_types instance <<< DefinedSymbol where (<<<) file {ds_ident} = file <<< "DefinedSymbol: " <<< ds_ident instance <<< FunctionType where (<<<) file (CheckedType _) = file <<< "CheckedType" (<<<) file (SpecifiedType _ _ _) = file <<< "SpecifiedType" (<<<) file (UncheckedType _) = file <<< "UncheckedType" (<<<) file (ExpandedType _ _ _) = file <<< "ExpandedType" (<<<) file EmptyFunctionType = file <<< "EmptyFunctionType"