def funm(A, func, disp=True):
A = jnp.asarray(A)
if A.ndim != 2 or A.shape[0] != A.shape[1]:
raise ValueError('expected square array_like input')
T, Z = schur(A)
T, Z = rsf2csf(T, Z)
F = jnp.diag(func(jnp.diag(T)))
F = F.astype(T.dtype.char)
F, minden = _algorithm_11_1_1(F, T)
F = Z @ F @ Z.conj().T
if disp:
return F
if F.dtype.char.lower() == 'e':
tol = jnp.finfo(jnp.float16).eps
if F.dtype.char.lower() == 'f':
tol = jnp.finfo(jnp.float32).eps
else:
tol = jnp.finfo(jnp.float64).eps
minden = jnp.where(minden == 0.0, tol, minden)
err = jnp.where(jnp.any(jnp.isinf(F)), jnp.inf, jnp.minimum(1, jnp.maximum(
tol, (tol / minden) * norm(jnp.triu(T, 1), 1))))
return F, err
def _unique_sorted_mask(ar, axis):
aux = moveaxis(ar, axis, 0)
if np.issubdtype(aux.dtype, np.complexfloating):
# Work around issue in sorting of complex numbers with Nan only in the
# imaginary component. This can be removed if sorting in this situation
# is fixed to match numpy.
aux = where(isnan(aux), _lax_const(aux, np.nan), aux)
size, *out_shape = aux.shape
if _prod(out_shape) == 0:
size = 1
perm = zeros(1, dtype=int)
else:
perm = lexsort(aux.reshape(size, _prod(out_shape)).T[::-1])
aux = aux[perm]
if aux.size:
if dtypes.issubdtype(aux.dtype, np.inexact):
# This is appropriate for both float and complex due to the documented behavior of np.unique:
# See https://github.com/numpy/numpy/blob/v1.22.0/numpy/lib/arraysetops.py#L212-L220
neq = lambda x, y: lax.ne(x, y) & ~(isnan(x) & isnan(y))
else:
neq = lax.ne
mask = ones(size, dtype=bool).at[1:].set(
any(neq(aux[1:], aux[:-1]), tuple(range(1, aux.ndim))))
else:
mask = zeros(size, dtype=bool)
return aux, mask, perm
def matrix_rank(M, tol=None):
M = _promote_arg_dtypes(jnp.asarray(M))
if M.ndim > 2:
raise TypeError("array should have 2 or fewer dimensions")
if M.ndim < 2:
return jnp.any(M != 0).astype(jnp.int32)
S = svd(M, full_matrices=False, compute_uv=False)
if tol is None:
tol = S.max() * np.max(M.shape) * jnp.finfo(S.dtype).eps
return jnp.sum(S > tol)
def _slogdet_lu(a):
dtype = lax.dtype(a)
lu, pivot, _ = lax_linalg.lu(a)
diag = jnp.diagonal(lu, axis1=-2, axis2=-1)
is_zero = jnp.any(diag == jnp.array(0, dtype=dtype), axis=-1)
iota = lax.expand_dims(jnp.arange(a.shape[-1]), range(pivot.ndim - 1))
parity = jnp.count_nonzero(pivot != iota, axis=-1)
if jnp.iscomplexobj(a):
sign = jnp.prod(diag / jnp.abs(diag), axis=-1)
else:
sign = jnp.array(1, dtype=dtype)
parity = parity + jnp.count_nonzero(diag < 0, axis=-1)
sign = jnp.where(is_zero, jnp.array(0, dtype=dtype),
sign * jnp.array(-2 * (parity % 2) + 1, dtype=dtype))
logdet = jnp.where(is_zero, jnp.array(-jnp.inf, dtype=dtype),
jnp.sum(jnp.log(jnp.abs(diag)), axis=-1))
return sign, jnp.real(logdet)
def slogdet(a):
a = _promote_arg_dtypes(jnp.asarray(a))
dtype = lax.dtype(a)
a_shape = jnp.shape(a)
if len(a_shape) < 2 or a_shape[-1] != a_shape[-2]:
msg = "Argument to slogdet() must have shape [..., n, n], got {}"
raise ValueError(msg.format(a_shape))
lu, pivot, _ = lax_linalg.lu(a)
diag = jnp.diagonal(lu, axis1=-2, axis2=-1)
is_zero = jnp.any(diag == jnp.array(0, dtype=dtype), axis=-1)
parity = jnp.count_nonzero(pivot != jnp.arange(a_shape[-1]), axis=-1)
if jnp.iscomplexobj(a):
sign = jnp.prod(diag / jnp.abs(diag), axis=-1)
else:
sign = jnp.array(1, dtype=dtype)
parity = parity + jnp.count_nonzero(diag < 0, axis=-1)
sign = jnp.where(is_zero, jnp.array(0, dtype=dtype),
sign * jnp.array(-2 * (parity % 2) + 1, dtype=dtype))
logdet = jnp.where(is_zero, jnp.array(-jnp.inf, dtype=dtype),
jnp.sum(jnp.log(jnp.abs(diag)), axis=-1))
return sign, jnp.real(logdet)
def _cofactor_solve(a, b):
"""Equivalent to det(a)*solve(a, b) for nonsingular mat.
Intermediate function used for jvp and vjp of det.
This function borrows heavily from jax.numpy.linalg.solve and
jax.numpy.linalg.slogdet to compute the gradient of the determinant
in a way that is well defined even for low rank matrices.
This function handles two different cases:
* rank(a) == n or n-1
* rank(a) < n-1
For rank n-1 matrices, the gradient of the determinant is a rank 1 matrix.
Rather than computing det(a)*solve(a, b), which would return NaN, we work
directly with the LU decomposition. If a = p @ l @ u, then
det(a)*solve(a, b) =
prod(diag(u)) * u^-1 @ l^-1 @ p^-1 b =
prod(diag(u)) * triangular_solve(u, solve(p @ l, b))
If a is rank n-1, then the lower right corner of u will be zero and the
triangular_solve will fail.
Let x = solve(p @ l, b) and y = det(a)*solve(a, b).
Then y_{n}
x_{n} / u_{nn} * prod_{i=1...n}(u_{ii}) =
x_{n} * prod_{i=1...n-1}(u_{ii})
So by replacing the lower-right corner of u with prod_{i=1...n-1}(u_{ii})^-1
we can avoid the triangular_solve failing.
To correctly compute the rest of y_{i} for i != n, we simply multiply
x_{i} by det(a) for all i != n, which will be zero if rank(a) = n-1.
For the second case, a check is done on the matrix to see if `solve`
returns NaN or Inf, and gives a matrix of zeros as a result, as the
gradient of the determinant of a matrix with rank less than n-1 is 0.
This will still return the correct value for rank n-1 matrices, as the check
is applied *after* the lower right corner of u has been updated.
Args:
a: A square matrix or batch of matrices, possibly singular.
b: A matrix, or batch of matrices of the same dimension as a.
Returns:
det(a) and cofactor(a)^T*b, aka adjugate(a)*b
"""
a = _promote_arg_dtypes(jnp.asarray(a))
b = _promote_arg_dtypes(jnp.asarray(b))
a_shape = jnp.shape(a)
b_shape = jnp.shape(b)
a_ndims = len(a_shape)
if not (a_ndims >= 2 and a_shape[-1] == a_shape[-2]
and b_shape[-2:] == a_shape[-2:]):
msg = ("The arguments to _cofactor_solve must have shapes "
"a=[..., m, m] and b=[..., m, m]; got a={} and b={}")
raise ValueError(msg.format(a_shape, b_shape))
if a_shape[-1] == 1:
return a[..., 0, 0], b
# lu contains u in the upper triangular matrix and l in the strict lower
# triangular matrix.
# The diagonal of l is set to ones without loss of generality.
lu, pivots, permutation = lax_linalg.lu(a)
dtype = lax.dtype(a)
batch_dims = lax.broadcast_shapes(lu.shape[:-2], b.shape[:-2])
x = jnp.broadcast_to(b, batch_dims + b.shape[-2:])
lu = jnp.broadcast_to(lu, batch_dims + lu.shape[-2:])
# Compute (partial) determinant, ignoring last diagonal of LU
diag = jnp.diagonal(lu, axis1=-2, axis2=-1)
parity = jnp.count_nonzero(pivots != jnp.arange(a_shape[-1]), axis=-1)
sign = jnp.asarray(-2 * (parity % 2) + 1, dtype=dtype)
# partial_det[:, -1] contains the full determinant and
# partial_det[:, -2] contains det(u) / u_{nn}.
partial_det = jnp.cumprod(diag, axis=-1) * sign[..., None]
lu = lu.at[..., -1, -1].set(1.0 / partial_det[..., -2])
permutation = jnp.broadcast_to(permutation, batch_dims + (a_shape[-1], ))
iotas = jnp.ix_(*(lax.iota(jnp.int32, b) for b in batch_dims + (1, )))
# filter out any matrices that are not full rank
d = jnp.ones(x.shape[:-1], x.dtype)
d = lax_linalg.triangular_solve(lu, d, left_side=True, lower=False)
d = jnp.any(jnp.logical_or(jnp.isnan(d), jnp.isinf(d)), axis=-1)
d = jnp.tile(d[..., None, None], d.ndim * (1, ) + x.shape[-2:])
x = jnp.where(d, jnp.zeros_like(x), x) # first filter
x = x[iotas[:-1] + (permutation, slice(None))]
x = lax_linalg.triangular_solve(lu,
x,
left_side=True,
lower=True,
unit_diagonal=True)
x = jnp.concatenate(
(x[..., :-1, :] * partial_det[..., -1, None, None], x[..., -1:, :]),
axis=-2)
x = lax_linalg.triangular_solve(lu, x, left_side=True, lower=False)
x = jnp.where(d, jnp.zeros_like(x), x) # second filter
return partial_det[..., -1], x