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"This module provides functionality for compilation of strings as dolfin Expressions."

# Copyright (C) 2008-2008 Martin Sandve Alnes
#
# This file is part of DOLFIN.
#
# DOLFIN is free software: you can redistribute it and/or modify
# it under the terms of the GNU Lesser General Public License as published by
# the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# DOLFIN is distributed in the hope that it will be useful,
# but WITHOUT ANY WARRANTY; without even the implied warranty of
# MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
# GNU Lesser General Public License for more details.
#
# You should have received a copy of the GNU Lesser General Public License
# along with DOLFIN. If not, see <http://www.gnu.org/licenses/>.
#
# Modified by Johan Hake 2008-2009
#
# First added:  2008-06-04
# Last changed: 2011-04-18

import re
import types
import hashlib
import instant

# Import local compile_extension_module
from dolfin.compilemodules.compilemodule import (compile_extension_module,
                                                 expression_to_code_fragments,
                                                 math_header)

__all__ = ["compile_expressions"]

_expression_template = """
class %(classname)s: public Expression
{
public:
%(members)s
  %(classname)s():Expression()
  {
%(value_shape)s
%(constructor)s
  }

  void eval(dolfin::Array<double>& values, const dolfin::Array<double>& x) const
  {
%(evalcode)s
  }
};
"""

def flatten_and_check_expression(expr):
    # Convert expr to a flat tuple of strings
    # and return value_shape and geometrical dimensions
    if isinstance(expr, str):
        return (expr,), ()
    elif isinstance(expr, (tuple,list)):
        if all(isinstance(e,tuple) for e in expr):
            shape = (len(expr),len(expr[0]))
            expr = sum(expr, ())
        else:
            shape = (len(expr),)
        if all(isinstance(e,str) for e in expr):
            return expr, shape
    raise TypeError, "Wrong type of expressions. Provide a 'str', a 'tuple' of 'str' or a 'tuple' of 'tuple' of 'str': %s" % str(expr)

def expression_to_dolfin_expression(expr):
    "Generates code for a dolfin::Expression subclass for a single expression."

    # Check and flattern provided expression
    expr, shape = flatten_and_check_expression(expr)
    
    # Extract code fragments from the expr
    fragments, members = expression_to_code_fragments(expr, ["v","x"])
    
    # Generate code for value_rank
    value_shape_code = ""
    for value_dim in shape:
        value_shape_code += "    value_shape.push_back(%d);\n"%value_dim

    # Generate code for the actual expression evaluation
    evalcode = "\n".join("    values[%d] = %s;" % (i, c) for (i,c) in enumerate(expr))

    # Assign classname
    classname = "Expression_" + hashlib.md5(evalcode).hexdigest()

    # Connect the code fragments using the expression template code
    fragments["classname"] = classname
    fragments["evalcode"]  = evalcode
    fragments["value_shape"] = value_shape_code

    # Produce the C++ code for the expression class
    code = _expression_template % fragments
    return classname, code, members


def compile_expression_code(code, classnames = None, module_name = None):

    # Autodetect classnames:
    _classnames = re.findall(r"class[ ]+([\w]+).*", code)

    # Just a little assertion for safety:
    if classnames is None:
        classnames = _classnames
    else:
        assert all(a == b for (a,b) in zip(classnames, _classnames))

    # Complete the code
    code = """
%s

namespace dolfin
{

%s

}
"""%(math_header, code)

    # Compile the extension module
    compiled_module = compile_extension_module(\
                             code,
                             dolfin_module_import=["function", "mesh", "common"])

    # Get the compiled class
    expression_classes = [getattr(compiled_module, name) for name in classnames]
    return expression_classes

def compile_expressions(cppargs):
    """Compiles a tuple of C++ expressions into a dolfin::Expression class.

    If 'cppexpr' is True, 'expression' is interpreted as c++ expressions, that
    will be used to construct an Expression class.

    The expression can either be a str in which case it is
    interpreted as a scalar expression and a scalar Expression is generated.

    If the expression is a tuple consisting of more than one str it is
    interpreted as a vector expression, and a rank 1 Expression is generated.

    A tuple of tuples of str objects is interpreted as a matrix
    expression, and a rank 2 Expression is generated.

    If an expression string contains a name, it is assumed to be a scalar
    parameter name, and is added as a public member of the generated expression.
    The names of these parameters are then returned in a list together with the
    compiled expression class.

    If 'cppexpr' is True, 'expression' is interpreted as c++ code with complete
    implementations of a subclasses of dolfin::Expression.
    """
    #, which contains:
    #    %s
    #""" % "\n".join("        " + b for b in _builtins)
    # FIXME: Hook up this to a more general debug mechanism
    assert(isinstance(cppargs, list))
    
    # Check for uniq sub expressions
    if len(set(hashlib.md5(repr(expr)) for expr in cppargs)) \
               != len(cppargs):
        raise TypeError, "The batch-compiled expressions must be unique."
    
    # Collect code and classnames
    code_snippets = []; classnames = []; all_members = []
    for cpparg in cppargs:
        assert(isinstance(cpparg, (str, tuple, list)))
        # If the cpparg includes the word 'class' and 'Expression',
        # assume it is a c++ code snippet
        if isinstance(cpparg, str) and "class" in cpparg and "Expression" in cpparg:
            # Assume that a code snippet is passed as cpparg
            code = cpparg
            
            # Get the class name
            classname = re.findall(r"class[ ]+([\w]+).*", code)[0]
            members = []
            
            # FIXME: Check for passed dimension?
        else:
            classname, code, members = expression_to_dolfin_expression(cpparg)
        all_members.append(members)
        code_snippets.append(code)
        classnames.append(classname)

    expression_classes = compile_expression_code("\n\n".join(\
        code_snippets), classnames)

    return expression_classes, all_members

if __name__ == "__main__":
    cn1, code1 = expression_to_dolfin_expression("exp(alpha)",{'alpha':1.5})
    cn2, code2 = expression_to_dolfin_expression(("sin(x[0])", "cos(x[1])", "0.0"),{})
    cn3, code3 = expression_to_dolfin_expression((("sin(x[0])", "cos(x[1])"), ("0.0", "1.0")),{})

    print code1
    print cn1

    print code2
    print cn2

    print code3
    print cn3