// Protocol Buffers - Google's data interchange format // Copyright 2014 Google Inc. All rights reserved. // https://developers.google.com/protocol-buffers/ // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are // met: // // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above // copyright notice, this list of conditions and the following disclaimer // in the documentation and/or other materials provided with the // distribution. // * Neither the name of Google Inc. nor the names of its // contributors may be used to endorse or promote products derived from // this software without specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS // "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT // LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR // A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT // OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT // LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, // DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY // THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT // (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. #include "protobuf.h" // ----------------------------------------------------------------------------- // Common utilities. // ----------------------------------------------------------------------------- static const char* get_str(VALUE str) { Check_Type(str, T_STRING); return RSTRING_PTR(str); } static VALUE rb_str_maybe_null(const char* s) { if (s == NULL) { s = ""; } return rb_str_new2(s); } static upb_def* check_notfrozen(const upb_def* def) { if (upb_def_isfrozen(def)) { rb_raise(rb_eRuntimeError, "Attempt to modify a frozen descriptor. Once descriptors are " "added to the descriptor pool, they may not be modified."); } return (upb_def*)def; } static upb_msgdef* check_msg_notfrozen(const upb_msgdef* def) { return upb_downcast_msgdef_mutable(check_notfrozen((const upb_def*)def)); } static upb_fielddef* check_field_notfrozen(const upb_fielddef* def) { return upb_downcast_fielddef_mutable(check_notfrozen((const upb_def*)def)); } static upb_oneofdef* check_oneof_notfrozen(const upb_oneofdef* def) { return (upb_oneofdef*)check_notfrozen((const upb_def*)def); } static upb_enumdef* check_enum_notfrozen(const upb_enumdef* def) { return (upb_enumdef*)check_notfrozen((const upb_def*)def); } // ----------------------------------------------------------------------------- // DescriptorPool. // ----------------------------------------------------------------------------- #define DEFINE_CLASS(name, string_name) \ VALUE c ## name = Qnil; \ const rb_data_type_t _ ## name ## _type = { \ string_name, \ { name ## _mark, name ## _free, NULL }, \ }; \ name* ruby_to_ ## name(VALUE val) { \ name* ret; \ TypedData_Get_Struct(val, name, &_ ## name ## _type, ret); \ return ret; \ } \ #define DEFINE_SELF(type, var, rb_var) \ type* var = ruby_to_ ## type(rb_var) // Global singleton DescriptorPool. The user is free to create others, but this // is used by generated code. VALUE generated_pool; DEFINE_CLASS(DescriptorPool, "Google::Protobuf::DescriptorPool"); void DescriptorPool_mark(void* _self) { } void DescriptorPool_free(void* _self) { DescriptorPool* self = _self; upb_symtab_free(self->symtab); xfree(self); } /* * call-seq: * DescriptorPool.new => pool * * Creates a new, empty, descriptor pool. */ VALUE DescriptorPool_alloc(VALUE klass) { DescriptorPool* self = ALLOC(DescriptorPool); self->symtab = upb_symtab_new(); return TypedData_Wrap_Struct(klass, &_DescriptorPool_type, self); } void DescriptorPool_register(VALUE module) { VALUE klass = rb_define_class_under( module, "DescriptorPool", rb_cObject); rb_define_alloc_func(klass, DescriptorPool_alloc); rb_define_method(klass, "add", DescriptorPool_add, 1); rb_define_method(klass, "build", DescriptorPool_build, 0); rb_define_method(klass, "lookup", DescriptorPool_lookup, 1); rb_define_singleton_method(klass, "generated_pool", DescriptorPool_generated_pool, 0); rb_gc_register_address(&cDescriptorPool); cDescriptorPool = klass; rb_gc_register_address(&generated_pool); generated_pool = rb_class_new_instance(0, NULL, klass); } static void add_descriptor_to_pool(DescriptorPool* self, Descriptor* descriptor) { CHECK_UPB( upb_symtab_add(self->symtab, (upb_def**)&descriptor->msgdef, 1, NULL, &status), "Adding Descriptor to DescriptorPool failed"); } static void add_enumdesc_to_pool(DescriptorPool* self, EnumDescriptor* enumdesc) { CHECK_UPB( upb_symtab_add(self->symtab, (upb_def**)&enumdesc->enumdef, 1, NULL, &status), "Adding EnumDescriptor to DescriptorPool failed"); } /* * call-seq: * DescriptorPool.add(descriptor) * * Adds the given Descriptor or EnumDescriptor to this pool. All references to * other types in a Descriptor's fields must be resolvable within this pool or * an exception will be raised. */ VALUE DescriptorPool_add(VALUE _self, VALUE def) { DEFINE_SELF(DescriptorPool, self, _self); VALUE def_klass = rb_obj_class(def); if (def_klass == cDescriptor) { add_descriptor_to_pool(self, ruby_to_Descriptor(def)); } else if (def_klass == cEnumDescriptor) { add_enumdesc_to_pool(self, ruby_to_EnumDescriptor(def)); } else { rb_raise(rb_eArgError, "Second argument must be a Descriptor or EnumDescriptor."); } return Qnil; } /* * call-seq: * DescriptorPool.build(&block) * * Invokes the block with a Builder instance as self. All message and enum types * added within the block are committed to the pool atomically, and may refer * (co)recursively to each other. The user should call Builder#add_message and * Builder#add_enum within the block as appropriate. This is the recommended, * idiomatic way to define new message and enum types. */ VALUE DescriptorPool_build(VALUE _self) { VALUE ctx = rb_class_new_instance(0, NULL, cBuilder); VALUE block = rb_block_proc(); rb_funcall_with_block(ctx, rb_intern("instance_eval"), 0, NULL, block); rb_funcall(ctx, rb_intern("finalize_to_pool"), 1, _self); return Qnil; } /* * call-seq: * DescriptorPool.lookup(name) => descriptor * * Finds a Descriptor or EnumDescriptor by name and returns it, or nil if none * exists with the given name. */ VALUE DescriptorPool_lookup(VALUE _self, VALUE name) { DEFINE_SELF(DescriptorPool, self, _self); const char* name_str = get_str(name); const upb_def* def = upb_symtab_lookup(self->symtab, name_str); if (!def) { return Qnil; } return get_def_obj(def); } /* * call-seq: * DescriptorPool.generated_pool => descriptor_pool * * Class method that returns the global DescriptorPool. This is a singleton into * which generated-code message and enum types are registered. The user may also * register types in this pool for convenience so that they do not have to hold * a reference to a private pool instance. */ VALUE DescriptorPool_generated_pool(VALUE _self) { return generated_pool; } // ----------------------------------------------------------------------------- // Descriptor. // ----------------------------------------------------------------------------- DEFINE_CLASS(Descriptor, "Google::Protobuf::Descriptor"); void Descriptor_mark(void* _self) { Descriptor* self = _self; rb_gc_mark(self->klass); } void Descriptor_free(void* _self) { Descriptor* self = _self; upb_msgdef_unref(self->msgdef, &self->msgdef); if (self->layout) { free_layout(self->layout); } if (self->fill_handlers) { upb_handlers_unref(self->fill_handlers, &self->fill_handlers); } if (self->fill_method) { upb_pbdecodermethod_unref(self->fill_method, &self->fill_method); } if (self->json_fill_method) { upb_json_parsermethod_unref(self->json_fill_method, &self->json_fill_method); } if (self->pb_serialize_handlers) { upb_handlers_unref(self->pb_serialize_handlers, &self->pb_serialize_handlers); } if (self->json_serialize_handlers) { upb_handlers_unref(self->json_serialize_handlers, &self->json_serialize_handlers); } if (self->json_serialize_handlers_preserve) { upb_handlers_unref(self->json_serialize_handlers_preserve, &self->json_serialize_handlers_preserve); } xfree(self); } /* * call-seq: * Descriptor.new => descriptor * * Creates a new, empty, message type descriptor. At a minimum, its name must be * set before it is added to a pool. It cannot be used to create messages until * it is added to a pool, after which it becomes immutable (as part of a * finalization process). */ VALUE Descriptor_alloc(VALUE klass) { Descriptor* self = ALLOC(Descriptor); VALUE ret = TypedData_Wrap_Struct(klass, &_Descriptor_type, self); self->msgdef = upb_msgdef_new(&self->msgdef); self->klass = Qnil; self->layout = NULL; self->fill_handlers = NULL; self->fill_method = NULL; self->json_fill_method = NULL; self->pb_serialize_handlers = NULL; self->json_serialize_handlers = NULL; self->json_serialize_handlers_preserve = NULL; return ret; } void Descriptor_register(VALUE module) { VALUE klass = rb_define_class_under( module, "Descriptor", rb_cObject); rb_define_alloc_func(klass, Descriptor_alloc); rb_define_method(klass, "each", Descriptor_each, 0); rb_define_method(klass, "lookup", Descriptor_lookup, 1); rb_define_method(klass, "add_field", Descriptor_add_field, 1); rb_define_method(klass, "add_oneof", Descriptor_add_oneof, 1); rb_define_method(klass, "each_oneof", Descriptor_each_oneof, 0); rb_define_method(klass, "lookup_oneof", Descriptor_lookup_oneof, 1); rb_define_method(klass, "msgclass", Descriptor_msgclass, 0); rb_define_method(klass, "name", Descriptor_name, 0); rb_define_method(klass, "name=", Descriptor_name_set, 1); rb_include_module(klass, rb_mEnumerable); rb_gc_register_address(&cDescriptor); cDescriptor = klass; } /* * call-seq: * Descriptor.name => name * * Returns the name of this message type as a fully-qualfied string (e.g., * My.Package.MessageType). */ VALUE Descriptor_name(VALUE _self) { DEFINE_SELF(Descriptor, self, _self); return rb_str_maybe_null(upb_msgdef_fullname(self->msgdef)); } /* * call-seq: * Descriptor.name = name * * Assigns a name to this message type. The descriptor must not have been added * to a pool yet. */ VALUE Descriptor_name_set(VALUE _self, VALUE str) { DEFINE_SELF(Descriptor, self, _self); upb_msgdef* mut_def = check_msg_notfrozen(self->msgdef); const char* name = get_str(str); CHECK_UPB( upb_msgdef_setfullname(mut_def, name, &status), "Error setting Descriptor name"); return Qnil; } /* * call-seq: * Descriptor.each(&block) * * Iterates over fields in this message type, yielding to the block on each one. */ VALUE Descriptor_each(VALUE _self) { DEFINE_SELF(Descriptor, self, _self); upb_msg_field_iter it; for (upb_msg_field_begin(&it, self->msgdef); !upb_msg_field_done(&it); upb_msg_field_next(&it)) { const upb_fielddef* field = upb_msg_iter_field(&it); VALUE obj = get_def_obj(field); rb_yield(obj); } return Qnil; } /* * call-seq: * Descriptor.lookup(name) => FieldDescriptor * * Returns the field descriptor for the field with the given name, if present, * or nil if none. */ VALUE Descriptor_lookup(VALUE _self, VALUE name) { DEFINE_SELF(Descriptor, self, _self); const char* s = get_str(name); const upb_fielddef* field = upb_msgdef_ntofz(self->msgdef, s); if (field == NULL) { return Qnil; } return get_def_obj(field); } /* * call-seq: * Descriptor.add_field(field) => nil * * Adds the given FieldDescriptor to this message type. This descriptor must not * have been added to a pool yet. Raises an exception if a field with the same * name or number already exists. Sub-type references (e.g. for fields of type * message) are not resolved at this point. */ VALUE Descriptor_add_field(VALUE _self, VALUE obj) { DEFINE_SELF(Descriptor, self, _self); upb_msgdef* mut_def = check_msg_notfrozen(self->msgdef); FieldDescriptor* def = ruby_to_FieldDescriptor(obj); upb_fielddef* mut_field_def = check_field_notfrozen(def->fielddef); CHECK_UPB( upb_msgdef_addfield(mut_def, mut_field_def, NULL, &status), "Adding field to Descriptor failed"); add_def_obj(def->fielddef, obj); return Qnil; } /* * call-seq: * Descriptor.add_oneof(oneof) => nil * * Adds the given OneofDescriptor to this message type. This descriptor must not * have been added to a pool yet. Raises an exception if a oneof with the same * name already exists, or if any of the oneof's fields' names or numbers * conflict with an existing field in this message type. All fields in the oneof * are added to the message descriptor. Sub-type references (e.g. for fields of * type message) are not resolved at this point. */ VALUE Descriptor_add_oneof(VALUE _self, VALUE obj) { DEFINE_SELF(Descriptor, self, _self); upb_msgdef* mut_def = check_msg_notfrozen(self->msgdef); OneofDescriptor* def = ruby_to_OneofDescriptor(obj); upb_oneofdef* mut_oneof_def = check_oneof_notfrozen(def->oneofdef); CHECK_UPB( upb_msgdef_addoneof(mut_def, mut_oneof_def, NULL, &status), "Adding oneof to Descriptor failed"); add_def_obj(def->oneofdef, obj); return Qnil; } /* * call-seq: * Descriptor.each_oneof(&block) => nil * * Invokes the given block for each oneof in this message type, passing the * corresponding OneofDescriptor. */ VALUE Descriptor_each_oneof(VALUE _self) { DEFINE_SELF(Descriptor, self, _self); upb_msg_oneof_iter it; for (upb_msg_oneof_begin(&it, self->msgdef); !upb_msg_oneof_done(&it); upb_msg_oneof_next(&it)) { const upb_oneofdef* oneof = upb_msg_iter_oneof(&it); VALUE obj = get_def_obj(oneof); rb_yield(obj); } return Qnil; } /* * call-seq: * Descriptor.lookup_oneof(name) => OneofDescriptor * * Returns the oneof descriptor for the oneof with the given name, if present, * or nil if none. */ VALUE Descriptor_lookup_oneof(VALUE _self, VALUE name) { DEFINE_SELF(Descriptor, self, _self); const char* s = get_str(name); const upb_oneofdef* oneof = upb_msgdef_ntooz(self->msgdef, s); if (oneof == NULL) { return Qnil; } return get_def_obj(oneof); } /* * call-seq: * Descriptor.msgclass => message_klass * * Returns the Ruby class created for this message type. Valid only once the * message type has been added to a pool. */ VALUE Descriptor_msgclass(VALUE _self) { DEFINE_SELF(Descriptor, self, _self); if (!upb_def_isfrozen((const upb_def*)self->msgdef)) { rb_raise(rb_eRuntimeError, "Cannot fetch message class from a Descriptor not yet in a pool."); } if (self->klass == Qnil) { self->klass = build_class_from_descriptor(self); } return self->klass; } // ----------------------------------------------------------------------------- // FieldDescriptor. // ----------------------------------------------------------------------------- DEFINE_CLASS(FieldDescriptor, "Google::Protobuf::FieldDescriptor"); void FieldDescriptor_mark(void* _self) { } void FieldDescriptor_free(void* _self) { FieldDescriptor* self = _self; upb_fielddef_unref(self->fielddef, &self->fielddef); xfree(self); } /* * call-seq: * FieldDescriptor.new => field * * Returns a new field descriptor. Its name, type, etc. must be set before it is * added to a message type. */ VALUE FieldDescriptor_alloc(VALUE klass) { FieldDescriptor* self = ALLOC(FieldDescriptor); VALUE ret = TypedData_Wrap_Struct(klass, &_FieldDescriptor_type, self); upb_fielddef* fielddef = upb_fielddef_new(&self->fielddef); upb_fielddef_setpacked(fielddef, false); self->fielddef = fielddef; return ret; } void FieldDescriptor_register(VALUE module) { VALUE klass = rb_define_class_under( module, "FieldDescriptor", rb_cObject); rb_define_alloc_func(klass, FieldDescriptor_alloc); rb_define_method(klass, "name", FieldDescriptor_name, 0); rb_define_method(klass, "name=", FieldDescriptor_name_set, 1); rb_define_method(klass, "type", FieldDescriptor_type, 0); rb_define_method(klass, "type=", FieldDescriptor_type_set, 1); rb_define_method(klass, "label", FieldDescriptor_label, 0); rb_define_method(klass, "label=", FieldDescriptor_label_set, 1); rb_define_method(klass, "number", FieldDescriptor_number, 0); rb_define_method(klass, "number=", FieldDescriptor_number_set, 1); rb_define_method(klass, "submsg_name", FieldDescriptor_submsg_name, 0); rb_define_method(klass, "submsg_name=", FieldDescriptor_submsg_name_set, 1); rb_define_method(klass, "subtype", FieldDescriptor_subtype, 0); rb_define_method(klass, "get", FieldDescriptor_get, 1); rb_define_method(klass, "set", FieldDescriptor_set, 2); rb_gc_register_address(&cFieldDescriptor); cFieldDescriptor = klass; } /* * call-seq: * FieldDescriptor.name => name * * Returns the name of this field. */ VALUE FieldDescriptor_name(VALUE _self) { DEFINE_SELF(FieldDescriptor, self, _self); return rb_str_maybe_null(upb_fielddef_name(self->fielddef)); } /* * call-seq: * FieldDescriptor.name = name * * Sets the name of this field. Cannot be called once the containing message * type, if any, is added to a pool. */ VALUE FieldDescriptor_name_set(VALUE _self, VALUE str) { DEFINE_SELF(FieldDescriptor, self, _self); upb_fielddef* mut_def = check_field_notfrozen(self->fielddef); const char* name = get_str(str); CHECK_UPB(upb_fielddef_setname(mut_def, name, &status), "Error setting FieldDescriptor name"); return Qnil; } upb_fieldtype_t ruby_to_fieldtype(VALUE type) { if (TYPE(type) != T_SYMBOL) { rb_raise(rb_eArgError, "Expected symbol for field type."); } #define CONVERT(upb, ruby) \ if (SYM2ID(type) == rb_intern( # ruby )) { \ return UPB_TYPE_ ## upb; \ } CONVERT(FLOAT, float); CONVERT(DOUBLE, double); CONVERT(BOOL, bool); CONVERT(STRING, string); CONVERT(BYTES, bytes); CONVERT(MESSAGE, message); CONVERT(ENUM, enum); CONVERT(INT32, int32); CONVERT(INT64, int64); CONVERT(UINT32, uint32); CONVERT(UINT64, uint64); #undef CONVERT rb_raise(rb_eArgError, "Unknown field type."); return 0; } VALUE fieldtype_to_ruby(upb_fieldtype_t type) { switch (type) { #define CONVERT(upb, ruby) \ case UPB_TYPE_ ## upb : return ID2SYM(rb_intern( # ruby )); CONVERT(FLOAT, float); CONVERT(DOUBLE, double); CONVERT(BOOL, bool); CONVERT(STRING, string); CONVERT(BYTES, bytes); CONVERT(MESSAGE, message); CONVERT(ENUM, enum); CONVERT(INT32, int32); CONVERT(INT64, int64); CONVERT(UINT32, uint32); CONVERT(UINT64, uint64); #undef CONVERT } return Qnil; } upb_descriptortype_t ruby_to_descriptortype(VALUE type) { if (TYPE(type) != T_SYMBOL) { rb_raise(rb_eArgError, "Expected symbol for field type."); } #define CONVERT(upb, ruby) \ if (SYM2ID(type) == rb_intern( # ruby )) { \ return UPB_DESCRIPTOR_TYPE_ ## upb; \ } CONVERT(FLOAT, float); CONVERT(DOUBLE, double); CONVERT(BOOL, bool); CONVERT(STRING, string); CONVERT(BYTES, bytes); CONVERT(MESSAGE, message); CONVERT(GROUP, group); CONVERT(ENUM, enum); CONVERT(INT32, int32); CONVERT(INT64, int64); CONVERT(UINT32, uint32); CONVERT(UINT64, uint64); CONVERT(SINT32, sint32); CONVERT(SINT64, sint64); CONVERT(FIXED32, fixed32); CONVERT(FIXED64, fixed64); CONVERT(SFIXED32, sfixed32); CONVERT(SFIXED64, sfixed64); #undef CONVERT rb_raise(rb_eArgError, "Unknown field type."); return 0; } VALUE descriptortype_to_ruby(upb_descriptortype_t type) { switch (type) { #define CONVERT(upb, ruby) \ case UPB_DESCRIPTOR_TYPE_ ## upb : return ID2SYM(rb_intern( # ruby )); CONVERT(FLOAT, float); CONVERT(DOUBLE, double); CONVERT(BOOL, bool); CONVERT(STRING, string); CONVERT(BYTES, bytes); CONVERT(MESSAGE, message); CONVERT(GROUP, group); CONVERT(ENUM, enum); CONVERT(INT32, int32); CONVERT(INT64, int64); CONVERT(UINT32, uint32); CONVERT(UINT64, uint64); CONVERT(SINT32, sint32); CONVERT(SINT64, sint64); CONVERT(FIXED32, fixed32); CONVERT(FIXED64, fixed64); CONVERT(SFIXED32, sfixed32); CONVERT(SFIXED64, sfixed64); #undef CONVERT } return Qnil; } /* * call-seq: * FieldDescriptor.type => type * * Returns this field's type, as a Ruby symbol, or nil if not yet set. * * Valid field types are: * :int32, :int64, :uint32, :uint64, :float, :double, :bool, :string, * :bytes, :message. */ VALUE FieldDescriptor_type(VALUE _self) { DEFINE_SELF(FieldDescriptor, self, _self); if (!upb_fielddef_typeisset(self->fielddef)) { return Qnil; } return descriptortype_to_ruby(upb_fielddef_descriptortype(self->fielddef)); } /* * call-seq: * FieldDescriptor.type = type * * Sets this field's type. Cannot be called if field is part of a message type * already in a pool. */ VALUE FieldDescriptor_type_set(VALUE _self, VALUE type) { DEFINE_SELF(FieldDescriptor, self, _self); upb_fielddef* mut_def = check_field_notfrozen(self->fielddef); upb_fielddef_setdescriptortype(mut_def, ruby_to_descriptortype(type)); return Qnil; } /* * call-seq: * FieldDescriptor.label => label * * Returns this field's label (i.e., plurality), as a Ruby symbol. * * Valid field labels are: * :optional, :repeated */ VALUE FieldDescriptor_label(VALUE _self) { DEFINE_SELF(FieldDescriptor, self, _self); switch (upb_fielddef_label(self->fielddef)) { #define CONVERT(upb, ruby) \ case UPB_LABEL_ ## upb : return ID2SYM(rb_intern( # ruby )); CONVERT(OPTIONAL, optional); CONVERT(REQUIRED, required); CONVERT(REPEATED, repeated); #undef CONVERT } return Qnil; } /* * call-seq: * FieldDescriptor.label = label * * Sets the label on this field. Cannot be called if field is part of a message * type already in a pool. */ VALUE FieldDescriptor_label_set(VALUE _self, VALUE label) { DEFINE_SELF(FieldDescriptor, self, _self); upb_fielddef* mut_def = check_field_notfrozen(self->fielddef); upb_label_t upb_label = -1; bool converted = false; if (TYPE(label) != T_SYMBOL) { rb_raise(rb_eArgError, "Expected symbol for field label."); } #define CONVERT(upb, ruby) \ if (SYM2ID(label) == rb_intern( # ruby )) { \ upb_label = UPB_LABEL_ ## upb; \ converted = true; \ } CONVERT(OPTIONAL, optional); CONVERT(REQUIRED, required); CONVERT(REPEATED, repeated); #undef CONVERT if (!converted) { rb_raise(rb_eArgError, "Unknown field label."); } upb_fielddef_setlabel(mut_def, upb_label); return Qnil; } /* * call-seq: * FieldDescriptor.number => number * * Returns the tag number for this field. */ VALUE FieldDescriptor_number(VALUE _self) { DEFINE_SELF(FieldDescriptor, self, _self); return INT2NUM(upb_fielddef_number(self->fielddef)); } /* * call-seq: * FieldDescriptor.number = number * * Sets the tag number for this field. Cannot be called if field is part of a * message type already in a pool. */ VALUE FieldDescriptor_number_set(VALUE _self, VALUE number) { DEFINE_SELF(FieldDescriptor, self, _self); upb_fielddef* mut_def = check_field_notfrozen(self->fielddef); CHECK_UPB(upb_fielddef_setnumber(mut_def, NUM2INT(number), &status), "Error setting field number"); return Qnil; } /* * call-seq: * FieldDescriptor.submsg_name => submsg_name * * Returns the name of the message or enum type corresponding to this field, if * it is a message or enum field (respectively), or nil otherwise. This type * name will be resolved within the context of the pool to which the containing * message type is added. */ VALUE FieldDescriptor_submsg_name(VALUE _self) { DEFINE_SELF(FieldDescriptor, self, _self); if (!upb_fielddef_hassubdef(self->fielddef)) { return Qnil; } return rb_str_maybe_null(upb_fielddef_subdefname(self->fielddef)); } /* * call-seq: * FieldDescriptor.submsg_name = submsg_name * * Sets the name of the message or enum type corresponding to this field, if it * is a message or enum field (respectively). This type name will be resolved * within the context of the pool to which the containing message type is added. * Cannot be called on field that are not of message or enum type, or on fields * that are part of a message type already added to a pool. */ VALUE FieldDescriptor_submsg_name_set(VALUE _self, VALUE value) { DEFINE_SELF(FieldDescriptor, self, _self); upb_fielddef* mut_def = check_field_notfrozen(self->fielddef); const char* str = get_str(value); if (!upb_fielddef_hassubdef(self->fielddef)) { rb_raise(cTypeError, "FieldDescriptor does not have subdef."); } CHECK_UPB(upb_fielddef_setsubdefname(mut_def, str, &status), "Error setting submessage name"); return Qnil; } /* * call-seq: * FieldDescriptor.subtype => message_or_enum_descriptor * * Returns the message or enum descriptor corresponding to this field's type if * it is a message or enum field, respectively, or nil otherwise. Cannot be * called *until* the containing message type is added to a pool (and thus * resolved). */ VALUE FieldDescriptor_subtype(VALUE _self) { DEFINE_SELF(FieldDescriptor, self, _self); const upb_def* def; if (!upb_fielddef_hassubdef(self->fielddef)) { return Qnil; } def = upb_fielddef_subdef(self->fielddef); if (def == NULL) { return Qnil; } return get_def_obj(def); } /* * call-seq: * FieldDescriptor.get(message) => value * * Returns the value set for this field on the given message. Raises an * exception if message is of the wrong type. */ VALUE FieldDescriptor_get(VALUE _self, VALUE msg_rb) { DEFINE_SELF(FieldDescriptor, self, _self); MessageHeader* msg; TypedData_Get_Struct(msg_rb, MessageHeader, &Message_type, msg); if (msg->descriptor->msgdef != upb_fielddef_containingtype(self->fielddef)) { rb_raise(cTypeError, "get method called on wrong message type"); } return layout_get(msg->descriptor->layout, Message_data(msg), self->fielddef); } /* * call-seq: * FieldDescriptor.set(message, value) * * Sets the value corresponding to this field to the given value on the given * message. Raises an exception if message is of the wrong type. Performs the * ordinary type-checks for field setting. */ VALUE FieldDescriptor_set(VALUE _self, VALUE msg_rb, VALUE value) { DEFINE_SELF(FieldDescriptor, self, _self); MessageHeader* msg; TypedData_Get_Struct(msg_rb, MessageHeader, &Message_type, msg); if (msg->descriptor->msgdef != upb_fielddef_containingtype(self->fielddef)) { rb_raise(cTypeError, "set method called on wrong message type"); } layout_set(msg->descriptor->layout, Message_data(msg), self->fielddef, value); return Qnil; } // ----------------------------------------------------------------------------- // OneofDescriptor. // ----------------------------------------------------------------------------- DEFINE_CLASS(OneofDescriptor, "Google::Protobuf::OneofDescriptor"); void OneofDescriptor_mark(void* _self) { } void OneofDescriptor_free(void* _self) { OneofDescriptor* self = _self; upb_oneofdef_unref(self->oneofdef, &self->oneofdef); xfree(self); } /* * call-seq: * OneofDescriptor.new => oneof_descriptor * * Creates a new, empty, oneof descriptor. The oneof may only be modified prior * to being added to a message descriptor which is subsequently added to a pool. */ VALUE OneofDescriptor_alloc(VALUE klass) { OneofDescriptor* self = ALLOC(OneofDescriptor); VALUE ret = TypedData_Wrap_Struct(klass, &_OneofDescriptor_type, self); self->oneofdef = upb_oneofdef_new(&self->oneofdef); return ret; } void OneofDescriptor_register(VALUE module) { VALUE klass = rb_define_class_under( module, "OneofDescriptor", rb_cObject); rb_define_alloc_func(klass, OneofDescriptor_alloc); rb_define_method(klass, "name", OneofDescriptor_name, 0); rb_define_method(klass, "name=", OneofDescriptor_name_set, 1); rb_define_method(klass, "add_field", OneofDescriptor_add_field, 1); rb_define_method(klass, "each", OneofDescriptor_each, 0); rb_include_module(klass, rb_mEnumerable); rb_gc_register_address(&cOneofDescriptor); cOneofDescriptor = klass; } /* * call-seq: * OneofDescriptor.name => name * * Returns the name of this oneof. */ VALUE OneofDescriptor_name(VALUE _self) { DEFINE_SELF(OneofDescriptor, self, _self); return rb_str_maybe_null(upb_oneofdef_name(self->oneofdef)); } /* * call-seq: * OneofDescriptor.name = name * * Sets a new name for this oneof. The oneof must not have been added to a * message descriptor yet. */ VALUE OneofDescriptor_name_set(VALUE _self, VALUE value) { DEFINE_SELF(OneofDescriptor, self, _self); upb_oneofdef* mut_def = check_oneof_notfrozen(self->oneofdef); const char* str = get_str(value); CHECK_UPB(upb_oneofdef_setname(mut_def, str, &status), "Error setting oneof name"); return Qnil; } /* * call-seq: * OneofDescriptor.add_field(field) => nil * * Adds a field to this oneof. The field may have been added to this oneof in * the past, or the message to which this oneof belongs (if any), but may not * have already been added to any other oneof or message. Otherwise, an * exception is raised. * * All fields added to the oneof via this method will be automatically added to * the message to which this oneof belongs, if it belongs to one currently, or * else will be added to any message to which the oneof is later added at the * time that it is added. */ VALUE OneofDescriptor_add_field(VALUE _self, VALUE obj) { DEFINE_SELF(OneofDescriptor, self, _self); upb_oneofdef* mut_def = check_oneof_notfrozen(self->oneofdef); FieldDescriptor* def = ruby_to_FieldDescriptor(obj); upb_fielddef* mut_field_def = check_field_notfrozen(def->fielddef); CHECK_UPB( upb_oneofdef_addfield(mut_def, mut_field_def, NULL, &status), "Adding field to OneofDescriptor failed"); add_def_obj(def->fielddef, obj); return Qnil; } /* * call-seq: * OneofDescriptor.each(&block) => nil * * Iterates through fields in this oneof, yielding to the block on each one. */ VALUE OneofDescriptor_each(VALUE _self, VALUE field) { DEFINE_SELF(OneofDescriptor, self, _self); upb_oneof_iter it; for (upb_oneof_begin(&it, self->oneofdef); !upb_oneof_done(&it); upb_oneof_next(&it)) { const upb_fielddef* f = upb_oneof_iter_field(&it); VALUE obj = get_def_obj(f); rb_yield(obj); } return Qnil; } // ----------------------------------------------------------------------------- // EnumDescriptor. // ----------------------------------------------------------------------------- DEFINE_CLASS(EnumDescriptor, "Google::Protobuf::EnumDescriptor"); void EnumDescriptor_mark(void* _self) { EnumDescriptor* self = _self; rb_gc_mark(self->module); } void EnumDescriptor_free(void* _self) { EnumDescriptor* self = _self; upb_enumdef_unref(self->enumdef, &self->enumdef); xfree(self); } /* * call-seq: * EnumDescriptor.new => enum_descriptor * * Creates a new, empty, enum descriptor. Must be added to a pool before the * enum type can be used. The enum type may only be modified prior to adding to * a pool. */ VALUE EnumDescriptor_alloc(VALUE klass) { EnumDescriptor* self = ALLOC(EnumDescriptor); VALUE ret = TypedData_Wrap_Struct(klass, &_EnumDescriptor_type, self); self->enumdef = upb_enumdef_new(&self->enumdef); self->module = Qnil; return ret; } void EnumDescriptor_register(VALUE module) { VALUE klass = rb_define_class_under( module, "EnumDescriptor", rb_cObject); rb_define_alloc_func(klass, EnumDescriptor_alloc); rb_define_method(klass, "name", EnumDescriptor_name, 0); rb_define_method(klass, "name=", EnumDescriptor_name_set, 1); rb_define_method(klass, "add_value", EnumDescriptor_add_value, 2); rb_define_method(klass, "lookup_name", EnumDescriptor_lookup_name, 1); rb_define_method(klass, "lookup_value", EnumDescriptor_lookup_value, 1); rb_define_method(klass, "each", EnumDescriptor_each, 0); rb_define_method(klass, "enummodule", EnumDescriptor_enummodule, 0); rb_include_module(klass, rb_mEnumerable); rb_gc_register_address(&cEnumDescriptor); cEnumDescriptor = klass; } /* * call-seq: * EnumDescriptor.name => name * * Returns the name of this enum type. */ VALUE EnumDescriptor_name(VALUE _self) { DEFINE_SELF(EnumDescriptor, self, _self); return rb_str_maybe_null(upb_enumdef_fullname(self->enumdef)); } /* * call-seq: * EnumDescriptor.name = name * * Sets the name of this enum type. Cannot be called if the enum type has * already been added to a pool. */ VALUE EnumDescriptor_name_set(VALUE _self, VALUE str) { DEFINE_SELF(EnumDescriptor, self, _self); upb_enumdef* mut_def = check_enum_notfrozen(self->enumdef); const char* name = get_str(str); CHECK_UPB(upb_enumdef_setfullname(mut_def, name, &status), "Error setting EnumDescriptor name"); return Qnil; } /* * call-seq: * EnumDescriptor.add_value(key, value) * * Adds a new key => value mapping to this enum type. Key must be given as a * Ruby symbol. Cannot be called if the enum type has already been added to a * pool. Will raise an exception if the key or value is already in use. */ VALUE EnumDescriptor_add_value(VALUE _self, VALUE name, VALUE number) { DEFINE_SELF(EnumDescriptor, self, _self); upb_enumdef* mut_def = check_enum_notfrozen(self->enumdef); const char* name_str = rb_id2name(SYM2ID(name)); int32_t val = NUM2INT(number); CHECK_UPB(upb_enumdef_addval(mut_def, name_str, val, &status), "Error adding value to enum"); return Qnil; } /* * call-seq: * EnumDescriptor.lookup_name(name) => value * * Returns the numeric value corresponding to the given key name (as a Ruby * symbol), or nil if none. */ VALUE EnumDescriptor_lookup_name(VALUE _self, VALUE name) { DEFINE_SELF(EnumDescriptor, self, _self); const char* name_str= rb_id2name(SYM2ID(name)); int32_t val = 0; if (upb_enumdef_ntoiz(self->enumdef, name_str, &val)) { return INT2NUM(val); } else { return Qnil; } } /* * call-seq: * EnumDescriptor.lookup_value(name) => value * * Returns the key name (as a Ruby symbol) corresponding to the integer value, * or nil if none. */ VALUE EnumDescriptor_lookup_value(VALUE _self, VALUE number) { DEFINE_SELF(EnumDescriptor, self, _self); int32_t val = NUM2INT(number); const char* name = upb_enumdef_iton(self->enumdef, val); if (name != NULL) { return ID2SYM(rb_intern(name)); } else { return Qnil; } } /* * call-seq: * EnumDescriptor.each(&block) * * Iterates over key => value mappings in this enum's definition, yielding to * the block with (key, value) arguments for each one. */ VALUE EnumDescriptor_each(VALUE _self) { DEFINE_SELF(EnumDescriptor, self, _self); upb_enum_iter it; for (upb_enum_begin(&it, self->enumdef); !upb_enum_done(&it); upb_enum_next(&it)) { VALUE key = ID2SYM(rb_intern(upb_enum_iter_name(&it))); VALUE number = INT2NUM(upb_enum_iter_number(&it)); rb_yield_values(2, key, number); } return Qnil; } /* * call-seq: * EnumDescriptor.enummodule => module * * Returns the Ruby module corresponding to this enum type. Cannot be called * until the enum descriptor has been added to a pool. */ VALUE EnumDescriptor_enummodule(VALUE _self) { DEFINE_SELF(EnumDescriptor, self, _self); if (!upb_def_isfrozen((const upb_def*)self->enumdef)) { rb_raise(rb_eRuntimeError, "Cannot fetch enum module from an EnumDescriptor not yet " "in a pool."); } if (self->module == Qnil) { self->module = build_module_from_enumdesc(self); } return self->module; } // ----------------------------------------------------------------------------- // MessageBuilderContext. // ----------------------------------------------------------------------------- DEFINE_CLASS(MessageBuilderContext, "Google::Protobuf::Internal::MessageBuilderContext"); void MessageBuilderContext_mark(void* _self) { MessageBuilderContext* self = _self; rb_gc_mark(self->descriptor); rb_gc_mark(self->builder); } void MessageBuilderContext_free(void* _self) { MessageBuilderContext* self = _self; xfree(self); } VALUE MessageBuilderContext_alloc(VALUE klass) { MessageBuilderContext* self = ALLOC(MessageBuilderContext); VALUE ret = TypedData_Wrap_Struct( klass, &_MessageBuilderContext_type, self); self->descriptor = Qnil; self->builder = Qnil; return ret; } void MessageBuilderContext_register(VALUE module) { VALUE klass = rb_define_class_under( module, "MessageBuilderContext", rb_cObject); rb_define_alloc_func(klass, MessageBuilderContext_alloc); rb_define_method(klass, "initialize", MessageBuilderContext_initialize, 2); rb_define_method(klass, "optional", MessageBuilderContext_optional, -1); rb_define_method(klass, "required", MessageBuilderContext_required, -1); rb_define_method(klass, "repeated", MessageBuilderContext_repeated, -1); rb_define_method(klass, "map", MessageBuilderContext_map, -1); rb_define_method(klass, "oneof", MessageBuilderContext_oneof, 1); rb_gc_register_address(&cMessageBuilderContext); cMessageBuilderContext = klass; } /* * call-seq: * MessageBuilderContext.new(desc, builder) => context * * Create a new message builder context around the given message descriptor and * builder context. This class is intended to serve as a DSL context to be used * with #instance_eval. */ VALUE MessageBuilderContext_initialize(VALUE _self, VALUE msgdef, VALUE builder) { DEFINE_SELF(MessageBuilderContext, self, _self); self->descriptor = msgdef; self->builder = builder; return Qnil; } static VALUE msgdef_add_field(VALUE msgdef, const char* label, VALUE name, VALUE type, VALUE number, VALUE type_class) { VALUE fielddef = rb_class_new_instance(0, NULL, cFieldDescriptor); VALUE name_str = rb_str_new2(rb_id2name(SYM2ID(name))); rb_funcall(fielddef, rb_intern("label="), 1, ID2SYM(rb_intern(label))); rb_funcall(fielddef, rb_intern("name="), 1, name_str); rb_funcall(fielddef, rb_intern("type="), 1, type); rb_funcall(fielddef, rb_intern("number="), 1, number); if (type_class != Qnil) { if (TYPE(type_class) != T_STRING) { rb_raise(rb_eArgError, "Expected string for type class"); } // Make it an absolute type name by prepending a dot. type_class = rb_str_append(rb_str_new2("."), type_class); rb_funcall(fielddef, rb_intern("submsg_name="), 1, type_class); } rb_funcall(msgdef, rb_intern("add_field"), 1, fielddef); return fielddef; } /* * call-seq: * MessageBuilderContext.optional(name, type, number, type_class = nil) * * Defines a new optional field on this message type with the given type, tag * number, and type class (for message and enum fields). The type must be a Ruby * symbol (as accepted by FieldDescriptor#type=) and the type_class must be a * string, if present (as accepted by FieldDescriptor#submsg_name=). */ VALUE MessageBuilderContext_optional(int argc, VALUE* argv, VALUE _self) { DEFINE_SELF(MessageBuilderContext, self, _self); VALUE name, type, number, type_class; if (argc < 3) { rb_raise(rb_eArgError, "Expected at least 3 arguments."); } name = argv[0]; type = argv[1]; number = argv[2]; type_class = (argc > 3) ? argv[3] : Qnil; return msgdef_add_field(self->descriptor, "optional", name, type, number, type_class); } /* * call-seq: * MessageBuilderContext.required(name, type, number, type_class = nil) * * Defines a new required field on this message type with the given type, tag * number, and type class (for message and enum fields). The type must be a Ruby * symbol (as accepted by FieldDescriptor#type=) and the type_class must be a * string, if present (as accepted by FieldDescriptor#submsg_name=). * * Proto3 does not have required fields, but this method exists for * completeness. Any attempt to add a message type with required fields to a * pool will currently result in an error. */ VALUE MessageBuilderContext_required(int argc, VALUE* argv, VALUE _self) { DEFINE_SELF(MessageBuilderContext, self, _self); VALUE name, type, number, type_class; if (argc < 3) { rb_raise(rb_eArgError, "Expected at least 3 arguments."); } name = argv[0]; type = argv[1]; number = argv[2]; type_class = (argc > 3) ? argv[3] : Qnil; return msgdef_add_field(self->descriptor, "required", name, type, number, type_class); } /* * call-seq: * MessageBuilderContext.repeated(name, type, number, type_class = nil) * * Defines a new repeated field on this message type with the given type, tag * number, and type class (for message and enum fields). The type must be a Ruby * symbol (as accepted by FieldDescriptor#type=) and the type_class must be a * string, if present (as accepted by FieldDescriptor#submsg_name=). */ VALUE MessageBuilderContext_repeated(int argc, VALUE* argv, VALUE _self) { DEFINE_SELF(MessageBuilderContext, self, _self); VALUE name, type, number, type_class; if (argc < 3) { rb_raise(rb_eArgError, "Expected at least 3 arguments."); } name = argv[0]; type = argv[1]; number = argv[2]; type_class = (argc > 3) ? argv[3] : Qnil; return msgdef_add_field(self->descriptor, "repeated", name, type, number, type_class); } /* * call-seq: * MessageBuilderContext.map(name, key_type, value_type, number, * value_type_class = nil) * * Defines a new map field on this message type with the given key and value * types, tag number, and type class (for message and enum value types). The key * type must be :int32/:uint32/:int64/:uint64, :bool, or :string. The value type * type must be a Ruby symbol (as accepted by FieldDescriptor#type=) and the * type_class must be a string, if present (as accepted by * FieldDescriptor#submsg_name=). */ VALUE MessageBuilderContext_map(int argc, VALUE* argv, VALUE _self) { DEFINE_SELF(MessageBuilderContext, self, _self); VALUE name, key_type, value_type, number, type_class; VALUE mapentry_desc, mapentry_desc_name; if (argc < 4) { rb_raise(rb_eArgError, "Expected at least 4 arguments."); } name = argv[0]; key_type = argv[1]; value_type = argv[2]; number = argv[3]; type_class = (argc > 4) ? argv[4] : Qnil; // Validate the key type. We can't accept enums, messages, or floats/doubles // as map keys. (We exclude these explicitly, and the field-descriptor setter // below then ensures that the type is one of the remaining valid options.) if (SYM2ID(key_type) == rb_intern("float") || SYM2ID(key_type) == rb_intern("double") || SYM2ID(key_type) == rb_intern("enum") || SYM2ID(key_type) == rb_intern("message")) { rb_raise(rb_eArgError, "Cannot add a map field with a float, double, enum, or message " "type."); } // Create a new message descriptor for the map entry message, and create a // repeated submessage field here with that type. mapentry_desc = rb_class_new_instance(0, NULL, cDescriptor); mapentry_desc_name = rb_funcall(self->descriptor, rb_intern("name"), 0); mapentry_desc_name = rb_str_cat2(mapentry_desc_name, "_MapEntry_"); mapentry_desc_name = rb_str_cat2(mapentry_desc_name, rb_id2name(SYM2ID(name))); Descriptor_name_set(mapentry_desc, mapentry_desc_name); { // The 'mapentry' attribute has no Ruby setter because we do not want the // user attempting to DIY the setup below; we want to ensure that the fields // are correct. So we reach into the msgdef here to set the bit manually. Descriptor* mapentry_desc_self = ruby_to_Descriptor(mapentry_desc); upb_msgdef_setmapentry((upb_msgdef*)mapentry_desc_self->msgdef, true); } { // optional key = 1; VALUE key_field = rb_class_new_instance(0, NULL, cFieldDescriptor); FieldDescriptor_name_set(key_field, rb_str_new2("key")); FieldDescriptor_label_set(key_field, ID2SYM(rb_intern("optional"))); FieldDescriptor_number_set(key_field, INT2NUM(1)); FieldDescriptor_type_set(key_field, key_type); Descriptor_add_field(mapentry_desc, key_field); } { // optional value = 2; VALUE value_field = rb_class_new_instance(0, NULL, cFieldDescriptor); FieldDescriptor_name_set(value_field, rb_str_new2("value")); FieldDescriptor_label_set(value_field, ID2SYM(rb_intern("optional"))); FieldDescriptor_number_set(value_field, INT2NUM(2)); FieldDescriptor_type_set(value_field, value_type); if (type_class != Qnil) { VALUE submsg_name = rb_str_new2("."); // prepend '.' to make absolute. submsg_name = rb_str_append(submsg_name, type_class); FieldDescriptor_submsg_name_set(value_field, submsg_name); } Descriptor_add_field(mapentry_desc, value_field); } { // Add the map-entry message type to the current builder, and use the type // to create the map field itself. Builder* builder_self = ruby_to_Builder(self->builder); rb_ary_push(builder_self->pending_list, mapentry_desc); } { VALUE map_field = rb_class_new_instance(0, NULL, cFieldDescriptor); VALUE name_str = rb_str_new2(rb_id2name(SYM2ID(name))); VALUE submsg_name; FieldDescriptor_name_set(map_field, name_str); FieldDescriptor_number_set(map_field, number); FieldDescriptor_label_set(map_field, ID2SYM(rb_intern("repeated"))); FieldDescriptor_type_set(map_field, ID2SYM(rb_intern("message"))); submsg_name = rb_str_new2("."); // prepend '.' to make name absolute. submsg_name = rb_str_append(submsg_name, mapentry_desc_name); FieldDescriptor_submsg_name_set(map_field, submsg_name); Descriptor_add_field(self->descriptor, map_field); } return Qnil; } /* * call-seq: * MessageBuilderContext.oneof(name, &block) => nil * * Creates a new OneofDescriptor with the given name, creates a * OneofBuilderContext attached to that OneofDescriptor, evaluates the given * block in the context of that OneofBuilderContext with #instance_eval, and * then adds the oneof to the message. * * This is the recommended, idiomatic way to build oneof definitions. */ VALUE MessageBuilderContext_oneof(VALUE _self, VALUE name) { DEFINE_SELF(MessageBuilderContext, self, _self); VALUE oneofdef = rb_class_new_instance(0, NULL, cOneofDescriptor); VALUE args[2] = { oneofdef, self->builder }; VALUE ctx = rb_class_new_instance(2, args, cOneofBuilderContext); VALUE block = rb_block_proc(); VALUE name_str = rb_str_new2(rb_id2name(SYM2ID(name))); rb_funcall(oneofdef, rb_intern("name="), 1, name_str); rb_funcall_with_block(ctx, rb_intern("instance_eval"), 0, NULL, block); Descriptor_add_oneof(self->descriptor, oneofdef); return Qnil; } // ----------------------------------------------------------------------------- // OneofBuilderContext. // ----------------------------------------------------------------------------- DEFINE_CLASS(OneofBuilderContext, "Google::Protobuf::Internal::OneofBuilderContext"); void OneofBuilderContext_mark(void* _self) { OneofBuilderContext* self = _self; rb_gc_mark(self->descriptor); rb_gc_mark(self->builder); } void OneofBuilderContext_free(void* _self) { OneofBuilderContext* self = _self; xfree(self); } VALUE OneofBuilderContext_alloc(VALUE klass) { OneofBuilderContext* self = ALLOC(OneofBuilderContext); VALUE ret = TypedData_Wrap_Struct( klass, &_OneofBuilderContext_type, self); self->descriptor = Qnil; self->builder = Qnil; return ret; } void OneofBuilderContext_register(VALUE module) { VALUE klass = rb_define_class_under( module, "OneofBuilderContext", rb_cObject); rb_define_alloc_func(klass, OneofBuilderContext_alloc); rb_define_method(klass, "initialize", OneofBuilderContext_initialize, 2); rb_define_method(klass, "optional", OneofBuilderContext_optional, -1); rb_gc_register_address(&cOneofBuilderContext); cOneofBuilderContext = klass; } /* * call-seq: * OneofBuilderContext.new(desc, builder) => context * * Create a new oneof builder context around the given oneof descriptor and * builder context. This class is intended to serve as a DSL context to be used * with #instance_eval. */ VALUE OneofBuilderContext_initialize(VALUE _self, VALUE oneofdef, VALUE builder) { DEFINE_SELF(OneofBuilderContext, self, _self); self->descriptor = oneofdef; self->builder = builder; return Qnil; } /* * call-seq: * OneofBuilderContext.optional(name, type, number, type_class = nil) * * Defines a new optional field in this oneof with the given type, tag number, * and type class (for message and enum fields). The type must be a Ruby symbol * (as accepted by FieldDescriptor#type=) and the type_class must be a string, * if present (as accepted by FieldDescriptor#submsg_name=). */ VALUE OneofBuilderContext_optional(int argc, VALUE* argv, VALUE _self) { DEFINE_SELF(OneofBuilderContext, self, _self); VALUE name, type, number, type_class; if (argc < 3) { rb_raise(rb_eArgError, "Expected at least 3 arguments."); } name = argv[0]; type = argv[1]; number = argv[2]; type_class = (argc > 3) ? argv[3] : Qnil; return msgdef_add_field(self->descriptor, "optional", name, type, number, type_class); } // ----------------------------------------------------------------------------- // EnumBuilderContext. // ----------------------------------------------------------------------------- DEFINE_CLASS(EnumBuilderContext, "Google::Protobuf::Internal::EnumBuilderContext"); void EnumBuilderContext_mark(void* _self) { EnumBuilderContext* self = _self; rb_gc_mark(self->enumdesc); } void EnumBuilderContext_free(void* _self) { EnumBuilderContext* self = _self; xfree(self); } VALUE EnumBuilderContext_alloc(VALUE klass) { EnumBuilderContext* self = ALLOC(EnumBuilderContext); VALUE ret = TypedData_Wrap_Struct( klass, &_EnumBuilderContext_type, self); self->enumdesc = Qnil; return ret; } void EnumBuilderContext_register(VALUE module) { VALUE klass = rb_define_class_under( module, "EnumBuilderContext", rb_cObject); rb_define_alloc_func(klass, EnumBuilderContext_alloc); rb_define_method(klass, "initialize", EnumBuilderContext_initialize, 1); rb_define_method(klass, "value", EnumBuilderContext_value, 2); rb_gc_register_address(&cEnumBuilderContext); cEnumBuilderContext = klass; } /* * call-seq: * EnumBuilderContext.new(enumdesc) => context * * Create a new builder context around the given enum descriptor. This class is * intended to serve as a DSL context to be used with #instance_eval. */ VALUE EnumBuilderContext_initialize(VALUE _self, VALUE enumdef) { DEFINE_SELF(EnumBuilderContext, self, _self); self->enumdesc = enumdef; return Qnil; } static VALUE enumdef_add_value(VALUE enumdef, VALUE name, VALUE number) { rb_funcall(enumdef, rb_intern("add_value"), 2, name, number); return Qnil; } /* * call-seq: * EnumBuilder.add_value(name, number) * * Adds the given name => number mapping to the enum type. Name must be a Ruby * symbol. */ VALUE EnumBuilderContext_value(VALUE _self, VALUE name, VALUE number) { DEFINE_SELF(EnumBuilderContext, self, _self); return enumdef_add_value(self->enumdesc, name, number); } // ----------------------------------------------------------------------------- // Builder. // ----------------------------------------------------------------------------- DEFINE_CLASS(Builder, "Google::Protobuf::Internal::Builder"); void Builder_mark(void* _self) { Builder* self = _self; rb_gc_mark(self->pending_list); } void Builder_free(void* _self) { Builder* self = _self; xfree(self->defs); xfree(self); } /* * call-seq: * Builder.new => builder * * Creates a new Builder. A Builder can accumulate a set of new message and enum * descriptors and atomically register them into a pool in a way that allows for * (co)recursive type references. */ VALUE Builder_alloc(VALUE klass) { Builder* self = ALLOC(Builder); VALUE ret = TypedData_Wrap_Struct( klass, &_Builder_type, self); self->pending_list = Qnil; self->defs = NULL; return ret; } void Builder_register(VALUE module) { VALUE klass = rb_define_class_under(module, "Builder", rb_cObject); rb_define_alloc_func(klass, Builder_alloc); rb_define_method(klass, "add_message", Builder_add_message, 1); rb_define_method(klass, "add_enum", Builder_add_enum, 1); rb_define_method(klass, "initialize", Builder_initialize, 0); rb_define_method(klass, "finalize_to_pool", Builder_finalize_to_pool, 1); rb_gc_register_address(&cBuilder); cBuilder = klass; } /* * call-seq: * Builder.new(d) => builder * * Create a new message builder. */ VALUE Builder_initialize(VALUE _self) { DEFINE_SELF(Builder, self, _self); self->pending_list = rb_ary_new(); return Qnil; } /* * call-seq: * Builder.add_message(name, &block) * * Creates a new, empty descriptor with the given name, and invokes the block in * the context of a MessageBuilderContext on that descriptor. The block can then * call, e.g., MessageBuilderContext#optional and MessageBuilderContext#repeated * methods to define the message fields. * * This is the recommended, idiomatic way to build message definitions. */ VALUE Builder_add_message(VALUE _self, VALUE name) { DEFINE_SELF(Builder, self, _self); VALUE msgdef = rb_class_new_instance(0, NULL, cDescriptor); VALUE args[2] = { msgdef, _self }; VALUE ctx = rb_class_new_instance(2, args, cMessageBuilderContext); VALUE block = rb_block_proc(); rb_funcall(msgdef, rb_intern("name="), 1, name); rb_funcall_with_block(ctx, rb_intern("instance_eval"), 0, NULL, block); rb_ary_push(self->pending_list, msgdef); return Qnil; } /* * call-seq: * Builder.add_enum(name, &block) * * Creates a new, empty enum descriptor with the given name, and invokes the * block in the context of an EnumBuilderContext on that descriptor. The block * can then call EnumBuilderContext#add_value to define the enum values. * * This is the recommended, idiomatic way to build enum definitions. */ VALUE Builder_add_enum(VALUE _self, VALUE name) { DEFINE_SELF(Builder, self, _self); VALUE enumdef = rb_class_new_instance(0, NULL, cEnumDescriptor); VALUE ctx = rb_class_new_instance(1, &enumdef, cEnumBuilderContext); VALUE block = rb_block_proc(); rb_funcall(enumdef, rb_intern("name="), 1, name); rb_funcall_with_block(ctx, rb_intern("instance_eval"), 0, NULL, block); rb_ary_push(self->pending_list, enumdef); return Qnil; } static void validate_msgdef(const upb_msgdef* msgdef) { // Verify that no required fields exist. proto3 does not support these. upb_msg_field_iter it; for (upb_msg_field_begin(&it, msgdef); !upb_msg_field_done(&it); upb_msg_field_next(&it)) { const upb_fielddef* field = upb_msg_iter_field(&it); if (upb_fielddef_label(field) == UPB_LABEL_REQUIRED) { rb_raise(cTypeError, "Required fields are unsupported in proto3."); } } } static void validate_enumdef(const upb_enumdef* enumdef) { // Verify that an entry exists with integer value 0. (This is the default // value.) const char* lookup = upb_enumdef_iton(enumdef, 0); if (lookup == NULL) { rb_raise(cTypeError, "Enum definition does not contain a value for '0'."); } } /* * call-seq: * Builder.finalize_to_pool(pool) * * Adds all accumulated message and enum descriptors created in this builder * context to the given pool. The operation occurs atomically, and all * descriptors can refer to each other (including in cycles). This is the only * way to build (co)recursive message definitions. * * This method is usually called automatically by DescriptorPool#build after it * invokes the given user block in the context of the builder. The user should * not normally need to call this manually because a Builder is not normally * created manually. */ VALUE Builder_finalize_to_pool(VALUE _self, VALUE pool_rb) { DEFINE_SELF(Builder, self, _self); DescriptorPool* pool = ruby_to_DescriptorPool(pool_rb); REALLOC_N(self->defs, upb_def*, RARRAY_LEN(self->pending_list)); for (int i = 0; i < RARRAY_LEN(self->pending_list); i++) { VALUE def_rb = rb_ary_entry(self->pending_list, i); if (CLASS_OF(def_rb) == cDescriptor) { self->defs[i] = (upb_def*)ruby_to_Descriptor(def_rb)->msgdef; validate_msgdef((const upb_msgdef*)self->defs[i]); } else if (CLASS_OF(def_rb) == cEnumDescriptor) { self->defs[i] = (upb_def*)ruby_to_EnumDescriptor(def_rb)->enumdef; validate_enumdef((const upb_enumdef*)self->defs[i]); } } CHECK_UPB(upb_symtab_add(pool->symtab, (upb_def**)self->defs, RARRAY_LEN(self->pending_list), NULL, &status), "Unable to add defs to DescriptorPool"); for (int i = 0; i < RARRAY_LEN(self->pending_list); i++) { VALUE def_rb = rb_ary_entry(self->pending_list, i); add_def_obj(self->defs[i], def_rb); } self->pending_list = rb_ary_new(); return Qnil; }