Modules/cgen.py - platform/external/python/cpython3 - Gitiles

 ########################################################################
 # Copyright (c) 2000, BeOpen.com.
 # Copyright (c) 1995-2000, Corporation for National Research Initiatives.
 # Copyright (c) 1990-1995, Stichting Mathematisch Centrum.
 # All rights reserved.
 #
 # See the file "Misc/COPYRIGHT" for information on usage and
 # redistribution of this file, and for a DISCLAIMER OF ALL WARRANTIES.
 ########################################################################

 # Python script to parse cstubs file for gl and generate C stubs.
 # usage: python cgen.py <cstubs >glmodule.c
 #
 # NOTE: You  must first make a python binary without the "GL" option
 #	before you can run this, when building Python for the first time.
 #	See comments in the Makefile.
 #
 # XXX BUG return arrays generate wrong code
 # XXX need to change error returns into gotos to free mallocked arrays


 import string
 import sys


 # Function to print to stderr
 #
 def err(*args):
 	savestdout = sys.stdout
 	try:
 		sys.stdout = sys.stderr
 		for i in args:
 			print i,
 		print
 	finally:
 		sys.stdout = savestdout


 # The set of digits that form a number
 #
 digits = '0123456789'


 # Function to extract a string of digits from the front of the string.
 # Returns the leading string of digits and the remaining string.
 # If no number is found, returns '' and the original string.
 #
 def getnum(s):
 	n = ''
 	while s and s[0] in digits:
 		n = n + s[0]
 		s = s[1:]
 	return n, s


 # Function to check if a string is a number
 #
 def isnum(s):
 	if not s: return 0
 	for c in s:
 		if not c in digits: return 0
 	return 1


 # Allowed function return types
 #
 return_types = ['void', 'short', 'long']


 # Allowed function argument types
 #
 arg_types = ['char', 'string', 'short', 'u_short', 'float', 'long', 'double']


 # Need to classify arguments as follows
 #	simple input variable
 #	simple output variable
 #	input array
 #	output array
 #	input giving size of some array
 #
 # Array dimensions can be specified as follows
 #	constant
 #	argN
 #	constant * argN
 #	retval
 #	constant * retval
 #
 # The dimensions given as constants * something are really
 # arrays of points where points are 2- 3- or 4-tuples
 #
 # We have to consider three lists:
 #	python input arguments
 #	C stub arguments (in & out)
 #	python output arguments (really return values)
 #
 # There is a mapping from python input arguments to the input arguments
 # of the C stub, and a further mapping from C stub arguments to the
 # python return values


 # Exception raised by checkarg() and generate()
 #
 arg_error = 'bad arg'


 # Function to check one argument.
 # Arguments: the type and the arg "name" (really mode plus subscript).
 # Raises arg_error if something's wrong.
 # Return type, mode, factor, rest of subscript; factor and rest may be empty.
 #
 def checkarg(type, arg):
 	#
 	# Turn "char *x" into "string x".
 	#
 	if type == 'char' and arg[0] == '*':
 		type = 'string'
 		arg = arg[1:]
 	#
 	# Check that the type is supported.
 	#
 	if type not in arg_types:
 		raise arg_error, ('bad type', type)
 	if type[:2] == 'u_':
 		type = 'unsigned ' + type[2:]
 	#
 	# Split it in the mode (first character) and the rest.
 	#
 	mode, rest = arg[:1], arg[1:]
 	#
 	# The mode must be 's' for send (= input) or 'r' for return argument.
 	#
 	if mode not in ('r', 's'):
 		raise arg_error, ('bad arg mode', mode)
 	#
 	# Is it a simple argument: if so, we are done.
 	#
 	if not rest:
 		return type, mode, '', ''
 	#
 	# Not a simple argument; must be an array.
 	# The 'rest' must be a subscript enclosed in [ and ].
 	# The subscript must be one of the following forms,
 	# otherwise we don't handle it (where N is a number):
 	#	N
 	#	argN
 	#	retval
 	#	N*argN
 	#	N*retval
 	#
 	if rest[:1] <> '[' or rest[-1:] <> ']':
 		raise arg_error, ('subscript expected', rest)
 	sub = rest[1:-1]
 	#
 	# Is there a leading number?
 	#
 	num, sub = getnum(sub)
 	if num:
 		# There is a leading number
 		if not sub:
 			# The subscript is just a number
 			return type, mode, num, ''
 		if sub[:1] == '*':
 			# There is a factor prefix
 			sub = sub[1:]
 		else:
 			raise arg_error, ('\'*\' expected', sub)
 	if sub == 'retval':
 		# size is retval -- must be a reply argument
 		if mode <> 'r':
 			raise arg_error, ('non-r mode with [retval]', mode)
 	elif not isnum(sub) and (sub[:3] <> 'arg' or not isnum(sub[3:])):
 		raise arg_error, ('bad subscript', sub)
 	#
 	return type, mode, num, sub


 # List of functions for which we have generated stubs
 #
 functions = []


 # Generate the stub for the given function, using the database of argument
 # information build by successive calls to checkarg()
 #
 def generate(type, func, database):
 	#
 	# Check that we can handle this case:
 	# no variable size reply arrays yet
 	#
 	n_in_args = 0
 	n_out_args = 0
 	#
 	for a_type, a_mode, a_factor, a_sub in database:
 		if a_mode == 's':
 			n_in_args = n_in_args + 1
 		elif a_mode == 'r':
 			n_out_args = n_out_args + 1
 		else:
 			# Can't happen
 			raise arg_error, ('bad a_mode', a_mode)
 		if (a_mode == 'r' and a_sub) or a_sub == 'retval':
 			err('Function', func, 'too complicated:',
 			    a_type, a_mode, a_factor, a_sub)
 			print '/* XXX Too complicated to generate code for */'
 			return
 	#
 	functions.append(func)
 	#
 	# Stub header
 	#
 	print
 	print 'static PyObject *'
 	print 'gl_' + func + '(self, args)'
 	print '\tPyObject *self;'
 	print '\tPyObject *args;'
 	print '{'
 	#
 	# Declare return value if any
 	#
 	if type <> 'void':
 		print '\t' + type, 'retval;'
 	#
 	# Declare arguments
 	#
 	for i in range(len(database)):
 		a_type, a_mode, a_factor, a_sub = database[i]
 		print '\t' + a_type,
 		brac = ket = ''
 		if a_sub and not isnum(a_sub):
 			if a_factor:
 				brac = '('
 				ket = ')'
 			print brac + '*',
 		print 'arg' + `i+1` + ket,
 		if a_sub and isnum(a_sub):
 			print '[', a_sub, ']',
 		if a_factor:
 			print '[', a_factor, ']',
 		print ';'
 	#
 	# Find input arguments derived from array sizes
 	#
 	for i in range(len(database)):
 		a_type, a_mode, a_factor, a_sub = database[i]
 		if a_mode == 's' and a_sub[:3] == 'arg' and isnum(a_sub[3:]):
 			# Sending a variable-length array
 			n = eval(a_sub[3:])
 			if 1 <= n <= len(database):
 			    b_type, b_mode, b_factor, b_sub = database[n-1]
 			    if b_mode == 's':
 			        database[n-1] = b_type, 'i', a_factor, `i`
 			        n_in_args = n_in_args - 1
 	#
 	# Assign argument positions in the Python argument list
 	#
 	in_pos = []
 	i_in = 0
 	for i in range(len(database)):
 		a_type, a_mode, a_factor, a_sub = database[i]
 		if a_mode == 's':
 			in_pos.append(i_in)
 			i_in = i_in + 1
 		else:
 			in_pos.append(-1)
 	#
 	# Get input arguments
 	#
 	for i in range(len(database)):
 		a_type, a_mode, a_factor, a_sub = database[i]
 		if a_type[:9] == 'unsigned ':
 			xtype = a_type[9:]
 		else:
 			xtype = a_type
 		if a_mode == 'i':
 			#
 			# Implicit argument;
 			# a_factor is divisor if present,
 			# a_sub indicates which arg (`database index`)
 			#
 			j = eval(a_sub)
 			print '\tif',
 			print '(!geti' + xtype + 'arraysize(args,',
 			print `n_in_args` + ',',
 			print `in_pos[j]` + ',',
 			if xtype <> a_type:
 				print '('+xtype+' *)',
 			print '&arg' + `i+1` + '))'
 			print '\t\treturn NULL;'
 			if a_factor:
 				print '\targ' + `i+1`,
 				print '= arg' + `i+1`,
 				print '/', a_factor + ';'
 		elif a_mode == 's':
 			if a_sub and not isnum(a_sub):
 				# Allocate memory for varsize array
 				print '\tif ((arg' + `i+1`, '=',
 				if a_factor:
 					print '('+a_type+'(*)['+a_factor+'])',
 				print 'PyMem_NEW(' + a_type, ',',
 				if a_factor:
 					print a_factor, '*',
 				print a_sub, ')) == NULL)'
 				print '\t\treturn PyErr_NoMemory();'
 			print '\tif',
 			if a_factor or a_sub: # Get a fixed-size array array
 				print '(!geti' + xtype + 'array(args,',
 				print `n_in_args` + ',',
 				print `in_pos[i]` + ',',
 				if a_factor: print a_factor,
 				if a_factor and a_sub: print '*',
 				if a_sub: print a_sub,
 				print ',',
 				if (a_sub and a_factor) or xtype <> a_type:
 					print '('+xtype+' *)',
 				print 'arg' + `i+1` + '))'
 			else: # Get a simple variable
 				print '(!geti' + xtype + 'arg(args,',
 				print `n_in_args` + ',',
 				print `in_pos[i]` + ',',
 				if xtype <> a_type:
 					print '('+xtype+' *)',
 				print '&arg' + `i+1` + '))'
 			print '\t\treturn NULL;'
 	#
 	# Begin of function call
 	#
 	if type <> 'void':
 		print '\tretval =', func + '(',
 	else:
 		print '\t' + func + '(',
 	#
 	# Argument list
 	#
 	for i in range(len(database)):
 		if i > 0: print ',',
 		a_type, a_mode, a_factor, a_sub = database[i]
 		if a_mode == 'r' and not a_factor:
 			print '&',
 		print 'arg' + `i+1`,
 	#
 	# End of function call
 	#
 	print ');'
 	#
 	# Free varsize arrays
 	#
 	for i in range(len(database)):
 		a_type, a_mode, a_factor, a_sub = database[i]
 		if a_mode == 's' and a_sub and not isnum(a_sub):
 			print '\tPyMem_DEL(arg' + `i+1` + ');'
 	#
 	# Return
 	#
 	if n_out_args:
 		#
 		# Multiple return values -- construct a tuple
 		#
 		if type <> 'void':
 			n_out_args = n_out_args + 1
 		if n_out_args == 1:
 			for i in range(len(database)):
 				a_type, a_mode, a_factor, a_sub = database[i]
 				if a_mode == 'r':
 					break
 			else:
 				raise arg_error, 'expected r arg not found'
 			print '\treturn',
 			print mkobject(a_type, 'arg' + `i+1`) + ';'
 		else:
 			print '\t{ PyObject *v = PyTuple_New(',
 			print n_out_args, ');'
 			print '\t  if (v == NULL) return NULL;'
 			i_out = 0
 			if type <> 'void':
 				print '\t  PyTuple_SetItem(v,',
 				print `i_out` + ',',
 				print mkobject(type, 'retval') + ');'
 				i_out = i_out + 1
 			for i in range(len(database)):
 				a_type, a_mode, a_factor, a_sub = database[i]
 				if a_mode == 'r':
 					print '\t  PyTuple_SetItem(v,',
 					print `i_out` + ',',
 					s = mkobject(a_type, 'arg' + `i+1`)
 					print s + ');'
 					i_out = i_out + 1
 			print '\t  return v;'
 			print '\t}'
 	else:
 		#
 		# Simple function return
 		# Return None or return value
 		#
 		if type == 'void':
 			print '\tPy_INCREF(Py_None);'
 			print '\treturn Py_None;'
 		else:
 			print '\treturn', mkobject(type, 'retval') + ';'
 	#
 	# Stub body closing brace
 	#
 	print '}'


 # Subroutine to return a function call to mknew<type>object(<arg>)
 #
 def mkobject(type, arg):
 	if type[:9] == 'unsigned ':
 		type = type[9:]
 		return 'mknew' + type + 'object((' + type + ') ' + arg + ')'
 	return 'mknew' + type + 'object(' + arg + ')'


 defined_archs = []

 # usage: cgen [ -Dmach ... ] [ file ]
 for arg in sys.argv[1:]:
 	if arg[:2] == '-D':
 		defined_archs.append(arg[2:])
 	else:
 		# Open optional file argument
 		sys.stdin = open(arg, 'r')


 # Input line number
 lno = 0


 # Input is divided in two parts, separated by a line containing '%%'.
 #	<part1>		-- literally copied to stdout
 #	<part2>		-- stub definitions

 # Variable indicating the current input part.
 #
 part = 1

 # Main loop over the input
 #
 while 1:
 	try:
 		line = raw_input()
 	except EOFError:
 		break
 	#
 	lno = lno+1
 	words = string.split(line)
 	#
 	if part == 1:
 		#
 		# In part 1, copy everything literally
 		# except look for a line of just '%%'
 		#
 		if words == ['%%']:
 			part = part + 1
 		else:
 			#
 			# Look for names of manually written
 			# stubs: a single percent followed by the name
 			# of the function in Python.
 			# The stub name is derived by prefixing 'gl_'.
 			#
 			if words and words[0][0] == '%':
 				func = words[0][1:]
 				if (not func) and words[1:]:
 					func = words[1]
 				if func:
 					functions.append(func)
 			else:
 				print line
 		continue
 	if not words:
 		continue		# skip empty line
 	elif words[0] == 'if':
 		# if XXX rest
 		# if !XXX rest
 		if words[1][0] == '!':
 			if words[1][1:] in defined_archs:
 				continue
 		elif words[1] not in defined_archs:
 			continue
 		words = words[2:]
 	if words[0] == '#include':
 		print line
 	elif words[0][:1] == '#':
 		pass			# ignore comment
 	elif words[0] not in return_types:
 		err('Line', lno, ': bad return type :', words[0])
 	elif len(words) < 2:
 		err('Line', lno, ': no funcname :', line)
 	else:
 		if len(words) % 2 <> 0:
 			err('Line', lno, ': odd argument list :', words[2:])
 		else:
 			database = []
 			try:
 				for i in range(2, len(words), 2):
 					x = checkarg(words[i], words[i+1])
 					database.append(x)
 				print
 				print '/*',
 				for w in words: print w,
 				print '*/'
 				generate(words[0], words[1], database)
 			except arg_error, msg:
 				err('Line', lno, ':', msg)


 print
 print 'static struct PyMethodDef gl_methods[] = {'
 for func in functions:
 	print '\t{"' + func + '", gl_' + func + '},'
 print '\t{NULL, NULL} /* Sentinel */'
 print '};'
 print
 print 'void'
 print 'initgl()'
 print '{'
 print '\t(void) Py_InitModule("gl", gl_methods);'
 print '}'
	########################################################################
	# Copyright (c) 2000, BeOpen.com.
	# Copyright (c) 1995-2000, Corporation for National Research Initiatives.
	# Copyright (c) 1990-1995, Stichting Mathematisch Centrum.
	# All rights reserved.
	#
	# See the file "Misc/COPYRIGHT" for information on usage and
	# redistribution of this file, and for a DISCLAIMER OF ALL WARRANTIES.
	########################################################################

	# Python script to parse cstubs file for gl and generate C stubs.
	# usage: python cgen.py <cstubs >glmodule.c
	#
	# NOTE: You must first make a python binary without the "GL" option
	# before you can run this, when building Python for the first time.
	# See comments in the Makefile.
	#
	# XXX BUG return arrays generate wrong code
	# XXX need to change error returns into gotos to free mallocked arrays


	import string
	import sys


	# Function to print to stderr
	#
	def err(*args):
	savestdout = sys.stdout
	try:
	sys.stdout = sys.stderr
	for i in args:
	print i,
	print
	finally:
	sys.stdout = savestdout


	# The set of digits that form a number
	#
	digits = '0123456789'


	# Function to extract a string of digits from the front of the string.
	# Returns the leading string of digits and the remaining string.
	# If no number is found, returns '' and the original string.
	#
	def getnum(s):
	n = ''
	while s and s[0] in digits:
	n = n + s[0]
	s = s[1:]
	return n, s


	# Function to check if a string is a number
	#
	def isnum(s):
	if not s: return 0
	for c in s:
	if not c in digits: return 0
	return 1


	# Allowed function return types
	#
	return_types = ['void', 'short', 'long']


	# Allowed function argument types
	#
	arg_types = ['char', 'string', 'short', 'u_short', 'float', 'long', 'double']


	# Need to classify arguments as follows
	# simple input variable
	# simple output variable
	# input array
	# output array
	# input giving size of some array
	#
	# Array dimensions can be specified as follows
	# constant
	# argN
	# constant * argN
	# retval
	# constant * retval
	#
	# The dimensions given as constants * something are really
	# arrays of points where points are 2- 3- or 4-tuples
	#
	# We have to consider three lists:
	# python input arguments
	# C stub arguments (in & out)
	# python output arguments (really return values)
	#
	# There is a mapping from python input arguments to the input arguments
	# of the C stub, and a further mapping from C stub arguments to the
	# python return values


	# Exception raised by checkarg() and generate()
	#
	arg_error = 'bad arg'


	# Function to check one argument.
	# Arguments: the type and the arg "name" (really mode plus subscript).
	# Raises arg_error if something's wrong.
	# Return type, mode, factor, rest of subscript; factor and rest may be empty.
	#
	def checkarg(type, arg):
	#
	# Turn "char *x" into "string x".
	#
	if type == 'char' and arg[0] == '*':
	type = 'string'
	arg = arg[1:]
	#
	# Check that the type is supported.
	#
	if type not in arg_types:
	raise arg_error, ('bad type', type)
	if type[:2] == 'u_':
	type = 'unsigned ' + type[2:]
	#
	# Split it in the mode (first character) and the rest.
	#
	mode, rest = arg[:1], arg[1:]
	#
	# The mode must be 's' for send (= input) or 'r' for return argument.
	#
	if mode not in ('r', 's'):
	raise arg_error, ('bad arg mode', mode)
	#
	# Is it a simple argument: if so, we are done.
	#
	if not rest:
	return type, mode, '', ''
	#
	# Not a simple argument; must be an array.
	# The 'rest' must be a subscript enclosed in [ and ].
	# The subscript must be one of the following forms,
	# otherwise we don't handle it (where N is a number):
	# N
	# argN
	# retval
	# N*argN
	# N*retval
	#
	if rest[:1] <> '[' or rest[-1:] <> ']':
	raise arg_error, ('subscript expected', rest)
	sub = rest[1:-1]
	#
	# Is there a leading number?
	#
	num, sub = getnum(sub)
	if num:
	# There is a leading number
	if not sub:
	# The subscript is just a number
	return type, mode, num, ''
	if sub[:1] == '*':
	# There is a factor prefix
	sub = sub[1:]
	else:
	raise arg_error, ('\'*\' expected', sub)
	if sub == 'retval':
	# size is retval -- must be a reply argument
	if mode <> 'r':
	raise arg_error, ('non-r mode with [retval]', mode)
	elif not isnum(sub) and (sub[:3] <> 'arg' or not isnum(sub[3:])):
	raise arg_error, ('bad subscript', sub)
	#
	return type, mode, num, sub


	# List of functions for which we have generated stubs
	#
	functions = []


	# Generate the stub for the given function, using the database of argument
	# information build by successive calls to checkarg()
	#
	def generate(type, func, database):
	#
	# Check that we can handle this case:
	# no variable size reply arrays yet
	#
	n_in_args = 0
	n_out_args = 0
	#
	for a_type, a_mode, a_factor, a_sub in database:
	if a_mode == 's':
	n_in_args = n_in_args + 1
	elif a_mode == 'r':
	n_out_args = n_out_args + 1
	else:
	# Can't happen
	raise arg_error, ('bad a_mode', a_mode)
	if (a_mode == 'r' and a_sub) or a_sub == 'retval':
	err('Function', func, 'too complicated:',
	a_type, a_mode, a_factor, a_sub)
	print '/* XXX Too complicated to generate code for */'
	return
	#
	functions.append(func)
	#
	# Stub header
	#
	print
	print 'static PyObject *'
	print 'gl_' + func + '(self, args)'
	print '\tPyObject *self;'
	print '\tPyObject *args;'
	print '{'
	#
	# Declare return value if any
	#
	if type <> 'void':
	print '\t' + type, 'retval;'
	#
	# Declare arguments
	#
	for i in range(len(database)):
	a_type, a_mode, a_factor, a_sub = database[i]
	print '\t' + a_type,
	brac = ket = ''
	if a_sub and not isnum(a_sub):
	if a_factor:
	brac = '('
	ket = ')'
	print brac + '*',
	print 'arg' + `i+1` + ket,
	if a_sub and isnum(a_sub):
	print '[', a_sub, ']',
	if a_factor:
	print '[', a_factor, ']',
	print ';'
	#
	# Find input arguments derived from array sizes
	#
	for i in range(len(database)):
	a_type, a_mode, a_factor, a_sub = database[i]
	if a_mode == 's' and a_sub[:3] == 'arg' and isnum(a_sub[3:]):
	# Sending a variable-length array
	n = eval(a_sub[3:])
	if 1 <= n <= len(database):
	b_type, b_mode, b_factor, b_sub = database[n-1]
	if b_mode == 's':
	database[n-1] = b_type, 'i', a_factor, `i`
	n_in_args = n_in_args - 1
	#
	# Assign argument positions in the Python argument list
	#
	in_pos = []
	i_in = 0
	for i in range(len(database)):
	a_type, a_mode, a_factor, a_sub = database[i]
	if a_mode == 's':
	in_pos.append(i_in)
	i_in = i_in + 1
	else:
	in_pos.append(-1)
	#
	# Get input arguments
	#
	for i in range(len(database)):
	a_type, a_mode, a_factor, a_sub = database[i]
	if a_type[:9] == 'unsigned ':
	xtype = a_type[9:]
	else:
	xtype = a_type
	if a_mode == 'i':
	#
	# Implicit argument;
	# a_factor is divisor if present,
	# a_sub indicates which arg (`database index`)
	#
	j = eval(a_sub)
	print '\tif',
	print '(!geti' + xtype + 'arraysize(args,',
	print `n_in_args` + ',',
	print `in_pos[j]` + ',',
	if xtype <> a_type:
	print '('+xtype+' *)',
	print '&arg' + `i+1` + '))'
	print '\t\treturn NULL;'
	if a_factor:
	print '\targ' + `i+1`,
	print '= arg' + `i+1`,
	print '/', a_factor + ';'
	elif a_mode == 's':
	if a_sub and not isnum(a_sub):
	# Allocate memory for varsize array
	print '\tif ((arg' + `i+1`, '=',
	if a_factor:
	print '('+a_type+'(*)['+a_factor+'])',
	print 'PyMem_NEW(' + a_type, ',',
	if a_factor:
	print a_factor, '*',
	print a_sub, ')) == NULL)'
	print '\t\treturn PyErr_NoMemory();'
	print '\tif',
	if a_factor or a_sub: # Get a fixed-size array array
	print '(!geti' + xtype + 'array(args,',
	print `n_in_args` + ',',
	print `in_pos[i]` + ',',
	if a_factor: print a_factor,
	if a_factor and a_sub: print '*',
	if a_sub: print a_sub,
	print ',',
	if (a_sub and a_factor) or xtype <> a_type:
	print '('+xtype+' *)',
	print 'arg' + `i+1` + '))'
	else: # Get a simple variable
	print '(!geti' + xtype + 'arg(args,',
	print `n_in_args` + ',',
	print `in_pos[i]` + ',',
	if xtype <> a_type:
	print '('+xtype+' *)',
	print '&arg' + `i+1` + '))'
	print '\t\treturn NULL;'
	#
	# Begin of function call
	#
	if type <> 'void':
	print '\tretval =', func + '(',
	else:
	print '\t' + func + '(',
	#
	# Argument list
	#
	for i in range(len(database)):
	if i > 0: print ',',
	a_type, a_mode, a_factor, a_sub = database[i]
	if a_mode == 'r' and not a_factor:
	print '&',
	print 'arg' + `i+1`,
	#
	# End of function call
	#
	print ');'
	#
	# Free varsize arrays
	#
	for i in range(len(database)):
	a_type, a_mode, a_factor, a_sub = database[i]
	if a_mode == 's' and a_sub and not isnum(a_sub):
	print '\tPyMem_DEL(arg' + `i+1` + ');'
	#
	# Return
	#
	if n_out_args:
	#
	# Multiple return values -- construct a tuple
	#
	if type <> 'void':
	n_out_args = n_out_args + 1
	if n_out_args == 1:
	for i in range(len(database)):
	a_type, a_mode, a_factor, a_sub = database[i]
	if a_mode == 'r':
	break
	else:
	raise arg_error, 'expected r arg not found'
	print '\treturn',
	print mkobject(a_type, 'arg' + `i+1`) + ';'
	else:
	print '\t{ PyObject *v = PyTuple_New(',
	print n_out_args, ');'
	print '\t if (v == NULL) return NULL;'
	i_out = 0
	if type <> 'void':
	print '\t PyTuple_SetItem(v,',
	print `i_out` + ',',
	print mkobject(type, 'retval') + ');'
	i_out = i_out + 1
	for i in range(len(database)):
	a_type, a_mode, a_factor, a_sub = database[i]
	if a_mode == 'r':
	print '\t PyTuple_SetItem(v,',
	print `i_out` + ',',
	s = mkobject(a_type, 'arg' + `i+1`)
	print s + ');'
	i_out = i_out + 1
	print '\t return v;'
	print '\t}'
	else:
	#
	# Simple function return
	# Return None or return value
	#
	if type == 'void':
	print '\tPy_INCREF(Py_None);'
	print '\treturn Py_None;'
	else:
	print '\treturn', mkobject(type, 'retval') + ';'
	#
	# Stub body closing brace
	#
	print '}'


	# Subroutine to return a function call to mknew<type>object(<arg>)
	#
	def mkobject(type, arg):
	if type[:9] == 'unsigned ':
	type = type[9:]
	return 'mknew' + type + 'object((' + type + ') ' + arg + ')'
	return 'mknew' + type + 'object(' + arg + ')'


	defined_archs = []

	# usage: cgen [ -Dmach ... ] [ file ]
	for arg in sys.argv[1:]:
	if arg[:2] == '-D':
	defined_archs.append(arg[2:])
	else:
	# Open optional file argument
	sys.stdin = open(arg, 'r')


	# Input line number
	lno = 0


	# Input is divided in two parts, separated by a line containing '%%'.
	# <part1> -- literally copied to stdout
	# <part2> -- stub definitions

	# Variable indicating the current input part.
	#
	part = 1

	# Main loop over the input
	#
	while 1:
	try:
	line = raw_input()
	except EOFError:
	break
	#
	lno = lno+1
	words = string.split(line)
	#
	if part == 1:
	#
	# In part 1, copy everything literally
	# except look for a line of just '%%'
	#
	if words == ['%%']:
	part = part + 1
	else:
	#
	# Look for names of manually written
	# stubs: a single percent followed by the name
	# of the function in Python.
	# The stub name is derived by prefixing 'gl_'.
	#
	if words and words[0][0] == '%':
	func = words[0][1:]
	if (not func) and words[1:]:
	func = words[1]
	if func:
	functions.append(func)
	else:
	print line
	continue
	if not words:
	continue # skip empty line
	elif words[0] == 'if':
	# if XXX rest
	# if !XXX rest
	if words[1][0] == '!':
	if words[1][1:] in defined_archs:
	continue
	elif words[1] not in defined_archs:
	continue
	words = words[2:]
	if words[0] == '#include':
	print line
	elif words[0][:1] == '#':
	pass # ignore comment
	elif words[0] not in return_types:
	err('Line', lno, ': bad return type :', words[0])
	elif len(words) < 2:
	err('Line', lno, ': no funcname :', line)
	else:
	if len(words) % 2 <> 0:
	err('Line', lno, ': odd argument list :', words[2:])
	else:
	database = []
	try:
	for i in range(2, len(words), 2):
	x = checkarg(words[i], words[i+1])
	database.append(x)
	print
	print '/*',
	for w in words: print w,
	print '*/'
	generate(words[0], words[1], database)
	except arg_error, msg:
	err('Line', lno, ':', msg)


	print
	print 'static struct PyMethodDef gl_methods[] = {'
	for func in functions:
	print '\t{"' + func + '", gl_' + func + '},'
	print '\t{NULL, NULL} /* Sentinel */'
	print '};'
	print
	print 'void'
	print 'initgl()'
	print '{'
	print '\t(void) Py_InitModule("gl", gl_methods);'
	print '}'