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#----------------------------------------------------------------- # pycparser: explore_ast.py # # This example demonstrates how to "explore" the AST created by # pycparser to understand its structure. The AST is a n-nary tree # of nodes, each node having several children, each with a name. # Just read the code, and let the comments guide you. The lines # beginning with #~ can be uncommented to print out useful # information from the AST. # It helps to have the pycparser/_c_ast.cfg file in front of you. # # Copyright (C) 2008-2015, Eli Bendersky # License: BSD #----------------------------------------------------------------- from __future__ import print_function import sys from pycparser import c_parser, c_ast # This is some C source to parse. Note that pycparser must begin # at the top level of the C file, i.e. with either declarations # or function definitions (this is called "external declarations" # in C grammar lingo) # # Also, a C parser must have all the types declared in order to # build the correct AST. It doesn't matter what they're declared # to, so I've inserted the dummy typedef in the code to let the # parser know Hash and Node are types. You don't need to do it # when parsing real, correct C code. # text = r""" typedef int Node, Hash; void HashPrint(Hash* hash, void (*PrintFunc)(char*, char*)) { unsigned int i; if (hash == NULL || hash->heads == NULL) return; for (i = 0; i < hash->table_size; ++i) { Node* temp = hash->heads[i]; while (temp != NULL) { PrintFunc(temp->entry->key, temp->entry->value); temp = temp->next; } } } """ # Create the parser and ask to parse the text. parse() will throw # a ParseError if there's an error in the code # parser = c_parser.CParser() ast = parser.parse(text, filename='<none>') # Uncomment the following line to see the AST in a nice, human # readable way. show() is the most useful tool in exploring ASTs # created by pycparser. See the c_ast.py file for the options you # can pass it. # #~ ast.show() # OK, we've seen that the top node is FileAST. This is always the # top node of the AST. Its children are "external declarations", # and are stored in a list called ext[] (see _c_ast.cfg for the # names and types of Nodes and their children). # As you see from the printout, our AST has two Typedef children # and one FuncDef child. # Let's explore FuncDef more closely. As I've mentioned, the list # ext[] holds the children of FileAST. Since the function # definition is the third child, it's ext[2]. Uncomment the # following line to show it: # #~ ast.ext[2].show() # A FuncDef consists of a declaration, a list of parameter # declarations (for K&R style function definitions), and a body. # First, let's examine the declaration. # function_decl = ast.ext[2].decl # function_decl, like any other declaration, is a Decl. Its type child # is a FuncDecl, which has a return type and arguments stored in a # ParamList node #~ function_decl.type.show() #~ function_decl.type.args.show() # The following displays the name and type of each argument: # #~ for param_decl in function_decl.type.args.params: #~ print('Arg name: %s' % param_decl.name) #~ print('Type:') #~ param_decl.type.show(offset=6) # The body is of FuncDef is a Compound, which is a placeholder for a block # surrounded by {} (You should be reading _c_ast.cfg parallel to this # explanation and seeing these things with your own eyes). # Let's see the block's declarations: # function_body = ast.ext[2].body # The following displays the declarations and statements in the function # body # #~ for decl in function_body.block_items: #~ decl.show() # We can see a single variable declaration, i, declared to be a simple type # declaration of type 'unsigned int', followed by statements. # block_items is a list, so the third element is the For statement: # for_stmt = function_body.block_items[2] #~ for_stmt.show() # As you can see in _c_ast.cfg, For's children are 'init, cond, # next' for the respective parts of the 'for' loop specifier, # and stmt, which is either a single stmt or a Compound if there's # a block. # # Let's dig deeper, to the while statement inside the for loop: # while_stmt = for_stmt.stmt.block_items[1] #~ while_stmt.show() # While is simpler, it only has a condition node and a stmt node. # The condition: # while_cond = while_stmt.cond #~ while_cond.show() # Note that it's a BinaryOp node - the basic constituent of # expressions in our AST. BinaryOp is the expression tree, with # left and right nodes as children. It also has the op attribute, # which is just the string representation of the operator. # #~ print(while_cond.op) #~ while_cond.left.show() #~ while_cond.right.show() # # That's it for the example. I hope you now see how easy it is to explore the # AST created by pycparser. Although on the surface it is quite complex and has # a lot of node types, this is the inherent complexity of the C language every # parser/compiler designer has to cope with. # Using the tools provided by the c_ast package it's easy to explore the # structure of AST nodes and write code that processes them. # Specifically, see the cdecl.py example for a non-trivial demonstration of what # you can do by recursively going through the AST. #