بنقرة واحدة
flash
runpod-flash SDK and CLI for deploying AI workloads on Runpod serverless GPUs/CPUs.
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القائمة
runpod-flash SDK and CLI for deploying AI workloads on Runpod serverless GPUs/CPUs.
التثبيت باستخدام Codex أو Claude انسخ هذا Prompt والصقه في Codex أو Claude أو مساعد آخر ليراجع صفحة Skill ويثبّتها لك.
استنادا إلى تصنيف SOC المهني
Create and configure NodeTool agent YAML configs, set up agent tools, system prompts, planning agents, and workspace isolation. Use when user asks to create an agent config, write YAML for an agent, configure agent tools, set up autonomous execution, or work with the agent CLI.
Use NodeTool REST API, WebSocket protocol, Chat API (OpenAI-compatible), workflow execution endpoints, and streaming responses. Use when user asks about API endpoints, WebSocket protocol, how to call the API, build a client, integrate with NodeTool, or stream workflow results.
Create browser automation agents that navigate websites, extract data, fill forms, and perform multi-step web tasks using natural language instructions. Use when user asks to automate browsing, scrape websites with AI, build a web agent, or perform complex browser interactions.
Use NodeTool chat CLI commands, interactive terminal, agent mode, workspace management, and Global Chat features. Use when user asks about chat commands, interactive terminal, chat features, agent mode in chat, or the Global Chat interface.
Create custom NodeTool nodes, implement BaseNode subclasses, use @prop decorators, build node packages with process/genProcess methods, register nodes, handle media refs and secrets. Use when user asks to create a node, add a node type, build a custom node, implement a processor, or extend NodeTool with new functionality.
Deploy NodeTool servers using Docker, SSH, RunPod, GCP, or Supabase. Use when user asks to deploy, host, set up a server, configure Docker, use RunPod/GCP/Supabase, manage deployment.yaml, or configure environment variables for production.
| name | flash |
| description | runpod-flash SDK and CLI for deploying AI workloads on Runpod serverless GPUs/CPUs. |
| user-invocable | true |
Write code locally, test with flash run (dev server at localhost:8888), and flash automatically provisions and deploys to remote GPUs/CPUs in the cloud. Endpoint handles everything.
pip install runpod-flash # requires Python >=3.10
# auth option 1: browser-based login (saves token locally)
flash login
# auth option 2: API key via environment variable
export RUNPOD_API_KEY=your_key
flash init my-project # scaffold a new project in ./my-project
flash run # start local dev server at localhost:8888
flash run --auto-provision # same, but pre-provision endpoints (no cold start)
flash build # package artifact for deployment (500MB limit)
flash build --exclude pkg1,pkg2 # exclude packages from build
flash deploy # build + deploy (auto-selects env if only one)
flash deploy --env staging # build + deploy to "staging" environment
flash deploy --app my-app --env prod # deploy a specific app to an environment
flash deploy --preview # build + launch local preview in Docker
flash env list # list deployment environments
flash env create staging # create "staging" environment
flash env get staging # show environment details + resources
flash env delete staging # delete environment + tear down resources
flash undeploy list # list all active endpoints
flash undeploy my-endpoint # remove a specific endpoint
One function = one endpoint with its own workers.
from runpod_flash import Endpoint, GpuGroup
@Endpoint(name="my-worker", gpu=GpuGroup.AMPERE_80, workers=5, dependencies=["torch"])
async def compute(data):
import torch # MUST import inside function (cloudpickle)
return {"sum": torch.tensor(data, device="cuda").sum().item()}
result = await compute([1, 2, 3])
Multiple HTTP routes share one pool of workers.
from runpod_flash import Endpoint, GpuGroup
api = Endpoint(name="my-api", gpu=GpuGroup.ADA_24, workers=(1, 5), dependencies=["torch"])
@api.post("/predict")
async def predict(data: list[float]):
import torch
return {"result": torch.tensor(data, device="cuda").sum().item()}
@api.get("/health")
async def health():
return {"status": "ok"}
Deploy a pre-built Docker image and call it via HTTP.
from runpod_flash import Endpoint, GpuGroup, PodTemplate
server = Endpoint(
name="my-server",
image="my-org/my-image:latest",
gpu=GpuGroup.AMPERE_80,
workers=1,
env={"HF_TOKEN": "xxx"},
template=PodTemplate(containerDiskInGb=100),
)
# LB-style
result = await server.post("/v1/completions", {"prompt": "hello"})
models = await server.get("/v1/models")
# QB-style
job = await server.run({"prompt": "hello"})
await job.wait()
print(job.output)
Connect to an existing endpoint by ID (no provisioning):
ep = Endpoint(id="abc123")
job = await ep.runsync({"input": "hello"})
print(job.output)
| Parameters | Mode |
|---|---|
name= only | Decorator (your code) |
image= set | Client (deploys image, then HTTP calls) |
id= set | Client (connects to existing, no provisioning) |
Endpoint(
name="endpoint-name", # required (unless id= set)
id=None, # connect to existing endpoint
gpu=GpuGroup.AMPERE_80, # single GPU type (default: ANY)
gpu=[GpuGroup.ADA_24, GpuGroup.AMPERE_80], # or list for auto-select by supply
cpu=CpuInstanceType.CPU5C_4_8, # CPU type (mutually exclusive with gpu)
workers=5, # shorthand for (0, 5)
workers=(1, 5), # explicit (min, max)
idle_timeout=60, # seconds before scale-down (default: 60)
dependencies=["torch"], # pip packages for remote exec
system_dependencies=["ffmpeg"], # apt-get packages
image="org/image:tag", # pre-built Docker image (client mode)
env={"KEY": "val"}, # environment variables
volume=NetworkVolume(...), # persistent storage
gpu_count=1, # GPUs per worker
template=PodTemplate(containerDiskInGb=100),
flashboot=True, # fast cold starts
execution_timeout_ms=0, # max execution time (0 = unlimited)
)
gpu= and cpu= are mutually exclusiveworkers=5 means (0, 5). Default is (0, 1)idle_timeout default is 60 secondsflashboot=True (default) -- enables fast cold starts via snapshot restoregpu_count -- GPUs per worker (default 1), use >1 for multi-GPU modelsNetworkVolume(name="my-vol", size=100) # size in GB, default 100
PodTemplate(
containerDiskInGb=64, # container disk size (default 64)
dockerArgs="", # extra docker arguments
ports="", # exposed ports
startScript="", # script to run on start
)
Returned by ep.run() and ep.runsync() in client mode.
job = await ep.run({"data": [1, 2, 3]})
await job.wait(timeout=120) # poll until done
print(job.id, job.output, job.error, job.done)
await job.cancel()
| Enum | GPU | VRAM |
|---|---|---|
ANY | any | varies |
AMPERE_16 | RTX A4000 | 16GB |
AMPERE_24 | RTX A5000/L4 | 24GB |
AMPERE_48 | A40/A6000 | 48GB |
AMPERE_80 | A100 | 80GB |
ADA_24 | RTX 4090 | 24GB |
ADA_32_PRO | RTX 5090 | 32GB |
ADA_48_PRO | RTX 6000 Ada | 48GB |
ADA_80_PRO | H100 PCIe (80GB) / H100 HBM3 (80GB) / H100 NVL (94GB) | 80GB+ |
HOPPER_141 | H200 | 141GB |
| Enum | vCPU | RAM | Max Disk | Type |
|---|---|---|---|---|
CPU3G_1_4 | 1 | 4GB | 10GB | General |
CPU3G_2_8 | 2 | 8GB | 20GB | General |
CPU3G_4_16 | 4 | 16GB | 40GB | General |
CPU3G_8_32 | 8 | 32GB | 80GB | General |
CPU3C_1_2 | 1 | 2GB | 10GB | Compute |
CPU3C_2_4 | 2 | 4GB | 20GB | Compute |
CPU3C_4_8 | 4 | 8GB | 40GB | Compute |
CPU3C_8_16 | 8 | 16GB | 80GB | Compute |
CPU5C_1_2 | 1 | 2GB | 15GB | Compute (5th gen) |
CPU5C_2_4 | 2 | 4GB | 30GB | Compute (5th gen) |
CPU5C_4_8 | 4 | 8GB | 60GB | Compute (5th gen) |
CPU5C_8_16 | 8 | 16GB | 120GB | Compute (5th gen) |
from runpod_flash import Endpoint, CpuInstanceType
@Endpoint(name="cpu-work", cpu=CpuInstanceType.CPU5C_4_8, workers=5, dependencies=["pandas"])
async def process(data):
import pandas as pd
return pd.DataFrame(data).describe().to_dict()
from runpod_flash import Endpoint, GpuGroup, CpuInstanceType
@Endpoint(name="preprocess", cpu=CpuInstanceType.CPU5C_4_8, workers=5, dependencies=["pandas"])
async def preprocess(raw):
import pandas as pd
return pd.DataFrame(raw).to_dict("records")
@Endpoint(name="infer", gpu=GpuGroup.AMPERE_80, workers=5, dependencies=["torch"])
async def infer(clean):
import torch
t = torch.tensor([[v for v in r.values()] for r in clean], device="cuda")
return {"predictions": t.mean(dim=1).tolist()}
async def pipeline(data):
return await infer(await preprocess(data))
import asyncio
results = await asyncio.gather(compute(a), compute(b), compute(c))
await.dependencies=[].image=/id= = client. Otherwise = decorator.gpu=[GpuGroup.ADA_24, GpuGroup.AMPERE_80]) and set workers=5 or higher. The platform only auto-switches GPU types based on supply when max workers is at least 5.runsync timeout is 60s -- cold starts can exceed 60s. Use ep.runsync(data, timeout=120) for first requests or use ep.run() + job.wait() instead.