Concepts

πŸ—οΈ Architecture & Performance

View as Markdown

Data Designer is an orchestration framework that coordinates synthetic data generation workflows. It is a client of LLM inference serversβ€”it does not host models itself.

This guide explains the architecture, execution model, and how to tune performance for your specific use case.

Separation of Concerns

β”Œβ”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”          β”Œβ”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”
β”‚         Data Designer               β”‚          β”‚       Inference Server(s)           β”‚
β”‚         (Orchestration)             β”‚  HTTP    β”‚       (LLM Hosting)                 β”‚
β”‚                                     β”‚  ─────►  β”‚                                     β”‚
β”‚  β€’ Dataset workflow management      β”‚          β”‚  β€’ Model weights and execution      β”‚
β”‚  β€’ Column dependency resolution     β”‚          β”‚  β€’ GPU allocation and scheduling    β”‚
β”‚  β€’ Batching and parallelism         β”‚          β”‚  β€’ Request queuing                  β”‚
β”‚  β€’ Retry and error handling         β”‚          β”‚  β€’ Token generation                 β”‚
β”‚  β€’ Adaptive concurrency (AIMD)      β”‚          β”‚  β€’ Rate limiting (optional)         β”‚
β”‚  β€’ Data validation and quality      β”‚          β”‚                                     β”‚
β””β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”˜          β””β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”€β”˜
              β–²                                                    β–²
              β”‚                                                    β”‚
        Your workflow                                    Your infrastructure
         configuration                                    (or cloud API)

What Data Designer Does

  • Orchestrates the generation workflow across multiple columns
  • Resolves dependencies between columns (DAG-based execution)
  • Batches work into manageable chunks (buffer_size)
  • Parallelizes LLM calls within batches (max_parallel_requests)
  • Adapts to rate limits automatically via AIMD concurrency control
  • Handles errors with retries and early shutdown logic
  • Validates generated data against schemas and constraints

What Data Designer Does NOT Do

  • Host models: You must provide LLM endpoints
  • Manage GPUs: Your inference server handles GPU allocation
  • Scale inference: You must provision sufficient capacity
  • Impose rate limits: Your server or API gateway sets rate limits (Data Designer reacts to them automatically)

Execution Model

Two execution engines

The default execution path is the async engine, which dispatches work at the cell level and overlaps independent columns β€” see Async Engine below for its semantics. The legacy sync engine is still available for one transitional release via DATA_DESIGNER_ASYNC_ENGINE=0 and is what this section describes. The configuration knobs documented below (buffer_size, max_parallel_requests, AIMD throttle config, error handling) apply to both engines; the differences are flagged inline.

The sync engine processes datasets in batches, with parallel operations within each batch.

How It Works (sync engine)

Step 1: Split into batches

Your dataset is divided into batches of buffer_size records. Each batch is processed completely before moving to the next.

Step 2: Process columns sequentially

Within a batch, columns are generated one at a time following the dependency graph. The order depends on column dependenciesβ€”expression columns may come before LLM columns if the LLM columns depend on them. (The async engine relaxes this: columns whose per-cell dependencies are satisfied can run concurrently with columns earlier in the order.)

Example workflow:

Batch 1 (100 records)
β”‚
β”œβ”€β–Ί Column 1: category (Sampler)      ──── All 100 values generated
β”œβ”€β–Ί Column 2: prompt (LLM Text)       ──── All 100 values generated
β”œβ”€β–Ί Column 3: response (LLM Text)     ──── All 100 values generated
β”œβ”€β–Ί Column 4: score (Expression)      ──── All 100 values computed
β”‚
└─► Write batch to disk
    β”‚
    β–Ό
Batch 2 (100 records)
    ...repeat...

Step 3: Generate cells in parallel

Within each column, cells are processed in parallel up to the configured limit:

Column TypeParallelism Control
Samplernon_inference_max_parallel_workers
LLM (Text, Code, Structured, Judge)max_parallel_requests
ExpressionSequential (fast, CPU-bound)

Key Concepts

ConceptDescription
BatchingRecords are split into batches of buffer_size. In the sync engine, each batch completes entirely before the next begins; in the async engine, multiple row groups (the async equivalent) can be in flight concurrently.
Sequential columnsSync-engine only: columns within a batch are generated one at a time, respecting the dependency graph. The async engine schedules at the cell level instead.
Parallel cellsWithin a column, individual cells (records) are generated in parallel up to the configured limit. Same on both engines.

Concurrency Formula

At any moment, the number of concurrent LLM requests is:

1concurrent_requests = min(
2    buffer_size,                # Records in current batch
3    current_throttle_limit,     # AIMD-managed limit (≀ max_parallel_requests)
4    remaining_cells_in_column   # Cells left to generate
5)

max_parallel_requests sets the ceiling. The actual limit (current_throttle_limit) is managed at runtime by an AIMD (Additive Increase / Multiplicative Decrease) controller that reacts to rate-limit signals from the inference server:

  • During optional startup ramp: when rampup_seconds is greater than 0, a new throttle domain starts at one concurrent request and increases linearly toward max_parallel_requests over that duration.
  • On the first 429 in a burst: the limit is reduced by a configurable factor (default: 25% reduction) and a cooldown is applied. Further 429s from already in-flight requests in the same burst do not reduce the limit again β€” they release their permits and hold the limit steady.
  • After consecutive successes: the limit increases by 1 (by default) until it reaches the ceiling or a stabilized rate-limit threshold.

This means Data Designer automatically finds the right concurrency level for your server without manual tuning.

Engine paths

AIMD adaptive concurrency is fully active on the default async engine. The legacy sync engine is available for one transitional release via DATA_DESIGNER_ASYNC_ENGINE=0; on that path 429s are first retried at the HTTP transport layer and AIMD only engages as a fallback. See Async engine below.

Example: With buffer_size=100 and max_parallel_requests=32, Data Designer can send up to 32 requests in parallel. If rampup_seconds=30, it starts at one request and climbs linearly toward 32 over 30 seconds. If the server returns 429s, startup ramp stops, concurrency drops automatically (e.g., to 24, then 18), and normal AIMD recovery takes over once the server catches up.

Configuration Parameters

buffer_size (RunConfig)

Controls how many records are processed per batch.

1import data_designer.config as dd
2from data_designer.interface import DataDesigner
3
4run_config = dd.RunConfig(buffer_size=2000)
5
6designer = DataDesigner()
7designer.set_run_config(run_config)
ValueMemory UsageThroughputError Feedback
Low (100-500)LowerMay not saturate inferenceFast
Default (1000)ModerateGood for most casesModerate
High (2000-5000)HigherBetter for deep pipelinesSlower

When to increase: High-capacity inference server, single-model workflows, memory not constrained

When to decrease: Memory-constrained environments, development/debugging, complex multi-model pipelines

Resuming Interrupted Runs

Long generation jobs can be resumed from checkpoints by passing resume to DataDesigner.create() or data-designer create --resume.

1from data_designer.interface import DataDesigner, ResumeMode
2
3designer = DataDesigner()
4results = designer.create(
5    config_builder,
6    num_records=10_000,
7    dataset_name="training_data",
8    resume=ResumeMode.IF_POSSIBLE,
9)

Resume modes:

  • ResumeMode.NEVER (default): always start a fresh generation run. If the dataset directory already exists, Data Designer writes to a timestamped directory.
  • ResumeMode.ALWAYS: resume the existing dataset directory. Raises if the checkpoint is incompatible or cannot be resumed safely.
  • ResumeMode.IF_POSSIBLE: resume when the stored config fingerprint matches the current config; otherwise start a fresh timestamped run.

Data Designer stores the run configuration in metadata.json (buffer_size, target_num_records, config fingerprint) and builder_config.json. Both engines recover progress the same way: they scan completed batch_*.parquet row groups and read parquet metadata for the row count actually persisted. That keeps resume crash-safe even if a run was interrupted between writing a batch parquet and updating metadata, because the filesystem reflects the durable state even when metadata lags by a step.

Resume has a few important invariants:

  • buffer_size must match the original run.
  • num_records must be at least the original target; you may extend a run by requesting more records.
  • Runs with allow_resize=True columns are not resumable because row boundaries can change.
  • Once process_after_generation() has run, the dataset is considered terminal for resume. Re-running with the same target returns the existing dataset; extending requires a fresh run.
  • If a run crashed after every row group was written but before process_after_generation() could start, resume runs after-generation on the existing on-disk dataset (the parquet files are still clean) and marks it terminal afterwards. A crash during process_after_generation() still raises β€” the parquet files may have been partially rewritten and starting fresh is the only safe option.

The DatasetCreationResults returned by a resume invocation reflects the full dataset on disk for anything that reads the artifact directory (load_dataset, count_records, load_analysis, export, push_to_hub). Per-run observability β€” task_traces, model-usage logs, and telemetry events emitted during the call β€” is scoped to the resume invocation only; the original run’s in-memory traces are not persisted across process boundaries.

Only resume datasets from trusted artifact directories. Resume reads local metadata.json, builder_config.json, and parquet files to determine checkpoint state.

max_parallel_requests (InferenceParams)

Sets the maximum concurrent LLM API calls per model. This is the ceiling that the AIMD throttle controller can ramp up to β€” the actual concurrency at runtime may be lower if the server signals rate limits.

1import data_designer.config as dd
2
3model = dd.ModelConfig(
4    alias="my-model",
5    model="nvidia/nemotron-3-nano-30b-a3b",
6    provider="nvidia",
7    inference_parameters=dd.ChatCompletionInferenceParams(
8        max_parallel_requests=8,
9    ),
10)

Default: 4

When to increase: Your inference backend has high throughput capacity, you’re using a cloud API with generous rate limits, or you’re running vLLM/TensorRT-LLM with multiple GPUs. With AIMD, setting an aggressively high value is safer than before β€” the system will self-correct downward if the server can’t keep up. The salvage queue on the async engine (default) reclaims failed rows; on the sync engine the initial burst of 429s before AIMD stabilizes can drop rows, so start with a more conservative ceiling if you’ve opted into sync.

When to decrease: You want to cap resource usage to a known safe level, or you want more predictable/debuggable execution.

Finding the optimal value The right value depends on your inference stack and model. Self-hosted vLLM servers can often handle values as high as 256, 512, or even 1024 depending on your hardware.

With AIMD, a practical approach is to set max_parallel_requests to the upper bound you’re comfortable with and let the throttle controller find the sustainable level automatically. If you see frequent 429 β†’ recovery cycles in the logs, your ceiling is above the server’s true capacity but the system is handling it. If you never see any throttle activity, you may have room to increase the ceiling further.

Benchmark approach: Run a small dataset (e.g., 100 records) with increasing max_parallel_requests values (4 β†’ 8 β†’ 16 β†’ 32 β†’ …) and measure generation time. Stop increasing when the runtime stops decreasingβ€”that’s when your inference server is saturated.

non_inference_max_parallel_workers (RunConfig)

Controls thread pool size for non-LLM operations (samplers, expressions, validators).

1run_config = dd.RunConfig(non_inference_max_parallel_workers=8)
2designer.set_run_config(run_config)

Default: 4

When to increase: Many CPU-bound columns (complex expressions, heavy sampling)

Adaptive Throttling (RunConfig)

Data Designer uses an AIMD (Additive Increase / Multiplicative Decrease) controller to automatically adjust concurrency per model based on rate-limit feedback from the inference server. The defaults work well for most workloads. Override them via ThrottleConfig only when you understand the trade-offs.

Engine paths

Adaptive throttling is fully active on the default async engine, where 429 responses propagate directly to the AIMD controller. On the legacy sync engine (DATA_DESIGNER_ASYNC_ENGINE=0), 429s are first retried at the HTTP transport layer; ThrottleConfig settings only take effect as a fallback if transport retries are exhausted.

1import data_designer.config as dd
2from data_designer.interface import DataDesigner
3
4run_config = dd.RunConfig(
5    throttle=dd.ThrottleConfig(
6        reduce_factor=0.75,       # Multiply limit by this on a 429 (default: 0.75)
7        additive_increase=1,      # Add this many slots after success_window successes (default: 1)
8        success_window=25,        # Consecutive successes before increasing (default: 25)
9        cooldown_seconds=2.0,     # Pause after a 429 when no Retry-After header (default: 2.0)
10        ceiling_overshoot=0.10,   # Probe 10% above observed server limit (default: 0.10)
11        rampup_seconds=0.0,       # Optional startup ramp duration; 0 disables it (default: 0.0)
12    ),
13)
14
15designer = DataDesigner()
16designer.set_run_config(run_config)
ParameterDefaultEffect
reduce_factor0.75How aggressively to cut concurrency on a 429. Lower = more aggressive.
additive_increase1Slots added per recovery step. Higher = faster ramp-up, but riskier.
success_window25Consecutive successes required before each increase step.
cooldown_seconds2.0Pause duration after a 429 (used when the server doesn’t send Retry-After).
ceiling_overshoot0.10Fraction above the observed rate-limit ceiling the controller is allowed to probe.
rampup_seconds0.0Optional startup ramp duration. When greater than 0, domains start at one concurrent request and linearly climb to the configured ceiling unless a 429 aborts the ramp.

How it works in practice When a model endpoint returns HTTP 429, the controller reduces the concurrency limit for that model and pauses briefly. After enough consecutive successes, it begins ramping back up. If the server rate-limits again, the controller records that level as a ceiling and stabilizes just below it, with a small overshoot band to detect when the server can handle more load.

You can observe this in the logs β€” look for messages like concurrency reduced from X β†’ Y and concurrency increased from X β†’ Y.

Error Handling (RunConfig)

Control retry behavior and early shutdown for failed generations.

1run_config = dd.RunConfig(
2    max_conversation_restarts=5,           # Full conversation restarts (default: 5)
3    max_conversation_correction_steps=0,   # In-conversation corrections (default: 0)
4    disable_early_shutdown=False,          # Enable early shutdown (default)
5    shutdown_error_rate=0.5,               # Shut down if >50% errors
6    shutdown_error_window=10,              # Min tasks before error monitoring
7)
8designer.set_run_config(run_config)

When to adjust:

  • Strict schemas: Increase max_conversation_restarts to 7, add max_conversation_correction_steps=2
  • Debugging: Set disable_early_shutdown=True to see all errors
  • Simple text: Reduce max_conversation_restarts to 3

Async Engine

The async engine is the default execution path. It dispatches work at the cell level rather than the column level, so independent columns overlap in time and per-(provider, model) AIMD pools tune themselves independently. See the Async All the Way Down dev note for the full architecture.

Per-model timeouts drive every deadline

The inference_parameters.timeout field on a ModelConfig sets the per-request HTTP timeout. The same value also drives the syncβ†’async bridge that custom columns use when they call model.generate(). There is no separate queue-wait deadline β€” waits scale with provider speed and AIMD’s adaptive concurrency. Slow self-hosted endpoints (e.g. large models on a single GPU) only need this one knob raised:

1import data_designer.config as dd
2
3config_builder.add_model_config(
4    dd.ModelConfig(
5        alias="slow-model",
6        model="my/slow-model",
7        provider="my-provider",
8        inference_parameters=dd.ChatCompletionInferenceParams(
9            timeout=600,
10        ),
11    )
12)

Run outcomes

A run can finish with fewer records than requested when non-retryable errors drop rows. Inspect len(result.load_dataset()) to detect.

If the rate of non-retryable errors crosses RunConfig.shutdown_error_rate, generation stops early and raises DataDesignerEarlyShutdownError (a subclass of DataDesignerGenerationError). Catch it separately when a typed retry path is appropriate:

1from data_designer.interface.errors import DataDesignerEarlyShutdownError
2
3try:
4    result = dd_instance.create(config_builder, num_records=1000)
5except DataDesignerEarlyShutdownError:
6    # e.g. retry against a different model alias
7    ...

Opting out

Deprecated

DATA_DESIGNER_ASYNC_ENGINE=0 selects the legacy sync engine. This is a deprecated escape hatch for the transitional release and will be removed in a future version. The opt-out also emits a DeprecationWarning at run time so it shows up in your logs.

$DATA_DESIGNER_ASYNC_ENGINE=0 python my_pipeline.py

Common Problems

ProblemSymptomSolution
Low throughputLow GPU utilizationIncrease max_parallel_requests and/or buffer_size. If the throttle has self-reduced due to earlier 429s (check logs for β€œconcurrency reduced” messages), the server may need more capacity or you can wait for AIMD recovery.
Frequent 429 β†’ recovery cyclesLogs show repeated concurrency drops and ramp-upsThe max_parallel_requests ceiling is above the server’s sustained capacity. This is handled automatically, but you can lower the ceiling to reduce the sawtooth or tune reduce_factor / success_window.
Long tail of slow generationsMost records fast, few very slowReduce max_conversation_restarts, simplify schemas, improve prompts
Multi-model idle periodsOne model busy, others idleReduce buffer_size for faster cycling, or consolidate models
Memory errorsOOM crashesReduce buffer_size and max_parallel_requests
Too many errorsGeneration fails frequentlyCheck prompts/schemas; adjust shutdown_error_rate or disable early shutdown for debugging

Tuning Workflow

  1. Start with defaults for initial development β€” AIMD handles rate-limit adaptation automatically
  2. Profile your workload: How many LLM columns? How many records? What models?
  3. Identify bottleneck: Low GPU util β†’ increase max_parallel_requests (AIMD will self-correct if you overshoot). Memory issues β†’ decrease buffer_size. Long tails β†’ tune retry settings.
  4. Check throttle logs: Look for β€œconcurrency reduced” / β€œconcurrency increased” messages to understand whether rate limits are the bottleneck
  5. Iterate: Make one change at a time, measure impact before next change