Remove obsolete object file dumpers

git-svn-id: https://llvm.org/svn/llvm-project/llvm/trunk@179362 91177308-0d34-0410-b5e6-96231b3b80d8

test/Makefile.tests

@@ -38,7 +38,7 @@ LCCFLAGS  += -O2 -Wall
 LCXXFLAGS += -O2 -Wall
 LLCFLAGS =
 TESTRUNR = @echo Running test: $<; \
-             PATH="$(LLVMTOOLCURRENT):$(LLVM_SRC_ROOT)/test/Scripts:$(PATH)" \
+             PATH="$(LLVMTOOLCURRENT):$(PATH)" \
                   $(LLVM_SRC_ROOT)/test/TestRunner.sh
 
 LLCLIBS := $(LLCLIBS) -lm

test/Scripts/README.txt

@@ -1,2 +0,0 @@
-This directory contains scripts which are used by the TestRunner style
-tests, which allows them to be simpler and more direct.

test/Scripts/coff-dump.py

@@ -1,590 +0,0 @@
-#!/usr/bin/env python
-#===-- coff-dump.py - COFF object file dump utility-------------------------===#
-#
-#                     The LLVM Compiler Infrastructure
-#
-# This file is distributed under the University of Illinois Open Source
-# License. See LICENSE.TXT for details.
-#
-#===------------------------------------------------------------------------===#
-
-#
-# COFF File Definition
-#
-
-def string_table_entry (offset):
-  return ('ptr', '+ + PointerToSymbolTable * NumberOfSymbols 18 %s' % offset, ('scalar', 'cstr', '%s'))
-
-def secname(value):
-  if value[0] == '/':
-    return string_table_entry(value[1:].rstrip('\0'))
-  else:
-    return '%s'
-
-def symname(value):
-  parts = struct.unpack("<2L", value)
-  if parts[0] == 0:
-    return string_table_entry(parts[1])
-  else:
-    return '%s'
-
-file = ('struct', [
-  ('MachineType', ('enum', '<H', '0x%X', {
-    0x0:    'IMAGE_FILE_MACHINE_UNKNOWN',
-    0x1d3:  'IMAGE_FILE_MACHINE_AM33',
-    0x8664: 'IMAGE_FILE_MACHINE_AMD64',
-    0x1c0:  'IMAGE_FILE_MACHINE_ARM',
-    0xebc:  'IMAGE_FILE_MACHINE_EBC',
-    0x14c:  'IMAGE_FILE_MACHINE_I386',
-    0x200:  'IMAGE_FILE_MACHINE_IA64',
-    0x904:  'IMAGE_FILE_MACHINE_M32R',
-    0x266:  'IMAGE_FILE_MACHINE_MIPS16',
-    0x366:  'IMAGE_FILE_MACHINE_MIPSFPU',
-    0x466:  'IMAGE_FILE_MACHINE_MIPSFPU16',
-    0x1f0:  'IMAGE_FILE_MACHINE_POWERPC',
-    0x1f1:  'IMAGE_FILE_MACHINE_POWERPCFP',
-    0x166:  'IMAGE_FILE_MACHINE_R4000',
-    0x1a2:  'IMAGE_FILE_MACHINE_SH3',
-    0x1a3:  'IMAGE_FILE_MACHINE_SH3DSP',
-    0x1a6:  'IMAGE_FILE_MACHINE_SH4',
-    0x1a8:  'IMAGE_FILE_MACHINE_SH5',
-    0x1c2:  'IMAGE_FILE_MACHINE_THUMB',
-    0x169:  'IMAGE_FILE_MACHINE_WCEMIPSV2',
-  })),
-  ('NumberOfSections',     ('scalar',  '<H', '%d')),
-  ('TimeDateStamp',        ('scalar',  '<L', '%d')),
-  ('PointerToSymbolTable', ('scalar',  '<L', '0x%0X')),
-  ('NumberOfSymbols',      ('scalar',  '<L', '%d')),
-  ('SizeOfOptionalHeader', ('scalar',  '<H', '%d')),
-  ('Characteristics',      ('flags',   '<H', '0x%x', [
-    (0x0001,      'IMAGE_FILE_RELOCS_STRIPPED',         ),
-    (0x0002,      'IMAGE_FILE_EXECUTABLE_IMAGE',        ),
-    (0x0004,      'IMAGE_FILE_LINE_NUMS_STRIPPED',      ),
-    (0x0008,      'IMAGE_FILE_LOCAL_SYMS_STRIPPED',     ),
-    (0x0010,      'IMAGE_FILE_AGGRESSIVE_WS_TRIM',      ),
-    (0x0020,      'IMAGE_FILE_LARGE_ADDRESS_AWARE',     ),
-    (0x0080,      'IMAGE_FILE_BYTES_REVERSED_LO',       ),
-    (0x0100,      'IMAGE_FILE_32BIT_MACHINE',           ),
-    (0x0200,      'IMAGE_FILE_DEBUG_STRIPPED',          ),
-    (0x0400,      'IMAGE_FILE_REMOVABLE_RUN_FROM_SWAP', ),
-    (0x0800,      'IMAGE_FILE_NET_RUN_FROM_SWAP',       ),
-    (0x1000,      'IMAGE_FILE_SYSTEM',                  ),
-    (0x2000,      'IMAGE_FILE_DLL',                     ),
-    (0x4000,      'IMAGE_FILE_UP_SYSTEM_ONLY',          ),
-    (0x8000,      'IMAGE_FILE_BYTES_REVERSED_HI',       ),
-  ])),
-  ('Sections', ('array', '1', 'NumberOfSections', ('struct', [
-    ('Name',                 ('scalar',  '<8s', secname)),
-    ('VirtualSize',          ('scalar',  '<L',  '%d'   )),
-    ('VirtualAddress',       ('scalar',  '<L',  '%d'   )),
-    ('SizeOfRawData',        ('scalar',  '<L',  '%d'   )),
-    ('PointerToRawData',     ('scalar',  '<L',  '0x%X' )),
-    ('PointerToRelocations', ('scalar',  '<L',  '0x%X' )),
-    ('PointerToLineNumbers', ('scalar',  '<L',  '0x%X' )),
-    ('NumberOfRelocations',  ('scalar',  '<H',  '%d'   )),
-    ('NumberOfLineNumbers',  ('scalar',  '<H',  '%d'   )),
-    ('Charateristics',       ('flags',   '<L',  '0x%X', [
-      (0x00000008, 'IMAGE_SCN_TYPE_NO_PAD'),
-      (0x00000020, 'IMAGE_SCN_CNT_CODE'),
-      (0x00000040, 'IMAGE_SCN_CNT_INITIALIZED_DATA'),
-      (0x00000080, 'IMAGE_SCN_CNT_UNINITIALIZED_DATA'),
-      (0x00000100, 'IMAGE_SCN_LNK_OTHER'),
-      (0x00000200, 'IMAGE_SCN_LNK_INFO'),
-      (0x00000800, 'IMAGE_SCN_LNK_REMOVE'),
-      (0x00001000, 'IMAGE_SCN_LNK_COMDAT'),
-      (0x00008000, 'IMAGE_SCN_GPREL'),
-      (0x00020000, 'IMAGE_SCN_MEM_PURGEABLE'),
-      (0x00020000, 'IMAGE_SCN_MEM_16BIT'),
-      (0x00040000, 'IMAGE_SCN_MEM_LOCKED'),
-      (0x00080000, 'IMAGE_SCN_MEM_PRELOAD'),
-      (0x00F00000, 'IMAGE_SCN_ALIGN', {
-        0x00100000: 'IMAGE_SCN_ALIGN_1BYTES',
-        0x00200000: 'IMAGE_SCN_ALIGN_2BYTES',
-        0x00300000: 'IMAGE_SCN_ALIGN_4BYTES',
-        0x00400000: 'IMAGE_SCN_ALIGN_8BYTES',
-        0x00500000: 'IMAGE_SCN_ALIGN_16BYTES',
-        0x00600000: 'IMAGE_SCN_ALIGN_32BYTES',
-        0x00700000: 'IMAGE_SCN_ALIGN_64BYTES',
-        0x00800000: 'IMAGE_SCN_ALIGN_128BYTES',
-        0x00900000: 'IMAGE_SCN_ALIGN_256BYTES',
-        0x00A00000: 'IMAGE_SCN_ALIGN_512BYTES',
-        0x00B00000: 'IMAGE_SCN_ALIGN_1024BYTES',
-        0x00C00000: 'IMAGE_SCN_ALIGN_2048BYTES',
-        0x00D00000: 'IMAGE_SCN_ALIGN_4096BYTES',
-        0x00E00000: 'IMAGE_SCN_ALIGN_8192BYTES',
-      }),
-      (0x01000000, 'IMAGE_SCN_LNK_NRELOC_OVFL'),
-      (0x02000000, 'IMAGE_SCN_MEM_DISCARDABLE'),
-      (0x04000000, 'IMAGE_SCN_MEM_NOT_CACHED'),
-      (0x08000000, 'IMAGE_SCN_MEM_NOT_PAGED'),
-      (0x10000000, 'IMAGE_SCN_MEM_SHARED'),
-      (0x20000000, 'IMAGE_SCN_MEM_EXECUTE'),
-      (0x40000000, 'IMAGE_SCN_MEM_READ'),
-      (0x80000000, 'IMAGE_SCN_MEM_WRITE'),
-    ])),
-    ('SectionData', ('ptr', 'PointerToRawData', ('blob', 'SizeOfRawData'))),
-    ('Relocations', ('ptr', 'PointerToRelocations', ('array', '0', 'NumberOfRelocations', ('struct', [
-      ('VirtualAddress',   ('scalar', '<L', '0x%X')),
-      ('SymbolTableIndex', ('scalar', '<L', '%d'  )),
-      ('Type',             ('enum', '<H', '%d', ('MachineType', {
-        0x14c: {
-          0x0000: 'IMAGE_REL_I386_ABSOLUTE',
-          0x0001: 'IMAGE_REL_I386_DIR16',
-          0x0002: 'IMAGE_REL_I386_REL16',
-          0x0006: 'IMAGE_REL_I386_DIR32',
-          0x0007: 'IMAGE_REL_I386_DIR32NB',
-          0x0009: 'IMAGE_REL_I386_SEG12',
-          0x000A: 'IMAGE_REL_I386_SECTION',
-          0x000B: 'IMAGE_REL_I386_SECREL',
-          0x000C: 'IMAGE_REL_I386_TOKEN',
-          0x000D: 'IMAGE_REL_I386_SECREL7',
-          0x0014: 'IMAGE_REL_I386_REL32',
-        },
-        0x8664: {
-          0x0000: 'IMAGE_REL_AMD64_ABSOLUTE',
-          0x0001: 'IMAGE_REL_AMD64_ADDR64',
-          0x0002: 'IMAGE_REL_AMD64_ADDR32',
-          0x0003: 'IMAGE_REL_AMD64_ADDR32NB',
-          0x0004: 'IMAGE_REL_AMD64_REL32',
-          0x0005: 'IMAGE_REL_AMD64_REL32_1',
-          0x0006: 'IMAGE_REL_AMD64_REL32_2',
-          0x0007: 'IMAGE_REL_AMD64_REL32_3',
-          0x0008: 'IMAGE_REL_AMD64_REL32_4',
-          0x0009: 'IMAGE_REL_AMD64_REL32_5',
-          0x000A: 'IMAGE_REL_AMD64_SECTION',
-          0x000B: 'IMAGE_REL_AMD64_SECREL',
-          0x000C: 'IMAGE_REL_AMD64_SECREL7',
-          0x000D: 'IMAGE_REL_AMD64_TOKEN',
-          0x000E: 'IMAGE_REL_AMD64_SREL32',
-          0x000F: 'IMAGE_REL_AMD64_PAIR',
-          0x0010: 'IMAGE_REL_AMD64_SSPAN32',
-        },
-      }))),
-      ('SymbolName',       ('ptr', '+ PointerToSymbolTable * SymbolTableIndex 18', ('scalar',  '<8s', symname)))
-    ])))),
-  ]))),
-  ('Symbols', ('ptr', 'PointerToSymbolTable', ('byte-array', '18', '* NumberOfSymbols 18',  ('struct', [
-    ('Name',                ('scalar',  '<8s', symname)),
-    ('Value',               ('scalar',  '<L',  '%d'   )),
-    ('SectionNumber',       ('scalar',  '<H',  '%d'   )),
-    ('_Type',               ('scalar',  '<H',  None   )),
-    ('SimpleType',          ('enum',    '& _Type 15',  '%d', {
-      0: 'IMAGE_SYM_TYPE_NULL',
-      1: 'IMAGE_SYM_TYPE_VOID',
-      2: 'IMAGE_SYM_TYPE_CHAR',
-      3: 'IMAGE_SYM_TYPE_SHORT',
-      4: 'IMAGE_SYM_TYPE_INT',
-      5: 'IMAGE_SYM_TYPE_LONG',
-      6: 'IMAGE_SYM_TYPE_FLOAT',
-      7: 'IMAGE_SYM_TYPE_DOUBLE',
-      8: 'IMAGE_SYM_TYPE_STRUCT',
-      9: 'IMAGE_SYM_TYPE_UNION',
-      10: 'IMAGE_SYM_TYPE_ENUM',
-      11: 'IMAGE_SYM_TYPE_MOE',
-      12: 'IMAGE_SYM_TYPE_BYTE',
-      13: 'IMAGE_SYM_TYPE_WORD',
-      14: 'IMAGE_SYM_TYPE_UINT',
-      15: 'IMAGE_SYM_TYPE_DWORD',
-    })),                                # (Type & 0xF0) >> 4
-    ('ComplexType',         ('enum',    '>> & _Type 240 4',  '%d', {
-      0: 'IMAGE_SYM_DTYPE_NULL',
-      1: 'IMAGE_SYM_DTYPE_POINTER',
-      2: 'IMAGE_SYM_DTYPE_FUNCTION',
-      3: 'IMAGE_SYM_DTYPE_ARRAY',
-    })),
-    ('StorageClass',        ('enum',    '<B',  '%d', {
-      -1:  'IMAGE_SYM_CLASS_END_OF_FUNCTION',
-      0: 'IMAGE_SYM_CLASS_NULL',
-      1: 'IMAGE_SYM_CLASS_AUTOMATIC',
-      2: 'IMAGE_SYM_CLASS_EXTERNAL',
-      3: 'IMAGE_SYM_CLASS_STATIC',
-      4: 'IMAGE_SYM_CLASS_REGISTER',
-      5: 'IMAGE_SYM_CLASS_EXTERNAL_DEF',
-      6: 'IMAGE_SYM_CLASS_LABEL',
-      7: 'IMAGE_SYM_CLASS_UNDEFINED_LABEL',
-      8: 'IMAGE_SYM_CLASS_MEMBER_OF_STRUCT',
-      9: 'IMAGE_SYM_CLASS_ARGUMENT',
-      10: 'IMAGE_SYM_CLASS_STRUCT_TAG',
-      11: 'IMAGE_SYM_CLASS_MEMBER_OF_UNION',
-      12: 'IMAGE_SYM_CLASS_UNION_TAG',
-      13: 'IMAGE_SYM_CLASS_TYPE_DEFINITION',
-      14: 'IMAGE_SYM_CLASS_UNDEFINED_STATIC',
-      15: 'IMAGE_SYM_CLASS_ENUM_TAG',
-      16: 'IMAGE_SYM_CLASS_MEMBER_OF_ENUM',
-      17: 'IMAGE_SYM_CLASS_REGISTER_PARAM',
-      18: 'IMAGE_SYM_CLASS_BIT_FIELD',
-      100: 'IMAGE_SYM_CLASS_BLOCK',
-      101: 'IMAGE_SYM_CLASS_FUNCTION',
-      102: 'IMAGE_SYM_CLASS_END_OF_STRUCT',
-      103: 'IMAGE_SYM_CLASS_FILE',
-      104: 'IMAGE_SYM_CLASS_SECTION',
-      105: 'IMAGE_SYM_CLASS_WEAK_EXTERNAL',
-      107: 'IMAGE_SYM_CLASS_CLR_TOKEN',
-    })),
-    ('NumberOfAuxSymbols',  ('scalar',  '<B',  '%d'  )),
-    ('AuxillaryData', ('blob', '* NumberOfAuxSymbols 18')),
-  ])))),
-])
-
-#
-# Definition Interpreter
-#
-
-import sys, types, struct, re
-
-Input = None
-Stack = []
-Fields = {}
-
-Indent = 0
-NewLine = True
-
-def indent():
-  global Indent
-  Indent += 1
-
-def dedent():
-  global Indent
-  Indent -= 1
-
-def write(input):
-  global NewLine
-  output = ""
-
-  for char in input:
-
-    if NewLine:
-      output += Indent * '  '
-      NewLine = False
-
-    output += char
-
-    if char == '\n':
-      NewLine = True
-
-  sys.stdout.write(output)
-
-def read(format):
-  return struct.unpack(format, Input.read(struct.calcsize(format)))
-
-def read_cstr():
-  output = ""
-  while True:
-    char = Input.read(1)
-    if len(char) == 0:
-      raise RuntimeError ("EOF while reading cstr")
-    if char == '\0':
-      break
-    output += char
-  return output
-
-def push_pos(seek_to = None):
-  Stack [0:0] = [Input.tell()]
-  if seek_to:
-    Input.seek(seek_to)
-
-def pop_pos():
-  assert(len(Stack) > 0)
-  Input.seek(Stack[0])
-  del Stack[0]
-
-def print_binary_data(size):
-  value = ""
-  while size > 0:
-    if size >= 16:
-      data = Input.read(16)
-      size -= 16
-    else:
-      data = Input.read(size)
-      size = 0
-    value += data
-    bytes = ""
-    text = ""
-    for index in xrange(16):
-      if index < len(data):
-        if index == 8:
-          bytes += "- "
-        ch = ord(data[index])
-        bytes += "%02X " % ch
-        if ch >= 0x20 and ch <= 0x7F:
-          text += data[index]
-        else:
-          text += "."
-      else:
-        if index == 8:
-          bytes += "  "
-        bytes += "   "
-
-    write("%s|%s|\n" % (bytes, text))
-  return value
-
-idlit = re.compile("[a-zA-Z_][a-zA-Z0-9_-]*")
-numlit = re.compile("[0-9]+")
-
-def read_value(expr):
-
-  input = iter(expr.split())
-
-  def eval():
-
-    token = input.next()
-
-    if expr == 'cstr':
-      return read_cstr()
-    if expr == 'true':
-      return True
-    if expr == 'false':
-      return False
-
-    if token == '+':
-      return eval() + eval()
-    if token == '-':
-      return eval() - eval()
-    if token == '*':
-      return eval() * eval()
-    if token == '/':
-      return eval() / eval()
-    if token == '&':
-      return eval() & eval()
-    if token == '|':
-      return eval() | eval()
-    if token == '>>':
-      return eval() >> eval()
-    if token == '<<':
-      return eval() << eval()
-
-    if len(token) > 1 and token[0] in ('=', '@', '<', '!', '>'):
-      val = read(expr)
-      assert(len(val) == 1)
-      return val[0]
-
-    if idlit.match(token):
-      return Fields[token]
-    if numlit.match(token):
-      return int(token)
-
-    raise RuntimeError("unexpected token %s" % repr(token))
-
-  value = eval()
-
-  try:
-    input.next()
-  except StopIteration:
-    return value
-  raise RuntimeError("unexpected input at end of expression")
-
-def write_value(format,value):
-  format_type = type(format)
-  if format_type is types.StringType:
-    write(format % value)
-  elif format_type is types.FunctionType:
-    write_value(format(value), value)
-  elif format_type is types.TupleType:
-    Fields['this'] = value
-    handle_element(format)
-  elif format_type is types.NoneType:
-    pass
-  else:
-    raise RuntimeError("unexpected type: %s" % repr(format_type))
-
-def handle_scalar(entry):
-  iformat = entry[1]
-  oformat = entry[2]
-
-  value = read_value(iformat)
-
-  write_value(oformat, value)
-
-  return value
-
-def handle_enum(entry):
-  iformat = entry[1]
-  oformat = entry[2]
-  definitions = entry[3]
-
-  value = read_value(iformat)
-
-  if type(definitions) is types.TupleType:
-    selector = read_value(definitions[0])
-    definitions = definitions[1][selector]
-
-  if value in definitions:
-    description = definitions[value]
-  else:
-    description = "unknown"
-
-  write("%s (" % description)
-  write_value(oformat, value)
-  write(")")
-
-  return value
-
-def handle_flags(entry):
-  iformat = entry[1]
-  oformat = entry[2]
-  definitions = entry[3]
-
-  value = read_value(iformat)
-
-  write_value(oformat, value)
-
-  indent()
-  for entry in definitions:
-    mask = entry[0]
-    name = entry[1]
-    if len (entry) == 3:
-      map = entry[2]
-      selection = value & mask
-      if selection in map:
-        write("\n%s" % map[selection])
-      else:
-        write("\n%s <%d>" % (name, selection))
-    elif len(entry) == 2:
-      if value & mask != 0:
-        write("\n%s" % name)
-  dedent()
-
-  return value
-
-def handle_struct(entry):
-  global Fields
-  members = entry[1]
-
-  newFields = {}
-
-  write("{\n");
-  indent()
-
-  for member in members:
-    name = member[0]
-    type = member[1]
-
-    if name[0] != "_":
-      write("%s = " % name.ljust(24))
-
-    value = handle_element(type)
-
-    if name[0] != "_":
-      write("\n")
-
-    Fields[name] = value
-    newFields[name] = value
-
-  dedent()
-  write("}")
-
-  return newFields
-
-def handle_array(entry):
-  start_index = entry[1]
-  length = entry[2]
-  element = entry[3]
-
-  newItems = []
-
-  write("[\n")
-  indent()
-
-  start_index = read_value(start_index)
-  value = read_value(length)
-
-  for index in xrange(value):
-    write("%d = " % (index + start_index))
-    value = handle_element(element)
-    write("\n")
-    newItems.append(value)
-
-  dedent()
-  write("]")
-
-  return newItems
-
-def handle_byte_array(entry):
-  ent_size = entry[1]
-  length = entry[2]
-  element = entry[3]
-
-  newItems = []
-
-  write("[\n")
-  indent()
-
-  item_size = read_value(ent_size)
-  value = read_value(length)
-  end_of_array = Input.tell() + value
-
-  prev_loc = Input.tell()
-  index = 0
-  while Input.tell() < end_of_array:
-    write("%d = " % index)
-    value = handle_element(element)
-    write("\n")
-    newItems.append(value)
-    index += (Input.tell() - prev_loc) / item_size
-    prev_loc = Input.tell()
-
-  dedent()
-  write("]")
-
-  return newItems
-
-def handle_ptr(entry):
-  offset = entry[1]
-  element = entry[2]
-
-  value = None
-  offset = read_value(offset)
-
-  if offset != 0:
-
-    push_pos(offset)
-
-    value = handle_element(element)
-
-    pop_pos()
-
-  else:
-    write("None")
-
-  return value
-
-def handle_blob(entry):
-  length = entry[1]
-
-  write("\n")
-  indent()
-
-  value = print_binary_data(read_value(length))
-
-  dedent()
-
-  return value
-
-def handle_element(entry):
-  handlers = {
-    'struct':      handle_struct,
-    'scalar':      handle_scalar,
-    'enum':        handle_enum,
-    'flags':       handle_flags,
-    'ptr':         handle_ptr,
-    'blob':        handle_blob,
-    'array':       handle_array,
-    'byte-array':  handle_byte_array,
-  }
-
-  if not entry[0] in handlers:
-    raise RuntimeError ("unexpected type '%s'" % str (entry[0]))
-
-  return handlers[entry[0]](entry)
-
-if len(sys.argv) <= 1 or sys.argv[1] == '-':
-  import StringIO
-  Input = StringIO.StringIO(sys.stdin.read())
-else:
-  Input = open (sys.argv[1], "rb")
-
-try:
-  handle_element(file)
-finally:
-  Input.close()
-  Input = None

test/Scripts/coff-dump.py.bat

@@ -1,7 +0,0 @@
-@echo off
-
-@rem We need to set -u to treat stdin as binary. Python 3 has support for doing
-@rem this in code, but I haven't found a way to do this in 2.6 yet.
-
-%PYTHON_EXECUTABLE% -u %LLVM_SRC_ROOT%\test\Scripts\coff-dump.py %1 %2 %3 %4 %5 %6 %7 %8 %9
-

test/Scripts/common_dump.py

@@ -1,48 +0,0 @@
-def dataToHex(d):
-    """ Convert the raw data in 'd' to an hex string with a space every 4 bytes.
-    """
-    bytes = []
-    for i,c in enumerate(d):
-        byte = ord(c)
-        hex_byte = hex(byte)[2:]
-        if byte <= 0xf:
-            hex_byte = '0' + hex_byte
-        if i % 4 == 3:
-            hex_byte += ' '
-        bytes.append(hex_byte)
-    return ''.join(bytes).strip()
-
-def dataToHexUnified(d):
-    """ Convert the raw data in 'd' to an hex string with a space every 4 bytes.
-    Each 4byte number is prefixed with 0x for easy sed/rx
-    Fixme: convert all MC tests to use this routine instead of the above
-    """
-    bytes = []
-    for i,c in enumerate(d):
-        byte = ord(c)
-        hex_byte = hex(byte)[2:]
-        if byte <= 0xf:
-            hex_byte = '0' + hex_byte
-        if i % 4 == 0:
-            hex_byte = '0x' + hex_byte
-        if i % 4 == 3:
-            hex_byte += ' '
-        bytes.append(hex_byte)
-    return ''.join(bytes).strip()
-
-
-def HexDump(valPair):
-    """
-    1. do not print 'L'
-    2. Handle negatives and large numbers by mod (2^numBits)
-    3. print fixed length, prepend with zeros.
-       Length is exactly 2+(numBits/4)
-    4. Do print 0x Why?
-       so that they can be easily distinguished using sed/rx
-    """
-    val, numBits = valPair
-    assert 0 <= val < (1 << numBits)
-
-    val = val & (( 1 << numBits) - 1)
-    newFmt = "0x%0" + "%d" % (numBits / 4) + "x"
-    return newFmt % val

test/Scripts/elf-dump

@@ -1,285 +0,0 @@
-#!/usr/bin/env python
-
-import struct
-import sys
-import StringIO
-
-import common_dump
-
-class Reader:
-    def __init__(self, path):
-        if path == "-":
-            # Snarf all the data so we can seek.
-            self.file = StringIO.StringIO(sys.stdin.read())
-        else:
-            self.file = open(path, "rb")
-        self.isLSB = None
-        self.is64Bit = None
-        self.isN64 = False
-
-    def seek(self, pos):
-        self.file.seek(pos)
-
-    def read(self, N):
-        data = self.file.read(N)
-        if len(data) != N:
-            raise ValueError, "Out of data!"
-        return data
-
-    def read8(self):
-        return (ord(self.read(1)), 8)
-
-    def read16(self):
-        return (struct.unpack('><'[self.isLSB] + 'H', self.read(2))[0], 16)
-
-    def read32(self):
-        return (struct.unpack('><'[self.isLSB] + 'I', self.read(4))[0], 32)
-
-    def read64(self):
-        return (struct.unpack('><'[self.isLSB] + 'Q', self.read(8))[0], 64)
-
-    def readWord(self):
-        if self.is64Bit:
-            return self.read64()
-        else:
-            return self.read32()
-
-class StringTable:
-    def __init__(self, strings):
-       self.string_table = strings
-
-    def __getitem__(self, index):
-       end = self.string_table.index('\x00', index)
-       return self.string_table[index:end]
-
-class ProgramHeader:
-    def __init__(self, f):
-        self.p_type = f.read32()
-        if f.is64Bit:
-            self.p_flags = f.read32()
-        self.p_offset = f.readWord()
-        self.p_vaddr = f.readWord()
-        self.p_paddr = f.readWord()
-        self.p_filesz = f.readWord()
-        self.p_memsz = f.readWord()
-        if not f.is64Bit:
-            self.p_flags = f.read32()
-        self.p_align = f.readWord()
-
-    def dump(self):
-        print "  (('p_type', %s)" % common_dump.HexDump(self.p_type) 
-        print "   ('p_flags', %s)" % common_dump.HexDump(self.p_flags) 
-        print "   ('p_offset', %s)" % common_dump.HexDump(self.p_offset) 
-        print "   ('p_vaddr', %s)" % common_dump.HexDump(self.p_vaddr) 
-        print "   ('p_paddr', %s)" % common_dump.HexDump(self.p_paddr) 
-        print "   ('p_filesz', %s)" % common_dump.HexDump(self.p_filesz) 
-        print "   ('p_memsz', %s)" % common_dump.HexDump(self.p_memsz) 
-        print "   ('p_align', %s)" % common_dump.HexDump(self.p_align) 
-        print "  ),"
-
-class Section:
-    def __init__(self, f):
-        self.sh_name = f.read32()
-        self.sh_type = f.read32()
-        self.sh_flags = f.readWord()
-        self.sh_addr = f.readWord()
-        self.sh_offset = f.readWord()
-        self.sh_size = f.readWord()
-        self.sh_link = f.read32()
-        self.sh_info = f.read32()
-        self.sh_addralign = f.readWord()
-        self.sh_entsize = f.readWord()
-
-    def dump(self, shstrtab, f, strtab, dumpdata):
-        print "  (('sh_name', %s)" % common_dump.HexDump(self.sh_name), "# %r" % shstrtab[self.sh_name[0]]
-        print "   ('sh_type', %s)" % common_dump.HexDump(self.sh_type)
-        print "   ('sh_flags', %s)" % common_dump.HexDump(self.sh_flags)
-        print "   ('sh_addr', %s)" % common_dump.HexDump(self.sh_addr)
-        print "   ('sh_offset', %s)" % common_dump.HexDump(self.sh_offset)
-        print "   ('sh_size', %s)" % common_dump.HexDump(self.sh_size)
-        print "   ('sh_link', %s)" % common_dump.HexDump(self.sh_link)
-        print "   ('sh_info', %s)" % common_dump.HexDump(self.sh_info)
-        print "   ('sh_addralign', %s)" % common_dump.HexDump(self.sh_addralign)
-        print "   ('sh_entsize', %s)" % common_dump.HexDump(self.sh_entsize)
-        if self.sh_type[0] == 2: # SHT_SYMTAB
-            print "   ('_symbols', ["
-            dumpSymtab(f, self, strtab)
-            print "   ])"
-        elif self.sh_type[0] == 4 or self.sh_type[0] == 9: # SHT_RELA / SHT_REL
-            print "   ('_relocations', ["
-            dumpRel(f, self, self.sh_type[0] == 4)
-            print "   ])"
-        elif dumpdata:
-            f.seek(self.sh_offset[0])
-            if self.sh_type != 8: # != SHT_NOBITS
-                data = f.read(self.sh_size[0])
-                print "   ('_section_data', '%s')" % common_dump.dataToHex(data)
-            else:
-                print "   ('_section_data', '')" 
-        print "  ),"
-
-def dumpSymtab(f, section, strtab):
-    entries = section.sh_size[0] // section.sh_entsize[0]
-
-    for index in range(entries):
-        f.seek(section.sh_offset[0] + index * section.sh_entsize[0])
-        print "    # Symbol %s" % index
-        name = f.read32()
-        print "    (('st_name', %s)" % common_dump.HexDump(name), "# %r" % strtab[name[0]]
-        if not f.is64Bit:
-            print "     ('st_value', %s)" % common_dump.HexDump(f.read32())
-            print "     ('st_size', %s)" % common_dump.HexDump(f.read32())
-        st_info = f.read8()[0]
-        st_bind = (st_info >> 4, 4)
-        st_type = (st_info & 0xf, 4)
-        print "     ('st_bind', %s)" % common_dump.HexDump(st_bind)
-        print "     ('st_type', %s)" % common_dump.HexDump(st_type)
-        print "     ('st_other', %s)" % common_dump.HexDump(f.read8())
-        print "     ('st_shndx', %s)" % common_dump.HexDump(f.read16())
-        if f.is64Bit:
-            print "     ('st_value', %s)" % common_dump.HexDump(f.read64())
-            print "     ('st_size', %s)" % common_dump.HexDump(f.read64())
-        print "    ),"
-
-def dumpRel(f, section, dumprela = False):
-    entries = section.sh_size[0] // section.sh_entsize[0]
-
-    for index in range(entries):
-        f.seek(section.sh_offset[0] + index * section.sh_entsize[0])
-        print "    # Relocation %s" % index
-        print "    (('r_offset', %s)" % common_dump.HexDump(f.readWord())
-
-        if f.isN64:
-            r_sym =   f.read32()
-            r_ssym =  f.read8()
-            r_type3 = f.read8()
-            r_type2 = f.read8()
-            r_type =  f.read8()
-            print "     ('r_sym', %s)" % common_dump.HexDump(r_sym)
-            print "     ('r_ssym', %s)" % common_dump.HexDump(r_ssym)
-            print "     ('r_type3', %s)" % common_dump.HexDump(r_type3)
-            print "     ('r_type2', %s)" % common_dump.HexDump(r_type2)
-            print "     ('r_type', %s)" % common_dump.HexDump(r_type)
-        else:
-            r_info = f.readWord()[0]
-            if f.is64Bit:
-                r_sym = (r_info >> 32, 32)
-                r_type = (r_info & 0xffffffff, 32)
-            else:
-                r_sym = (r_info >> 8, 24)
-                r_type = (r_info & 0xff, 8)
-            print "     ('r_sym', %s)" % common_dump.HexDump(r_sym)
-            print "     ('r_type', %s)" % common_dump.HexDump(r_type)
-        if dumprela:
-            print "     ('r_addend', %s)" % common_dump.HexDump(f.readWord())
-        print "    ),"
-
-def dumpELF(path, opts):
-    f = Reader(path)
-
-    magic = f.read(4)
-    assert magic == '\x7FELF'
-
-    fileclass = f.read8()
-    if fileclass[0] == 1: # ELFCLASS32
-        f.is64Bit = False
-    elif fileclass[0] == 2: # ELFCLASS64
-        f.is64Bit = True
-    else:
-        raise ValueError, "Unknown file class %s" % common_dump.HexDump(fileclass)
-    print "('e_indent[EI_CLASS]', %s)" % common_dump.HexDump(fileclass)
-
-    byteordering = f.read8()
-    if byteordering[0] == 1: # ELFDATA2LSB
-        f.isLSB = True
-    elif byteordering[0] == 2: # ELFDATA2MSB
-        f.isLSB = False
-    else:
-        raise ValueError, "Unknown byte ordering %s" % common_dump.HexDump(byteordering)
-    print "('e_indent[EI_DATA]', %s)" % common_dump.HexDump(byteordering)
-
-    print "('e_indent[EI_VERSION]', %s)" % common_dump.HexDump(f.read8())
-    print "('e_indent[EI_OSABI]', %s)" % common_dump.HexDump(f.read8())
-    print "('e_indent[EI_ABIVERSION]', %s)" % common_dump.HexDump(f.read8())
-
-    f.seek(16) # Seek to end of e_ident.
-
-    print "('e_type', %s)" % common_dump.HexDump(f.read16())
-
-    # Does any other architecture use N64?
-    e_machine = f.read16()
-    if e_machine[0] == 0x0008 and f.is64Bit: # EM_MIPS && 64 bit
-        f.isN64 = True 
-    
-    print "('e_machine', %s)" % common_dump.HexDump(e_machine)
-    print "('e_version', %s)" % common_dump.HexDump(f.read32())
-    print "('e_entry', %s)" % common_dump.HexDump(f.readWord())
-    e_phoff = f.readWord()
-    print "('e_phoff', %s)" % common_dump.HexDump(e_phoff)
-    e_shoff = f.readWord()
-    print "('e_shoff', %s)" % common_dump.HexDump(e_shoff)
-    print "('e_flags', %s)" % common_dump.HexDump(f.read32())
-    print "('e_ehsize', %s)" % common_dump.HexDump(f.read16())
-    e_phentsize = f.read16()
-    print "('e_phentsize', %s)" % common_dump.HexDump(e_phentsize)
-    e_phnum = f.read16()
-    print "('e_phnum', %s)" % common_dump.HexDump(e_phnum)
-    e_shentsize = f.read16()
-    print "('e_shentsize', %s)" % common_dump.HexDump(e_shentsize)
-    e_shnum = f.read16()
-    print "('e_shnum', %s)" % common_dump.HexDump(e_shnum)
-    e_shstrndx = f.read16()
-    print "('e_shstrndx', %s)" % common_dump.HexDump(e_shstrndx)
-    
-
-    # Read all section headers
-    sections = []
-    for index in range(e_shnum[0]):
-        f.seek(e_shoff[0] + index * e_shentsize[0])
-        s = Section(f)
-        sections.append(s)
-
-    # Read .shstrtab so we can resolve section names
-    f.seek(sections[e_shstrndx[0]].sh_offset[0])
-    shstrtab = StringTable(f.read(sections[e_shstrndx[0]].sh_size[0]))
-
-    # Get the symbol string table
-    strtab = None
-    for section in sections:
-        if shstrtab[section.sh_name[0]] == ".strtab":
-            f.seek(section.sh_offset[0])
-            strtab = StringTable(f.read(section.sh_size[0]))
-            break
-
-    print "('_sections', ["
-    for index in range(e_shnum[0]):
-        print "  # Section %s" % index
-        sections[index].dump(shstrtab, f, strtab, opts.dumpSectionData)
-    print "])"
-
-    # Read all  program headers
-    headers = []
-    for index in range(e_phnum[0]):
-        f.seek(e_phoff[0] + index * e_phentsize[0])
-        h = ProgramHeader(f)
-        headers.append(h)
-
-    print "('_ProgramHeaders', ["
-    for index in range(e_phnum[0]):
-        print "  # Program Header %s" % index
-        headers[index].dump()
-    print "])"
-
-if __name__ == "__main__":
-    from optparse import OptionParser, OptionGroup
-    parser = OptionParser("usage: %prog [options] {files}")
-    parser.add_option("", "--dump-section-data", dest="dumpSectionData",
-                      help="Dump the contents of sections",
-                      action="store_true", default=False)
-    (opts, args) = parser.parse_args()
-
-    if not args:
-        args.append('-')
-
-    for arg in args:
-        dumpELF(arg, opts)

test/Scripts/elf-dump.bat

@@ -1,7 +0,0 @@
-@echo off
-
-@rem We need to set -u to treat stdin as binary. Python 3 has support for doing
-@rem this in code, but I haven't found a way to do this in 2.6 yet.
-
-%PYTHON_EXECUTABLE% -u %LLVM_SRC_ROOT%\test\Scripts\elf-dump %1 %2 %3 %4 %5 %6 %7 %8 %9
-

test/Scripts/ignore

@@ -1,10 +0,0 @@
-#!/bin/sh
-#
-# Program: ignore
-#
-# Synopsis: Ignore the result code of the command and always return 0
-#
-# Syntax:   ignore command <arguments>
-
-"$@" || exit 0 && exit 0
-exit 0

test/Scripts/macho-dumpx

@@ -1,294 +0,0 @@
-#!/usr/bin/env python
-
-import struct
-import sys
-import StringIO
-
-import common_dump
-
-class Reader:
-   def __init__(self, path):
-      if path == '-':
-         # Snarf all the data so we can seek.
-         self.file = StringIO.StringIO(sys.stdin.read())
-      else:
-         self.file = open(path,'rb')
-      self.isLSB = None
-      self.is64Bit = None
-
-      self.string_table = None
-
-   def tell(self):
-      return self.file.tell()
-
-   def seek(self, pos):
-      self.file.seek(pos)
-
-   def read(self, N):
-      data = self.file.read(N)
-      if len(data) != N:
-         raise ValueError,"Out of data!"
-      return data
-
-   def read8(self):
-      return ord(self.read(1))
-
-   def read16(self):
-      return struct.unpack('><'[self.isLSB] + 'H', self.read(2))[0]
-
-   def read32(self):
-      # Force to 32-bit, if possible; otherwise these might be long ints on a
-      # big-endian platform. FIXME: Why???
-      Value = struct.unpack('><'[self.isLSB] + 'I', self.read(4))[0]
-      return int(Value)
-
-   def read64(self):
-      Value = struct.unpack('><'[self.isLSB] + 'Q', self.read(8))[0]
-      if Value == int(Value):
-         Value = int(Value)
-      return Value
-
-   def registerStringTable(self, strings):
-      if self.string_table is not None:
-         raise ValueError,"%s: warning: multiple string tables" % sys.argv[0]
-
-      self.string_table = strings
-
-   def getString(self, index):
-      if self.string_table is None:
-         raise ValueError,"%s: warning: no string table registered" % sys.argv[0]
-      
-      end = self.string_table.index('\x00', index)
-      return self.string_table[index:end]
-
-def dumpmacho(path, opts):
-   f = Reader(path)
-
-   magic = f.read(4)
-   if magic == '\xFE\xED\xFA\xCE':
-      f.isLSB, f.is64Bit = False, False
-   elif magic == '\xCE\xFA\xED\xFE':
-      f.isLSB, f.is64Bit = True, False
-   elif magic == '\xFE\xED\xFA\xCF':
-      f.isLSB, f.is64Bit = False, True
-   elif magic == '\xCF\xFA\xED\xFE':
-      f.isLSB, f.is64Bit = True, True
-   else:
-      raise ValueError,"Not a Mach-O object file: %r (bad magic)" % path
-
-   print "('cputype', %r)" % f.read32()
-   print "('cpusubtype', %r)" % f.read32()
-   filetype = f.read32()
-   print "('filetype', %r)" % filetype
-   
-   numLoadCommands = f.read32()
-   print "('num_load_commands', %r)" % numLoadCommands
-
-   loadCommandsSize = f.read32()
-   print "('load_commands_size', %r)" % loadCommandsSize
-
-   print "('flag', %r)" % f.read32()
-
-   if f.is64Bit:
-      print "('reserved', %r)" % f.read32()
-
-   start = f.tell()
-
-   print "('load_commands', ["
-   for i in range(numLoadCommands):
-      dumpLoadCommand(f, i, opts)
-   print "])"
-
-   if f.tell() - start != loadCommandsSize:
-      raise ValueError,"%s: warning: invalid load commands size: %r" % (
-         sys.argv[0], loadCommandsSize)
-
-def dumpLoadCommand(f, i, opts):
-   start = f.tell()
-
-   print "  # Load Command %r" % i
-   cmd = f.read32()
-   print " (('command', %r)" % cmd
-   cmdSize = f.read32()
-   print "  ('size', %r)" % cmdSize
-
-   if cmd == 1:
-      dumpSegmentLoadCommand(f, opts, False)
-   elif cmd == 2:
-      dumpSymtabCommand(f, opts)
-   elif cmd == 11:
-      dumpDysymtabCommand(f, opts)
-   elif cmd == 25:
-      dumpSegmentLoadCommand(f, opts, True)
-   elif cmd == 27:
-      import uuid
-      print "  ('uuid', %s)" % uuid.UUID(bytes=f.read(16))
-   else:
-      print >>sys.stderr,"%s: warning: unknown load command: %r" % (
-         sys.argv[0], cmd)
-      f.read(cmdSize - 8)
-   print " ),"
-
-   if f.tell() - start != cmdSize:
-      raise ValueError,"%s: warning: invalid load command size: %r" % (
-         sys.argv[0], cmdSize)
-
-def dumpSegmentLoadCommand(f, opts, is64Bit):
-   print "  ('segment_name', %r)" % f.read(16) 
-   if is64Bit:
-      print "  ('vm_addr', %r)" % f.read64()
-      print "  ('vm_size', %r)" % f.read64()
-      print "  ('file_offset', %r)" % f.read64()
-      print "  ('file_size', %r)" % f.read64()
-   else:
-      print "  ('vm_addr', %r)" % f.read32()
-      print "  ('vm_size', %r)" % f.read32()
-      print "  ('file_offset', %r)" % f.read32()
-      print "  ('file_size', %r)" % f.read32()
-   print "  ('maxprot', %r)" % f.read32()
-   print "  ('initprot', %r)" % f.read32()
-   numSections = f.read32()
-   print "  ('num_sections', %r)" % numSections
-   print "  ('flags', %r)" % f.read32()
-
-   print "  ('sections', ["
-   for i in range(numSections):
-      dumpSection(f, i, opts, is64Bit)
-   print "  ])"
-
-def dumpSymtabCommand(f, opts):
-   symoff = f.read32()
-   print "  ('symoff', %r)" % symoff
-   nsyms = f.read32()
-   print "  ('nsyms', %r)" % nsyms
-   stroff = f.read32()
-   print "  ('stroff', %r)" % stroff
-   strsize = f.read32()
-   print "  ('strsize', %r)" % strsize
-
-   prev_pos = f.tell()
-
-   f.seek(stroff)
-   string_data = f.read(strsize)
-   print "  ('_string_data', %r)" % string_data
-
-   f.registerStringTable(string_data)
-
-   f.seek(symoff)
-   print "  ('_symbols', ["
-   for i in range(nsyms):
-      dumpNlist32(f, i, opts)
-   print "  ])"
-      
-   f.seek(prev_pos)
-
-def dumpNlist32(f, i, opts):
-   print "    # Symbol %r" % i
-   n_strx = f.read32()
-   print "   (('n_strx', %r)" % n_strx
-   n_type = f.read8()
-   print "    ('n_type', %#x)" % n_type
-   n_sect = f.read8()
-   print "    ('n_sect', %r)" % n_sect
-   n_desc = f.read16()
-   print "    ('n_desc', %r)" % n_desc
-   if f.is64Bit:
-      n_value = f.read64()
-      print "    ('n_value', %r)" % n_value
-   else:
-      n_value = f.read32()
-      print "    ('n_value', %r)" % n_value
-   print "    ('_string', %r)" % f.getString(n_strx)
-   print "   ),"
-
-def dumpDysymtabCommand(f, opts):   
-   print "  ('ilocalsym', %r)" % f.read32()
-   print "  ('nlocalsym', %r)" % f.read32()
-   print "  ('iextdefsym', %r)" % f.read32()
-   print "  ('nextdefsym', %r)" % f.read32()
-   print "  ('iundefsym', %r)" % f.read32()
-   print "  ('nundefsym', %r)" % f.read32()
-   print "  ('tocoff', %r)" % f.read32()
-   print "  ('ntoc', %r)" % f.read32()
-   print "  ('modtaboff', %r)" % f.read32()
-   print "  ('nmodtab', %r)" % f.read32()
-   print "  ('extrefsymoff', %r)" % f.read32()
-   print "  ('nextrefsyms', %r)" % f.read32()
-   indirectsymoff = f.read32()
-   print "  ('indirectsymoff', %r)" % indirectsymoff
-   nindirectsyms = f.read32()
-   print "  ('nindirectsyms', %r)" % nindirectsyms
-   print "  ('extreloff', %r)" % f.read32()
-   print "  ('nextrel', %r)" % f.read32()
-   print "  ('locreloff', %r)" % f.read32()
-   print "  ('nlocrel', %r)" % f.read32()
-
-   prev_pos = f.tell()
-
-   f.seek(indirectsymoff)
-   print "  ('_indirect_symbols', ["
-   for i in range(nindirectsyms):
-      print "    # Indirect Symbol %r" % i
-      print "    (('symbol_index', %#x),)," % f.read32()
-   print "  ])"
-      
-   f.seek(prev_pos)
-
-def dumpSection(f, i, opts, is64Bit):
-   print "    # Section %r" % i
-   print "   (('section_name', %r)" % f.read(16)
-   print "    ('segment_name', %r)" % f.read(16)
-   if is64Bit:
-      print "    ('address', %r)" % f.read64()
-      size = f.read64()
-      print "    ('size', %r)" % size
-   else:
-      print "    ('address', %r)" % f.read32()
-      size = f.read32()
-      print "    ('size', %r)" % size
-   offset = f.read32()
-   print "    ('offset', %r)" % offset
-   print "    ('alignment', %r)" % f.read32()   
-   reloc_offset = f.read32()
-   print "    ('reloc_offset', %r)" % reloc_offset
-   num_reloc = f.read32()
-   print "    ('num_reloc', %r)" % num_reloc
-   print "    ('flags', %#x)" % f.read32()
-   print "    ('reserved1', %r)" % f.read32()
-   print "    ('reserved2', %r)" % f.read32()
-   if is64Bit:
-      print "    ('reserved3', %r)" % f.read32()
-   print "   ),"
-
-   prev_pos = f.tell()
-
-   f.seek(reloc_offset)
-   print "  ('_relocations', ["
-   for i in range(num_reloc):
-      print "    # Relocation %r" % i
-      print "    (('word-0', %#x)," % f.read32()
-      print "     ('word-1', %#x))," % f.read32()
-   print "  ])"
-
-   if opts.dumpSectionData:
-      f.seek(offset)
-      print "  ('_section_data', '%s')" % common_dump.dataToHex(f.read(size))
-      
-   f.seek(prev_pos)
-   
-def main():
-    from optparse import OptionParser, OptionGroup
-    parser = OptionParser("usage: %prog [options] {files}")
-    parser.add_option("", "--dump-section-data", dest="dumpSectionData",
-                      help="Dump the contents of sections",
-                      action="store_true", default=False)    
-    (opts, args) = parser.parse_args()
-
-    if not args:
-       args.append('-')
-
-    for arg in args:
-       dumpmacho(arg, opts)
-
-if __name__ == '__main__':
-   main()

test/Scripts/macho-dumpx.bat

@@ -1,7 +0,0 @@
-@echo off
-
-@rem We need to set -u to treat stdin as binary. Python 3 has support for doing
-@rem this in code, but I haven't found a way to do this in 2.6 yet.
-
-%PYTHON_EXECUTABLE% -u %LLVM_SRC_ROOT%\test\Scripts\macho-dump %1 %2 %3 %4 %5 %6 %7 %8 %9
-

test/lit.cfg

@@ -56,17 +56,8 @@ llvm_obj_root = getattr(config, 'llvm_obj_root', None)
 if llvm_obj_root is not None:
     config.test_exec_root = os.path.join(llvm_obj_root, 'test')
 
-# Tweak the PATH to include the scripts dir, the tools dir, and the llvm-gcc bin
-# dir (if available).
+# Tweak the PATH to include the tools dir.
 if llvm_obj_root is not None:
-    llvm_src_root = getattr(config, 'llvm_src_root', None)
-    if not llvm_src_root:
-        lit.fatal('No LLVM source root set!')
-    path = os.path.pathsep.join((os.path.join(llvm_src_root, 'test',
-                                              'Scripts'),
-                                 config.environment['PATH']))
-    config.environment['PATH'] = path
-
     llvm_tools_dir = getattr(config, 'llvm_tools_dir', None)
     if not llvm_tools_dir:
         lit.fatal('No LLVM tools dir set!')