serialize-data-formats
关于
This skill helps developers serialize and deserialize data across multiple formats like JSON, XML, YAML, Protobuf, MessagePack, and Arrow/Parquet. It provides guidance on selecting the right format, implementing encode/decode patterns, and understanding performance tradeoffs and interoperability. Use it to choose wire formats for APIs, persist data, exchange between languages, or optimize for size and speed.
快速安装
Claude Code
推荐npx skills add pjt222/agent-almanac -a claude-code/plugin add https://github.com/pjt222/agent-almanacgit clone https://github.com/pjt222/agent-almanac.git ~/.claude/skills/serialize-data-formats在 Claude Code 中复制并粘贴此命令以安装该技能
技能文档
Serialize Data Formats
Select+impl right serialization format → correct encode/decode + perf awareness.
Use When
- Wire format for API
- Persist structured data → disk|object storage
- Exchange between langs
- Optimize size|speed
- Migrate formats
In
- Required: Data structure (schema|example)
- Required: Use case (API|storage|stream|analytics)
- Optional: Perf reqs (size|speed|schema enforce)
- Optional: Target lang|runtime constraints
- Optional: Human readability
Do
Step 1: Select Format
| Format | Human Readable | Schema | Size | Speed | Best For |
|---|---|---|---|---|---|
| JSON | Yes | Optional (JSON Schema) | Medium | Medium | REST APIs, config, broad interop |
| XML | Yes | XSD, DTD | Large | Slow | Enterprise/legacy, SOAP, documents |
| YAML | Yes | Optional | Medium | Slow | Config files, CI/CD, Kubernetes |
| Protocol Buffers | No | Required (.proto) | Small | Fast | gRPC, microservices, mobile |
| MessagePack | No | None | Small | Fast | Real-time, embedded, Redis |
| Arrow/Parquet | No | Built-in | Very Small | Very Fast | Analytics, columnar queries, data lakes |
Decision tree:
- Human edit? → YAML (config) | JSON (data)
- Strict schema + fast RPC? → Protobuf
- Smallest wire? → MessagePack | Protobuf
- Columnar analytics? → Parquet
- In-memory interchange? → Arrow
- Legacy enterprise? → XML
→ Format selected w/ documented rationale.
If err: reqs conflict (human + fast) → prioritize primary use case + note tradeoff.
Step 2: JSON Serialize
import json
from datetime import datetime, date
from dataclasses import dataclass, asdict
@dataclass
class Measurement:
sensor_id: str
value: float
unit: str
timestamp: datetime
# Custom encoder for non-standard types
class CustomEncoder(json.JSONEncoder):
def default(self, obj):
if isinstance(obj, datetime):
return obj.isoformat()
if isinstance(obj, date):
return obj.isoformat()
if isinstance(obj, bytes):
import base64
return base64.b64encode(obj).decode('ascii')
return super().default(obj)
# Serialize
measurement = Measurement("sensor-01", 23.5, "celsius", datetime.now())
json_str = json.dumps(asdict(measurement), cls=CustomEncoder, indent=2)
# Deserialize
data = json.loads(json_str)
# R: JSON with jsonlite
library(jsonlite)
# Serialize
df <- data.frame(sensor_id = "sensor-01", value = 23.5, unit = "celsius")
json_str <- jsonlite::toJSON(df, auto_unbox = TRUE, pretty = TRUE)
# Deserialize
df_back <- jsonlite::fromJSON(json_str)
→ Round-trip preserves all types accurately.
If err: type lost (dates → strings) → add explicit conversion in deserialize.
Step 3: Protobuf
.proto:
syntax = "proto3";
package sensors;
message Measurement {
string sensor_id = 1;
double value = 2;
string unit = 3;
int64 timestamp_ms = 4; // Unix milliseconds
}
message MeasurementBatch {
repeated Measurement measurements = 1;
}
Gen+use:
# Generate Python code
protoc --python_out=. sensors.proto
# Generate Go code
protoc --go_out=. sensors.proto
from sensors_pb2 import Measurement, MeasurementBatch
import time
# Serialize
m = Measurement(
sensor_id="sensor-01",
value=23.5,
unit="celsius",
timestamp_ms=int(time.time() * 1000)
)
binary = m.SerializeToString() # Compact binary
# Deserialize
m2 = Measurement()
m2.ParseFromString(binary)
→ Binary 3-10x smaller than JSON.
If err: protoc unavail → lang-native lib (betterproto Py).
Step 4: MessagePack
import msgpack
from datetime import datetime
# Custom packing for datetime
def encode_datetime(obj):
if isinstance(obj, datetime):
return {"__datetime__": True, "s": obj.isoformat()}
return obj
def decode_datetime(obj):
if "__datetime__" in obj:
return datetime.fromisoformat(obj["s"])
return obj
data = {"sensor_id": "sensor-01", "value": 23.5, "ts": datetime.now()}
# Serialize (smaller than JSON, faster than JSON)
packed = msgpack.packb(data, default=encode_datetime)
# Deserialize
unpacked = msgpack.unpackb(packed, object_hook=decode_datetime, raw=False)
→ Output 15-30% smaller than JSON for typical payloads.
If err: lang lacks MessagePack → fallback JSON+gzip.
Step 5: Parquet (Columnar)
import pyarrow as pa
import pyarrow.parquet as pq
import pandas as pd
# Create data
df = pd.DataFrame({
"sensor_id": ["s-01", "s-02", "s-01", "s-03"] * 1000,
"value": [23.5, 18.2, 24.1, 19.8] * 1000,
"unit": ["celsius"] * 4000,
"timestamp": pd.date_range("2025-01-01", periods=4000, freq="min")
})
# Write Parquet (columnar, compressed)
table = pa.Table.from_pandas(df)
pq.write_table(table, "measurements.parquet", compression="snappy")
# Read Parquet (can read specific columns without loading all data)
table_back = pq.read_table("measurements.parquet", columns=["sensor_id", "value"])
df_subset = table_back.to_pandas()
# R: Parquet with arrow
library(arrow)
# Write
df <- data.frame(sensor_id = rep("s-01", 1000), value = rnorm(1000))
arrow::write_parquet(df, "measurements.parquet")
# Read (with column selection — only reads selected columns from disk)
df_back <- arrow::read_parquet("measurements.parquet", col_select = c("value"))
→ Parquet 5-20x smaller than CSV for tabular.
If err: Arrow unavail → fastparquet (Py)|CSV+gzip fallback.
Step 6: Compare Perf
import json, msgpack, time
import pyarrow as pa, pyarrow.parquet as pq
data = [{"id": i, "value": i * 0.1, "label": f"item-{i}"} for i in range(10000)]
# JSON
start = time.perf_counter()
json_bytes = json.dumps(data).encode()
json_time = time.perf_counter() - start
# MessagePack
start = time.perf_counter()
msgpack_bytes = msgpack.packb(data)
msgpack_time = time.perf_counter() - start
print(f"JSON: {len(json_bytes):>8} bytes, {json_time*1000:.1f} ms")
print(f"MsgPack: {len(msgpack_bytes):>8} bytes, {msgpack_time*1000:.1f} ms")
→ Benchmarks guide format for prod.
If err: insufficient perf any format → consider compression (zstd, snappy) as orthogonal optimization.
Check
- Format matches use case (rationale documented)
- Round-trip preserves all types
- Edge cases: empty, null, Unicode, large nums
- Perf benchmarked for representative sizes
- Err handling for malformed (graceful fail)
- Schema documented (JSON Schema|.proto|equiv)
Traps
- Float precision: JSON = IEEE 754 doubles. String encoding for financial.
- Date/time: No native JSON datetime. Always document format (ISO 8601) + timezone.
- Schema evolution: Add|remove fields can break consumers. Protobuf good; JSON needs careful versioning.
- Binary in JSON: Base64 inflates ~33%. Binary format for binary-heavy.
- YAML security: Parsers may exec arbitrary code via
!!python/objecttags. Always safe loaders.
→
design-serialization-schema— schema design, versioning, evolutionimplement-pharma-serialisation— pharma serialisation (diff domain, same naming)create-quarto-report— data output for reports
GitHub 仓库
相关推荐技能
qmd
开发这是一个本地搜索和索引的CLI工具,支持BM25、向量搜索和重排序功能。开发者可以用它快速索引本地文件(如Markdown文档)并进行混合搜索,特别适合代码库或文档的本地检索。它还提供MCP模式,能轻松集成到Claude开发环境中使用。
subagent-driven-development
开发该Skill用于在当前会话中执行包含独立任务的实施计划,它会为每个任务分派一个全新的子代理并在任务间进行代码审查。这种"全新子代理+任务间审查"的模式既能保障代码质量,又能实现快速迭代。适合需要在当前会话中连续执行独立任务,并希望在每个任务后都有质量把关的开发场景。
mcporter
开发mcporter Skill 让开发者能在Claude中直接管理和调用MCP服务器。它支持列出可用服务器、调用工具、处理OAuth认证以及管理服务器守护进程。开发者可以通过命令行式交互快速执行`mcporter list`查看服务器,或使用`mcporter call`直接调用工具,简化了MCP工作流程。
adk-deployment-specialist
开发这是一个用于部署和编排Google Vertex AI ADK智能体的Claude Skill,专为构建生产级多智能体系统而设计。它支持通过A2A协议进行智能体通信,提供代码执行沙箱和记忆库功能,并能处理智能体发现与任务提交。当开发者需要部署ADK智能体或编排多智能体协作时,可使用此Skill来简化Vertex AI Agent Engine的部署流程。