1#ifndef STAN_MATH_OPENCL_PRIM_EXPONENTIAL_LCCDF_HPP
2#define STAN_MATH_OPENCL_PRIM_EXPONENTIAL_LCCDF_HPP
29template <
typename T_y_cl,
typename T_inv_scale_cl,
31 T_y_cl, T_inv_scale_cl>* =
nullptr,
32 require_any_not_stan_scalar_t<T_y_cl, T_inv_scale_cl>* =
nullptr>
34 const T_y_cl& y,
const T_inv_scale_cl&
beta) {
35 static constexpr const char* function =
"exponential_lccdf(OpenCL)";
41 "Inverse scale parameter",
beta);
51 const auto& beta_val =
value_of(beta_col);
53 auto check_y_nonnegative
54 =
check_cl(function,
"Random variable", y_val,
"nonnegative");
55 auto y_nonnegative_expr = y_val >= 0.0;
56 auto check_beta_positive_finite =
check_cl(
57 function,
"Inverse scale parameter", beta_val,
"positive finite");
58 auto beta_positive_finite_expr = 0.0 < beta_val &&
isfinite(beta_val);
64 results(check_y_nonnegative, check_beta_positive_finite, lccdf_cl)
65 =
expressions(y_nonnegative_expr, beta_positive_finite_expr, lccdf_expr);
71 if constexpr (is_autodiff_v<T_y_cl>) {
72 partials<0>(ops_partials) =
constant(0.0, N, 1) - beta_val;
74 if constexpr (is_autodiff_v<T_inv_scale_cl>) {
75 partials<1>(ops_partials) =
constant(0.0, N, 1) - y_val;
77 return ops_partials.build(lccdf);
Represents an arithmetic matrix on the OpenCL device.
elt_multiply_< as_operation_cl_t< T_a >, as_operation_cl_t< T_b > > elt_multiply(T_a &&a, T_b &&b)
isfinite_< as_operation_cl_t< T > > isfinite(T &&a)
auto check_cl(const char *function, const char *var_name, T &&y, const char *must_be)
Constructs a check on opencl matrix or expression.
results_cl< T_results... > results(T_results &&... results)
Deduces types for constructing results_cl object.
auto as_column_vector_or_scalar(T &&a)
as_column_vector_or_scalar of a kernel generator expression.
auto constant(const T a, int rows, int cols)
Matrix of repeated values in kernel generator expressions.
auto colwise_sum(T &&a)
Column wise sum - reduction of a kernel generator expression.
expressions_cl< T_expressions... > expressions(T_expressions &&... expressions)
Deduces types for constructing expressions_cl object.
return_type_t< T_y_cl, T_inv_scale_cl > exponential_lccdf(const T_y_cl &y, const T_inv_scale_cl &beta)
Calculates the log exponential cumulative distribution function for the given y and beta.
auto from_matrix_cl(const T &src)
Copies the source matrix that is stored on the OpenCL device to the destination Eigen matrix.
require_all_t< is_prim_or_rev_kernel_expression< std::decay_t< Types > >... > require_all_prim_or_rev_kernel_expression_t
Require type satisfies is_prim_or_rev_kernel_expression.
typename return_type< Ts... >::type return_type_t
Convenience type for the return type of the specified template parameters.
T value_of(const fvar< T > &v)
Return the value of the specified variable.
void check_consistent_sizes(const char *)
Trivial no input case, this function is a no-op.
auto sum(const std::vector< T > &m)
Return the sum of the entries of the specified standard vector.
int64_t max_size(const T1 &x1, const Ts &... xs)
Calculate the size of the largest input.
fvar< T > beta(const fvar< T > &x1, const fvar< T > &x2)
Return fvar with the beta function applied to the specified arguments and its gradient.
auto make_partials_propagator(Ops &&... ops)
Construct an partials_propagator.
typename partials_return_type< Args... >::type partials_return_t
The lgamma implementation in stan-math is based on either the reentrant safe lgamma_r implementation ...
bool isnan(const stan::math::var &a)
Checks if the given number is NaN.
