use derive_new::new;
use onnx_ir_derive::NodeBuilder;
use crate::ir::{ArgType, Argument, AttributeValue, DType, Node, RawNode, TensorType};
use crate::processor::{
InputSpec, NodeProcessor, NodeSpec, OutputPreferences, OutputSpec, ProcessError,
};
#[derive(Debug, Clone, Default, new)]
pub struct ScalerConfig {
pub scale: Option<Vec<f32>>,
pub offset: Option<Vec<f32>>,
}
#[derive(Debug, Clone, new, NodeBuilder)]
pub struct ScalerNode {
pub name: String,
pub inputs: Vec<Argument>,
pub outputs: Vec<Argument>,
pub config: ScalerConfig,
}
pub(crate) struct ScalerProcessor;
impl NodeProcessor for ScalerProcessor {
type Config = ScalerConfig;
fn spec(&self) -> NodeSpec {
NodeSpec {
min_opset: 1,
max_opset: None,
inputs: InputSpec::Exact(1),
outputs: OutputSpec::Exact(1),
}
}
fn infer_types(
&self,
node: &mut RawNode,
_opset: usize,
_output_preferences: &OutputPreferences,
) -> Result<(), ProcessError> {
let (rank, static_shape) = match &node.inputs[0].ty {
ArgType::Tensor(t) => {
match t.dtype {
DType::F32 | DType::F64 | DType::I32 | DType::I64 => {}
other => {
return Err(ProcessError::TypeMismatch {
expected: "tensor(float | double | int32 | int64)".to_string(),
actual: format!("tensor({other:?})"),
});
}
}
(t.rank, t.static_shape.clone())
}
other => {
return Err(ProcessError::TypeMismatch {
expected: "tensor(float | double | int32 | int64)".to_string(),
actual: format!("{other:?}"),
});
}
};
node.outputs[0].ty = ArgType::Tensor(TensorType {
dtype: DType::F32,
rank,
static_shape,
});
Ok(())
}
fn extract_config(&self, node: &RawNode, _opset: usize) -> Result<Self::Config, ProcessError> {
let mut scale: Option<Vec<f32>> = None;
let mut offset: Option<Vec<f32>> = None;
for (key, value) in node.attrs.iter() {
match key.as_str() {
"scale" => {
if let AttributeValue::Float32s(floats) = value {
scale = Some(floats.clone());
} else {
return Err(ProcessError::InvalidAttribute {
name: "scale".to_string(),
reason: format!("expected Float32s, got {value:?}"),
});
}
}
"offset" => {
if let AttributeValue::Float32s(floats) = value {
offset = Some(floats.clone());
} else {
return Err(ProcessError::InvalidAttribute {
name: "offset".to_string(),
reason: format!("expected Float32s, got {value:?}"),
});
}
}
_ => {}
}
}
if let (Some(s), Some(o)) = (&scale, &offset)
&& s.len() != o.len()
{
return Err(ProcessError::InvalidAttribute {
name: "scale/offset".to_string(),
reason: format!(
"scale and offset must have the same length, got {} and {}",
s.len(),
o.len()
),
});
}
Ok(ScalerConfig::new(scale, offset))
}
fn build_node(&self, builder: RawNode, opset: usize) -> Node {
let config = self
.extract_config(&builder, opset)
.expect("ScalerProcessor: config extraction failed");
Node::Scaler(ScalerNode::new(
builder.name,
builder.inputs,
builder.outputs,
config,
))
}
}
#[cfg(test)]
mod tests {
use super::*;
use crate::ir::NodeType;
use crate::node::test_utils::TestNodeBuilder;
use crate::processor::OutputPreferences;
use burn_tensor::BoolStore;
fn make_node(scale: Option<Vec<f32>>, offset: Option<Vec<f32>>, dtype: DType) -> RawNode {
let mut builder =
match dtype {
DType::F32 => TestNodeBuilder::new(NodeType::Scaler, "test_scaler")
.input_tensor_f32("X", 2, None),
DType::F64 => TestNodeBuilder::new(NodeType::Scaler, "test_scaler")
.input_tensor_f64("X", 2, None),
DType::I32 => TestNodeBuilder::new(NodeType::Scaler, "test_scaler")
.input_tensor_i32("X", 2, None),
DType::I64 => TestNodeBuilder::new(NodeType::Scaler, "test_scaler")
.input_tensor_i64("X", 2, None),
DType::Bool(_) => TestNodeBuilder::new(NodeType::Scaler, "test_scaler")
.input_tensor_bool("X", 2, None),
_ => panic!("unsupported dtype in test helper"),
}
.output_tensor_f32("Y", 2, None);
if let Some(s) = scale {
builder = builder.attr_floats("scale", s);
}
if let Some(o) = offset {
builder = builder.attr_floats("offset", o);
}
builder.build()
}
#[test]
fn test_scaler_config_extraction() {
let config = ScalerConfig::new(Some(vec![2.0]), Some(vec![1.0]));
assert!(config.scale.is_some());
assert_eq!(config.scale.unwrap(), vec![2.0]);
assert!(config.offset.is_some());
assert_eq!(config.offset.unwrap(), vec![1.0]);
}
#[test]
fn test_scaler_node_builder() {
let config = ScalerConfig::new(Some(vec![2.0]), Some(vec![1.0]));
let node = ScalerNode::new("test_scaler".to_string(), vec![], vec![], config);
assert_eq!(node.name, "test_scaler");
assert_eq!(node.inputs.len(), 0);
assert_eq!(node.outputs.len(), 0);
assert!(node.config.scale.is_some());
assert!(node.config.offset.is_some());
}
#[test]
fn test_infer_types_f32_preserves_shape() {
let mut node = make_node(Some(vec![2.0]), Some(vec![1.0]), DType::F32);
let processor = ScalerProcessor;
let prefs = OutputPreferences::new();
processor.infer_types(&mut node, 1, &prefs).unwrap();
match &node.outputs[0].ty {
ArgType::Tensor(t) => {
assert_eq!(t.dtype, DType::F32);
assert_eq!(t.rank, 2);
}
other => panic!("expected Tensor, got {other:?}"),
}
}
#[test]
fn test_infer_types_int64_output_is_f32() {
let mut node = make_node(Some(vec![2.0]), None, DType::I64);
let processor = ScalerProcessor;
let prefs = OutputPreferences::new();
processor.infer_types(&mut node, 1, &prefs).unwrap();
match &node.outputs[0].ty {
ArgType::Tensor(t) => assert_eq!(t.dtype, DType::F32),
other => panic!("expected Tensor, got {other:?}"),
}
}
#[test]
fn test_infer_types_rejects_invalid_dtype() {
let mut node = make_node(None, None, DType::Bool(BoolStore::Native));
let processor = ScalerProcessor;
let prefs = OutputPreferences::new();
let err = processor.infer_types(&mut node, 1, &prefs).unwrap_err();
assert!(matches!(err, ProcessError::TypeMismatch { .. }));
}
#[test]
fn test_extract_config_both_attrs() {
let node = make_node(Some(vec![2.0, 3.0]), Some(vec![0.5, 1.0]), DType::F32);
let processor = ScalerProcessor;
let config = processor.extract_config(&node, 1).unwrap();
assert_eq!(config.scale.unwrap(), vec![2.0, 3.0]);
assert_eq!(config.offset.unwrap(), vec![0.5, 1.0]);
}
#[test]
fn test_extract_config_length_mismatch_error() {
let node = make_node(Some(vec![1.0, 2.0]), Some(vec![0.5]), DType::F32);
let processor = ScalerProcessor;
let err = processor.extract_config(&node, 1).unwrap_err();
assert!(matches!(
err,
ProcessError::InvalidAttribute { ref name, .. } if name == "scale/offset"
));
}
}