[lld] r244691 - COFF: Align sections to 512-byte boundaries on disk.
Sean Silva via llvm-commits
llvm-commits at lists.llvm.org
Mon Sep 14 13:40:38 PDT 2015
This weirdness is described a little bit in Windows Internals (6th
edition). On page 283-284 of Part 2 (in Chapter 10, "Memory Management"),
it describes that there is a "data section control area" and "image section
control area" for each file (it seems that each "control area" roughly
corresponding to a file tracked by the page cache). The "data section
control area" is basically the tracking structure for mapped pages of the
file. The "image section control area" is the same thing and usually null,
but for image files contains duplicated copies of the file, regardless of
alignment. Based on the description, it seems like there is no way to avoid
the duplication unfortunately. I also just looked on windows 8 and,
empirically, page-aligned mappings don't seem to be shared between "data"
and "image".
It seems like "image" type mappings can only be created by the image
loader; this isn't related to executable vs. non-executable permissions
thankfully.
-- Sean Silva
On Wed, Sep 9, 2015 at 9:59 PM, Sean Silva <chisophugis at gmail.com> wrote:
>
>
> On Wed, Sep 9, 2015 at 8:49 PM, Rui Ueyama <ruiu at google.com> wrote:
>
>> Thank you for doing this, but I cannot decipher these values myself. Does
>> that means the kernel does some crazy stuff for non-4K-aligned sections?
>>
>
> I can only speculate (and I still have a hard time believing this), but I
> have to assume that if link.exe still produces binaries like this, then the
> reasoning may be that since they already need to be compatible with
> previous binaries, then they might as well keep doing what they are doing.
> While solving this requires a hack, it does not need to be very costly; it
> shouldn't have a noticeable overall performance effect, except where the
> image needs to be simultaneously loaded at two different offsets modulo the
> page size.
>
> Since it isn't possible (AFAIK) on windows for a process to create a
> "misaligned" mapping like this, the primary time that I expect this to
> matter is when an image is being handled as "data" by a regular process and
> simultaneously loaded as an image (or merely close in time, since files
> will persist in the page cache). For example, I recently installed google
> chrome on my machine, and you can see that this random dll is duplicated in
> memory: http://i.imgur.com/i90JVzO.png
> Hopefully, if the file is page-aligned, then this extra copy will not need
> to happen (I have not tested; the kernel may unconditionally create a
> duplicate "Image" page even if it doesn't technically need to).
> Even with a binary that has not been recently touched or anything there
> still seems to be a small amount of duplication, such as mspaint.exe on my
> machine: http://i.imgur.com/ul1LZJz.png
> (some process was looking at just the first part of the file?)
> Unfortunately, the 0x0 offset allocation seems to be duplicated for
> "Image", even though there is no alignment concern, so I don't know if
> there is hope that aligning will help things. Further testing is required.
>
> -- Sean Silva
>
>
>>
>> On Thu, Sep 10, 2015 at 11:17 AM, Sean Silva <chisophugis at gmail.com>
>> wrote:
>>
>>> I got a chance to look at this today in RamMap. Looks like they do have
>>> some crazy hack in the kernel to handle images specially:
>>> http://i.imgur.com/BeDov07.png
>>> They have a special "image" flag column to indicate this.
>>>
>>> -- Sean Silva
>>>
>>> On Fri, Aug 14, 2015 at 1:19 AM, Sean Silva <chisophugis at gmail.com>
>>> wrote:
>>>
>>>>
>>>>
>>>> On Thu, Aug 13, 2015 at 10:53 PM, Rui Ueyama <ruiu at google.com> wrote:
>>>>
>>>>> On Fri, Aug 14, 2015 at 8:04 AM, Sean Silva <chisophugis at gmail.com>
>>>>> wrote:
>>>>>
>>>>>>
>>>>>>
>>>>>> On Thu, Aug 13, 2015 at 12:51 AM, Rui Ueyama <ruiu at google.com> wrote:
>>>>>>
>>>>>>> I think I do understand how the paging mechanism works. :) We are
>>>>>>> talking about different things. My question is why you think a file offset
>>>>>>> must be at a 4K boundary in order to map it efficiently to memory. To me
>>>>>>> you seems to be claiming that mmap(0, /*length*/4096, PROT_READ|PROT_EXEC,
>>>>>>> 0, SomeFD, /*file offset*/5120) is much inefficient than mmap(0,
>>>>>>> /*length*/4096, PROT_READ|PROT_EXEC, 0, SomeFD, /*file
>>>>>>> offset*/4096) because of the file offset of the former mmap call is not a
>>>>>>> multiple of 4096. And I'm saying that that's not true.
>>>>>>>
>>>>>>
>>>>>>
>>>>>> The paging layer generally has the file already in physical memory
>>>>>> before you ask it to map it. When it originally read the file off disk, how
>>>>>> would it know what alignment the file should have in physical memory? The
>>>>>> reality is that the alignment in the file is the alignment in physical
>>>>>> memory. If the paging system had to be aware of having different parts of
>>>>>> the file mapped in at arbitrary alignments it would be much more
>>>>>> complicated (in practice, it will either be a hard error, or will force the
>>>>>> kernel to explicitly make a copy, but the paging system won't do this
>>>>>> automatically).
>>>>>>
>>>>>
>>>>> The loader is able to (and I presume it does) read only the header of
>>>>> an executable first and then map each sections to memory. I don't think
>>>>> that the entire executables files are "generally" already mapped to memory.
>>>>>
>>>>
>>>> I say "generally" because the loader cannot know or not (layering
>>>> violation in the kernel).
>>>>
>>>>
>>>>> Executable files are usually read only by the loader, and as long as
>>>>> the loader is consistent in how it maps each section to memory, no memcpy
>>>>> is needed.
>>>>>
>>>>
>>>> It would require a pretty serious layering violation for something as
>>>> high-level as the loader to control at what offset modulo the page size a
>>>> piece of a file is read into. It would require reaching through so many
>>>> layers of the kernel in order for the loader to control that. In both Linux
>>>> and FreeBSD (as examples of something in general), there is simply no API
>>>> for mapping files that operates at sub-page granularity. In Linux vm_mmap
>>>> literally rejects anything that is not page aligned (
>>>> http://lxr.free-electrons.com/source/mm/util.c#L306), and immediately
>>>> calls into vm_mmap_pgoff which operates in terms of pages only. In FreeBSD,
>>>> in the link I gave you can see that the copying process is external to the
>>>> virtual memory system / fs -- the loader has to do it itself.
>>>>
>>>> Like I said, it is possible for Windows to have a hack to do this. But
>>>> it seems unlikely since fixing the linker is so much easier. I can believe
>>>> that link.exe might set the FileAlignment to 512 bytes, but surely it must
>>>> be actually page aligning the sections in the file (which is correct to do
>>>> with a setting of FileAlignment == 512).
>>>>
>>>> -- Sean Silva
>>>>
>>>>
>>>>>
>>>>>
>>>>>> Also, keep in mind that 512 byte "sector size" has almost nothing to
>>>>>> do with how modern kernels/hardware do IO. It is a historical thing.
>>>>>>
>>>>>> -- Sean Silva
>>>>>>
>>>>>>
>>>>>>
>>>>>>>
>>>>>>> On Thu, Aug 13, 2015 at 4:10 PM, Sean Silva <chisophugis at gmail.com>
>>>>>>> wrote:
>>>>>>>
>>>>>>>>
>>>>>>>>
>>>>>>>> On Wed, Aug 12, 2015 at 10:59 PM, Rui Ueyama <ruiu at google.com>
>>>>>>>> wrote:
>>>>>>>>
>>>>>>>>> What I don't understand is that why the offset from the beginning
>>>>>>>>> of the file must be multiple of page size in order to avoid full copy.
>>>>>>>>> Windows requires all sections to be aligned at least 4K in memory and 512
>>>>>>>>> bytes on file, and I don't see any problem there.
>>>>>>>>>
>>>>>>>>> Let's say we have two sections, A and B, whose sizes are 1024B and
>>>>>>>>> 4096B, respectively. We also assume that A's offset from the beginning of
>>>>>>>>> file is 4096, and B's 5120. The loader can map offset 4096 to 8192 of the
>>>>>>>>> file to some page, and 5120 to 9216 to other page. Why can't that?
>>>>>>>>>
>>>>>>>>
>>>>>>>> From the kernel's perspective of mapping memory (on x86), memory is
>>>>>>>> divided into aligned 4K pieces. 5120 % 4096 == 1024, so in order to map it
>>>>>>>> at an address that is 4K aligned, it must do a full memmove in order to
>>>>>>>> move all the memory by 1024 bytes so that it is 4K aligned. This image
>>>>>>>> maybe helps to understand how a 32-bit x86 CPU understands a virtual memory
>>>>>>>> address:
>>>>>>>>
>>>>>>>> https://upload.wikimedia.org/wikipedia/commons/8/8e/X86_Paging_4K.svg
>>>>>>>>
>>>>>>>> IIRC the resources I learned from are:
>>>>>>>>
>>>>>>>> http://duartes.org/gustavo/blog/post/how-the-kernel-manages-your-memory/
>>>>>>>> http://duartes.org/gustavo/blog/post/the-thing-king/
>>>>>>>> (that web page has many other very, *very* good posts. A list can
>>>>>>>> be seen at: http://duartes.org/gustavo/blog/category/internals/)
>>>>>>>>
>>>>>>>> I think you will find that understanding virtual memory (and TLB)
>>>>>>>> will greatly help you optimize LLD, since many operations in LLD have very
>>>>>>>> high pressure on the virtual memory system.
>>>>>>>>
>>>>>>>> -- Sean Silva
>>>>>>>>
>>>>>>>>
>>>>>>>>>
>>>>>>>>> On Thu, Aug 13, 2015 at 2:44 PM, Sean Silva <chisophugis at gmail.com
>>>>>>>>> > wrote:
>>>>>>>>>
>>>>>>>>>>
>>>>>>>>>>
>>>>>>>>>> On Wed, Aug 12, 2015 at 7:17 PM, Rui Ueyama <ruiu at google.com>
>>>>>>>>>> wrote:
>>>>>>>>>>
>>>>>>>>>>> I didn't test to see if this change ever has a negative impact
>>>>>>>>>>> on memory usage, but my guess is that's very unlikely because this layout
>>>>>>>>>>> is the same as what MSVC linker creates. If this is inefficient, virtually
>>>>>>>>>>> all Windows executables are being suffered by that, which is unlikely. My
>>>>>>>>>>> understanding is that the kernel maps each section separately to a memory
>>>>>>>>>>> address, so file offset of each section can be given independently from
>>>>>>>>>>> other sections.
>>>>>>>>>>>
>>>>>>>>>>
>>>>>>>>>> The mapping is done at the granularity of aligned 4K pages
>>>>>>>>>> minimum (this is just how the x86 hardware page table mechanism works). A
>>>>>>>>>> piece of the file cannot be moved by an amount that is not a multiple of 4K
>>>>>>>>>> without a full copy.
>>>>>>>>>>
>>>>>>>>>> The only way this could (in the usual case) not have a large
>>>>>>>>>> overhead is for the kernel to do a crazy hack like have special paging
>>>>>>>>>> semantics for files that are executables. This means that when LLD finishes
>>>>>>>>>> working on a memory mapped file, if a section is not 4K aligned at least,
>>>>>>>>>> then the kernel has to then do a copy to make the file conform the the
>>>>>>>>>> actual memory layout it needs to have in the paging subsystem.
>>>>>>>>>>
>>>>>>>>>> Or does windows make full copies of sections always? In other
>>>>>>>>>> words processes don't share e.g. readonly text?
>>>>>>>>>>
>>>>>>>>>> In ELF, the offset in the file and the offset in memory are
>>>>>>>>>> required to be congruent modulo the alignment (see the documentation of
>>>>>>>>>> p_align in
>>>>>>>>>> http://www.sco.com/developers/gabi/latest/ch5.pheader.html),
>>>>>>>>>> precisely to avoid the need to do crazy hacks like this when loading the
>>>>>>>>>> program.
>>>>>>>>>>
>>>>>>>>>> You can see that Linux will reject the binary:
>>>>>>>>>> http://lxr.free-electrons.com/source/fs/binfmt_elf.c#L664
>>>>>>>>>> (load_elf_binary)
>>>>>>>>>> -> http://lxr.free-electrons.com/source/fs/binfmt_elf.c#L336
>>>>>>>>>> (elf_map)
>>>>>>>>>> -> http://lxr.free-electrons.com/source/mm/util.c#L306 (vm_mmap)
>>>>>>>>>> Notice:
>>>>>>>>>> 312 if (unlikely(offset & ~PAGE_MASK))
>>>>>>>>>> 313 return -EINVAL;
>>>>>>>>>>
>>>>>>>>>> FreeBSD is more lenient, but you can see that the kernel does not
>>>>>>>>>> like the situation when this is violated:
>>>>>>>>>>
>>>>>>>>>> http://src.illumos.org/source/xref/freebsd-head/sys/kern/imgact_elf.c#593
>>>>>>>>>> (__elfN(load_file))
>>>>>>>>>> -->
>>>>>>>>>> http://src.illumos.org/source/xref/freebsd-head/sys/kern/imgact_elf.c#467
>>>>>>>>>> (__elfN(load_section))
>>>>>>>>>> -->
>>>>>>>>>> http://src.illumos.org/source/xref/freebsd-head/sys/kern/imgact_elf.c#398
>>>>>>>>>> (__elfN(map_insert))
>>>>>>>>>> 423 /*
>>>>>>>>>> 424 * The mapping is not page aligned. This means we have
>>>>>>>>>> 425 * to copy the data. Sigh.
>>>>>>>>>> 426 */
>>>>>>>>>>
>>>>>>>>>> -- Sean Silva
>>>>>>>>>>
>>>>>>>>>>
>>>>>>>>>>>
>>>>>>>>>>> On Wed, Aug 12, 2015 at 5:31 PM, Sean Silva <
>>>>>>>>>>> chisophugis at gmail.com> wrote:
>>>>>>>>>>>
>>>>>>>>>>>>
>>>>>>>>>>>>
>>>>>>>>>>>> On Tue, Aug 11, 2015 at 4:09 PM, Rui Ueyama via llvm-commits <
>>>>>>>>>>>> llvm-commits at lists.llvm.org> wrote:
>>>>>>>>>>>>
>>>>>>>>>>>>> Author: ruiu
>>>>>>>>>>>>> Date: Tue Aug 11 18:09:00 2015
>>>>>>>>>>>>> New Revision: 244691
>>>>>>>>>>>>>
>>>>>>>>>>>>> URL: http://llvm.org/viewvc/llvm-project?rev=244691&view=rev
>>>>>>>>>>>>> Log:
>>>>>>>>>>>>> COFF: Align sections to 512-byte boundaries on disk.
>>>>>>>>>>>>>
>>>>>>>>>>>>> Sections must start at page boundaries in memory, but they
>>>>>>>>>>>>> can be aligned to sector boundaries (512-bytes) on disk.
>>>>>>>>>>>>> We aligned them to 4096-byte boundaries even on disk, so we
>>>>>>>>>>>>> wasted disk space a bit.
>>>>>>>>>>>>>
>>>>>>>>>>>>
>>>>>>>>>>>> This will likely force the kernel to copy or otherwise do
>>>>>>>>>>>> unnecessary work when loading. Are you sure that isn't happening? The
>>>>>>>>>>>> kernel ideally wants to just create a couple page table entries. But if it
>>>>>>>>>>>> needs to move things around at <4K granularity to make them properly
>>>>>>>>>>>> aligned to their load address when loading (like this patch I think causes)
>>>>>>>>>>>> then it will need to do copies.
>>>>>>>>>>>>
>>>>>>>>>>>> This can likely be checked by looking for an increase in real
>>>>>>>>>>>> memory usage for the system when the new binaries are loaded (vs. the old
>>>>>>>>>>>> page-aligned ones), since the kernel will have a copy sitting in page cache
>>>>>>>>>>>> and a copy for alignment mapped into the process address space;
>>>>>>>>>>>> alternatively, you can check for the slowdown from the kernel copies when
>>>>>>>>>>>> faulting the memory into the process's address space (or (less likely) it
>>>>>>>>>>>> may do the copies eagerly which should be easy to measure too).
>>>>>>>>>>>>
>>>>>>>>>>>> -- Sean Silva
>>>>>>>>>>>>
>>>>>>>>>>>>
>>>>>>>>>>>>>
>>>>>>>>>>>>> Modified:
>>>>>>>>>>>>> lld/trunk/COFF/Writer.cpp
>>>>>>>>>>>>> lld/trunk/test/COFF/baserel.test
>>>>>>>>>>>>> lld/trunk/test/COFF/hello32.test
>>>>>>>>>>>>>
>>>>>>>>>>>>> Modified: lld/trunk/COFF/Writer.cpp
>>>>>>>>>>>>> URL:
>>>>>>>>>>>>> http://llvm.org/viewvc/llvm-project/lld/trunk/COFF/Writer.cpp?rev=244691&r1=244690&r2=244691&view=diff
>>>>>>>>>>>>>
>>>>>>>>>>>>> ==============================================================================
>>>>>>>>>>>>> --- lld/trunk/COFF/Writer.cpp (original)
>>>>>>>>>>>>> +++ lld/trunk/COFF/Writer.cpp Tue Aug 11 18:09:00 2015
>>>>>>>>>>>>> @@ -37,8 +37,7 @@ using namespace lld;
>>>>>>>>>>>>> using namespace lld::coff;
>>>>>>>>>>>>>
>>>>>>>>>>>>> static const int PageSize = 4096;
>>>>>>>>>>>>> -static const int FileAlignment = 512;
>>>>>>>>>>>>> -static const int SectionAlignment = 4096;
>>>>>>>>>>>>> +static const int SectorSize = 512;
>>>>>>>>>>>>> static const int DOSStubSize = 64;
>>>>>>>>>>>>> static const int NumberfOfDataDirectory = 16;
>>>>>>>>>>>>>
>>>>>>>>>>>>> @@ -174,7 +173,7 @@ void OutputSection::addChunk(Chunk *C) {
>>>>>>>>>>>>> Off += C->getSize();
>>>>>>>>>>>>> Header.VirtualSize = Off;
>>>>>>>>>>>>> if (C->hasData())
>>>>>>>>>>>>> - Header.SizeOfRawData = RoundUpToAlignment(Off,
>>>>>>>>>>>>> FileAlignment);
>>>>>>>>>>>>> + Header.SizeOfRawData = RoundUpToAlignment(Off,
>>>>>>>>>>>>> SectorSize);
>>>>>>>>>>>>> }
>>>>>>>>>>>>>
>>>>>>>>>>>>> void OutputSection::addPermissions(uint32_t C) {
>>>>>>>>>>>>> @@ -507,15 +506,14 @@ void Writer::createSymbolAndStringTable(
>>>>>>>>>>>>> // We position the symbol table to be adjacent to the end
>>>>>>>>>>>>> of the last section.
>>>>>>>>>>>>> uint64_t FileOff =
>>>>>>>>>>>>> LastSection->getFileOff() +
>>>>>>>>>>>>> - RoundUpToAlignment(LastSection->getRawSize(),
>>>>>>>>>>>>> FileAlignment);
>>>>>>>>>>>>> + RoundUpToAlignment(LastSection->getRawSize(),
>>>>>>>>>>>>> SectorSize);
>>>>>>>>>>>>> if (!OutputSymtab.empty()) {
>>>>>>>>>>>>> PointerToSymbolTable = FileOff;
>>>>>>>>>>>>> FileOff += OutputSymtab.size() * sizeof(coff_symbol16);
>>>>>>>>>>>>> }
>>>>>>>>>>>>> if (!Strtab.empty())
>>>>>>>>>>>>> FileOff += Strtab.size() + 4;
>>>>>>>>>>>>> - FileSize = SizeOfHeaders +
>>>>>>>>>>>>> - RoundUpToAlignment(FileOff - SizeOfHeaders,
>>>>>>>>>>>>> FileAlignment);
>>>>>>>>>>>>> + FileSize = RoundUpToAlignment(FileOff, SectorSize);
>>>>>>>>>>>>> }
>>>>>>>>>>>>>
>>>>>>>>>>>>> // Visits all sections to assign incremental, non-overlapping
>>>>>>>>>>>>> RVAs and
>>>>>>>>>>>>> @@ -526,9 +524,9 @@ void Writer::assignAddresses() {
>>>>>>>>>>>>> sizeof(coff_section) *
>>>>>>>>>>>>> OutputSections.size();
>>>>>>>>>>>>> SizeOfHeaders +=
>>>>>>>>>>>>> Config->is64() ? sizeof(pe32plus_header) :
>>>>>>>>>>>>> sizeof(pe32_header);
>>>>>>>>>>>>> - SizeOfHeaders = RoundUpToAlignment(SizeOfHeaders, PageSize);
>>>>>>>>>>>>> + SizeOfHeaders = RoundUpToAlignment(SizeOfHeaders,
>>>>>>>>>>>>> SectorSize);
>>>>>>>>>>>>> uint64_t RVA = 0x1000; // The first page is kept unmapped.
>>>>>>>>>>>>> - uint64_t FileOff = SizeOfHeaders;
>>>>>>>>>>>>> + FileSize = SizeOfHeaders;
>>>>>>>>>>>>> // Move DISCARDABLE (or non-memory-mapped) sections to the
>>>>>>>>>>>>> end of file because
>>>>>>>>>>>>> // the loader cannot handle holes.
>>>>>>>>>>>>> std::stable_partition(
>>>>>>>>>>>>> @@ -539,13 +537,11 @@ void Writer::assignAddresses() {
>>>>>>>>>>>>> if (Sec->getName() == ".reloc")
>>>>>>>>>>>>> addBaserels(Sec);
>>>>>>>>>>>>> Sec->setRVA(RVA);
>>>>>>>>>>>>> - Sec->setFileOffset(FileOff);
>>>>>>>>>>>>> + Sec->setFileOffset(FileSize);
>>>>>>>>>>>>> RVA += RoundUpToAlignment(Sec->getVirtualSize(),
>>>>>>>>>>>>> PageSize);
>>>>>>>>>>>>> - FileOff += RoundUpToAlignment(Sec->getRawSize(),
>>>>>>>>>>>>> FileAlignment);
>>>>>>>>>>>>> + FileSize += RoundUpToAlignment(Sec->getRawSize(),
>>>>>>>>>>>>> SectorSize);
>>>>>>>>>>>>> }
>>>>>>>>>>>>> SizeOfImage = SizeOfHeaders + RoundUpToAlignment(RVA -
>>>>>>>>>>>>> 0x1000, PageSize);
>>>>>>>>>>>>> - FileSize = SizeOfHeaders +
>>>>>>>>>>>>> - RoundUpToAlignment(FileOff - SizeOfHeaders,
>>>>>>>>>>>>> FileAlignment);
>>>>>>>>>>>>> }
>>>>>>>>>>>>>
>>>>>>>>>>>>> template <typename PEHeaderTy> void Writer::writeHeader() {
>>>>>>>>>>>>> @@ -584,8 +580,8 @@ template <typename PEHeaderTy> void Writ
>>>>>>>>>>>>> Buf += sizeof(*PE);
>>>>>>>>>>>>> PE->Magic = Config->is64() ? PE32Header::PE32_PLUS :
>>>>>>>>>>>>> PE32Header::PE32;
>>>>>>>>>>>>> PE->ImageBase = Config->ImageBase;
>>>>>>>>>>>>> - PE->SectionAlignment = SectionAlignment;
>>>>>>>>>>>>> - PE->FileAlignment = FileAlignment;
>>>>>>>>>>>>> + PE->SectionAlignment = PageSize;
>>>>>>>>>>>>> + PE->FileAlignment = SectorSize;
>>>>>>>>>>>>> PE->MajorImageVersion = Config->MajorImageVersion;
>>>>>>>>>>>>> PE->MinorImageVersion = Config->MinorImageVersion;
>>>>>>>>>>>>> PE->MajorOperatingSystemVersion = Config->MajorOSVersion;
>>>>>>>>>>>>>
>>>>>>>>>>>>> Modified: lld/trunk/test/COFF/baserel.test
>>>>>>>>>>>>> URL:
>>>>>>>>>>>>> http://llvm.org/viewvc/llvm-project/lld/trunk/test/COFF/baserel.test?rev=244691&r1=244690&r2=244691&view=diff
>>>>>>>>>>>>>
>>>>>>>>>>>>> ==============================================================================
>>>>>>>>>>>>> --- lld/trunk/test/COFF/baserel.test (original)
>>>>>>>>>>>>> +++ lld/trunk/test/COFF/baserel.test Tue Aug 11 18:09:00 2015
>>>>>>>>>>>>> @@ -61,7 +61,7 @@
>>>>>>>>>>>>> # BASEREL-HEADER-NEXT: VirtualSize: 0x20
>>>>>>>>>>>>> # BASEREL-HEADER-NEXT: VirtualAddress: 0x5000
>>>>>>>>>>>>> # BASEREL-HEADER-NEXT: RawDataSize: 512
>>>>>>>>>>>>> -# BASEREL-HEADER-NEXT: PointerToRawData: 0x1800
>>>>>>>>>>>>> +# BASEREL-HEADER-NEXT: PointerToRawData: 0xC00
>>>>>>>>>>>>> # BASEREL-HEADER-NEXT: PointerToRelocations: 0x0
>>>>>>>>>>>>> # BASEREL-HEADER-NEXT: PointerToLineNumbers: 0x0
>>>>>>>>>>>>> # BASEREL-HEADER-NEXT: RelocationCount: 0
>>>>>>>>>>>>>
>>>>>>>>>>>>> Modified: lld/trunk/test/COFF/hello32.test
>>>>>>>>>>>>> URL:
>>>>>>>>>>>>> http://llvm.org/viewvc/llvm-project/lld/trunk/test/COFF/hello32.test?rev=244691&r1=244690&r2=244691&view=diff
>>>>>>>>>>>>>
>>>>>>>>>>>>> ==============================================================================
>>>>>>>>>>>>> --- lld/trunk/test/COFF/hello32.test (original)
>>>>>>>>>>>>> +++ lld/trunk/test/COFF/hello32.test Tue Aug 11 18:09:00 2015
>>>>>>>>>>>>> @@ -38,8 +38,8 @@ HEADER-NEXT: MajorImageVersion: 0
>>>>>>>>>>>>> HEADER-NEXT: MinorImageVersion: 0
>>>>>>>>>>>>> HEADER-NEXT: MajorSubsystemVersion: 6
>>>>>>>>>>>>> HEADER-NEXT: MinorSubsystemVersion: 0
>>>>>>>>>>>>> -HEADER-NEXT: SizeOfImage: 20480
>>>>>>>>>>>>> -HEADER-NEXT: SizeOfHeaders: 4096
>>>>>>>>>>>>> +HEADER-NEXT: SizeOfImage: 16896
>>>>>>>>>>>>> +HEADER-NEXT: SizeOfHeaders: 512
>>>>>>>>>>>>> HEADER-NEXT: Subsystem: IMAGE_SUBSYSTEM_WINDOWS_CUI (0x3)
>>>>>>>>>>>>> HEADER-NEXT: Characteristics [ (0x8140)
>>>>>>>>>>>>> HEADER-NEXT: IMAGE_DLL_CHARACTERISTICS_DYNAMIC_BASE (0x40)
>>>>>>>>>>>>>
>>>>>>>>>>>>>
>>>>>>>>>>>>> _______________________________________________
>>>>>>>>>>>>> llvm-commits mailing list
>>>>>>>>>>>>> llvm-commits at lists.llvm.org
>>>>>>>>>>>>> http://lists.llvm.org/cgi-bin/mailman/listinfo/llvm-commits
>>>>>>>>>>>>>
>>>>>>>>>>>>
>>>>>>>>>>>>
>>>>>>>>>>>
>>>>>>>>>>
>>>>>>>>>
>>>>>>>>
>>>>>>>
>>>>>>
>>>>>
>>>>
>>>
>>
>
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