Preliminary interactive layout of window manager's demo_launcher.
[chromium-blink-merge.git] / ppapi / generate_ppapi_size_checks.py
blob11b4d9884e3473eabd816d5e776c3edf85c8f7bd
1 #!/usr/bin/env python
2 # Copyright (c) 2012 The Chromium Authors. All rights reserved.
3 # Use of this source code is governed by a BSD-style license that can be
4 # found in the LICENSE file.
6 """This script should be run manually on occasion to make sure all PPAPI types
7 have appropriate size checking.
8 """
10 import optparse
11 import os
12 import subprocess
13 import sys
16 # The string that the PrintNamesAndSizes plugin uses to indicate a type is
17 # expected to have architecture-dependent size.
18 ARCH_DEPENDENT_STRING = "ArchDependentSize"
21 COPYRIGHT_STRING_C = (
22 """/* Copyright (c) %s The Chromium Authors. All rights reserved.
23 * Use of this source code is governed by a BSD-style license that can be
24 * found in the LICENSE file.
26 * This file has compile assertions for the sizes of types that are dependent
27 * on the architecture for which they are compiled (i.e., 32-bit vs 64-bit).
30 """) % datetime.date.today().year
33 class SourceLocation(object):
34 """A class representing the source location of a definiton."""
36 def __init__(self, filename="", start_line=-1, end_line=-1):
37 self.filename = os.path.normpath(filename)
38 self.start_line = start_line
39 self.end_line = end_line
42 class TypeInfo(object):
43 """A class representing information about a C++ type. It contains the
44 following fields:
45 - kind: The Clang TypeClassName (Record, Enum, Typedef, Union, etc)
46 - name: The unmangled string name of the type.
47 - size: The size in bytes of the type.
48 - arch_dependent: True if the type may have architecture dependent size
49 according to PrintNamesAndSizes. False otherwise. Types
50 which are considered architecture-dependent from 32-bit
51 to 64-bit are pointers, longs, unsigned longs, and any
52 type that contains an architecture-dependent type.
53 - source_location: A SourceLocation describing where the type is defined.
54 - target: The target Clang was compiling when it found the type definition.
55 This is used only for diagnostic output.
56 - parsed_line: The line which Clang output which was used to create this
57 TypeInfo (as the info_string parameter to __init__). This is
58 used only for diagnostic output.
59 """
61 def __init__(self, info_string, target):
62 """Create a TypeInfo from a given info_string. Also store the name of the
63 target for which the TypeInfo was first created just so we can print useful
64 error information.
65 info_string is a comma-delimited string of the following form:
66 kind,name,size,arch_dependent,source_file,start_line,end_line
67 Where:
68 - kind: The Clang TypeClassName (Record, Enum, Typedef, Union, etc)
69 - name: The unmangled string name of the type.
70 - size: The size in bytes of the type.
71 - arch_dependent: 'ArchDependentSize' if the type has architecture-dependent
72 size, NotArchDependentSize otherwise.
73 - source_file: The source file in which the type is defined.
74 - first_line: The first line of the definition (counting from 0).
75 - last_line: The last line of the definition (counting from 0).
76 This should match the output of the PrintNamesAndSizes plugin.
77 """
78 [self.kind, self.name, self.size, arch_dependent_string, source_file,
79 start_line, end_line] = info_string.split(',')
80 self.target = target
81 self.parsed_line = info_string
82 # Note that Clang counts line numbers from 1, but we want to count from 0.
83 self.source_location = SourceLocation(source_file,
84 int(start_line)-1,
85 int(end_line)-1)
86 self.arch_dependent = (arch_dependent_string == ARCH_DEPENDENT_STRING)
89 class FilePatch(object):
90 """A class representing a set of line-by-line changes to a particular file.
91 None of the changes are applied until Apply is called. All line numbers are
92 counted from 0.
93 """
95 def __init__(self, filename):
96 self.filename = filename
97 self.linenums_to_delete = set()
98 # A dictionary from line number to an array of strings to be inserted at
99 # that line number.
100 self.lines_to_add = {}
102 def Delete(self, start_line, end_line):
103 """Make the patch delete the lines starting with |start_line| up to but not
104 including |end_line|.
106 self.linenums_to_delete |= set(range(start_line, end_line))
108 def Add(self, text, line_number):
109 """Add the given text before the text on the given line number."""
110 if line_number in self.lines_to_add:
111 self.lines_to_add[line_number].append(text)
112 else:
113 self.lines_to_add[line_number] = [text]
115 def Apply(self):
116 """Apply the patch by writing it to self.filename."""
117 # Read the lines of the existing file in to a list.
118 sourcefile = open(self.filename, "r")
119 file_lines = sourcefile.readlines()
120 sourcefile.close()
121 # Now apply the patch. Our strategy is to keep the array at the same size,
122 # and just edit strings in the file_lines list as necessary. When we delete
123 # lines, we just blank the line and keep it in the list. When we add lines,
124 # we just prepend the added source code to the start of the existing line at
125 # that line number. This way, all the line numbers we cached from calls to
126 # Add and Delete remain valid list indices, and we don't have to worry about
127 # maintaining any offsets. Each element of file_lines at the end may
128 # contain any number of lines (0 or more) delimited by carriage returns.
129 for linenum_to_delete in self.linenums_to_delete:
130 file_lines[linenum_to_delete] = "";
131 for linenum, sourcelines in self.lines_to_add.items():
132 # Sort the lines we're adding so we get relatively consistent results.
133 sourcelines.sort()
134 # Prepend the new lines. When we output
135 file_lines[linenum] = "".join(sourcelines) + file_lines[linenum]
136 newsource = open(self.filename, "w")
137 for line in file_lines:
138 newsource.write(line)
139 newsource.close()
142 def CheckAndInsert(typeinfo, typeinfo_map):
143 """Check if a TypeInfo exists already in the given map with the same name. If
144 so, make sure the size is consistent.
145 - If the name exists but the sizes do not match, print a message and
146 exit with non-zero exit code.
147 - If the name exists and the sizes match, do nothing.
148 - If the name does not exist, insert the typeinfo in to the map.
151 # If the type is unnamed, ignore it.
152 if typeinfo.name == "":
153 return
154 # If the size is 0, ignore it.
155 elif int(typeinfo.size) == 0:
156 return
157 # If the type is not defined under ppapi, ignore it.
158 elif typeinfo.source_location.filename.find("ppapi") == -1:
159 return
160 # If the type is defined under GLES2, ignore it.
161 elif typeinfo.source_location.filename.find("GLES2") > -1:
162 return
163 # If the type is an interface (by convention, starts with PPP_ or PPB_),
164 # ignore it.
165 elif (typeinfo.name[:4] == "PPP_") or (typeinfo.name[:4] == "PPB_"):
166 return
167 elif typeinfo.name in typeinfo_map:
168 if typeinfo.size != typeinfo_map[typeinfo.name].size:
169 print "Error: '" + typeinfo.name + "' is", \
170 typeinfo_map[typeinfo.name].size, \
171 "bytes on target '" + typeinfo_map[typeinfo.name].target + \
172 "', but", typeinfo.size, "on target '" + typeinfo.target + "'"
173 print typeinfo_map[typeinfo.name].parsed_line
174 print typeinfo.parsed_line
175 sys.exit(1)
176 else:
177 # It's already in the map and the sizes match.
178 pass
179 else:
180 typeinfo_map[typeinfo.name] = typeinfo
183 def ProcessTarget(clang_command, target, types):
184 """Run clang using the given clang_command for the given target string. Parse
185 the output to create TypeInfos for each discovered type. Insert each type in
186 to the 'types' dictionary. If the type already exists in the types
187 dictionary, make sure that the size matches what's already in the map. If
188 not, exit with an error message.
190 p = subprocess.Popen(clang_command + " -triple " + target,
191 shell=True,
192 stdout=subprocess.PIPE)
193 lines = p.communicate()[0].split()
194 for line in lines:
195 typeinfo = TypeInfo(line, target)
196 CheckAndInsert(typeinfo, types)
199 def ToAssertionCode(typeinfo):
200 """Convert the TypeInfo to an appropriate C compile assertion.
201 If it's a struct (Record in Clang terminology), we want a line like this:
202 PP_COMPILE_ASSERT_STRUCT_SIZE_IN_BYTES(<name>, <size>);\n
203 Enums:
204 PP_COMPILE_ASSERT_ENUM_SIZE_IN_BYTES(<name>, <size>);\n
205 Typedefs:
206 PP_COMPILE_ASSERT_SIZE_IN_BYTES(<name>, <size>);\n
209 line = "PP_COMPILE_ASSERT_"
210 if typeinfo.kind == "Enum":
211 line += "ENUM_"
212 elif typeinfo.kind == "Record":
213 line += "STRUCT_"
214 line += "SIZE_IN_BYTES("
215 line += typeinfo.name
216 line += ", "
217 line += typeinfo.size
218 line += ");\n"
219 return line
222 def IsMacroDefinedName(typename):
223 """Return true iff the given typename came from a PPAPI compile assertion."""
224 return typename.find("PP_Dummy_Struct_For_") == 0
227 def WriteArchSpecificCode(types, root, filename):
228 """Write a header file that contains a compile-time assertion for the size of
229 each of the given typeinfos, in to a file named filename rooted at root.
231 assertion_lines = [ToAssertionCode(typeinfo) for typeinfo in types]
232 assertion_lines.sort()
233 outfile = open(os.path.join(root, filename), "w")
234 header_guard = "PPAPI_TESTS_" + filename.upper().replace(".", "_") + "_"
235 outfile.write(COPYRIGHT_STRING_C)
236 outfile.write('#ifndef ' + header_guard + '\n')
237 outfile.write('#define ' + header_guard + '\n\n')
238 outfile.write('#include "ppapi/tests/test_struct_sizes.c"\n\n')
239 for line in assertion_lines:
240 outfile.write(line)
241 outfile.write('\n#endif /* ' + header_guard + ' */\n')
244 def main(argv):
245 # See README file for example command-line invocation. This script runs the
246 # PrintNamesAndSizes Clang plugin with 'test_struct_sizes.c' as input, which
247 # should include all C headers and all existing size checks. It runs the
248 # plugin multiple times; once for each of a set of targets, some 32-bit and
249 # some 64-bit. It verifies that wherever possible, types have a consistent
250 # size on both platforms. Types that can't easily have consistent size (e.g.
251 # ones that contain a pointer) are checked to make sure they are consistent
252 # for all 32-bit platforms and consistent on all 64-bit platforms, but the
253 # sizes on 32 vs 64 are allowed to differ.
255 # Then, if all the types have consistent size as expected, compile assertions
256 # are added to the source code. Types whose size is independent of
257 # architectureacross have their compile assertions placed immediately after
258 # their definition in the C API header. Types whose size differs on 32-bit
259 # vs 64-bit have a compile assertion placed in each of:
260 # ppapi/tests/arch_dependent_sizes_32.h and
261 # ppapi/tests/arch_dependent_sizes_64.h.
263 # Note that you should always check the results of the tool to make sure
264 # they are sane.
265 parser = optparse.OptionParser()
266 parser.add_option(
267 '-c', '--clang-path', dest='clang_path',
268 default=(''),
269 help='the path to the clang binary (default is to get it from your path)')
270 parser.add_option(
271 '-p', '--plugin', dest='plugin',
272 default='tests/clang/libPrintNamesAndSizes.so',
273 help='The path to the PrintNamesAndSizes plugin library.')
274 parser.add_option(
275 '--targets32', dest='targets32',
276 default='i386-pc-linux,arm-pc-linux,i386-pc-win32',
277 help='Which 32-bit target triples to provide to clang.')
278 parser.add_option(
279 '--targets64', dest='targets64',
280 default='x86_64-pc-linux,x86_64-pc-win',
281 help='Which 32-bit target triples to provide to clang.')
282 parser.add_option(
283 '-r', '--ppapi-root', dest='ppapi_root',
284 default='.',
285 help='The root directory of ppapi.')
286 options, args = parser.parse_args(argv)
287 if args:
288 parser.print_help()
289 print 'ERROR: invalid argument'
290 sys.exit(1)
292 clang_executable = os.path.join(options.clang_path, 'clang')
293 clang_command = clang_executable + " -cc1" \
294 + " -load " + options.plugin \
295 + " -plugin PrintNamesAndSizes" \
296 + " -I" + os.path.join(options.ppapi_root, "..") \
297 + " " \
298 + os.path.join(options.ppapi_root, "tests", "test_struct_sizes.c")
300 # Dictionaries mapping type names to TypeInfo objects.
301 # Types that have size dependent on architecture, for 32-bit
302 types32 = {}
303 # Types that have size dependent on architecture, for 64-bit
304 types64 = {}
305 # Note that types32 and types64 should contain the same types, but with
306 # different sizes.
308 # Types whose size should be consistent regardless of architecture.
309 types_independent = {}
311 # Now run clang for each target. Along the way, make sure architecture-
312 # dependent types are consistent sizes on all 32-bit platforms and consistent
313 # on all 64-bit platforms.
314 targets32 = options.targets32.split(',');
315 for target in targets32:
316 # For each 32-bit target, run the PrintNamesAndSizes Clang plugin to get
317 # information about all types in the translation unit, and add a TypeInfo
318 # for each of them to types32. If any size mismatches are found,
319 # ProcessTarget will spit out an error and exit.
320 ProcessTarget(clang_command, target, types32)
321 targets64 = options.targets64.split(',');
322 for target in targets64:
323 # Do the same as above for each 64-bit target; put all types in types64.
324 ProcessTarget(clang_command, target, types64)
326 # Now for each dictionary, find types whose size are consistent regardless of
327 # architecture, and move those in to types_independent. Anywhere sizes
328 # differ, make sure they are expected to be architecture-dependent based on
329 # their structure. If we find types which could easily be consistent but
330 # aren't, spit out an error and exit.
331 types_independent = {}
332 for typename, typeinfo32 in types32.items():
333 if (typename in types64):
334 typeinfo64 = types64[typename]
335 if (typeinfo64.size == typeinfo32.size):
336 # The types are the same size, so we can treat it as arch-independent.
337 types_independent[typename] = typeinfo32
338 del types32[typename]
339 del types64[typename]
340 elif (typeinfo32.arch_dependent or typeinfo64.arch_dependent):
341 # The type is defined in such a way that it would be difficult to make
342 # its size consistent. E.g., it has pointers. We'll leave it in the
343 # arch-dependent maps so that we can put arch-dependent size checks in
344 # test code.
345 pass
346 else:
347 # The sizes don't match, but there's no reason they couldn't. It's
348 # probably due to an alignment mismatch between Win32/NaCl vs Linux32/
349 # Mac32.
350 print "Error: '" + typename + "' is", typeinfo32.size, \
351 "bytes on target '" + typeinfo32.target + \
352 "', but", typeinfo64.size, "on target '" + typeinfo64.target + "'"
353 print typeinfo32.parsed_line
354 print typeinfo64.parsed_line
355 sys.exit(1)
356 else:
357 print "WARNING: Type '", typename, "' was defined for target '",
358 print typeinfo32.target, ", but not for any 64-bit targets."
360 # Now we have all the information we need to generate our static assertions.
361 # Types that have consistent size across architectures will have the static
362 # assertion placed immediately after their definition. Types whose size
363 # depends on 32-bit vs 64-bit architecture will have checks placed in
364 # tests/arch_dependent_sizes_32/64.h.
366 # This dictionary maps file names to FilePatch objects. We will add items
367 # to it as needed. Each FilePatch represents a set of changes to make to the
368 # associated file (additions and deletions).
369 file_patches = {}
371 # Find locations of existing macros, and just delete them all. Note that
372 # normally, only things in 'types_independent' need to be deleted, as arch-
373 # dependent checks exist in tests/arch_dependent_sizes_32/64.h, which are
374 # always completely over-ridden. However, it's possible that a type that used
375 # to be arch-independent has changed to now be arch-dependent (e.g., because
376 # a pointer was added), and we want to delete the old check in that case.
377 for name, typeinfo in \
378 types_independent.items() + types32.items() + types64.items():
379 if IsMacroDefinedName(name):
380 sourcefile = typeinfo.source_location.filename
381 if sourcefile not in file_patches:
382 file_patches[sourcefile] = FilePatch(sourcefile)
383 file_patches[sourcefile].Delete(typeinfo.source_location.start_line,
384 typeinfo.source_location.end_line+1)
386 # Add a compile-time assertion for each type whose size is independent of
387 # architecture. These assertions go immediately after the class definition.
388 for name, typeinfo in types_independent.items():
389 # Ignore dummy types that were defined by macros and also ignore types that
390 # are 0 bytes (i.e., typedefs to void).
391 if not IsMacroDefinedName(name) and typeinfo.size > 0:
392 sourcefile = typeinfo.source_location.filename
393 if sourcefile not in file_patches:
394 file_patches[sourcefile] = FilePatch(sourcefile)
395 # Add the assertion code just after the definition of the type.
396 # E.g.:
397 # struct Foo {
398 # int32_t x;
399 # };
400 # PP_COMPILE_ASSERT_STRUCT_SIZE_IN_BYTES(Foo, 4); <---Add this line
401 file_patches[sourcefile].Add(ToAssertionCode(typeinfo),
402 typeinfo.source_location.end_line+1)
404 # Apply our patches. This actually edits the files containing the definitions
405 # for the types in types_independent.
406 for filename, patch in file_patches.items():
407 patch.Apply()
409 # Write out a file of checks for 32-bit architectures and a separate file for
410 # 64-bit architectures. These only have checks for types that are
411 # architecture-dependent.
412 c_source_root = os.path.join(options.ppapi_root, "tests")
413 WriteArchSpecificCode(types32.values(),
414 c_source_root,
415 "arch_dependent_sizes_32.h")
416 WriteArchSpecificCode(types64.values(),
417 c_source_root,
418 "arch_dependent_sizes_64.h")
420 return 0
423 if __name__ == '__main__':
424 sys.exit(main(sys.argv[1:]))