Python store_multprec_system Examples

Programming Language: Python

Namespace/Package Name: interface

Method/Function: store_multprec_system

Examples at hotexamples.com: 2

Python store_multprec_system - 2 examples found. These are the top rated real world Python examples of interface.store_multprec_system extracted from open source projects. You can rate examples to help us improve the quality of examples.

Example #1

Show file

File: solver.py Project: callmetaste/PHCpack

def multprec_usolve(pol, mxi, eps, decimals):
    """
    Applies the method of Durand-Kerner (aka Weierstrass)
    to the polynomial in the string pol, in arbitrary multiprecision,
    the number of decimal places in the precision is in decimals.
    The maximum number of iterations is in mxi,
    the requirement on the accuracy in eps.
    """
    from phcpy.phcpy2c2 import py2c_usolve_multprec
    from phcpy.interface import store_multprec_system, load_multprec_solutions
    store_multprec_system([pol], decimals)
    nit = py2c_usolve_multprec(decimals, mxi, eps)
    rts = load_multprec_solutions()
    return (nit, rts)

Example #2

Show file

File: solver.py Project: callmetaste/PHCpack

def newton_step(system, solutions, precision='d', decimals=100):
    """
    Applies one Newton step to the solutions of the system.
    For each solution, prints its last line of diagnostics.
    Four levels of precision are supported:
    d  : standard double precision (1.1e-15 or 2^(-53)),
    dd : double double precision (4.9e-32 or 2^(-104)),
    qd : quad double precision (1.2e-63 or 2^(-209)).
    mp : arbitrary precision, where the number of decimal places
    in the working precision is determined by decimals.
    """
    if(precision == 'd'):
        from interface import store_standard_system
        from interface import store_standard_solutions, load_standard_solutions
        store_standard_system(system)
        store_standard_solutions(len(system), solutions)
        from phcpy.phcpy2c2 import py2c_standard_Newton_step
        py2c_standard_Newton_step()
        result = load_standard_solutions()
    elif(precision == 'dd'):
        from interface import store_dobldobl_system
        from interface import store_dobldobl_solutions, load_dobldobl_solutions
        store_dobldobl_system(system)
        store_dobldobl_solutions(len(system), solutions)
        from phcpy.phcpy2c2 import py2c_dobldobl_Newton_step
        py2c_dobldobl_Newton_step()
        result = load_dobldobl_solutions()
    elif(precision == 'qd'):
        from interface import store_quaddobl_system
        from interface import store_quaddobl_solutions, load_quaddobl_solutions
        store_quaddobl_system(system)
        store_quaddobl_solutions(len(system), solutions)
        from phcpy.phcpy2c2 import py2c_quaddobl_Newton_step
        py2c_quaddobl_Newton_step()
        result = load_quaddobl_solutions()
    elif(precision == 'mp'):
        from interface import store_multprec_system
        from interface import store_multprec_solutions, load_multprec_solutions
        store_multprec_system(system, decimals)
        store_multprec_solutions(len(system), solutions)
        from phcpy.phcpy2c2 import py2c_multprec_Newton_step
        py2c_multprec_Newton_step(decimals)
        result = load_multprec_solutions()
    else:
        print 'wrong argument for precision'
        return None
    for sol in result:
        strsol = sol.split('\n')
        print strsol[-1]
    return result