#!/usr/bin/env python ''' emcc - compiler helper script ============================= emcc is a drop-in replacement for a compiler like gcc or clang. Tell your build system to use this instead of the compiler, and similarly use emar, emld and emranlib instead of the same command without 'em'. Example uses: * For configure, instead of ./configure, cmake, etc., run emconfigure.py with that command as an argument, for example emconfigure.py ./configure [options] emconfigure.py is a tiny script that just sets some environment vars as a convenience. The command just shown is equivalent to EMMAKEN_JUST_CONFIGURE=1 RANLIB=PATH/emranlib AR=PATH/emar CXX=PATH/em++ CC=PATH/emcc ./configure [options] where PATH is the path to this file. EMMAKEN_JUST_CONFIGURE tells emcc that it is being run in ./configure, so it should relay everything to gcc/g++. You should not define that when running make, of course. * With CMake, the same command will work (with cmake instead of ./configure). You may also be able to do the following in your CMakeLists.txt: SET(CMAKE_C_COMPILER "PATH/emcc") SET(CMAKE_CXX_COMPILER "PATH/em++") SET(CMAKE_LINKER "PATH/emld") SET(CMAKE_CXX_LINKER "PATH/emld") SET(CMAKE_C_LINK_EXECUTABLE "PATH/emld") SET(CMAKE_CXX_LINK_EXECUTABLE "PATH/emld") SET(CMAKE_AR "PATH/emar") SET(CMAKE_RANLIB "PATH/emranlib") * For SCons the shared.py can be imported like so: __file__ = str(Dir('#/project_path_to_emscripten/dummy/dummy')) __rootpath__ = os.path.abspath(os.path.dirname(os.path.dirname(__file__))) def path_from_root(*pathelems): return os.path.join(__rootpath__, *pathelems) exec(open(path_from_root('tools', 'shared.py'), 'r').read()) For using the Emscripten compilers/linkers/etc. you can do: env = Environment() ... env.Append(CCFLAGS = COMPILER_OPTS) env.Replace(LINK = LLVM_LD) env.Replace(LD = LLVM_LD) TODO: Document all relevant setup changes After setting that up, run your build system normally. Note the appearance of em++ instead of emcc for the C++ compiler. This is needed for cases where we get a C++ file with a C extension, in which case CMake can be told to run g++ on it despite the .c extension, see https://github.com/kripken/emscripten/issues/6 (If a similar situation occurs with ./configure, you can do the same there too.) emcc can be influenced by a few environment variables: EMMAKEN_NO_SDK - Will tell emcc *not* to use the emscripten headers. Instead your system headers will be used. EMMAKEN_COMPILER - The compiler to be used, if you don't want the default clang. ''' import os, sys, shutil, tempfile from subprocess import Popen, PIPE, STDOUT from tools import shared DEBUG = os.environ.get('EMCC_DEBUG') TEMP_DIR = os.environ.get('EMCC_TEMP_DIR') LEAVE_INPUTS_RAW = os.environ.get('EMCC_LEAVE_INPUTS_RAW') # Do not compile .ll files into .bc, just compile them with emscripten directly # Not recommended, this is mainly for the test runner, or if you have some other # specific need. # One major limitation with this mode is that dlmalloc and libc++ cannot be # added in. Also, LLVM optimizations will not be done, nor dead code elimination if DEBUG: print >> sys.stderr, 'emcc: ', ' '.join(sys.argv) if DEBUG and LEAVE_INPUTS_RAW: print >> sys.stderr, 'emcc: leaving inputs raw' shared.check_sanity() # Handle some global flags if len(sys.argv) == 1: print 'emcc: no input files' exit(0) if sys.argv[1] == '--version': print '''emcc (Emscripten GCC-like replacement) 2.0 Copyright (C) 2011 the Emscripten authors. This is free and open source software under the MIT license. There is NO warranty; not even for MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. ''' exit(0) elif sys.argv[1] == '--help': this = os.path.basename('em++' if os.environ.get('EMMAKEN_CXX') else 'emcc') print '''%s [options] file... Most normal gcc/g++ options will work, for example: --help Display this information --version Display compiler version information Options that are modified or new in %s include: -O0 No optimizations (default) -O1 Simple optimizations, including safe LLVM optimizations, and no runtime assertions or C++ exception catching (to re-enable C++ exception catching, use -s DISABLE_EXCEPTION_CATCHING=0 ). Note: Optimizations are only done when compiling to JavaScript, not to intermediate bitcode. -O2 As -O1, plus the relooper (loop recreation), plus closure compiler advanced opts Warning: Compiling with this takes a long time! -O3 As -O2, plus dangerous optimizations that may break the generated code! If that happens, try -O2 and then adding dangerous optimizations one by one. -s OPTION=VALUE JavaScript code generation option passed into the emscripten compiler --typed-arrays 0: No typed arrays 1: Parallel typed arrays 2: Shared (C-like) typed arrays (default) --llvm-opts 0: No LLVM optimizations (default in -O0) 1: Safe/portable LLVM optimizations (default in -O1 and above) 2: Full, unsafe/unportable LLVM optimizations; this will almost certainly break the generated code! --closure 0: No closure compiler (default in -O0, -O1) 1: Run closure compiler (default in -O2, -O3) --js-transform will be called on the generated code before it is optimized. This lets you modify the JavaScript, for example adding some code or removing some code, in a way that those modifications will be optimized together with the generated code properly. will be called with the filename of the generated code as a parameter; to modify the code, you can read the original data and then append to it or overwrite it with the modified data. is interpreted as a space-separated list of arguments, for example, of "python processor.py" will cause a python script to be run. --compress 0: Do not compress the generated JavaScript's whitespace (default if closure compiler will not be run) 1: Compress the generated JavaScript's whitespace (default if closure compiler will be run). Note that this by itself will not minify the code (closure does that) The target file, if specified (-o ), defines what will be generated: .js JavaScript (default) .html HTML with embedded JavaScript .bc LLVM bitcode .o LLVM bitcode The -c option (which tells gcc not to run the linker) will cause LLVM bitcode to be generated, as %s only generates JavaScript in the final linking stage of building. The input file(s) can be either source code files that Clang can handle (C or C++), LLVM bitcode in binary form, or LLVM assembly files in human-readable form. ''' % (this, this, this) exit(0) # If this is a configure-type thing, do not compile to JavaScript, instead use clang # to compile to a native binary (using our headers, so things make sense later) CONFIGURE_CONFIG = os.environ.get('EMMAKEN_JUST_CONFIGURE') CMAKE_CONFIG = 'CMakeFiles/cmTryCompileExec.dir' in ' '.join(sys.argv)# or 'CMakeCCompilerId' in ' '.join(sys.argv) if CONFIGURE_CONFIG or CMAKE_CONFIG: compiler = shared.CLANG if not ('CXXCompiler' in ' '.join(sys.argv) or os.environ.get('EMMAKEN_CXX')): compiler = shared.to_cc(compiler) cmd = [compiler] + shared.EMSDK_OPTS + sys.argv[1:] if DEBUG: print >> sys.stderr, 'emcc, just configuring: ', compiler, cmd exit(os.execvp(compiler, cmd)) if os.environ.get('EMMAKEN_COMPILER'): CXX = os.environ['EMMAKEN_COMPILER'] else: CXX = shared.CLANG CC = shared.to_cc(CXX) # If we got here from a redirection through emmakenxx.py, then force a C++ compiler here if os.environ.get('EMMAKEN_CXX'): CC = CXX CC_ADDITIONAL_ARGS = shared.COMPILER_OPTS # + ['-g']? EMMAKEN_CFLAGS = os.environ.get('EMMAKEN_CFLAGS') if EMMAKEN_CFLAGS: CC_ADDITIONAL_ARGS += EMMAKEN_CFLAGS.split(' ') # ---------------- Utilities --------------- SOURCE_SUFFIXES = ('.c', '.cpp', '.cxx', '.cc') BITCODE_SUFFIXES = ('.bc', '.o', '.ll') def unsuffixed(name): return '.'.join(name.split('.')[:-1]) def unsuffixed_basename(name): return os.path.basename(unsuffixed(name)) LLVM_INTERNAL_OPT_LEVEL = 2 # ---------------- End configs ------------- if len(sys.argv) == 1 or sys.argv[1] in ['x', 't']: # noop ar if DEBUG: print >> sys.stderr, 'emcc, just ar' sys.exit(0) use_cxx = True header = False # pre-compiled headers. We fake that by just copying the file for i in range(1, len(sys.argv)): arg = sys.argv[i] if not arg.startswith('-'): if arg.endswith('.c'): use_cxx = False if arg.endswith('.h') and sys.argv[i-1] != '-include': header = True # Check if a target is specified target = None for i in range(len(sys.argv)-1): if sys.argv[i].startswith('-o='): raise Exception('Invalid syntax: do not use -o=X, use -o X') if sys.argv[i] == '-o': target = sys.argv[i+1] sys.argv = sys.argv[:i] + sys.argv[i+2:] break if header: # header or such if DEBUG: print >> sys.stderr, 'Just copy.' shutil.copy(sys.argv[-1], sys.argv[-2]) exit(0) if TEMP_DIR: temp_dir = TEMP_DIR if os.path.exists(temp_dir): shutil.rmtree(temp_dir) # clear it os.makedirs(temp_dir) else: temp_dir = tempfile.mkdtemp() def in_temp(name): return os.path.join(temp_dir, name) try: call = CXX if use_cxx else CC ## Parse args newargs = sys.argv[1:] opt_level = 0 llvm_opt_level = None closure = None js_transform = None compress_whitespace = None def check_bad_eq(arg): assert '=' not in arg, 'Invalid parameter (do not use "=" with "--" options)' for i in range(len(newargs)): if newargs[i].startswith('-O'): try: opt_level = int(newargs[i][2]) assert 0 <= opt_level <= 3 except: raise Exception('Invalid optimization level: ' + newargs[i]) newargs[i] = '' elif newargs[i].startswith('--llvm-opts'): check_bad_eq(newargs[i]) llvm_opt_level = eval(newargs[i+1]) assert 0 <= llvm_opt_level <= 1, 'Only two levels of LLVM optimizations are supported so far, 0 (none) and 1 (safe)' newargs[i] = '' newargs[i+1] = '' elif newargs[i].startswith('--closure'): check_bad_eq(newargs[i]) closure = int(newargs[i+1]) newargs[i] = '' newargs[i+1] = '' elif newargs[i].startswith('--js-transform'): check_bad_eq(newargs[i]) js_transform = newargs[i+1] newargs[i] = '' newargs[i+1] = '' elif newargs[i].startswith('--compress'): check_bad_eq(newargs[i]) compress_whitespace = int(newargs[i+1]) newargs[i] = '' newargs[i+1] = '' elif newargs[i] == '-MF': # clang cannot handle this, so we fake it f = open(newargs[i+1], 'w') f.write('\n') f.close() newargs[i] = '' newargs[i+1] = '' newargs = [ arg for arg in newargs if arg is not '' ] if llvm_opt_level is None: llvm_opt_level = 1 if opt_level >= 1 else 0 if closure is None: closure = 1 if opt_level >= 2 else 0 if compress_whitespace is None: compress_whitespace = closure # if closure is run, compress whitespace if closure: assert os.path.exists(shared.CLOSURE_COMPILER), 'emcc: fatal: Closure compiler (%s) does not exist' % shared.CLOSURE_COMPILER settings_changes = [] for i in range(len(newargs)): if newargs[i] == '-s': assert '=' in newargs[i+1], 'Incorrect syntax for -s (use -s OPT=VAL): ' + newargs[i+1] settings_changes.append(newargs[i+1]) newargs[i] = newargs[i+1] = '' elif newargs[i].startswith('--typed-arrays'): assert '=' not in newargs[i], 'Invalid typed arrays parameter (do not use "=")' settings_changes.append('USE_TYPED_ARRAYS=' + newargs[i+1]) newargs[i] = '' newargs[i+1] = '' newargs = [ arg for arg in newargs if arg is not '' ] input_files = [] has_source_inputs = False for i in range(len(newargs)): # find input files XXX this a simple heuristic. we should really analyze based on a full understanding of gcc params, # right now we just assume that what is left contains no more |-x OPT| things arg = newargs[i] if arg.endswith(SOURCE_SUFFIXES + BITCODE_SUFFIXES): # we already removed -o , so all these should be inputs newargs[i] = '' if os.path.exists(arg): if arg.endswith(SOURCE_SUFFIXES): input_files.append(arg) has_source_inputs = True else: # this should be bitcode, make sure it is valid if arg.endswith('.ll') or shared.Building.is_bitcode(arg): input_files.append(arg) else: print >> sys.stderr, 'emcc: %s: Not valid LLVM bitcode' % arg else: print >> sys.stderr, 'emcc: %s: No such file or directory' % arg newargs = [ arg for arg in newargs if arg is not '' ] assert len(input_files) > 0, 'emcc: no input files' newargs += CC_ADDITIONAL_ARGS specified_target = target target = specified_target if specified_target is not None else 'a.out.js' # specified_target is the user-specified one, target is what we will generate target_basename = unsuffixed_basename(target) # -c means do not link in gcc, and for us, the parallel is to not go all the way to JS, but stop at bitcode has_dash_c = '-c' in newargs if has_dash_c: assert has_source_inputs, 'Must have source code inputs to use -c' target = target_basename + '.o' if '.' in target: final_suffix = target.split('.')[-1] else: final_suffix = '' # Apply optimization level settings shared.Settings.apply_opt_level(opt_level, noisy=True) # Apply -s settings in newargs here (after optimization levels, so they can override them) for change in settings_changes: key, value = change.split('=') exec('shared.Settings.' + key + ' = ' + value) ## Compile source code to bitcode if DEBUG: print >> sys.stderr, 'emcc: compiling to bitcode' # First, generate LLVM bitcode. For each input file, we get base.o with bitcode for input_file in input_files: if input_file.endswith(SOURCE_SUFFIXES): if DEBUG: print >> sys.stderr, 'emcc: compiling source file: ', input_file output_file = in_temp(unsuffixed_basename(input_file) + '.o') args = newargs + ['-emit-llvm', '-c', input_file, '-o', output_file] if DEBUG: print >> sys.stderr, "emcc running:", call, ' '.join(args) Popen([call] + args).communicate() # let compiler frontend print directly, so colors are saved (PIPE kills that) if not os.path.exists(output_file): print >> sys.stderr, 'emcc: compiler frontend failed to generate LLVM bitcode, halting' sys.exit(1) else: # bitcode if input_file.endswith(('.bc', '.o')): if DEBUG: print >> sys.stderr, 'emcc: copying bitcode file: ', input_file shutil.copyfile(input_file, in_temp(unsuffixed_basename(input_file) + '.o')) else: #.ll if not LEAVE_INPUTS_RAW: # Note that by assembling the .ll file, then disassembling it later, we will # remove annotations which is a good thing for compilation time if DEBUG: print >> sys.stderr, 'emcc: assembling assembly file: ', input_file shared.Building.llvm_as(input_file, in_temp(unsuffixed_basename(input_file) + '.o')) # If we were just asked to generate bitcode, stop there if final_suffix not in ['js', 'html']: if llvm_opt_level > 0: print >> sys.stderr, 'emcc: warning: -Ox flags ignored, since not generating JavaScript' if not specified_target: for input_file in input_files: shutil.move(in_temp(unsuffixed_basename(input_file) + '.o'), unsuffixed_basename(input_file) + '.' + final_suffix) else: if len(input_files) == 1: shutil.move(in_temp(unsuffixed_basename(input_files[0]) + '.o'), specified_target) else: assert not has_dash_c, 'fatal error: cannot specify -o with -c with multiple files' + str(sys.argv) # We have a specified target (-o ), which is not JavaScript or HTML, and # we have multiple files: Link them TODO: llvm link-time opts? ld_args = map(lambda input_file: in_temp(unsuffixed_basename(input_file) + '.o'), input_files) + \ ['-o', specified_target] #[arg.split('-Wl,')[1] for arg in filter(lambda arg: arg.startswith('-Wl,'), sys.argv)] if DEBUG: print >> sys.stderr, 'emcc: link: ' + str(ld_args) Popen([shared.LLVM_LINK] + ld_args).communicate() exit(0) ## Continue on to create JavaScript if DEBUG: print >> sys.stderr, 'emcc: will generate JavaScript' extra_files_to_link = [] if not LEAVE_INPUTS_RAW: # Check if we need to include some libraries that we compile. (We implement libc ourselves in js, but # compile a malloc implementation and stdlibc++.) # Note that we assume a single symbol is enough to know if we have/do not have dlmalloc etc. If you # include just a few symbols but want the rest, this will not work. # dlmalloc def create_dlmalloc(): if DEBUG: print >> sys.stderr, 'emcc: building dlmalloc for cache' Popen([shared.EMCC, shared.path_from_root('system', 'lib', 'dlmalloc.c'), '-g', '-o', in_temp('dlmalloc.o')], stdout=PIPE, stderr=PIPE).communicate() # we include the libc++ new stuff here, so that the common case of using just new/delete is quick to link Popen([shared.EMXX, shared.path_from_root('system', 'lib', 'libcxx', 'new.cpp'), '-g', '-o', in_temp('new.o')], stdout=PIPE, stderr=PIPE).communicate() shared.Building.link([in_temp('dlmalloc.o'), in_temp('new.o')], in_temp('dlmalloc_full.o')) return in_temp('dlmalloc_full.o') def fix_dlmalloc(): # dlmalloc needs some sign correction. # If we are in mode 0, switch to 2. We will add our lines try: if shared.Settings.CORRECT_SIGNS == 0: raise Exception('we need to change to 2') except: # we fail if equal to 0 - so we need to switch to 2 - or if CORRECT_SIGNS is not even in Settings shared.Settings.CORRECT_SIGNS = 2 if shared.Settings.CORRECT_SIGNS == 2: shared.Settings.CORRECT_SIGNS_LINES = [shared.path_from_root('src', 'dlmalloc.c') + ':' + str(i+4) for i in [4816, 4191, 4246, 4199, 4205, 4235, 4227]] # If we are in mode 1, we are correcting everything anyhow. If we are in mode 3, we will be corrected # so all is well anyhow too. # XXX We also need to add libc symbols that use malloc, for example strdup. It's very rare to use just them and not # a normal malloc symbol (like free, after calling strdup), so we haven't hit this yet, but it is possible. dlmalloc_symbols = open(shared.path_from_root('system', 'lib', 'dlmalloc.symbols')).read().split('\n') # libcxx def create_libcxx(): if DEBUG: print >> sys.stderr, 'emcc: building libcxx for cache' shared.Building.build_library('libcxx', shared.EMSCRIPTEN_TEMP_DIR, shared.EMSCRIPTEN_TEMP_DIR, ['libcxx.bc'], configure=None, copy_project=True, source_dir=shared.path_from_root('system', 'lib', 'libcxx')) return os.path.join(shared.EMSCRIPTEN_TEMP_DIR, 'libcxx', 'libcxx.bc') def fix_libcxx(): assert shared.Settings.QUANTUM_SIZE == 4, 'We do not support libc++ with QUANTUM_SIZE == 1' # libcxx might need corrections, so turn them all on. TODO: check which are actually needed shared.Settings.CORRECT_SIGNS = shared.Settings.CORRECT_OVERFLOWS = shared.Settings.CORRECT_ROUNDINGS = 1 print >> sys.stderr, 'emcc: warning: using libcxx turns on CORRECT_* options' libcxx_symbols = map(lambda line: line.strip().split(' ')[1], open(shared.path_from_root('system', 'lib', 'libcxx', 'symbols')).readlines()) libcxx_symbols = filter(lambda symbol: symbol not in dlmalloc_symbols, libcxx_symbols) libcxx_symbols = set(libcxx_symbols) force = False # If we have libcxx, we must force inclusion of dlmalloc, since libcxx uses new internally. Note: this is kind of hacky for name, create, fix, library_symbols in [('libcxx', create_libcxx, fix_libcxx, libcxx_symbols), ('dlmalloc', create_dlmalloc, fix_dlmalloc, dlmalloc_symbols)]: need = [] has = [] for input_file in input_files: symbols = shared.Building.llvm_nm(in_temp(unsuffixed_basename(input_file) + '.o')) for library_symbol in library_symbols: if library_symbol in symbols.undefs: need.append(library_symbol) if library_symbol in symbols.defs: has.append(library_symbol) if DEBUG: print >> sys.stderr, 'emcc: considering including %s: we need |%s| and have |%s|' % (name, str(need), str(has)) if force or (need and not has): # We need to build and link the library in if DEBUG: print >> sys.stderr, 'emcc: including %s' % name extra_files_to_link.append(shared.Cache.get(name, create)) force = True if fix: fix() # First, combine the bitcode files if there are several if len(input_files) + len(extra_files_to_link) > 1: linker_inputs = map(lambda input_file: in_temp(unsuffixed_basename(input_file) + '.o'), input_files) + extra_files_to_link if DEBUG: print >> sys.stderr, 'emcc: linking: ', linker_inputs shared.Building.link(linker_inputs, in_temp(target_basename + '.bc')) # TODO: LLVM link-time opts? here and/or elsewhere? else: if not LEAVE_INPUTS_RAW: shutil.move(in_temp(unsuffixed_basename(input_files[0]) + '.o'), in_temp(target_basename + '.bc')) # Optimize, if asked to if llvm_opt_level > 0 and not LEAVE_INPUTS_RAW: if DEBUG: print >> sys.stderr, 'emcc: LLVM opts' shared.Building.llvm_opt(in_temp(target_basename + '.bc'), LLVM_INTERNAL_OPT_LEVEL, safe=llvm_opt_level < 2) else: # If possible, remove dead functions etc., this potentially saves a lot in the size of the generated code (and the time to compile it) if not LEAVE_INPUTS_RAW and not shared.Settings.BUILD_AS_SHARED_LIB and not shared.Settings.LINKABLE: if DEBUG: print >> sys.stderr, 'emcc: LLVM dead globals elimination' shared.Building.llvm_opt(in_temp(target_basename + '.bc'), ['-internalize', '-globaldce']) # Emscripten try: if shared.Settings.RELOOP: print >> sys.stderr, 'emcc: warning: The relooper optimization can be very slow.' except: pass if DEBUG: print >> sys.stderr, 'emcc: saving intermediate processing steps to %s' % shared.EMSCRIPTEN_TEMP_DIR intermediate_counter = 0 def save_intermediate(name=None, suffix='js'): global intermediate_counter shutil.copyfile(final, os.path.join(shared.EMSCRIPTEN_TEMP_DIR, 'emcc-%d%s.%s' % (intermediate_counter, '' if name is None else '-' + name, suffix))) intermediate_counter += 1 if not LEAVE_INPUTS_RAW: final = in_temp(target_basename + '.bc') if DEBUG: save_intermediate('bc', 'bc') final = shared.Building.llvm_dis(final, final + '.ll') else: assert len(input_files) == 1 final = input_files[0] if DEBUG: save_intermediate('ll', 'll') if DEBUG: print >> sys.stderr, 'emcc: LLVM => JS' final = shared.Building.emscripten(final, append_ext=False) if DEBUG: save_intermediate('original') # Apply a source code transformation, if requested if js_transform: shutil.copyfile(final, final + '.tr.js') final += '.tr.js' if DEBUG: print >> sys.stderr, 'emcc: applying transform: %s' % js_transform Popen(js_transform.split(' ') + [os.path.abspath(final)]).communicate() if DEBUG: save_intermediate('transformed') # It is useful to run several js optimizer passes together, to save on unneeded unparsing/reparsing js_optimizer_queue = [] def flush_js_optimizer_queue(): global final, js_optimizer_queue if len(js_optimizer_queue) > 0: if not DEBUG: final = shared.Building.js_optimizer(final, js_optimizer_queue) else: for name in js_optimizer_queue: print >> sys.stderr, 'emcc: applying js optimization pass:', name final = shared.Building.js_optimizer(final, [name]) save_intermediate(name) js_optimizer_queue = [] if opt_level >= 1: if DEBUG: print >> sys.stderr, 'emcc: running pre-closure post-opts' if DEBUG: # Clean up the syntax a bit final = shared.Building.js_optimizer(final, []) if DEBUG: save_intermediate('pretty') if shared.Settings.RELOOP: js_optimizer_queue += ['hoistMultiples', 'loopOptimizer'] flush_js_optimizer_queue() # eliminator if DEBUG: print >> sys.stderr, 'emcc: running variable eliminator' final = shared.Building.eliminator(final) if DEBUG: save_intermediate('eliminator') # js optimizer pre-pass js_optimizer_queue += ['simplifyExpressionsPre', 'optimizeShiftsConservative'] ###js_optimizer_queue += ['optimizeShiftsAggressive'] ###final = shared.Building.eliminator(final) # aggressive shifts optimization introduces some new variables, remove ones that we can ###if DEBUG: save_intermediate('eliminator') if closure: flush_js_optimizer_queue() if DEBUG: print >> sys.stderr, 'emcc: running closure' final = shared.Building.closure_compiler(final) if DEBUG: save_intermediate('closure') if opt_level >= 1: # js optimizer post-pass if DEBUG: print >> sys.stderr, 'emcc: running post-closure post-opts' js_optimizer_queue += ['simplifyExpressionsPost'] if compress_whitespace: js_optimizer_queue += ['compress'] flush_js_optimizer_queue() # If we were asked to also generate HTML, do that if final_suffix == 'html': if DEBUG: print >> sys.stderr, 'emcc: generating HTML' shell = open(shared.path_from_root('src', 'shell.html')).read() html = open(target, 'w') html.write(shell.replace('{{{ SCRIPT_CODE }}}', open(final).read())) html.close() else: # copy final JS to output shutil.move(final, target) finally: if not TEMP_DIR: try: shutil.rmtree(temp_dir) except: pass else: print >> sys.stderr, 'emcc saved files are in:', temp_dir