implementation module partition import syntax, transform, utilities // PARTITIONING :: PartitioningInfo = { pi_marks :: !.{# Int} , pi_next_num :: !Int , pi_next_group :: !Int , pi_groups :: ![ComponentMembers] , pi_deps :: ![Int] } NotChecked :== -1 partitionateFunctions :: !*{# FunDef} ![IndexRange] -> (!*{!Component}, !*{# FunDef}) partitionateFunctions fun_defs ranges #! max_fun_nr = size fun_defs # partitioning_info = { pi_marks = createArray max_fun_nr NotChecked, pi_deps = [], pi_next_num = 0, pi_next_group = 0, pi_groups = [] } (fun_defs, {pi_groups,pi_next_group}) = foldSt (partitionate_functions max_fun_nr) ranges (fun_defs, partitioning_info) groups = { {component_members = group} \\ group <- reverse pi_groups } = (groups, fun_defs) where partitionate_functions :: !Index !IndexRange !(!*{# FunDef}, !*PartitioningInfo) -> (!*{# FunDef}, !*PartitioningInfo) partitionate_functions max_fun_nr ir=:{ir_from,ir_to} (fun_defs, pi=:{pi_marks}) | ir_from == ir_to = (fun_defs, pi) | pi_marks.[ir_from] == NotChecked # (_, fun_defs, pi) = partitionate_function ir_from max_fun_nr fun_defs pi = partitionate_functions max_fun_nr { ir & ir_from = inc ir_from } (fun_defs, pi) = partitionate_functions max_fun_nr { ir & ir_from = inc ir_from } (fun_defs, pi) partitionate_function :: !Int !Int !*{# FunDef} !*PartitioningInfo -> *(!Int, !*{# FunDef}, !*PartitioningInfo) partitionate_function fun_index max_fun_nr fun_defs pi=:{pi_next_num} # (fd, fun_defs) = fun_defs![fun_index] # {fi_calls} = fd.fun_info (min_dep, fun_defs, pi) = visit_functions fi_calls max_fun_nr max_fun_nr fun_defs (push_on_dep_stack fun_index pi) with visit_functions :: ![FunCall] !Int !Int !*{# FunDef} !*PartitioningInfo -> *(!Int, !*{# FunDef}, !*PartitioningInfo) visit_functions [FunCall fc_index _:funs] min_dep max_fun_nr fun_defs pi=:{pi_marks} #! mark = pi_marks.[fc_index] | mark == NotChecked # (mark, fun_defs, pi) = partitionate_function fc_index max_fun_nr fun_defs pi = visit_functions funs (min min_dep mark) max_fun_nr fun_defs pi = visit_functions funs (min min_dep mark) max_fun_nr fun_defs pi visit_functions [DclFunCall module_index fc_index:funs] min_dep max_fun_nr fun_defs pi = visit_functions funs min_dep max_fun_nr fun_defs pi visit_functions [] min_dep max_fun_nr fun_defs pi = (min_dep, fun_defs, pi) = try_to_close_group fun_index pi_next_num min_dep max_fun_nr fun_defs pi push_on_dep_stack :: !Int !*PartitioningInfo -> *PartitioningInfo; push_on_dep_stack fun_index pi=:{pi_deps,pi_marks,pi_next_num} = { pi & pi_deps = [fun_index : pi_deps], pi_marks = { pi_marks & [fun_index] = pi_next_num}, pi_next_num = inc pi_next_num} try_to_close_group :: !Int !Int !Int !Int !*{# FunDef} !*PartitioningInfo -> *(!Int, !*{# FunDef}, !*PartitioningInfo) try_to_close_group fun_index fun_nr min_dep max_fun_nr fun_defs pi=:{pi_marks, pi_deps, pi_groups, pi_next_group} | fun_nr <= min_dep # (pi_deps, pi_marks, group, fun_defs) = close_group False False fun_index pi_deps pi_marks NoComponentMembers max_fun_nr pi_next_group fun_defs pi = { pi & pi_deps = pi_deps, pi_marks = pi_marks, pi_next_group = inc pi_next_group, pi_groups = [group : pi_groups] } = (max_fun_nr, fun_defs, pi) = (min_dep, fun_defs, pi) where close_group :: !Bool !Bool !Int ![Int] !*{# Int} !ComponentMembers !Int !Int !*{# FunDef} -> (![Int], !*{# Int}, !ComponentMembers, !*{# FunDef}) close_group n_r_known non_recursive fun_index [d:ds] marks group max_fun_nr group_number fun_defs # marks = { marks & [d] = max_fun_nr } # (fd,fun_defs) = fun_defs![d] # non_recursive = case n_r_known of True -> non_recursive _ -> case fun_index == d of True -> isEmpty [fc \\ fc <- fd.fun_info.fi_calls | case fc of FunCall idx _ -> idx == d; _ -> False] _ -> False # fd = { fd & fun_info.fi_group_index = group_number, fun_info.fi_properties = set_rec_prop non_recursive fd.fun_info.fi_properties} # fun_defs = { fun_defs & [d] = fd} | d == fun_index = (ds, marks, ComponentMember d group, fun_defs) = close_group True non_recursive fun_index ds marks (ComponentMember d group) max_fun_nr group_number fun_defs :: PartitioningInfo` = { pi_marks` :: !.{# Int} , pi_next_num` :: !Int , pi_next_group` :: !Int , pi_groups` :: ![ComponentMembers] , pi_deps` :: ![Int] , pi_collect` :: !.CollectState } stripStrictLets :: !*{# FunDef} !*PredefinedSymbols !*VarHeap !*ExpressionHeap !*ErrorAdmin -> (!*{# FunDef}, !*PredefinedSymbols, !*VarHeap, !*ExpressionHeap, !*ErrorAdmin) stripStrictLets fun_defs predef_symbols var_heap sym_heap error_admin # (cs_predef,predef_symbols) = get_predef_symbols_for_transform predef_symbols # collect_state = { cos_predef_symbols_for_transform = cs_predef , cos_var_heap = var_heap , cos_expression_heap = sym_heap , cos_error = error_admin } # (fun_defs,collect_state) = aMapSt determine_ref_counts fun_defs collect_state = (fun_defs,predef_symbols,collect_state.cos_var_heap, collect_state.cos_expression_heap, collect_state.cos_error) where aMapSt f a s # (l,s) = mapSt f [e \\ e <-: a] s = ({e \\ e <- l},s) partitionateFunctions` :: !*{# FunDef} ![IndexRange] !Index !Int !Int !*PredefinedSymbols !*VarHeap !*ExpressionHeap !*ErrorAdmin -> (!*{!Component}, !*{# FunDef}, !*PredefinedSymbols, !*VarHeap, !*ExpressionHeap, !*ErrorAdmin) partitionateFunctions` fun_defs ranges main_dcl_module_n def_min def_max predef_symbols var_heap sym_heap error_admin #! max_fun_nr = size fun_defs # (cs_predef,predef_symbols) = get_predef_symbols_for_transform predef_symbols # collect_state = { cos_predef_symbols_for_transform = cs_predef , cos_var_heap = var_heap , cos_expression_heap = sym_heap , cos_error = error_admin } # partitioning_info = { pi_collect` = collect_state , pi_marks` = createArray max_fun_nr NotChecked , pi_deps` = [] , pi_next_num` = 0 , pi_next_group` = 0 , pi_groups` = [] } (fun_defs, {pi_groups`,pi_next_group`,pi_collect`}) = foldSt (partitionate_functions max_fun_nr) ranges (fun_defs, partitioning_info) groups = { {component_members = group} \\ group <- reverse pi_groups` } = (groups, fun_defs, predef_symbols, pi_collect`.cos_var_heap, pi_collect`.cos_expression_heap, pi_collect`.cos_error) where partitionate_functions :: !Index !IndexRange !(!*{# FunDef}, !*PartitioningInfo`) -> (!*{# FunDef}, !*PartitioningInfo`) partitionate_functions max_fun_nr ir=:{ir_from,ir_to} (fun_defs, pi=:{pi_marks`}) | ir_from == ir_to = (fun_defs, pi) | pi_marks`.[ir_from] == NotChecked # (_, fun_defs, pi) = partitionate_function ir_from max_fun_nr fun_defs pi = partitionate_functions max_fun_nr { ir & ir_from = inc ir_from } (fun_defs, pi) = partitionate_functions max_fun_nr { ir & ir_from = inc ir_from } (fun_defs, pi) partitionate_function :: !Int !Int !*{# FunDef} !*PartitioningInfo` -> *(!Int, !*{# FunDef}, !*PartitioningInfo`) partitionate_function fun_index max_fun_nr fun_defs pi=:{pi_next_num`,pi_collect`} # (fd, fun_defs) = fun_defs![fun_index] # (fd,pi_collect`) = determine_ref_counts fd pi_collect` # pi = {pi & pi_collect` = pi_collect`} # fc_state = find_calls { main_dcl_module_n=main_dcl_module_n , def_min=def_min , def_max=def_max , fun_index=fun_index } fd.fun_body {fun_calls = []} fi_calls = fc_state.fun_calls fd = {fd & fun_info.fi_calls = fi_calls} # fun_defs = {fun_defs & [fun_index] = fd} pi = push_on_dep_stack fun_index pi (min_dep, fun_defs, pi) = visit_functions fi_calls max_fun_nr max_fun_nr fun_defs pi with visit_functions :: ![FunCall] !Int !Int !*{# FunDef} !*PartitioningInfo` -> *(!Int, !*{# FunDef}, !*PartitioningInfo`) visit_functions [FunCall fc_index _:funs] min_dep max_fun_nr fun_defs pi=:{pi_marks`} #! mark = pi_marks`.[fc_index] | mark == NotChecked # (mark, fun_defs, pi) = partitionate_function fc_index max_fun_nr fun_defs pi = visit_functions funs (min min_dep mark) max_fun_nr fun_defs pi = visit_functions funs (min min_dep mark) max_fun_nr fun_defs pi visit_functions [GeneratedFunCall fc_index _:funs] min_dep max_fun_nr fun_defs pi=:{pi_marks`} #! mark = pi_marks`.[fc_index] | mark == NotChecked # (mark, fun_defs, pi) = partitionate_function fc_index max_fun_nr fun_defs pi = visit_functions funs (min min_dep mark) max_fun_nr fun_defs pi = visit_functions funs (min min_dep mark) max_fun_nr fun_defs pi visit_functions [DclFunCall module_index fc_index:funs] min_dep max_fun_nr fun_defs pi = visit_functions funs min_dep max_fun_nr fun_defs pi visit_functions [] min_dep max_fun_nr fun_defs pi = (min_dep, fun_defs, pi) = try_to_close_group fun_index pi_next_num` min_dep max_fun_nr fun_defs pi push_on_dep_stack :: !Int !*PartitioningInfo` -> *PartitioningInfo`; push_on_dep_stack fun_index pi=:{pi_deps`,pi_marks`,pi_next_num`} = { pi & pi_deps` = [fun_index : pi_deps`], pi_marks` = { pi_marks` & [fun_index] = pi_next_num`}, pi_next_num` = inc pi_next_num`} try_to_close_group :: !Int !Int !Int !Int !*{# FunDef} !*PartitioningInfo` -> *(!Int, !*{# FunDef}, !*PartitioningInfo`) try_to_close_group fun_index fun_nr min_dep max_fun_nr fun_defs pi=:{pi_marks`, pi_deps`, pi_groups`, pi_next_group`} | fun_nr <= min_dep # (pi_deps`, pi_marks`, group, fun_defs) = close_group False False fun_index pi_deps` pi_marks` NoComponentMembers max_fun_nr pi_next_group` fun_defs pi = { pi & pi_deps` = pi_deps`, pi_marks` = pi_marks`, pi_next_group` = inc pi_next_group`, pi_groups` = [group : pi_groups`] } = (max_fun_nr, fun_defs, pi) = (min_dep, fun_defs, pi) where close_group :: !Bool !Bool !Int ![Int] !*{# Int} !ComponentMembers !Int !Int !*{# FunDef} -> (![Int], !*{# Int}, !ComponentMembers, !*{# FunDef}) close_group n_r_known non_recursive fun_index [d:ds] marks group max_fun_nr group_number fun_defs # marks = { marks & [d] = max_fun_nr } # (fd,fun_defs) = fun_defs![d] # non_recursive = case n_r_known of True -> non_recursive _ -> case fun_index == d of True -> isEmpty [fc \\ fc <- fd.fun_info.fi_calls | case fc of FunCall idx _ -> idx == d; _ -> False] _ -> False # fd = { fd & fun_info.fi_group_index = group_number, fun_info.fi_properties = set_rec_prop non_recursive fd.fun_info.fi_properties} # fun_defs = { fun_defs & [d] = fd} | d == fun_index = (ds, marks, ComponentMember d group, fun_defs) = close_group True non_recursive fun_index ds marks (ComponentMember d group) max_fun_nr group_number fun_defs :: PartitioningInfo`` = { pi_marks`` :: !.Marks , pi_next_num`` :: !Int , pi_next_group`` :: !Int , pi_groups`` :: ![ComponentMembers] , pi_deps`` :: !ComponentMembers , pi_collect`` :: !.CollectState } :: Marks :== {# Mark} :: Mark = { m_fun :: !Int, m_mark :: !Int} create_marks max_fun_nr functions // # marks = createArray max_fun_nr max_fun_nr // = {marks & [i] = NotChecked \\ i <- functions} = {{m_fun = fun, m_mark = NotChecked} \\ fun <- component_members_to_list functions} component_members_to_list (ComponentMember member members) = [member : component_members_to_list members] component_members_to_list (GeneratedComponentMember member _ members) = [member : component_members_to_list members] component_members_to_list NoComponentMembers = [] get_mark max_fun_nr marks fun // :== marks.[fun] :== get_mark 0 marks fun max_fun_nr where get_mark :: !Int !{#Mark} !Int !Int -> Int get_mark i marks fun max_fun_nr | ifun = get_mark (i+1) marks fun max_fun_nr = marks.[i].m_mark = max_fun_nr set_mark marks fun val // :== { marks & [fun] = val} // :== { if (m_fun==fun) {m & m_mark = val} m \\ m=:{m_fun=m_fun} <-: marks} :== { if (m.m_fun==fun) {m & m_mark = val} m \\ m <-: marks} partitionateFunctions`` :: !Int !Int !*{#FunDef} !ComponentMembers !Index !Int !Int !*FunctionHeap !*PredefinedSymbols !*VarHeap !*ExpressionHeap !*ErrorAdmin -> (!Int, ![Component], !*{#FunDef}, !*FunctionHeap, !*PredefinedSymbols, !*VarHeap, !*ExpressionHeap, !*ErrorAdmin) partitionateFunctions`` max_fun_nr next_group fun_defs functions main_dcl_module_n def_min def_max fun_heap predef_symbols var_heap sym_heap error_admin # marks = create_marks max_fun_nr functions # (cs_predef,predef_symbols) = get_predef_symbols_for_transform predef_symbols # collect_state = { cos_predef_symbols_for_transform = cs_predef , cos_var_heap = var_heap , cos_expression_heap = sym_heap , cos_error = error_admin } # partitioning_info = { pi_marks`` = marks , pi_deps`` = NoComponentMembers , pi_next_num`` = 0 , pi_next_group`` = next_group , pi_groups`` = [] , pi_collect`` = collect_state } (fun_defs, fun_heap, {pi_groups``,pi_next_group``,pi_collect``}) = partitionate_component functions max_fun_nr (fun_defs, fun_heap, partitioning_info) groups = [ {component_members = group} \\ group <- reverse pi_groups`` ] = (pi_next_group``,groups, fun_defs, fun_heap, predef_symbols, pi_collect``.cos_var_heap, pi_collect``.cos_expression_heap, pi_collect``.cos_error) where partitionate_component :: !ComponentMembers !Index !(!*{# FunDef}, !*FunctionHeap, !*PartitioningInfo``) -> (!*{# FunDef}, !*FunctionHeap, !*PartitioningInfo``) partitionate_component (ComponentMember member members) max_fun_nr (fun_defs, fun_heap, pi=:{pi_marks``}) | get_mark max_fun_nr pi_marks`` member == NotChecked # (_, fun_defs, fun_heap, pi) = partitionate_function member max_fun_nr fun_defs fun_heap pi = partitionate_component members max_fun_nr (fun_defs, fun_heap, pi) = partitionate_component members max_fun_nr (fun_defs, fun_heap, pi) partitionate_component (GeneratedComponentMember member fun_ptr members) max_fun_nr (fun_defs, fun_heap, pi=:{pi_marks``}) | get_mark max_fun_nr pi_marks`` member == NotChecked # (_, fun_defs, fun_heap, pi) = partitionate_generated_function member fun_ptr max_fun_nr fun_defs fun_heap pi = partitionate_component members max_fun_nr (fun_defs, fun_heap, pi) = partitionate_component members max_fun_nr (fun_defs, fun_heap, pi) partitionate_component NoComponentMembers max_fun_nr (fun_defs, fun_heap, pi) = (fun_defs, fun_heap, pi) partitionate_function :: !Int !Int !*{# FunDef} !*FunctionHeap !*PartitioningInfo`` -> *(!Int, !*{# FunDef}, !*FunctionHeap, !*PartitioningInfo``) partitionate_function fun_index max_fun_nr fun_defs fun_heap pi=:{pi_next_num``,pi_collect``} # (fd,fun_defs) = fun_defs![fun_index] (fd,pi_collect``) = determine_ref_counts fd pi_collect`` pi = {pi & pi_collect`` = pi_collect``} fc_state = find_calls {main_dcl_module_n=main_dcl_module_n, def_min=def_min, def_max=def_max, fun_index=fun_index} fd.fun_body {fun_calls = []} fi_calls = fc_state.fun_calls fd = {fd & fun_info.fi_calls = fi_calls} fun_defs = {fun_defs & [fun_index] = fd} pi = push_on_dep_stack fun_index pi = visit_functions_and_try_to_close_group fi_calls fun_index pi_next_num`` max_fun_nr fun_defs fun_heap pi partitionate_generated_function :: !Int !FunctionInfoPtr !Int !*{# FunDef} !*FunctionHeap !*PartitioningInfo`` -> *(!Int, !*{# FunDef}, !*FunctionHeap, !*PartitioningInfo``) partitionate_generated_function fun_index fun_ptr max_fun_nr fun_defs fun_heap pi=:{pi_next_num``,pi_collect``} # (FI_Function gf=:{gf_fun_def=fd}, fun_heap) = readPtr fun_ptr fun_heap (fd,pi_collect``) = determine_ref_counts fd pi_collect`` pi = {pi & pi_collect`` = pi_collect``} fc_state = find_calls {main_dcl_module_n=main_dcl_module_n, def_min=def_min, def_max=def_max, fun_index=fun_index} fd.fun_body {fun_calls = []} fi_calls = fc_state.fun_calls fd = {fd & fun_info.fi_calls = fi_calls} fun_heap = writePtr fun_ptr (FI_Function {gf & gf_fun_def = fd}) fun_heap pi = push_generated_function_on_dep_stack fun_index fun_ptr pi = visit_functions_and_try_to_close_group fi_calls fun_index pi_next_num`` max_fun_nr fun_defs fun_heap pi visit_functions_and_try_to_close_group :: ![FunCall] !Int !Int !Int !*{#FunDef} !*FunctionHeap !*PartitioningInfo`` -> *(!Int,!*{#FunDef},!*FunctionHeap,!*PartitioningInfo``) visit_functions_and_try_to_close_group fi_calls fun_index pi_next_num`` max_fun_nr fun_defs fun_heap pi # (min_dep, fun_defs, fun_heap, pi) = visit_functions fi_calls max_fun_nr max_fun_nr fun_defs fun_heap pi = try_to_close_group fun_index pi_next_num`` min_dep max_fun_nr fun_defs fun_heap pi visit_functions :: ![FunCall] !Int !Int !*{# FunDef} !*FunctionHeap !*PartitioningInfo`` -> *(!Int, !*{# FunDef}, !*FunctionHeap, !*PartitioningInfo``) visit_functions [FunCall fc_index _:funs] min_dep max_fun_nr fun_defs fun_heap pi=:{pi_marks``} #! mark = get_mark max_fun_nr pi_marks`` fc_index | mark == NotChecked # (mark, fun_defs, fun_heap, pi) = partitionate_function fc_index max_fun_nr fun_defs fun_heap pi = visit_functions funs (min min_dep mark) max_fun_nr fun_defs fun_heap pi = visit_functions funs (min min_dep mark) max_fun_nr fun_defs fun_heap pi visit_functions [GeneratedFunCall fc_index fun_ptr:funs] min_dep max_fun_nr fun_defs fun_heap pi=:{pi_marks``} #! mark = get_mark max_fun_nr pi_marks`` fc_index | mark == NotChecked # (mark, fun_defs, fun_heap, pi) = partitionate_generated_function fc_index fun_ptr max_fun_nr fun_defs fun_heap pi = visit_functions funs (min min_dep mark) max_fun_nr fun_defs fun_heap pi = visit_functions funs (min min_dep mark) max_fun_nr fun_defs fun_heap pi visit_functions [DclFunCall module_index fc_index:funs] min_dep max_fun_nr fun_defs fun_heap pi = visit_functions funs min_dep max_fun_nr fun_defs fun_heap pi visit_functions [] min_dep max_fun_nr fun_defs fun_heap pi = (min_dep, fun_defs, fun_heap, pi) push_on_dep_stack :: !Int !*PartitioningInfo`` -> *PartitioningInfo``; push_on_dep_stack fun_index pi=:{pi_deps``,pi_marks``,pi_next_num``} = {pi & pi_deps`` = ComponentMember fun_index pi_deps`` , pi_marks`` = set_mark pi_marks`` fun_index pi_next_num`` , pi_next_num`` = inc pi_next_num`` } push_generated_function_on_dep_stack :: !Int !FunctionInfoPtr !*PartitioningInfo`` -> *PartitioningInfo``; push_generated_function_on_dep_stack fun_index fun_ptr pi=:{pi_deps``,pi_marks``,pi_next_num``} = {pi & pi_deps`` = GeneratedComponentMember fun_index fun_ptr pi_deps`` , pi_marks`` = set_mark pi_marks`` fun_index pi_next_num`` , pi_next_num`` = inc pi_next_num`` } try_to_close_group :: !Int !Int !Int !Int !*{# FunDef} !*FunctionHeap !*PartitioningInfo`` -> *(!Int, !*{# FunDef}, !*FunctionHeap, !*PartitioningInfo``) try_to_close_group fun_index fun_nr min_dep max_fun_nr fun_defs fun_heap pi=:{pi_marks``, pi_deps``, pi_groups``, pi_next_group``} | fun_nr <= min_dep # (pi_deps``, pi_marks``, group, fun_defs, fun_heap) = close_group False False fun_index pi_deps`` pi_marks`` NoComponentMembers max_fun_nr pi_next_group`` fun_defs fun_heap pi = { pi & pi_deps`` = pi_deps``, pi_marks`` = pi_marks``, pi_next_group`` = inc pi_next_group``, pi_groups`` = [group : pi_groups``] } = (max_fun_nr, fun_defs, fun_heap, pi) = (min_dep, fun_defs, fun_heap, pi) where close_group :: !Bool !Bool !Int !ComponentMembers !*Marks !ComponentMembers !Int !Int !*{# FunDef} !*FunctionHeap -> (!ComponentMembers, !*Marks, !ComponentMembers, !*{# FunDef}, !*FunctionHeap) close_group n_r_known non_recursive fun_index (ComponentMember d ds) marks group max_fun_nr group_number fun_defs fun_heap # marks = set_mark marks d max_fun_nr (fun_info,fun_defs) = fun_defs![d].fun_info non_recursive = determine_if_function_non_recursive n_r_known fun_index d fun_info.fi_calls non_recursive fun_info = {fun_info & fi_group_index = group_number, fi_properties = set_rec_prop non_recursive fun_info.fi_properties} fun_defs = {fun_defs & [d].fun_info = fun_info} | d == fun_index = (ds, marks, ComponentMember d group, fun_defs, fun_heap) = close_group True non_recursive fun_index ds marks (ComponentMember d group) max_fun_nr group_number fun_defs fun_heap close_group n_r_known non_recursive fun_index (GeneratedComponentMember d fun_ptr ds) marks group max_fun_nr group_number fun_defs fun_heap # marks = set_mark marks d max_fun_nr (FI_Function gf=:{gf_fun_def={fun_info}}, fun_heap) = readPtr fun_ptr fun_heap non_recursive = determine_if_function_non_recursive n_r_known fun_index d fun_info.fi_calls non_recursive fun_info = {fun_info & fi_group_index = group_number, fi_properties = set_rec_prop non_recursive fun_info.fi_properties} fun_heap = writePtr fun_ptr (FI_Function {gf & gf_fun_def.fun_info=fun_info}) fun_heap | d == fun_index = (ds, marks, GeneratedComponentMember d fun_ptr group, fun_defs, fun_heap) = close_group True non_recursive fun_index ds marks (GeneratedComponentMember d fun_ptr group) max_fun_nr group_number fun_defs fun_heap determine_if_function_non_recursive :: !Bool !Index !Index ![FunCall] !Bool -> Bool determine_if_function_non_recursive n_r_known fun_index d fi_calls non_recursive | n_r_known = non_recursive | fun_index == d = isEmpty [fc \\ fc <- fi_calls | case fc of FunCall idx _ -> idx == d; GeneratedFunCall idx _ -> idx == d; _ -> False] = False :: FindCallsInfo = { main_dcl_module_n :: !Index , def_min :: !Int , def_max :: !Int , fun_index :: !Int } :: FindCallsState = { fun_calls :: ![FunCall] } class find_calls a :: !FindCallsInfo !a !FindCallsState -> FindCallsState instance find_calls [a] | find_calls a where find_calls fc_info els fc_state = foldSt (find_calls fc_info) els fc_state instance find_calls (Optional a) | find_calls a where find_calls fc_info (Yes e) fc_state = find_calls fc_info e fc_state find_calls fc_info No fc_state = fc_state instance find_calls FunctionBody where find_calls fc_info (TransformedBody tb) fc_state = find_calls fc_info tb fc_state // find_calls fc_info NoBody fc_state = fc_state find_calls fc_info _ fc_state = abort ("Undefined pattern in FunctionBody: "+++toString fc_info.fun_index+++ "?" +++ toString fc_info.def_min+++ "?" +++ toString fc_info.def_max +++ "\n") instance find_calls TransformedBody where find_calls fc_info {tb_rhs} fc_state = find_calls fc_info tb_rhs fc_state instance find_calls Expression where find_calls fc_info (Var _) fc_state = fc_state find_calls fc_info (App app) fc_state = find_calls fc_info app fc_state find_calls fc_info (exp @ exps) fc_state = find_calls fc_info exps (find_calls fc_info exp fc_state) find_calls fc_info (Let lete) fc_state = find_calls fc_info lete fc_state find_calls fc_info (Case kees) fc_state = find_calls fc_info kees fc_state find_calls fc_info (Selection _ exp sells) fc_state = find_calls fc_info sells (find_calls fc_info exp fc_state) find_calls fc_info (Update e1 sl e2) fc_state #! fc_state = find_calls fc_info e1 fc_state fc_state = find_calls fc_info sl fc_state = find_calls fc_info e2 fc_state find_calls fc_info (RecordUpdate _ expr bexps) fc_state #! fc_state = find_calls fc_info expr fc_state = find_calls fc_info (map (\{bind_src} -> bind_src) bexps) fc_state find_calls fc_info (TupleSelect _ _ expr) fc_state = find_calls fc_info expr fc_state find_calls fc_info (BasicExpr _) fc_state = fc_state find_calls fc_info (AnyCodeExpr _ _ _) fc_state = fc_state find_calls fc_info (ABCCodeExpr _ _) fc_state = fc_state find_calls fc_info (MatchExpr _ expr) fc_state = find_calls fc_info expr fc_state find_calls fc_info (IsConstructor expr _ _ _ _ _) fc_state = find_calls fc_info expr fc_state find_calls fc_info EE fc_state = fc_state find_calls fc_info (NoBind _) fc_state = fc_state find_calls fc_info (FailExpr _) fc_state = fc_state find_calls fc_info (DictionariesFunction dictionaries expr expr_type) fc_state = find_calls fc_info expr fc_state find_calls fc_info ExprToBeRemoved fc_state = fc_state instance find_calls App where find_calls fc_info {app_symb,app_args} fc_state #! fc_state = get_index app_symb.symb_kind fc_state = find_calls fc_info app_args fc_state where get_index (SK_Function {glob_object,glob_module}) fc_state | fc_info.main_dcl_module_n == glob_module && (glob_object < fc_info.def_max || glob_object >= fc_info.def_min) = {fc_state & fun_calls = [FunCall glob_object 0: fc_state.fun_calls]} = {fc_state & fun_calls = [DclFunCall glob_module glob_object: fc_state.fun_calls]} get_index (SK_Constructor idx) fc_state = fc_state get_index (SK_LocalMacroFunction idx) fc_state = {fc_state & fun_calls = [FunCall idx 0: fc_state.fun_calls]} get_index (SK_GeneratedFunction fun_ptr idx) fc_state = {fc_state & fun_calls = [GeneratedFunCall idx fun_ptr : fc_state.fun_calls]} instance find_calls Let where find_calls fc_info {let_strict_binds,let_lazy_binds,let_expr} fc_state = find_calls fc_info (let_strict_binds++let_lazy_binds) (find_calls fc_info let_expr fc_state) instance find_calls Case where find_calls fc_info {case_expr,case_guards,case_default} fc_state #! fc_state = find_calls fc_info case_expr fc_state fc_state = find_calls fc_info case_default fc_state = find_calls fc_info case_guards fc_state instance find_calls Selection where find_calls fc_info (RecordSelection _ _) fc_state = fc_state find_calls fc_info (ArraySelection _ _ expr) fc_state = find_calls fc_info expr fc_state find_calls fc_info (DictionarySelection _ sells _ expr) fc_state = find_calls fc_info expr (find_calls fc_info sells fc_state) find_calls _ u _ = abort "Undefined pattern in Selection\n" instance find_calls LetBind where find_calls fc_info {lb_src} fc_state = find_calls fc_info lb_src fc_state instance find_calls CasePatterns where find_calls fc_info (AlgebraicPatterns _ pats) fc_state = find_calls fc_info pats fc_state find_calls fc_info (BasicPatterns _ pats) fc_state = find_calls fc_info pats fc_state find_calls fc_info (DynamicPatterns pats) fc_state = find_calls fc_info pats fc_state find_calls fc_info (OverloadedListPatterns _ expr pats) fc_state = find_calls fc_info pats (find_calls fc_info expr fc_state) find_calls fc_info (NoPattern) fc_state = fc_state find_calls _ u _ = abort "Undefined pattern in CasePatterns\n" instance find_calls AlgebraicPattern where find_calls fc_info {ap_expr} fc_state = find_calls fc_info ap_expr fc_state instance find_calls BasicPattern where find_calls fc_info {bp_expr} fc_state = find_calls fc_info bp_expr fc_state instance find_calls DynamicPattern where find_calls fc_info {dp_rhs} fc_state = find_calls fc_info dp_rhs fc_state determine_ref_counts fd=:{fun_body=TransformedBody {tb_args,tb_rhs}} pi_collect # (new_rhs, new_args, _, _, pi_collect) = determineVariablesAndRefCounts tb_args tb_rhs pi_collect # fd = {fd & fun_body=TransformedBody {tb_args=new_args,tb_rhs=new_rhs}} = (fd,pi_collect) determine_ref_counts fd pi_collect = (fd, pi_collect) // from check.icl get_predef_symbols_for_transform :: *PredefinedSymbols -> (!PredefSymbolsForTransform,!.PredefinedSymbols) // clean 2.0 does not allow this, clean 1.3 does: // get_predef_symbols_for_transform cs_predef_symbols=:{[PD_DummyForStrictAliasFun]=predef_alias_dummy,[PD_AndOp]=predef_and,[PD_OrOp]=predef_or} get_predef_symbols_for_transform cs_predef_symbols # (predef_alias_dummy,cs_predef_symbols) = cs_predef_symbols![PD_DummyForStrictAliasFun] # (predef_and,cs_predef_symbols) = cs_predef_symbols![PD_AndOp] # (predef_or,cs_predef_symbols) = cs_predef_symbols![PD_OrOp] = ({predef_alias_dummy=predef_alias_dummy,predef_and=predef_and,predef_or=predef_or},cs_predef_symbols) dummy_predef_symbol = { pds_module = 0 , pds_def = 0 } dummy_predef_symbols = { predef_alias_dummy = dummy_predef_symbol , predef_and = dummy_predef_symbol , predef_or = dummy_predef_symbol } set_rec_prop non_recursive fi_properties | non_recursive = fi_properties bitor FI_IsNonRecursive = fi_properties bitand (bitnot FI_IsNonRecursive)