/
codegen.py
2236 lines (1780 loc) · 79.6 KB
/
codegen.py
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"""
module for generating C, C++, Fortran77, Fortran90, Julia, Rust
and Octave/Matlab routines that evaluate SymPy expressions.
This module is work in progress.
Only the milestones with a '+' character in the list below have been completed.
--- How is sympy.utilities.codegen different from sympy.printing.ccode? ---
We considered the idea to extend the printing routines for SymPy functions in
such a way that it prints complete compilable code, but this leads to a few
unsurmountable issues that can only be tackled with dedicated code generator:
- For C, one needs both a code and a header file, while the printing routines
generate just one string. This code generator can be extended to support
.pyf files for f2py.
- SymPy functions are not concerned with programming-technical issues, such
as input, output and input-output arguments. Other examples are contiguous
or non-contiguous arrays, including headers of other libraries such as gsl
or others.
- It is highly interesting to evaluate several SymPy functions in one C
routine, eventually sharing common intermediate results with the help
of the cse routine. This is more than just printing.
- From the programming perspective, expressions with constants should be
evaluated in the code generator as much as possible. This is different
for printing.
--- Basic assumptions ---
* A generic Routine data structure describes the routine that must be
translated into C/Fortran/... code. This data structure covers all
features present in one or more of the supported languages.
* Descendants from the CodeGen class transform multiple Routine instances
into compilable code. Each derived class translates into a specific
language.
* In many cases, one wants a simple workflow. The friendly functions in the
last part are a simple api on top of the Routine/CodeGen stuff. They are
easier to use, but are less powerful.
--- Milestones ---
+ First working version with scalar input arguments, generating C code,
tests
+ Friendly functions that are easier to use than the rigorous
Routine/CodeGen workflow.
+ Integer and Real numbers as input and output
+ Output arguments
+ InputOutput arguments
+ Sort input/output arguments properly
+ Contiguous array arguments (numpy matrices)
+ Also generate .pyf code for f2py (in autowrap module)
+ Isolate constants and evaluate them beforehand in double precision
+ Fortran 90
+ Octave/Matlab
- Common Subexpression Elimination
- User defined comments in the generated code
- Optional extra include lines for libraries/objects that can eval special
functions
- Test other C compilers and libraries: gcc, tcc, libtcc, gcc+gsl, ...
- Contiguous array arguments (SymPy matrices)
- Non-contiguous array arguments (SymPy matrices)
- ccode must raise an error when it encounters something that cannot be
translated into c. ccode(integrate(sin(x)/x, x)) does not make sense.
- Complex numbers as input and output
- A default complex datatype
- Include extra information in the header: date, user, hostname, sha1
hash, ...
- Fortran 77
- C++
- Python
- Julia
- Rust
- ...
"""
import os
import textwrap
from io import StringIO
from sympy import __version__ as sympy_version
from sympy.core import Symbol, S, Tuple, Equality, Function, Basic
from sympy.printing.c import c_code_printers
from sympy.printing.codeprinter import AssignmentError
from sympy.printing.fortran import FCodePrinter
from sympy.printing.julia import JuliaCodePrinter
from sympy.printing.octave import OctaveCodePrinter
from sympy.printing.rust import RustCodePrinter
from sympy.tensor import Idx, Indexed, IndexedBase
from sympy.matrices import (MatrixSymbol, ImmutableMatrix, MatrixBase,
MatrixExpr, MatrixSlice)
from sympy.utilities.iterables import is_sequence
__all__ = [
# description of routines
"Routine", "DataType", "default_datatypes", "get_default_datatype",
"Argument", "InputArgument", "OutputArgument", "Result",
# routines -> code
"CodeGen", "CCodeGen", "FCodeGen", "JuliaCodeGen", "OctaveCodeGen",
"RustCodeGen",
# friendly functions
"codegen", "make_routine",
]
#
# Description of routines
#
class Routine:
"""Generic description of evaluation routine for set of expressions.
A CodeGen class can translate instances of this class into code in a
particular language. The routine specification covers all the features
present in these languages. The CodeGen part must raise an exception
when certain features are not present in the target language. For
example, multiple return values are possible in Python, but not in C or
Fortran. Another example: Fortran and Python support complex numbers,
while C does not.
"""
def __init__(self, name, arguments, results, local_vars, global_vars):
"""Initialize a Routine instance.
Parameters
==========
name : string
Name of the routine.
arguments : list of Arguments
These are things that appear in arguments of a routine, often
appearing on the right-hand side of a function call. These are
commonly InputArguments but in some languages, they can also be
OutputArguments or InOutArguments (e.g., pass-by-reference in C
code).
results : list of Results
These are the return values of the routine, often appearing on
the left-hand side of a function call. The difference between
Results and OutputArguments and when you should use each is
language-specific.
local_vars : list of Results
These are variables that will be defined at the beginning of the
function.
global_vars : list of Symbols
Variables which will not be passed into the function.
"""
# extract all input symbols and all symbols appearing in an expression
input_symbols = set()
symbols = set()
for arg in arguments:
if isinstance(arg, OutputArgument):
symbols.update(arg.expr.free_symbols - arg.expr.atoms(Indexed))
elif isinstance(arg, InputArgument):
input_symbols.add(arg.name)
elif isinstance(arg, InOutArgument):
input_symbols.add(arg.name)
symbols.update(arg.expr.free_symbols - arg.expr.atoms(Indexed))
else:
raise ValueError("Unknown Routine argument: %s" % arg)
for r in results:
if not isinstance(r, Result):
raise ValueError("Unknown Routine result: %s" % r)
symbols.update(r.expr.free_symbols - r.expr.atoms(Indexed))
local_symbols = set()
for r in local_vars:
if isinstance(r, Result):
symbols.update(r.expr.free_symbols - r.expr.atoms(Indexed))
local_symbols.add(r.name)
else:
local_symbols.add(r)
symbols = {s.label if isinstance(s, Idx) else s for s in symbols}
# Check that all symbols in the expressions are covered by
# InputArguments/InOutArguments---subset because user could
# specify additional (unused) InputArguments or local_vars.
notcovered = symbols.difference(
input_symbols.union(local_symbols).union(global_vars))
if notcovered != set():
raise ValueError("Symbols needed for output are not in input " +
", ".join([str(x) for x in notcovered]))
self.name = name
self.arguments = arguments
self.results = results
self.local_vars = local_vars
self.global_vars = global_vars
def __str__(self):
return self.__class__.__name__ + "({name!r}, {arguments}, {results}, {local_vars}, {global_vars})".format(**self.__dict__)
__repr__ = __str__
@property
def variables(self):
"""Returns a set of all variables possibly used in the routine.
For routines with unnamed return values, the dummies that may or
may not be used will be included in the set.
"""
v = set(self.local_vars)
for arg in self.arguments:
v.add(arg.name)
for res in self.results:
v.add(res.result_var)
return v
@property
def result_variables(self):
"""Returns a list of OutputArgument, InOutArgument and Result.
If return values are present, they are at the end of the list.
"""
args = [arg for arg in self.arguments if isinstance(
arg, (OutputArgument, InOutArgument))]
args.extend(self.results)
return args
class DataType:
"""Holds strings for a certain datatype in different languages."""
def __init__(self, cname, fname, pyname, jlname, octname, rsname):
self.cname = cname
self.fname = fname
self.pyname = pyname
self.jlname = jlname
self.octname = octname
self.rsname = rsname
default_datatypes = {
"int": DataType("int", "INTEGER*4", "int", "", "", "i32"),
"float": DataType("double", "REAL*8", "float", "", "", "f64"),
"complex": DataType("double", "COMPLEX*16", "complex", "", "", "float") #FIXME:
# complex is only supported in fortran, python, julia, and octave.
# So to not break c or rust code generation, we stick with double or
# float, respectively (but actually should raise an exception for
# explicitly complex variables (x.is_complex==True))
}
COMPLEX_ALLOWED = False
def get_default_datatype(expr, complex_allowed=None):
"""Derives an appropriate datatype based on the expression."""
if complex_allowed is None:
complex_allowed = COMPLEX_ALLOWED
if complex_allowed:
final_dtype = "complex"
else:
final_dtype = "float"
if expr.is_integer:
return default_datatypes["int"]
elif expr.is_real:
return default_datatypes["float"]
elif isinstance(expr, MatrixBase):
#check all entries
dt = "int"
for element in expr:
if dt == "int" and not element.is_integer:
dt = "float"
if dt == "float" and not element.is_real:
return default_datatypes[final_dtype]
return default_datatypes[dt]
else:
return default_datatypes[final_dtype]
class Variable:
"""Represents a typed variable."""
def __init__(self, name, datatype=None, dimensions=None, precision=None):
"""Return a new variable.
Parameters
==========
name : Symbol or MatrixSymbol
datatype : optional
When not given, the data type will be guessed based on the
assumptions on the symbol argument.
dimension : sequence containing tupes, optional
If present, the argument is interpreted as an array, where this
sequence of tuples specifies (lower, upper) bounds for each
index of the array.
precision : int, optional
Controls the precision of floating point constants.
"""
if not isinstance(name, (Symbol, MatrixSymbol)):
raise TypeError("The first argument must be a SymPy symbol.")
if datatype is None:
datatype = get_default_datatype(name)
elif not isinstance(datatype, DataType):
raise TypeError("The (optional) `datatype' argument must be an "
"instance of the DataType class.")
if dimensions and not isinstance(dimensions, (tuple, list)):
raise TypeError(
"The dimension argument must be a sequence of tuples")
self._name = name
self._datatype = {
'C': datatype.cname,
'FORTRAN': datatype.fname,
'JULIA': datatype.jlname,
'OCTAVE': datatype.octname,
'PYTHON': datatype.pyname,
'RUST': datatype.rsname,
}
self.dimensions = dimensions
self.precision = precision
def __str__(self):
return "%s(%r)" % (self.__class__.__name__, self.name)
__repr__ = __str__
@property
def name(self):
return self._name
def get_datatype(self, language):
"""Returns the datatype string for the requested language.
Examples
========
>>> from sympy import Symbol
>>> from sympy.utilities.codegen import Variable
>>> x = Variable(Symbol('x'))
>>> x.get_datatype('c')
'double'
>>> x.get_datatype('fortran')
'REAL*8'
"""
try:
return self._datatype[language.upper()]
except KeyError:
raise CodeGenError("Has datatypes for languages: %s" %
", ".join(self._datatype))
class Argument(Variable):
"""An abstract Argument data structure: a name and a data type.
This structure is refined in the descendants below.
"""
pass
class InputArgument(Argument):
pass
class ResultBase:
"""Base class for all "outgoing" information from a routine.
Objects of this class stores a SymPy expression, and a SymPy object
representing a result variable that will be used in the generated code
only if necessary.
"""
def __init__(self, expr, result_var):
self.expr = expr
self.result_var = result_var
def __str__(self):
return "%s(%r, %r)" % (self.__class__.__name__, self.expr,
self.result_var)
__repr__ = __str__
class OutputArgument(Argument, ResultBase):
"""OutputArgument are always initialized in the routine."""
def __init__(self, name, result_var, expr, datatype=None, dimensions=None, precision=None):
"""Return a new variable.
Parameters
==========
name : Symbol, MatrixSymbol
The name of this variable. When used for code generation, this
might appear, for example, in the prototype of function in the
argument list.
result_var : Symbol, Indexed
Something that can be used to assign a value to this variable.
Typically the same as `name` but for Indexed this should be e.g.,
"y[i]" whereas `name` should be the Symbol "y".
expr : object
The expression that should be output, typically a SymPy
expression.
datatype : optional
When not given, the data type will be guessed based on the
assumptions on the symbol argument.
dimension : sequence containing tupes, optional
If present, the argument is interpreted as an array, where this
sequence of tuples specifies (lower, upper) bounds for each
index of the array.
precision : int, optional
Controls the precision of floating point constants.
"""
Argument.__init__(self, name, datatype, dimensions, precision)
ResultBase.__init__(self, expr, result_var)
def __str__(self):
return "%s(%r, %r, %r)" % (self.__class__.__name__, self.name, self.result_var, self.expr)
__repr__ = __str__
class InOutArgument(Argument, ResultBase):
"""InOutArgument are never initialized in the routine."""
def __init__(self, name, result_var, expr, datatype=None, dimensions=None, precision=None):
if not datatype:
datatype = get_default_datatype(expr)
Argument.__init__(self, name, datatype, dimensions, precision)
ResultBase.__init__(self, expr, result_var)
__init__.__doc__ = OutputArgument.__init__.__doc__
def __str__(self):
return "%s(%r, %r, %r)" % (self.__class__.__name__, self.name, self.expr,
self.result_var)
__repr__ = __str__
class Result(Variable, ResultBase):
"""An expression for a return value.
The name result is used to avoid conflicts with the reserved word
"return" in the Python language. It is also shorter than ReturnValue.
These may or may not need a name in the destination (e.g., "return(x*y)"
might return a value without ever naming it).
"""
def __init__(self, expr, name=None, result_var=None, datatype=None,
dimensions=None, precision=None):
"""Initialize a return value.
Parameters
==========
expr : SymPy expression
name : Symbol, MatrixSymbol, optional
The name of this return variable. When used for code generation,
this might appear, for example, in the prototype of function in a
list of return values. A dummy name is generated if omitted.
result_var : Symbol, Indexed, optional
Something that can be used to assign a value to this variable.
Typically the same as `name` but for Indexed this should be e.g.,
"y[i]" whereas `name` should be the Symbol "y". Defaults to
`name` if omitted.
datatype : optional
When not given, the data type will be guessed based on the
assumptions on the expr argument.
dimension : sequence containing tupes, optional
If present, this variable is interpreted as an array,
where this sequence of tuples specifies (lower, upper)
bounds for each index of the array.
precision : int, optional
Controls the precision of floating point constants.
"""
# Basic because it is the base class for all types of expressions
if not isinstance(expr, (Basic, MatrixBase)):
raise TypeError("The first argument must be a SymPy expression.")
if name is None:
name = 'result_%d' % abs(hash(expr))
if datatype is None:
#try to infer data type from the expression
datatype = get_default_datatype(expr)
if isinstance(name, str):
if isinstance(expr, (MatrixBase, MatrixExpr)):
name = MatrixSymbol(name, *expr.shape)
else:
name = Symbol(name)
if result_var is None:
result_var = name
Variable.__init__(self, name, datatype=datatype,
dimensions=dimensions, precision=precision)
ResultBase.__init__(self, expr, result_var)
def __str__(self):
return "%s(%r, %r, %r)" % (self.__class__.__name__, self.expr, self.name,
self.result_var)
__repr__ = __str__
#
# Transformation of routine objects into code
#
class CodeGen:
"""Abstract class for the code generators."""
printer = None # will be set to an instance of a CodePrinter subclass
def _indent_code(self, codelines):
return self.printer.indent_code(codelines)
def _printer_method_with_settings(self, method, settings=None, *args, **kwargs):
settings = settings or {}
ori = {k: self.printer._settings[k] for k in settings}
for k, v in settings.items():
self.printer._settings[k] = v
result = getattr(self.printer, method)(*args, **kwargs)
for k, v in ori.items():
self.printer._settings[k] = v
return result
def _get_symbol(self, s):
"""Returns the symbol as fcode prints it."""
if self.printer._settings['human']:
expr_str = self.printer.doprint(s)
else:
constants, not_supported, expr_str = self.printer.doprint(s)
if constants or not_supported:
raise ValueError("Failed to print %s" % str(s))
return expr_str.strip()
def __init__(self, project="project", cse=False):
"""Initialize a code generator.
Derived classes will offer more options that affect the generated
code.
"""
self.project = project
self.cse = cse
def routine(self, name, expr, argument_sequence=None, global_vars=None):
"""Creates an Routine object that is appropriate for this language.
This implementation is appropriate for at least C/Fortran. Subclasses
can override this if necessary.
Here, we assume at most one return value (the l-value) which must be
scalar. Additional outputs are OutputArguments (e.g., pointers on
right-hand-side or pass-by-reference). Matrices are always returned
via OutputArguments. If ``argument_sequence`` is None, arguments will
be ordered alphabetically, but with all InputArguments first, and then
OutputArgument and InOutArguments.
"""
if self.cse:
from sympy.simplify.cse_main import cse
if is_sequence(expr) and not isinstance(expr, (MatrixBase, MatrixExpr)):
if not expr:
raise ValueError("No expression given")
for e in expr:
if not e.is_Equality:
raise CodeGenError("Lists of expressions must all be Equalities. {} is not.".format(e))
# create a list of right hand sides and simplify them
rhs = [e.rhs for e in expr]
common, simplified = cse(rhs)
# pack the simplified expressions back up with their left hand sides
expr = [Equality(e.lhs, rhs) for e, rhs in zip(expr, simplified)]
else:
if isinstance(expr, Equality):
common, simplified = cse(expr.rhs) #, ignore=in_out_args)
expr = Equality(expr.lhs, simplified[0])
else:
common, simplified = cse(expr)
expr = simplified
local_vars = [Result(b,a) for a,b in common]
local_symbols = {a for a,_ in common}
local_expressions = Tuple(*[b for _,b in common])
else:
local_expressions = Tuple()
if is_sequence(expr) and not isinstance(expr, (MatrixBase, MatrixExpr)):
if not expr:
raise ValueError("No expression given")
expressions = Tuple(*expr)
else:
expressions = Tuple(expr)
if self.cse:
if {i.label for i in expressions.atoms(Idx)} != set():
raise CodeGenError("CSE and Indexed expressions do not play well together yet")
else:
# local variables for indexed expressions
local_vars = {i.label for i in expressions.atoms(Idx)}
local_symbols = local_vars
# global variables
global_vars = set() if global_vars is None else set(global_vars)
# symbols that should be arguments
symbols = (expressions.free_symbols | local_expressions.free_symbols) - local_symbols - global_vars
new_symbols = set()
new_symbols.update(symbols)
for symbol in symbols:
if isinstance(symbol, Idx):
new_symbols.remove(symbol)
new_symbols.update(symbol.args[1].free_symbols)
if isinstance(symbol, Indexed):
new_symbols.remove(symbol)
symbols = new_symbols
# Decide whether to use output argument or return value
return_val = []
output_args = []
for expr in expressions:
if isinstance(expr, Equality):
out_arg = expr.lhs
expr = expr.rhs
if isinstance(out_arg, Indexed):
dims = tuple([ (S.Zero, dim - 1) for dim in out_arg.shape])
symbol = out_arg.base.label
elif isinstance(out_arg, Symbol):
dims = []
symbol = out_arg
elif isinstance(out_arg, MatrixSymbol):
dims = tuple([ (S.Zero, dim - 1) for dim in out_arg.shape])
symbol = out_arg
else:
raise CodeGenError("Only Indexed, Symbol, or MatrixSymbol "
"can define output arguments.")
if expr.has(symbol):
output_args.append(
InOutArgument(symbol, out_arg, expr, dimensions=dims))
else:
output_args.append(
OutputArgument(symbol, out_arg, expr, dimensions=dims))
# remove duplicate arguments when they are not local variables
if symbol not in local_vars:
# avoid duplicate arguments
symbols.remove(symbol)
elif isinstance(expr, (ImmutableMatrix, MatrixSlice)):
# Create a "dummy" MatrixSymbol to use as the Output arg
out_arg = MatrixSymbol('out_%s' % abs(hash(expr)), *expr.shape)
dims = tuple([(S.Zero, dim - 1) for dim in out_arg.shape])
output_args.append(
OutputArgument(out_arg, out_arg, expr, dimensions=dims))
else:
return_val.append(Result(expr))
arg_list = []
# setup input argument list
# helper to get dimensions for data for array-like args
def dimensions(s):
return [(S.Zero, dim - 1) for dim in s.shape]
array_symbols = {}
for array in expressions.atoms(Indexed) | local_expressions.atoms(Indexed):
array_symbols[array.base.label] = array
for array in expressions.atoms(MatrixSymbol) | local_expressions.atoms(MatrixSymbol):
array_symbols[array] = array
for symbol in sorted(symbols, key=str):
if symbol in array_symbols:
array = array_symbols[symbol]
metadata = {'dimensions': dimensions(array)}
else:
metadata = {}
arg_list.append(InputArgument(symbol, **metadata))
output_args.sort(key=lambda x: str(x.name))
arg_list.extend(output_args)
if argument_sequence is not None:
# if the user has supplied IndexedBase instances, we'll accept that
new_sequence = []
for arg in argument_sequence:
if isinstance(arg, IndexedBase):
new_sequence.append(arg.label)
else:
new_sequence.append(arg)
argument_sequence = new_sequence
missing = [x for x in arg_list if x.name not in argument_sequence]
if missing:
msg = "Argument list didn't specify: {0} "
msg = msg.format(", ".join([str(m.name) for m in missing]))
raise CodeGenArgumentListError(msg, missing)
# create redundant arguments to produce the requested sequence
name_arg_dict = {x.name: x for x in arg_list}
new_args = []
for symbol in argument_sequence:
try:
new_args.append(name_arg_dict[symbol])
except KeyError:
if isinstance(symbol, (IndexedBase, MatrixSymbol)):
metadata = {'dimensions': dimensions(symbol)}
else:
metadata = {}
new_args.append(InputArgument(symbol, **metadata))
arg_list = new_args
return Routine(name, arg_list, return_val, local_vars, global_vars)
def write(self, routines, prefix, to_files=False, header=True, empty=True):
"""Writes all the source code files for the given routines.
The generated source is returned as a list of (filename, contents)
tuples, or is written to files (see below). Each filename consists
of the given prefix, appended with an appropriate extension.
Parameters
==========
routines : list
A list of Routine instances to be written
prefix : string
The prefix for the output files
to_files : bool, optional
When True, the output is written to files. Otherwise, a list
of (filename, contents) tuples is returned. [default: False]
header : bool, optional
When True, a header comment is included on top of each source
file. [default: True]
empty : bool, optional
When True, empty lines are included to structure the source
files. [default: True]
"""
if to_files:
for dump_fn in self.dump_fns:
filename = "%s.%s" % (prefix, dump_fn.extension)
with open(filename, "w") as f:
dump_fn(self, routines, f, prefix, header, empty)
else:
result = []
for dump_fn in self.dump_fns:
filename = "%s.%s" % (prefix, dump_fn.extension)
contents = StringIO()
dump_fn(self, routines, contents, prefix, header, empty)
result.append((filename, contents.getvalue()))
return result
def dump_code(self, routines, f, prefix, header=True, empty=True):
"""Write the code by calling language specific methods.
The generated file contains all the definitions of the routines in
low-level code and refers to the header file if appropriate.
Parameters
==========
routines : list
A list of Routine instances.
f : file-like
Where to write the file.
prefix : string
The filename prefix, used to refer to the proper header file.
Only the basename of the prefix is used.
header : bool, optional
When True, a header comment is included on top of each source
file. [default : True]
empty : bool, optional
When True, empty lines are included to structure the source
files. [default : True]
"""
code_lines = self._preprocessor_statements(prefix)
for routine in routines:
if empty:
code_lines.append("\n")
code_lines.extend(self._get_routine_opening(routine))
code_lines.extend(self._declare_arguments(routine))
code_lines.extend(self._declare_globals(routine))
code_lines.extend(self._declare_locals(routine))
if empty:
code_lines.append("\n")
code_lines.extend(self._call_printer(routine))
if empty:
code_lines.append("\n")
code_lines.extend(self._get_routine_ending(routine))
code_lines = self._indent_code(''.join(code_lines))
if header:
code_lines = ''.join(self._get_header() + [code_lines])
if code_lines:
f.write(code_lines)
class CodeGenError(Exception):
pass
class CodeGenArgumentListError(Exception):
@property
def missing_args(self):
return self.args[1]
header_comment = """Code generated with SymPy %(version)s
See http://www.sympy.org/ for more information.
This file is part of '%(project)s'
"""
class CCodeGen(CodeGen):
"""Generator for C code.
The .write() method inherited from CodeGen will output a code file and
an interface file, <prefix>.c and <prefix>.h respectively.
"""
code_extension = "c"
interface_extension = "h"
standard = 'c99'
def __init__(self, project="project", printer=None,
preprocessor_statements=None, cse=False):
super().__init__(project=project, cse=cse)
self.printer = printer or c_code_printers[self.standard.lower()]()
self.preprocessor_statements = preprocessor_statements
if preprocessor_statements is None:
self.preprocessor_statements = ['#include <math.h>']
def _get_header(self):
"""Writes a common header for the generated files."""
code_lines = []
code_lines.append("/" + "*"*78 + '\n')
tmp = header_comment % {"version": sympy_version,
"project": self.project}
for line in tmp.splitlines():
code_lines.append(" *%s*\n" % line.center(76))
code_lines.append(" " + "*"*78 + "/\n")
return code_lines
def get_prototype(self, routine):
"""Returns a string for the function prototype of the routine.
If the routine has multiple result objects, an CodeGenError is
raised.
See: https://en.wikipedia.org/wiki/Function_prototype
"""
if len(routine.results) > 1:
raise CodeGenError("C only supports a single or no return value.")
elif len(routine.results) == 1:
ctype = routine.results[0].get_datatype('C')
else:
ctype = "void"
type_args = []
for arg in routine.arguments:
name = self.printer.doprint(arg.name)
if arg.dimensions or isinstance(arg, ResultBase):
type_args.append((arg.get_datatype('C'), "*%s" % name))
else:
type_args.append((arg.get_datatype('C'), name))
arguments = ", ".join([ "%s %s" % t for t in type_args])
return "%s %s(%s)" % (ctype, routine.name, arguments)
def _preprocessor_statements(self, prefix):
code_lines = []
code_lines.append('#include "{}.h"'.format(os.path.basename(prefix)))
code_lines.extend(self.preprocessor_statements)
code_lines = ['{}\n'.format(l) for l in code_lines]
return code_lines
def _get_routine_opening(self, routine):
prototype = self.get_prototype(routine)
return ["%s {\n" % prototype]
def _declare_arguments(self, routine):
# arguments are declared in prototype
return []
def _declare_globals(self, routine):
# global variables are not explicitly declared within C functions
return []
def _declare_locals(self, routine):
# Compose a list of symbols to be dereferenced in the function
# body. These are the arguments that were passed by a reference
# pointer, excluding arrays.
dereference = []
for arg in routine.arguments:
if isinstance(arg, ResultBase) and not arg.dimensions:
dereference.append(arg.name)
code_lines = []
for result in routine.local_vars:
# local variables that are simple symbols such as those used as indices into
# for loops are defined declared elsewhere.
if not isinstance(result, Result):
continue
if result.name != result.result_var:
raise CodeGen("Result variable and name should match: {}".format(result))
assign_to = result.name
t = result.get_datatype('c')
if isinstance(result.expr, (MatrixBase, MatrixExpr)):
dims = result.expr.shape
code_lines.append("{} {}[{}];\n".format(t, str(assign_to), dims[0]*dims[1]))
prefix = ""
else:
prefix = "const {} ".format(t)
constants, not_c, c_expr = self._printer_method_with_settings(
'doprint', {"human": False, "dereference": dereference},
result.expr, assign_to=assign_to)
for name, value in sorted(constants, key=str):
code_lines.append("double const %s = %s;\n" % (name, value))
code_lines.append("{}{}\n".format(prefix, c_expr))
return code_lines
def _call_printer(self, routine):
code_lines = []
# Compose a list of symbols to be dereferenced in the function
# body. These are the arguments that were passed by a reference
# pointer, excluding arrays.
dereference = []
for arg in routine.arguments:
if isinstance(arg, ResultBase) and not arg.dimensions:
dereference.append(arg.name)
return_val = None
for result in routine.result_variables:
if isinstance(result, Result):
assign_to = routine.name + "_result"
t = result.get_datatype('c')
code_lines.append("{} {};\n".format(t, str(assign_to)))
return_val = assign_to
else: