#!/usr/bin/env python # (C) Copyright IBM Corporation 2004, 2005 # All Rights Reserved. # # Permission is hereby granted, free of charge, to any person obtaining a # copy of this software and associated documentation files (the "Software"), # to deal in the Software without restriction, including without limitation # on the rights to use, copy, modify, merge, publish, distribute, sub # license, and/or sell copies of the Software, and to permit persons to whom # the Software is furnished to do so, subject to the following conditions: # # The above copyright notice and this permission notice (including the next # paragraph) shall be included in all copies or substantial portions of the # Software. # # THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR # IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, # FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT. IN NO EVENT SHALL # IBM AND/OR ITS SUPPLIERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER # LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING # FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS # IN THE SOFTWARE. # # Authors: # Ian Romanick import libxml2 import re, sys, string import typeexpr def parse_GL_API( file_name, factory = None ): doc = libxml2.readFile( file_name, None, libxml2.XML_PARSE_XINCLUDE + libxml2.XML_PARSE_NOBLANKS + libxml2.XML_PARSE_DTDVALID + libxml2.XML_PARSE_DTDATTR + libxml2.XML_PARSE_DTDLOAD + libxml2.XML_PARSE_NOENT ) ret = doc.xincludeProcess() if not factory: factory = gl_item_factory() api = factory.create_item( "api", None, None ) api.process_element( doc ) doc.freeDoc() return api def is_attr_true( element, name ): """Read a name value from an element's attributes. The value read from the attribute list must be either 'true' or 'false'. If the value is 'false', zero will be returned. If the value is 'true', non-zero will be returned. An exception will be raised for any other value.""" value = element.nsProp( name, None ) if value == "true": return 1 elif value == "false": return 0 else: raise RuntimeError('Invalid value "%s" for boolean "%s".' % (value, name)) class gl_print_base: """Base class of all API pretty-printers. In the model-view-controller pattern, this is the view. Any derived class will want to over-ride the printBody, printRealHader, and printRealFooter methods. Some derived classes may want to over-ride printHeader and printFooter, or even Print (though this is unlikely). """ def __init__(self): # Name of the script that is generating the output file. # Every derived class should set this to the name of its # source file. self.name = "a" # License on the *generated* source file. This may differ # from the license on the script that is generating the file. # Every derived class should set this to some reasonable # value. # # See license.py for an example of a reasonable value. self.license = "The license for this file is unspecified." # The header_tag is the name of the C preprocessor define # used to prevent multiple inclusion. Typically only # generated C header files need this to be set. Setting it # causes code to be generated automatically in printHeader # and printFooter. self.header_tag = None # List of file-private defines that must be undefined at the # end of the file. This can be used in header files to define # names for use in the file, then undefine them at the end of # the header file. self.undef_list = [] return def Print(self, api): self.printHeader() self.printBody(api) self.printFooter() return def printHeader(self): """Print the header associated with all files and call the printRealHeader method.""" print '/* DO NOT EDIT - This file generated automatically by %s script */' \ % (self.name) print '' print '/*' print ' * ' + self.license.replace('\n', '\n * ') print ' */' print '' if self.header_tag: print '#if !defined( %s )' % (self.header_tag) print '# define %s' % (self.header_tag) print '' self.printRealHeader(); return def printFooter(self): """Print the header associated with all files and call the printRealFooter method.""" self.printRealFooter() if self.undef_list: print '' for u in self.undef_list: print "# undef %s" % (u) if self.header_tag: print '' print '#endif /* !defined( %s ) */' % (self.header_tag) def printRealHeader(self): """Print the "real" header for the created file. In the base class, this function is empty. All derived classes should over-ride this function.""" return def printRealFooter(self): """Print the "real" footer for the created file. In the base class, this function is empty. All derived classes should over-ride this function.""" return def printPure(self): """Conditionally define `PURE' function attribute. Conditionally defines a preprocessor macro `PURE' that wraps GCC's `pure' function attribute. The conditional code can be easilly adapted to other compilers that support a similar feature. The name is also added to the file's undef_list. """ self.undef_list.append("PURE") print """# if __GNUC__ > 2 || (__GNUC__ == 2 && __GNUC_MINOR__ >= 96) # define PURE __attribute__((pure)) # else # define PURE # endif""" return def printFastcall(self): """Conditionally define `FASTCALL' function attribute. Conditionally defines a preprocessor macro `FASTCALL' that wraps GCC's `fastcall' function attribute. The conditional code can be easilly adapted to other compilers that support a similar feature. The name is also added to the file's undef_list. """ self.undef_list.append("FASTCALL") print """# if defined(__i386__) && defined(__GNUC__) && !defined(__CYGWIN__) && !defined(__MINGW32__) # define FASTCALL __attribute__((fastcall)) # else # define FASTCALL # endif""" return def printVisibility(self, S, s): """Conditionally define visibility function attribute. Conditionally defines a preprocessor macro name S that wraps GCC's visibility function attribute. The visibility used is the parameter s. The conditional code can be easilly adapted to other compilers that support a similar feature. The name is also added to the file's undef_list. """ self.undef_list.append(S) print """# if (__GNUC__ > 3 || (__GNUC__ == 3 && __GNUC_MINOR__ >= 3)) && !defined(__CYGWIN__) && !defined(__MINGW32__) # define %s __attribute__((visibility("%s"))) # else # define %s # endif""" % (S, s, S) return def printNoinline(self): """Conditionally define `NOINLINE' function attribute. Conditionally defines a preprocessor macro `NOINLINE' that wraps GCC's `noinline' function attribute. The conditional code can be easilly adapted to other compilers that support a similar feature. The name is also added to the file's undef_list. """ self.undef_list.append("NOINLINE") print """# if defined(__GNUC__) # define NOINLINE __attribute__((noinline)) # else # define NOINLINE # endif""" return def real_function_name(element): name = element.nsProp( "name", None ) alias = element.nsProp( "alias", None ) if alias: return alias else: return name def real_category_name(c): if re.compile("[1-9][0-9]*[.][0-9]+").match(c): return "GL_VERSION_" + c.replace(".", "_") else: return c def create_parameter_string(parameters, include_names): """Create a parameter string from a list of gl_parameters.""" list = [] for p in parameters: if include_names: list.append( p.string() ) else: list.append( p.type_string() ) if len(list) == 0: list = ["void"] return string.join(list, ", ") class gl_item: def __init__(self, element, context): self.context = context self.name = element.nsProp( "name", None ) self.category = real_category_name( element.parent.nsProp( "name", None ) ) return class gl_type( gl_item ): def __init__(self, element, context): gl_item.__init__(self, element, context) self.size = int( element.nsProp( "size", None ), 0 ) te = typeexpr.type_expression( None ) tn = typeexpr.type_node() tn.size = int( element.nsProp( "size", None ), 0 ) tn.integer = not is_attr_true( element, "float" ) tn.unsigned = is_attr_true( element, "unsigned" ) tn.name = "GL" + self.name te.set_base_type_node( tn ) self.type_expr = te return def get_type_expression(self): return self.type_expr class gl_enum( gl_item ): def __init__(self, element, context): gl_item.__init__(self, element, context) self.value = int( element.nsProp( "value", None ), 0 ) temp = element.nsProp( "count", None ) if not temp or temp == "?": self.default_count = -1 else: try: c = int(temp) except Exception,e: raise RuntimeError('Invalid count value "%s" for enum "%s" in function "%s" when an integer was expected.' % (temp, self.name, n)) self.default_count = c return def priority(self): """Calculate a 'priority' for this enum name. When an enum is looked up by number, there may be many possible names, but only one is the 'prefered' name. The priority is used to select which name is the 'best'. Highest precedence is given to core GL name. ARB extension names have the next highest, followed by EXT extension names. Vendor extension names are the lowest. """ if self.name.endswith( "_BIT" ): bias = 1 else: bias = 0 if self.category.startswith( "GL_VERSION_" ): priority = 0 elif self.category.startswith( "GL_ARB_" ): priority = 2 elif self.category.startswith( "GL_EXT_" ): priority = 4 else: priority = 6 return priority + bias class gl_parameter: def __init__(self, element, context): self.name = element.nsProp( "name", None ) ts = element.nsProp( "type", None ) self.type_expr = typeexpr.type_expression( ts, context ) temp = element.nsProp( "variable_param", None ) if temp: self.count_parameter_list = temp.split( ' ' ) else: self.count_parameter_list = [] # The count tag can be either a numeric string or the name of # a variable. If it is the name of a variable, the int(c) # statement will throw an exception, and the except block will # take over. c = element.nsProp( "count", None ) try: count = int(c) self.count = count self.counter = None except Exception,e: count = 1 self.count = 0 self.counter = c self.count_scale = int(element.nsProp( "count_scale", None )) elements = (count * self.count_scale) if elements == 1: elements = 0 #if ts == "GLdouble": # print '/* stack size -> %s = %u (before)*/' % (self.name, self.type_expr.get_stack_size()) # print '/* # elements = %u */' % (elements) self.type_expr.set_elements( elements ) #if ts == "GLdouble": # print '/* stack size -> %s = %u (after) */' % (self.name, self.type_expr.get_stack_size()) self.is_counter = is_attr_true( element, 'counter' ) self.is_output = is_attr_true( element, 'output' ) # Pixel data has special parameters. self.width = element.nsProp('img_width', None) self.height = element.nsProp('img_height', None) self.depth = element.nsProp('img_depth', None) self.extent = element.nsProp('img_extent', None) self.img_xoff = element.nsProp('img_xoff', None) self.img_yoff = element.nsProp('img_yoff', None) self.img_zoff = element.nsProp('img_zoff', None) self.img_woff = element.nsProp('img_woff', None) self.img_format = element.nsProp('img_format', None) self.img_type = element.nsProp('img_type', None) self.img_target = element.nsProp('img_target', None) self.img_pad_dimensions = is_attr_true( element, 'img_pad_dimensions' ) self.img_null_flag = is_attr_true( element, 'img_null_flag' ) self.img_send_null = is_attr_true( element, 'img_send_null' ) return def compatible(self, other): return 1 def is_array(self): return self.is_pointer() def is_pointer(self): return self.type_expr.is_pointer() def is_image(self): if self.width: return 1 else: return 0 def is_variable_length(self): return len(self.count_parameter_list) or self.counter def is_64_bit(self): count = self.type_expr.get_element_count() if count: if (self.size() / count) == 8: return 1 else: if self.size() == 8: return 1 return 0 def string(self): return self.type_expr.original_string + " " + self.name def type_string(self): return self.type_expr.original_string def get_base_type_string(self): return self.type_expr.get_base_name() def get_dimensions(self): if not self.width: return [ 0, "0", "0", "0", "0" ] dim = 1 w = self.width h = "1" d = "1" e = "1" if self.height: dim = 2 h = self.height if self.depth: dim = 3 d = self.depth if self.extent: dim = 4 e = self.extent return [ dim, w, h, d, e ] def get_stack_size(self): return self.type_expr.get_stack_size() def size(self): if self.is_image(): return 0 else: return self.type_expr.get_element_size() def get_element_count(self): c = self.type_expr.get_element_count() if c == 0: return 1 return c def size_string(self, use_parens = 1): s = self.size() if self.counter or self.count_parameter_list: list = [ "compsize" ] if self.counter and self.count_parameter_list: list.append( self.counter ) elif self.counter: list = [ self.counter ] if s > 1: list.append( str(s) ) if len(list) > 1 and use_parens : return "(%s)" % (string.join(list, " * ")) else: return string.join(list, " * ") elif self.is_image(): return "compsize" else: return str(s) def format_string(self): if self.type_expr.original_string == "GLenum": return "0x%x" else: return self.type_expr.format_string() class gl_function( gl_item ): def __init__(self, element, context): self.context = context self.name = None self.entry_points = [] self.return_type = "void" self.parameters = [] self.offset = -1 self.initialized = 0 self.images = [] # Track the parameter string (for the function prototype) # for each entry-point. This is done because some functions # change their prototype slightly when promoted from extension # to ARB extension to core. glTexImage3DEXT and glTexImage3D # are good examples of this. Scripts that need to generate # code for these differing aliases need to real prototype # for each entry-point. Otherwise, they may generate code # that won't compile. self.parameter_strings = {} self.process_element( element ) return def process_element(self, element): name = element.nsProp( "name", None ) alias = element.nsProp( "alias", None ) self.entry_points.append( name ) if alias: true_name = alias else: true_name = name # Only try to set the offset when a non-alias # entry-point is being processes. offset = element.nsProp( "offset", None ) if offset: try: o = int( offset ) self.offset = o except Exception, e: self.offset = -1 if not self.name: self.name = true_name elif self.name != true_name: raise RuntimeError("Function true name redefined. Was %s, now %s." % (self.name, true_name)) # There are two possible cases. The first time an entry-point # with data is seen, self.initialized will be 0. On that # pass, we just fill in the data. The next time an # entry-point with data is seen, self.initialized will be 1. # On that pass we have to make that the new values match the # valuse from the previous entry-point. parameters = [] return_type = "void" child = element.children while child: if child.type == "element": if child.name == "return": return_type = child.nsProp( "type", None ) elif child.name == "param": param = self.context.factory.create_item( "parameter", child, self.context) parameters.append( param ) child = child.next if self.initialized: if self.return_type != return_type: raise RuntimeError( "Return type changed in %s. Was %s, now %s." % (name, self.return_type, return_type)) if len(parameters) != len(self.parameters): raise RuntimeError( "Parameter count mismatch in %s. Was %d, now %d." % (name, len(self.parameters), len(parameters))) for j in range(0, len(parameters)): p1 = parameters[j] p2 = self.parameters[j] if not p1.compatible( p2 ): raise RuntimeError( 'Parameter type mismatch in %s. "%s" was "%s", now "%s".' % (name, p2.name, p2.type_expr.original_string, p1.type_expr.original_string)) if true_name == name or not self.initialized: self.return_type = return_type self.parameters = parameters for param in self.parameters: if param.is_image(): self.images.append( param ) if element.children: self.initialized = 1 self.parameter_strings[name] = create_parameter_string(parameters, 1) else: self.parameter_strings[name] = None return def get_images(self): """Return potentially empty list of input images.""" return self.images def parameterIterator(self): return self.parameters.__iter__(); def get_parameter_string(self, entrypoint = None): if entrypoint: s = self.parameter_strings[ entrypoint ] if s: return s return create_parameter_string( self.parameters, 1 ) class gl_item_factory: """Factory to create objects derived from gl_item.""" def create_item(self, item_name, element, context): if item_name == "function": return gl_function(element, context) if item_name == "type": return gl_type(element, context) elif item_name == "enum": return gl_enum(element, context) elif item_name == "parameter": return gl_parameter(element, context) elif item_name == "api": return gl_api(self) else: return None class gl_api: def __init__(self, factory): self.functions_by_name = {} self.enums_by_name = {} self.types_by_name = {} self.category_dict = {} self.factory = factory typeexpr.create_initial_types() return def process_element(self, doc): element = doc.children while element.type != "element" or element.name != "OpenGLAPI": element = element.next if element: self.process_OpenGLAPI(element) return def process_OpenGLAPI(self, element): child = element.children while child: if child.type == "element": if child.name == "category": self.process_category( child ) elif child.name == "OpenGLAPI": self.process_OpenGLAPI( child ) child = child.next return def process_category(self, cat): cat_name = cat.nsProp( "name", None ) cat_number = cat.nsProp( "number", None ) child = cat.children while child: if child.type == "element": if child.name == "function": func_name = real_function_name( child ) temp_name = child.nsProp( "name", None ) self.category_dict[ temp_name ] = [cat_name, cat_number] if self.functions_by_name.has_key( func_name ): func = self.functions_by_name[ func_name ] func.process_element( child ) else: func = self.factory.create_item( "function", child, self ) self.functions_by_name[ func_name ] = func elif child.name == "enum": enum = self.factory.create_item( "enum", child, self ) self.enums_by_name[ enum.name ] = enum elif child.name == "type": t = self.factory.create_item( "type", child, self ) self.types_by_name[ "GL" + t.name ] = t child = child.next return def functionIterateByOffset(self): max_offset = -1 for func in self.functions_by_name.itervalues(): if func.offset > max_offset: max_offset = func.offset temp = [None for i in range(0, max_offset + 1)] for func in self.functions_by_name.itervalues(): if func.offset != -1: temp[ func.offset ] = func list = [] for i in range(0, max_offset + 1): if temp[i]: list.append(temp[i]) return list.__iter__(); def functionIterateAll(self): return self.functions_by_name.itervalues() def enumIterateByName(self): keys = self.enums_by_name.keys() keys.sort() list = [] for enum in keys: list.append( self.enums_by_name[ enum ] ) return list.__iter__() def get_category_for_name( self, name ): if self.category_dict.has_key(name): return self.category_dict[name] else: return ["", None] def typeIterate(self): return self.types_by_name.itervalues() def find_type( self, type_name ): if type_name in self.types_by_name: return self.types_by_name[ type_name ].type_expr else: print "Unable to find base type matching \"%s\"." % (type_name) return None