[TypenameInstruction::] The Typename Construct. Defining the typename construct. @h Definition. For what this does and why it is used, see //inter: Textual Inter//. = void TypenameInstruction::define_construct(void) { inter_construct *IC = InterInstruction::create_construct(TYPENAME_IST, I"typename"); InterInstruction::defines_symbol_in_fields(IC, DEFN_TYPENAME_IFLD, -1); InterInstruction::specify_syntax(IC, I"typename IDENTIFIER TOKEN TOKENS"); InterInstruction::data_extent_at_least(IC, 7); InterInstruction::permit(IC, INSIDE_PLAIN_PACKAGE_ICUP); METHOD_ADD(IC, CONSTRUCT_READ_MTID, TypenameInstruction::read); METHOD_ADD(IC, CONSTRUCT_TRANSPOSE_MTID, TypenameInstruction::transpose); METHOD_ADD(IC, CONSTRUCT_VERIFY_MTID, TypenameInstruction::verify); METHOD_ADD(IC, CONSTRUCT_WRITE_MTID, TypenameInstruction::write); } @h Instructions. In bytecode, the frame of a |typename| instruction is laid out with the compulsory words -- see //Inter Nodes// -- followed by these. The eventual length is flexible: there can be any number of operands from 0 upwards. @d DEFN_TYPENAME_IFLD (DATA_IFLD + 0) @d ENUM_RANGE_TYPENAME_IFLD (DATA_IFLD + 1) @d NO_INSTANCES_TYPENAME_IFLD (DATA_IFLD + 2) @d SUPER_TYPENAME_IFLD (DATA_IFLD + 3) @d PERM_LIST_TYPENAME_IFLD (DATA_IFLD + 4) @d PLIST_TYPENAME_IFLD (DATA_IFLD + 5) @d CONSTRUCTOR_TYPENAME_IFLD (DATA_IFLD + 6) @d OPERANDS_TYPENAME_IFLD (DATA_IFLD + 7) = inter_error_message *TypenameInstruction::new(inter_bookmark *IBM, inter_symbol *typename_s, inter_ti constructor, inter_symbol *super_s, int arity, inter_ti *operands, inter_ti level, inter_error_location *eloc) { inter_ti super_SID = 0; if (super_s) super_SID = InterSymbolsTable::id_at_bookmark(IBM, super_s); inter_package *pack = InterBookmark::package(IBM); inter_warehouse *warehouse = InterBookmark::warehouse(IBM); inter_tree_node *P = Inode::new_with_7_data_fields(IBM, TYPENAME_IST, /* DEFN_TYPENAME_IFLD: */ InterSymbolsTable::id_at_bookmark(IBM, typename_s), /* ENUM_RANGE_TYPENAME_IFLD: */ 0, /* NO_INSTANCES_TYPENAME_IFLD: */ 0, /* SUPER_TYPENAME_IFLD: */ super_SID, /* PERM_LIST_TYPENAME_IFLD: */ InterWarehouse::create_node_list(warehouse, pack), /* PLIST_TYPENAME_IFLD: */ InterWarehouse::create_node_list(warehouse, pack), /* CONSTRUCTOR_TYPENAME_IFLD: */ constructor, eloc, level); if (arity > 0) { Inode::extend_instruction_by(P, (inter_ti) arity); for (int i=0; iW.instruction[OPERANDS_TYPENAME_IFLD+i] = operands[i]; } inter_error_message *E = VerifyingInter::instruction(InterBookmark::package(IBM), P); if (E) return E; NodePlacement::move_to_moving_bookmark(P, IBM); return NULL; } void TypenameInstruction::transpose(inter_construct *IC, inter_tree_node *P, inter_ti *grid, inter_ti grid_extent, inter_error_message **E) { P->W.instruction[PERM_LIST_TYPENAME_IFLD] = grid[P->W.instruction[PERM_LIST_TYPENAME_IFLD]]; P->W.instruction[PLIST_TYPENAME_IFLD] = grid[P->W.instruction[PLIST_TYPENAME_IFLD]]; } @ Verification consists only of sanity checks. = void TypenameInstruction::verify(inter_construct *IC, inter_tree_node *P, inter_package *owner, inter_error_message **E) { inter_symbol *typename_s = TypenameInstruction::typename(P); if ((P->W.instruction[ENUM_RANGE_TYPENAME_IFLD] > 0) && (InterTypes::is_enumerated(InterTypes::from_type_name(typename_s)) == FALSE)) { *E = Inode::error(P, I"spurious extent in non-enumeration", NULL); return; } if (P->W.instruction[SUPER_TYPENAME_IFLD] != 0) { *E = VerifyingInter::SID_field(owner, P, SUPER_TYPENAME_IFLD, TYPENAME_IST); if (*E) return; inter_symbol *super_s = TypenameInstruction::super(typename_s); if (InterTypes::is_enumerated(InterTypes::from_type_name(super_s)) == FALSE) { *E = Inode::error(P, I"subtype of nonenumerated type", NULL); return; } } *E = VerifyingInter::node_list_field(owner, P, PERM_LIST_TYPENAME_IFLD); if (*E) return; *E = VerifyingInter::node_list_field(owner, P, PLIST_TYPENAME_IFLD); if (*E) return; *E = VerifyingInter::constructor_field(P, CONSTRUCTOR_TYPENAME_IFLD); if (*E) return; inter_type type = InterTypes::from_constructor_code(TypenameInstruction::constructor(typename_s)); int arity = P->W.extent - OPERANDS_TYPENAME_IFLD; for (int i=0; imr.exp[0]; text_stream *operator_text = ilp->mr.exp[1]; text_stream *defn_text = ilp->mr.exp[2]; inter_symbol *symb = TextualInter::new_symbol(eloc, InterBookmark::scope(IBM), typename_text, E); if (*E) return; inter_semisimple_type_description parsed_description; InterTypes::initialise_isstd(&parsed_description); inter_symbol *super_s = NULL; if (Str::eq(operator_text, I"<=")) { super_s = TextualInter::find_symbol(IBM, eloc, defn_text, TYPENAME_IST, E); if ((*E == NULL) && (InterTypes::is_enumerated(InterTypes::from_type_name(super_s)) == FALSE)) { *E = InterErrors::quoted(I"not a type which can have subtypes", defn_text, eloc); return; } parsed_description.constructor_code = ENUM_ITCONC; parsed_description.arity = 0; } else if (Str::eq(operator_text, I"=")) { *E = InterTypes::parse_semisimple(ilp->mr.exp[2], InterBookmark::scope(IBM), eloc, &parsed_description); } else { *E = InterErrors::quoted(I"expected '=' or '<='", operator_text, eloc); } if (*E == NULL) *E = TypenameInstruction::new(IBM, symb, parsed_description.constructor_code, super_s, parsed_description.arity, parsed_description.operand_TIDs, (inter_ti) ilp->indent_level, eloc); InterTypes::dispose_of_isstd(&parsed_description); } @h Writing to textual Inter syntax. = void TypenameInstruction::write(inter_construct *IC, OUTPUT_STREAM, inter_tree_node *P) { inter_symbol *typename_s = TypenameInstruction::typename(P); WRITE("typename %S ", InterSymbol::identifier(typename_s)); inter_symbol *super = TypenameInstruction::super(typename_s); if (super) { WRITE("<= "); TextualInter::write_symbol_from(OUT, P, SUPER_TYPENAME_IFLD); } else { WRITE("= "); InterTypes::write_typename_definition(OUT, typename_s); } } @h Access functions. = inter_symbol *TypenameInstruction::typename(inter_tree_node *P) { if (P == NULL) return NULL; if (Inode::isnt(P, TYPENAME_IST)) return NULL; return InterSymbolsTable::symbol_from_ID_at_node(P, DEFN_TYPENAME_IFLD); } inter_symbol *TypenameInstruction::super(inter_symbol *typename_s) { if (typename_s == NULL) return NULL; inter_tree_node *D = InterSymbol::definition(typename_s); if (D == NULL) return NULL; return InterSymbolsTable::symbol_from_ID_at_node(D, SUPER_TYPENAME_IFLD); } inter_node_list *TypenameInstruction::permissions_list(inter_symbol *typename_s) { if (typename_s == NULL) return NULL; inter_tree_node *D = InterSymbol::definition(typename_s); if (D == NULL) return NULL; return Inode::ID_to_frame_list(D, D->W.instruction[PERM_LIST_TYPENAME_IFLD]); } inter_node_list *TypenameInstruction::properties_list(inter_symbol *typename_s) { if (typename_s == NULL) return NULL; inter_tree_node *D = InterSymbol::definition(typename_s); if (D == NULL) return NULL; return Inode::ID_to_frame_list(D, D->W.instruction[PLIST_TYPENAME_IFLD]); } @ The definition of the semisimple type: = inter_ti TypenameInstruction::constructor(inter_symbol *typename_s) { if (typename_s == NULL) return UNCHECKED_ITCONC; inter_tree_node *D = InterSymbol::definition(typename_s); if (D == NULL) return UNCHECKED_ITCONC; return D->W.instruction[CONSTRUCTOR_TYPENAME_IFLD]; } int TypenameInstruction::arity(inter_symbol *typename_s) { if (typename_s == NULL) return 0; inter_tree_node *D = InterSymbol::definition(typename_s); if (D == NULL) return 0; return D->W.extent - OPERANDS_TYPENAME_IFLD; } inter_type TypenameInstruction::operand_type(inter_symbol *typename_s, int i) { if (typename_s == NULL) return InterTypes::unchecked(); inter_tree_node *D = InterSymbol::definition(typename_s); if (D == NULL) return InterTypes::unchecked(); if (i >= D->W.extent - OPERANDS_TYPENAME_IFLD) return InterTypes::unchecked(); inter_ti TID = D->W.instruction[OPERANDS_TYPENAME_IFLD + i]; inter_symbols_table *T = InterPackage::scope_of(D); return InterTypes::from_TID(T, TID); } @ Enumeration counter, relevant only when the typename is enumerated: = inter_ti TypenameInstruction::next_enumerated_value(inter_symbol *typename_s) { if (typename_s == NULL) return 0; inter_tree_node *D = InterSymbol::definition(typename_s); if (D == NULL) return 0; return ++(D->W.instruction[ENUM_RANGE_TYPENAME_IFLD]); } @ For an enumerated typename, if a new instance is created, this is called: = void TypenameInstruction::new_instance(inter_symbol *typename_s, inter_symbol *inst_name) { if (typename_s == NULL) return; inter_tree_node *D = InterSymbol::definition(typename_s); if (D == NULL) return; D->W.instruction[NO_INSTANCES_TYPENAME_IFLD]++; inter_symbol *S = TypenameInstruction::super(typename_s); if (S) TypenameInstruction::new_instance(S, inst_name); } int TypenameInstruction::instance_count(inter_symbol *typename_s) { if (typename_s == NULL) return 0; inter_tree_node *D = InterSymbol::definition(typename_s); if (D == NULL) return 0; return (int) D->W.instruction[NO_INSTANCES_TYPENAME_IFLD]; } @h Two tests. = int TypenameInstruction::is(inter_symbol *typename_s) { if (typename_s == NULL) return FALSE; inter_tree_node *D = InterSymbol::definition(typename_s); if (Inode::is(D, TYPENAME_IST)) return TRUE; return FALSE; } int TypenameInstruction::is_a(inter_symbol *typename1_s, inter_symbol *typename2_s) { inter_type type1 = InterTypes::from_type_name(typename1_s); inter_type type2 = InterTypes::from_type_name(typename2_s); if ((InterTypes::is_unchecked(type1)) || (InterTypes::is_unchecked(type2))) return TRUE; while (typename1_s) { if (typename1_s == typename2_s) return TRUE; typename1_s = TypenameInstruction::super(typename1_s); } return FALSE; }