backend.h - platform/external/ltrace - Git at Google

 /*
  * This file is part of ltrace.
  * Copyright (C) 2012,2013 Petr Machata, Red Hat Inc.
  *
  * 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 2 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, write to the Free Software
  * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA
  * 02110-1301 USA
  */

 #ifndef BACKEND_H
 #define BACKEND_H

 #include "forward.h"
 #include "sysdep.h"

 #include <gelf.h>

 enum process_status {
 	PS_INVALID,	/* Failure.  */
 	PS_STOP,	/* Job-control stop.  */
 	PS_TRACING_STOP,
 	PS_SLEEPING,
 	PS_ZOMBIE,
 	PS_OTHER,	/* Necessary other states can be added as needed.  */
 };

 /*
  * This file contains documentation of back end interface.  Some of
  * these may be implemented on an OS level (i.e. they are the same
  * e.g. on all Linux architectures), some may differ per architecture
  * on the same OS (e.g. a way to insert a breakpoint into the process
  * image is a likely candidate).
  */

 /* Convert a PID to a path to the corresponding binary.  */
 char *pid2name(pid_t pid);

 /* Given a PID, find a leader of thread group.  */
 pid_t process_leader(pid_t pid);

 /* Given a PID of leader thread, fill in PIDs of all the tasks.  The
  * function will initialize the pointer *RET_TASKS to a
  * newly-allocated array, and will store number of elements in that
  * array to *RET_N.  You have to free that buffer when you don't need
  * it anymore.  */
 int process_tasks(pid_t pid, pid_t **ret_tasks, size_t *ret_n);

 /* Answer whether the process PID is stopped.  Returns 0 when not
  * stopped, 1 when stopped, or -1 when there was an error.  */
 int process_stopped(pid_t pid);

 /* Answer a status of the task PID.  See enum process_status.  */
 enum process_status process_status(pid_t pid);

 /* Wait for PID to be ready for tracing.  */
 int wait_for_proc(pid_t pid);

 /* Send a signal SIG to the task PID.  */
 int task_kill(pid_t pid, int sig);

 /* Called after PID is attached, but before it is continued.  */
 void trace_set_options(struct process *proc);

 /* Called after ltrace forks.  Should attach the newly created child,
  * in whose context this function is called.  */
 void trace_me(void);

 /* Called when ltrace needs to attach to PID, such as when it attaches
  * to a running process, whose PID is given on the command line.  */
 int trace_pid(pid_t pid);

 /* Stop tracing PID.  */
 void untrace_pid(pid_t pid);

 /* The back end may need to store arbitrary data to a process.  This
  * is a place where it can initialize PROC->arch_dep.  XXX this should
  * be dropped in favor of arhc_process_init on pmachata/libs.  */
 void get_arch_dep(struct process *proc);

 /* Return current instruction pointer of PROC.
  *
  * XXX note that the IP must fit into an arch pointer.  This prevents
  * us to use 32-bit ltrace to trace 64-bit process, even on arches
  * that would otherwise support this.  Above we have a definition of
  * arch_addr_t.  This should be converted to an integral type and
  * used for target addresses throughout.  */
 void *get_instruction_pointer(struct process *proc);

 /* Set instruction pointer of PROC to ADDR.  XXX see above.  */
 void set_instruction_pointer(struct process *proc, void *addr);

 /* Return current stack pointer of PROC.  XXX see above.  */
 void *get_stack_pointer(struct process *proc);

 /* Find and return caller address, i.e. the address where the current
  * function returns.  */
 void *get_return_addr(struct process *proc, void *stack_pointer);

 /* Enable breakpoint SBP in process PROC.  */
 void enable_breakpoint(struct process *proc, struct breakpoint *sbp);

 /* Disable breakpoint SBP in process PROC.  */
 void disable_breakpoint(struct process *proc, struct breakpoint *sbp);

 /* Determine whether the event that we have just seen (and that is
  * recorded in STATUS) was a syscall.  If it was, return 1.  If it was
  * a return from syscall, return 2.  In both cases, set *SYSNUM to the
  * number of said syscall.  If it wasn't a syscall, return 0.  If
  * there was an error, return -1.  */
 int syscall_p(struct process *proc, int status, int *sysnum);

 /* Continue execution of the process with given PID.  */
 void continue_process(pid_t pid);

 /* Called after we received a signal SIGNUM.  Should do whatever
  * book-keeping is necessary and continue the process if
  * necessary.  */
 void continue_after_signal(pid_t pid, int signum);

 /* Called after we received a system call SYSNUM.  RET_P is 0 if this
  * is system call, otherwise it's return from a system call.  The
  * callback should do whatever book-keeping is necessary and continue
  * the process if necessary.  */
 void continue_after_syscall(struct process *proc, int sysnum, int ret_p);

 /* Called after we hit a breakpoint SBP.  Should do whatever
  * book-keeping is necessary and then continue the process.  */
 void continue_after_breakpoint(struct process *proc, struct breakpoint *sbp);

 /* Called after we received a vfork.  Should do whatever book-keeping
  * is necessary and continue the process if necessary.  N.B. right
  * now, with Linux/GNU the only back end, this is not necessary.  I
  * imagine other systems may be different.  */
 void continue_after_vfork(struct process *proc);

 /* Called after the process exec's.  Should do whatever book-keeping
  * is necessary and then continue the process.  */
 void continue_after_exec(struct process *proc);

 /* Called when trace_me or primary trace_pid fail.  This may plug in
  * any platform-specific knowledge of why it could be so.  */
 void trace_fail_warning(pid_t pid);

 /* A pair of functions called to initiate a detachment request when
  * ltrace is about to exit.  Their job is to undo any effects that
  * tracing had and eventually detach process, perhaps by way of
  * installing a process handler.
  *
  * OS_LTRACE_EXITING_SIGHANDLER is called from a signal handler
  * context right after the signal was captured.  It returns 1 if the
  * request was handled or 0 if it wasn't.
  *
  * If the call to OS_LTRACE_EXITING_SIGHANDLER didn't handle the
  * request, OS_LTRACE_EXITING is called when the next event is
  * generated.  Therefore it's called in "safe" context, without
  * re-entrancy concerns, but it's only called after an even is
  * generated.  */
 int os_ltrace_exiting_sighandler(void);
 void os_ltrace_exiting(void);

 /* Should copy COUNT bytes from address ADDR of process PROC to local
  * buffer BUF.  */
 size_t umovebytes(struct process *proc, arch_addr_t addr,
 		  void *buf, size_t count);

 /* Find out an address of symbol SYM in process PROC, and return.
  * Returning NULL delays breakpoint insertion and enables heaps of
  * arch-specific black magic that we should clean up some day.
  *
  * XXX the same points as for get_instruction_pointer apply. */
 void *sym2addr(struct process *proc, struct library_symbol *sym);

 /* Obtain address of PLT entry corresponding to relocation RELA in
  * file LTE.  This is NDX-th PLT entry in the file.
  *
  * XXX should this return arch_addr_t?  */
 GElf_Addr arch_plt_sym_val(struct ltelf *lte, size_t ndx, GElf_Rela *rela);

 /* Called at some point after we have attached to PROC.  This callback
  * should insert an introspection breakpoint for handling dynamic
  * linker library loads.  */
 int linkmap_init(struct process *proc, arch_addr_t dyn_addr);

 /* This should produce and return the next event of one of the traced
  * processes.  The returned pointer will not be freed by the core and
  * should be either statically allocated, or the management should be
  * done some other way.  */
 struct Event *next_event(void);

 /* Called when process PROC was removed.  */
 void process_removed(struct process *proc);

 /* This should extract entry point address and interpreter (dynamic
  * linker) bias if possible.  Returns 0 if there were no errors, -1
  * otherwise.  Sets *ENTRYP and *INTERP_BIASP to non-zero values if
  * the corresponding value is known, or zero otherwise; this is not
  * done for pointers that are NULL.  */
 int process_get_entry(struct process *proc,
 		      arch_addr_t *entryp,
 		      arch_addr_t *interp_biasp);


 /* Optional callbacks
  *
  * Some callbacks are only available if backend (arch.h) has a certain
  * define.  If such a define is not present, default implementation
  * (most often doing nothing at all) us used instead.  This is used
  * for gradual extensions of ltrace, so that backends that are not
  * fully up to date, or that don't need certain functionality, keep
  * working, while other backends take advantage of the optional
  * features.  */

 /* The following callbacks have to be implemented in backend if arch.h
  * defines ARCH_HAVE_LTELF_DATA.  Those are used to init and destroy
  * LTE->arch.  arch_elf_init returns 0 on success or a negative value
  * on failure.  */
 int arch_elf_init(struct ltelf *lte, struct library *lib);
 void arch_elf_destroy(struct ltelf *lte);

 /* The following callbacks have to be implemented in OS backend if
  * os.h defines OS_HAVE_BREAKPOINT_DATA.  Those are used to init,
  * destroy, and clone SBP->os.  os_breakpoint_init and
  * os_breakpoint_clone return 0 on success or a negative value on
  * failure.  */
 int os_breakpoint_init(struct process *proc, struct breakpoint *sbp);
 void os_breakpoint_destroy(struct breakpoint *sbp);
 int os_breakpoint_clone(struct breakpoint *retp, struct breakpoint *sbp);

 /* The following callbacks have to be implemented in backend if arch.h
  * defines ARCH_HAVE_BREAKPOINT_DATA.  Those are used to init,
  * destroy, and clone SBP->arch.  arch_breakpoint_init and
  * arch_breakpoint_clone return 0 on success or a negative value on
  * failure.  */
 int arch_breakpoint_init(struct process *proc, struct breakpoint *sbp);
 void arch_breakpoint_destroy(struct breakpoint *sbp);
 int arch_breakpoint_clone(struct breakpoint *retp, struct breakpoint *sbp);

 /* The following callbacks have to be implemented in OS backend if
  * os.h defines OS_HAVE_LIBRARY_DATA.  Those are used to init, destroy
  * and clone LIB->os.  os_library_init and os_library_clone return 0
  * on success or a negative value on failure.  */
 int os_library_init(struct library *lib);
 void os_library_destroy(struct library *lib);
 int os_library_clone(struct library *retp, struct library *lib);

 /* The following callbacks have to be implemented in backend if arch.h
  * defines ARCH_HAVE_LIBRARY_DATA.  Those are used to init, destroy
  * and clone LIB->arch.  arch_library_init and arch_library_clone
  * return 0 on success or a negative value on failure.  */
 int arch_library_init(struct library *lib);
 void arch_library_destroy(struct library *lib);
 int arch_library_clone(struct library *retp, struct library *lib);

 /* The following callbacks have to be implemented in OS backend if
  * os.h defines OS_HAVE_LIBRARY_SYMBOL_DATA.  Those are used to init,
  * destroy and clone LIBSYM->os.  os_library_symbol_init and
  * os_library_symbol_clone return 0 on success or a negative value on
  * failure.  */
 int os_library_symbol_init(struct library_symbol *libsym);
 void os_library_symbol_destroy(struct library_symbol *libsym);
 int os_library_symbol_clone(struct library_symbol *retp,
 			    struct library_symbol *libsym);

 /* The following callbacks have to be implemented in backend if arch.h
  * defines ARCH_HAVE_LIBRARY_SYMBOL_DATA.  Those are used to init,
  * destroy and clone LIBSYM->arch.  arch_library_symbol_init and
  * arch_library_symbol_clone return 0 on success or a negative value
  * on failure.  */
 int arch_library_symbol_init(struct library_symbol *libsym);
 void arch_library_symbol_destroy(struct library_symbol *libsym);
 int arch_library_symbol_clone(struct library_symbol *retp,
 			      struct library_symbol *libsym);

 /* The following callbacks have to be implemented in OS backend if
  * os.h defines OS_HAVE_PROCESS_DATA.  The protocol is same as for,
  * respectively, arch_process_init, arch_process_destroy,
  * arch_process_clone and arch_process_exec.  */
 int os_process_init(struct process *proc);
 void os_process_destroy(struct process *proc);
 int os_process_clone(struct process *retp, struct process *proc);
 int os_process_exec(struct process *proc);

 /* The following callbacks have to be implemented in backend if arch.h
  * defines ARCH_HAVE_PROCESS_DATA.  Those are used to init, destroy
  * and clone PROC->arch.  arch_process_exec is called to update
  * PROC->arch in case that PROC underwent an exec.  See notes at
  * process_init, process_destroy, process_clone and process_exec in
  * proc.h.  */
 int arch_process_init(struct process *proc);
 void arch_process_destroy(struct process *proc);
 int arch_process_clone(struct process *retp, struct process *proc);
 int arch_process_exec(struct process *proc);

 /* The following callback has to be implemented in backend if arch.h
  * defines ARCH_HAVE_GET_SYM_INFO.
  *
  * This is called for every PLT relocation RELA in ELF file LTE (which
  * is named FILENAME), that ltrace is about to add.  The corresponding
  * PLT entry is for SYM_INDEX-th relocation in the file.  This call is
  * supposed to initialize SYM and RELA.  It returns 0 if there were no
  * errors and given symbol should be used, 1 if the symbol should not
  * be used, or a negative value if there were errors.  */
 int arch_get_sym_info(struct ltelf *lte, const char *filename, size_t sym_index,
 		      GElf_Rela *rela, GElf_Sym *sym);

 enum plt_status {
 	PLT_FAIL,
 	PLT_OK,
 	PLT_DEFAULT,
 };

 /* The following callback has to be implemented in OS backend if os.h
  * defines OS_HAVE_ADD_PLT_ENTRY.
  *
  * This is called for every PLT relocation R in ELF file LTE, that
  * ltrace is about to add to a library constructed in process PROC.
  * The corresponding PLT entry is for symbol called NAME, and it's
  * I-th relocation in the file.
  *
  * If this function returns PLT_DEFAULT, PLT address is obtained by
  * calling arch_plt_sym_val, and symbol is allocated.  If PLT_OK or
  * PLT_DEFAULT are returned, the chain of symbols passed back in RET
  * is added to library under construction.  */
 enum plt_status os_elf_add_plt_entry(struct process *proc, struct ltelf *lte,
 				     const char *name, GElf_Rela *rela,
 				     size_t i, struct library_symbol **ret);

 /* Like os_elf_add_plt_entry, but tied to ARCH_HAVE_ADD_PLT_ENTRY in
  * arch.h.  The arch callback is called first.  If it returns
  * PLT_DEFAULT, the os callback is called next.  */
 enum plt_status arch_elf_add_plt_entry(struct process *proc, struct ltelf *lte,
 				       const char *name, GElf_Rela *rela,
 				       size_t i, struct library_symbol **ret);

 /* The following callback has to be implemented in OS backend if os.h
  * defines OS_HAVE_ADD_FUNC_ENTRY.
  *
  * This is called for every symbol in ltrace is about to add to the
  * library constructed for LTE in process PROC.
  *
  * If this function returns PLT_DEFAULT, then if there is a
  * pre-existing symbol, its name may be updated if the newly-found
  * name is shorter.  Otherwise a new symbol is created.
  *
  * If PLT_OK or PLT_DEFAULT are returned, the chain of symbols passed
  * back in RET is added to library under construction.  */
 enum plt_status os_elf_add_func_entry(struct process *proc, struct ltelf *lte,
 				      const GElf_Sym *sym,
 				      arch_addr_t addr, const char *name,
 				      struct library_symbol **ret);

 /* Like os_elf_add_func_entry, but tied to ARCH_HAVE_ADD_FUNC_ENTRY in
  * arch.h.  The arch callback is called first.  If it returns
  * PLT_DEFAULT, the os callback is called next.  */
 enum plt_status arch_elf_add_func_entry(struct process *proc, struct ltelf *lte,
 					const GElf_Sym *sym,
 					arch_addr_t addr, const char *name,
 					struct library_symbol **ret);

 /* This callback needs to be implemented if arch.h defines
  * ARCH_HAVE_DYNLINK_DONE.  It is called after the dynamic linker is
  * done with the process start-up.  */
 void arch_dynlink_done(struct process *proc);

 /* This callback needs to be implemented if arch.h defines
  * ARCH_HAVE_SYMBOL_RET.  It is called after a traced call returns.  */
 void arch_symbol_ret(struct process *proc, struct library_symbol *libsym);


 /* This callback needs to be implemented if arch.h defines
  * ARCH_HAVE_FIND_DL_DEBUG.
  * It is called by generic code to find the address of the dynamic
  * linkers debug structure.
  * DYN_ADDR holds the address of the dynamic section.
  * If the debug area is found, return 0 and fill in the address in *RET.
  * If the debug area is not found, return a negative value.  */
 int arch_find_dl_debug(struct process *proc, arch_addr_t dyn_addr,
 		       arch_addr_t *ret);

 /* This is called to obtain a list of directories to search when
  * loading config files.  The callback sets *RETP to a pointer to the
  * first element of a NULL-terminated array of directory names.  It's
  * legitimate to set *RETP to NULL to indicate there are no
  * directories.  The function returns 0 on success or a negative value
  * on a failure.
  *
  * If PRIVATE is set, the list in *RETP should contain only user's own
  * directories (presumably under HOME if there's any such thing on the
  * given OS).  Otherwise only system directories should be reported.
  *
  * The directories don't have to exist.  Directories passed in -F are
  * handled separately by the caller and this callback shouldn't
  * concern itself with it.  */
 int os_get_config_dirs(int private, const char ***retp);

 /* This is called to obtain list of legacy config files to import, if
  * any.  A reference to initialized vector of char* is passed in.
  *
  * This returns 0 on success, in which case strings from *RETP (if
  * any) are interpreted as files names.  These files belong to the
  * caller and will eventually be freed.
  *
  * Returns a negative value for failure, in which case *RETP contents
  * are not consulted in any way.  */
 int os_get_ltrace_conf_filenames(struct vect *retp);

 /* If arch.h defines ARCH_HAVE_FETCH_ARG, the following callbacks have
  * to be implemented: arch_fetch_arg_init, arch_fetch_arg_clone,
  * arch_fetch_arg_done, arch_fetch_arg_next and arch_fetch_retval.
  * See fetch.h for details.  */

 /* If arch.h defines both ARCH_HAVE_FETCH_ARG and
  * ARCH_HAVE_FETCH_PACK, the following callbacks have to be
  * implemented: arch_fetch_param_pack_start,
  * arch_fetch_param_pack_end.  See fetch.h for details.  */

 enum sw_singlestep_status {
 	SWS_FAIL,
 	SWS_OK,
 	SWS_HW,
 };
 struct sw_singlestep_data;

 /* The following callback has to be implemented in backend if arch.h
  * defines ARCH_HAVE_SW_SINGLESTEP.
  *
  * This is called before the OS backend requests hardware singlestep.
  * arch_sw_singlestep should consider whether a singlestep needs to be
  * done in software.  If not, it returns SWS_HW.  Otherwise it needs
  * to add one or several breakpoints by calling ADD_CB.  When it is
  * done, it continues the process as appropriate, and answers either
  * SWS_OK, or SWS_FAIL, depending on how it went.
  *
  * PROC is the process that should perform the singlestep, BP the
  * breakpoint that we are singlestepping over.  ADD_CB is a callback
  * to request adding breakpoints that should trap the process after
  * it's continued.  The arguments to ADD_CB are the address where the
  * breakpoint should be added, and DATA.  ADD_CB returns 0 on success
  * or a negative value on failure.  It is expected that
  * arch_sw_singlestep returns SWS_FAIL if ADD_CB returns error.  */
 enum sw_singlestep_status arch_sw_singlestep(struct process *proc,
 					     struct breakpoint *bp,
 					     int (*add_cb)(arch_addr_t addr,
 						   struct sw_singlestep_data *),
 					     struct sw_singlestep_data *data);

 #endif /* BACKEND_H */
	/*
	* This file is part of ltrace.
	* Copyright (C) 2012,2013 Petr Machata, Red Hat Inc.
	*
	* 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 2 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, write to the Free Software
	* Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA
	* 02110-1301 USA
	*/

	#ifndef BACKEND_H
	#define BACKEND_H

	#include "forward.h"
	#include "sysdep.h"

	#include <gelf.h>

	enum process_status {
	PS_INVALID, /* Failure. */
	PS_STOP, /* Job-control stop. */
	PS_TRACING_STOP,
	PS_SLEEPING,
	PS_ZOMBIE,
	PS_OTHER, /* Necessary other states can be added as needed. */
	};

	/*
	* This file contains documentation of back end interface. Some of
	* these may be implemented on an OS level (i.e. they are the same
	* e.g. on all Linux architectures), some may differ per architecture
	* on the same OS (e.g. a way to insert a breakpoint into the process
	* image is a likely candidate).
	*/

	/* Convert a PID to a path to the corresponding binary. */
	char *pid2name(pid_t pid);

	/* Given a PID, find a leader of thread group. */
	pid_t process_leader(pid_t pid);

	/* Given a PID of leader thread, fill in PIDs of all the tasks. The
	* function will initialize the pointer *RET_TASKS to a
	* newly-allocated array, and will store number of elements in that
	* array to *RET_N. You have to free that buffer when you don't need
	* it anymore. */
	int process_tasks(pid_t pid, pid_t *ret_tasks, size_t ret_n);

	/* Answer whether the process PID is stopped. Returns 0 when not
	* stopped, 1 when stopped, or -1 when there was an error. */
	int process_stopped(pid_t pid);

	/* Answer a status of the task PID. See enum process_status. */
	enum process_status process_status(pid_t pid);

	/* Wait for PID to be ready for tracing. */
	int wait_for_proc(pid_t pid);

	/* Send a signal SIG to the task PID. */
	int task_kill(pid_t pid, int sig);

	/* Called after PID is attached, but before it is continued. */
	void trace_set_options(struct process *proc);

	/* Called after ltrace forks. Should attach the newly created child,
	* in whose context this function is called. */
	void trace_me(void);

	/* Called when ltrace needs to attach to PID, such as when it attaches
	* to a running process, whose PID is given on the command line. */
	int trace_pid(pid_t pid);

	/* Stop tracing PID. */
	void untrace_pid(pid_t pid);

	/* The back end may need to store arbitrary data to a process. This
	* is a place where it can initialize PROC->arch_dep. XXX this should
	* be dropped in favor of arhc_process_init on pmachata/libs. */
	void get_arch_dep(struct process *proc);

	/* Return current instruction pointer of PROC.
	*
	* XXX note that the IP must fit into an arch pointer. This prevents
	* us to use 32-bit ltrace to trace 64-bit process, even on arches
	* that would otherwise support this. Above we have a definition of
	* arch_addr_t. This should be converted to an integral type and
	* used for target addresses throughout. */
	void get_instruction_pointer(struct process proc);

	/* Set instruction pointer of PROC to ADDR. XXX see above. */
	void set_instruction_pointer(struct process proc, void addr);

	/* Return current stack pointer of PROC. XXX see above. */
	void get_stack_pointer(struct process proc);

	/* Find and return caller address, i.e. the address where the current
	* function returns. */
	void get_return_addr(struct process proc, void *stack_pointer);

	/* Enable breakpoint SBP in process PROC. */
	void enable_breakpoint(struct process proc, struct breakpoint sbp);

	/* Disable breakpoint SBP in process PROC. */
	void disable_breakpoint(struct process proc, struct breakpoint sbp);

	/* Determine whether the event that we have just seen (and that is
	* recorded in STATUS) was a syscall. If it was, return 1. If it was
	* a return from syscall, return 2. In both cases, set *SYSNUM to the
	* number of said syscall. If it wasn't a syscall, return 0. If
	* there was an error, return -1. */
	int syscall_p(struct process proc, int status, int sysnum);

	/* Continue execution of the process with given PID. */
	void continue_process(pid_t pid);

	/* Called after we received a signal SIGNUM. Should do whatever
	* book-keeping is necessary and continue the process if
	* necessary. */
	void continue_after_signal(pid_t pid, int signum);

	/* Called after we received a system call SYSNUM. RET_P is 0 if this
	* is system call, otherwise it's return from a system call. The
	* callback should do whatever book-keeping is necessary and continue
	* the process if necessary. */
	void continue_after_syscall(struct process *proc, int sysnum, int ret_p);

	/* Called after we hit a breakpoint SBP. Should do whatever
	* book-keeping is necessary and then continue the process. */
	void continue_after_breakpoint(struct process proc, struct breakpoint sbp);

	/* Called after we received a vfork. Should do whatever book-keeping
	* is necessary and continue the process if necessary. N.B. right
	* now, with Linux/GNU the only back end, this is not necessary. I
	* imagine other systems may be different. */
	void continue_after_vfork(struct process *proc);

	/* Called after the process exec's. Should do whatever book-keeping
	* is necessary and then continue the process. */
	void continue_after_exec(struct process *proc);

	/* Called when trace_me or primary trace_pid fail. This may plug in
	* any platform-specific knowledge of why it could be so. */
	void trace_fail_warning(pid_t pid);

	/* A pair of functions called to initiate a detachment request when
	* ltrace is about to exit. Their job is to undo any effects that
	* tracing had and eventually detach process, perhaps by way of
	* installing a process handler.
	*
	* OS_LTRACE_EXITING_SIGHANDLER is called from a signal handler
	* context right after the signal was captured. It returns 1 if the
	* request was handled or 0 if it wasn't.
	*
	* If the call to OS_LTRACE_EXITING_SIGHANDLER didn't handle the
	* request, OS_LTRACE_EXITING is called when the next event is
	* generated. Therefore it's called in "safe" context, without
	* re-entrancy concerns, but it's only called after an even is
	* generated. */
	int os_ltrace_exiting_sighandler(void);
	void os_ltrace_exiting(void);

	/* Should copy COUNT bytes from address ADDR of process PROC to local
	* buffer BUF. */
	size_t umovebytes(struct process *proc, arch_addr_t addr,
	void *buf, size_t count);

	/* Find out an address of symbol SYM in process PROC, and return.
	* Returning NULL delays breakpoint insertion and enables heaps of
	* arch-specific black magic that we should clean up some day.
	*
	* XXX the same points as for get_instruction_pointer apply. */
	void sym2addr(struct process proc, struct library_symbol *sym);

	/* Obtain address of PLT entry corresponding to relocation RELA in
	* file LTE. This is NDX-th PLT entry in the file.
	*
	* XXX should this return arch_addr_t? */
	GElf_Addr arch_plt_sym_val(struct ltelf lte, size_t ndx, GElf_Rela rela);

	/* Called at some point after we have attached to PROC. This callback
	* should insert an introspection breakpoint for handling dynamic
	* linker library loads. */
	int linkmap_init(struct process *proc, arch_addr_t dyn_addr);

	/* This should produce and return the next event of one of the traced
	* processes. The returned pointer will not be freed by the core and
	* should be either statically allocated, or the management should be
	* done some other way. */
	struct Event *next_event(void);

	/* Called when process PROC was removed. */
	void process_removed(struct process *proc);

	/* This should extract entry point address and interpreter (dynamic
	* linker) bias if possible. Returns 0 if there were no errors, -1
	* otherwise. Sets ENTRYP and INTERP_BIASP to non-zero values if
	* the corresponding value is known, or zero otherwise; this is not
	* done for pointers that are NULL. */
	int process_get_entry(struct process *proc,
	arch_addr_t *entryp,
	arch_addr_t *interp_biasp);


	/* Optional callbacks
	*
	* Some callbacks are only available if backend (arch.h) has a certain
	* define. If such a define is not present, default implementation
	* (most often doing nothing at all) us used instead. This is used
	* for gradual extensions of ltrace, so that backends that are not
	* fully up to date, or that don't need certain functionality, keep
	* working, while other backends take advantage of the optional
	* features. */

	/* The following callbacks have to be implemented in backend if arch.h
	* defines ARCH_HAVE_LTELF_DATA. Those are used to init and destroy
	* LTE->arch. arch_elf_init returns 0 on success or a negative value
	* on failure. */
	int arch_elf_init(struct ltelf lte, struct library lib);
	void arch_elf_destroy(struct ltelf *lte);

	/* The following callbacks have to be implemented in OS backend if
	* os.h defines OS_HAVE_BREAKPOINT_DATA. Those are used to init,
	* destroy, and clone SBP->os. os_breakpoint_init and
	* os_breakpoint_clone return 0 on success or a negative value on
	* failure. */
	int os_breakpoint_init(struct process proc, struct breakpoint sbp);
	void os_breakpoint_destroy(struct breakpoint *sbp);
	int os_breakpoint_clone(struct breakpoint retp, struct breakpoint sbp);

	/* The following callbacks have to be implemented in backend if arch.h
	* defines ARCH_HAVE_BREAKPOINT_DATA. Those are used to init,
	* destroy, and clone SBP->arch. arch_breakpoint_init and
	* arch_breakpoint_clone return 0 on success or a negative value on
	* failure. */
	int arch_breakpoint_init(struct process proc, struct breakpoint sbp);
	void arch_breakpoint_destroy(struct breakpoint *sbp);
	int arch_breakpoint_clone(struct breakpoint retp, struct breakpoint sbp);

	/* The following callbacks have to be implemented in OS backend if
	* os.h defines OS_HAVE_LIBRARY_DATA. Those are used to init, destroy
	* and clone LIB->os. os_library_init and os_library_clone return 0
	* on success or a negative value on failure. */
	int os_library_init(struct library *lib);
	void os_library_destroy(struct library *lib);
	int os_library_clone(struct library retp, struct library lib);

	/* The following callbacks have to be implemented in backend if arch.h
	* defines ARCH_HAVE_LIBRARY_DATA. Those are used to init, destroy
	* and clone LIB->arch. arch_library_init and arch_library_clone
	* return 0 on success or a negative value on failure. */
	int arch_library_init(struct library *lib);
	void arch_library_destroy(struct library *lib);
	int arch_library_clone(struct library retp, struct library lib);

	/* The following callbacks have to be implemented in OS backend if
	* os.h defines OS_HAVE_LIBRARY_SYMBOL_DATA. Those are used to init,
	* destroy and clone LIBSYM->os. os_library_symbol_init and
	* os_library_symbol_clone return 0 on success or a negative value on
	* failure. */
	int os_library_symbol_init(struct library_symbol *libsym);
	void os_library_symbol_destroy(struct library_symbol *libsym);
	int os_library_symbol_clone(struct library_symbol *retp,
	struct library_symbol *libsym);

	/* The following callbacks have to be implemented in backend if arch.h
	* defines ARCH_HAVE_LIBRARY_SYMBOL_DATA. Those are used to init,
	* destroy and clone LIBSYM->arch. arch_library_symbol_init and
	* arch_library_symbol_clone return 0 on success or a negative value
	* on failure. */
	int arch_library_symbol_init(struct library_symbol *libsym);
	void arch_library_symbol_destroy(struct library_symbol *libsym);
	int arch_library_symbol_clone(struct library_symbol *retp,
	struct library_symbol *libsym);

	/* The following callbacks have to be implemented in OS backend if
	* os.h defines OS_HAVE_PROCESS_DATA. The protocol is same as for,
	* respectively, arch_process_init, arch_process_destroy,
	* arch_process_clone and arch_process_exec. */
	int os_process_init(struct process *proc);
	void os_process_destroy(struct process *proc);
	int os_process_clone(struct process retp, struct process proc);
	int os_process_exec(struct process *proc);

	/* The following callbacks have to be implemented in backend if arch.h
	* defines ARCH_HAVE_PROCESS_DATA. Those are used to init, destroy
	* and clone PROC->arch. arch_process_exec is called to update
	* PROC->arch in case that PROC underwent an exec. See notes at
	* process_init, process_destroy, process_clone and process_exec in
	* proc.h. */
	int arch_process_init(struct process *proc);
	void arch_process_destroy(struct process *proc);
	int arch_process_clone(struct process retp, struct process proc);
	int arch_process_exec(struct process *proc);

	/* The following callback has to be implemented in backend if arch.h
	* defines ARCH_HAVE_GET_SYM_INFO.
	*
	* This is called for every PLT relocation RELA in ELF file LTE (which
	* is named FILENAME), that ltrace is about to add. The corresponding
	* PLT entry is for SYM_INDEX-th relocation in the file. This call is
	* supposed to initialize SYM and RELA. It returns 0 if there were no
	* errors and given symbol should be used, 1 if the symbol should not
	* be used, or a negative value if there were errors. */
	int arch_get_sym_info(struct ltelf lte, const char filename, size_t sym_index,
	GElf_Rela rela, GElf_Sym sym);

	enum plt_status {
	PLT_FAIL,
	PLT_OK,
	PLT_DEFAULT,
	};

	/* The following callback has to be implemented in OS backend if os.h
	* defines OS_HAVE_ADD_PLT_ENTRY.
	*
	* This is called for every PLT relocation R in ELF file LTE, that
	* ltrace is about to add to a library constructed in process PROC.
	* The corresponding PLT entry is for symbol called NAME, and it's
	* I-th relocation in the file.
	*
	* If this function returns PLT_DEFAULT, PLT address is obtained by
	* calling arch_plt_sym_val, and symbol is allocated. If PLT_OK or
	* PLT_DEFAULT are returned, the chain of symbols passed back in RET
	* is added to library under construction. */
	enum plt_status os_elf_add_plt_entry(struct process proc, struct ltelf lte,
	const char name, GElf_Rela rela,
	size_t i, struct library_symbol **ret);

	/* Like os_elf_add_plt_entry, but tied to ARCH_HAVE_ADD_PLT_ENTRY in
	* arch.h. The arch callback is called first. If it returns
	* PLT_DEFAULT, the os callback is called next. */
	enum plt_status arch_elf_add_plt_entry(struct process proc, struct ltelf lte,
	const char name, GElf_Rela rela,
	size_t i, struct library_symbol **ret);

	/* The following callback has to be implemented in OS backend if os.h
	* defines OS_HAVE_ADD_FUNC_ENTRY.
	*
	* This is called for every symbol in ltrace is about to add to the
	* library constructed for LTE in process PROC.
	*
	* If this function returns PLT_DEFAULT, then if there is a
	* pre-existing symbol, its name may be updated if the newly-found
	* name is shorter. Otherwise a new symbol is created.
	*
	* If PLT_OK or PLT_DEFAULT are returned, the chain of symbols passed
	* back in RET is added to library under construction. */
	enum plt_status os_elf_add_func_entry(struct process proc, struct ltelf lte,
	const GElf_Sym *sym,
	arch_addr_t addr, const char *name,
	struct library_symbol **ret);

	/* Like os_elf_add_func_entry, but tied to ARCH_HAVE_ADD_FUNC_ENTRY in
	* arch.h. The arch callback is called first. If it returns
	* PLT_DEFAULT, the os callback is called next. */
	enum plt_status arch_elf_add_func_entry(struct process proc, struct ltelf lte,
	const GElf_Sym *sym,
	arch_addr_t addr, const char *name,
	struct library_symbol **ret);

	/* This callback needs to be implemented if arch.h defines
	* ARCH_HAVE_DYNLINK_DONE. It is called after the dynamic linker is
	* done with the process start-up. */
	void arch_dynlink_done(struct process *proc);

	/* This callback needs to be implemented if arch.h defines
	* ARCH_HAVE_SYMBOL_RET. It is called after a traced call returns. */
	void arch_symbol_ret(struct process proc, struct library_symbol libsym);


	/* This callback needs to be implemented if arch.h defines
	* ARCH_HAVE_FIND_DL_DEBUG.
	* It is called by generic code to find the address of the dynamic
	* linkers debug structure.
	* DYN_ADDR holds the address of the dynamic section.
	* If the debug area is found, return 0 and fill in the address in *RET.
	* If the debug area is not found, return a negative value. */
	int arch_find_dl_debug(struct process *proc, arch_addr_t dyn_addr,
	arch_addr_t *ret);

	/* This is called to obtain a list of directories to search when
	* loading config files. The callback sets *RETP to a pointer to the
	* first element of a NULL-terminated array of directory names. It's
	* legitimate to set *RETP to NULL to indicate there are no
	* directories. The function returns 0 on success or a negative value
	* on a failure.
	*
	* If PRIVATE is set, the list in *RETP should contain only user's own
	* directories (presumably under HOME if there's any such thing on the
	* given OS). Otherwise only system directories should be reported.
	*
	* The directories don't have to exist. Directories passed in -F are
	* handled separately by the caller and this callback shouldn't
	* concern itself with it. */
	int os_get_config_dirs(int private, const char ***retp);

	/* This is called to obtain list of legacy config files to import, if
	* any. A reference to initialized vector of char* is passed in.
	*
	* This returns 0 on success, in which case strings from *RETP (if
	* any) are interpreted as files names. These files belong to the
	* caller and will eventually be freed.
	*
	* Returns a negative value for failure, in which case *RETP contents
	* are not consulted in any way. */
	int os_get_ltrace_conf_filenames(struct vect *retp);

	/* If arch.h defines ARCH_HAVE_FETCH_ARG, the following callbacks have
	* to be implemented: arch_fetch_arg_init, arch_fetch_arg_clone,
	* arch_fetch_arg_done, arch_fetch_arg_next and arch_fetch_retval.
	* See fetch.h for details. */

	/* If arch.h defines both ARCH_HAVE_FETCH_ARG and
	* ARCH_HAVE_FETCH_PACK, the following callbacks have to be
	* implemented: arch_fetch_param_pack_start,
	* arch_fetch_param_pack_end. See fetch.h for details. */

	enum sw_singlestep_status {
	SWS_FAIL,
	SWS_OK,
	SWS_HW,
	};
	struct sw_singlestep_data;

	/* The following callback has to be implemented in backend if arch.h
	* defines ARCH_HAVE_SW_SINGLESTEP.
	*
	* This is called before the OS backend requests hardware singlestep.
	* arch_sw_singlestep should consider whether a singlestep needs to be
	* done in software. If not, it returns SWS_HW. Otherwise it needs
	* to add one or several breakpoints by calling ADD_CB. When it is
	* done, it continues the process as appropriate, and answers either
	* SWS_OK, or SWS_FAIL, depending on how it went.
	*
	* PROC is the process that should perform the singlestep, BP the
	* breakpoint that we are singlestepping over. ADD_CB is a callback
	* to request adding breakpoints that should trap the process after
	* it's continued. The arguments to ADD_CB are the address where the
	* breakpoint should be added, and DATA. ADD_CB returns 0 on success
	* or a negative value on failure. It is expected that
	* arch_sw_singlestep returns SWS_FAIL if ADD_CB returns error. */
	enum sw_singlestep_status arch_sw_singlestep(struct process *proc,
	struct breakpoint *bp,
	int (*add_cb)(arch_addr_t addr,
	struct sw_singlestep_data *),
	struct sw_singlestep_data *data);

	#endif /* BACKEND_H */