Chromium Code Reviews Chromium Code Reviews
Issue 535943002:
Alter how relocation packing cuts holes from libchrome.so. (Closed)
Base URL: https://chromium.googlesource.com/chromium/src.git@master| Index: tools/relocation_packer/src/elf_file.cc |
| diff --git a/tools/relocation_packer/src/elf_file.cc b/tools/relocation_packer/src/elf_file.cc |
| index 35268c37a02dac4414ad9fbbe1e1ca7c0895cd26..941c1b1cba92c51306720fb1b9ea14ed9b53831d 100644 |
| --- a/tools/relocation_packer/src/elf_file.cc |
| +++ b/tools/relocation_packer/src/elf_file.cc |
| @@ -7,6 +7,7 @@ |
| #include <stdlib.h> |
| #include <sys/types.h> |
| #include <unistd.h> |
| +#include <algorithm> |
| #include <string> |
| #include <vector> |
| @@ -75,18 +76,20 @@ void VerboseLogProgramHeader(size_t program_header_index, |
| case PT_LOAD: type = "LOAD"; break; |
| case PT_DYNAMIC: type = "DYNAMIC"; break; |
| case PT_INTERP: type = "INTERP"; break; |
| - case PT_NOTE: type = "NOTE"; break; |
| - case PT_SHLIB: type = "SHLIB"; break; |
| case PT_PHDR: type = "PHDR"; break; |
| - case PT_TLS: type = "TLS"; break; |
| + case PT_GNU_RELRO: type = "GNU_RELRO"; break; |
| + case PT_GNU_STACK: type = "GNU_STACK"; break; |
| + case PT_ARM_EXIDX: type = "EXIDX"; break; |
| default: type = "(OTHER)"; break; |
| } |
| - VLOG(1) << "phdr " << program_header_index << " : " << type; |
| + VLOG(1) << "phdr[" << program_header_index << "] : " << type; |
| VLOG(1) << " p_offset = " << program_header->p_offset; |
| VLOG(1) << " p_vaddr = " << program_header->p_vaddr; |
| VLOG(1) << " p_paddr = " << program_header->p_paddr; |
| VLOG(1) << " p_filesz = " << program_header->p_filesz; |
| VLOG(1) << " p_memsz = " << program_header->p_memsz; |
| + VLOG(1) << " p_flags = " << program_header->p_flags; |
| + VLOG(1) << " p_align = " << program_header->p_align; |
| } |
| // Verbose ELF section header logging. |
| @@ -182,13 +185,6 @@ bool ElfFile::Load() { |
| bool has_rel_relocations = false; |
| bool has_rela_relocations = false; |
| - // Flag set if we encounter any .debug* section. We do not adjust any |
| - // offsets or addresses of any debug data, so if we find one of these then |
| - // the resulting output shared object should still run, but might not be |
| - // usable for debugging, disassembly, and so on. Provides a warning if |
| - // this occurs. |
| - bool has_debug_section = false; |
| - |
| Elf_Scn* section = NULL; |
| while ((section = elf_nextscn(elf, section)) != NULL) { |
| const ELF::Shdr* section_header = ELF::getshdr(section); |
| @@ -216,11 +212,6 @@ bool ElfFile::Load() { |
| found_dynamic_section = section; |
| } |
| - // If we find a section named .debug*, set the debug warning flag. |
| - if (std::string(name).find(".debug") == 0) { |
| - has_debug_section = true; |
| - } |
| - |
| // Ensure we preserve alignment, repeated later for the data block(s). |
| CHECK(section_header->sh_addralign <= kPreserveAlignment); |
| @@ -258,10 +249,6 @@ bool ElfFile::Load() { |
| return false; |
| } |
| - if (has_debug_section) { |
| - LOG(WARNING) << "Found .debug section(s), and ignored them"; |
| - } |
| - |
| elf_ = elf; |
| relocations_section_ = found_relocations_section; |
| dynamic_section_ = found_dynamic_section; |
| @@ -286,45 +273,6 @@ void AdjustElfHeaderForHole(ELF::Ehdr* elf_header, |
| } |
| } |
| -// Helper for ResizeSection(). Adjust all program headers for the hole. |
| -void AdjustProgramHeadersForHole(ELF::Phdr* elf_program_header, |
| - size_t program_header_count, |
| - ELF::Off hole_start, |
| - ssize_t hole_size) { |
| - for (size_t i = 0; i < program_header_count; ++i) { |
| - ELF::Phdr* program_header = &elf_program_header[i]; |
| - |
| - if (program_header->p_offset > hole_start) { |
| - // The hole start is past this segment, so adjust offsets and addrs. |
| - program_header->p_offset += hole_size; |
| - VLOG(1) << "phdr " << i |
| - << " p_offset adjusted to "<< program_header->p_offset; |
| - |
| - // Only adjust vaddr and paddr if this program header has them. |
| - if (program_header->p_vaddr != 0) { |
| - program_header->p_vaddr += hole_size; |
| - VLOG(1) << "phdr " << i |
| - << " p_vaddr adjusted to " << program_header->p_vaddr; |
| - } |
| - if (program_header->p_paddr != 0) { |
| - program_header->p_paddr += hole_size; |
| - VLOG(1) << "phdr " << i |
| - << " p_paddr adjusted to " << program_header->p_paddr; |
| - } |
| - } else if (program_header->p_offset + |
| - program_header->p_filesz > hole_start) { |
| - // The hole start is within this segment, so adjust file and in-memory |
| - // sizes, but leave offsets and addrs unchanged. |
| - program_header->p_filesz += hole_size; |
| - VLOG(1) << "phdr " << i |
| - << " p_filesz adjusted to " << program_header->p_filesz; |
| - program_header->p_memsz += hole_size; |
| - VLOG(1) << "phdr " << i |
| - << " p_memsz adjusted to " << program_header->p_memsz; |
| - } |
| - } |
| -} |
| - |
| // Helper for ResizeSection(). Adjust all section headers for the hole. |
| void AdjustSectionHeadersForHole(Elf* elf, |
| ELF::Off hole_start, |
| @@ -341,20 +289,433 @@ void AdjustSectionHeadersForHole(Elf* elf, |
| section_header->sh_offset += hole_size; |
| VLOG(1) << "section " << name |
| << " sh_offset adjusted to " << section_header->sh_offset; |
| - // Only adjust section addr if this section has one. |
| - if (section_header->sh_addr != 0) { |
| - section_header->sh_addr += hole_size; |
| - VLOG(1) << "section " << name |
| - << " sh_addr adjusted to " << section_header->sh_addr; |
| + } |
| + } |
| +} |
| + |
| +// Helper for ResizeSection(). Adjust the offsets of any program headers |
| +// that have offsets currently beyond the hole start. |
| +void AdjustProgramHeaderOffsets(ELF::Phdr* program_headers, |
| + size_t count, |
| + ELF::Phdr* ignored_1, |
| + ELF::Phdr* ignored_2, |
| + ELF::Off hole_start, |
| + ssize_t hole_size) { |
| + for (size_t i = 0; i < count; ++i) { |
| + ELF::Phdr* program_header = &program_headers[i]; |
| + |
| + if (program_header == ignored_1 || program_header == ignored_2) |
| + continue; |
| + |
| + if (program_header->p_offset > hole_start) { |
| + // The hole start is past this segment, so adjust offset. |
| + program_header->p_offset += hole_size; |
| + VLOG(1) << "phdr[" << i |
| + << "] p_offset adjusted to "<< program_header->p_offset; |
| + } |
| + } |
| +} |
| + |
| +// Helper for ResizeSection(). Find the first loadable segment in the |
| +// file. We expect it to map from file offset zero. |
| +ELF::Phdr* FindFirstLoadSegment(ELF::Phdr* program_headers, |
| + size_t count) { |
| + ELF::Phdr* first_loadable_segment = NULL; |
| + |
| + for (size_t i = 0; i < count; ++i) { |
| + ELF::Phdr* program_header = &program_headers[i]; |
| + |
| + if (program_header->p_type == PT_LOAD && |
| + program_header->p_offset == 0 && |
| + program_header->p_vaddr == 0 && |
| + program_header->p_paddr == 0) { |
| + first_loadable_segment = program_header; |
| + } |
| + } |
| + CHECK(first_loadable_segment); |
|
Anton
2014/09/03 16:57:20
Here and below I want a bit more text to come out
simonb (inactive)
2014/09/03 17:52:22
Done.
|
| + |
| + return first_loadable_segment; |
| +} |
| + |
| +// Helper for ResizeSection(). Find the PT_GNU_STACK segment, and check |
| +// that it contains what we expect so we can restore it on unpack if needed. |
| +ELF::Phdr* FindUnusedGnuStackSegment(ELF::Phdr* program_headers, |
| + size_t count) { |
| + ELF::Phdr* unused_segment = NULL; |
| + |
| + for (size_t i = 0; i < count; ++i) { |
| + ELF::Phdr* program_header = &program_headers[i]; |
| + |
| + if (program_header->p_type == PT_GNU_STACK && |
| + program_header->p_offset == 0 && |
| + program_header->p_vaddr == 0 && |
| + program_header->p_paddr == 0 && |
| + program_header->p_filesz == 0 && |
| + program_header->p_memsz == 0 && |
| + program_header->p_flags == (PF_R | PF_W) && |
| + program_header->p_align == ELF::kGnuStackSegmentAlignment) { |
| + unused_segment = program_header; |
| + } |
| + } |
| + CHECK(unused_segment); |
| + |
| + return unused_segment; |
| +} |
| + |
| +// Helper for ResizeSection(). Find the segment that was the first loadable |
| +// one before we split it into two. This is the one into which we coalesce |
| +// the split segments on unpacking. |
| +ELF::Phdr* FindOriginalFirstLoadSegment(ELF::Phdr* program_headers, |
| + size_t count) { |
| + const ELF::Phdr* first_loadable_segment = |
| + FindFirstLoadSegment(program_headers, count); |
| + |
| + ELF::Phdr* original_first_loadable_segment = NULL; |
| + |
| + for (size_t i = 0; i < count; ++i) { |
| + ELF::Phdr* program_header = &program_headers[i]; |
| + |
| + // The original first loadable segment is the one that follows on from |
| + // the one we wrote on split to be the current first loadable segment. |
| + if (program_header->p_type == PT_LOAD && |
| + program_header->p_offset == first_loadable_segment->p_filesz) { |
| + original_first_loadable_segment = program_header; |
| + } |
| + } |
| + CHECK(original_first_loadable_segment); |
| + |
| + return original_first_loadable_segment; |
| +} |
| + |
| +// Helper for ResizeSection(). Find the segment that contains the hole. |
| +Elf_Scn* FindSectionContainingHole(Elf* elf, |
| + ELF::Off hole_start, |
| + ssize_t hole_size) { |
| + Elf_Scn* section = NULL; |
| + Elf_Scn* last_unholed_section = NULL; |
| + |
| + while ((section = elf_nextscn(elf, section)) != NULL) { |
| + const ELF::Shdr* section_header = ELF::getshdr(section); |
| + |
| + // Because we get here after section headers have been adjusted for the |
| + // hole, we need to 'undo' that adjustment to give a view of the original |
| + // sections layout. |
| + ELF::Off offset = section_header->sh_offset; |
| + if (section_header->sh_offset >= hole_start) { |
| + offset -= hole_size; |
| + } |
| + |
| + if (offset <= hole_start) { |
| + last_unholed_section = section; |
| + } |
| + } |
| + CHECK(last_unholed_section); |
| + |
| + // The section containing the hole is the one after the last one found |
| + // by the loop above. |
| + Elf_Scn* holed_section = elf_nextscn(elf, last_unholed_section); |
| + CHECK(holed_section); |
| + |
| + return holed_section; |
| +} |
| + |
| +// Helper for ResizeSection(). Find the last section contained in a segment. |
| +Elf_Scn* FindLastSectionInSegment(Elf* elf, |
| + ELF::Phdr* program_header, |
| + ELF::Off hole_start, |
| + ssize_t hole_size) { |
| + const ELF::Off segment_end = |
| + program_header->p_offset + program_header->p_filesz; |
| + |
| + Elf_Scn* section = NULL; |
| + Elf_Scn* last_section = NULL; |
| + |
| + while ((section = elf_nextscn(elf, section)) != NULL) { |
| + const ELF::Shdr* section_header = ELF::getshdr(section); |
| + |
| + // As above, 'undo' any section offset adjustment to give a view of the |
| + // original sections layout. |
| + ELF::Off offset = section_header->sh_offset; |
| + if (section_header->sh_offset >= hole_start) { |
| + offset -= hole_size; |
| + } |
| + |
| + if (offset < segment_end) { |
| + last_section = section; |
| + } |
| + } |
| + CHECK(last_section); |
| + |
| + return last_section; |
| +} |
| + |
| +// Helper for ResizeSection(). Order loadable segments by their offsets. |
| +// The crazy linker contains assumptions about loadable segment ordering, |
| +// and it is better if we do not break them. |
| +void SortOrderSensitiveProgramHeaders(ELF::Phdr* program_headers, |
| + size_t count) { |
| + std::vector<ELF::Phdr*> orderable; |
| + |
| + // Collect together orderable program headers. These are all the LOAD |
| + // segments, and any GNU_STACK that may be present (removed on packing, |
| + // but replaced on unpacking). |
| + for (size_t i = 0; i < count; ++i) { |
| + ELF::Phdr* program_header = &program_headers[i]; |
| + |
| + if (program_header->p_type == PT_LOAD || |
| + program_header->p_type == PT_GNU_STACK) { |
| + orderable.push_back(program_header); |
| + } |
| + } |
| + |
| + // Order these program headers so that any PT_GNU_STACK is last, and |
| + // the LOAD segments that precede it appear in offset order. Uses |
| + // insertion sort. |
| + for (size_t i = 1; i < orderable.size(); ++i) { |
| + for (size_t j = i; j > 0; --j) { |
| + ELF::Phdr* first = orderable[j - 1]; |
| + ELF::Phdr* second = orderable[j]; |
| + |
| + if (!(first->p_type == PT_GNU_STACK || |
| + first->p_offset > second->p_offset)) { |
| + break; |
| } |
| + std::swap(*first, *second); |
| + } |
| + } |
| +} |
| + |
| +// Helper for ResizeSection(). The GNU_STACK program header is unused in |
| +// Android, so we can repurpose it here. Before packing, the program header |
| +// table contains something like: |
| +// |
| +// Type Offset VirtAddr PhysAddr FileSiz MemSiz Flg Align |
| +// LOAD 0x000000 0x00000000 0x00000000 0x1efc818 0x1efc818 R E 0x1000 |
| +// LOAD 0x1efd008 0x01efe008 0x01efe008 0x17ec3c 0x1a0324 RW 0x1000 |
| +// DYNAMIC 0x205ec50 0x0205fc50 0x0205fc50 0x00108 0x00108 RW 0x4 |
| +// GNU_STACK 0x000000 0x00000000 0x00000000 0x00000 0x00000 RW 0 |
| +// |
| +// The hole in the file is in the first of these. In order to preserve all |
| +// load addresses, what we do is to turn the GNU_STACK into a new LOAD entry |
| +// that maps segments up to where we created the hole, adjust the first LOAD |
| +// entry so that it maps segments after that, adjust any other program |
| +// headers whose offset is after the hole start, and finally order the LOAD |
| +// segments by offset, to give: |
| +// |
| +// Type Offset VirtAddr PhysAddr FileSiz MemSiz Flg Align |
| +// LOAD 0x000000 0x00000000 0x00000000 0x14ea4 0x212ea4 R E 0x1000 |
| +// LOAD 0x014ea4 0x00212ea4 0x00212ea4 0x1cea164 0x1cea164 R E 0x1000 |
| +// DYNAMIC 0x1e60c50 0x0205fc50 0x0205fc50 0x00108 0x00108 RW 0x4 |
| +// LOAD 0x1cff008 0x01efe008 0x01efe008 0x17ec3c 0x1a0324 RW 0x1000 |
| +// |
| +// We work out the split points by finding the .rel.dyn or .rela.dyn section |
| +// that contains the hole, and by finding the last section in a given segment. |
| +// |
| +// To unpack, we reverse the above to leave the file as it was originally. |
| +void SplitProgramHeadersForHole(Elf* elf, |
| + ELF::Off hole_start, |
| + ssize_t hole_size) { |
| + CHECK(hole_size < 0); |
| + const ELF::Ehdr* elf_header = ELF::getehdr(elf); |
| + CHECK(elf_header); |
| + |
| + ELF::Phdr* elf_program_header = ELF::getphdr(elf); |
| + CHECK(elf_program_header); |
| + |
| + const size_t program_header_count = elf_header->e_phnum; |
| + |
| + // Locate the segment that we can overwrite to form the new LOAD entry, |
| + // and the segment that we are going to split into two parts. |
| + ELF::Phdr* spliced_header = |
| + FindUnusedGnuStackSegment(elf_program_header, program_header_count); |
| + ELF::Phdr* split_header = |
| + FindFirstLoadSegment(elf_program_header, program_header_count); |
| + |
| + VLOG(1) << "phdr[" << split_header - elf_program_header << "] split"; |
| + VLOG(1) << "phdr[" << spliced_header - elf_program_header << "] new LOAD"; |
| + |
| + // Find the section that contains the hole. We split on the section that |
| + // follows it. |
| + Elf_Scn* holed_section = |
| + FindSectionContainingHole(elf, hole_start, hole_size); |
| + |
| + size_t string_index; |
| + elf_getshdrstrndx(elf, &string_index); |
| + |
| + ELF::Shdr* section_header = ELF::getshdr(holed_section); |
| + std::string name = elf_strptr(elf, string_index, section_header->sh_name); |
| + VLOG(1) << "section " << name << " split after"; |
| + |
| + // Find the last section in the segment we are splitting. |
| + Elf_Scn* last_section = |
| + FindLastSectionInSegment(elf, split_header, hole_start, hole_size); |
| + |
| + section_header = ELF::getshdr(last_section); |
| + name = elf_strptr(elf, string_index, section_header->sh_name); |
| + VLOG(1) << "section " << name << " split end"; |
| + |
| + // Split on the section following the holed one, and up to (but not |
| + // including) the section following the last one in the split segment. |
| + Elf_Scn* split_section = elf_nextscn(elf, holed_section); |
| + CHECK(split_section); |
| + Elf_Scn* end_section = elf_nextscn(elf, last_section); |
| + CHECK(end_section); |
| + |
| + // Split the first portion of split_header into spliced_header. Done |
| + // by copying the entire split_header into spliced_header, then changing |
| + // only the fields that set the segment sizes. |
| + *spliced_header = *split_header; |
| + const ELF::Shdr* split_section_header = ELF::getshdr(split_section); |
| + spliced_header->p_filesz = split_section_header->sh_offset; |
| + spliced_header->p_memsz = split_section_header->sh_addr; |
| + |
| + // Now rewrite split_header to remove the part we spliced from it. |
| + const ELF::Shdr* end_section_header = ELF::getshdr(end_section); |
| + split_header->p_offset = spliced_header->p_filesz; |
| + |
| + CHECK(split_header->p_vaddr == split_header->p_paddr); |
| + split_header->p_vaddr = spliced_header->p_memsz; |
| + split_header->p_paddr = split_header->p_vaddr; |
| + |
| + CHECK(split_header->p_filesz == split_header->p_memsz); |
| + split_header->p_filesz = |
| + end_section_header->sh_offset - spliced_header->p_filesz; |
| + split_header->p_memsz = split_header->p_filesz; |
| + |
| + // Adjust the offsets of all program headers that are not one of the pair |
| + // we just created by splitting. |
| + AdjustProgramHeaderOffsets(elf_program_header, |
| + program_header_count, |
| + spliced_header, |
| + split_header, |
| + hole_start, |
| + hole_size); |
| + |
| + // Finally, order loadable segments by offset/address. The crazy linker |
| + // contains assumptions about loadable segment ordering. |
| + SortOrderSensitiveProgramHeaders(elf_program_header, |
| + program_header_count); |
| +} |
| + |
| +// Helper for ResizeSection(). Undo the work of SplitProgramHeadersForHole(). |
| +void CoalesceProgramHeadersForHole(Elf* elf, |
| + ELF::Off hole_start, |
| + ssize_t hole_size) { |
| + CHECK(hole_size > 0); |
| + const ELF::Ehdr* elf_header = ELF::getehdr(elf); |
| + CHECK(elf_header); |
| + |
| + ELF::Phdr* elf_program_header = ELF::getphdr(elf); |
| + CHECK(elf_program_header); |
| + |
| + const size_t program_header_count = elf_header->e_phnum; |
| + |
| + // Locate the segment that we overwrote to form the new LOAD entry, and |
| + // the segment that we split into two parts on packing. |
| + ELF::Phdr* spliced_header = |
| + FindFirstLoadSegment(elf_program_header, program_header_count); |
| + ELF::Phdr* split_header = |
| + FindOriginalFirstLoadSegment(elf_program_header, program_header_count); |
| + |
| + VLOG(1) << "phdr[" << spliced_header - elf_program_header << "] stack"; |
| + VLOG(1) << "phdr[" << split_header - elf_program_header << "] coalesce"; |
| + |
| + // Find the last section in the second segment we are coalescing. |
| + Elf_Scn* last_section = |
| + FindLastSectionInSegment(elf, split_header, hole_start, hole_size); |
| + |
| + size_t string_index; |
| + elf_getshdrstrndx(elf, &string_index); |
| + |
| + const ELF::Shdr* section_header = ELF::getshdr(last_section); |
| + std::string name = elf_strptr(elf, string_index, section_header->sh_name); |
| + VLOG(1) << "section " << name << " coalesced"; |
| + |
| + // Rewrite the coalesced segment into split_header. |
| + const ELF::Shdr* last_section_header = ELF::getshdr(last_section); |
| + split_header->p_offset = spliced_header->p_offset; |
| + split_header->p_vaddr = spliced_header->p_vaddr; |
| + split_header->p_paddr = split_header->p_vaddr; |
| + split_header->p_filesz = |
| + last_section_header->sh_offset + last_section_header->sh_size; |
| + split_header->p_memsz = split_header->p_filesz; |
| + |
| + // Reconstruct the original GNU_STACK segment into spliced_header. |
| + spliced_header->p_type = PT_GNU_STACK; |
| + spliced_header->p_offset = 0; |
| + spliced_header->p_vaddr = 0; |
| + spliced_header->p_paddr = 0; |
| + spliced_header->p_filesz = 0; |
| + spliced_header->p_memsz = 0; |
| + spliced_header->p_flags = PF_R | PF_W; |
| + spliced_header->p_align = ELF::kGnuStackSegmentAlignment; |
| + |
| + // Adjust the offsets of all program headers that are not one of the pair |
| + // we just coalesced. |
| + AdjustProgramHeaderOffsets(elf_program_header, |
| + program_header_count, |
| + spliced_header, |
| + split_header, |
| + hole_start, |
| + hole_size); |
| + |
| + // Finally, order loadable segments by offset/address. The crazy linker |
| + // contains assumptions about loadable segment ordering. |
| + SortOrderSensitiveProgramHeaders(elf_program_header, |
| + program_header_count); |
| +} |
| + |
| +// Helper for ResizeSection(). Rewrite program headers. |
| +void RewriteProgramHeadersForHole(Elf* elf, |
| + ELF::Off hole_start, |
| + ssize_t hole_size) { |
| + // If hole_size is negative then we are removing a piece of the file, and |
| + // we want to split program headers so that we keep the same addresses |
| + // for text and data. If positive, then we are putting that piece of the |
| + // file back in, so we coalesce the previously split program headers. |
| + if (hole_size < 0) |
| + SplitProgramHeadersForHole(elf, hole_start, hole_size); |
| + else if (hole_size > 0) |
| + CoalesceProgramHeadersForHole(elf, hole_start, hole_size); |
| +} |
| + |
| +// Helper for ResizeSection(). Locate and return the dynamic section. |
| +Elf_Scn* GetDynamicSection(Elf* elf) { |
| + const ELF::Ehdr* elf_header = ELF::getehdr(elf); |
| + CHECK(elf_header); |
| + |
| + const ELF::Phdr* elf_program_header = ELF::getphdr(elf); |
| + CHECK(elf_program_header); |
| + |
| + // Find the program header that describes the dynamic section. |
| + const ELF::Phdr* dynamic_program_header = NULL; |
| + for (size_t i = 0; i < elf_header->e_phnum; ++i) { |
| + const ELF::Phdr* program_header = &elf_program_header[i]; |
| + |
| + if (program_header->p_type == PT_DYNAMIC) { |
| + dynamic_program_header = program_header; |
| + } |
| + } |
| + CHECK(dynamic_program_header); |
| + |
| + // Now find the section with the same offset as this program header. |
| + Elf_Scn* dynamic_section = NULL; |
| + Elf_Scn* section = NULL; |
| + while ((section = elf_nextscn(elf, section)) != NULL) { |
| + ELF::Shdr* section_header = ELF::getshdr(section); |
| + |
| + if (section_header->sh_offset == dynamic_program_header->p_offset) { |
| + dynamic_section = section; |
| } |
| } |
| + CHECK(dynamic_section != NULL); |
| + |
| + return dynamic_section; |
| } |
| // Helper for ResizeSection(). Adjust the .dynamic section for the hole. |
| template <typename Rel> |
| void AdjustDynamicSectionForHole(Elf_Scn* dynamic_section, |
| - bool is_relocations_resize, |
| ELF::Off hole_start, |
| ssize_t hole_size) { |
| Elf_Data* data = GetSectionData(dynamic_section); |
| @@ -367,30 +728,6 @@ void AdjustDynamicSectionForHole(Elf_Scn* dynamic_section, |
| for (size_t i = 0; i < dynamics.size(); ++i) { |
| ELF::Dyn* dynamic = &dynamics[i]; |
| const ELF::Sword tag = dynamic->d_tag; |
| - // Any tags that hold offsets are adjustment candidates. |
| - const bool is_adjustable = (tag == DT_PLTGOT || |
| - tag == DT_HASH || |
| - tag == DT_STRTAB || |
| - tag == DT_SYMTAB || |
| - tag == DT_RELA || |
| - tag == DT_INIT || |
| - tag == DT_FINI || |
| - tag == DT_REL || |
| - tag == DT_JMPREL || |
| - tag == DT_INIT_ARRAY || |
| - tag == DT_FINI_ARRAY || |
| - tag == DT_ANDROID_REL_OFFSET); |
| - if (is_adjustable && dynamic->d_un.d_ptr > hole_start) { |
| - dynamic->d_un.d_ptr += hole_size; |
| - VLOG(1) << "dynamic[" << i << "] " << dynamic->d_tag |
| - << " d_ptr adjusted to " << dynamic->d_un.d_ptr; |
| - } |
| - |
| - // If we are specifically resizing dynamic relocations, we need to make |
| - // some added adjustments to tags that indicate the counts of relative |
| - // relocations in the shared object. |
| - if (!is_relocations_resize) |
| - continue; |
| // DT_RELSZ or DT_RELASZ indicate the overall size of relocations. |
| // Only one will be present. Adjust by hole size. |
| @@ -413,7 +750,7 @@ void AdjustDynamicSectionForHole(Elf_Scn* dynamic_section, |
| << " d_val adjusted to " << dynamic->d_un.d_val; |
| } |
| - // DT_RELENT and DT_RELAENT don't change, but make sure they are what |
| + // DT_RELENT and DT_RELAENT do not change, but make sure they are what |
| // we expect. Only one will be present. |
| if (tag == DT_RELENT || tag == DT_RELAENT) { |
| CHECK(dynamic->d_un.d_val == sizeof(Rel)); |
| @@ -425,93 +762,6 @@ void AdjustDynamicSectionForHole(Elf_Scn* dynamic_section, |
| RewriteSectionData(data, section_data, bytes); |
| } |
| -// Helper for ResizeSection(). Adjust the .dynsym section for the hole. |
| -// We need to adjust the values for the symbols represented in it. |
| -void AdjustDynSymSectionForHole(Elf_Scn* dynsym_section, |
| - ELF::Off hole_start, |
| - ssize_t hole_size) { |
| - Elf_Data* data = GetSectionData(dynsym_section); |
| - |
| - const ELF::Sym* dynsym_base = reinterpret_cast<ELF::Sym*>(data->d_buf); |
| - std::vector<ELF::Sym> dynsyms |
| - (dynsym_base, |
| - dynsym_base + data->d_size / sizeof(dynsyms[0])); |
| - |
| - for (size_t i = 0; i < dynsyms.size(); ++i) { |
| - ELF::Sym* dynsym = &dynsyms[i]; |
| - const int type = static_cast<int>(ELF_ST_TYPE(dynsym->st_info)); |
| - const bool is_adjustable = (type == STT_OBJECT || |
| - type == STT_FUNC || |
| - type == STT_SECTION || |
| - type == STT_FILE || |
| - type == STT_COMMON || |
| - type == STT_TLS); |
| - if (is_adjustable && dynsym->st_value > hole_start) { |
| - dynsym->st_value += hole_size; |
| - VLOG(1) << "dynsym[" << i << "] type=" << type |
| - << " st_value adjusted to " << dynsym->st_value; |
| - } |
| - } |
| - |
| - void* section_data = &dynsyms[0]; |
| - size_t bytes = dynsyms.size() * sizeof(dynsyms[0]); |
| - RewriteSectionData(data, section_data, bytes); |
| -} |
| - |
| -// Helper for ResizeSection(). Adjust the plt relocations section for the |
| -// hole. We need to adjust the offset of every relocation inside it that |
| -// falls beyond the hole start. |
| -template <typename Rel> |
| -void AdjustRelPltSectionForHole(Elf_Scn* relplt_section, |
| - ELF::Off hole_start, |
| - ssize_t hole_size) { |
| - Elf_Data* data = GetSectionData(relplt_section); |
| - |
| - const Rel* relplt_base = reinterpret_cast<Rel*>(data->d_buf); |
| - std::vector<Rel> relplts( |
| - relplt_base, |
| - relplt_base + data->d_size / sizeof(relplts[0])); |
| - |
| - for (size_t i = 0; i < relplts.size(); ++i) { |
| - Rel* relplt = &relplts[i]; |
| - if (relplt->r_offset > hole_start) { |
| - relplt->r_offset += hole_size; |
| - VLOG(1) << "relplt[" << i |
| - << "] r_offset adjusted to " << relplt->r_offset; |
| - } |
| - } |
| - |
| - void* section_data = &relplts[0]; |
| - size_t bytes = relplts.size() * sizeof(relplts[0]); |
| - RewriteSectionData(data, section_data, bytes); |
| -} |
| - |
| -// Helper for ResizeSection(). Adjust the .symtab section for the hole. |
| -// We want to adjust the value of every symbol in it that falls beyond |
| -// the hole start. |
| -void AdjustSymTabSectionForHole(Elf_Scn* symtab_section, |
| - ELF::Off hole_start, |
| - ssize_t hole_size) { |
| - Elf_Data* data = GetSectionData(symtab_section); |
| - |
| - const ELF::Sym* symtab_base = reinterpret_cast<ELF::Sym*>(data->d_buf); |
| - std::vector<ELF::Sym> symtab( |
| - symtab_base, |
| - symtab_base + data->d_size / sizeof(symtab[0])); |
| - |
| - for (size_t i = 0; i < symtab.size(); ++i) { |
| - ELF::Sym* sym = &symtab[i]; |
| - if (sym->st_value > hole_start) { |
| - sym->st_value += hole_size; |
| - VLOG(1) << "symtab[" << i << "] value adjusted to " << sym->st_value; |
| - } |
| - } |
| - |
| - void* section_data = &symtab[0]; |
| - size_t bytes = symtab.size() * sizeof(symtab[0]); |
| - RewriteSectionData(data, section_data, bytes); |
| -} |
| - |
| // Resize a section. If the new size is larger than the current size, open |
| // up a hole by increasing file offsets that come after the hole. If smaller |
| // than the current size, remove the hole by decreasing those offsets. |
| @@ -521,9 +771,7 @@ void ResizeSection(Elf* elf, Elf_Scn* section, size_t new_size) { |
| if (section_header->sh_size == new_size) |
| return; |
| - // Note if we are resizing the real dyn relocations. If yes, then we have |
| - // to massage d_un.d_val in the dynamic section where d_tag is DT_RELSZ or |
| - // DT_RELASZ and DT_RELCOUNT or DT_RELACOUNT. |
| + // Note if we are resizing the real dyn relocations. |
| size_t string_index; |
| elf_getshdrstrndx(elf, &string_index); |
| const std::string section_name = |
| @@ -550,95 +798,25 @@ void ResizeSection(Elf* elf, Elf_Scn* section, size_t new_size) { |
| data->d_size += hole_size; |
| section_header->sh_size += hole_size; |
| - ELF::Ehdr* elf_header = ELF::getehdr(elf); |
| - ELF::Phdr* elf_program_header = ELF::getphdr(elf); |
| - |
| // Add the hole size to all offsets in the ELF file that are after the |
| // start of the hole. If the hole size is positive we are expanding the |
| // section to create a new hole; if negative, we are closing up a hole. |
| // Start with the main ELF header. |
| + ELF::Ehdr* elf_header = ELF::getehdr(elf); |
| AdjustElfHeaderForHole(elf_header, hole_start, hole_size); |
| - // Adjust all program headers. |
| - AdjustProgramHeadersForHole(elf_program_header, |
| - elf_header->e_phnum, |
| - hole_start, |
| - hole_size); |
| - |
| // Adjust all section headers. |
| AdjustSectionHeadersForHole(elf, hole_start, hole_size); |
| - // We use the dynamic program header entry to locate the dynamic section. |
| - const ELF::Phdr* dynamic_program_header = NULL; |
| + // If resizing the dynamic relocations, rewrite the program headers to |
| + // either split or coalesce segments, and adjust dynamic entries to match. |
| + if (is_relocations_resize) { |
| + RewriteProgramHeadersForHole(elf, hole_start, hole_size); |
| - // Find the dynamic program header entry. |
| - for (size_t i = 0; i < elf_header->e_phnum; ++i) { |
| - ELF::Phdr* program_header = &elf_program_header[i]; |
| - |
| - if (program_header->p_type == PT_DYNAMIC) { |
| - dynamic_program_header = program_header; |
| - } |
| + Elf_Scn* dynamic_section = GetDynamicSection(elf);; |
|
Anton
2014/09/03 16:57:20
two semicolons, just to be sure.
simonb (inactive)
2014/09/03 17:52:21
Done.
|
| + AdjustDynamicSectionForHole<Rel>(dynamic_section, hole_start, hole_size); |
| } |
| - CHECK(dynamic_program_header); |
| - |
| - // Sections requiring special attention, and the packed android |
| - // relocations offset. |
| - Elf_Scn* dynamic_section = NULL; |
| - Elf_Scn* dynsym_section = NULL; |
| - Elf_Scn* plt_relocations_section = NULL; |
| - Elf_Scn* symtab_section = NULL; |
| - ELF::Off android_relocations_offset = 0; |
| - |
| - // Find these sections, and the packed android relocations offset. |
| - section = NULL; |
| - while ((section = elf_nextscn(elf, section)) != NULL) { |
| - ELF::Shdr* section_header = ELF::getshdr(section); |
| - std::string name = elf_strptr(elf, string_index, section_header->sh_name); |
| - |
| - if (section_header->sh_offset == dynamic_program_header->p_offset) { |
| - dynamic_section = section; |
| - } |
| - if (name == ".dynsym") { |
| - dynsym_section = section; |
| - } |
| - if (name == ".rel.plt" || name == ".rela.plt") { |
| - plt_relocations_section = section; |
| - } |
| - if (name == ".symtab") { |
| - symtab_section = section; |
| - } |
| - |
| - // Note packed android relocations offset. |
| - if (name == ".android.rel.dyn" || name == ".android.rela.dyn") { |
| - android_relocations_offset = section_header->sh_offset; |
| - } |
| - } |
| - CHECK(dynamic_section != NULL); |
| - CHECK(dynsym_section != NULL); |
| - CHECK(plt_relocations_section != NULL); |
| - CHECK(android_relocations_offset != 0); |
| - |
| - // Adjust the .dynamic section for the hole. Because we have to edit the |
| - // current contents of .dynamic we disallow resizing it. |
| - CHECK(section != dynamic_section); |
| - AdjustDynamicSectionForHole<Rel>(dynamic_section, |
| - is_relocations_resize, |
| - hole_start, |
| - hole_size); |
| - |
| - // Adjust the .dynsym section for the hole. |
| - AdjustDynSymSectionForHole(dynsym_section, hole_start, hole_size); |
| - |
| - // Adjust the plt relocations section for the hole. |
| - AdjustRelPltSectionForHole<Rel>(plt_relocations_section, |
| - hole_start, |
| - hole_size); |
| - |
| - // If present, adjust the .symtab section for the hole. If the shared |
| - // library was stripped then .symtab will be absent. |
| - if (symtab_section) |
| - AdjustSymTabSectionForHole(symtab_section, hole_start, hole_size); |
| } |
| // Find the first slot in a dynamics array with the given tag. The array |
| @@ -691,100 +869,6 @@ void RemoveDynamicEntry(ELF::Sword tag, |
| CHECK(dynamics->at(dynamics->size() - 1).d_tag == DT_NULL); |
| } |
| -// Adjust a relocation. For a relocation without addend, we find its target |
| -// in the section and adjust that. For a relocation with addend, the target |
| -// is the relocation addend, and the section data at the target is zero. |
| -template <typename Rel> |
| -void AdjustRelocation(ssize_t index, |
| - ELF::Addr hole_start, |
| - ssize_t hole_size, |
| - Rel* relocation, |
| - ELF::Off* target); |
| - |
| -template <> |
| -void AdjustRelocation<ELF::Rel>(ssize_t index, |
| - ELF::Addr hole_start, |
| - ssize_t hole_size, |
| - ELF::Rel* relocation, |
| - ELF::Off* target) { |
| - // Adjust the target if after the hole start. |
| - if (*target > hole_start) { |
| - *target += hole_size; |
| - VLOG(1) << "relocation[" << index << "] target adjusted to " << *target; |
| - } |
| -} |
| - |
| -template <> |
| -void AdjustRelocation<ELF::Rela>(ssize_t index, |
| - ELF::Addr hole_start, |
| - ssize_t hole_size, |
| - ELF::Rela* relocation, |
| - ELF::Off* target) { |
| - // The relocation's target is the addend. Adjust if after the hole start. |
| - if (relocation->r_addend > hole_start) { |
| - relocation->r_addend += hole_size; |
| - VLOG(1) << "relocation[" |
| - << index << "] addend adjusted to " << relocation->r_addend; |
| - } |
| -} |
| - |
| -// For relative relocations without addends, adjust the file data to which |
| -// they refer. For relative relocations with addends, adjust the addends. |
| -// This translates data into the area it will occupy after the hole in |
| -// the dynamic relocations is added or removed. |
| -template <typename Rel> |
| -void AdjustRelocationTargets(Elf* elf, |
| - ELF::Off hole_start, |
| - ssize_t hole_size, |
| - std::vector<Rel>* relocations) { |
| - Elf_Scn* section = NULL; |
| - while ((section = elf_nextscn(elf, section)) != NULL) { |
| - const ELF::Shdr* section_header = ELF::getshdr(section); |
| - |
| - // Ignore sections that do not appear in a process memory image. |
| - if (section_header->sh_addr == 0) |
| - continue; |
| - |
| - Elf_Data* data = GetSectionData(section); |
| - |
| - // Ignore sections with no effective data. |
| - if (data->d_buf == NULL) |
| - continue; |
| - |
| - // Identify this section's start and end addresses. |
| - const ELF::Addr section_start = section_header->sh_addr; |
| - const ELF::Addr section_end = section_start + section_header->sh_size; |
| - |
| - // Create a copy of the section's data. |
| - uint8_t* area = new uint8_t[data->d_size]; |
| - memcpy(area, data->d_buf, data->d_size); |
| - |
| - for (size_t i = 0; i < relocations->size(); ++i) { |
| - Rel* relocation = &relocations->at(i); |
| - CHECK(ELF_R_TYPE(relocation->r_info) == ELF::kRelativeRelocationCode); |
| - |
| - // See if this relocation points into the current section. |
| - if (relocation->r_offset >= section_start && |
| - relocation->r_offset < section_end) { |
| - // The relocation's target is what it points to in area. |
| - // For relocations without addend, this is what we adjust; for |
| - // relocations with addend, we leave this (it will be zero) |
| - // and instead adjust the addend. |
| - ELF::Addr byte_offset = relocation->r_offset - section_start; |
| - ELF::Off* target = reinterpret_cast<ELF::Off*>(area + byte_offset); |
| - AdjustRelocation<Rel>(i, hole_start, hole_size, relocation, target); |
| - } |
| - } |
| - |
| - // If we altered the data for this section, write it back. |
| - if (memcmp(area, data->d_buf, data->d_size)) { |
| - RewriteSectionData(data, area, data->d_size); |
| - } |
| - delete [] area; |
| - } |
| -} |
| - |
| -// Pad relocations with a given number of null relocations. |
| template <typename Rel> |
| void PadRelocations(size_t count, std::vector<Rel>* relocations); |
| @@ -809,23 +893,6 @@ void PadRelocations<ELF::Rela>(size_t count, |
| relocations->insert(relocations->end(), padding.begin(), padding.end()); |
| } |
| -// Adjust relocations so that the offset that they indicate will be correct |
| -// after the hole in the dynamic relocations is added or removed (in effect, |
| -// relocate the relocations). |
| -template <typename Rel> |
| -void AdjustRelocations(ELF::Off hole_start, |
| - ssize_t hole_size, |
| - std::vector<Rel>* relocations) { |
| - for (size_t i = 0; i < relocations->size(); ++i) { |
| - Rel* relocation = &relocations->at(i); |
| - if (relocation->r_offset > hole_start) { |
| - relocation->r_offset += hole_size; |
| - VLOG(1) << "relocation[" << i |
| - << "] offset adjusted to " << relocation->r_offset; |
| - } |
| - } |
| -} |
| - |
| } // namespace |
| // Remove relative entries from dynamic relocations and write as packed |
| @@ -895,12 +962,11 @@ bool ElfFile::PackTypedRelocations(const std::vector<Rel>& relocations, |
| return false; |
| } |
| - // Unless padding, pre-apply relative relocations to account for the |
| - // hole, and pre-adjust all relocation offsets accordingly. |
| + // If not padding fully, apply only enough padding to preserve alignment. |
| + // Otherwise, pad so that we do not shrink the relocations section at all. |
| if (!is_padding_relocations_) { |
| - // Pre-calculate the size of the hole we will close up when we rewrite |
| - // dynamic relocations. We have to adjust relocation addresses to |
| - // account for this. |
| + // Calculate the size of the hole we will close up when we rewrite |
| + // dynamic relocations. |
| ELF::Shdr* section_header = ELF::getshdr(relocations_section_); |
| const ELF::Off hole_start = section_header->sh_offset; |
| ssize_t hole_size = |
| @@ -939,14 +1005,6 @@ bool ElfFile::PackTypedRelocations(const std::vector<Rel>& relocations, |
| // Add null relocations to other_relocations to preserve alignment. |
| PadRelocations<Rel>(padding, &other_relocations); |
| LOG(INFO) << "Alignment pad : " << padding << " relocations"; |
| - |
| - // Apply relocations to all relative data to relocate it into the |
| - // area it will occupy once the hole in the dynamic relocations is removed. |
| - AdjustRelocationTargets<Rel>( |
| - elf_, hole_start, -hole_size, &relative_relocations); |
| - // Relocate the relocations. |
| - AdjustRelocations<Rel>(hole_start, -hole_size, &relative_relocations); |
| - AdjustRelocations<Rel>(hole_start, -hole_size, &other_relocations); |
| } else { |
| // If padding, add NONE-type relocations to other_relocations to make it |
| // the same size as the the original relocations we read in. This makes |
| @@ -1009,12 +1067,18 @@ bool ElfFile::PackTypedRelocations(const std::vector<Rel>& relocations, |
| dynamic_base + data->d_size / sizeof(dynamics[0])); |
| // Use two of the spare slots to describe the packed section. |
| ELF::Shdr* section_header = ELF::getshdr(android_relocations_section_); |
| - const ELF::Dyn offset_dyn |
| - = {DT_ANDROID_REL_OFFSET, {section_header->sh_offset}}; |
| - AddDynamicEntry(offset_dyn, &dynamics); |
| - const ELF::Dyn size_dyn |
| - = {DT_ANDROID_REL_SIZE, {section_header->sh_size}}; |
| - AddDynamicEntry(size_dyn, &dynamics); |
| + { |
| + ELF::Dyn dyn; |
| + dyn.d_tag = DT_ANDROID_REL_OFFSET; |
| + dyn.d_un.d_ptr = section_header->sh_offset; |
| + AddDynamicEntry(dyn, &dynamics); |
| + } |
| + { |
| + ELF::Dyn dyn; |
| + dyn.d_tag = DT_ANDROID_REL_SIZE; |
| + dyn.d_un.d_val = section_header->sh_size; |
| + AddDynamicEntry(dyn, &dynamics); |
| + } |
| const void* dynamics_data = &dynamics[0]; |
| const size_t dynamics_bytes = dynamics.size() * sizeof(dynamics[0]); |
| RewriteSectionData(data, dynamics_data, dynamics_bytes); |
| @@ -1126,14 +1190,6 @@ bool ElfFile::UnpackTypedRelocations(const std::vector<uint8_t>& packed, |
| // Adjust the hole size for the padding added to preserve alignment. |
| hole_size -= padding * sizeof(other_relocations[0]); |
| LOG(INFO) << "Expansion : " << hole_size << " bytes"; |
| - |
| - // Apply relocations to all relative data to relocate it into the |
| - // area it will occupy once the hole in dynamic relocations is opened. |
| - AdjustRelocationTargets<Rel>( |
| - elf_, hole_start, hole_size, &relative_relocations); |
| - // Relocate the relocations. |
| - AdjustRelocations<Rel>(hole_start, hole_size, &relative_relocations); |
| - AdjustRelocations<Rel>(hole_start, hole_size, &other_relocations); |
| } |
| // Rewrite the current dynamic relocations section to be the relative |
