tripy-new-operation
Add a new operation to nvtripy. Use when: implementing a new op, adding a frontend op, creating a trace op, registering an op in the API. Covers the full…
npx skills add https://github.com/nvidia/tensorrt-incubator --skill tripy-new-operationAdding a New Operation to nvtripy
When to Use
- Adding a new mathematical, tensor, or neural network operation
- Creating a new frontend function that maps to TensorRT/MLIR ops
- Extending the op registry with unary, binary, or custom operations
Architecture Overview
Operations in nvtripy follow a Frontend → Trace → MLIR pipeline:
- Trace Op (
nvtripy/trace/ops/): Defines the computational graph node — rank inference, dtype inference, and MLIR code generation. - Frontend Op (
nvtripy/frontend/ops/): The public API function — exports, constraints, docstring, and bridges to the trace op viacreate_op(). - Registration: Both
__init__.pyfiles must be updated so the op is discoverable.
Procedure
Step 1: Create the Trace Operation
Create a file in nvtripy/trace/ops/<op_name>.py:
from dataclasses import dataclass
import nvtripy.trace.ops.utils as op_utils
from mlir_tensorrt.compiler.dialects import tensorrt
from nvtripy.trace.ops.base import TraceOp
@dataclass(repr=False)
class MyOp(TraceOp):
# Add any op-specific parameters as dataclass fields:
dim: int
# Choose a rank inference policy:
infer_rank = op_utils.InferRankPolicies.same_as_input()
def to_mlir(self, inputs, outputs):
# Generate MLIR using the tensorrt dialect:
return [tensorrt.some_op(inputs[0], self.dim)]
Key base class requirements (from TraceOp):
infer_rank(required): Set output rank. Use policies fromInferRankPolicies:same_as_input(idx=0)— output rank matches input[idx]same_shape_as_input(idx=0)— output has same shape (not just rank)same_as_shape_of_shape_input(idx=0)— rank from a shape tensormax_of_inputs()— rank is max across all inputs- Or define a custom function
to_mlir(self, inputs, outputs)(required): Return list of MLIR operationsinfer_dtypes()(optional): Default propagates frominputs[0]. Override for multi-dtype ops.infer_devices()(optional): Default sets all outputs to GPU.get_num_outputs()(optional): Default is 1. Override for multi-output ops.str_skip_fields()(optional): Fields to omit from string representation.
Factory pattern for families of similar ops (see trace/ops/unary.py):
def make_unary_op(name, attr_name):
@dataclass(repr=False)
class UnaryOp(TraceOp):
infer_rank = op_utils.InferRankPolicies.same_as_input()
def to_mlir(self, inputs, outputs):
return [tensorrt.unary(inputs[0], tensorrt.UnaryOperationAttr.get(attr_name))]
UnaryOp.__name__ = name
return UnaryOp
Exp = make_unary_op("Exp", "kEXP")
Step 2: Create the Frontend Operation
Create a file in nvtripy/frontend/ops/<op_name>.py:
from typing import Optional
from nvtripy import export
from nvtripy.common import datatype as dt
from nvtripy.frontend import wrappers
from nvtripy.frontend.constraints import GetInput, GetReturn, OneOf
from nvtripy.frontend.ops import utils as op_utils
from nvtripy.trace.ops.my_op import MyOp
@export.public_api(document_under="operations/functions")
@wrappers.interface(
input_requirements=OneOf(GetInput("input").dtype, [dt.float32, dt.float16, dt.bfloat16]),
output_guarantees=GetReturn(0).dtype == GetInput("input").dtype,
)
def my_op(input: "nvtripy.Tensor", dim: Optional[int] = None) -> "nvtripy.Tensor":
r"""
Brief description of what the op does.
Args:
input: The input tensor.
dim: The dimension to operate on.
Returns:
A tensor of the same shape as the input.
.. code-block:: python
:linenos:
input = tp.iota([2, 3], dtype=tp.float32)
output = tp.my_op(input, dim=0)
assert tp.allclose(output, expected_tensor)
"""
dim = op_utils.process_dim(dim, input.rank)
return op_utils.create_op(MyOp, [input], dim=dim)
Key decorator details:
@export.public_api(document_under="..."): Registers in public API and docs hierarchy. Common paths:"operations/functions"— general tensor ops"operations/initializers"— tensor creation ops (ones, zeros, full)"operations/modules"— nn module classes
@wrappers.interface(...): Defines input constraints and output guarantees (see constraint skill)- Bridge to trace via
op_utils.create_op(TraceOpClass, [inputs], **kwargs)
Step 3: Register in __init__.py Files
nvtripy/frontend/ops/__init__.py: Add import so auto-discovery finds the module.
nvtripy/trace/ops/__init__.py: Usually empty — trace ops are imported directly by frontend ops.
Step 4: Add as Tensor Method (Optional)
If the op should be callable as tensor.my_op(), register it in the TENSOR_METHOD_REGISTRY via the frontend tensor metaclass system. Check nvtripy/frontend/tensor.py for the pattern.
Complete Example: Softmax
Trace op (nvtripy/trace/ops/softmax.py):
@dataclass(repr=False)
class Softmax(TraceOp):
dim: int
infer_rank = op_utils.InferRankPolicies.same_as_input()
def to_mlir(self, inputs, outputs):
return [tensorrt.softmax(inputs[0], self.dim)]
Frontend op (nvtripy/frontend/ops/softmax.py):
@export.public_api(document_under="operations/functions")
@wrappers.interface(
input_requirements=OneOf(GetInput("input").dtype, [dt.float32, dt.float16, dt.bfloat16]),
output_guarantees=GetReturn(0).dtype == GetInput("input").dtype,
)
def softmax(input: "nvtripy.Tensor", dim: Optional[int] = None) -> "nvtripy.Tensor":
# Handle None dim by flattening
# Handle rank < 2 by unsqueezing (TensorRT requirement)
dim = op_utils.process_dim(dim, input.rank)
return op_utils.create_op(Softmax, [input], dim=dim)
Checklist
- Trace op created in
nvtripy/trace/ops/withinfer_rankandto_mlir - Frontend op created in
nvtripy/frontend/ops/with@export.public_apiand@wrappers.interface - Constraints defined for valid dtypes and output guarantees
- Docstring includes Args, Returns, and a working
.. code-block:: pythonexample -
__init__.pyupdated if needed for auto-discovery - Tests added in
tests/frontend/ops/andtests/trace/ops/(see testing skill)