| /* Core dump and executable file functions below target vector, for GDB. |
| |
| Copyright (C) 1986-2024 Free Software Foundation, Inc. |
| |
| This file is part of GDB. |
| |
| This program is free software; you can redistribute it and/or modify |
| it under the terms of the GNU General Public License as published by |
| the Free Software Foundation; either version 3 of the License, or |
| (at your option) any later version. |
| |
| This program is distributed in the hope that it will be useful, |
| but WITHOUT ANY WARRANTY; without even the implied warranty of |
| MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the |
| GNU General Public License for more details. |
| |
| You should have received a copy of the GNU General Public License |
| along with this program. If not, see <http://www.gnu.org/licenses/>. */ |
| |
| #include "arch-utils.h" |
| #include <signal.h> |
| #include <fcntl.h> |
| #include "exceptions.h" |
| #include "frame.h" |
| #include "inferior.h" |
| #include "infrun.h" |
| #include "symtab.h" |
| #include "command.h" |
| #include "bfd.h" |
| #include "target.h" |
| #include "process-stratum-target.h" |
| #include "gdbcore.h" |
| #include "gdbthread.h" |
| #include "regcache.h" |
| #include "regset.h" |
| #include "symfile.h" |
| #include "exec.h" |
| #include "readline/tilde.h" |
| #include "solib.h" |
| #include "solist.h" |
| #include "filenames.h" |
| #include "progspace.h" |
| #include "objfiles.h" |
| #include "gdb_bfd.h" |
| #include "completer.h" |
| #include "gdbsupport/filestuff.h" |
| #include "build-id.h" |
| #include "gdbsupport/pathstuff.h" |
| #include "gdbsupport/scoped_fd.h" |
| #include "gdbsupport/x86-xstate.h" |
| #include <unordered_map> |
| #include <unordered_set> |
| #include "cli/cli-cmds.h" |
| #include "xml-tdesc.h" |
| #include "memtag.h" |
| #include "cli/cli-style.h" |
| |
| #ifndef O_LARGEFILE |
| #define O_LARGEFILE 0 |
| #endif |
| |
| /* A mem_range and the build-id associated with the file mapped into the |
| given range. */ |
| |
| struct mem_range_and_build_id |
| { |
| mem_range_and_build_id (mem_range &&r, const bfd_build_id *id) |
| : range (r), |
| build_id (id) |
| { /* Nothing. */ } |
| |
| /* A range of memory addresses. */ |
| mem_range range; |
| |
| /* The build-id of the file mapped into RANGE. */ |
| const bfd_build_id *build_id; |
| }; |
| |
| /* An instance of this class is created within the core_target and is used |
| to hold all the information that relating to mapped files, their address |
| ranges, and their corresponding build-ids. */ |
| |
| struct mapped_file_info |
| { |
| /* See comment on function definition. */ |
| |
| void add (const char *soname, const char *expected_filename, |
| const char *actual_filename, std::vector<mem_range> &&ranges, |
| const bfd_build_id *build_id); |
| |
| /* See comment on function definition. */ |
| |
| std::optional <core_target_mapped_file_info> |
| lookup (const char *filename, const std::optional<CORE_ADDR> &addr); |
| |
| private: |
| |
| /* Helper for ::lookup. BUILD_ID is a build-id that was found in |
| one of the data structures within this class. Lookup the |
| corresponding filename in m_build_id_to_filename_map and return a pair |
| containing the build-id and filename. |
| |
| If no corresponding filename is found in m_build_id_to_filename_map |
| then the returned pair contains BUILD_ID and an empty string. |
| |
| If BUILD_ID is nullptr then the returned pair contains nullptr and an |
| empty string. */ |
| |
| struct core_target_mapped_file_info |
| make_result (const bfd_build_id *build_id) |
| { |
| if (build_id != nullptr) |
| { |
| auto it = m_build_id_to_filename_map.find (build_id); |
| if (it != m_build_id_to_filename_map.end ()) |
| return { build_id, it->second }; |
| } |
| |
| return { build_id, {} }; |
| } |
| |
| /* A type that maps a string to a build-id. */ |
| using string_to_build_id_map |
| = std::unordered_map<std::string, const bfd_build_id *>; |
| |
| /* A type that maps a build-id to a string. */ |
| using build_id_to_string_map |
| = std::unordered_map<const bfd_build_id *, std::string>; |
| |
| /* When loading a core file, the build-ids are extracted based on the |
| file backed mappings. This map associates the name of a file that was |
| mapped into the core file with the corresponding build-id. The |
| build-id pointers in this map will never be nullptr as we only record |
| files if they have a build-id. */ |
| |
| string_to_build_id_map m_filename_to_build_id_map; |
| |
| /* Map a build-id pointer back to the name of the file that was mapped |
| into the inferior's address space. If we lookup a matching build-id |
| using either a soname or an address then this map allows us to also |
| provide a full path to a file with a matching build-id. */ |
| |
| build_id_to_string_map m_build_id_to_filename_map; |
| |
| /* If the file that was mapped into the core file was a shared library |
| then it might have a DT_SONAME tag in its .dynamic section, this tag |
| contains the name of a shared object. When opening a shared library, |
| if it's basename appears in this map then we can use the corresponding |
| build-id. |
| |
| In the rare case that two different files have the same DT_SONAME |
| value then the build-id pointer in this map will be nullptr, this |
| indicates that it's not possible to find a build-id based on the given |
| DT_SONAME value. */ |
| |
| string_to_build_id_map m_soname_to_build_id_map; |
| |
| /* This vector maps memory ranges onto an associated build-id. The |
| ranges are those of the files mapped into the core file. |
| |
| Entries in this vector must not overlap, and are sorted be increasing |
| memory address. Within each entry the build-id pointer will not be |
| nullptr. |
| |
| While building this vector the entries are not sorted, they are |
| sorted once after the table has finished being built. */ |
| |
| std::vector<mem_range_and_build_id> m_address_to_build_id_list; |
| |
| /* False if address_to_build_id_list is unsorted, otherwise true. */ |
| |
| bool m_address_to_build_id_list_sorted = false; |
| }; |
| |
| /* The core file target. */ |
| |
| static const target_info core_target_info = { |
| "core", |
| N_("Local core dump file"), |
| N_("Use a core file as a target.\n\ |
| Specify the filename of the core file.") |
| }; |
| |
| class core_target final : public process_stratum_target |
| { |
| public: |
| core_target (); |
| |
| const target_info &info () const override |
| { return core_target_info; } |
| |
| void close () override; |
| void detach (inferior *, int) override; |
| void fetch_registers (struct regcache *, int) override; |
| |
| enum target_xfer_status xfer_partial (enum target_object object, |
| const char *annex, |
| gdb_byte *readbuf, |
| const gdb_byte *writebuf, |
| ULONGEST offset, ULONGEST len, |
| ULONGEST *xfered_len) override; |
| void files_info () override; |
| |
| bool thread_alive (ptid_t ptid) override; |
| const struct target_desc *read_description () override; |
| |
| std::string pid_to_str (ptid_t) override; |
| |
| const char *thread_name (struct thread_info *) override; |
| |
| bool has_all_memory () override { return true; } |
| bool has_memory () override; |
| bool has_stack () override; |
| bool has_registers () override; |
| bool has_execution (inferior *inf) override { return false; } |
| |
| bool info_proc (const char *, enum info_proc_what) override; |
| |
| bool supports_memory_tagging () override; |
| |
| /* Core file implementation of fetch_memtags. Fetch the memory tags from |
| core file notes. */ |
| bool fetch_memtags (CORE_ADDR address, size_t len, |
| gdb::byte_vector &tags, int type) override; |
| |
| /* If the architecture supports it, check if ADDRESS is within a memory range |
| mapped with tags. For example, MTE tags for AArch64. */ |
| bool is_address_tagged (gdbarch *gdbarch, CORE_ADDR address) override; |
| |
| x86_xsave_layout fetch_x86_xsave_layout () override; |
| |
| /* A few helpers. */ |
| |
| /* Getter, see variable definition. */ |
| struct gdbarch *core_gdbarch () |
| { |
| return m_core_gdbarch; |
| } |
| |
| /* See definition. */ |
| void get_core_register_section (struct regcache *regcache, |
| const struct regset *regset, |
| const char *name, |
| int section_min_size, |
| const char *human_name, |
| bool required); |
| |
| /* See definition. */ |
| void info_proc_mappings (struct gdbarch *gdbarch); |
| |
| std::optional <core_target_mapped_file_info> |
| lookup_mapped_file_info (const char *filename, |
| const std::optional<CORE_ADDR> &addr) |
| { |
| return m_mapped_file_info.lookup (filename, addr); |
| } |
| |
| private: /* per-core data */ |
| |
| /* Get rid of the core inferior. */ |
| void clear_core (); |
| |
| /* The core's section table. Note that these target sections are |
| *not* mapped in the current address spaces' set of target |
| sections --- those should come only from pure executable or |
| shared library bfds. The core bfd sections are an implementation |
| detail of the core target, just like ptrace is for unix child |
| targets. */ |
| std::vector<target_section> m_core_section_table; |
| |
| /* File-backed address space mappings: some core files include |
| information about memory mapped files. */ |
| std::vector<target_section> m_core_file_mappings; |
| |
| /* Unavailable mappings. These correspond to pathnames which either |
| weren't found or could not be opened. Knowing these addresses can |
| still be useful. */ |
| std::vector<mem_range> m_core_unavailable_mappings; |
| |
| /* Data structure that holds information mapping filenames and address |
| ranges to the corresponding build-ids as well as the reverse build-id |
| to filename mapping. */ |
| mapped_file_info m_mapped_file_info; |
| |
| /* Build m_core_file_mappings and m_mapped_file_info. Called from the |
| constructor. */ |
| void build_file_mappings (); |
| |
| /* FIXME: kettenis/20031023: Eventually this field should |
| disappear. */ |
| struct gdbarch *m_core_gdbarch = NULL; |
| }; |
| |
| core_target::core_target () |
| { |
| /* Find a first arch based on the BFD. We need the initial gdbarch so |
| we can setup the hooks to find a target description. */ |
| m_core_gdbarch = gdbarch_from_bfd (current_program_space->core_bfd ()); |
| |
| /* If the arch is able to read a target description from the core, it |
| could yield a more specific gdbarch. */ |
| const struct target_desc *tdesc = read_description (); |
| |
| if (tdesc != nullptr) |
| { |
| struct gdbarch_info info; |
| info.abfd = current_program_space->core_bfd (); |
| info.target_desc = tdesc; |
| m_core_gdbarch = gdbarch_find_by_info (info); |
| } |
| |
| if (!m_core_gdbarch |
| || !gdbarch_iterate_over_regset_sections_p (m_core_gdbarch)) |
| error (_("\"%s\": Core file format not supported"), |
| bfd_get_filename (current_program_space->core_bfd ())); |
| |
| /* Find the data section */ |
| m_core_section_table = build_section_table (current_program_space->core_bfd ()); |
| |
| build_file_mappings (); |
| } |
| |
| /* Construct the table for file-backed mappings if they exist. |
| |
| For each unique path in the note, we'll open a BFD with a bfd |
| target of "binary". This is an unstructured bfd target upon which |
| we'll impose a structure from the mappings in the architecture-specific |
| mappings note. A BFD section is allocated and initialized for each |
| file-backed mapping. |
| |
| We take care to not share already open bfds with other parts of |
| GDB; in particular, we don't want to add new sections to existing |
| BFDs. We do, however, ensure that the BFDs that we allocate here |
| will go away (be deallocated) when the core target is detached. */ |
| |
| void |
| core_target::build_file_mappings () |
| { |
| /* Type holding information about a single file mapped into the inferior |
| at the point when the core file was created. Associates a build-id |
| with the list of regions the file is mapped into. */ |
| struct mapped_file |
| { |
| /* Type for a region of a file that was mapped into the inferior when |
| the core file was generated. */ |
| struct region |
| { |
| /* Constructor. See member variables for argument descriptions. */ |
| region (CORE_ADDR start_, CORE_ADDR end_, CORE_ADDR file_ofs_) |
| : start (start_), |
| end (end_), |
| file_ofs (file_ofs_) |
| { /* Nothing. */ } |
| |
| /* The inferior address for the start of the mapped region. */ |
| CORE_ADDR start; |
| |
| /* The inferior address immediately after the mapped region. */ |
| CORE_ADDR end; |
| |
| /* The offset within the mapped file for this content. */ |
| CORE_ADDR file_ofs; |
| }; |
| |
| /* If not nullptr, then this is the build-id associated with this |
| file. */ |
| const bfd_build_id *build_id = nullptr; |
| |
| /* If true then we have seen multiple different build-ids associated |
| with the same filename. The build_id field will have been set back |
| to nullptr, and we should not set build_id in future. */ |
| bool ignore_build_id_p = false; |
| |
| /* All the mapped regions of this file. */ |
| std::vector<region> regions; |
| }; |
| |
| std::unordered_map<std::string, struct bfd *> bfd_map; |
| std::unordered_set<std::string> unavailable_paths; |
| |
| /* All files mapped into the core file. The key is the filename. */ |
| std::unordered_map<std::string, mapped_file> mapped_files; |
| |
| /* See linux_read_core_file_mappings() in linux-tdep.c for an example |
| read_core_file_mappings method. */ |
| gdbarch_read_core_file_mappings (m_core_gdbarch, |
| current_program_space->core_bfd (), |
| |
| /* After determining the number of mappings, read_core_file_mappings |
| will invoke this lambda. */ |
| [&] (ULONGEST) |
| { |
| }, |
| |
| /* read_core_file_mappings will invoke this lambda for each mapping |
| that it finds. */ |
| [&] (int num, ULONGEST start, ULONGEST end, ULONGEST file_ofs, |
| const char *filename, const bfd_build_id *build_id) |
| { |
| /* Architecture-specific read_core_mapping methods are expected to |
| weed out non-file-backed mappings. */ |
| gdb_assert (filename != nullptr); |
| |
| /* Add this mapped region to the data for FILENAME. */ |
| mapped_file &file_data = mapped_files[filename]; |
| file_data.regions.emplace_back (start, end, file_ofs); |
| if (build_id != nullptr && !file_data.ignore_build_id_p) |
| { |
| if (file_data.build_id == nullptr) |
| file_data.build_id = build_id; |
| else if (!build_id_equal (build_id, file_data.build_id)) |
| { |
| warning (_("Multiple build-ids found for %ps"), |
| styled_string (file_name_style.style (), filename)); |
| file_data.build_id = nullptr; |
| file_data.ignore_build_id_p = true; |
| } |
| } |
| }); |
| |
| for (const auto &iter : mapped_files) |
| { |
| const std::string &filename = iter.first; |
| const mapped_file &file_data = iter.second; |
| |
| /* Use exec_file_find() to do sysroot expansion. It'll |
| also strip the potential sysroot "target:" prefix. If |
| there is no sysroot, an equivalent (possibly more |
| canonical) pathname will be provided. */ |
| gdb::unique_xmalloc_ptr<char> expanded_fname |
| = exec_file_find (filename.c_str (), nullptr); |
| |
| bool build_id_mismatch = false; |
| if (expanded_fname != nullptr && file_data.build_id != nullptr) |
| { |
| /* We temporarily open the bfd as a structured target, this |
| allows us to read the build-id from the bfd if there is one. |
| For this task it's OK if we reuse an already open bfd object, |
| so we make this call through GDB's bfd cache. Once we've |
| checked the build-id (if there is one) we'll drop this |
| reference and re-open the bfd using the "binary" target. */ |
| gdb_bfd_ref_ptr tmp_bfd |
| = gdb_bfd_open (expanded_fname.get (), gnutarget); |
| |
| if (tmp_bfd != nullptr |
| && bfd_check_format (tmp_bfd.get (), bfd_object) |
| && build_id_bfd_get (tmp_bfd.get ()) != nullptr) |
| { |
| /* The newly opened TMP_BFD has a build-id, and this mapped |
| file has a build-id extracted from the core-file. Check |
| the build-id's match, and if not, reject TMP_BFD. */ |
| const struct bfd_build_id *found |
| = build_id_bfd_get (tmp_bfd.get ()); |
| if (!build_id_equal (found, file_data.build_id)) |
| build_id_mismatch = true; |
| } |
| } |
| |
| gdb_bfd_ref_ptr abfd; |
| if (expanded_fname != nullptr && !build_id_mismatch) |
| { |
| struct bfd *b = bfd_openr (expanded_fname.get (), "binary"); |
| abfd = gdb_bfd_ref_ptr::new_reference (b); |
| } |
| |
| if ((expanded_fname == nullptr |
| || abfd == nullptr |
| || !bfd_check_format (abfd.get (), bfd_object)) |
| && file_data.build_id != nullptr) |
| { |
| abfd = find_objfile_by_build_id (file_data.build_id, |
| filename.c_str ()); |
| |
| if (abfd != nullptr) |
| { |
| /* The find_objfile_by_build_id will have opened ABFD using |
| the GNUTARGET global bfd type, however, we need the bfd |
| opened as the binary type (see the function's header |
| comment), so now we reopen ABFD with the desired binary |
| type. */ |
| expanded_fname |
| = make_unique_xstrdup (bfd_get_filename (abfd.get ())); |
| struct bfd *b = bfd_openr (expanded_fname.get (), "binary"); |
| gdb_assert (b != nullptr); |
| abfd = gdb_bfd_ref_ptr::new_reference (b); |
| } |
| } |
| |
| std::vector<mem_range> ranges; |
| for (const mapped_file::region ®ion : file_data.regions) |
| ranges.emplace_back (region.start, region.end - region.start); |
| |
| if (expanded_fname == nullptr |
| || abfd == nullptr |
| || !bfd_check_format (abfd.get (), bfd_object)) |
| { |
| /* If ABFD was opened, but the wrong format, close it now. */ |
| abfd = nullptr; |
| |
| /* Record all regions for this file as unavailable. */ |
| for (const mapped_file::region ®ion : file_data.regions) |
| m_core_unavailable_mappings.emplace_back (region.start, |
| region.end |
| - region.start); |
| |
| /* And give the user an appropriate warning. */ |
| if (build_id_mismatch) |
| { |
| if (expanded_fname == nullptr |
| || filename == expanded_fname.get ()) |
| warning (_("File %ps doesn't match build-id from core-file " |
| "during file-backed mapping processing"), |
| styled_string (file_name_style.style (), |
| filename.c_str ())); |
| else |
| warning (_("File %ps which was expanded to %ps, doesn't match " |
| "build-id from core-file during file-backed " |
| "mapping processing"), |
| styled_string (file_name_style.style (), |
| filename.c_str ()), |
| styled_string (file_name_style.style (), |
| expanded_fname.get ())); |
| } |
| else |
| { |
| if (expanded_fname == nullptr |
| || filename == expanded_fname.get ()) |
| warning (_("Can't open file %ps during file-backed mapping " |
| "note processing"), |
| styled_string (file_name_style.style (), |
| filename.c_str ())); |
| else |
| warning (_("Can't open file %ps which was expanded to %ps " |
| "during file-backed mapping note processing"), |
| styled_string (file_name_style.style (), |
| filename.c_str ()), |
| styled_string (file_name_style.style (), |
| expanded_fname.get ())); |
| } |
| } |
| else |
| { |
| /* Ensure that the bfd will be closed when core_bfd is closed. |
| This can be checked before/after a core file detach via "maint |
| info bfds". */ |
| gdb_bfd_record_inclusion (current_program_space->core_bfd (), |
| abfd.get ()); |
| |
| /* Create sections for each mapped region. */ |
| for (const mapped_file::region ®ion : file_data.regions) |
| { |
| /* Make new BFD section. All sections have the same name, |
| which is permitted by bfd_make_section_anyway(). */ |
| asection *sec = bfd_make_section_anyway (abfd.get (), "load"); |
| if (sec == nullptr) |
| error (_("Can't make section")); |
| sec->filepos = region.file_ofs; |
| bfd_set_section_flags (sec, SEC_READONLY | SEC_HAS_CONTENTS); |
| bfd_set_section_size (sec, region.end - region.start); |
| bfd_set_section_vma (sec, region.start); |
| bfd_set_section_lma (sec, region.start); |
| bfd_set_section_alignment (sec, 2); |
| |
| /* Set target_section fields. */ |
| m_core_file_mappings.emplace_back (region.start, region.end, sec); |
| } |
| } |
| |
| /* If this is a bfd with a build-id then record the filename, |
| optional soname (DT_SONAME .dynamic attribute), and the range of |
| addresses at which this bfd is mapped. This information can be |
| used to perform build-id checking when loading the shared |
| libraries. */ |
| if (file_data.build_id != nullptr) |
| { |
| normalize_mem_ranges (&ranges); |
| |
| const char *actual_filename = nullptr; |
| gdb::unique_xmalloc_ptr<char> soname; |
| if (abfd != nullptr) |
| { |
| actual_filename = bfd_get_filename (abfd.get ()); |
| soname = gdb_bfd_read_elf_soname (actual_filename); |
| } |
| |
| m_mapped_file_info.add (soname.get (), filename.c_str (), |
| actual_filename, std::move (ranges), |
| file_data.build_id); |
| } |
| } |
| |
| normalize_mem_ranges (&m_core_unavailable_mappings); |
| } |
| |
| /* An arbitrary identifier for the core inferior. */ |
| #define CORELOW_PID 1 |
| |
| void |
| core_target::clear_core () |
| { |
| if (current_program_space->core_bfd () != nullptr) |
| { |
| switch_to_no_thread (); /* Avoid confusion from thread |
| stuff. */ |
| exit_inferior (current_inferior ()); |
| |
| /* Clear out solib state while the bfd is still open. See |
| comments in clear_solib in solib.c. */ |
| clear_solib (current_program_space); |
| |
| current_program_space->cbfd.reset (nullptr); |
| } |
| } |
| |
| /* Close the core target. */ |
| |
| void |
| core_target::close () |
| { |
| clear_core (); |
| |
| /* Core targets are heap-allocated (see core_target_open), so here |
| we delete ourselves. */ |
| delete this; |
| } |
| |
| /* Look for sections whose names start with `.reg/' so that we can |
| extract the list of threads in a core file. */ |
| |
| /* If ASECT is a section whose name begins with '.reg/' then extract the |
| lwpid after the '/' and create a new thread in INF. |
| |
| If REG_SECT is not nullptr, and the both ASECT and REG_SECT point at the |
| same position in the parent bfd object then switch to the newly created |
| thread, otherwise, the selected thread is left unchanged. */ |
| |
| static void |
| add_to_thread_list (asection *asect, asection *reg_sect, inferior *inf) |
| { |
| if (!startswith (bfd_section_name (asect), ".reg/")) |
| return; |
| |
| int lwpid = atoi (bfd_section_name (asect) + 5); |
| ptid_t ptid (inf->pid, lwpid); |
| thread_info *thr = add_thread (inf->process_target (), ptid); |
| |
| /* Warning, Will Robinson, looking at BFD private data! */ |
| |
| if (reg_sect != NULL |
| && asect->filepos == reg_sect->filepos) /* Did we find .reg? */ |
| switch_to_thread (thr); /* Yes, make it current. */ |
| } |
| |
| /* Issue a message saying we have no core to debug, if FROM_TTY. */ |
| |
| static void |
| maybe_say_no_core_file_now (int from_tty) |
| { |
| if (from_tty) |
| gdb_printf (_("No core file now.\n")); |
| } |
| |
| /* Backward compatibility with old way of specifying core files. */ |
| |
| void |
| core_file_command (const char *filename, int from_tty) |
| { |
| dont_repeat (); /* Either way, seems bogus. */ |
| |
| if (filename == NULL) |
| { |
| if (current_program_space->core_bfd () != nullptr) |
| { |
| target_detach (current_inferior (), from_tty); |
| gdb_assert (current_program_space->core_bfd () == nullptr); |
| } |
| else |
| maybe_say_no_core_file_now (from_tty); |
| } |
| else |
| core_target_open (filename, from_tty); |
| } |
| |
| /* A vmcore file is a core file created by the Linux kernel at the point of |
| a crash. Each thread in the core file represents a real CPU core, and |
| the lwpid for each thread is the pid of the process that was running on |
| that core at the moment of the crash. |
| |
| However, not every CPU core will have been running a process, some cores |
| will be idle. For these idle cores the CPU writes an lwpid of 0. And |
| of course, multiple cores might be idle, so there could be multiple |
| threads with an lwpid of 0. |
| |
| The problem is GDB doesn't really like threads with an lwpid of 0; GDB |
| presents such a thread as a process rather than a thread. And GDB |
| certainly doesn't like multiple threads having the same lwpid, each time |
| a new thread is seen with the same lwpid the earlier thread (with the |
| same lwpid) will be deleted. |
| |
| This function addresses both of these problems by assigning a fake lwpid |
| to any thread with an lwpid of 0. |
| |
| GDB finds the lwpid information by looking at the bfd section names |
| which include the lwpid, e.g. .reg/NN where NN is the lwpid. This |
| function looks though all the section names looking for sections named |
| .reg/NN. If any sections are found where NN == 0, then we assign a new |
| unique value of NN. Then, in a second pass, any sections ending /0 are |
| assigned their new number. |
| |
| Remember, a core file may contain multiple register sections for |
| different register sets, but the sets are always grouped by thread, so |
| we can figure out which registers should be assigned the same new |
| lwpid. For example, consider a core file containing: |
| |
| .reg/0, .reg2/0, .reg/0, .reg2/0 |
| |
| This represents two threads, each thread contains a .reg and .reg2 |
| register set. The .reg represents the start of each thread. After |
| renaming the sections will now look like this: |
| |
| .reg/1, .reg2/1, .reg/2, .reg2/2 |
| |
| After calling this function the rest of the core file handling code can |
| treat this core file just like any other core file. */ |
| |
| static void |
| rename_vmcore_idle_reg_sections (bfd *abfd, inferior *inf) |
| { |
| /* Map from the bfd section to its lwpid (the /NN number). */ |
| std::vector<std::pair<asection *, int>> sections_and_lwpids; |
| |
| /* The set of all /NN numbers found. Needed so we can easily find unused |
| numbers in the case that we need to rename some sections. */ |
| std::unordered_set<int> all_lwpids; |
| |
| /* A count of how many sections called .reg/0 we have found. */ |
| unsigned zero_lwpid_count = 0; |
| |
| /* Look for all the .reg sections. Record the section object and the |
| lwpid which is extracted from the section name. Spot if any have an |
| lwpid of zero. */ |
| for (asection *sect : gdb_bfd_sections (current_program_space->core_bfd ())) |
| { |
| if (startswith (bfd_section_name (sect), ".reg/")) |
| { |
| int lwpid = atoi (bfd_section_name (sect) + 5); |
| sections_and_lwpids.emplace_back (sect, lwpid); |
| all_lwpids.insert (lwpid); |
| if (lwpid == 0) |
| zero_lwpid_count++; |
| } |
| } |
| |
| /* If every ".reg/NN" section has a non-zero lwpid then we don't need to |
| do any renaming. */ |
| if (zero_lwpid_count == 0) |
| return; |
| |
| /* Assign a new number to any .reg sections with an lwpid of 0. */ |
| int new_lwpid = 1; |
| for (auto §_and_lwpid : sections_and_lwpids) |
| if (sect_and_lwpid.second == 0) |
| { |
| while (all_lwpids.find (new_lwpid) != all_lwpids.end ()) |
| new_lwpid++; |
| sect_and_lwpid.second = new_lwpid; |
| new_lwpid++; |
| } |
| |
| /* Now update the names of any sections with an lwpid of 0. This is |
| more than just the .reg sections we originally found. */ |
| std::string replacement_lwpid_str; |
| auto iter = sections_and_lwpids.begin (); |
| int replacement_lwpid = 0; |
| for (asection *sect : gdb_bfd_sections (current_program_space->core_bfd ())) |
| { |
| if (iter != sections_and_lwpids.end () && sect == iter->first) |
| { |
| gdb_assert (startswith (bfd_section_name (sect), ".reg/")); |
| |
| int lwpid = atoi (bfd_section_name (sect) + 5); |
| if (lwpid == iter->second) |
| { |
| /* This section was not given a new number. */ |
| gdb_assert (lwpid != 0); |
| replacement_lwpid = 0; |
| } |
| else |
| { |
| replacement_lwpid = iter->second; |
| ptid_t ptid (inf->pid, replacement_lwpid); |
| if (!replacement_lwpid_str.empty ()) |
| replacement_lwpid_str += ", "; |
| replacement_lwpid_str += target_pid_to_str (ptid); |
| } |
| |
| iter++; |
| } |
| |
| if (replacement_lwpid != 0) |
| { |
| const char *name = bfd_section_name (sect); |
| size_t len = strlen (name); |
| |
| if (strncmp (name + len - 2, "/0", 2) == 0) |
| { |
| /* This section needs a new name. */ |
| std::string name_str |
| = string_printf ("%.*s/%d", |
| static_cast<int> (len - 2), |
| name, replacement_lwpid); |
| char *name_buf |
| = static_cast<char *> (bfd_alloc (abfd, name_str.size () + 1)); |
| if (name_buf == nullptr) |
| error (_("failed to allocate space for section name '%s'"), |
| name_str.c_str ()); |
| memcpy (name_buf, name_str.c_str(), name_str.size () + 1); |
| bfd_rename_section (sect, name_buf); |
| } |
| } |
| } |
| |
| if (zero_lwpid_count == 1) |
| warning (_("found thread with pid 0, assigned replacement Target Id: %s"), |
| replacement_lwpid_str.c_str ()); |
| else |
| warning (_("found threads with pid 0, assigned replacement Target Ids: %s"), |
| replacement_lwpid_str.c_str ()); |
| } |
| |
| /* Locate (and load) an executable file (and symbols) given the core file |
| BFD ABFD. */ |
| |
| static void |
| locate_exec_from_corefile_build_id (bfd *abfd, int from_tty) |
| { |
| const bfd_build_id *build_id = build_id_bfd_get (abfd); |
| if (build_id == nullptr) |
| return; |
| |
| gdb_bfd_ref_ptr execbfd |
| = find_objfile_by_build_id (build_id, abfd->filename); |
| |
| if (execbfd != nullptr) |
| { |
| exec_file_attach (bfd_get_filename (execbfd.get ()), from_tty); |
| symbol_file_add_main (bfd_get_filename (execbfd.get ()), |
| symfile_add_flag (from_tty ? SYMFILE_VERBOSE : 0)); |
| } |
| } |
| |
| /* See gdbcore.h. */ |
| |
| void |
| core_target_open (const char *arg, int from_tty) |
| { |
| const char *p; |
| int siggy; |
| int scratch_chan; |
| int flags; |
| |
| target_preopen (from_tty); |
| if (!arg) |
| { |
| if (current_program_space->core_bfd ()) |
| error (_("No core file specified. (Use `detach' " |
| "to stop debugging a core file.)")); |
| else |
| error (_("No core file specified.")); |
| } |
| |
| gdb::unique_xmalloc_ptr<char> filename (tilde_expand (arg)); |
| if (strlen (filename.get ()) != 0 |
| && !IS_ABSOLUTE_PATH (filename.get ())) |
| filename = make_unique_xstrdup (gdb_abspath (filename).c_str ()); |
| |
| flags = O_BINARY | O_LARGEFILE; |
| if (write_files) |
| flags |= O_RDWR; |
| else |
| flags |= O_RDONLY; |
| scratch_chan = gdb_open_cloexec (filename.get (), flags, 0).release (); |
| if (scratch_chan < 0) |
| perror_with_name (filename.get ()); |
| |
| gdb_bfd_ref_ptr temp_bfd (gdb_bfd_fopen (filename.get (), gnutarget, |
| write_files ? FOPEN_RUB : FOPEN_RB, |
| scratch_chan)); |
| if (temp_bfd == NULL) |
| perror_with_name (filename.get ()); |
| |
| if (!bfd_check_format (temp_bfd.get (), bfd_core)) |
| { |
| /* Do it after the err msg */ |
| /* FIXME: should be checking for errors from bfd_close (for one |
| thing, on error it does not free all the storage associated |
| with the bfd). */ |
| error (_("\"%s\" is not a core dump: %s"), |
| filename.get (), bfd_errmsg (bfd_get_error ())); |
| } |
| |
| current_program_space->cbfd = std::move (temp_bfd); |
| |
| core_target *target = new core_target (); |
| |
| /* Own the target until it is successfully pushed. */ |
| target_ops_up target_holder (target); |
| |
| validate_files (); |
| |
| /* If we have no exec file, try to set the architecture from the |
| core file. We don't do this unconditionally since an exec file |
| typically contains more information that helps us determine the |
| architecture than a core file. */ |
| if (!current_program_space->exec_bfd ()) |
| set_gdbarch_from_file (current_program_space->core_bfd ()); |
| |
| current_inferior ()->push_target (std::move (target_holder)); |
| |
| switch_to_no_thread (); |
| |
| /* Need to flush the register cache (and the frame cache) from a |
| previous debug session. If inferior_ptid ends up the same as the |
| last debug session --- e.g., b foo; run; gcore core1; step; gcore |
| core2; core core1; core core2 --- then there's potential for |
| get_current_regcache to return the cached regcache of the |
| previous session, and the frame cache being stale. */ |
| registers_changed (); |
| |
| /* Find (or fake) the pid for the process in this core file, and |
| initialise the current inferior with that pid. */ |
| bool fake_pid_p = false; |
| int pid = bfd_core_file_pid (current_program_space->core_bfd ()); |
| if (pid == 0) |
| { |
| fake_pid_p = true; |
| pid = CORELOW_PID; |
| } |
| |
| inferior *inf = current_inferior (); |
| gdb_assert (inf->pid == 0); |
| inferior_appeared (inf, pid); |
| inf->fake_pid_p = fake_pid_p; |
| |
| /* Rename any .reg/0 sections, giving them each a fake lwpid. */ |
| rename_vmcore_idle_reg_sections (current_program_space->core_bfd (), inf); |
| |
| /* Build up thread list from BFD sections, and possibly set the |
| current thread to the .reg/NN section matching the .reg |
| section. */ |
| asection *reg_sect |
| = bfd_get_section_by_name (current_program_space->core_bfd (), ".reg"); |
| for (asection *sect : gdb_bfd_sections (current_program_space->core_bfd ())) |
| add_to_thread_list (sect, reg_sect, inf); |
| |
| if (inferior_ptid == null_ptid) |
| { |
| /* Either we found no .reg/NN section, and hence we have a |
| non-threaded core (single-threaded, from gdb's perspective), |
| or for some reason add_to_thread_list couldn't determine |
| which was the "main" thread. The latter case shouldn't |
| usually happen, but we're dealing with input here, which can |
| always be broken in different ways. */ |
| thread_info *thread = first_thread_of_inferior (inf); |
| |
| if (thread == NULL) |
| thread = add_thread_silent (target, ptid_t (CORELOW_PID)); |
| |
| switch_to_thread (thread); |
| } |
| |
| if (current_program_space->exec_bfd () == nullptr) |
| locate_exec_from_corefile_build_id (current_program_space->core_bfd (), |
| from_tty); |
| |
| post_create_inferior (from_tty); |
| |
| /* Now go through the target stack looking for threads since there |
| may be a thread_stratum target loaded on top of target core by |
| now. The layer above should claim threads found in the BFD |
| sections. */ |
| try |
| { |
| target_update_thread_list (); |
| } |
| |
| catch (const gdb_exception_error &except) |
| { |
| exception_print (gdb_stderr, except); |
| } |
| |
| p = bfd_core_file_failing_command (current_program_space->core_bfd ()); |
| if (p) |
| gdb_printf (_("Core was generated by `%s'.\n"), p); |
| |
| /* Clearing any previous state of convenience variables. */ |
| clear_exit_convenience_vars (); |
| |
| siggy = bfd_core_file_failing_signal (current_program_space->core_bfd ()); |
| if (siggy > 0) |
| { |
| gdbarch *core_gdbarch = target->core_gdbarch (); |
| |
| /* If we don't have a CORE_GDBARCH to work with, assume a native |
| core (map gdb_signal from host signals). If we do have |
| CORE_GDBARCH to work with, but no gdb_signal_from_target |
| implementation for that gdbarch, as a fallback measure, |
| assume the host signal mapping. It'll be correct for native |
| cores, but most likely incorrect for cross-cores. */ |
| enum gdb_signal sig = (core_gdbarch != NULL |
| && gdbarch_gdb_signal_from_target_p (core_gdbarch) |
| ? gdbarch_gdb_signal_from_target (core_gdbarch, |
| siggy) |
| : gdb_signal_from_host (siggy)); |
| |
| gdb_printf (_("Program terminated with signal %s, %s"), |
| gdb_signal_to_name (sig), gdb_signal_to_string (sig)); |
| if (gdbarch_report_signal_info_p (core_gdbarch)) |
| gdbarch_report_signal_info (core_gdbarch, current_uiout, sig); |
| gdb_printf (_(".\n")); |
| |
| /* Set the value of the internal variable $_exitsignal, |
| which holds the signal uncaught by the inferior. */ |
| set_internalvar_integer (lookup_internalvar ("_exitsignal"), |
| siggy); |
| } |
| |
| /* Fetch all registers from core file. */ |
| target_fetch_registers (get_thread_regcache (inferior_thread ()), -1); |
| |
| /* Now, set up the frame cache, and print the top of stack. */ |
| reinit_frame_cache (); |
| print_stack_frame (get_selected_frame (NULL), 1, SRC_AND_LOC, 1); |
| |
| /* Current thread should be NUM 1 but the user does not know that. |
| If a program is single threaded gdb in general does not mention |
| anything about threads. That is why the test is >= 2. */ |
| if (thread_count (target) >= 2) |
| { |
| try |
| { |
| thread_command (NULL, from_tty); |
| } |
| catch (const gdb_exception_error &except) |
| { |
| exception_print (gdb_stderr, except); |
| } |
| } |
| } |
| |
| void |
| core_target::detach (inferior *inf, int from_tty) |
| { |
| /* Get rid of the core. Don't rely on core_target::close doing it, |
| because target_detach may be called with core_target's refcount > 1, |
| meaning core_target::close may not be called yet by the |
| unpush_target call below. */ |
| clear_core (); |
| |
| /* Note that 'this' may be dangling after this call. unpush_target |
| closes the target if the refcount reaches 0, and our close |
| implementation deletes 'this'. */ |
| inf->unpush_target (this); |
| |
| /* Clear the register cache and the frame cache. */ |
| registers_changed (); |
| reinit_frame_cache (); |
| maybe_say_no_core_file_now (from_tty); |
| } |
| |
| /* Try to retrieve registers from a section in core_bfd, and supply |
| them to REGSET. |
| |
| If ptid's lwp member is zero, do the single-threaded |
| thing: look for a section named NAME. If ptid's lwp |
| member is non-zero, do the multi-threaded thing: look for a section |
| named "NAME/LWP", where LWP is the shortest ASCII decimal |
| representation of ptid's lwp member. |
| |
| HUMAN_NAME is a human-readable name for the kind of registers the |
| NAME section contains, for use in error messages. |
| |
| If REQUIRED is true, print an error if the core file doesn't have a |
| section by the appropriate name. Otherwise, just do nothing. */ |
| |
| void |
| core_target::get_core_register_section (struct regcache *regcache, |
| const struct regset *regset, |
| const char *name, |
| int section_min_size, |
| const char *human_name, |
| bool required) |
| { |
| gdb_assert (regset != nullptr); |
| |
| struct bfd_section *section; |
| bfd_size_type size; |
| bool variable_size_section = (regset->flags & REGSET_VARIABLE_SIZE); |
| |
| thread_section_name section_name (name, regcache->ptid ()); |
| |
| section = bfd_get_section_by_name (current_program_space->core_bfd (), |
| section_name.c_str ()); |
| if (! section) |
| { |
| if (required) |
| warning (_("Couldn't find %s registers in core file."), |
| human_name); |
| return; |
| } |
| |
| size = bfd_section_size (section); |
| if (size < section_min_size) |
| { |
| warning (_("Section `%s' in core file too small."), |
| section_name.c_str ()); |
| return; |
| } |
| if (size != section_min_size && !variable_size_section) |
| { |
| warning (_("Unexpected size of section `%s' in core file."), |
| section_name.c_str ()); |
| } |
| |
| gdb::byte_vector contents (size); |
| if (!bfd_get_section_contents (current_program_space->core_bfd (), section, |
| contents.data (), (file_ptr) 0, size)) |
| { |
| warning (_("Couldn't read %s registers from `%s' section in core file."), |
| human_name, section_name.c_str ()); |
| return; |
| } |
| |
| regset->supply_regset (regset, regcache, -1, contents.data (), size); |
| } |
| |
| /* Data passed to gdbarch_iterate_over_regset_sections's callback. */ |
| struct get_core_registers_cb_data |
| { |
| core_target *target; |
| struct regcache *regcache; |
| }; |
| |
| /* Callback for get_core_registers that handles a single core file |
| register note section. */ |
| |
| static void |
| get_core_registers_cb (const char *sect_name, int supply_size, int collect_size, |
| const struct regset *regset, |
| const char *human_name, void *cb_data) |
| { |
| gdb_assert (regset != nullptr); |
| |
| auto *data = (get_core_registers_cb_data *) cb_data; |
| bool required = false; |
| bool variable_size_section = (regset->flags & REGSET_VARIABLE_SIZE); |
| |
| if (!variable_size_section) |
| gdb_assert (supply_size == collect_size); |
| |
| if (strcmp (sect_name, ".reg") == 0) |
| { |
| required = true; |
| if (human_name == NULL) |
| human_name = "general-purpose"; |
| } |
| else if (strcmp (sect_name, ".reg2") == 0) |
| { |
| if (human_name == NULL) |
| human_name = "floating-point"; |
| } |
| |
| data->target->get_core_register_section (data->regcache, regset, sect_name, |
| supply_size, human_name, required); |
| } |
| |
| /* Get the registers out of a core file. This is the machine- |
| independent part. Fetch_core_registers is the machine-dependent |
| part, typically implemented in the xm-file for each |
| architecture. */ |
| |
| /* We just get all the registers, so we don't use regno. */ |
| |
| void |
| core_target::fetch_registers (struct regcache *regcache, int regno) |
| { |
| if (!(m_core_gdbarch != nullptr |
| && gdbarch_iterate_over_regset_sections_p (m_core_gdbarch))) |
| { |
| gdb_printf (gdb_stderr, |
| "Can't fetch registers from this type of core file\n"); |
| return; |
| } |
| |
| struct gdbarch *gdbarch = regcache->arch (); |
| get_core_registers_cb_data data = { this, regcache }; |
| gdbarch_iterate_over_regset_sections (gdbarch, |
| get_core_registers_cb, |
| (void *) &data, NULL); |
| |
| /* Mark all registers not found in the core as unavailable. */ |
| for (int i = 0; i < gdbarch_num_regs (regcache->arch ()); i++) |
| if (regcache->get_register_status (i) == REG_UNKNOWN) |
| regcache->raw_supply (i, NULL); |
| } |
| |
| void |
| core_target::files_info () |
| { |
| print_section_info (&m_core_section_table, current_program_space->core_bfd ()); |
| } |
| |
| |
| enum target_xfer_status |
| core_target::xfer_partial (enum target_object object, const char *annex, |
| gdb_byte *readbuf, const gdb_byte *writebuf, |
| ULONGEST offset, ULONGEST len, ULONGEST *xfered_len) |
| { |
| switch (object) |
| { |
| case TARGET_OBJECT_MEMORY: |
| { |
| enum target_xfer_status xfer_status; |
| |
| /* Try accessing memory contents from core file data, |
| restricting consideration to those sections for which |
| the BFD section flag SEC_HAS_CONTENTS is set. */ |
| auto has_contents_cb = [] (const struct target_section *s) |
| { |
| return ((s->the_bfd_section->flags & SEC_HAS_CONTENTS) != 0); |
| }; |
| xfer_status = section_table_xfer_memory_partial |
| (readbuf, writebuf, |
| offset, len, xfered_len, |
| m_core_section_table, |
| has_contents_cb); |
| if (xfer_status == TARGET_XFER_OK) |
| return TARGET_XFER_OK; |
| |
| /* Check file backed mappings. If they're available, use core file |
| provided mappings (e.g. from .note.linuxcore.file or the like) |
| as this should provide a more accurate result. */ |
| if (!m_core_file_mappings.empty ()) |
| { |
| xfer_status = section_table_xfer_memory_partial |
| (readbuf, writebuf, offset, len, xfered_len, |
| m_core_file_mappings); |
| if (xfer_status == TARGET_XFER_OK) |
| return xfer_status; |
| } |
| |
| /* If the access is within an unavailable file mapping then we try |
| to check in the stratum below (the executable stratum). The |
| thinking here is that if the mapping was read/write then the |
| contents would have been written into the core file and the |
| access would have been satisfied by m_core_section_table. |
| |
| But if the access has not yet been resolved then we can assume |
| the access is read-only. If the executable was not found |
| during the mapped file check then we'll have an unavailable |
| mapping entry, however, if the user has provided the executable |
| (maybe in a different location) then we might be able to |
| resolve the access from there. |
| |
| If that fails, but the access is within an unavailable region, |
| then the access itself should fail. */ |
| for (const auto &mr : m_core_unavailable_mappings) |
| { |
| if (mr.contains (offset)) |
| { |
| if (!mr.contains (offset + len)) |
| len = mr.start + mr.length - offset; |
| |
| xfer_status |
| = this->beneath ()->xfer_partial (TARGET_OBJECT_MEMORY, |
| nullptr, readbuf, |
| writebuf, offset, |
| len, xfered_len); |
| if (xfer_status == TARGET_XFER_OK) |
| return TARGET_XFER_OK; |
| |
| return TARGET_XFER_E_IO; |
| } |
| } |
| |
| /* The following is acting as a fallback in case we encounter a |
| situation where the core file is lacking and mapped file |
| information. Here we query the exec file stratum to see if it |
| can resolve the access. Doing this when we are missing mapped |
| file information might be the best we can do, but there are |
| certainly cases this will get wrong, e.g. if an inferior created |
| a zero initialised mapping over the top of some data that exists |
| within the executable then this will return the executable data |
| rather than the zero data. Maybe we should just drop this |
| block? */ |
| if (m_core_file_mappings.empty () |
| && m_core_unavailable_mappings.empty ()) |
| { |
| xfer_status |
| = this->beneath ()->xfer_partial (object, annex, readbuf, |
| writebuf, offset, len, |
| xfered_len); |
| if (xfer_status == TARGET_XFER_OK) |
| return TARGET_XFER_OK; |
| } |
| |
| /* Finally, attempt to access data in core file sections with |
| no contents. These will typically read as all zero. */ |
| auto no_contents_cb = [&] (const struct target_section *s) |
| { |
| return !has_contents_cb (s); |
| }; |
| xfer_status = section_table_xfer_memory_partial |
| (readbuf, writebuf, |
| offset, len, xfered_len, |
| m_core_section_table, |
| no_contents_cb); |
| |
| return xfer_status; |
| } |
| case TARGET_OBJECT_AUXV: |
| if (readbuf) |
| { |
| /* When the aux vector is stored in core file, BFD |
| represents this with a fake section called ".auxv". */ |
| |
| struct bfd_section *section; |
| bfd_size_type size; |
| |
| section = bfd_get_section_by_name (current_program_space->core_bfd (), |
| ".auxv"); |
| if (section == NULL) |
| return TARGET_XFER_E_IO; |
| |
| size = bfd_section_size (section); |
| if (offset >= size) |
| return TARGET_XFER_EOF; |
| size -= offset; |
| if (size > len) |
| size = len; |
| |
| if (size == 0) |
| return TARGET_XFER_EOF; |
| if (!bfd_get_section_contents (current_program_space->core_bfd (), |
| section, readbuf, (file_ptr) offset, |
| size)) |
| { |
| warning (_("Couldn't read NT_AUXV note in core file.")); |
| return TARGET_XFER_E_IO; |
| } |
| |
| *xfered_len = (ULONGEST) size; |
| return TARGET_XFER_OK; |
| } |
| return TARGET_XFER_E_IO; |
| |
| case TARGET_OBJECT_WCOOKIE: |
| if (readbuf) |
| { |
| /* When the StackGhost cookie is stored in core file, BFD |
| represents this with a fake section called |
| ".wcookie". */ |
| |
| struct bfd_section *section; |
| bfd_size_type size; |
| |
| section = bfd_get_section_by_name (current_program_space->core_bfd (), |
| ".wcookie"); |
| if (section == NULL) |
| return TARGET_XFER_E_IO; |
| |
| size = bfd_section_size (section); |
| if (offset >= size) |
| return TARGET_XFER_EOF; |
| size -= offset; |
| if (size > len) |
| size = len; |
| |
| if (size == 0) |
| return TARGET_XFER_EOF; |
| if (!bfd_get_section_contents (current_program_space->core_bfd (), |
| section, readbuf, (file_ptr) offset, |
| size)) |
| { |
| warning (_("Couldn't read StackGhost cookie in core file.")); |
| return TARGET_XFER_E_IO; |
| } |
| |
| *xfered_len = (ULONGEST) size; |
| return TARGET_XFER_OK; |
| |
| } |
| return TARGET_XFER_E_IO; |
| |
| case TARGET_OBJECT_LIBRARIES: |
| if (m_core_gdbarch != nullptr |
| && gdbarch_core_xfer_shared_libraries_p (m_core_gdbarch)) |
| { |
| if (writebuf) |
| return TARGET_XFER_E_IO; |
| else |
| { |
| *xfered_len = gdbarch_core_xfer_shared_libraries (m_core_gdbarch, |
| readbuf, |
| offset, len); |
| |
| if (*xfered_len == 0) |
| return TARGET_XFER_EOF; |
| else |
| return TARGET_XFER_OK; |
| } |
| } |
| return TARGET_XFER_E_IO; |
| |
| case TARGET_OBJECT_LIBRARIES_AIX: |
| if (m_core_gdbarch != nullptr |
| && gdbarch_core_xfer_shared_libraries_aix_p (m_core_gdbarch)) |
| { |
| if (writebuf) |
| return TARGET_XFER_E_IO; |
| else |
| { |
| *xfered_len |
| = gdbarch_core_xfer_shared_libraries_aix (m_core_gdbarch, |
| readbuf, offset, |
| len); |
| |
| if (*xfered_len == 0) |
| return TARGET_XFER_EOF; |
| else |
| return TARGET_XFER_OK; |
| } |
| } |
| return TARGET_XFER_E_IO; |
| |
| case TARGET_OBJECT_SIGNAL_INFO: |
| if (readbuf) |
| { |
| if (m_core_gdbarch != nullptr |
| && gdbarch_core_xfer_siginfo_p (m_core_gdbarch)) |
| { |
| LONGEST l = gdbarch_core_xfer_siginfo (m_core_gdbarch, readbuf, |
| offset, len); |
| |
| if (l >= 0) |
| { |
| *xfered_len = l; |
| if (l == 0) |
| return TARGET_XFER_EOF; |
| else |
| return TARGET_XFER_OK; |
| } |
| } |
| } |
| return TARGET_XFER_E_IO; |
| |
| default: |
| return this->beneath ()->xfer_partial (object, annex, readbuf, |
| writebuf, offset, len, |
| xfered_len); |
| } |
| } |
| |
| |
| |
| /* Okay, let's be honest: threads gleaned from a core file aren't |
| exactly lively, are they? On the other hand, if we don't claim |
| that each & every one is alive, then we don't get any of them |
| to appear in an "info thread" command, which is quite a useful |
| behaviour. |
| */ |
| bool |
| core_target::thread_alive (ptid_t ptid) |
| { |
| return true; |
| } |
| |
| /* Ask the current architecture what it knows about this core file. |
| That will be used, in turn, to pick a better architecture. This |
| wrapper could be avoided if targets got a chance to specialize |
| core_target. */ |
| |
| const struct target_desc * |
| core_target::read_description () |
| { |
| /* First check whether the target wants us to use the corefile target |
| description notes. */ |
| if (gdbarch_use_target_description_from_corefile_notes |
| (m_core_gdbarch, current_program_space->core_bfd ())) |
| { |
| /* If the core file contains a target description note then go ahead and |
| use that. */ |
| bfd_size_type tdesc_note_size = 0; |
| struct bfd_section *tdesc_note_section |
| = bfd_get_section_by_name (current_program_space->core_bfd (), ".gdb-tdesc"); |
| if (tdesc_note_section != nullptr) |
| tdesc_note_size = bfd_section_size (tdesc_note_section); |
| if (tdesc_note_size > 0) |
| { |
| gdb::char_vector contents (tdesc_note_size + 1); |
| if (bfd_get_section_contents (current_program_space->core_bfd (), |
| tdesc_note_section, contents.data (), |
| (file_ptr) 0, tdesc_note_size)) |
| { |
| /* Ensure we have a null terminator. */ |
| contents[tdesc_note_size] = '\0'; |
| const struct target_desc *result |
| = string_read_description_xml (contents.data ()); |
| if (result != nullptr) |
| return result; |
| } |
| } |
| } |
| |
| /* If the architecture provides a corefile target description hook, use |
| it now. Even if the core file contains a target description in a note |
| section, it is not useful for targets that can potentially have distinct |
| descriptions for each thread. One example is AArch64's SVE/SME |
| extensions that allow per-thread vector length changes, resulting in |
| registers with different sizes. */ |
| if (m_core_gdbarch && gdbarch_core_read_description_p (m_core_gdbarch)) |
| { |
| const struct target_desc *result; |
| |
| result = gdbarch_core_read_description |
| (m_core_gdbarch, this, current_program_space->core_bfd ()); |
| if (result != nullptr) |
| return result; |
| } |
| |
| return this->beneath ()->read_description (); |
| } |
| |
| std::string |
| core_target::pid_to_str (ptid_t ptid) |
| { |
| struct inferior *inf; |
| int pid; |
| |
| /* The preferred way is to have a gdbarch/OS specific |
| implementation. */ |
| if (m_core_gdbarch != nullptr |
| && gdbarch_core_pid_to_str_p (m_core_gdbarch)) |
| return gdbarch_core_pid_to_str (m_core_gdbarch, ptid); |
| |
| /* Otherwise, if we don't have one, we'll just fallback to |
| "process", with normal_pid_to_str. */ |
| |
| /* Try the LWPID field first. */ |
| pid = ptid.lwp (); |
| if (pid != 0) |
| return normal_pid_to_str (ptid_t (pid)); |
| |
| /* Otherwise, this isn't a "threaded" core -- use the PID field, but |
| only if it isn't a fake PID. */ |
| inf = find_inferior_ptid (this, ptid); |
| if (inf != NULL && !inf->fake_pid_p) |
| return normal_pid_to_str (ptid); |
| |
| /* No luck. We simply don't have a valid PID to print. */ |
| return "<main task>"; |
| } |
| |
| const char * |
| core_target::thread_name (struct thread_info *thr) |
| { |
| if (m_core_gdbarch != nullptr |
| && gdbarch_core_thread_name_p (m_core_gdbarch)) |
| return gdbarch_core_thread_name (m_core_gdbarch, thr); |
| return NULL; |
| } |
| |
| bool |
| core_target::has_memory () |
| { |
| return current_program_space->core_bfd () != nullptr; |
| } |
| |
| bool |
| core_target::has_stack () |
| { |
| return current_program_space->core_bfd () != nullptr; |
| } |
| |
| bool |
| core_target::has_registers () |
| { |
| return current_program_space->core_bfd () != nullptr; |
| } |
| |
| /* Implement the to_info_proc method. */ |
| |
| bool |
| core_target::info_proc (const char *args, enum info_proc_what request) |
| { |
| struct gdbarch *gdbarch = get_current_arch (); |
| |
| /* Since this is the core file target, call the 'core_info_proc' |
| method on gdbarch, not 'info_proc'. */ |
| if (gdbarch_core_info_proc_p (gdbarch)) |
| gdbarch_core_info_proc (gdbarch, args, request); |
| |
| return true; |
| } |
| |
| /* Implementation of the "supports_memory_tagging" target_ops method. */ |
| |
| bool |
| core_target::supports_memory_tagging () |
| { |
| /* Look for memory tag sections. If they exist, that means this core file |
| supports memory tagging. */ |
| |
| return (bfd_get_section_by_name (current_program_space->core_bfd (), "memtag") |
| != nullptr); |
| } |
| |
| /* Implementation of the "fetch_memtags" target_ops method. */ |
| |
| bool |
| core_target::fetch_memtags (CORE_ADDR address, size_t len, |
| gdb::byte_vector &tags, int type) |
| { |
| gdbarch *gdbarch = current_inferior ()->arch (); |
| |
| /* Make sure we have a way to decode the memory tag notes. */ |
| if (!gdbarch_decode_memtag_section_p (gdbarch)) |
| error (_("gdbarch_decode_memtag_section not implemented for this " |
| "architecture.")); |
| |
| memtag_section_info info; |
| info.memtag_section = nullptr; |
| |
| while (get_next_core_memtag_section (current_program_space->core_bfd (), |
| info.memtag_section, address, info)) |
| { |
| size_t adjusted_length |
| = (address + len < info.end_address) ? len : (info.end_address - address); |
| |
| /* Decode the memory tag note and return the tags. */ |
| gdb::byte_vector tags_read |
| = gdbarch_decode_memtag_section (gdbarch, info.memtag_section, type, |
| address, adjusted_length); |
| |
| /* Transfer over the tags that have been read. */ |
| tags.insert (tags.end (), tags_read.begin (), tags_read.end ()); |
| |
| /* ADDRESS + LEN may cross the boundaries of a particular memory tag |
| segment. Check if we need to fetch tags from a different section. */ |
| if (!tags_read.empty () && (address + len) < info.end_address) |
| return true; |
| |
| /* There are more tags to fetch. Update ADDRESS and LEN. */ |
| len -= (info.end_address - address); |
| address = info.end_address; |
| } |
| |
| return false; |
| } |
| |
| bool |
| core_target::is_address_tagged (gdbarch *gdbarch, CORE_ADDR address) |
| { |
| return gdbarch_tagged_address_p (gdbarch, address); |
| } |
| |
| /* Implementation of the "fetch_x86_xsave_layout" target_ops method. */ |
| |
| x86_xsave_layout |
| core_target::fetch_x86_xsave_layout () |
| { |
| if (m_core_gdbarch != nullptr && |
| gdbarch_core_read_x86_xsave_layout_p (m_core_gdbarch)) |
| { |
| x86_xsave_layout layout; |
| if (!gdbarch_core_read_x86_xsave_layout (m_core_gdbarch, layout)) |
| return {}; |
| |
| return layout; |
| } |
| |
| return {}; |
| } |
| |
| /* Get a pointer to the current core target. If not connected to a |
| core target, return NULL. */ |
| |
| static core_target * |
| get_current_core_target () |
| { |
| target_ops *proc_target = current_inferior ()->process_target (); |
| return dynamic_cast<core_target *> (proc_target); |
| } |
| |
| /* Display file backed mappings from core file. */ |
| |
| void |
| core_target::info_proc_mappings (struct gdbarch *gdbarch) |
| { |
| if (!m_core_file_mappings.empty ()) |
| { |
| gdb_printf (_("Mapped address spaces:\n\n")); |
| if (gdbarch_addr_bit (gdbarch) == 32) |
| { |
| gdb_printf ("\t%10s %10s %10s %10s %s\n", |
| "Start Addr", |
| " End Addr", |
| " Size", " Offset", "objfile"); |
| } |
| else |
| { |
| gdb_printf (" %18s %18s %10s %10s %s\n", |
| "Start Addr", |
| " End Addr", |
| " Size", " Offset", "objfile"); |
| } |
| } |
| |
| for (const target_section &tsp : m_core_file_mappings) |
| { |
| ULONGEST start = tsp.addr; |
| ULONGEST end = tsp.endaddr; |
| ULONGEST file_ofs = tsp.the_bfd_section->filepos; |
| const char *filename = bfd_get_filename (tsp.the_bfd_section->owner); |
| |
| if (gdbarch_addr_bit (gdbarch) == 32) |
| gdb_printf ("\t%10s %10s %10s %10s %s\n", |
| paddress (gdbarch, start), |
| paddress (gdbarch, end), |
| hex_string (end - start), |
| hex_string (file_ofs), |
| filename); |
| else |
| gdb_printf (" %18s %18s %10s %10s %s\n", |
| paddress (gdbarch, start), |
| paddress (gdbarch, end), |
| hex_string (end - start), |
| hex_string (file_ofs), |
| filename); |
| } |
| } |
| |
| /* Implement "maintenance print core-file-backed-mappings" command. |
| |
| If mappings are loaded, the results should be similar to the |
| mappings shown by "info proc mappings". This command is mainly a |
| debugging tool for GDB developers to make sure that the expected |
| mappings are present after loading a core file. For Linux, the |
| output provided by this command will be very similar (if not |
| identical) to that provided by "info proc mappings". This is not |
| necessarily the case for other OSes which might provide |
| more/different information in the "info proc mappings" output. */ |
| |
| static void |
| maintenance_print_core_file_backed_mappings (const char *args, int from_tty) |
| { |
| core_target *targ = get_current_core_target (); |
| if (targ != nullptr) |
| targ->info_proc_mappings (targ->core_gdbarch ()); |
| } |
| |
| /* Add more details discovered while processing the core-file's mapped file |
| information, we're building maps between filenames and the corresponding |
| build-ids, between address ranges and the corresponding build-ids, and |
| also a reverse map between build-id and the corresponding filename. |
| |
| SONAME is the DT_SONAME attribute extracted from the .dynamic section of |
| a shared library that was mapped into the core file. This can be |
| nullptr if the mapped files was not a shared library, or didn't have a |
| DT_SONAME attribute. |
| |
| EXPECTED_FILENAME is the name of the file that was mapped into the |
| inferior as extracted from the core file, this should never be nullptr. |
| |
| ACTUAL_FILENAME is the name of the actual file GDB found to provide the |
| mapped file information, this can be nullptr if GDB failed to find a |
| suitable file. This might be different to EXPECTED_FILENAME, e.g. GDB |
| might have downloaded the file from debuginfod and so ACTUAL_FILENAME |
| will be a file in the debuginfod client cache. |
| |
| RANGES is the list of memory ranges at which this file was mapped into |
| the inferior. |
| |
| BUILD_ID is the build-id for this mapped file, this will never be |
| nullptr. Not every mapped file will have a build-id, but there's no |
| point calling this function if we failed to find a build-id; this |
| structure only exists so we can lookup files based on their build-id. */ |
| |
| void |
| mapped_file_info::add (const char *soname, |
| const char *expected_filename, |
| const char *actual_filename, |
| std::vector<mem_range> &&ranges, |
| const bfd_build_id *build_id) |
| { |
| gdb_assert (build_id != nullptr); |
| gdb_assert (expected_filename != nullptr); |
| |
| if (soname != nullptr) |
| { |
| /* If we already have an entry with this SONAME then this indicates |
| that the inferior has two files mapped into memory with different |
| file names (and most likely different build-ids), but with the |
| same DT_SONAME attribute. In this case we can't use the |
| DT_SONAME to figure out the expected build-id of a shared |
| library, so poison the entry for this SONAME by setting the entry |
| to nullptr. */ |
| auto it = m_soname_to_build_id_map.find (soname); |
| if (it != m_soname_to_build_id_map.end () |
| && it->second != nullptr |
| && !build_id_equal (it->second, build_id)) |
| m_soname_to_build_id_map[soname] = nullptr; |
| else |
| m_soname_to_build_id_map[soname] = build_id; |
| } |
| |
| /* When the core file is initially opened and the mapped files are |
| parsed, we group the build-id information based on the file name. As |
| a consequence, we should see each EXPECTED_FILENAME value exactly |
| once. This means that each insertion should always succeed. */ |
| const auto [it, inserted] |
| = m_filename_to_build_id_map.emplace (expected_filename, build_id); |
| gdb_assert (inserted); |
| |
| /* Setup the reverse build-id to file name map. */ |
| if (actual_filename != nullptr) |
| m_build_id_to_filename_map.emplace (build_id, actual_filename); |
| |
| /* Setup the list of memory range to build-id objects. */ |
| for (mem_range &r : ranges) |
| m_address_to_build_id_list.emplace_back (std::move (r), build_id); |
| |
| /* At this point the m_address_to_build_id_list is unsorted (we just |
| added some entries to the end of the list). All entries should be |
| added before any look-ups are performed, and the list is only sorted |
| when the first look-up is performed. */ |
| gdb_assert (!m_address_to_build_id_list_sorted); |
| } |
| |
| /* FILENAME is the name of a file GDB is trying to load, and ADDR is |
| (optionally) an address within the file in the inferior's address space. |
| |
| Search through the information gathered from the core-file's mapped file |
| information looking for a file named FILENAME, or for a file that covers |
| ADDR. If a match is found then return the build-id for the file along |
| with the location where GDB found the mapped file. |
| |
| The location of the mapped file might be the empty string if GDB was |
| unable to find the mapped file. |
| |
| If no build-id can be found for FILENAME then GDB will return a pair |
| containing nullptr (for the build-id) and an empty string for the file |
| name. */ |
| |
| std::optional <core_target_mapped_file_info> |
| mapped_file_info::lookup (const char *filename, |
| const std::optional<CORE_ADDR> &addr) |
| { |
| if (filename != nullptr) |
| { |
| /* If there's a matching entry in m_filename_to_build_id_map then the |
| associated build-id will not be nullptr, and can be used to |
| validate that FILENAME is correct. */ |
| auto it = m_filename_to_build_id_map.find (filename); |
| if (it != m_filename_to_build_id_map.end ()) |
| return make_result (it->second); |
| } |
| |
| if (addr.has_value ()) |
| { |
| /* On the first lookup, sort the address_to_build_id_list. */ |
| if (!m_address_to_build_id_list_sorted) |
| { |
| std::sort (m_address_to_build_id_list.begin (), |
| m_address_to_build_id_list.end (), |
| [] (const mem_range_and_build_id &a, |
| const mem_range_and_build_id &b) { |
| return a.range < b.range; |
| }); |
| m_address_to_build_id_list_sorted = true; |
| } |
| |
| /* Look for the first entry whose range's start address is not less |
| than, or equal too, the address ADDR. If we find such an entry, |
| then the previous entry's range might contain ADDR. If it does |
| then that previous entry's build-id can be used. */ |
| auto it = std::lower_bound |
| (m_address_to_build_id_list.begin (), |
| m_address_to_build_id_list.end (), |
| *addr, |
| [] (const mem_range_and_build_id &a, |
| const CORE_ADDR &b) { |
| return a.range.start <= b; |
| }); |
| |
| if (it != m_address_to_build_id_list.begin ()) |
| { |
| --it; |
| |
| if (it->range.contains (*addr)) |
| return make_result (it->build_id); |
| } |
| } |
| |
| if (filename != nullptr) |
| { |
| /* If the basename of FILENAME appears in m_soname_to_build_id_map |
| then when the mapped files were processed, we saw a file with a |
| DT_SONAME attribute corresponding to FILENAME, use that build-id |
| to validate FILENAME. |
| |
| However, the build-id in this map might be nullptr if we saw |
| multiple mapped files with the same DT_SONAME attribute (though |
| this should be pretty rare). */ |
| auto it |
| = m_soname_to_build_id_map.find (lbasename (filename)); |
| if (it != m_soname_to_build_id_map.end () |
| && it->second != nullptr) |
| return make_result (it->second); |
| } |
| |
| return {}; |
| } |
| |
| /* See gdbcore.h. */ |
| |
| std::optional <core_target_mapped_file_info> |
| core_target_find_mapped_file (const char *filename, |
| std::optional<CORE_ADDR> addr) |
| { |
| core_target *targ = get_current_core_target (); |
| if (targ == nullptr || current_program_space->cbfd.get () == nullptr) |
| return {}; |
| |
| return targ->lookup_mapped_file_info (filename, addr); |
| } |
| |
| void _initialize_corelow (); |
| void |
| _initialize_corelow () |
| { |
| add_target (core_target_info, core_target_open, |
| deprecated_filename_completer); |
| add_cmd ("core-file-backed-mappings", class_maintenance, |
| maintenance_print_core_file_backed_mappings, |
| _("Print core file's file-backed mappings."), |
| &maintenanceprintlist); |
| } |