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//
// A rust binding for the GSL library by Guillaume Gomez (guillaume1.gomez@gmail.com)
//
use crate::Value;
use ffi::FFI;
/// This function returns the index i of the array x_array such that `x_array[i] <= x < x_array[i+1]`.
/// The index is searched for in the range `[index_lo,index_hi]`.
#[doc(alias = "gsl_interp_bsearch")]
pub fn bsearch(x_array: &[f64], x: f64, index_lo: usize, index_hi: usize) -> usize {
unsafe { sys::gsl_interp_bsearch(x_array.as_ptr(), x, index_lo, index_hi) }
}
/// This function returns the interpolated value of y for a given point x, using the interpolation
/// object interp, data arrays xa and ya and the accelerator acc. When x is outside the range of xa,
/// the error code ::Dom is returned with a value of rgsl::NAN for y.
#[doc(alias = "gsl_interp_eval")]
pub fn eval(interp: &::Interp, xa: &[f64], ya: &[f64], x: f64, acc: &mut ::InterpAccel) -> f64 {
unsafe {
sys::gsl_interp_eval(
interp.unwrap_shared(),
xa.as_ptr(),
ya.as_ptr(),
x,
&mut acc.0,
)
}
}
/// This function returns the interpolated value of y for a given point x, using the interpolation
/// object interp, data arrays xa and ya and the accelerator acc. When x is outside the range of xa,
/// the error code ::Dom is returned with a value of rgsl::NAN for y.
///
/// Returns `y`.
#[doc(alias = "gsl_interp_eval_e")]
pub fn eval_e(
interp: &::Interp,
xa: &[f64],
ya: &[f64],
x: f64,
acc: &mut ::InterpAccel,
) -> Result<f64, Value> {
let mut y = 0.;
let ret = unsafe {
sys::gsl_interp_eval_e(
interp.unwrap_shared(),
xa.as_ptr(),
ya.as_ptr(),
x,
&mut acc.0,
&mut y,
)
};
result_handler!(ret, y)
}
/// This function returns the derivative d of an interpolated function for a given point x, using
/// the interpolation object interp, data arrays xa and ya and the accelerator acc.
#[doc(alias = "gsl_interp_eval_deriv")]
pub fn eval_deriv(
interp: &::Interp,
xa: &[f64],
ya: &[f64],
x: f64,
acc: &mut ::InterpAccel,
) -> f64 {
unsafe {
sys::gsl_interp_eval_deriv(
interp.unwrap_shared(),
xa.as_ptr(),
ya.as_ptr(),
x,
&mut acc.0,
)
}
}
/// This function returns the derivative d of an interpolated function for a given point x, using
/// the interpolation object interp, data arrays xa and ya and the accelerator acc.
///
/// Returns `(Value, d)`.
#[doc(alias = "gsl_interp_eval_deriv_e")]
pub fn eval_deriv_e(
interp: &::Interp,
xa: &[f64],
ya: &[f64],
x: f64,
acc: &mut ::InterpAccel,
) -> Result<f64, Value> {
let mut d = 0.;
let ret = unsafe {
sys::gsl_interp_eval_deriv_e(
interp.unwrap_shared(),
xa.as_ptr(),
ya.as_ptr(),
x,
&mut acc.0,
&mut d,
)
};
result_handler!(ret, d)
}
/// This function returns the second derivative d2 of an interpolated function for a given point x,
/// using the interpolation object interp, data arrays xa and ya and the accelerator acc.
#[doc(alias = "gsl_interp_eval_deriv2")]
pub fn eval_deriv2(
interp: &::Interp,
xa: &[f64],
ya: &[f64],
x: f64,
acc: &mut ::InterpAccel,
) -> f64 {
unsafe {
sys::gsl_interp_eval_deriv2(
interp.unwrap_shared(),
xa.as_ptr(),
ya.as_ptr(),
x,
&mut acc.0,
)
}
}
/// This function returns the second derivative d2 of an interpolated function for a given point x,
/// using the interpolation object interp, data arrays xa and ya and the accelerator acc.
///
/// Returns `(Value, d2)`.
#[doc(alias = "gsl_interp_eval_deriv2_e")]
pub fn eval_deriv2_e(
interp: &::Interp,
xa: &[f64],
ya: &[f64],
x: f64,
acc: &mut ::InterpAccel,
) -> Result<f64, Value> {
let mut d2 = 0.;
let ret = unsafe {
sys::gsl_interp_eval_deriv2_e(
interp.unwrap_shared(),
xa.as_ptr(),
ya.as_ptr(),
x,
&mut acc.0,
&mut d2,
)
};
result_handler!(ret, d2)
}
/// This function returns the numerical integral result of an interpolated function over the range
/// [a, b], using the interpolation object interp, data arrays xa and ya and the accelerator acc.
#[doc(alias = "gsl_interp_eval_integ")]
pub fn eval_integ(
interp: &::Interp,
xa: &[f64],
ya: &[f64],
a: f64,
b: f64,
acc: &mut ::InterpAccel,
) -> f64 {
unsafe {
sys::gsl_interp_eval_integ(
interp.unwrap_shared(),
xa.as_ptr(),
ya.as_ptr(),
a,
b,
&mut acc.0,
)
}
}
/// This function returns the numerical integral result of an interpolated function over the range
/// [a, b], using the interpolation object interp, data arrays xa and ya and the accelerator acc.
///
/// Returns `(Value, result)`.
#[doc(alias = "gsl_interp_eval_integ_e")]
pub fn eval_integ_e(
interp: &::Interp,
xa: &[f64],
ya: &[f64],
a: f64,
b: f64,
acc: &mut ::InterpAccel,
) -> Result<f64, Value> {
let mut result = 0.;
let ret = unsafe {
sys::gsl_interp_eval_integ_e(
interp.unwrap_shared(),
xa.as_ptr(),
ya.as_ptr(),
a,
b,
&mut acc.0,
&mut result,
)
};
result_handler!(ret, result)
}