[Crash-utility] questions about crash utility
卜弋天
buyit at live.cn
Fri Jan 18 17:04:24 UTC 2013
> Date: Fri, 18 Jan 2013 10:23:00 -0500
> From: anderson at redhat.com
> To: crash-utility at redhat.com
> Subject: Re: [Crash-utility] questions about crash utility
>
>
>
> ----- Original Message -----
> >
> >
> >
> > Hi Dave:
> >
> > thank you very much for your detail answer, this really helpful.
> > please see my inline words. thanks.
> >
> >
> > > Date: Thu, 17 Jan 2013 14:17:36 -0500
> > > From: anderson at redhat.com
> > > To: crash-utility at redhat.com
> > > Subject: Re: [Crash-utility] questions about crash utility
> >
> > > The fact that crash gets as far as it does at least means that the
> > > ELF header you've created was deemed acceptable as an ARM vmcore.
> > > However, the error messages re: "cpu_present_mask indicates..." and
> > > "cannot determine base kernel version" indicate that the data
> > > that was read from the vmcore was clearly not the correct data.
> > >
> > > The "cpu_present_mask" value that it read contained too
> > > many bits -- presuming that the 32-bit ARM processor is
> > > still limited to only 4 cpus. (looks like upstream that
> > > CONFIG_NR_CPUS is still 2 in the arch/arm/configs files.)
> > >
> > > But more indicative of the wrong data being read is the second
> > > "cannot determine base kernel version" message, which was generated
> > > after it read the kernel's "init_uts_ns" uts_namespace structure.
> > > After reading it, it sees that the "release" string contains
> > > non-ASCII data, whereas it should contain the kernel version:
> > >
> > > crash> p init_uts_ns
> > > init_uts_ns = $3 = {
> > > kref = {
> > > refcount = {
> > > counter = 2
> > > }
> > > },
> > > name = {
> > > sysname =
> > > "Linux\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000",
> > > nodename =
> > > "phenom-01.lab.bos.redhat.com\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000",
> > > release =
> > > "2.6.32-313.el6.x86_64\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000",
> > > version = "#1 SMP Thu Sep 27 16:25:19 EDT
> > > 2012\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000",
> > > machine =
> > > "x86_64\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000",
> > > domainname =
> > > "(none)\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000\000"
> > > }
> > > }
> > > crash>
> > >
> > > So it appears that you're reading data from the wrong
> > > locations in the dumpfile. You should be able to verify
> > > that by bringing up the crash session with the --minimal
> > > flag like this:
> > >
> > > $ crash --minimal vmlinux vmcore
> > >
> > > That will bypass most of the initialization, including all
> > > readmem() calls of the vmcore. Then do this:
> > >
> > > crash> rd linux_banner 20
> > > ffffffff818000a0: 65762078756e694c 2e33206e6f697372 Linux version
> > > 3.
> > > ffffffff818000b0: 63662e312d312e35 365f3638782e3731 5.1-1.fc17.x86_6
> > > ffffffff818000c0: 626b636f6d282034 69756240646c6975 4(mockbuild at bui
> > > ffffffff818000d0: 2e33322d6d76646c 6465662e32786870 ldvm-23.phx2.fed
> > > ffffffff818000e0: 656a6f727061726f 202967726f2e7463 oraproject.org)
> > > ffffffff818000f0: 7265762063636728 372e34206e6f6973 (gcc version 4.7
> > > ffffffff81800100: 303231303220302e 6465522820373035 .0 20120507
> > > (Red
> > > ffffffff81800110: 372e342074614820 47282029352d302e Hat 4.7.0-5) (G
> > > ffffffff81800120: 3123202920294343 75685420504d5320 CC) ) #1 SMP Thu
> > > ffffffff81800130: 3120392067754120 2033343a30353a37 Aug 9 17:50:43
> > > crash> rd -a linux_banner
> > > ffffffff818000a0: Linux version 3.5.1-1.fc17.x86_64 (mockbuild at buildvm-23.phx2
> > > ffffffff818000dc: .fedoraproject.org) (gcc version 4.7.0 20120507 (Red Hat 4.7
> > > ffffffff81800118: .0-5) (GCC) ) #1 SMP Thu Aug 9 17:50:43 UTC 2012
> > > crash>
> > >
> > > I'm guessing that you will not see a string starting with "Linux version"
> > > with your dumpfile as shown above.
> > >
> > > If that's the case, then it's clear that the readmem() function is ultimately
> > > reading from the wrong vmcore file offset.
> > >
> > > Here's what you can try doing. Taking the linux_banner example above,
> > > you can check where in the dumpfile it's reading from by setting the debug
> > > flag, before doing a simple read -- like this example on an ARM dumpfile:
> > >
> > > crash> set debug 8
> > > debug: 8
> > > crash> rd linux_banner
> > > <addr: c033ea10 count: 1 flag: 488 (KVADDR)>
> > > <readmem: c033ea10, KVADDR, "32-bit KVADDR", 4, (FOE), ff94f048>
> > > <read_kdump: addr: c033ea10 paddr: 33ea10 cnt: 4>
> > > read_netdump: addr: c033ea10 paddr: 33ea10 cnt: 4 offset: 33f088
> > > c033ea10: 756e694c Linu
> > > crash>
> > >
> > > The linux_banner is at virtual address c033ea10 (addr). First it gets translated
> > > into physical address 33ea10 (paddr). Then that paddr is translated into the
> > > vmcore file offset of 33f088. It lseeks to vmcore file offset 33f088 and
> > > reads 4 bytes, which contain "756e694c", or the first 4 bytes of the
> > > "Linux version ..." string.
> > >
> > > Note that if I subtract the physical address from vmcore file offset
> > > I get this:
> > >
> > > crash> eval 33f088 - 33ea10
> > > hexadecimal: 678
> > > decimal: 1656
> > > octal: 3170
> > > binary: 00000000000000000000011001111000
> > > crash>
> > >
> > > which would put physical address 0 at a vmcore file offset of 0x678, and
> > > therefore implying that that the ELF header comprises the first 0x678 bytes.
> > > And looking at the vmcore, that can be verified:
> > >
> >
> > yes you are right, here i get the result as below:
> > crash> set debug 8
> > debug: 8
> > crash> rd linux_banner
> > <addr: c065a071 count: 1 flag: 488 (KVADDR)>
> > <readmem: c065a071, KVADDR, "32-bit KVADDR", 4, (FOE), ffdf297c>
> > <read_kdump: addr: c065a071 paddr: 85a071 cnt: 4>
> > read_netdump: addr: c065a071 paddr: 85a071 cnt: 4 offset: 65a0e5
> > c065a071: 03e59130 0...
> >
> > the virtual address is 0xc065a071 , and the physical address is
> > 0x85a071 , and the offset is 0x65a0e5.
> > my elf header is 116 bytes long, 0x65a0e5 - 116=0x65A071, which has a
> > gap 0x00200000 with the physical address 0x85a071.
> >
> >
> > > $ readelf -a vmcore
> > > ELF Header:
> > > Magic: 7f 45 4c 46 01 01 01 00 00 00 00 00 00 00 00 00
> > > Class: ELF32
> > > Data: 2's complement, little endian
> > > Version: 1 (current)
> > > OS/ABI: UNIX - System V
> > > ABI Version: 0
> > > Type: CORE (Core file)
> > > Machine: ARM
> > > Version: 0x1
> > > Entry point address: 0x0
> > > Start of program headers: 52 (bytes into file)
> > > Start of section headers: 0 (bytes into file)
> > > Flags: 0x0
> > > Size of this header: 52 (bytes)
> > > Size of program headers: 32 (bytes)
> > > Number of program headers: 3
> > > Size of section headers: 0 (bytes)
> > > Number of section headers: 0
> > > Section header string table index: 0
> > >
> > > There are no sections in this file.
> > >
> > > There are no sections to group in this file.
> > >
> > > Program Headers:
> > > Type Offset VirtAddr PhysAddr FileSiz MemSiz Flg Align
> > > NOTE 0x000094 0x00000000 0x004e345c 0x005e4 0x005e4 0
> > > LOAD 0x000678 0xc0000000 0x00000000 0x5600000 0x5600000 RWE 0
> > > LOAD 0x5600678 0xc5700000 0x05700000 0x100000 0x100000 RWE 0
> > > ...
> > >
> > > Note that the "Offset" value of the first PT_LOAD segment has a file offset
> > > value of 0x678.
> > >
> >
> > here i got the result as below:
> > Program Headers:
> > Type Offset VirtAddr PhysAddr FileSiz MemSiz Flg Align
> > NOTE 0x000000 0x00000000 0x00000000 0x00000 0x00000 0
> > LOAD 0x000074 0xc0000000 0x00200000 0x2fe00000 0x2fe00000 RWE 0
> >
> > so the problem is i don't understand the elf header meaning
> > accurately. if i modify code as below, everything is ok for me:
> >
> > offset += sizeof(struct elf_phdr);
> > phdr->p_offset = offset+0x00200000;
> > phdr->p_vaddr = 0xc0000000;
> > phdr->p_paddr = 0x00200000;
> > phdr->p_filesz = phdr->p_memsz = = MEMSIZE-0x00200000;
> >
> >
> > although my modification can make crash utility work well, i want to
> > know exactly whether i am doing the right thing.
> > 1. our platform has the ddr address from physical address 0x0.
> > 2. when compiling Linux kernel, our platform set in .config file:
> > CONFIG_PHYS_OFFSET=0x00200000
> > 3. when Kernel crash, all ddr content will be dumped, from address
> > 0x0~768MB. but kernel data starts from 0x00200000 actually.
> >
> > my questions are:
> > 1. whether my setting of ELF header is correct this time? the offset,
> > paddr, and p_memsz?
>
> I'm not really sure. Even though you've got it to work OK, I don't
> understand your new phdr->p_offset and phdr->p_filesz/phdr->p_memsz
> settings. The phdr->p_offset value typically points to the beginning
> of the physical memory segment, which in your case, would be at physical
> address 0x0 at file offset 0x74. And the phdr->p_filesz/phdr->p_memsz
> values are typically equal to the full size of the physical memory
> segment (MEMSIZE).
> if i set p_offset to 0, the file offset seems not correct. for example, when i try to read linux_banner, i got below result: crash> set debug 8
debug: 8
crash> rd linux_banner
<addr: c065a071 count: 1 flag: 488 (KVADDR)>
<readmem: c065a071, KVADDR, "32-bit KVADDR", 4, (FOE), ffdf297c>
<read_kdump: addr: c065a071 paddr: 85a071 cnt: 4> read_netdump: addr: c065a071 paddr: 85a071 cnt: 4 offset: 65a0e5
c065a071: 03e59130 0... virtual address is c065a071, physical address is 85a071, this is ok.but the tool said the file offset is 65a0e5, which is not correct. because my dump binarycontains ddr content from 0x0, the data of physical address 85a071 should be at dump fileoffset 85a071+74= 85a0e5, rather than 65a0e5. so i guess the elf header should be modified to set phdr->p_offset =header size + 0x00200000.i don't know how to tell crash utility it should add value 0x00200000 when read dump file.
> I only have one ELF ARM dumpfile sample, but it does not have any
> physical offset:
>
> crash> vtop c0000000
> VIRTUAL PHYSICAL
> c0000000 0
>
> PAGE DIRECTORY: c0004000
> PGD: c0007000 => 1140e
> PMD: c0007000 => 1140e
> PAGE: 0 (1MB)
>
>
> PAGE PHYSICAL MAPPING INDEX CNT FLAGS
> c042d000 0 0 0 0 80000
> crash>
>
> Does "vtop c0000000" work as expected on your vmcore? yes i think the vtop command works well on my side: crash> vtop c0000000
VIRTUAL PHYSICAL
c0000000 200000PAGE DIRECTORY: c0004000
PGD: c0007000 => 21140e
PMD: c0007000 => 21140e
PAGE: 200000 (1MB)
PAGE PHYSICAL MAPPING INDEX CNT FLAGS
c1370800 200000 e5d43061 42 1 80068
>
> Also, can you read the last physical page of memory? For example, on
> my ARM dump, I can check that by doing this:
>
> crash> kmem -p | tail -5
> c04dcf60 57fb000 0 0 1 400
> c04dcf80 57fc000 0 0 1 400
> c04dcfa0 57fd000 0 0 1 400
> c04dcfc0 57fe000 0 0 1 400
> c04dcfe0 57ff000 0 0 1 400
> crash> rd -p 57ff000
> 57ff000: ef9f0000 ....
> crash>
> result is as below: crash> kmem -p |tail -5
c19b934c 2ccfb000 0 0 1 400
c19b9370 2ccfc000 0 0 1 400
c19b9394 2ccfd000 0 0 1 400
c19b93b8 2ccfe000 0 0 1 400
c19b93dc 2ccff000 0 0 1 400
crash> rd -p 2ccff000
2ccff000: fffdffff ....
> Also, can you confirm that your kernel's symbol list starts
> at c0000000, i.e., something like this:
>
> crash> sym -l
> c0004000 (A) swapper_pg_dir
> c0008000 (t) .init
> c0008000 (T) __init_begin
> c0008000 (T) _sinittext
> c0008000 (T) _stext
> c0008000 (T) stext
> c0008040 (t) __create_page_tables
> c00080e4 (t) __enable_mmu_loc
> c00080f0 (t) __error_a
> c00080f4 (t) __lookup_machine_type
> c0008128 (t) __lookup_machine_type_data
> ...
>
> I just want to make sure that the kernel symbols actually start
> at c000000, and not c2000000.
> yes, the symbols actually start from c0000000: crash> sym -l
c0004000 (A) swapper_pg_dir
c0005fb8 (A) __crc_scsi_host_get
c0008000 (t) .head.text
c0008000 (T) _text
c0008000 (T) stext
c0008050 (t) __create_page_tables
c0008104 (t) __turn_mmu_on_loc
c0008110 (T) secondary_startup
> > 2. i am wondering how does crash utility translate virtual address to
> > physical address before and after it get the kernel page table?
> > before get kernel page table, does it calculate as : (virtual_addr -
> > p_vaddr + p_paddr) ? after get kernel page table, does it walk
> > through the page table and find out the real physical address
> > accordingly?
>
> For kernel unity-mapped kernel virtual addresses, it's not necessary
> to walk the page tables. It simply does this:
>
> #define VTOP(X) \
> ((unsigned long)(X)-(machdep->kvbase)+(machdep->machspec->phys_base))
>
> You can check your machdep->kvbase and machdep->machspec->phys_base
> values by entering "help -m", for example:
>
> crash> help -m | grep -e kvbase -e phys_base
> kvbase: c0000000
> phys_base: 0
> crash>
> my result is as below, should be ok: crash> help -m | grep -e kvbase -e phys_base
kvbase: c0000000
phys_base: 200000
> Certainly vmalloc (and user-space) virtual addresses require a page
> table walkthough, but the arm_kvtop() function does this:
>
> static int
> arm_kvtop(struct task_context *tc, ulong kvaddr, physaddr_t *paddr, int verbose)
> {
> if (!IS_KVADDR(kvaddr))
> return FALSE;
>
> if (!vt->vmalloc_start) {
> *paddr = VTOP(kvaddr);
> return TRUE;
> }
>
> if (!IS_VMALLOC_ADDR(kvaddr)) {
> *paddr = VTOP(kvaddr); <=== unity-mapped kernel virtual addresses
> if (!verbose)
> return TRUE;
> }
>
> return arm_vtop(kvaddr, (ulong *)vt->kernel_pgd[0], paddr, verbose);
> }
>
> and where vmalloc addresses fall through and arm_vtop() is called to walk
> the page tables.
>
> However, you can translate unity-mapped addresses using the kernel page tables
> with the "vtop" command, as shown in the "vtop c000000" example above.
>
> > 3. my real purpose is to get the ftrace content from dump file by
> > crash utility , but seem the command trace is not for this case, do
> > i need to compile the extension "trace" of crash utility? is there
> > any guide to follow?
>
> That's correct. You can do this:
>
> $ wget http://people.redhat.com/anderson/crash-6.1.2.tar.gz
> ...
> $ tar xvzmf crash-6.1.2.tar.gz
> ...
> $ cd crash-6.1.2
> $ make
> ...
> $ make extensions
> ...
> $ ./crash vmlinux vmcore
> ...
> crash> extend trace.so
> ./extensions/trace.so: shared object loaded
> crash> help trace
> ... i have made the trace extension work, however, trace show need trace-cmd, but in my ubuntu PC, run "sudo apt-get install trace-cmd", i get below error:E: Couldn't find package trace-cmd
by Google, i found that there is a project git://git.kernel.org/pub/scm/linux/kernel/git/rostedt/trace-cmd.git. maybe i can only compile this tool and use it ?
>
> Dave
>
> --
> Crash-utility mailing list
> Crash-utility at redhat.com
> https://www.redhat.com/mailman/listinfo/crash-utility
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