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e17bebd049
vaddr needs to be equal to the paddr since the dump file represents the physical memory image. Without setting vaddr correctly, GDB would load all the different memory regions on top of each other to vaddr 0, thus making GDB showing the wrong memory data for a given address. Signed-off-by: Jon Doron <arilou@gmail.com> Message-Id: <20190109082203.27142-1-arilou@gmail.com> Reviewed-by: Marc-André Lureau <marcandre.lureau@redhat.com> Tested-by: Marc-André Lureau <marcandre.lureau@redhat.com> Acked-by: Laszlo Ersek <lersek@redhat.com>
600 lines
20 KiB
Python
600 lines
20 KiB
Python
"""
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This python script adds a new gdb command, "dump-guest-memory". It
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should be loaded with "source dump-guest-memory.py" at the (gdb)
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prompt.
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Copyright (C) 2013, Red Hat, Inc.
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Authors:
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Laszlo Ersek <lersek@redhat.com>
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Janosch Frank <frankja@linux.vnet.ibm.com>
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This work is licensed under the terms of the GNU GPL, version 2 or later. See
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the COPYING file in the top-level directory.
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"""
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from __future__ import print_function
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import ctypes
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import struct
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try:
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UINTPTR_T = gdb.lookup_type("uintptr_t")
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except Exception as inst:
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raise gdb.GdbError("Symbols must be loaded prior to sourcing dump-guest-memory.\n"
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"Symbols may be loaded by 'attach'ing a QEMU process id or by "
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"'load'ing a QEMU binary.")
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TARGET_PAGE_SIZE = 0x1000
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TARGET_PAGE_MASK = 0xFFFFFFFFFFFFF000
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# Special value for e_phnum. This indicates that the real number of
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# program headers is too large to fit into e_phnum. Instead the real
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# value is in the field sh_info of section 0.
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PN_XNUM = 0xFFFF
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EV_CURRENT = 1
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ELFCLASS32 = 1
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ELFCLASS64 = 2
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ELFDATA2LSB = 1
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ELFDATA2MSB = 2
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ET_CORE = 4
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PT_LOAD = 1
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PT_NOTE = 4
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EM_386 = 3
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EM_PPC = 20
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EM_PPC64 = 21
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EM_S390 = 22
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EM_AARCH = 183
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EM_X86_64 = 62
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VMCOREINFO_FORMAT_ELF = 1
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def le16_to_cpu(val):
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return struct.unpack("<H", struct.pack("=H", val))[0]
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def le32_to_cpu(val):
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return struct.unpack("<I", struct.pack("=I", val))[0]
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def le64_to_cpu(val):
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return struct.unpack("<Q", struct.pack("=Q", val))[0]
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class ELF(object):
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"""Representation of a ELF file."""
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def __init__(self, arch):
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self.ehdr = None
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self.notes = []
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self.segments = []
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self.notes_size = 0
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self.endianness = None
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self.elfclass = ELFCLASS64
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if arch == 'aarch64-le':
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self.endianness = ELFDATA2LSB
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self.elfclass = ELFCLASS64
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self.ehdr = get_arch_ehdr(self.endianness, self.elfclass)
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self.ehdr.e_machine = EM_AARCH
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elif arch == 'aarch64-be':
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self.endianness = ELFDATA2MSB
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self.ehdr = get_arch_ehdr(self.endianness, self.elfclass)
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self.ehdr.e_machine = EM_AARCH
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elif arch == 'X86_64':
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self.endianness = ELFDATA2LSB
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self.ehdr = get_arch_ehdr(self.endianness, self.elfclass)
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self.ehdr.e_machine = EM_X86_64
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elif arch == '386':
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self.endianness = ELFDATA2LSB
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self.elfclass = ELFCLASS32
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self.ehdr = get_arch_ehdr(self.endianness, self.elfclass)
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self.ehdr.e_machine = EM_386
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elif arch == 's390':
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self.endianness = ELFDATA2MSB
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self.ehdr = get_arch_ehdr(self.endianness, self.elfclass)
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self.ehdr.e_machine = EM_S390
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elif arch == 'ppc64-le':
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self.endianness = ELFDATA2LSB
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self.ehdr = get_arch_ehdr(self.endianness, self.elfclass)
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self.ehdr.e_machine = EM_PPC64
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elif arch == 'ppc64-be':
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self.endianness = ELFDATA2MSB
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self.ehdr = get_arch_ehdr(self.endianness, self.elfclass)
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self.ehdr.e_machine = EM_PPC64
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else:
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raise gdb.GdbError("No valid arch type specified.\n"
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"Currently supported types:\n"
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"aarch64-be, aarch64-le, X86_64, 386, s390, "
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"ppc64-be, ppc64-le")
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self.add_segment(PT_NOTE, 0, 0)
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def add_note(self, n_name, n_desc, n_type):
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"""Adds a note to the ELF."""
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note = get_arch_note(self.endianness, len(n_name), len(n_desc))
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note.n_namesz = len(n_name) + 1
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note.n_descsz = len(n_desc)
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note.n_name = n_name.encode()
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note.n_type = n_type
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# Desc needs to be 4 byte aligned (although the 64bit spec
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# specifies 8 byte). When defining n_desc as uint32 it will be
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# automatically aligned but we need the memmove to copy the
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# string into it.
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ctypes.memmove(note.n_desc, n_desc.encode(), len(n_desc))
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self.notes.append(note)
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self.segments[0].p_filesz += ctypes.sizeof(note)
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self.segments[0].p_memsz += ctypes.sizeof(note)
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def add_vmcoreinfo_note(self, vmcoreinfo):
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"""Adds a vmcoreinfo note to the ELF dump."""
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# compute the header size, and copy that many bytes from the note
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header = get_arch_note(self.endianness, 0, 0)
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ctypes.memmove(ctypes.pointer(header),
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vmcoreinfo, ctypes.sizeof(header))
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if header.n_descsz > 1 << 20:
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print('warning: invalid vmcoreinfo size')
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return
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# now get the full note
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note = get_arch_note(self.endianness,
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header.n_namesz - 1, header.n_descsz)
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ctypes.memmove(ctypes.pointer(note), vmcoreinfo, ctypes.sizeof(note))
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self.notes.append(note)
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self.segments[0].p_filesz += ctypes.sizeof(note)
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self.segments[0].p_memsz += ctypes.sizeof(note)
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def add_segment(self, p_type, p_paddr, p_size):
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"""Adds a segment to the elf."""
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phdr = get_arch_phdr(self.endianness, self.elfclass)
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phdr.p_type = p_type
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phdr.p_paddr = p_paddr
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phdr.p_vaddr = p_paddr
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phdr.p_filesz = p_size
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phdr.p_memsz = p_size
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self.segments.append(phdr)
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self.ehdr.e_phnum += 1
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def to_file(self, elf_file):
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"""Writes all ELF structures to the the passed file.
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Structure:
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Ehdr
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Segment 0:PT_NOTE
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Segment 1:PT_LOAD
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Segment N:PT_LOAD
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Note 0..N
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Dump contents
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"""
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elf_file.write(self.ehdr)
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off = ctypes.sizeof(self.ehdr) + \
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len(self.segments) * ctypes.sizeof(self.segments[0])
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for phdr in self.segments:
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phdr.p_offset = off
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elf_file.write(phdr)
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off += phdr.p_filesz
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for note in self.notes:
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elf_file.write(note)
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def get_arch_note(endianness, len_name, len_desc):
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"""Returns a Note class with the specified endianness."""
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if endianness == ELFDATA2LSB:
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superclass = ctypes.LittleEndianStructure
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else:
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superclass = ctypes.BigEndianStructure
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len_name = len_name + 1
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class Note(superclass):
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"""Represents an ELF note, includes the content."""
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_fields_ = [("n_namesz", ctypes.c_uint32),
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("n_descsz", ctypes.c_uint32),
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("n_type", ctypes.c_uint32),
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("n_name", ctypes.c_char * len_name),
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("n_desc", ctypes.c_uint32 * ((len_desc + 3) // 4))]
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return Note()
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class Ident(ctypes.Structure):
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"""Represents the ELF ident array in the ehdr structure."""
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_fields_ = [('ei_mag0', ctypes.c_ubyte),
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('ei_mag1', ctypes.c_ubyte),
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('ei_mag2', ctypes.c_ubyte),
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('ei_mag3', ctypes.c_ubyte),
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('ei_class', ctypes.c_ubyte),
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('ei_data', ctypes.c_ubyte),
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('ei_version', ctypes.c_ubyte),
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('ei_osabi', ctypes.c_ubyte),
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('ei_abiversion', ctypes.c_ubyte),
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('ei_pad', ctypes.c_ubyte * 7)]
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def __init__(self, endianness, elfclass):
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self.ei_mag0 = 0x7F
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self.ei_mag1 = ord('E')
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self.ei_mag2 = ord('L')
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self.ei_mag3 = ord('F')
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self.ei_class = elfclass
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self.ei_data = endianness
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self.ei_version = EV_CURRENT
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def get_arch_ehdr(endianness, elfclass):
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"""Returns a EHDR64 class with the specified endianness."""
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if endianness == ELFDATA2LSB:
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superclass = ctypes.LittleEndianStructure
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else:
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superclass = ctypes.BigEndianStructure
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class EHDR64(superclass):
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"""Represents the 64 bit ELF header struct."""
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_fields_ = [('e_ident', Ident),
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('e_type', ctypes.c_uint16),
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('e_machine', ctypes.c_uint16),
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('e_version', ctypes.c_uint32),
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('e_entry', ctypes.c_uint64),
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('e_phoff', ctypes.c_uint64),
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('e_shoff', ctypes.c_uint64),
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('e_flags', ctypes.c_uint32),
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('e_ehsize', ctypes.c_uint16),
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('e_phentsize', ctypes.c_uint16),
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('e_phnum', ctypes.c_uint16),
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('e_shentsize', ctypes.c_uint16),
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('e_shnum', ctypes.c_uint16),
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('e_shstrndx', ctypes.c_uint16)]
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def __init__(self):
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super(superclass, self).__init__()
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self.e_ident = Ident(endianness, elfclass)
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self.e_type = ET_CORE
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self.e_version = EV_CURRENT
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self.e_ehsize = ctypes.sizeof(self)
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self.e_phoff = ctypes.sizeof(self)
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self.e_phentsize = ctypes.sizeof(get_arch_phdr(endianness, elfclass))
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self.e_phnum = 0
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class EHDR32(superclass):
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"""Represents the 32 bit ELF header struct."""
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_fields_ = [('e_ident', Ident),
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('e_type', ctypes.c_uint16),
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('e_machine', ctypes.c_uint16),
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('e_version', ctypes.c_uint32),
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('e_entry', ctypes.c_uint32),
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('e_phoff', ctypes.c_uint32),
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('e_shoff', ctypes.c_uint32),
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('e_flags', ctypes.c_uint32),
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('e_ehsize', ctypes.c_uint16),
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('e_phentsize', ctypes.c_uint16),
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('e_phnum', ctypes.c_uint16),
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('e_shentsize', ctypes.c_uint16),
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('e_shnum', ctypes.c_uint16),
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('e_shstrndx', ctypes.c_uint16)]
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def __init__(self):
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super(superclass, self).__init__()
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self.e_ident = Ident(endianness, elfclass)
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self.e_type = ET_CORE
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self.e_version = EV_CURRENT
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self.e_ehsize = ctypes.sizeof(self)
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self.e_phoff = ctypes.sizeof(self)
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self.e_phentsize = ctypes.sizeof(get_arch_phdr(endianness, elfclass))
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self.e_phnum = 0
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# End get_arch_ehdr
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if elfclass == ELFCLASS64:
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return EHDR64()
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else:
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return EHDR32()
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def get_arch_phdr(endianness, elfclass):
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"""Returns a 32 or 64 bit PHDR class with the specified endianness."""
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if endianness == ELFDATA2LSB:
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superclass = ctypes.LittleEndianStructure
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else:
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superclass = ctypes.BigEndianStructure
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class PHDR64(superclass):
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"""Represents the 64 bit ELF program header struct."""
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_fields_ = [('p_type', ctypes.c_uint32),
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('p_flags', ctypes.c_uint32),
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('p_offset', ctypes.c_uint64),
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('p_vaddr', ctypes.c_uint64),
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('p_paddr', ctypes.c_uint64),
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('p_filesz', ctypes.c_uint64),
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('p_memsz', ctypes.c_uint64),
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('p_align', ctypes.c_uint64)]
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class PHDR32(superclass):
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"""Represents the 32 bit ELF program header struct."""
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_fields_ = [('p_type', ctypes.c_uint32),
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('p_offset', ctypes.c_uint32),
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('p_vaddr', ctypes.c_uint32),
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('p_paddr', ctypes.c_uint32),
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('p_filesz', ctypes.c_uint32),
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('p_memsz', ctypes.c_uint32),
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('p_flags', ctypes.c_uint32),
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('p_align', ctypes.c_uint32)]
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# End get_arch_phdr
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if elfclass == ELFCLASS64:
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return PHDR64()
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else:
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return PHDR32()
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def int128_get64(val):
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"""Returns low 64bit part of Int128 struct."""
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try:
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assert val["hi"] == 0
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return val["lo"]
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except gdb.error:
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u64t = gdb.lookup_type('uint64_t').array(2)
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u64 = val.cast(u64t)
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if sys.byteorder == 'little':
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assert u64[1] == 0
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return u64[0]
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else:
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assert u64[0] == 0
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return u64[1]
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def qlist_foreach(head, field_str):
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"""Generator for qlists."""
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var_p = head["lh_first"]
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while var_p != 0:
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var = var_p.dereference()
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var_p = var[field_str]["le_next"]
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yield var
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def qemu_map_ram_ptr(block, offset):
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"""Returns qemu vaddr for given guest physical address."""
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return block["host"] + offset
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def memory_region_get_ram_ptr(memory_region):
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if memory_region["alias"] != 0:
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return (memory_region_get_ram_ptr(memory_region["alias"].dereference())
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+ memory_region["alias_offset"])
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return qemu_map_ram_ptr(memory_region["ram_block"], 0)
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def get_guest_phys_blocks():
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"""Returns a list of ram blocks.
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Each block entry contains:
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'target_start': guest block phys start address
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'target_end': guest block phys end address
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'host_addr': qemu vaddr of the block's start
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"""
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guest_phys_blocks = []
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print("guest RAM blocks:")
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print("target_start target_end host_addr message "
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"count")
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print("---------------- ---------------- ---------------- ------- "
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"-----")
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current_map_p = gdb.parse_and_eval("address_space_memory.current_map")
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current_map = current_map_p.dereference()
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# Conversion to int is needed for python 3
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# compatibility. Otherwise range doesn't cast the value itself and
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# breaks.
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for cur in range(int(current_map["nr"])):
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flat_range = (current_map["ranges"] + cur).dereference()
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memory_region = flat_range["mr"].dereference()
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# we only care about RAM
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if (not memory_region["ram"] or
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memory_region["ram_device"] or
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memory_region["nonvolatile"]):
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continue
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section_size = int128_get64(flat_range["addr"]["size"])
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target_start = int128_get64(flat_range["addr"]["start"])
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target_end = target_start + section_size
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host_addr = (memory_region_get_ram_ptr(memory_region)
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+ flat_range["offset_in_region"])
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predecessor = None
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# find continuity in guest physical address space
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if len(guest_phys_blocks) > 0:
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predecessor = guest_phys_blocks[-1]
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predecessor_size = (predecessor["target_end"] -
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predecessor["target_start"])
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# the memory API guarantees monotonically increasing
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# traversal
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assert predecessor["target_end"] <= target_start
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# we want continuity in both guest-physical and
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# host-virtual memory
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if (predecessor["target_end"] < target_start or
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predecessor["host_addr"] + predecessor_size != host_addr):
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predecessor = None
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if predecessor is None:
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# isolated mapping, add it to the list
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guest_phys_blocks.append({"target_start": target_start,
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"target_end": target_end,
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"host_addr": host_addr})
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message = "added"
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else:
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# expand predecessor until @target_end; predecessor's
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# start doesn't change
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predecessor["target_end"] = target_end
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message = "joined"
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print("%016x %016x %016x %-7s %5u" %
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(target_start, target_end, host_addr.cast(UINTPTR_T),
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message, len(guest_phys_blocks)))
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return guest_phys_blocks
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# The leading docstring doesn't have idiomatic Python formatting. It is
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# printed by gdb's "help" command (the first line is printed in the
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# "help data" summary), and it should match how other help texts look in
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# gdb.
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class DumpGuestMemory(gdb.Command):
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"""Extract guest vmcore from qemu process coredump.
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The two required arguments are FILE and ARCH:
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FILE identifies the target file to write the guest vmcore to.
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ARCH specifies the architecture for which the core will be generated.
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This GDB command reimplements the dump-guest-memory QMP command in
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python, using the representation of guest memory as captured in the qemu
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coredump. The qemu process that has been dumped must have had the
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command line option "-machine dump-guest-core=on" which is the default.
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For simplicity, the "paging", "begin" and "end" parameters of the QMP
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command are not supported -- no attempt is made to get the guest's
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internal paging structures (ie. paging=false is hard-wired), and guest
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memory is always fully dumped.
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Currently aarch64-be, aarch64-le, X86_64, 386, s390, ppc64-be,
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ppc64-le guests are supported.
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The CORE/NT_PRSTATUS and QEMU notes (that is, the VCPUs' statuses) are
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not written to the vmcore. Preparing these would require context that is
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only present in the KVM host kernel module when the guest is alive. A
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fake ELF note is written instead, only to keep the ELF parser of "crash"
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happy.
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Dependent on how busted the qemu process was at the time of the
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coredump, this command might produce unpredictable results. If qemu
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deliberately called abort(), or it was dumped in response to a signal at
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a halfway fortunate point, then its coredump should be in reasonable
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shape and this command should mostly work."""
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def __init__(self):
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super(DumpGuestMemory, self).__init__("dump-guest-memory",
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gdb.COMMAND_DATA,
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gdb.COMPLETE_FILENAME)
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self.elf = None
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self.guest_phys_blocks = None
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def dump_init(self, vmcore):
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"""Prepares and writes ELF structures to core file."""
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# Needed to make crash happy, data for more useful notes is
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# not available in a qemu core.
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self.elf.add_note("NONE", "EMPTY", 0)
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# We should never reach PN_XNUM for paging=false dumps,
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# there's just a handful of discontiguous ranges after
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# merging.
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# The constant is needed to account for the PT_NOTE segment.
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phdr_num = len(self.guest_phys_blocks) + 1
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assert phdr_num < PN_XNUM
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for block in self.guest_phys_blocks:
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block_size = block["target_end"] - block["target_start"]
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self.elf.add_segment(PT_LOAD, block["target_start"], block_size)
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self.elf.to_file(vmcore)
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def dump_iterate(self, vmcore):
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"""Writes guest core to file."""
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qemu_core = gdb.inferiors()[0]
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for block in self.guest_phys_blocks:
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cur = block["host_addr"]
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left = block["target_end"] - block["target_start"]
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print("dumping range at %016x for length %016x" %
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(cur.cast(UINTPTR_T), left))
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while left > 0:
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chunk_size = min(TARGET_PAGE_SIZE, left)
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chunk = qemu_core.read_memory(cur, chunk_size)
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vmcore.write(chunk)
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cur += chunk_size
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left -= chunk_size
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def phys_memory_read(self, addr, size):
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qemu_core = gdb.inferiors()[0]
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for block in self.guest_phys_blocks:
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if block["target_start"] <= addr \
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and addr + size <= block["target_end"]:
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haddr = block["host_addr"] + (addr - block["target_start"])
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return qemu_core.read_memory(haddr, size)
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return None
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def add_vmcoreinfo(self):
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if gdb.lookup_symbol("vmcoreinfo_realize")[0] is None:
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return
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vmci = 'vmcoreinfo_realize::vmcoreinfo_state'
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if not gdb.parse_and_eval("%s" % vmci) \
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or not gdb.parse_and_eval("(%s)->has_vmcoreinfo" % vmci):
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return
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fmt = gdb.parse_and_eval("(%s)->vmcoreinfo.guest_format" % vmci)
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addr = gdb.parse_and_eval("(%s)->vmcoreinfo.paddr" % vmci)
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size = gdb.parse_and_eval("(%s)->vmcoreinfo.size" % vmci)
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fmt = le16_to_cpu(fmt)
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addr = le64_to_cpu(addr)
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size = le32_to_cpu(size)
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if fmt != VMCOREINFO_FORMAT_ELF:
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return
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vmcoreinfo = self.phys_memory_read(addr, size)
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if vmcoreinfo:
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self.elf.add_vmcoreinfo_note(bytes(vmcoreinfo))
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def invoke(self, args, from_tty):
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"""Handles command invocation from gdb."""
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# Unwittingly pressing the Enter key after the command should
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# not dump the same multi-gig coredump to the same file.
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self.dont_repeat()
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argv = gdb.string_to_argv(args)
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if len(argv) != 2:
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raise gdb.GdbError("usage: dump-guest-memory FILE ARCH")
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self.elf = ELF(argv[1])
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self.guest_phys_blocks = get_guest_phys_blocks()
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self.add_vmcoreinfo()
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with open(argv[0], "wb") as vmcore:
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self.dump_init(vmcore)
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self.dump_iterate(vmcore)
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DumpGuestMemory()
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