use super::{
assert_almost_equals, new_backward_input, new_input, new_tensor, Backward, Data, Forward,
Gradient, MatrixVectorMul, MatrixVectorMulBackward, MatrixVectorMulBackwardLeft,
MatrixVectorMulBackwardRight, Overwrite, Tensor,
};
#[cfg(feature = "blas")]
extern crate blas_src;
mod forward {
use super::{
assert_almost_equals, new_input, new_tensor, Data, Forward, MatrixVectorMul, Tensor,
};
#[test]
fn creation() {
let left = new_input((3, 3), vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]);
let right = new_input(3, vec![1.; 3]);
let node = MatrixVectorMul::new(left, right);
assert_eq!(*node.data(), Tensor::from_elem(3, 0.));
assert_eq!(*node.data_mut(), Tensor::from_elem(3, 0.));
assert!(!node.was_computed());
}
#[test]
fn computation_was_computed_transition() {
let left = new_input((3, 3), vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]);
let right = new_input(3, vec![1.; 3]);
let node = MatrixVectorMul::new(left, right);
node.forward();
assert!(node.was_computed());
node.forward();
assert!(node.was_computed());
node.reset_computation();
assert!(!node.was_computed());
node.reset_computation();
assert!(!node.was_computed());
}
#[test]
fn forward() {
let left = new_input((3, 3), vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]);
let right = new_input(3, vec![1.; 3]);
let node = MatrixVectorMul::new(left, right.clone());
node.forward();
assert_almost_equals(&*node.data(), &new_tensor(3, vec![6., 15., 24.]));
*right.data_mut() = new_tensor(3, vec![-2.; 3]);
assert_almost_equals(&*right.data(), &new_tensor(3, vec![-2.; 3]));
node.forward();
assert_almost_equals(&*node.data(), &new_tensor(3, vec![6., 15., 24.]));
node.reset_computation();
node.forward();
assert_almost_equals(&*node.data(), &new_tensor(3, vec![-12., -30., -48.]));
}
#[test]
fn debug() {
let left = new_input((3, 3), vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]);
let right = new_input(3, vec![1.; 3]);
let node = MatrixVectorMul::new(left, right.clone());
let output = "MatrixVectorMul { data: [0.0, 0.0, 0.0], shape=[3], strides=[1], layout=CFcf (0xf), const ndim=1, computed: false }";
assert_eq!(output, format!("{:?}", node));
}
#[test]
fn display() {
let left = new_input((3, 3), vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]);
let right = new_input(3, vec![1.; 3]);
let node = MatrixVectorMul::new(left, right.clone());
assert_eq!(format!("{}", node.data()), format!("{}", node));
}
}
mod backward {
use super::{
assert_almost_equals, new_backward_input, new_input, new_tensor, Backward, Gradient,
MatrixVectorMulBackward, MatrixVectorMulBackwardLeft, MatrixVectorMulBackwardRight,
Overwrite, Tensor,
};
#[test]
fn creation() {
let node = MatrixVectorMulBackward::new(
new_input((3, 3), vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]),
new_backward_input((3, 3), vec![0.; 9]),
new_input(3, vec![1., 2., 3.]),
new_backward_input(3, vec![0.; 3]),
);
assert_eq!(*node.gradient(), Tensor::from_elem(3, 0.));
assert_eq!(*node.gradient_mut(), Tensor::from_elem(3, 0.));
assert!(node.can_overwrite());
}
#[test]
fn computation_state_transition() {
let lhs = new_backward_input((3, 3), vec![0.; 9]);
let rhs = new_backward_input(3, vec![0.; 3]);
let node = MatrixVectorMulBackward::new(
new_input((3, 3), vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]),
lhs.clone(),
new_input(3, vec![1., 2., 3.]),
rhs.clone(),
);
node.backward();
assert!(node.can_overwrite());
assert!(!lhs.can_overwrite());
assert!(!rhs.can_overwrite());
node.backward();
assert!(node.can_overwrite());
assert!(!lhs.can_overwrite());
assert!(!rhs.can_overwrite());
lhs.set_overwrite(true);
assert!(node.can_overwrite());
assert!(lhs.can_overwrite());
assert!(!rhs.can_overwrite());
lhs.set_overwrite(true);
assert!(node.can_overwrite());
assert!(lhs.can_overwrite());
assert!(!rhs.can_overwrite());
rhs.set_overwrite(true);
assert!(node.can_overwrite());
assert!(lhs.can_overwrite());
assert!(rhs.can_overwrite());
rhs.set_overwrite(true);
assert!(node.can_overwrite());
assert!(lhs.can_overwrite());
assert!(rhs.can_overwrite());
node.set_overwrite(false);
assert!(!node.can_overwrite());
assert!(lhs.can_overwrite());
assert!(rhs.can_overwrite());
node.set_overwrite(false);
assert!(!node.can_overwrite());
assert!(lhs.can_overwrite());
assert!(rhs.can_overwrite());
node.backward();
assert!(!node.can_overwrite());
assert!(!lhs.can_overwrite());
assert!(!rhs.can_overwrite());
node.backward();
assert!(!node.can_overwrite());
assert!(!lhs.can_overwrite());
assert!(!rhs.can_overwrite());
}
#[test]
fn backward() {
let lhs = new_backward_input((3, 3), vec![0.; 9]);
let rhs = new_backward_input(3, vec![0.; 3]);
let node = MatrixVectorMulBackward::new(
new_input((3, 3), vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]),
lhs.clone(),
new_input(3, vec![1., 2., 3.]),
rhs.clone(),
);
*node.gradient_mut() = new_tensor(3, vec![1.; 3]);
assert_almost_equals(&*node.gradient(), &new_tensor(3, vec![1.; 3]));
node.backward();
assert_almost_equals(
&*lhs.gradient(),
&new_tensor((3, 3), vec![1., 2., 3., 1., 2., 3., 1., 2., 3.]),
);
assert_almost_equals(&*rhs.gradient(), &new_tensor(3, vec![12., 15., 18.]));
node.backward();
assert_almost_equals(
&*lhs.gradient(),
&new_tensor((3, 3), vec![2., 4., 6., 2., 4., 6., 2., 4., 6.]),
);
assert_almost_equals(&*rhs.gradient(), &new_tensor(3, vec![24., 30., 36.]));
lhs.set_overwrite(true);
rhs.set_overwrite(true);
node.backward();
assert_almost_equals(
&*lhs.gradient(),
&new_tensor((3, 3), vec![1., 2., 3., 1., 2., 3., 1., 2., 3.]),
);
assert_almost_equals(&*rhs.gradient(), &new_tensor(3, vec![12., 15., 18.]));
}
#[test]
fn debug() {
let lhs = new_backward_input((3, 3), vec![0.; 9]);
let rhs = new_backward_input(3, vec![0.; 3]);
let node = MatrixVectorMulBackward::new(
new_input((3, 3), vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]),
lhs,
new_input(3, vec![1., 2., 3.]),
rhs,
);
let output = "MatrixVectorMulBackward { gradient: Some([0.0, 0.0, 0.0], shape=[3], strides=[1], layout=CFcf (0xf), const ndim=1), overwrite: true }";
assert_eq!(output, format!("{:?}", node));
}
#[test]
fn display() {
let lhs = new_backward_input((3, 3), vec![0.; 9]);
let rhs = new_backward_input(3, vec![0.; 3]);
let node = MatrixVectorMulBackward::new(
new_input((3, 3), vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]),
lhs,
new_input(3, vec![1., 2., 3.]),
rhs,
);
assert_eq!(format!("{}", node.gradient()), format!("{}", node));
}
#[test]
fn backward_left() {
let diff = new_backward_input((3, 3), vec![0.; 9]);
let node = MatrixVectorMulBackwardLeft::new(diff.clone(), new_input(3, vec![1., 2., 3.]));
*node.gradient_mut() = new_tensor(3, vec![1.; 3]);
assert_almost_equals(&*node.gradient(), &new_tensor(3, vec![1.; 3]));
node.backward();
assert_almost_equals(
&*diff.gradient(),
&new_tensor((3, 3), vec![1., 2., 3., 1., 2., 3., 1., 2., 3.]),
);
node.backward();
assert_almost_equals(
&*diff.gradient(),
&new_tensor((3, 3), vec![2., 4., 6., 2., 4., 6., 2., 4., 6.]),
);
diff.set_overwrite(true);
node.backward();
assert_almost_equals(
&*diff.gradient(),
&new_tensor((3, 3), vec![1., 2., 3., 1., 2., 3., 1., 2., 3.]),
);
}
#[test]
fn debug_left() {
let diff = new_backward_input((3, 3), vec![0.; 9]);
let node = MatrixVectorMulBackwardLeft::new(diff.clone(), new_input(3, vec![1., 2., 3.]));
let output = "MatrixVectorMulBackwardLeft { gradient: Some([0.0, 0.0, 0.0], shape=[3], strides=[1], layout=CFcf (0xf), const ndim=1), overwrite: true }";
assert_eq!(output, format!("{:?}", node));
}
#[test]
fn display_left() {
let diff = new_backward_input((3, 3), vec![0.; 9]);
let node = MatrixVectorMulBackwardLeft::new(diff.clone(), new_input(3, vec![1., 2., 3.]));
assert_eq!(format!("{}", node.gradient()), format!("{}", node));
}
#[test]
fn backward_right() {
let diff = new_backward_input(3, vec![0.; 3]);
let node = MatrixVectorMulBackwardRight::new(
new_input((3, 3), vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]),
diff.clone(),
);
*node.gradient_mut() = new_tensor(3, vec![1.; 3]);
assert_almost_equals(&*node.gradient(), &new_tensor(3, vec![1.; 3]));
node.backward();
assert_almost_equals(&*diff.gradient(), &new_tensor(3, vec![12., 15., 18.]));
node.backward();
assert_almost_equals(&*diff.gradient(), &new_tensor(3, vec![24., 30., 36.]));
diff.set_overwrite(true);
node.backward();
assert_almost_equals(&*diff.gradient(), &new_tensor(3, vec![12., 15., 18.]));
}
#[test]
fn debug_right() {
let diff = new_backward_input(3, vec![0.; 3]);
let node = MatrixVectorMulBackwardRight::new(
new_input((3, 3), vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]),
diff,
);
let output = "MatrixVectorMulBackwardRight { gradient: Some([0.0, 0.0, 0.0], shape=[3], strides=[1], layout=CFcf (0xf), const ndim=1), overwrite: true }";
assert_eq!(output, format!("{:?}", node));
}
#[test]
fn display_right() {
let diff = new_backward_input(3, vec![0.; 3]);
let node = MatrixVectorMulBackwardRight::new(
new_input((3, 3), vec![1., 2., 3., 4., 5., 6., 7., 8., 9.]),
diff.clone(),
);
assert_eq!(format!("{}", node.gradient()), format!("{}", node));
}
#[test]
fn no_grad() {
let node = MatrixVectorMulBackward::new(
new_input((3, 3), vec![0.; 9]),
new_backward_input((3, 3), vec![0.; 9]),
new_input(3, vec![0.; 3]),
new_backward_input(3, vec![0.; 3]),
);
node.no_grad();
assert!(node.gradient.borrow().is_none());
node.with_grad();
assert_eq!(&*node.gradient(), Tensor::zeros(node.shape));
let node = MatrixVectorMulBackwardLeft::new(
new_backward_input((3, 3), vec![0.; 9]),
new_input(3, vec![0.; 3]),
);
node.no_grad();
assert!(node.gradient.borrow().is_none());
node.with_grad();
assert_eq!(&*node.gradient(), Tensor::zeros(node.shape));
let node = MatrixVectorMulBackwardRight::new(
new_input((3, 3), vec![0.; 9]),
new_backward_input(3, vec![0.; 3]),
);
node.no_grad();
assert!(node.gradient.borrow().is_none());
node.with_grad();
assert_eq!(&*node.gradient(), Tensor::zeros(node.shape));
}
}