import * as _m0 from "protobufjs/minimal"; import { DeepPartial, Long } from "@osmonauts/helpers"; export declare enum FieldDescriptorProto_Type { /** * TYPE_DOUBLE - 0 is reserved for errors. * Order is weird for historical reasons. */ TYPE_DOUBLE = 1, TYPE_FLOAT = 2, /** * TYPE_INT64 - Not ZigZag encoded. Negative numbers take 10 bytes. Use TYPE_SINT64 if * negative values are likely. */ TYPE_INT64 = 3, TYPE_UINT64 = 4, /** * TYPE_INT32 - Not ZigZag encoded. Negative numbers take 10 bytes. Use TYPE_SINT32 if * negative values are likely. */ TYPE_INT32 = 5, TYPE_FIXED64 = 6, TYPE_FIXED32 = 7, TYPE_BOOL = 8, TYPE_STRING = 9, /** * TYPE_GROUP - Tag-delimited aggregate. * Group type is deprecated and not supported in proto3. However, Proto3 * implementations should still be able to parse the group wire format and * treat group fields as unknown fields. */ TYPE_GROUP = 10, TYPE_MESSAGE = 11, /** TYPE_BYTES - New in version 2. */ TYPE_BYTES = 12, TYPE_UINT32 = 13, TYPE_ENUM = 14, TYPE_SFIXED32 = 15, TYPE_SFIXED64 = 16, /** TYPE_SINT32 - Uses ZigZag encoding. */ TYPE_SINT32 = 17, /** TYPE_SINT64 - Uses ZigZag encoding. */ TYPE_SINT64 = 18, UNRECOGNIZED = -1 } export declare function fieldDescriptorProto_TypeFromJSON(object: any): FieldDescriptorProto_Type; export declare function fieldDescriptorProto_TypeToJSON(object: FieldDescriptorProto_Type): string; export declare enum FieldDescriptorProto_Label { /** LABEL_OPTIONAL - 0 is reserved for errors */ LABEL_OPTIONAL = 1, LABEL_REQUIRED = 2, LABEL_REPEATED = 3, UNRECOGNIZED = -1 } export declare function fieldDescriptorProto_LabelFromJSON(object: any): FieldDescriptorProto_Label; export declare function fieldDescriptorProto_LabelToJSON(object: FieldDescriptorProto_Label): string; /** Generated classes can be optimized for speed or code size. */ export declare enum FileOptions_OptimizeMode { /** * SPEED - Generate complete code for parsing, serialization, * etc. */ SPEED = 1, /** CODE_SIZE - Use ReflectionOps to implement these methods. */ CODE_SIZE = 2, /** LITE_RUNTIME - Generate code using MessageLite and the lite runtime. */ LITE_RUNTIME = 3, UNRECOGNIZED = -1 } export declare function fileOptions_OptimizeModeFromJSON(object: any): FileOptions_OptimizeMode; export declare function fileOptions_OptimizeModeToJSON(object: FileOptions_OptimizeMode): string; export declare enum FieldOptions_CType { /** STRING - Default mode. */ STRING = 0, CORD = 1, STRING_PIECE = 2, UNRECOGNIZED = -1 } export declare function fieldOptions_CTypeFromJSON(object: any): FieldOptions_CType; export declare function fieldOptions_CTypeToJSON(object: FieldOptions_CType): string; export declare enum FieldOptions_JSType { /** JS_NORMAL - Use the default type. */ JS_NORMAL = 0, /** JS_STRING - Use JavaScript strings. */ JS_STRING = 1, /** JS_NUMBER - Use JavaScript numbers. */ JS_NUMBER = 2, UNRECOGNIZED = -1 } export declare function fieldOptions_JSTypeFromJSON(object: any): FieldOptions_JSType; export declare function fieldOptions_JSTypeToJSON(object: FieldOptions_JSType): string; /** * Is this method side-effect-free (or safe in HTTP parlance), or idempotent, * or neither? HTTP based RPC implementation may choose GET verb for safe * methods, and PUT verb for idempotent methods instead of the default POST. */ export declare enum MethodOptions_IdempotencyLevel { IDEMPOTENCY_UNKNOWN = 0, /** NO_SIDE_EFFECTS - implies idempotent */ NO_SIDE_EFFECTS = 1, /** IDEMPOTENT - idempotent, but may have side effects */ IDEMPOTENT = 2, UNRECOGNIZED = -1 } export declare function methodOptions_IdempotencyLevelFromJSON(object: any): MethodOptions_IdempotencyLevel; export declare function methodOptions_IdempotencyLevelToJSON(object: MethodOptions_IdempotencyLevel): string; /** * The protocol compiler can output a FileDescriptorSet containing the .proto * files it parses. */ export interface FileDescriptorSet { file: FileDescriptorProto[]; } /** Describes a complete .proto file. */ export interface FileDescriptorProto { /** file name, relative to root of source tree */ name: string; package: string; /** Names of files imported by this file. */ dependency: string[]; /** Indexes of the public imported files in the dependency list above. */ public_dependency: number[]; /** * Indexes of the weak imported files in the dependency list. * For Google-internal migration only. Do not use. */ weak_dependency: number[]; /** All top-level definitions in this file. */ message_type: DescriptorProto[]; enum_type: EnumDescriptorProto[]; service: ServiceDescriptorProto[]; extension: FieldDescriptorProto[]; options: FileOptions; /** * This field contains optional information about the original source code. * You may safely remove this entire field without harming runtime * functionality of the descriptors -- the information is needed only by * development tools. */ source_code_info: SourceCodeInfo; /** * The syntax of the proto file. * The supported values are "proto2" and "proto3". */ syntax: string; } /** Describes a message type. */ export interface DescriptorProto { name: string; field: FieldDescriptorProto[]; extension: FieldDescriptorProto[]; nested_type: DescriptorProto[]; enum_type: EnumDescriptorProto[]; extension_range: DescriptorProto_ExtensionRange[]; oneof_decl: OneofDescriptorProto[]; options: MessageOptions; reserved_range: DescriptorProto_ReservedRange[]; /** * Reserved field names, which may not be used by fields in the same message. * A given name may only be reserved once. */ reserved_name: string[]; } export interface DescriptorProto_ExtensionRange { /** Inclusive. */ start: number; /** Exclusive. */ end: number; options: ExtensionRangeOptions; } /** * Range of reserved tag numbers. Reserved tag numbers may not be used by * fields or extension ranges in the same message. Reserved ranges may * not overlap. */ export interface DescriptorProto_ReservedRange { /** Inclusive. */ start: number; /** Exclusive. */ end: number; } export interface ExtensionRangeOptions { /** The parser stores options it doesn't recognize here. See above. */ uninterpreted_option: UninterpretedOption[]; } /** Describes a field within a message. */ export interface FieldDescriptorProto { name: string; number: number; label: FieldDescriptorProto_Label; /** * If type_name is set, this need not be set. If both this and type_name * are set, this must be one of TYPE_ENUM, TYPE_MESSAGE or TYPE_GROUP. */ type: FieldDescriptorProto_Type; /** * For message and enum types, this is the name of the type. If the name * starts with a '.', it is fully-qualified. Otherwise, C++-like scoping * rules are used to find the type (i.e. first the nested types within this * message are searched, then within the parent, on up to the root * namespace). */ type_name: string; /** * For extensions, this is the name of the type being extended. It is * resolved in the same manner as type_name. */ extendee: string; /** * For numeric types, contains the original text representation of the value. * For booleans, "true" or "false". * For strings, contains the default text contents (not escaped in any way). * For bytes, contains the C escaped value. All bytes >= 128 are escaped. * TODO(kenton): Base-64 encode? */ default_value: string; /** * If set, gives the index of a oneof in the containing type's oneof_decl * list. This field is a member of that oneof. */ oneof_index: number; /** * JSON name of this field. The value is set by protocol compiler. If the * user has set a "json_name" option on this field, that option's value * will be used. Otherwise, it's deduced from the field's name by converting * it to camelCase. */ json_name: string; options: FieldOptions; } /** Describes a oneof. */ export interface OneofDescriptorProto { name: string; options: OneofOptions; } /** Describes an enum type. */ export interface EnumDescriptorProto { name: string; value: EnumValueDescriptorProto[]; options: EnumOptions; /** * Range of reserved numeric values. Reserved numeric values may not be used * by enum values in the same enum declaration. Reserved ranges may not * overlap. */ reserved_range: EnumDescriptorProto_EnumReservedRange[]; /** * Reserved enum value names, which may not be reused. A given name may only * be reserved once. */ reserved_name: string[]; } /** * Range of reserved numeric values. Reserved values may not be used by * entries in the same enum. Reserved ranges may not overlap. * * Note that this is distinct from DescriptorProto.ReservedRange in that it * is inclusive such that it can appropriately represent the entire int32 * domain. */ export interface EnumDescriptorProto_EnumReservedRange { /** Inclusive. */ start: number; /** Inclusive. */ end: number; } /** Describes a value within an enum. */ export interface EnumValueDescriptorProto { name: string; number: number; options: EnumValueOptions; } /** Describes a service. */ export interface ServiceDescriptorProto { name: string; method: MethodDescriptorProto[]; options: ServiceOptions; } /** Describes a method of a service. */ export interface MethodDescriptorProto { name: string; /** * Input and output type names. These are resolved in the same way as * FieldDescriptorProto.type_name, but must refer to a message type. */ input_type: string; output_type: string; options: MethodOptions; /** Identifies if client streams multiple client messages */ client_streaming: boolean; /** Identifies if server streams multiple server messages */ server_streaming: boolean; } export interface FileOptions { /** * Sets the Java package where classes generated from this .proto will be * placed. By default, the proto package is used, but this is often * inappropriate because proto packages do not normally start with backwards * domain names. */ java_package: string; /** * If set, all the classes from the .proto file are wrapped in a single * outer class with the given name. This applies to both Proto1 * (equivalent to the old "--one_java_file" option) and Proto2 (where * a .proto always translates to a single class, but you may want to * explicitly choose the class name). */ java_outer_classname: string; /** * If set true, then the Java code generator will generate a separate .java * file for each top-level message, enum, and service defined in the .proto * file. Thus, these types will *not* be nested inside the outer class * named by java_outer_classname. However, the outer class will still be * generated to contain the file's getDescriptor() method as well as any * top-level extensions defined in the file. */ java_multiple_files: boolean; /** This option does nothing. */ /** @deprecated */ java_generate_equals_and_hash: boolean; /** * If set true, then the Java2 code generator will generate code that * throws an exception whenever an attempt is made to assign a non-UTF-8 * byte sequence to a string field. * Message reflection will do the same. * However, an extension field still accepts non-UTF-8 byte sequences. * This option has no effect on when used with the lite runtime. */ java_string_check_utf8: boolean; optimize_for: FileOptions_OptimizeMode; /** * Sets the Go package where structs generated from this .proto will be * placed. If omitted, the Go package will be derived from the following: * - The basename of the package import path, if provided. * - Otherwise, the package statement in the .proto file, if present. * - Otherwise, the basename of the .proto file, without extension. */ go_package: string; /** * Should generic services be generated in each language? "Generic" services * are not specific to any particular RPC system. They are generated by the * main code generators in each language (without additional plugins). * Generic services were the only kind of service generation supported by * early versions of google.protobuf. * * Generic services are now considered deprecated in favor of using plugins * that generate code specific to your particular RPC system. Therefore, * these default to false. Old code which depends on generic services should * explicitly set them to true. */ cc_generic_services: boolean; java_generic_services: boolean; py_generic_services: boolean; php_generic_services: boolean; /** * Is this file deprecated? * Depending on the target platform, this can emit Deprecated annotations * for everything in the file, or it will be completely ignored; in the very * least, this is a formalization for deprecating files. */ deprecated: boolean; /** * Enables the use of arenas for the proto messages in this file. This applies * only to generated classes for C++. */ cc_enable_arenas: boolean; /** * Sets the objective c class prefix which is prepended to all objective c * generated classes from this .proto. There is no default. */ objc_class_prefix: string; /** Namespace for generated classes; defaults to the package. */ csharp_namespace: string; /** * By default Swift generators will take the proto package and CamelCase it * replacing '.' with underscore and use that to prefix the types/symbols * defined. When this options is provided, they will use this value instead * to prefix the types/symbols defined. */ swift_prefix: string; /** * Sets the php class prefix which is prepended to all php generated classes * from this .proto. Default is empty. */ php_class_prefix: string; /** * Use this option to change the namespace of php generated classes. Default * is empty. When this option is empty, the package name will be used for * determining the namespace. */ php_namespace: string; /** * Use this option to change the namespace of php generated metadata classes. * Default is empty. When this option is empty, the proto file name will be * used for determining the namespace. */ php_metadata_namespace: string; /** * Use this option to change the package of ruby generated classes. Default * is empty. When this option is not set, the package name will be used for * determining the ruby package. */ ruby_package: string; /** * The parser stores options it doesn't recognize here. * See the documentation for the "Options" section above. */ uninterpreted_option: UninterpretedOption[]; } export interface MessageOptions { /** * Set true to use the old proto1 MessageSet wire format for extensions. * This is provided for backwards-compatibility with the MessageSet wire * format. You should not use this for any other reason: It's less * efficient, has fewer features, and is more complicated. * * The message must be defined exactly as follows: * message Foo { * option message_set_wire_format = true; * extensions 4 to max; * } * Note that the message cannot have any defined fields; MessageSets only * have extensions. * * All extensions of your type must be singular messages; e.g. they cannot * be int32s, enums, or repeated messages. * * Because this is an option, the above two restrictions are not enforced by * the protocol compiler. */ message_set_wire_format: boolean; /** * Disables the generation of the standard "descriptor()" accessor, which can * conflict with a field of the same name. This is meant to make migration * from proto1 easier; new code should avoid fields named "descriptor". */ no_standard_descriptor_accessor: boolean; /** * Is this message deprecated? * Depending on the target platform, this can emit Deprecated annotations * for the message, or it will be completely ignored; in the very least, * this is a formalization for deprecating messages. */ deprecated: boolean; /** * Whether the message is an automatically generated map entry type for the * maps field. * * For maps fields: * map map_field = 1; * The parsed descriptor looks like: * message MapFieldEntry { * option map_entry = true; * optional KeyType key = 1; * optional ValueType value = 2; * } * repeated MapFieldEntry map_field = 1; * * Implementations may choose not to generate the map_entry=true message, but * use a native map in the target language to hold the keys and values. * The reflection APIs in such implementations still need to work as * if the field is a repeated message field. * * NOTE: Do not set the option in .proto files. Always use the maps syntax * instead. The option should only be implicitly set by the proto compiler * parser. */ map_entry: boolean; /** The parser stores options it doesn't recognize here. See above. */ uninterpreted_option: UninterpretedOption[]; } export interface FieldOptions { /** * The ctype option instructs the C++ code generator to use a different * representation of the field than it normally would. See the specific * options below. This option is not yet implemented in the open source * release -- sorry, we'll try to include it in a future version! */ ctype: FieldOptions_CType; /** * The packed option can be enabled for repeated primitive fields to enable * a more efficient representation on the wire. Rather than repeatedly * writing the tag and type for each element, the entire array is encoded as * a single length-delimited blob. In proto3, only explicit setting it to * false will avoid using packed encoding. */ packed: boolean; /** * The jstype option determines the JavaScript type used for values of the * field. The option is permitted only for 64 bit integral and fixed types * (int64, uint64, sint64, fixed64, sfixed64). A field with jstype JS_STRING * is represented as JavaScript string, which avoids loss of precision that * can happen when a large value is converted to a floating point JavaScript. * Specifying JS_NUMBER for the jstype causes the generated JavaScript code to * use the JavaScript "number" type. The behavior of the default option * JS_NORMAL is implementation dependent. * * This option is an enum to permit additional types to be added, e.g. * goog.math.Integer. */ jstype: FieldOptions_JSType; /** * Should this field be parsed lazily? Lazy applies only to message-type * fields. It means that when the outer message is initially parsed, the * inner message's contents will not be parsed but instead stored in encoded * form. The inner message will actually be parsed when it is first accessed. * * This is only a hint. Implementations are free to choose whether to use * eager or lazy parsing regardless of the value of this option. However, * setting this option true suggests that the protocol author believes that * using lazy parsing on this field is worth the additional bookkeeping * overhead typically needed to implement it. * * This option does not affect the public interface of any generated code; * all method signatures remain the same. Furthermore, thread-safety of the * interface is not affected by this option; const methods remain safe to * call from multiple threads concurrently, while non-const methods continue * to require exclusive access. * * * Note that implementations may choose not to check required fields within * a lazy sub-message. That is, calling IsInitialized() on the outer message * may return true even if the inner message has missing required fields. * This is necessary because otherwise the inner message would have to be * parsed in order to perform the check, defeating the purpose of lazy * parsing. An implementation which chooses not to check required fields * must be consistent about it. That is, for any particular sub-message, the * implementation must either *always* check its required fields, or *never* * check its required fields, regardless of whether or not the message has * been parsed. */ lazy: boolean; /** * Is this field deprecated? * Depending on the target platform, this can emit Deprecated annotations * for accessors, or it will be completely ignored; in the very least, this * is a formalization for deprecating fields. */ deprecated: boolean; /** For Google-internal migration only. Do not use. */ weak: boolean; /** The parser stores options it doesn't recognize here. See above. */ uninterpreted_option: UninterpretedOption[]; } export interface OneofOptions { /** The parser stores options it doesn't recognize here. See above. */ uninterpreted_option: UninterpretedOption[]; } export interface EnumOptions { /** * Set this option to true to allow mapping different tag names to the same * value. */ allow_alias: boolean; /** * Is this enum deprecated? * Depending on the target platform, this can emit Deprecated annotations * for the enum, or it will be completely ignored; in the very least, this * is a formalization for deprecating enums. */ deprecated: boolean; /** The parser stores options it doesn't recognize here. See above. */ uninterpreted_option: UninterpretedOption[]; } export interface EnumValueOptions { /** * Is this enum value deprecated? * Depending on the target platform, this can emit Deprecated annotations * for the enum value, or it will be completely ignored; in the very least, * this is a formalization for deprecating enum values. */ deprecated: boolean; /** The parser stores options it doesn't recognize here. See above. */ uninterpreted_option: UninterpretedOption[]; } export interface ServiceOptions { /** * Is this service deprecated? * Depending on the target platform, this can emit Deprecated annotations * for the service, or it will be completely ignored; in the very least, * this is a formalization for deprecating services. */ deprecated: boolean; /** The parser stores options it doesn't recognize here. See above. */ uninterpreted_option: UninterpretedOption[]; } export interface MethodOptions { /** * Is this method deprecated? * Depending on the target platform, this can emit Deprecated annotations * for the method, or it will be completely ignored; in the very least, * this is a formalization for deprecating methods. */ deprecated: boolean; idempotency_level: MethodOptions_IdempotencyLevel; /** The parser stores options it doesn't recognize here. See above. */ uninterpreted_option: UninterpretedOption[]; } /** * A message representing a option the parser does not recognize. This only * appears in options protos created by the compiler::Parser class. * DescriptorPool resolves these when building Descriptor objects. Therefore, * options protos in descriptor objects (e.g. returned by Descriptor::options(), * or produced by Descriptor::CopyTo()) will never have UninterpretedOptions * in them. */ export interface UninterpretedOption { name: UninterpretedOption_NamePart[]; /** * The value of the uninterpreted option, in whatever type the tokenizer * identified it as during parsing. Exactly one of these should be set. */ identifier_value: string; positive_int_value: Long; negative_int_value: Long; double_value: number; string_value: Uint8Array; aggregate_value: string; } /** * The name of the uninterpreted option. Each string represents a segment in * a dot-separated name. is_extension is true iff a segment represents an * extension (denoted with parentheses in options specs in .proto files). * E.g.,{ ["foo", false], ["bar.baz", true], ["qux", false] } represents * "foo.(bar.baz).qux". */ export interface UninterpretedOption_NamePart { name_part: string; is_extension: boolean; } /** * Encapsulates information about the original source file from which a * FileDescriptorProto was generated. */ export interface SourceCodeInfo { /** * A Location identifies a piece of source code in a .proto file which * corresponds to a particular definition. This information is intended * to be useful to IDEs, code indexers, documentation generators, and similar * tools. * * For example, say we have a file like: * message Foo { * optional string foo = 1; * } * Let's look at just the field definition: * optional string foo = 1; * ^ ^^ ^^ ^ ^^^ * a bc de f ghi * We have the following locations: * span path represents * [a,i) [ 4, 0, 2, 0 ] The whole field definition. * [a,b) [ 4, 0, 2, 0, 4 ] The label (optional). * [c,d) [ 4, 0, 2, 0, 5 ] The type (string). * [e,f) [ 4, 0, 2, 0, 1 ] The name (foo). * [g,h) [ 4, 0, 2, 0, 3 ] The number (1). * * Notes: * - A location may refer to a repeated field itself (i.e. not to any * particular index within it). This is used whenever a set of elements are * logically enclosed in a single code segment. For example, an entire * extend block (possibly containing multiple extension definitions) will * have an outer location whose path refers to the "extensions" repeated * field without an index. * - Multiple locations may have the same path. This happens when a single * logical declaration is spread out across multiple places. The most * obvious example is the "extend" block again -- there may be multiple * extend blocks in the same scope, each of which will have the same path. * - A location's span is not always a subset of its parent's span. For * example, the "extendee" of an extension declaration appears at the * beginning of the "extend" block and is shared by all extensions within * the block. * - Just because a location's span is a subset of some other location's span * does not mean that it is a descendant. For example, a "group" defines * both a type and a field in a single declaration. Thus, the locations * corresponding to the type and field and their components will overlap. * - Code which tries to interpret locations should probably be designed to * ignore those that it doesn't understand, as more types of locations could * be recorded in the future. */ location: SourceCodeInfo_Location[]; } export interface SourceCodeInfo_Location { /** * Identifies which part of the FileDescriptorProto was defined at this * location. * * Each element is a field number or an index. They form a path from * the root FileDescriptorProto to the place where the definition. For * example, this path: * [ 4, 3, 2, 7, 1 ] * refers to: * file.message_type(3) // 4, 3 * .field(7) // 2, 7 * .name() // 1 * This is because FileDescriptorProto.message_type has field number 4: * repeated DescriptorProto message_type = 4; * and DescriptorProto.field has field number 2: * repeated FieldDescriptorProto field = 2; * and FieldDescriptorProto.name has field number 1: * optional string name = 1; * * Thus, the above path gives the location of a field name. If we removed * the last element: * [ 4, 3, 2, 7 ] * this path refers to the whole field declaration (from the beginning * of the label to the terminating semicolon). */ path: number[]; /** * Always has exactly three or four elements: start line, start column, * end line (optional, otherwise assumed same as start line), end column. * These are packed into a single field for efficiency. Note that line * and column numbers are zero-based -- typically you will want to add * 1 to each before displaying to a user. */ span: number[]; /** * If this SourceCodeInfo represents a complete declaration, these are any * comments appearing before and after the declaration which appear to be * attached to the declaration. * * A series of line comments appearing on consecutive lines, with no other * tokens appearing on those lines, will be treated as a single comment. * * leading_detached_comments will keep paragraphs of comments that appear * before (but not connected to) the current element. Each paragraph, * separated by empty lines, will be one comment element in the repeated * field. * * Only the comment content is provided; comment markers (e.g. //) are * stripped out. For block comments, leading whitespace and an asterisk * will be stripped from the beginning of each line other than the first. * Newlines are included in the output. * * Examples: * * optional int32 foo = 1; // Comment attached to foo. * // Comment attached to bar. * optional int32 bar = 2; * * optional string baz = 3; * // Comment attached to baz. * // Another line attached to baz. * * // Comment attached to qux. * // * // Another line attached to qux. * optional double qux = 4; * * // Detached comment for corge. This is not leading or trailing comments * // to qux or corge because there are blank lines separating it from * // both. * * // Detached comment for corge paragraph 2. * * optional string corge = 5; * /* Block comment attached * * to corge. Leading asterisks * * will be removed. *\/ * /* Block comment attached to * * grault. *\/ * optional int32 grault = 6; * * // ignored detached comments. */ leading_comments: string; trailing_comments: string; leading_detached_comments: string[]; } /** * Describes the relationship between generated code and its original source * file. A GeneratedCodeInfo message is associated with only one generated * source file, but may contain references to different source .proto files. */ export interface GeneratedCodeInfo { /** * An Annotation connects some span of text in generated code to an element * of its generating .proto file. */ annotation: GeneratedCodeInfo_Annotation[]; } export interface GeneratedCodeInfo_Annotation { /** * Identifies the element in the original source .proto file. This field * is formatted the same as SourceCodeInfo.Location.path. */ path: number[]; /** Identifies the filesystem path to the original source .proto. */ source_file: string; /** * Identifies the starting offset in bytes in the generated code * that relates to the identified object. */ begin: number; /** * Identifies the ending offset in bytes in the generated code that * relates to the identified offset. The end offset should be one past * the last relevant byte (so the length of the text = end - begin). */ end: number; } export declare const FileDescriptorSet: { encode(message: FileDescriptorSet, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): FileDescriptorSet; fromJSON(object: any): FileDescriptorSet; toJSON(message: FileDescriptorSet): unknown; fromPartial(object: DeepPartial): FileDescriptorSet; }; export declare const FileDescriptorProto: { encode(message: FileDescriptorProto, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): FileDescriptorProto; fromJSON(object: any): FileDescriptorProto; toJSON(message: FileDescriptorProto): unknown; fromPartial(object: DeepPartial): FileDescriptorProto; }; export declare const DescriptorProto: { encode(message: DescriptorProto, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): DescriptorProto; fromJSON(object: any): DescriptorProto; toJSON(message: DescriptorProto): unknown; fromPartial(object: DeepPartial): DescriptorProto; }; export declare const DescriptorProto_ExtensionRange: { encode(message: DescriptorProto_ExtensionRange, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): DescriptorProto_ExtensionRange; fromJSON(object: any): DescriptorProto_ExtensionRange; toJSON(message: DescriptorProto_ExtensionRange): unknown; fromPartial(object: DeepPartial): DescriptorProto_ExtensionRange; }; export declare const DescriptorProto_ReservedRange: { encode(message: DescriptorProto_ReservedRange, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): DescriptorProto_ReservedRange; fromJSON(object: any): DescriptorProto_ReservedRange; toJSON(message: DescriptorProto_ReservedRange): unknown; fromPartial(object: DeepPartial): DescriptorProto_ReservedRange; }; export declare const ExtensionRangeOptions: { encode(message: ExtensionRangeOptions, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): ExtensionRangeOptions; fromJSON(object: any): ExtensionRangeOptions; toJSON(message: ExtensionRangeOptions): unknown; fromPartial(object: DeepPartial): ExtensionRangeOptions; }; export declare const FieldDescriptorProto: { encode(message: FieldDescriptorProto, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): FieldDescriptorProto; fromJSON(object: any): FieldDescriptorProto; toJSON(message: FieldDescriptorProto): unknown; fromPartial(object: DeepPartial): FieldDescriptorProto; }; export declare const OneofDescriptorProto: { encode(message: OneofDescriptorProto, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): OneofDescriptorProto; fromJSON(object: any): OneofDescriptorProto; toJSON(message: OneofDescriptorProto): unknown; fromPartial(object: DeepPartial): OneofDescriptorProto; }; export declare const EnumDescriptorProto: { encode(message: EnumDescriptorProto, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): EnumDescriptorProto; fromJSON(object: any): EnumDescriptorProto; toJSON(message: EnumDescriptorProto): unknown; fromPartial(object: DeepPartial): EnumDescriptorProto; }; export declare const EnumDescriptorProto_EnumReservedRange: { encode(message: EnumDescriptorProto_EnumReservedRange, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): EnumDescriptorProto_EnumReservedRange; fromJSON(object: any): EnumDescriptorProto_EnumReservedRange; toJSON(message: EnumDescriptorProto_EnumReservedRange): unknown; fromPartial(object: DeepPartial): EnumDescriptorProto_EnumReservedRange; }; export declare const EnumValueDescriptorProto: { encode(message: EnumValueDescriptorProto, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): EnumValueDescriptorProto; fromJSON(object: any): EnumValueDescriptorProto; toJSON(message: EnumValueDescriptorProto): unknown; fromPartial(object: DeepPartial): EnumValueDescriptorProto; }; export declare const ServiceDescriptorProto: { encode(message: ServiceDescriptorProto, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): ServiceDescriptorProto; fromJSON(object: any): ServiceDescriptorProto; toJSON(message: ServiceDescriptorProto): unknown; fromPartial(object: DeepPartial): ServiceDescriptorProto; }; export declare const MethodDescriptorProto: { encode(message: MethodDescriptorProto, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): MethodDescriptorProto; fromJSON(object: any): MethodDescriptorProto; toJSON(message: MethodDescriptorProto): unknown; fromPartial(object: DeepPartial): MethodDescriptorProto; }; export declare const FileOptions: { encode(message: FileOptions, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): FileOptions; fromJSON(object: any): FileOptions; toJSON(message: FileOptions): unknown; fromPartial(object: DeepPartial): FileOptions; }; export declare const MessageOptions: { encode(message: MessageOptions, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): MessageOptions; fromJSON(object: any): MessageOptions; toJSON(message: MessageOptions): unknown; fromPartial(object: DeepPartial): MessageOptions; }; export declare const FieldOptions: { encode(message: FieldOptions, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): FieldOptions; fromJSON(object: any): FieldOptions; toJSON(message: FieldOptions): unknown; fromPartial(object: DeepPartial): FieldOptions; }; export declare const OneofOptions: { encode(message: OneofOptions, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): OneofOptions; fromJSON(object: any): OneofOptions; toJSON(message: OneofOptions): unknown; fromPartial(object: DeepPartial): OneofOptions; }; export declare const EnumOptions: { encode(message: EnumOptions, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): EnumOptions; fromJSON(object: any): EnumOptions; toJSON(message: EnumOptions): unknown; fromPartial(object: DeepPartial): EnumOptions; }; export declare const EnumValueOptions: { encode(message: EnumValueOptions, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): EnumValueOptions; fromJSON(object: any): EnumValueOptions; toJSON(message: EnumValueOptions): unknown; fromPartial(object: DeepPartial): EnumValueOptions; }; export declare const ServiceOptions: { encode(message: ServiceOptions, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): ServiceOptions; fromJSON(object: any): ServiceOptions; toJSON(message: ServiceOptions): unknown; fromPartial(object: DeepPartial): ServiceOptions; }; export declare const MethodOptions: { encode(message: MethodOptions, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): MethodOptions; fromJSON(object: any): MethodOptions; toJSON(message: MethodOptions): unknown; fromPartial(object: DeepPartial): MethodOptions; }; export declare const UninterpretedOption: { encode(message: UninterpretedOption, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): UninterpretedOption; fromJSON(object: any): UninterpretedOption; toJSON(message: UninterpretedOption): unknown; fromPartial(object: DeepPartial): UninterpretedOption; }; export declare const UninterpretedOption_NamePart: { encode(message: UninterpretedOption_NamePart, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): UninterpretedOption_NamePart; fromJSON(object: any): UninterpretedOption_NamePart; toJSON(message: UninterpretedOption_NamePart): unknown; fromPartial(object: DeepPartial): UninterpretedOption_NamePart; }; export declare const SourceCodeInfo: { encode(message: SourceCodeInfo, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): SourceCodeInfo; fromJSON(object: any): SourceCodeInfo; toJSON(message: SourceCodeInfo): unknown; fromPartial(object: DeepPartial): SourceCodeInfo; }; export declare const SourceCodeInfo_Location: { encode(message: SourceCodeInfo_Location, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): SourceCodeInfo_Location; fromJSON(object: any): SourceCodeInfo_Location; toJSON(message: SourceCodeInfo_Location): unknown; fromPartial(object: DeepPartial): SourceCodeInfo_Location; }; export declare const GeneratedCodeInfo: { encode(message: GeneratedCodeInfo, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): GeneratedCodeInfo; fromJSON(object: any): GeneratedCodeInfo; toJSON(message: GeneratedCodeInfo): unknown; fromPartial(object: DeepPartial): GeneratedCodeInfo; }; export declare const GeneratedCodeInfo_Annotation: { encode(message: GeneratedCodeInfo_Annotation, writer?: _m0.Writer): _m0.Writer; decode(input: _m0.Reader | Uint8Array, length?: number): GeneratedCodeInfo_Annotation; fromJSON(object: any): GeneratedCodeInfo_Annotation; toJSON(message: GeneratedCodeInfo_Annotation): unknown; fromPartial(object: DeepPartial): GeneratedCodeInfo_Annotation; };