mirror of
https://github.com/yuzu-emu/unicorn
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339 lines
14 KiB
Python
339 lines
14 KiB
Python
# 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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#
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# Copyright (C) 2013, Red Hat, Inc.
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#
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# Authors:
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# Laszlo Ersek <lersek@redhat.com>
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#
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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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# 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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import struct
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class DumpGuestMemory(gdb.Command):
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"""Extract guest vmcore from qemu process coredump.
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The sole argument is FILE, identifying the target file to write the
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guest vmcore to.
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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".
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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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Only x86_64 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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TARGET_PAGE_SIZE = 0x1000
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TARGET_PAGE_MASK = 0xFFFFFFFFFFFFF000
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# Various ELF constants
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EM_X86_64 = 62 # AMD x86-64 target machine
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ELFDATA2LSB = 1 # little endian
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ELFCLASS64 = 2
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ELFMAG = "\x7FELF"
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EV_CURRENT = 1
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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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# 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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# Format strings for packing and header size calculation.
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ELF64_EHDR = ("4s" # e_ident/magic
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"B" # e_ident/class
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"B" # e_ident/data
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"B" # e_ident/version
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"B" # e_ident/osabi
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"8s" # e_ident/pad
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"H" # e_type
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"H" # e_machine
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"I" # e_version
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"Q" # e_entry
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"Q" # e_phoff
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"Q" # e_shoff
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"I" # e_flags
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"H" # e_ehsize
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"H" # e_phentsize
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"H" # e_phnum
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"H" # e_shentsize
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"H" # e_shnum
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"H" # e_shstrndx
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)
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ELF64_PHDR = ("I" # p_type
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"I" # p_flags
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"Q" # p_offset
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"Q" # p_vaddr
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"Q" # p_paddr
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"Q" # p_filesz
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"Q" # p_memsz
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"Q" # p_align
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)
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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.uintptr_t = gdb.lookup_type("uintptr_t")
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self.elf64_ehdr_le = struct.Struct("<%s" % self.ELF64_EHDR)
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self.elf64_phdr_le = struct.Struct("<%s" % self.ELF64_PHDR)
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def int128_get64(self, val):
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assert (val["hi"] == 0)
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return val["lo"]
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def qtailq_foreach(self, head, field_str):
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var_p = head["tqh_first"]
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while (var_p != 0):
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var = var_p.dereference()
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yield var
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var_p = var[field_str]["tqe_next"]
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def qemu_get_ram_block(self, ram_addr):
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ram_blocks = gdb.parse_and_eval("ram_list.blocks")
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for block in self.qtailq_foreach(ram_blocks, "next"):
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if (ram_addr - block["offset"] < block["length"]):
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return block
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raise gdb.GdbError("Bad ram offset %x" % ram_addr)
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def qemu_get_ram_ptr(self, ram_addr):
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block = self.qemu_get_ram_block(ram_addr)
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return block["host"] + (ram_addr - block["offset"])
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def memory_region_get_ram_ptr(self, mr):
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if (mr["alias"] != 0):
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return (self.memory_region_get_ram_ptr(mr["alias"].dereference()) +
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mr["alias_offset"])
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return self.qemu_get_ram_ptr(mr["ram_addr"] & self.TARGET_PAGE_MASK)
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def guest_phys_blocks_init(self):
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self.guest_phys_blocks = []
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def guest_phys_blocks_append(self):
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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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for cur in range(current_map["nr"]):
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flat_range = (current_map["ranges"] + cur).dereference()
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mr = flat_range["mr"].dereference()
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# we only care about RAM
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if (not mr["ram"]):
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continue
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section_size = self.int128_get64(flat_range["addr"]["size"])
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target_start = self.int128_get64(flat_range["addr"]["start"])
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target_end = target_start + section_size
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host_addr = (self.memory_region_get_ram_ptr(mr) +
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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(self.guest_phys_blocks) > 0):
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predecessor = self.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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self.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(self.uintptr_t),
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message, len(self.guest_phys_blocks)))
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def cpu_get_dump_info(self):
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# We can't synchronize the registers with KVM post-mortem, and
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# the bits in (first_x86_cpu->env.hflags) seem to be stale; they
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# may not reflect long mode for example. Hence just assume the
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# most common values. This also means that instruction pointer
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# etc. will be bogus in the dump, but at least the RAM contents
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# should be valid.
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self.dump_info = {"d_machine": self.EM_X86_64,
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"d_endian" : self.ELFDATA2LSB,
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"d_class" : self.ELFCLASS64}
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def encode_elf64_ehdr_le(self):
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return self.elf64_ehdr_le.pack(
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self.ELFMAG, # e_ident/magic
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self.dump_info["d_class"], # e_ident/class
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self.dump_info["d_endian"], # e_ident/data
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self.EV_CURRENT, # e_ident/version
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0, # e_ident/osabi
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"", # e_ident/pad
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self.ET_CORE, # e_type
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self.dump_info["d_machine"], # e_machine
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self.EV_CURRENT, # e_version
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0, # e_entry
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self.elf64_ehdr_le.size, # e_phoff
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0, # e_shoff
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0, # e_flags
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self.elf64_ehdr_le.size, # e_ehsize
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self.elf64_phdr_le.size, # e_phentsize
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self.phdr_num, # e_phnum
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0, # e_shentsize
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0, # e_shnum
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0 # e_shstrndx
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)
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def encode_elf64_note_le(self):
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return self.elf64_phdr_le.pack(self.PT_NOTE, # p_type
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0, # p_flags
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(self.memory_offset -
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len(self.note)), # p_offset
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0, # p_vaddr
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0, # p_paddr
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len(self.note), # p_filesz
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len(self.note), # p_memsz
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0 # p_align
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)
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def encode_elf64_load_le(self, offset, start_hwaddr, range_size):
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return self.elf64_phdr_le.pack(self.PT_LOAD, # p_type
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0, # p_flags
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offset, # p_offset
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0, # p_vaddr
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start_hwaddr, # p_paddr
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range_size, # p_filesz
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range_size, # p_memsz
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0 # p_align
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)
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def note_init(self, name, desc, type):
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# name must include a trailing NUL
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namesz = (len(name) + 1 + 3) / 4 * 4
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descsz = (len(desc) + 3) / 4 * 4
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fmt = ("<" # little endian
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"I" # n_namesz
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"I" # n_descsz
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"I" # n_type
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"%us" # name
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"%us" # desc
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% (namesz, descsz))
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self.note = struct.pack(fmt,
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len(name) + 1, len(desc), type, name, desc)
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def dump_init(self):
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self.guest_phys_blocks_init()
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self.guest_phys_blocks_append()
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self.cpu_get_dump_info()
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# we have no way to retrieve the VCPU status from KVM
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# post-mortem
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self.note_init("NONE", "EMPTY", 0)
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# Account for PT_NOTE.
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self.phdr_num = 1
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# We should never reach PN_XNUM for paging=false dumps: there's
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# just a handful of discontiguous ranges after merging.
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self.phdr_num += len(self.guest_phys_blocks)
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assert (self.phdr_num < self.PN_XNUM)
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# Calculate the ELF file offset where the memory dump commences:
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#
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# ELF header
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# PT_NOTE
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# PT_LOAD: 1
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# PT_LOAD: 2
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# ...
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# PT_LOAD: len(self.guest_phys_blocks)
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# ELF note
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# memory dump
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self.memory_offset = (self.elf64_ehdr_le.size +
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self.elf64_phdr_le.size * self.phdr_num +
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len(self.note))
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def dump_begin(self, vmcore):
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vmcore.write(self.encode_elf64_ehdr_le())
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vmcore.write(self.encode_elf64_note_le())
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running = self.memory_offset
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for block in self.guest_phys_blocks:
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range_size = block["target_end"] - block["target_start"]
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vmcore.write(self.encode_elf64_load_le(running,
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block["target_start"],
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range_size))
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running += range_size
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vmcore.write(self.note)
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def dump_iterate(self, vmcore):
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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(self.uintptr_t), left))
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while (left > 0):
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chunk_size = min(self.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 create_vmcore(self, filename):
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vmcore = open(filename, "wb")
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self.dump_begin(vmcore)
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self.dump_iterate(vmcore)
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vmcore.close()
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def invoke(self, args, from_tty):
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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) != 1):
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raise gdb.GdbError("usage: dump-guest-memory FILE")
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self.dump_init()
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self.create_vmcore(argv[0])
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DumpGuestMemory()
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