# -*- coding: future_fstrings -*-
#
# Copyright 2019 Gianluca Frison, Dimitris Kouzoupis, Robin Verschueren,
# Andrea Zanelli, Niels van Duijkeren, Jonathan Frey, Tommaso Sartor,
# Branimir Novoselnik, Rien Quirynen, Rezart Qelibari, Dang Doan,
# Jonas Koenemann, Yutao Chen, Tobias Schöls, Jonas Schlagenhauf, Moritz Diehl
#
# This file is part of acados.
#
# The 2-Clause BSD License
#
# Redistribution and use in source and binary forms, with or without
# modification, are permitted provided that the following conditions are met:
#
# 1. Redistributions of source code must retain the above copyright notice,
# this list of conditions and the following disclaimer.
#
# 2. Redistributions in binary form must reproduce the above copyright notice,
# this list of conditions and the following disclaimer in the documentation
# and/or other materials provided with the distribution.
#
# THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
# AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
# IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
# ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE
# LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
# CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
# SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
# INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
# CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
# ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
# POSSIBILITY OF SUCH DAMAGE.;
#
import sys , os , json
import numpy as np
from ctypes import *
from copy import deepcopy
from . generate_c_code_explicit_ode import generate_c_code_explicit_ode
from . generate_c_code_implicit_ode import generate_c_code_implicit_ode
from . generate_c_code_gnsf import generate_c_code_gnsf
from . acados_sim import AcadosSim
from . acados_ocp import AcadosOcp
from . acados_model import acados_model_strip_casadi_symbolics
from . utils import is_column , render_template , format_class_dict , np_array_to_list , \
make_model_consistent , set_up_imported_gnsf_model , get_python_interface_path
from . builders import CMakeBuilder
def make_sim_dims_consistent ( acados_sim ) :
dims = acados_sim . dims
model = acados_sim . model
# nx
if is_column ( model . x ) :
dims . nx = model . x . shape [ 0 ]
else :
raise Exception ( " model.x should be column vector! " )
# nu
if is_column ( model . u ) :
dims . nu = model . u . shape [ 0 ]
elif model . u == None or model . u == [ ] :
dims . nu = 0
else :
raise Exception ( " model.u should be column vector or None! " )
# nz
if is_column ( model . z ) :
dims . nz = model . z . shape [ 0 ]
elif model . z == None or model . z == [ ] :
dims . nz = 0
else :
raise Exception ( " model.z should be column vector or None! " )
# np
if is_column ( model . p ) :
dims . np = model . p . shape [ 0 ]
elif model . p == None or model . p == [ ] :
dims . np = 0
else :
raise Exception ( " model.p should be column vector or None! " )
def get_sim_layout ( ) :
python_interface_path = get_python_interface_path ( )
abs_path = os . path . join ( python_interface_path , ' acados_sim_layout.json ' )
with open ( abs_path , ' r ' ) as f :
sim_layout = json . load ( f )
return sim_layout
def sim_formulation_json_dump ( acados_sim , json_file = ' acados_sim.json ' ) :
# Load acados_sim structure description
sim_layout = get_sim_layout ( )
# Copy input sim object dictionary
sim_dict = dict ( deepcopy ( acados_sim ) . __dict__ )
for key , v in sim_layout . items ( ) :
# skip non dict attributes
if not isinstance ( v , dict ) : continue
# Copy sim object attributes dictionaries
sim_dict [ key ] = dict ( getattr ( acados_sim , key ) . __dict__ )
sim_dict [ ' model ' ] = acados_model_strip_casadi_symbolics ( sim_dict [ ' model ' ] )
sim_json = format_class_dict ( sim_dict )
with open ( json_file , ' w ' ) as f :
json . dump ( sim_json , f , default = np_array_to_list , indent = 4 , sort_keys = True )
def sim_get_default_cmake_builder ( ) - > CMakeBuilder :
"""
If : py : class : ` ~ acados_template . acados_sim_solver . AcadosSimSolver ` is used with ` CMake ` this function returns a good first setting .
: return : default : py : class : ` ~ acados_template . builders . CMakeBuilder `
"""
cmake_builder = CMakeBuilder ( )
cmake_builder . options_on = [ ' BUILD_ACADOS_SIM_SOLVER_LIB ' ]
return cmake_builder
def sim_render_templates ( json_file , model_name , code_export_dir , cmake_options : CMakeBuilder = None ) :
# setting up loader and environment
json_path = os . path . join ( os . getcwd ( ) , json_file )
if not os . path . exists ( json_path ) :
raise Exception ( f " { json_path } not found! " )
template_dir = code_export_dir
## Render templates
in_file = ' acados_sim_solver.in.c '
out_file = f ' acados_sim_solver_ { model_name } .c '
render_template ( in_file , out_file , template_dir , json_path )
in_file = ' acados_sim_solver.in.h '
out_file = f ' acados_sim_solver_ { model_name } .h '
render_template ( in_file , out_file , template_dir , json_path )
# Builder
if cmake_options is not None :
in_file = ' CMakeLists.in.txt '
out_file = ' CMakeLists.txt '
render_template ( in_file , out_file , template_dir , json_path )
else :
in_file = ' Makefile.in '
out_file = ' Makefile '
render_template ( in_file , out_file , template_dir , json_path )
in_file = ' main_sim.in.c '
out_file = f ' main_sim_ { model_name } .c '
render_template ( in_file , out_file , template_dir , json_path )
## folder model
template_dir = os . path . join ( code_export_dir , model_name + ' _model ' )
in_file = ' model.in.h '
out_file = f ' { model_name } _model.h '
render_template ( in_file , out_file , template_dir , json_path )
def sim_generate_casadi_functions ( acados_sim ) :
model = acados_sim . model
model = make_model_consistent ( model )
integrator_type = acados_sim . solver_options . integrator_type
opts = dict ( generate_hess = acados_sim . solver_options . sens_hess ,
code_export_directory = acados_sim . code_export_directory )
# generate external functions
if integrator_type == ' ERK ' :
generate_c_code_explicit_ode ( model , opts )
elif integrator_type == ' IRK ' :
generate_c_code_implicit_ode ( model , opts )
elif integrator_type == ' GNSF ' :
generate_c_code_gnsf ( model , opts )
class AcadosSimSolver :
"""
Class to interact with the acados integrator C object .
: param acados_sim : type : py : class : ` ~ acados_template . acados_ocp . AcadosOcp ` ( takes values to generate an instance : py : class : ` ~ acados_template . acados_sim . AcadosSim ` ) or : py : class : ` ~ acados_template . acados_sim . AcadosSim `
: param json_file : Default : ' acados_sim.json '
: param build : Default : True
: param cmake_builder : type : py : class : ` ~ acados_template . utils . CMakeBuilder ` generate a ` CMakeLists . txt ` and use
the ` CMake ` pipeline instead of a ` Makefile ` ( ` CMake ` seems to be the better option in conjunction with
` MS Visual Studio ` ) ; default : ` None `
"""
def __init__ ( self , acados_sim_ , json_file = ' acados_sim.json ' , build = True , cmake_builder : CMakeBuilder = None ) :
self . solver_created = False
if isinstance ( acados_sim_ , AcadosOcp ) :
# set up acados_sim_
acados_sim = AcadosSim ( )
acados_sim . model = acados_sim_ . model
acados_sim . dims . nx = acados_sim_ . dims . nx
acados_sim . dims . nu = acados_sim_ . dims . nu
acados_sim . dims . nz = acados_sim_ . dims . nz
acados_sim . dims . np = acados_sim_ . dims . np
acados_sim . solver_options . integrator_type = acados_sim_ . solver_options . integrator_type
acados_sim . code_export_directory = acados_sim_ . code_export_directory
elif isinstance ( acados_sim_ , AcadosSim ) :
acados_sim = acados_sim_
acados_sim . __problem_class = ' SIM '
model_name = acados_sim . model . name
make_sim_dims_consistent ( acados_sim )
# reuse existing json and casadi functions, when creating integrator from ocp
if isinstance ( acados_sim_ , AcadosSim ) :
if acados_sim . solver_options . integrator_type == ' GNSF ' :
set_up_imported_gnsf_model ( acados_sim )
sim_generate_casadi_functions ( acados_sim )
sim_formulation_json_dump ( acados_sim , json_file )
code_export_dir = acados_sim . code_export_directory
if build :
# render templates
sim_render_templates ( json_file , model_name , code_export_dir , cmake_builder )
# Compile solver
cwd = os . getcwd ( )
code_export_dir = os . path . abspath ( code_export_dir )
os . chdir ( code_export_dir )
if cmake_builder is not None :
cmake_builder . exec ( code_export_dir )
else :
os . system ( ' make sim_shared_lib ' )
os . chdir ( cwd )
self . sim_struct = acados_sim
model_name = self . sim_struct . model . name
self . model_name = model_name
# Load acados library to avoid unloading the library.
# This is necessary if acados was compiled with OpenMP, since the OpenMP threads can't be destroyed.
# Unloading a library which uses OpenMP results in a segfault (on any platform?).
# see [https://stackoverflow.com/questions/34439956/vc-crash-when-freeing-a-dll-built-with-openmp]
# or [https://python.hotexamples.com/examples/_ctypes/-/dlclose/python-dlclose-function-examples.html]
libacados_name = ' libacados.so '
libacados_filepath = os . path . join ( acados_sim . acados_lib_path , libacados_name )
self . __acados_lib = CDLL ( libacados_filepath )
# find out if acados was compiled with OpenMP
try :
self . __acados_lib_uses_omp = getattr ( self . __acados_lib , ' omp_get_thread_num ' ) is not None
except AttributeError as e :
self . __acados_lib_uses_omp = False
if self . __acados_lib_uses_omp :
print ( ' acados was compiled with OpenMP. ' )
else :
print ( ' acados was compiled without OpenMP. ' )
# Ctypes
lib_prefix = ' lib '
lib_ext = ' .so '
if os . name == ' nt ' :
lib_prefix = ' '
lib_ext = ' '
self . shared_lib_name = os . path . join ( code_export_dir , f ' { lib_prefix } acados_sim_solver_ { model_name } { lib_ext } ' )
print ( f ' self.shared_lib_name = " { self . shared_lib_name } " ' )
self . shared_lib = CDLL ( self . shared_lib_name )
# create capsule
getattr ( self . shared_lib , f " { model_name } _acados_sim_solver_create_capsule " ) . restype = c_void_p
self . capsule = getattr ( self . shared_lib , f " { model_name } _acados_sim_solver_create_capsule " ) ( )
# create solver
getattr ( self . shared_lib , f " { model_name } _acados_sim_create " ) . argtypes = [ c_void_p ]
getattr ( self . shared_lib , f " { model_name } _acados_sim_create " ) . restype = c_int
assert getattr ( self . shared_lib , f " { model_name } _acados_sim_create " ) ( self . capsule ) == 0
self . solver_created = True
getattr ( self . shared_lib , f " { model_name } _acados_get_sim_opts " ) . argtypes = [ c_void_p ]
getattr ( self . shared_lib , f " { model_name } _acados_get_sim_opts " ) . restype = c_void_p
self . sim_opts = getattr ( self . shared_lib , f " { model_name } _acados_get_sim_opts " ) ( self . capsule )
getattr ( self . shared_lib , f " { model_name } _acados_get_sim_dims " ) . argtypes = [ c_void_p ]
getattr ( self . shared_lib , f " { model_name } _acados_get_sim_dims " ) . restype = c_void_p
self . sim_dims = getattr ( self . shared_lib , f " { model_name } _acados_get_sim_dims " ) ( self . capsule )
getattr ( self . shared_lib , f " { model_name } _acados_get_sim_config " ) . argtypes = [ c_void_p ]
getattr ( self . shared_lib , f " { model_name } _acados_get_sim_config " ) . restype = c_void_p
self . sim_config = getattr ( self . shared_lib , f " { model_name } _acados_get_sim_config " ) ( self . capsule )
getattr ( self . shared_lib , f " { model_name } _acados_get_sim_out " ) . argtypes = [ c_void_p ]
getattr ( self . shared_lib , f " { model_name } _acados_get_sim_out " ) . restype = c_void_p
self . sim_out = getattr ( self . shared_lib , f " { model_name } _acados_get_sim_out " ) ( self . capsule )
getattr ( self . shared_lib , f " { model_name } _acados_get_sim_in " ) . argtypes = [ c_void_p ]
getattr ( self . shared_lib , f " { model_name } _acados_get_sim_in " ) . restype = c_void_p
self . sim_in = getattr ( self . shared_lib , f " { model_name } _acados_get_sim_in " ) ( self . capsule )
getattr ( self . shared_lib , f " { model_name } _acados_get_sim_solver " ) . argtypes = [ c_void_p ]
getattr ( self . shared_lib , f " { model_name } _acados_get_sim_solver " ) . restype = c_void_p
self . sim_solver = getattr ( self . shared_lib , f " { model_name } _acados_get_sim_solver " ) ( self . capsule )
nu = self . sim_struct . dims . nu
nx = self . sim_struct . dims . nx
nz = self . sim_struct . dims . nz
self . gettable = {
' x ' : nx ,
' xn ' : nx ,
' u ' : nu ,
' z ' : nz ,
' S_forw ' : nx * ( nx + nu ) ,
' Sx ' : nx * nx ,
' Su ' : nx * nu ,
' S_adj ' : nx + nu ,
' S_hess ' : ( nx + nu ) * ( nx + nu ) ,
' S_algebraic ' : ( nz ) * ( nx + nu ) ,
}
self . settable = [ ' S_adj ' , ' T ' , ' x ' , ' u ' , ' xdot ' , ' z ' , ' p ' ] # S_forw
def solve ( self ) :
"""
Solve the simulation problem with current input .
"""
getattr ( self . shared_lib , f " { self . model_name } _acados_sim_solve " ) . argtypes = [ c_void_p ]
getattr ( self . shared_lib , f " { self . model_name } _acados_sim_solve " ) . restype = c_int
status = getattr ( self . shared_lib , f " { self . model_name } _acados_sim_solve " ) ( self . capsule )
return status
def get ( self , field_ ) :
"""
Get the last solution of the solver .
: param str field : string in [ ' x ' , ' u ' , ' z ' , ' S_forw ' , ' Sx ' , ' Su ' , ' S_adj ' , ' S_hess ' , ' S_algebraic ' ]
"""
field = field_
field = field . encode ( ' utf-8 ' )
if field_ in self . gettable . keys ( ) :
# allocate array
dims = self . gettable [ field_ ]
out = np . ascontiguousarray ( np . zeros ( ( dims , ) ) , dtype = np . float64 )
out_data = cast ( out . ctypes . data , POINTER ( c_double ) )
self . shared_lib . sim_out_get . argtypes = [ c_void_p , c_void_p , c_void_p , c_char_p , c_void_p ]
self . shared_lib . sim_out_get ( self . sim_config , self . sim_dims , self . sim_out , field , out_data )
if field_ == ' S_forw ' :
nu = self . sim_struct . dims . nu
nx = self . sim_struct . dims . nx
out = out . reshape ( nx , nx + nu , order = ' F ' )
elif field_ == ' Sx ' :
nx = self . sim_struct . dims . nx
out = out . reshape ( nx , nx , order = ' F ' )
elif field_ == ' Su ' :
nx = self . sim_struct . dims . nx
nu = self . sim_struct . dims . nu
out = out . reshape ( nx , nu , order = ' F ' )
elif field_ == ' S_hess ' :
nx = self . sim_struct . dims . nx
nu = self . sim_struct . dims . nu
out = out . reshape ( nx + nu , nx + nu , order = ' F ' )
elif field_ == ' S_algebraic ' :
nx = self . sim_struct . dims . nx
nu = self . sim_struct . dims . nu
nz = self . sim_struct . dims . nz
out = out . reshape ( nz , nx + nu , order = ' F ' )
else :
raise Exception ( f ' AcadosSimSolver.get(): Unknown field { field_ } , ' \
f ' available fields are { " , " . join ( self . gettable . keys ( ) ) } ' )
return out
def set ( self , field_ , value_ ) :
"""
Set numerical data inside the solver .
: param field : string in [ ' p ' , ' S_adj ' , ' T ' , ' x ' , ' u ' , ' xdot ' , ' z ' ]
: param value : the value with appropriate size .
"""
# cast value_ to avoid conversion issues
if isinstance ( value_ , ( float , int ) ) :
value_ = np . array ( [ value_ ] )
value_ = value_ . astype ( float )
value_data = cast ( value_ . ctypes . data , POINTER ( c_double ) )
value_data_p = cast ( ( value_data ) , c_void_p )
field = field_
field = field . encode ( ' utf-8 ' )
# treat parameters separately
if field_ == ' p ' :
model_name = self . sim_struct . model . name
getattr ( self . shared_lib , f " { model_name } _acados_sim_update_params " ) . argtypes = [ c_void_p , POINTER ( c_double ) , c_int ]
value_data = cast ( value_ . ctypes . data , POINTER ( c_double ) )
getattr ( self . shared_lib , f " { model_name } _acados_sim_update_params " ) ( self . capsule , value_data , value_ . shape [ 0 ] )
return
else :
# dimension check
dims = np . ascontiguousarray ( np . zeros ( ( 2 , ) ) , dtype = np . intc )
dims_data = cast ( dims . ctypes . data , POINTER ( c_int ) )
self . shared_lib . sim_dims_get_from_attr . argtypes = [ c_void_p , c_void_p , c_char_p , POINTER ( c_int ) ]
self . shared_lib . sim_dims_get_from_attr ( self . sim_config , self . sim_dims , field , dims_data )
value_ = np . ravel ( value_ , order = ' F ' )
value_shape = value_ . shape
if len ( value_shape ) == 1 :
value_shape = ( value_shape [ 0 ] , 0 )
if value_shape != tuple ( dims ) :
raise Exception ( ' AcadosSimSolver.set(): mismatching dimension ' \
' for field " {} " with dimension {} (you have {} ) ' . format ( field_ , tuple ( dims ) , value_shape ) )
# set
if field_ in [ ' xdot ' , ' z ' ] :
self . shared_lib . sim_solver_set . argtypes = [ c_void_p , c_char_p , c_void_p ]
self . shared_lib . sim_solver_set ( self . sim_solver , field , value_data_p )
elif field_ in self . settable :
self . shared_lib . sim_in_set . argtypes = [ c_void_p , c_void_p , c_void_p , c_char_p , c_void_p ]
self . shared_lib . sim_in_set ( self . sim_config , self . sim_dims , self . sim_in , field , value_data_p )
else :
raise Exception ( f ' AcadosSimSolver.set(): Unknown field { field_ } , ' \
f ' available fields are { " , " . join ( self . settable ) } ' )
return
def __del__ ( self ) :
if self . solver_created :
getattr ( self . shared_lib , f " { self . model_name } _acados_sim_free " ) . argtypes = [ c_void_p ]
getattr ( self . shared_lib , f " { self . model_name } _acados_sim_free " ) . restype = c_int
getattr ( self . shared_lib , f " { self . model_name } _acados_sim_free " ) ( self . capsule )
getattr ( self . shared_lib , f " { self . model_name } _acados_sim_solver_free_capsule " ) . argtypes = [ c_void_p ]
getattr ( self . shared_lib , f " { self . model_name } _acados_sim_solver_free_capsule " ) . restype = c_int
getattr ( self . shared_lib , f " { self . model_name } _acados_sim_solver_free_capsule " ) ( self . capsule )
try :
self . dlclose ( self . shared_lib . _handle )
except :
pass
