Osmosis MCP Server

//@ts-nocheck import { BinaryReader, BinaryWriter } from "../../../binary"; import { bytesFromBase64, base64FromBytes, isSet } from "../../../helpers"; import { GlobalDecoderRegistry } from "../../../registry"; export var HashOp; (function (HashOp) { /** NO_HASH - NO_HASH is the default if no data passed. Note this is an illegal argument some places. */ HashOp[HashOp["NO_HASH"] = 0] = "NO_HASH"; HashOp[HashOp["SHA256"] = 1] = "SHA256"; HashOp[HashOp["SHA512"] = 2] = "SHA512"; HashOp[HashOp["KECCAK256"] = 3] = "KECCAK256"; HashOp[HashOp["RIPEMD160"] = 4] = "RIPEMD160"; /** BITCOIN - ripemd160(sha256(x)) */ HashOp[HashOp["BITCOIN"] = 5] = "BITCOIN"; HashOp[HashOp["SHA512_256"] = 6] = "SHA512_256"; HashOp[HashOp["BLAKE2B_512"] = 7] = "BLAKE2B_512"; HashOp[HashOp["BLAKE2S_256"] = 8] = "BLAKE2S_256"; HashOp[HashOp["BLAKE3"] = 9] = "BLAKE3"; HashOp[HashOp["UNRECOGNIZED"] = -1] = "UNRECOGNIZED"; })(HashOp || (HashOp = {})); export const HashOpSDKType = HashOp; export const HashOpAmino = HashOp; export function hashOpFromJSON(object) { switch (object) { case 0: case "NO_HASH": return HashOp.NO_HASH; case 1: case "SHA256": return HashOp.SHA256; case 2: case "SHA512": return HashOp.SHA512; case 3: case "KECCAK256": return HashOp.KECCAK256; case 4: case "RIPEMD160": return HashOp.RIPEMD160; case 5: case "BITCOIN": return HashOp.BITCOIN; case 6: case "SHA512_256": return HashOp.SHA512_256; case 7: case "BLAKE2B_512": return HashOp.BLAKE2B_512; case 8: case "BLAKE2S_256": return HashOp.BLAKE2S_256; case 9: case "BLAKE3": return HashOp.BLAKE3; case -1: case "UNRECOGNIZED": default: return HashOp.UNRECOGNIZED; } } export function hashOpToJSON(object) { switch (object) { case HashOp.NO_HASH: return "NO_HASH"; case HashOp.SHA256: return "SHA256"; case HashOp.SHA512: return "SHA512"; case HashOp.KECCAK256: return "KECCAK256"; case HashOp.RIPEMD160: return "RIPEMD160"; case HashOp.BITCOIN: return "BITCOIN"; case HashOp.SHA512_256: return "SHA512_256"; case HashOp.BLAKE2B_512: return "BLAKE2B_512"; case HashOp.BLAKE2S_256: return "BLAKE2S_256"; case HashOp.BLAKE3: return "BLAKE3"; case HashOp.UNRECOGNIZED: default: return "UNRECOGNIZED"; } } /** * LengthOp defines how to process the key and value of the LeafOp * to include length information. After encoding the length with the given * algorithm, the length will be prepended to the key and value bytes. * (Each one with it's own encoded length) */ export var LengthOp; (function (LengthOp) { /** NO_PREFIX - NO_PREFIX don't include any length info */ LengthOp[LengthOp["NO_PREFIX"] = 0] = "NO_PREFIX"; /** VAR_PROTO - VAR_PROTO uses protobuf (and go-amino) varint encoding of the length */ LengthOp[LengthOp["VAR_PROTO"] = 1] = "VAR_PROTO"; /** VAR_RLP - VAR_RLP uses rlp int encoding of the length */ LengthOp[LengthOp["VAR_RLP"] = 2] = "VAR_RLP"; /** FIXED32_BIG - FIXED32_BIG uses big-endian encoding of the length as a 32 bit integer */ LengthOp[LengthOp["FIXED32_BIG"] = 3] = "FIXED32_BIG"; /** FIXED32_LITTLE - FIXED32_LITTLE uses little-endian encoding of the length as a 32 bit integer */ LengthOp[LengthOp["FIXED32_LITTLE"] = 4] = "FIXED32_LITTLE"; /** FIXED64_BIG - FIXED64_BIG uses big-endian encoding of the length as a 64 bit integer */ LengthOp[LengthOp["FIXED64_BIG"] = 5] = "FIXED64_BIG"; /** FIXED64_LITTLE - FIXED64_LITTLE uses little-endian encoding of the length as a 64 bit integer */ LengthOp[LengthOp["FIXED64_LITTLE"] = 6] = "FIXED64_LITTLE"; /** REQUIRE_32_BYTES - REQUIRE_32_BYTES is like NONE, but will fail if the input is not exactly 32 bytes (sha256 output) */ LengthOp[LengthOp["REQUIRE_32_BYTES"] = 7] = "REQUIRE_32_BYTES"; /** REQUIRE_64_BYTES - REQUIRE_64_BYTES is like NONE, but will fail if the input is not exactly 64 bytes (sha512 output) */ LengthOp[LengthOp["REQUIRE_64_BYTES"] = 8] = "REQUIRE_64_BYTES"; LengthOp[LengthOp["UNRECOGNIZED"] = -1] = "UNRECOGNIZED"; })(LengthOp || (LengthOp = {})); export const LengthOpSDKType = LengthOp; export const LengthOpAmino = LengthOp; export function lengthOpFromJSON(object) { switch (object) { case 0: case "NO_PREFIX": return LengthOp.NO_PREFIX; case 1: case "VAR_PROTO": return LengthOp.VAR_PROTO; case 2: case "VAR_RLP": return LengthOp.VAR_RLP; case 3: case "FIXED32_BIG": return LengthOp.FIXED32_BIG; case 4: case "FIXED32_LITTLE": return LengthOp.FIXED32_LITTLE; case 5: case "FIXED64_BIG": return LengthOp.FIXED64_BIG; case 6: case "FIXED64_LITTLE": return LengthOp.FIXED64_LITTLE; case 7: case "REQUIRE_32_BYTES": return LengthOp.REQUIRE_32_BYTES; case 8: case "REQUIRE_64_BYTES": return LengthOp.REQUIRE_64_BYTES; case -1: case "UNRECOGNIZED": default: return LengthOp.UNRECOGNIZED; } } export function lengthOpToJSON(object) { switch (object) { case LengthOp.NO_PREFIX: return "NO_PREFIX"; case LengthOp.VAR_PROTO: return "VAR_PROTO"; case LengthOp.VAR_RLP: return "VAR_RLP"; case LengthOp.FIXED32_BIG: return "FIXED32_BIG"; case LengthOp.FIXED32_LITTLE: return "FIXED32_LITTLE"; case LengthOp.FIXED64_BIG: return "FIXED64_BIG"; case LengthOp.FIXED64_LITTLE: return "FIXED64_LITTLE"; case LengthOp.REQUIRE_32_BYTES: return "REQUIRE_32_BYTES"; case LengthOp.REQUIRE_64_BYTES: return "REQUIRE_64_BYTES"; case LengthOp.UNRECOGNIZED: default: return "UNRECOGNIZED"; } } function createBaseExistenceProof() { return { key: new Uint8Array(), value: new Uint8Array(), leaf: undefined, path: [] }; } export const ExistenceProof = { typeUrl: "/cosmos.ics23.v1.ExistenceProof", aminoType: "cosmos-sdk/ExistenceProof", is(o) { return o && (o.$typeUrl === ExistenceProof.typeUrl || (o.key instanceof Uint8Array || typeof o.key === "string") && (o.value instanceof Uint8Array || typeof o.value === "string") && Array.isArray(o.path) && (!o.path.length || InnerOp.is(o.path[0]))); }, isSDK(o) { return o && (o.$typeUrl === ExistenceProof.typeUrl || (o.key instanceof Uint8Array || typeof o.key === "string") && (o.value instanceof Uint8Array || typeof o.value === "string") && Array.isArray(o.path) && (!o.path.length || InnerOp.isSDK(o.path[0]))); }, isAmino(o) { return o && (o.$typeUrl === ExistenceProof.typeUrl || (o.key instanceof Uint8Array || typeof o.key === "string") && (o.value instanceof Uint8Array || typeof o.value === "string") && Array.isArray(o.path) && (!o.path.length || InnerOp.isAmino(o.path[0]))); }, encode(message, writer = BinaryWriter.create()) { if (message.key.length !== 0) { writer.uint32(10).bytes(message.key); } if (message.value.length !== 0) { writer.uint32(18).bytes(message.value); } if (message.leaf !== undefined) { LeafOp.encode(message.leaf, writer.uint32(26).fork()).ldelim(); } for (const v of message.path) { InnerOp.encode(v, writer.uint32(34).fork()).ldelim(); } return writer; }, decode(input, length) { const reader = input instanceof BinaryReader ? input : new BinaryReader(input); let end = length === undefined ? reader.len : reader.pos + length; const message = createBaseExistenceProof(); while (reader.pos < end) { const tag = reader.uint32(); switch (tag >>> 3) { case 1: message.key = reader.bytes(); break; case 2: message.value = reader.bytes(); break; case 3: message.leaf = LeafOp.decode(reader, reader.uint32()); break; case 4: message.path.push(InnerOp.decode(reader, reader.uint32())); break; default: reader.skipType(tag & 7); break; } } return message; }, fromPartial(object) { const message = createBaseExistenceProof(); message.key = object.key ?? new Uint8Array(); message.value = object.value ?? new Uint8Array(); message.leaf = object.leaf !== undefined && object.leaf !== null ? LeafOp.fromPartial(object.leaf) : undefined; message.path = object.path?.map(e => InnerOp.fromPartial(e)) || []; return message; }, fromAmino(object) { const message = createBaseExistenceProof(); if (object.key !== undefined && object.key !== null) { message.key = bytesFromBase64(object.key); } if (object.value !== undefined && object.value !== null) { message.value = bytesFromBase64(object.value); } if (object.leaf !== undefined && object.leaf !== null) { message.leaf = LeafOp.fromAmino(object.leaf); } message.path = object.path?.map(e => InnerOp.fromAmino(e)) || []; return message; }, toAmino(message) { const obj = {}; obj.key = message.key ? base64FromBytes(message.key) : undefined; obj.value = message.value ? base64FromBytes(message.value) : undefined; obj.leaf = message.leaf ? LeafOp.toAmino(message.leaf) : undefined; if (message.path) { obj.path = message.path.map(e => e ? InnerOp.toAmino(e) : undefined); } else { obj.path = message.path; } return obj; }, fromAminoMsg(object) { return ExistenceProof.fromAmino(object.value); }, toAminoMsg(message) { return { type: "cosmos-sdk/ExistenceProof", value: ExistenceProof.toAmino(message) }; }, fromProtoMsg(message) { return ExistenceProof.decode(message.value); }, toProto(message) { return ExistenceProof.encode(message).finish(); }, toProtoMsg(message) { return { typeUrl: "/cosmos.ics23.v1.ExistenceProof", value: ExistenceProof.encode(message).finish() }; } }; GlobalDecoderRegistry.register(ExistenceProof.typeUrl, ExistenceProof); GlobalDecoderRegistry.registerAminoProtoMapping(ExistenceProof.aminoType, ExistenceProof.typeUrl); function createBaseNonExistenceProof() { return { key: new Uint8Array(), left: undefined, right: undefined }; } export const NonExistenceProof = { typeUrl: "/cosmos.ics23.v1.NonExistenceProof", aminoType: "cosmos-sdk/NonExistenceProof", is(o) { return o && (o.$typeUrl === NonExistenceProof.typeUrl || o.key instanceof Uint8Array || typeof o.key === "string"); }, isSDK(o) { return o && (o.$typeUrl === NonExistenceProof.typeUrl || o.key instanceof Uint8Array || typeof o.key === "string"); }, isAmino(o) { return o && (o.$typeUrl === NonExistenceProof.typeUrl || o.key instanceof Uint8Array || typeof o.key === "string"); }, encode(message, writer = BinaryWriter.create()) { if (message.key.length !== 0) { writer.uint32(10).bytes(message.key); } if (message.left !== undefined) { ExistenceProof.encode(message.left, writer.uint32(18).fork()).ldelim(); } if (message.right !== undefined) { ExistenceProof.encode(message.right, writer.uint32(26).fork()).ldelim(); } return writer; }, decode(input, length) { const reader = input instanceof BinaryReader ? input : new BinaryReader(input); let end = length === undefined ? reader.len : reader.pos + length; const message = createBaseNonExistenceProof(); while (reader.pos < end) { const tag = reader.uint32(); switch (tag >>> 3) { case 1: message.key = reader.bytes(); break; case 2: message.left = ExistenceProof.decode(reader, reader.uint32()); break; case 3: message.right = ExistenceProof.decode(reader, reader.uint32()); break; default: reader.skipType(tag & 7); break; } } return message; }, fromPartial(object) { const message = createBaseNonExistenceProof(); message.key = object.key ?? new Uint8Array(); message.left = object.left !== undefined && object.left !== null ? ExistenceProof.fromPartial(object.left) : undefined; message.right = object.right !== undefined && object.right !== null ? ExistenceProof.fromPartial(object.right) : undefined; return message; }, fromAmino(object) { const message = createBaseNonExistenceProof(); if (object.key !== undefined && object.key !== null) { message.key = bytesFromBase64(object.key); } if (object.left !== undefined && object.left !== null) { message.left = ExistenceProof.fromAmino(object.left); } if (object.right !== undefined && object.right !== null) { message.right = ExistenceProof.fromAmino(object.right); } return message; }, toAmino(message) { const obj = {}; obj.key = message.key ? base64FromBytes(message.key) : undefined; obj.left = message.left ? ExistenceProof.toAmino(message.left) : undefined; obj.right = message.right ? ExistenceProof.toAmino(message.right) : undefined; return obj; }, fromAminoMsg(object) { return NonExistenceProof.fromAmino(object.value); }, toAminoMsg(message) { return { type: "cosmos-sdk/NonExistenceProof", value: NonExistenceProof.toAmino(message) }; }, fromProtoMsg(message) { return NonExistenceProof.decode(message.value); }, toProto(message) { return NonExistenceProof.encode(message).finish(); }, toProtoMsg(message) { return { typeUrl: "/cosmos.ics23.v1.NonExistenceProof", value: NonExistenceProof.encode(message).finish() }; } }; GlobalDecoderRegistry.register(NonExistenceProof.typeUrl, NonExistenceProof); GlobalDecoderRegistry.registerAminoProtoMapping(NonExistenceProof.aminoType, NonExistenceProof.typeUrl); function createBaseCommitmentProof() { return { exist: undefined, nonexist: undefined, batch: undefined, compressed: undefined }; } export const CommitmentProof = { typeUrl: "/cosmos.ics23.v1.CommitmentProof", aminoType: "cosmos-sdk/CommitmentProof", is(o) { return o && o.$typeUrl === CommitmentProof.typeUrl; }, isSDK(o) { return o && o.$typeUrl === CommitmentProof.typeUrl; }, isAmino(o) { return o && o.$typeUrl === CommitmentProof.typeUrl; }, encode(message, writer = BinaryWriter.create()) { if (message.exist !== undefined) { ExistenceProof.encode(message.exist, writer.uint32(10).fork()).ldelim(); } if (message.nonexist !== undefined) { NonExistenceProof.encode(message.nonexist, writer.uint32(18).fork()).ldelim(); } if (message.batch !== undefined) { BatchProof.encode(message.batch, writer.uint32(26).fork()).ldelim(); } if (message.compressed !== undefined) { CompressedBatchProof.encode(message.compressed, writer.uint32(34).fork()).ldelim(); } return writer; }, decode(input, length) { const reader = input instanceof BinaryReader ? input : new BinaryReader(input); let end = length === undefined ? reader.len : reader.pos + length; const message = createBaseCommitmentProof(); while (reader.pos < end) { const tag = reader.uint32(); switch (tag >>> 3) { case 1: message.exist = ExistenceProof.decode(reader, reader.uint32()); break; case 2: message.nonexist = NonExistenceProof.decode(reader, reader.uint32()); break; case 3: message.batch = BatchProof.decode(reader, reader.uint32()); break; case 4: message.compressed = CompressedBatchProof.decode(reader, reader.uint32()); break; default: reader.skipType(tag & 7); break; } } return message; }, fromPartial(object) { const message = createBaseCommitmentProof(); message.exist = object.exist !== undefined && object.exist !== null ? ExistenceProof.fromPartial(object.exist) : undefined; message.nonexist = object.nonexist !== undefined && object.nonexist !== null ? NonExistenceProof.fromPartial(object.nonexist) : undefined; message.batch = object.batch !== undefined && object.batch !== null ? BatchProof.fromPartial(object.batch) : undefined; message.compressed = object.compressed !== undefined && object.compressed !== null ? CompressedBatchProof.fromPartial(object.compressed) : undefined; return message; }, fromAmino(object) { const message = createBaseCommitmentProof(); if (object.exist !== undefined && object.exist !== null) { message.exist = ExistenceProof.fromAmino(object.exist); } if (object.nonexist !== undefined && object.nonexist !== null) { message.nonexist = NonExistenceProof.fromAmino(object.nonexist); } if (object.batch !== undefined && object.batch !== null) { message.batch = BatchProof.fromAmino(object.batch); } if (object.compressed !== undefined && object.compressed !== null) { message.compressed = CompressedBatchProof.fromAmino(object.compressed); } return message; }, toAmino(message) { const obj = {}; obj.exist = message.exist ? ExistenceProof.toAmino(message.exist) : undefined; obj.nonexist = message.nonexist ? NonExistenceProof.toAmino(message.nonexist) : undefined; obj.batch = message.batch ? BatchProof.toAmino(message.batch) : undefined; obj.compressed = message.compressed ? CompressedBatchProof.toAmino(message.compressed) : undefined; return obj; }, fromAminoMsg(object) { return CommitmentProof.fromAmino(object.value); }, toAminoMsg(message) { return { type: "cosmos-sdk/CommitmentProof", value: CommitmentProof.toAmino(message) }; }, fromProtoMsg(message) { return CommitmentProof.decode(message.value); }, toProto(message) { return CommitmentProof.encode(message).finish(); }, toProtoMsg(message) { return { typeUrl: "/cosmos.ics23.v1.CommitmentProof", value: CommitmentProof.encode(message).finish() }; } }; GlobalDecoderRegistry.register(CommitmentProof.typeUrl, CommitmentProof); GlobalDecoderRegistry.registerAminoProtoMapping(CommitmentProof.aminoType, CommitmentProof.typeUrl); function createBaseLeafOp() { return { hash: 0, prehashKey: 0, prehashValue: 0, length: 0, prefix: new Uint8Array() }; } export const LeafOp = { typeUrl: "/cosmos.ics23.v1.LeafOp", aminoType: "cosmos-sdk/LeafOp", is(o) { return o && (o.$typeUrl === LeafOp.typeUrl || isSet(o.hash) && isSet(o.prehashKey) && isSet(o.prehashValue) && isSet(o.length) && (o.prefix instanceof Uint8Array || typeof o.prefix === "string")); }, isSDK(o) { return o && (o.$typeUrl === LeafOp.typeUrl || isSet(o.hash) && isSet(o.prehash_key) && isSet(o.prehash_value) && isSet(o.length) && (o.prefix instanceof Uint8Array || typeof o.prefix === "string")); }, isAmino(o) { return o && (o.$typeUrl === LeafOp.typeUrl || isSet(o.hash) && isSet(o.prehash_key) && isSet(o.prehash_value) && isSet(o.length) && (o.prefix instanceof Uint8Array || typeof o.prefix === "string")); }, encode(message, writer = BinaryWriter.create()) { if (message.hash !== 0) { writer.uint32(8).int32(message.hash); } if (message.prehashKey !== 0) { writer.uint32(16).int32(message.prehashKey); } if (message.prehashValue !== 0) { writer.uint32(24).int32(message.prehashValue); } if (message.length !== 0) { writer.uint32(32).int32(message.length); } if (message.prefix.length !== 0) { writer.uint32(42).bytes(message.prefix); } return writer; }, decode(input, length) { const reader = input instanceof BinaryReader ? input : new BinaryReader(input); let end = length === undefined ? reader.len : reader.pos + length; const message = createBaseLeafOp(); while (reader.pos < end) { const tag = reader.uint32(); switch (tag >>> 3) { case 1: message.hash = reader.int32(); break; case 2: message.prehashKey = reader.int32(); break; case 3: message.prehashValue = reader.int32(); break; case 4: message.length = reader.int32(); break; case 5: message.prefix = reader.bytes(); break; default: reader.skipType(tag & 7); break; } } return message; }, fromPartial(object) { const message = createBaseLeafOp(); message.hash = object.hash ?? 0; message.prehashKey = object.prehashKey ?? 0; message.prehashValue = object.prehashValue ?? 0; message.length = object.length ?? 0; message.prefix = object.prefix ?? new Uint8Array(); return message; }, fromAmino(object) { const message = createBaseLeafOp(); if (object.hash !== undefined && object.hash !== null) { message.hash = object.hash; } if (object.prehash_key !== undefined && object.prehash_key !== null) { message.prehashKey = object.prehash_key; } if (object.prehash_value !== undefined && object.prehash_value !== null) { message.prehashValue = object.prehash_value; } if (object.length !== undefined && object.length !== null) { message.length = object.length; } if (object.prefix !== undefined && object.prefix !== null) { message.prefix = bytesFromBase64(object.prefix); } return message; }, toAmino(message) { const obj = {}; obj.hash = message.hash === 0 ? undefined : message.hash; obj.prehash_key = message.prehashKey === 0 ? undefined : message.prehashKey; obj.prehash_value = message.prehashValue === 0 ? undefined : message.prehashValue; obj.length = message.length === 0 ? undefined : message.length; obj.prefix = message.prefix ? base64FromBytes(message.prefix) : undefined; return obj; }, fromAminoMsg(object) { return LeafOp.fromAmino(object.value); }, toAminoMsg(message) { return { type: "cosmos-sdk/LeafOp", value: LeafOp.toAmino(message) }; }, fromProtoMsg(message) { return LeafOp.decode(message.value); }, toProto(message) { return LeafOp.encode(message).finish(); }, toProtoMsg(message) { return { typeUrl: "/cosmos.ics23.v1.LeafOp", value: LeafOp.encode(message).finish() }; } }; GlobalDecoderRegistry.register(LeafOp.typeUrl, LeafOp); GlobalDecoderRegistry.registerAminoProtoMapping(LeafOp.aminoType, LeafOp.typeUrl); function createBaseInnerOp() { return { hash: 0, prefix: new Uint8Array(), suffix: new Uint8Array() }; } export const InnerOp = { typeUrl: "/cosmos.ics23.v1.InnerOp", aminoType: "cosmos-sdk/InnerOp", is(o) { return o && (o.$typeUrl === InnerOp.typeUrl || isSet(o.hash) && (o.prefix instanceof Uint8Array || typeof o.prefix === "string") && (o.suffix instanceof Uint8Array || typeof o.suffix === "string")); }, isSDK(o) { return o && (o.$typeUrl === InnerOp.typeUrl || isSet(o.hash) && (o.prefix instanceof Uint8Array || typeof o.prefix === "string") && (o.suffix instanceof Uint8Array || typeof o.suffix === "string")); }, isAmino(o) { return o && (o.$typeUrl === InnerOp.typeUrl || isSet(o.hash) && (o.prefix instanceof Uint8Array || typeof o.prefix === "string") && (o.suffix instanceof Uint8Array || typeof o.suffix === "string")); }, encode(message, writer = BinaryWriter.create()) { if (message.hash !== 0) { writer.uint32(8).int32(message.hash); } if (message.prefix.length !== 0) { writer.uint32(18).bytes(message.prefix); } if (message.suffix.length !== 0) { writer.uint32(26).bytes(message.suffix); } return writer; }, decode(input, length) { const reader = input instanceof BinaryReader ? input : new BinaryReader(input); let end = length === undefined ? reader.len : reader.pos + length; const message = createBaseInnerOp(); while (reader.pos < end) { const tag = reader.uint32(); switch (tag >>> 3) { case 1: message.hash = reader.int32(); break; case 2: message.prefix = reader.bytes(); break; case 3: message.suffix = reader.bytes(); break; default: reader.skipType(tag & 7); break; } } return message; }, fromPartial(object) { const message = createBaseInnerOp(); message.hash = object.hash ?? 0; message.prefix = object.prefix ?? new Uint8Array(); message.suffix = object.suffix ?? new Uint8Array(); return message; }, fromAmino(object) { const message = createBaseInnerOp(); if (object.hash !== undefined && object.hash !== null) { message.hash = object.hash; } if (object.prefix !== undefined && object.prefix !== null) { message.prefix = bytesFromBase64(object.prefix); } if (object.suffix !== undefined && object.suffix !== null) { message.suffix = bytesFromBase64(object.suffix); } return message; }, toAmino(message) { const obj = {}; obj.hash = message.hash === 0 ? undefined : message.hash; obj.prefix = message.prefix ? base64FromBytes(message.prefix) : undefined; obj.suffix = message.suffix ? base64FromBytes(message.suffix) : undefined; return obj; }, fromAminoMsg(object) { return InnerOp.fromAmino(object.value); }, toAminoMsg(message) { return { type: "cosmos-sdk/InnerOp", value: InnerOp.toAmino(message) }; }, fromProtoMsg(message) { return InnerOp.decode(message.value); }, toProto(message) { return InnerOp.encode(message).finish(); }, toProtoMsg(message) { return { typeUrl: "/cosmos.ics23.v1.InnerOp", value: InnerOp.encode(message).finish() }; } }; GlobalDecoderRegistry.register(InnerOp.typeUrl, InnerOp); GlobalDecoderRegistry.registerAminoProtoMapping(InnerOp.aminoType, InnerOp.typeUrl); function createBaseProofSpec() { return { leafSpec: undefined, innerSpec: undefined, maxDepth: 0, minDepth: 0, prehashKeyBeforeComparison: false }; } export const ProofSpec = { typeUrl: "/cosmos.ics23.v1.ProofSpec", aminoType: "cosmos-sdk/ProofSpec", is(o) { return o && (o.$typeUrl === ProofSpec.typeUrl || typeof o.maxDepth === "number" && typeof o.minDepth === "number" && typeof o.prehashKeyBeforeComparison === "boolean"); }, isSDK(o) { return o && (o.$typeUrl === ProofSpec.typeUrl || typeof o.max_depth === "number" && typeof o.min_depth === "number" && typeof o.prehash_key_before_comparison === "boolean"); }, isAmino(o) { return o && (o.$typeUrl === ProofSpec.typeUrl || typeof o.max_depth === "number" && typeof o.min_depth === "number" && typeof o.prehash_key_before_comparison === "boolean"); }, encode(message, writer = BinaryWriter.create()) { if (message.leafSpec !== undefined) { LeafOp.encode(message.leafSpec, writer.uint32(10).fork()).ldelim(); } if (message.innerSpec !== undefined) { InnerSpec.encode(message.innerSpec, writer.uint32(18).fork()).ldelim(); } if (message.maxDepth !== 0) { writer.uint32(24).int32(message.maxDepth); } if (message.minDepth !== 0) { writer.uint32(32).int32(message.minDepth); } if (message.prehashKeyBeforeComparison === true) { writer.uint32(40).bool(message.prehashKeyBeforeComparison); } return writer; }, decode(input, length) { const reader = input instanceof BinaryReader ? input : new BinaryReader(input); let end = length === undefined ? reader.len : reader.pos + length; const message = createBaseProofSpec(); while (reader.pos < end) { const tag = reader.uint32(); switch (tag >>> 3) { case 1: message.leafSpec = LeafOp.decode(reader, reader.uint32()); break; case 2: message.innerSpec = InnerSpec.decode(reader, reader.uint32()); break; case 3: message.maxDepth = reader.int32(); break; case 4: message.minDepth = reader.int32(); break; case 5: message.prehashKeyBeforeComparison = reader.bool(); break; default: reader.skipType(tag & 7); break; } } return message; }, fromPartial(object) { const message = createBaseProofSpec(); message.leafSpec = object.leafSpec !== undefined && object.leafSpec !== null ? LeafOp.fromPartial(object.leafSpec) : undefined; message.innerSpec = object.innerSpec !== undefined && object.innerSpec !== null ? InnerSpec.fromPartial(object.innerSpec) : undefined; message.maxDepth = object.maxDepth ?? 0; message.minDepth = object.minDepth ?? 0; message.prehashKeyBeforeComparison = object.prehashKeyBeforeComparison ?? false; return message; }, fromAmino(object) { const message = createBaseProofSpec(); if (object.leaf_spec !== undefined && object.leaf_spec !== null) { message.leafSpec = LeafOp.fromAmino(object.leaf_spec); } if (object.inner_spec !== undefined && object.inner_spec !== null) { message.innerSpec = InnerSpec.fromAmino(object.inner_spec); } if (object.max_depth !== undefined && object.max_depth !== null) { message.maxDepth = object.max_depth; } if (object.min_depth !== undefined && object.min_depth !== null) { message.minDepth = object.min_depth; } if (object.prehash_key_before_comparison !== undefined && object.prehash_key_before_comparison !== null) { message.prehashKeyBeforeComparison = object.prehash_key_before_comparison; } return message; }, toAmino(message) { const obj = {}; obj.leaf_spec = message.leafSpec ? LeafOp.toAmino(message.leafSpec) : undefined; obj.inner_spec = message.innerSpec ? InnerSpec.toAmino(message.innerSpec) : undefined; obj.max_depth = message.maxDepth === 0 ? undefined : message.maxDepth; obj.min_depth = message.minDepth === 0 ? undefined : message.minDepth; obj.prehash_key_before_comparison = message.prehashKeyBeforeComparison === false ? undefined : message.prehashKeyBeforeComparison; return obj; }, fromAminoMsg(object) { return ProofSpec.fromAmino(object.value); }, toAminoMsg(message) { return { type: "cosmos-sdk/ProofSpec", value: ProofSpec.toAmino(message) }; }, fromProtoMsg(message) { return ProofSpec.decode(message.value); }, toProto(message) { return ProofSpec.encode(message).finish(); }, toProtoMsg(message) { return { typeUrl: "/cosmos.ics23.v1.ProofSpec", value: ProofSpec.encode(message).finish() }; } }; GlobalDecoderRegistry.register(ProofSpec.typeUrl, ProofSpec); GlobalDecoderRegistry.registerAminoProtoMapping(ProofSpec.aminoType, ProofSpec.typeUrl); function createBaseInnerSpec() { return { childOrder: [], childSize: 0, minPrefixLength: 0, maxPrefixLength: 0, emptyChild: new Uint8Array(), hash: 0 }; } export const InnerSpec = { typeUrl: "/cosmos.ics23.v1.InnerSpec", aminoType: "cosmos-sdk/InnerSpec", is(o) { return o && (o.$typeUrl === InnerSpec.typeUrl || Array.isArray(o.childOrder) && (!o.childOrder.length || typeof o.childOrder[0] === "number") && typeof o.childSize === "number" && typeof o.minPrefixLength === "number" && typeof o.maxPrefixLength === "number" && (o.emptyChild instanceof Uint8Array || typeof o.emptyChild === "string") && isSet(o.hash)); }, isSDK(o) { return o && (o.$typeUrl === InnerSpec.typeUrl || Array.isArray(o.child_order) && (!o.child_order.length || typeof o.child_order[0] === "number") && typeof o.child_size === "number" && typeof o.min_prefix_length === "number" && typeof o.max_prefix_length === "number" && (o.empty_child instanceof Uint8Array || typeof o.empty_child === "string") && isSet(o.hash)); }, isAmino(o) { return o && (o.$typeUrl === InnerSpec.typeUrl || Array.isArray(o.child_order) && (!o.child_order.length || typeof o.child_order[0] === "number") && typeof o.child_size === "number" && typeof o.min_prefix_length === "number" && typeof o.max_prefix_length === "number" && (o.empty_child instanceof Uint8Array || typeof o.empty_child === "string") && isSet(o.hash)); }, encode(message, writer = BinaryWriter.create()) { writer.uint32(10).fork(); for (const v of message.childOrder) { writer.int32(v); } writer.ldelim(); if (message.childSize !== 0) { writer.uint32(16).int32(message.childSize); } if (message.minPrefixLength !== 0) { writer.uint32(24).int32(message.minPrefixLength); } if (message.maxPrefixLength !== 0) { writer.uint32(32).int32(message.maxPrefixLength); } if (message.emptyChild.length !== 0) { writer.uint32(42).bytes(message.emptyChild); } if (message.hash !== 0) { writer.uint32(48).int32(message.hash); } return writer; }, decode(input, length) { const reader = input instanceof BinaryReader ? input : new BinaryReader(input); let end = length === undefined ? reader.len : reader.pos + length; const message = createBaseInnerSpec(); while (reader.pos < end) { const tag = reader.uint32(); switch (tag >>> 3) { case 1: if ((tag & 7) === 2) { const end2 = reader.uint32() + reader.pos; while (reader.pos < end2) { message.childOrder.push(reader.int32()); } } else { message.childOrder.push(reader.int32()); } break; case 2: message.childSize = reader.int32(); break; case 3: message.minPrefixLength = reader.int32(); break; case 4: message.maxPrefixLength = reader.int32(); break; case 5: message.emptyChild = reader.bytes(); break; case 6: message.hash = reader.int32(); break; default: reader.skipType(tag & 7); break; } } return message; }, fromPartial(object) { const message = createBaseInnerSpec(); message.childOrder = object.childOrder?.map(e => e) || []; message.childSize = object.childSize ?? 0; message.minPrefixLength = object.minPrefixLength ?? 0; message.maxPrefixLength = object.maxPrefixLength ?? 0; message.emptyChild = object.emptyChild ?? new Uint8Array(); message.hash = object.hash ?? 0; return message; }, fromAmino(object) { const message = createBaseInnerSpec(); message.childOrder = object.child_order?.map(e => e) || []; if (object.child_size !== undefined && object.child_size !== null) { message.childSize = object.child_size; } if (object.min_prefix_length !== undefined && object.min_prefix_length !== null) { message.minPrefixLength = object.min_prefix_length; } if (object.max_prefix_length !== undefined && object.max_prefix_length !== null) { message.maxPrefixLength = object.max_prefix_length; } if (object.empty_child !== undefined && object.empty_child !== null) { message.emptyChild = bytesFromBase64(object.empty_child); } if (object.hash !== undefined && object.hash !== null) { message.hash = object.hash; } return message; }, toAmino(message) { const obj = {}; if (message.childOrder) { obj.child_order = message.childOrder.map(e => e); } else { obj.child_order = message.childOrder; } obj.child_size = message.childSize === 0 ? undefined : message.childSize; obj.min_prefix_length = message.minPrefixLength === 0 ? undefined : message.minPrefixLength; obj.max_prefix_length = message.maxPrefixLength === 0 ? undefined : message.maxPrefixLength; obj.empty_child = message.emptyChild ? base64FromBytes(message.emptyChild) : undefined; obj.hash = message.hash === 0 ? undefined : message.hash; return obj; }, fromAminoMsg(object) { return InnerSpec.fromAmino(object.value); }, toAminoMsg(message) { return { type: "cosmos-sdk/InnerSpec", value: InnerSpec.toAmino(message) }; }, fromProtoMsg(message) { return InnerSpec.decode(message.value); }, toProto(message) { return InnerSpec.encode(message).finish(); }, toProtoMsg(message) { return { typeUrl: "/cosmos.ics23.v1.InnerSpec", value: InnerSpec.encode(message).finish() }; } }; GlobalDecoderRegistry.register(InnerSpec.typeUrl, InnerSpec); GlobalDecoderRegistry.registerAminoProtoMapping(InnerSpec.aminoType, InnerSpec.typeUrl); function createBaseBatchProof() { return { entries: [] }; } export const BatchProof = { typeUrl: "/cosmos.ics23.v1.BatchProof", aminoType: "cosmos-sdk/BatchProof", is(o) { return o && (o.$typeUrl === BatchProof.typeUrl || Array.isArray(o.entries) && (!o.entries.length || BatchEntry.is(o.entries[0]))); }, isSDK(o) { return o && (o.$typeUrl === BatchProof.typeUrl || Array.isArray(o.entries) && (!o.entries.length || BatchEntry.isSDK(o.entries[0]))); }, isAmino(o) { return o && (o.$typeUrl === BatchProof.typeUrl || Array.isArray(o.entries) && (!o.entries.length || BatchEntry.isAmino(o.entries[0]))); }, encode(message, writer = BinaryWriter.create()) { for (const v of message.entries) { BatchEntry.encode(v, writer.uint32(10).fork()).ldelim(); } return writer; }, decode(input, length) { const reader = input instanceof BinaryReader ? input : new BinaryReader(input); let end = length === undefined ? reader.len : reader.pos + length; const message = createBaseBatchProof(); while (reader.pos < end) { const tag = reader.uint32(); switch (tag >>> 3) { case 1: message.entries.push(BatchEntry.decode(reader, reader.uint32())); break; default: reader.skipType(tag & 7); break; } } return message; }, fromPartial(object) { const message = createBaseBatchProof(); message.entries = object.entries?.map(e => BatchEntry.fromPartial(e)) || []; return message; }, fromAmino(object) { const message = createBaseBatchProof(); message.entries = object.entries?.map(e => BatchEntry.fromAmino(e)) || []; return message; }, toAmino(message) { const obj = {}; if (message.entries) { obj.entries = message.entries.map(e => e ? BatchEntry.toAmino(e) : undefined); } else { obj.entries = message.entries; } return obj; }, fromAminoMsg(object) { return BatchProof.fromAmino(object.value); }, toAminoMsg(message) { return { type: "cosmos-sdk/BatchProof", value: BatchProof.toAmino(message) }; }, fromProtoMsg(message) { return BatchProof.decode(message.value); }, toProto(message) { return BatchProof.encode(message).finish(); }, toProtoMsg(message) { return { typeUrl: "/cosmos.ics23.v1.BatchProof", value: BatchProof.encode(message).finish() }; } }; GlobalDecoderRegistry.register(BatchProof.typeUrl, BatchProof); GlobalDecoderRegistry.registerAminoProtoMapping(BatchProof.aminoType, BatchProof.typeUrl); function createBaseBatchEntry() { return { exist: undefined, nonexist: undefined }; } export const BatchEntry = { typeUrl: "/cosmos.ics23.v1.BatchEntry", aminoType: "cosmos-sdk/BatchEntry", is(o) { return o && o.$typeUrl === BatchEntry.typeUrl; }, isSDK(o) { return o && o.$typeUrl === BatchEntry.typeUrl; }, isAmino(o) { return o && o.$typeUrl === BatchEntry.typeUrl; }, encode(message, writer = BinaryWriter.create()) { if (message.exist !== undefined) { ExistenceProof.encode(message.exist, writer.uint32(10).fork()).ldelim(); } if (message.nonexist !== undefined) { NonExistenceProof.encode(message.nonexist, writer.uint32(18).fork()).ldelim(); } return writer; }, decode(input, length) { const reader = input instanceof BinaryReader ? input : new BinaryReader(input); let end = length === undefined ? reader.len : reader.pos + length; const message = createBaseBatchEntry(); while (reader.pos < end) { const tag = reader.uint32(); switch (tag >>> 3) { case 1: message.exist = ExistenceProof.decode(reader, reader.uint32()); break; case 2: message.nonexist = NonExistenceProof.decode(reader, reader.uint32()); break; default: reader.skipType(tag & 7); break; } } return message; }, fromPartial(object) { const message = createBaseBatchEntry(); message.exist = object.exist !== undefined && object.exist !== null ? ExistenceProof.fromPartial(object.exist) : undefined; message.nonexist = object.nonexist !== undefined && object.nonexist !== null ? NonExistenceProof.fromPartial(object.nonexist) : undefined; return message; }, fromAmino(object) { const message = createBaseBatchEntry(); if (object.exist !== undefined && object.exist !== null) { message.exist = ExistenceProof.fromAmino(object.exist); } if (object.nonexist !== undefined && object.nonexist !== null) { message.nonexist = NonExistenceProof.fromAmino(object.nonexist); } return message; }, toAmino(message) { const obj = {}; obj.exist = message.exist ? ExistenceProof.toAmino(message.exist) : undefined; obj.nonexist = message.nonexist ? NonExistenceProof.toAmino(message.nonexist) : undefined; return obj; }, fromAminoMsg(object) { return BatchEntry.fromAmino(object.value); }, toAminoMsg(message) { return { type: "cosmos-sdk/BatchEntry", value: BatchEntry.toAmino(message) }; }, fromProtoMsg(message) { return BatchEntry.decode(message.value); }, toProto(message) { return BatchEntry.encode(message).finish(); }, toProtoMsg(message) { return { typeUrl: "/cosmos.ics23.v1.BatchEntry", value: BatchEntry.encode(message).finish() }; } }; GlobalDecoderRegistry.register(BatchEntry.typeUrl, BatchEntry); GlobalDecoderRegistry.registerAminoProtoMapping(BatchEntry.aminoType, BatchEntry.typeUrl); function createBaseCompressedBatchProof() { return { entries: [], lookupInners: [] }; } export const CompressedBatchProof = { typeUrl: "/cosmos.ics23.v1.CompressedBatchProof", aminoType: "cosmos-sdk/CompressedBatchProof", is(o) { return o && (o.$typeUrl === CompressedBatchProof.typeUrl || Array.isArray(o.entries) && (!o.entries.length || CompressedBatchEntry.is(o.entries[0])) && Array.isArray(o.lookupInners) && (!o.lookupInners.length || InnerOp.is(o.lookupInners[0]))); }, isSDK(o) { return o && (o.$typeUrl === CompressedBatchProof.typeUrl || Array.isArray(o.entries) && (!o.entries.length || CompressedBatchEntry.isSDK(o.entries[0])) && Array.isArray(o.lookup_inners) && (!o.lookup_inners.length || InnerOp.isSDK(o.lookup_inners[0]))); }, isAmino(o) { return o && (o.$typeUrl === CompressedBatchProof.typeUrl || Array.isArray(o.entries) && (!o.entries.length || CompressedBatchEntry.isAmino(o.entries[0])) && Array.isArray(o.lookup_inners) && (!o.lookup_inners.length || InnerOp.isAmino(o.lookup_inners[0]))); }, encode(message, writer = BinaryWriter.create()) { for (const v of message.entries) { CompressedBatchEntry.encode(v, writer.uint32(10).fork()).ldelim(); } for (const v of message.lookupInners) { InnerOp.encode(v, writer.uint32(18).fork()).ldelim(); } return writer; }, decode(input, length) { const reader = input instanceof BinaryReader ? input : new BinaryReader(input); let end = length === undefined ? reader.len : reader.pos + length; const message = createBaseCompressedBatchProof(); while (reader.pos < end) { const tag = reader.uint32(); switch (tag >>> 3) { case 1: message.entries.push(CompressedBatchEntry.decode(reader, reader.uint32())); break; case 2: message.lookupInners.push(InnerOp.decode(reader, reader.uint32())); break; default: reader.skipType(tag & 7); break; } } return message; }, fromPartial(object) { const message = createBaseCompressedBatchProof(); message.entries = object.entries?.map(e => CompressedBatchEntry.fromPartial(e)) || []; message.lookupInners = object.lookupInners?.map(e => InnerOp.fromPartial(e)) || []; return message; }, fromAmino(object) { const message = createBaseCompressedBatchProof(); message.entries = object.entries?.map(e => CompressedBatchEntry.fromAmino(e)) || []; message.lookupInners = object.lookup_inners?.map(e => InnerOp.fromAmino(e)) || []; return message; }, toAmino(message) { const obj = {}; if (message.entries) { obj.entries = message.entries.map(e => e ? CompressedBatchEntry.toAmino(e) : undefined); } else { obj.entries = message.entries; } if (message.lookupInners) { obj.lookup_inners = message.lookupInners.map(e => e ? InnerOp.toAmino(e) : undefined); } else { obj.lookup_inners = message.lookupInners; } return obj; }, fromAminoMsg(object) { return CompressedBatchProof.fromAmino(object.value); }, toAminoMsg(message) { return { type: "cosmos-sdk/CompressedBatchProof", value: CompressedBatchProof.toAmino(message) }; }, fromProtoMsg(message) { return CompressedBatchProof.decode(message.value); }, toProto(message) { return CompressedBatchProof.encode(message).finish(); }, toProtoMsg(message) { return { typeUrl: "/cosmos.ics23.v1.CompressedBatchProof", value: CompressedBatchProof.encode(message).finish() }; } }; GlobalDecoderRegistry.register(CompressedBatchProof.typeUrl, CompressedBatchProof); GlobalDecoderRegistry.registerAminoProtoMapping(CompressedBatchProof.aminoType, CompressedBatchProof.typeUrl); function createBaseCompressedBatchEntry() { return { exist: undefined, nonexist: undefined }; } export const CompressedBatchEntry = { typeUrl: "/cosmos.ics23.v1.CompressedBatchEntry", aminoType: "cosmos-sdk/CompressedBatchEntry", is(o) { return o && o.$typeUrl === CompressedBatchEntry.typeUrl; }, isSDK(o) { return o && o.$typeUrl === CompressedBatchEntry.typeUrl; }, isAmino(o) { return o && o.$typeUrl === CompressedBatchEntry.typeUrl; }, encode(message, writer = BinaryWriter.create()) { if (message.exist !== undefined) { CompressedExistenceProof.encode(message.exist, writer.uint32(10).fork()).ldelim(); } if (message.nonexist !== undefined) { CompressedNonExistenceProof.encode(message.nonexist, writer.uint32(18).fork()).ldelim(); } return writer; }, decode(input, length) { const reader = input instanceof BinaryReader ? input : new BinaryReader(input); let end = length === undefined ? reader.len : reader.pos + length; const message = createBaseCompressedBatchEntry(); while (reader.pos < end) { const tag = reader.uint32(); switch (tag >>> 3) { case 1: message.exist = CompressedExistenceProof.decode(reader, reader.uint32()); break; case 2: message.nonexist = CompressedNonExistenceProof.decode(reader, reader.uint32()); break; default: reader.skipType(tag & 7); break; } } return message; }, fromPartial(object) { const message = createBaseCompressedBatchEntry(); message.exist = object.exist !== undefined && object.exist !== null ? CompressedExistenceProof.fromPartial(object.exist) : undefined; message.nonexist = object.nonexist !== undefined && object.nonexist !== null ? CompressedNonExistenceProof.fromPartial(object.nonexist) : undefined; return message; }, fromAmino(object) { const message = createBaseCompressedBatchEntry(); if (object.exist !== undefined && object.exist !== null) { message.exist = CompressedExistenceProof.fromAmino(object.exist); } if (object.nonexist !== undefined && object.nonexist !== null) { message.nonexist = CompressedNonExistenceProof.fromAmino(object.nonexist); } return message; }, toAmino(message) { const obj = {}; obj.exist = message.exist ? CompressedExistenceProof.toAmino(message.exist) : undefined; obj.nonexist = message.nonexist ? CompressedNonExistenceProof.toAmino(message.nonexist) : undefined; return obj; }, fromAminoMsg(object) { return CompressedBatchEntry.fromAmino(object.value); }, toAminoMsg(message) { return { type: "cosmos-sdk/CompressedBatchEntry", value: CompressedBatchEntry.toAmino(message) }; }, fromProtoMsg(message) { return CompressedBatchEntry.decode(message.value); }, toProto(message) { return CompressedBatchEntry.encode(message).finish(); }, toProtoMsg(message) { return { typeUrl: "/cosmos.ics23.v1.CompressedBatchEntry", value: CompressedBatchEntry.encode(message).finish() }; } }; GlobalDecoderRegistry.register(CompressedBatchEntry.typeUrl, CompressedBatchEntry); GlobalDecoderRegistry.registerAminoProtoMapping(CompressedBatchEntry.aminoType, CompressedBatchEntry.typeUrl); function createBaseCompressedExistenceProof() { return { key: new Uint8Array(), value: new Uint8Array(), leaf: undefined, path: [] }; } export const CompressedExistenceProof = { typeUrl: "/cosmos.ics23.v1.CompressedExistenceProof", aminoType: "cosmos-sdk/CompressedExistenceProof", is(o) { return o && (o.$typeUrl === CompressedExistenceProof.typeUrl || (o.key instanceof Uint8Array || typeof o.key === "string") && (o.value instanceof Uint8Array || typeof o.value === "string") && Array.isArray(o.path) && (!o.path.length || typeof o.path[0] === "number")); }, isSDK(o) { return o && (o.$typeUrl === CompressedExistenceProof.typeUrl || (o.key instanceof Uint8Array || typeof o.key === "string") && (o.value instanceof Uint8Array || typeof o.value === "string") && Array.isArray(o.path) && (!o.path.length || typeof o.path[0] === "number")); }, isAmino(o) { return o && (o.$typeUrl === CompressedExistenceProof.typeUrl || (o.key instanceof Uint8Array || typeof o.key === "string") && (o.value instanceof Uint8Array || typeof o.value === "string") && Array.isArray(o.path) && (!o.path.length || typeof o.path[0] === "number")); }, encode(message, writer = BinaryWriter.create()) { if (message.key.length !== 0) { writer.uint32(10).bytes(message.key); } if (message.value.length !== 0) { writer.uint32(18).bytes(message.value); } if (message.leaf !== undefined) { LeafOp.encode(message.leaf, writer.uint32(26).fork()).ldelim(); } writer.uint32(34).fork(); for (const v of message.path) { writer.int32(v); } writer.ldelim(); return writer; }, decode(input, length) { const reader = input instanceof BinaryReader ? input : new BinaryReader(input); let end = length === undefined ? reader.len : reader.pos + length; const message = createBaseCompressedExistenceProof(); while (reader.pos < end) { const tag = reader.uint32(); switch (tag >>> 3) { case 1: message.key = reader.bytes(); break; case 2: message.value = reader.bytes(); break; case 3: message.leaf = LeafOp.decode(reader, reader.uint32()); break; case 4: if ((tag & 7) === 2) { const end2 = reader.uint32() + reader.pos; while (reader.pos < end2) { message.path.push(reader.int32()); } } else { message.path.push(reader.int32()); } break; default: reader.skipType(tag & 7); break; } } return message; }, fromPartial(object) { const message = createBaseCompressedExistenceProof(); message.key = object.key ?? new Uint8Array(); message.value = object.value ?? new Uint8Array(); message.leaf = object.leaf !== undefined && object.leaf !== null ? LeafOp.fromPartial(object.leaf) : undefined; message.path = object.path?.map(e => e) || []; return message; }, fromAmino(object) { const message = createBaseCompressedExistenceProof(); if (object.key !== undefined && object.key !== null) { message.key = bytesFromBase64(object.key); } if (object.value !== undefined && object.value !== null) { message.value = bytesFromBase64(object.value); } if (object.leaf !== undefined && object.leaf !== null) { message.leaf = LeafOp.fromAmino(object.leaf); } message.path = object.path?.map(e => e) || []; return message; }, toAmino(message) { const obj = {}; obj.key = message.key ? base64FromBytes(message.key) : undefined; obj.value = message.value ? base64FromBytes(message.value) : undefined; obj.leaf = message.leaf ? LeafOp.toAmino(message.leaf) : undefined; if (message.path) { obj.path = message.path.map(e => e); } else { obj.path = message.path; } return obj; }, fromAminoMsg(object) { return CompressedExistenceProof.fromAmino(object.value); }, toAminoMsg(message) { return { type: "cosmos-sdk/CompressedExistenceProof", value: CompressedExistenceProof.toAmino(message) }; }, fromProtoMsg(message) { return CompressedExistenceProof.decode(message.value); }, toProto(message) { return CompressedExistenceProof.encode(message).finish(); }, toProtoMsg(message) { return { typeUrl: "/cosmos.ics23.v1.CompressedExistenceProof", value: CompressedExistenceProof.encode(message).finish() }; } }; GlobalDecoderRegistry.register(CompressedExistenceProof.typeUrl, CompressedExistenceProof); GlobalDecoderRegistry.registerAminoProtoMapping(CompressedExistenceProof.aminoType, CompressedExistenceProof.typeUrl); function createBaseCompressedNonExistenceProof() { return { key: new Uint8Array(), left: undefined, right: undefined }; } export const CompressedNonExistenceProof = { typeUrl: "/cosmos.ics23.v1.CompressedNonExistenceProof", aminoType: "cosmos-sdk/CompressedNonExistenceProof", is(o) { return o && (o.$typeUrl === CompressedNonExistenceProof.typeUrl || o.key instanceof Uint8Array || typeof o.key === "string"); }, isSDK(o) { return o && (o.$typeUrl === CompressedNonExistenceProof.typeUrl || o.key instanceof Uint8Array || typeof o.key === "string"); }, isAmino(o) { return o && (o.$typeUrl === CompressedNonExistenceProof.typeUrl || o.key instanceof Uint8Array || typeof o.key === "string"); }, encode(message, writer = BinaryWriter.create()) { if (message.key.length !== 0) { writer.uint32(10).bytes(message.key); } if (message.left !== undefined) { CompressedExistenceProof.encode(message.left, writer.uint32(18).fork()).ldelim(); } if (message.right !== undefined) { CompressedExistenceProof.encode(message.right, writer.uint32(26).fork()).ldelim(); } return writer; }, decode(input, length) { const reader = input instanceof BinaryReader ? input : new BinaryReader(input); let end = length === undefined ? reader.len : reader.pos + length; const message = createBaseCompressedNonExistenceProof(); while (reader.pos < end) { const tag = reader.uint32(); switch (tag >>> 3) { case 1: message.key = reader.bytes(); break; case 2: message.left = CompressedExistenceProof.decode(reader, reader.uint32()); break; case 3: message.right = CompressedExistenceProof.decode(reader, reader.uint32()); break; default: reader.skipType(tag & 7); break; } } return message; }, fromPartial(object) { const message = createBaseCompressedNonExistenceProof(); message.key = object.key ?? new Uint8Array(); message.left = object.left !== undefined && object.left !== null ? CompressedExistenceProof.fromPartial(object.left) : undefined; message.right = object.right !== undefined && object.right !== null ? CompressedExistenceProof.fromPartial(object.right) : undefined; return message; }, fromAmino(object) { const message = createBaseCompressedNonExistenceProof(); if (object.key !== undefined && object.key !== null) { message.key = bytesFromBase64(object.key); } if (object.left !== undefined && object.left !== null) { message.left = CompressedExistenceProof.fromAmino(object.left); } if (object.right !== undefined && object.right !== null) { message.right = CompressedExistenceProof.fromAmino(object.right); } return message; }, toAmino(message) { const obj = {}; obj.key = message.key ? base64FromBytes(message.key) : undefined; obj.left = message.left ? CompressedExistenceProof.toAmino(message.left) : undefined; obj.right = message.right ? CompressedExistenceProof.toAmino(message.right) : undefined; return obj; }, fromAminoMsg(object) { return CompressedNonExistenceProof.fromAmino(object.value); }, toAminoMsg(message) { return { type: "cosmos-sdk/CompressedNonExistenceProof", value: CompressedNonExistenceProof.toAmino(message) }; }, fromProtoMsg(message) { return CompressedNonExistenceProof.decode(message.value); }, toProto(message) { return CompressedNonExistenceProof.encode(message).finish(); }, toProtoMsg(message) { return { typeUrl: "/cosmos.ics23.v1.CompressedNonExistenceProof", value: CompressedNonExistenceProof.encode(message).finish() }; } }; GlobalDecoderRegistry.register(CompressedNonExistenceProof.typeUrl, CompressedNonExistenceProof); GlobalDecoderRegistry.registerAminoProtoMapping(CompressedNonExistenceProof.aminoType, CompressedNonExistenceProof.typeUrl);