| name | parity-testing |
| description | Verify numerical parity between NeMo AutoModel implementations and reference HuggingFace models, including state dict and forward-pass checks. |
| when_to_use | Verifying numerical correctness of a new or modified model against its HuggingFace reference, debugging loss divergence or output mismatches, or validating state dict mappings. |
Parity Testing Skill for NeMo AutoModel
NeMo AutoModel adds custom model implementations (combined projections, backend switching, kernel patches) on top of HuggingFace transformers. Parity testing verifies that NeMo AutoModel's implementation produces numerically equivalent results to the reference HF implementation.
Key differences that can cause divergence:
- Combined QKV projections (interleaved layout) vs separate Q/K/V
- Combined GateUp MLP vs separate gate/up projections
- TE attention vs SDPA vs flex attention backends
- TE linear vs torch linear
- FP8/BF16 precision differences
- RoPE implementation differences
- State dict adapter conversion (from_hf/to_hf round-trip)
- Kernel patches (Liger kernels, etc.)
Setup
Identify the two implementations
from transformers import AutoModelForCausalLM
from nemo.collections.llm import NeMoAutoModelForCausalLM
The HF model is the reference. The NeMo AutoModel is the implementation under test.
nemo_model = NeMoAutoModelForCausalLM.from_pretrained("meta-llama/Llama-3.2-1B")
hf_model = AutoModelForCausalLM.from_pretrained("meta-llama/Llama-3.2-1B")
Create identical inputs
Use seeded random tensors to guarantee reproducibility across runs.
import torch
torch.manual_seed(42)
input_ids = torch.randint(0, 32000, (1, 128))
attention_mask = torch.ones_like(input_ids)
Use CPU + float32 for strictest comparison
GPU introduces non-determinism from parallel reductions and kernel launch order. Always start parity testing on CPU with float32 to isolate numerical differences caused by model implementation from those caused by hardware.
device = torch.device("cpu")
dtype = torch.float32
hf_model = hf_model.to(device=device, dtype=dtype).eval()
nemo_model = nemo_model.to(device=device, dtype=dtype).eval()
Test Strategy (3 Levels)
Level 1: State Dict Round-Trip (CPU/float32)
This is the fastest and most fundamental check. If the state dict adapter cannot perfectly round-trip weights, nothing else will work.
hf_model = AutoModelForCausalLM.from_pretrained(
"meta-llama/Llama-3.2-1B", torch_dtype=torch.float32, device_map="cpu"
)
nemo_model = NeMoAutoModelForCausalLM.from_pretrained(
"meta-llama/Llama-3.2-1B", torch_dtype=torch.float32, device_map="cpu"
)
adapter = nemo_model.state_dict_adapter
hf_sd = hf_model.state_dict()
custom_sd = adapter.from_hf(hf_sd)
roundtrip_sd = adapter.to_hf(custom_sd)
assert set(roundtrip_sd.keys()) == set(hf_sd.keys()), (
f"Key mismatch.\n"
f" Missing from roundtrip: {set(hf_sd.keys()) - set(roundtrip_sd.keys())}\n"
f" Extra in roundtrip: {set(roundtrip_sd.keys()) - set(hf_sd.keys())}"
)
for key in hf_sd:
max_diff = (hf_sd[key] - roundtrip_sd[key]).abs().max().item()
assert max_diff == 0.0, f"Round-trip mismatch for {key}: max_diff={max_diff}"
print("Level 1 PASSED: state dict round-trip is exact.")
What to check:
- All keys present in both dicts (no missing, no extra).
- Every tensor value matches exactly (max_diff == 0.0). Combined projection adapters must perfectly split and recombine weights.
- Tied weight keys (e.g.,
lm_head.weight aliasing model.embed_tokens.weight) are handled correctly.
Level 2: Component Parity (CPU/float32)
Test individual components in isolation to localize any divergence.
Components to test: attention, MLP, layer norm / RMSNorm, RoPE, full decoder layer.
from transformers import AutoConfig
config = AutoConfig.from_pretrained("meta-llama/Llama-3.2-1B")
config.num_hidden_layers = 2
config.hidden_size = 256
config.intermediate_size = 512
config.num_attention_heads = 4
config.num_key_value_heads = 2
hf_model = AutoModelForCausalLM.from_config(config).to(dtype=torch.float32, device="cpu").eval()
nemo_model = NeMoAutoModelForCausalLM.from_config(config).to(dtype=torch.float32, device="cpu").eval()
hf_sd = hf_model.state_dict()
adapter = nemo_model.state_dict_adapter
nemo_model.load_state_dict(adapter.from_hf(hf_sd))
Forward pass with identical seeded inputs:
torch.manual_seed(42)
input_ids = torch.randint(0, config.vocab_size, (1, 64))
attention_mask = torch.ones_like(input_ids)
with torch.no_grad():
hf_out = hf_model(input_ids, attention_mask=attention_mask)
nemo_out = nemo_model(input_ids, attention_mask=attention_mask)
max_diff, mean_diff, cos_sim = compare_tensors(
hf_out.logits, nemo_out.logits, name="component_parity_logits"
)
assert max_diff < 1e-5, f"Component parity FAILED: max_diff={max_diff}"
print("Level 2 PASSED: component parity within tolerance.")
Strict tolerance: max_diff < 1e-5 for float32 on CPU. This is tight enough to catch weight loading bugs while allowing for minor floating-point operation reordering.
Testing individual components (attention example):
hf_attn = hf_model.model.layers[0].self_attn
nemo_attn = nemo_model.model.layers[0].self_attn
torch.manual_seed(42)
hidden_states = torch.randn(1, 64, config.hidden_size)
position_ids = torch.arange(64).unsqueeze(0)
with torch.no_grad():
hf_attn_out = hf_attn(hidden_states, position_ids=position_ids)
nemo_attn_out = nemo_attn(hidden_states, position_ids=position_ids)
compare_tensors(hf_attn_out[0], nemo_attn_out[0], name="attention_output")
Repeat for MLP, norm, and full decoder layer.
Level 3: E2E Forward Pass (GPU/bfloat16)
Full model forward pass on GPU with bfloat16, reflecting realistic deployment conditions.
device = torch.device("cuda")
dtype = torch.bfloat16
hf_model = AutoModelForCausalLM.from_pretrained(
"meta-llama/Llama-3.2-1B", torch_dtype=dtype, device_map=device
).eval()
nemo_model = NeMoAutoModelForCausalLM.from_pretrained(
"meta-llama/Llama-3.2-1B", torch_dtype=dtype, device_map=device
).eval()
torch.manual_seed(42)
input_ids = torch.randint(0, 32000, (1, 128), device=device)
attention_mask = torch.ones_like(input_ids)
with torch.no_grad():
hf_out = hf_model(input_ids, attention_mask=attention_mask)
nemo_out = nemo_model(input_ids, attention_mask=attention_mask)
assert hf_out.logits.shape == nemo_out.logits.shape, (
f"Shape mismatch: {hf_out.logits.shape} vs {nemo_out.logits.shape}"
)
max_diff, mean_diff, cos_sim = compare_tensors(
hf_out.logits, nemo_out.logits, name="e2e_logits"
)
assert max_diff < 1e-2, f"E2E parity FAILED: max_diff={max_diff}"
assert cos_sim > 0.9999, f"E2E parity FAILED: cosine_sim={cos_sim}"
print("Level 3 PASSED: E2E forward pass parity within tolerance.")
Tolerances for bfloat16: max_diff < 1e-2, cosine_similarity > 0.9999. bfloat16 has limited mantissa bits, so per-element differences accumulate across layers.
Comparison Utilities
def compare_tensors(a, b, name=""):
"""Compare two tensors and report multiple similarity metrics.
Args:
a: Reference tensor (from HF model).
b: Test tensor (from NeMo AutoModel).
name: Label for the comparison (printed in output).
Returns:
Tuple of (max_diff, mean_diff, cosine_similarity).
"""
max_diff = (a - b).abs().max().item()
mean_diff = (a - b).abs().mean().item()
cos_sim = torch.nn.functional.cosine_similarity(
a.flatten().float(), b.flatten().float(), dim=0
).item()
print(
f"{name}: max_diff={max_diff:.6e}, mean_diff={mean_diff:.6e}, "
f"cosine_sim={cos_sim:.8f}"
)
return max_diff, mean_diff, cos_sim
def compare_state_dicts(sd_a, sd_b, prefix=""):
"""Compare two state dicts key-by-key, reporting per-parameter differences."""
keys_a = set(sd_a.keys())
keys_b = set(sd_b.keys())
missing = keys_a - keys_b
extra = keys_b - keys_a
if missing:
print(f"{prefix}Missing keys: {missing}")
if extra:
print(f"{prefix}Extra keys: {extra}")
shared = keys_a & keys_b
max_diffs = {}
for key in sorted(shared):
diff = (sd_a[key].float() - sd_b[key].float()).abs().max().item()
if diff > 0:
max_diffs[key] = diff
print(f"{prefix}{key}: max_diff={diff:.6e}")
if not max_diffs and not missing and not extra:
print(f"{prefix}All {len(shared)} parameters match exactly.")
return missing, extra, max_diffs
Debugging Workflow
Follow this procedure when a parity test fails.
Step 1: If E2E fails, isolate to component level
Run Level 2 component tests. Determine which component (attention, MLP, norm, RoPE, decoder layer) introduces the divergence.
Step 2: If component fails, check weight loading
Verify the state dict adapter round-trip (Level 1). If round-trip is not exact, the bug is in the adapter's from_hf() or to_hf() method.
nemo_sd = nemo_model.state_dict()
exported_hf_sd = adapter.to_hf(nemo_sd)
compare_state_dicts(hf_sd, exported_hf_sd, prefix="weight_check: ")
Step 3: If weights match but output differs, check backend
Different backends (TE vs SDPA vs flex attention) can produce different results even with identical weights. Force the baseline backend for parity testing:
from nemo.collections.llm import BackendConfig
nemo_model = NeMoAutoModelForCausalLM.from_pretrained(
"meta-llama/Llama-3.2-1B",
backend_config=BackendConfig(attn="sdpa", linear="torch"),
)
Step 4: Injection technique
Replace one NeMo component's output with the HF component's output and check if downstream computation matches. This isolates exactly which component introduces divergence.
with torch.no_grad():
hf_attn_out = hf_model.model.layers[0].self_attn(hidden_states, position_ids=position_ids)
nemo_layer = nemo_model.model.layers[0]
residual = hidden_states
normed = nemo_layer.input_layernorm(hidden_states)
attn_out = hf_attn_out[0]
hidden_states_after_attn = residual + attn_out
residual = hidden_states_after_attn
normed = nemo_layer.post_attention_layernorm(hidden_states_after_attn)
mlp_out = nemo_layer.mlp(normed)
final = residual + mlp_out
Step 5: Gradient parity
After forward pass parity is confirmed, verify gradients:
hf_model.train()
nemo_model.train()
hf_out = hf_model(input_ids, attention_mask=attention_mask, labels=input_ids)
nemo_out = nemo_model(input_ids, attention_mask=attention_mask, labels=input_ids)
hf_out.loss.backward()
nemo_out.loss.backward()
for (hf_name, hf_param), (nemo_name, nemo_param) in zip(
hf_model.named_parameters(), nemo_model.named_parameters()
):
if hf_param.grad is not None and nemo_param.grad is not None:
compare_tensors(hf_param.grad, nemo_param.grad, name=f"grad_{hf_name}")
Testing Rules
- Always test on CPU/float32 first. GPU and lower precision introduce noise that masks real bugs.
- Test both fresh load and save/reload cycle. A model that works after
from_pretrained may break after save_pretrained + from_pretrained if the state dict adapter has asymmetries.
- Never modify reference HF code. The HF model is the ground truth. Only modify the NeMo AutoModel implementation.
- Use deterministic inputs (torch.manual_seed). Every test must be reproducible.
- Compare all outputs, not just loss. Loss can match by coincidence even when logits diverge. Always compare logits, hidden states, and attention weights where possible.
- Check both forward pass and gradient computation. Forward parity does not guarantee backward parity, especially with custom kernels.
- Verify tied weights are handled correctly. If
tie_word_embeddings=True, confirm that lm_head.weight and embed_tokens.weight share the same tensor after loading.
- Test with and without kernel patches. Liger kernels, SDPA patching, and other optimizations may change numerics. Run parity tests with all patches disabled first, then enable them one at a time.
Code Anchors
These are the key source files relevant to parity testing:
| Component | Path |
|---|
| State dict adapter base | components/models/common/combined_projection/state_dict_adapter.py |
| Model registry | _transformers/registry.py |
| AutoModel entry point | _transformers/auto_model.py |
| Kernel patches | _transformers/kernel_patches.py |
| Model capabilities | _transformers/capabilities.py |