| |
| /*--------------------------------------------------------------------*/ |
| /*--- The core/tool interface. pub_tool_tooliface.h ---*/ |
| /*--------------------------------------------------------------------*/ |
| |
| /* |
| This file is part of Valgrind, a dynamic binary instrumentation |
| framework. |
| |
| Copyright (C) 2000-2012 Julian Seward |
| jseward@acm.org |
| |
| 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., 59 Temple Place, Suite 330, Boston, MA |
| 02111-1307, USA. |
| |
| The GNU General Public License is contained in the file COPYING. |
| */ |
| |
| #ifndef __PUB_TOOL_TOOLIFACE_H |
| #define __PUB_TOOL_TOOLIFACE_H |
| |
| #include "pub_tool_errormgr.h" // for Error, Supp |
| #include "libvex.h" // for all Vex stuff |
| |
| /* ------------------------------------------------------------------ */ |
| /* The interface version */ |
| |
| /* Initialise tool. Must do the following: |
| - initialise the `details' struct, via the VG_(details_*)() functions |
| - register the basic tool functions, via VG_(basic_tool_funcs)(). |
| May do the following: |
| - initialise the `needs' struct to indicate certain requirements, via |
| the VG_(needs_*)() functions |
| - any other tool-specific initialisation |
| */ |
| extern void (*VG_(tl_pre_clo_init)) ( void ); |
| |
| /* Every tool must include this macro somewhere, exactly once. The |
| interface version is no longer relevant, but we kept the same name |
| to avoid requiring changes to tools. |
| */ |
| #define VG_DETERMINE_INTERFACE_VERSION(pre_clo_init) \ |
| void (*VG_(tl_pre_clo_init)) ( void ) = pre_clo_init; |
| |
| /* ------------------------------------------------------------------ */ |
| /* Basic tool functions */ |
| |
| /* The tool_instrument function is passed as a callback to |
| LibVEX_Translate. VgCallbackClosure carries additional info |
| which the instrumenter might like to know, but which is opaque to |
| Vex. |
| */ |
| typedef |
| struct { |
| Addr64 nraddr; /* non-redirected guest address */ |
| Addr64 readdr; /* redirected guest address */ |
| ThreadId tid; /* tid requesting translation */ |
| } |
| VgCallbackClosure; |
| |
| extern void VG_(basic_tool_funcs)( |
| // Do any initialisation that can only be done after command line |
| // processing. |
| void (*post_clo_init)(void), |
| |
| // Instrument a basic block. Must be a true function, ie. the same |
| // input always results in the same output, because basic blocks |
| // can be retranslated, unless you're doing something really |
| // strange. Anyway, the arguments. Mostly they are straightforward |
| // except for the distinction between redirected and non-redirected |
| // guest code addresses, which is important to understand. |
| // |
| // VgCallBackClosure* closure contains extra arguments passed |
| // from Valgrind to the instrumenter, which Vex doesn't know about. |
| // You are free to look inside this structure. |
| // |
| // * closure->tid is the ThreadId of the thread requesting the |
| // translation. Not sure why this is here; perhaps callgrind |
| // uses it. |
| // |
| // * closure->nraddr is the non-redirected guest address of the |
| // start of the translation. In other words, the translation is |
| // being constructed because the guest program jumped to |
| // closure->nraddr but no translation of it was found. |
| // |
| // * closure->readdr is the redirected guest address, from which |
| // the translation was really made. |
| // |
| // To clarify this, consider what happens when, in Memcheck, the |
| // first call to malloc() happens. The guest program will be |
| // trying to jump to malloc() in libc; hence ->nraddr will contain |
| // that address. However, Memcheck intercepts and replaces |
| // malloc, hence ->readdr will be the address of Memcheck's |
| // malloc replacement in |
| // coregrind/m_replacemalloc/vg_replacemalloc.c. It follows |
| // that the first IMark in the translation will be labelled as |
| // from ->readdr rather than ->nraddr. |
| // |
| // Since most functions are not redirected, the majority of the |
| // time ->nraddr will be the same as ->readdr. However, you |
| // cannot assume this: if your tool has metadata associated |
| // with code addresses it will get into deep trouble if it does |
| // make this assumption. |
| // |
| // IRSB* sb_in is the incoming superblock to be instrumented, |
| // in flat IR form. |
| // |
| // VexGuestLayout* layout contains limited info on the layout of |
| // the guest state: where the stack pointer and program counter |
| // are, and which fields should be regarded as 'always defined'. |
| // Memcheck uses this. |
| // |
| // VexGuestExtents* vge points to a structure which states the |
| // precise byte ranges of original code from which this translation |
| // was made (there may be up to three different ranges involved). |
| // Note again that these are the real addresses from which the code |
| // came. And so it should be the case that closure->readdr is the |
| // same as vge->base[0]; indeed Cachegrind contains this assertion. |
| // |
| // Tools which associate shadow data with code addresses |
| // (cachegrind, callgrind) need to be particularly clear about |
| // whether they are making the association with redirected or |
| // non-redirected code addresses. Both approaches are viable |
| // but you do need to understand what's going on. See comments |
| // below on discard_basic_block_info(). |
| // |
| // IRType gWordTy and IRType hWordTy contain the types of native |
| // words on the guest (simulated) and host (real) CPUs. They will |
| // by either Ity_I32 or Ity_I64. So far we have never built a |
| // cross-architecture Valgrind so they should always be the same. |
| // |
| /* --- Further comments about the IR that your --- */ |
| /* --- instrumentation function will receive. --- */ |
| /* |
| In the incoming IRSB, the IR for each instruction begins with an |
| IRStmt_IMark, which states the address and length of the |
| instruction from which this IR came. This makes it easy for |
| profiling-style tools to know precisely which guest code |
| addresses are being executed. |
| |
| However, before the first IRStmt_IMark, there may be other IR |
| statements -- a preamble. In most cases this preamble is empty, |
| but when it isn't, what it contains is some supporting IR that |
| the JIT uses to ensure control flow works correctly. This |
| preamble does not modify any architecturally defined guest state |
| (registers or memory) and so does not contain anything that will |
| be of interest to your tool. |
| |
| You should therefore |
| |
| (1) copy any IR preceding the first IMark verbatim to the start |
| of the output IRSB. |
| |
| (2) not try to instrument it or modify it in any way. |
| |
| For the record, stuff that may be in the preamble at |
| present is: |
| |
| - A self-modifying-code check has been requested for this block. |
| The preamble will contain instructions to checksum the block, |
| compare against the expected value, and exit the dispatcher |
| requesting a discard (hence forcing a retranslation) if they |
| don't match. |
| |
| - This block is known to be the entry point of a wrapper of some |
| function F. In this case the preamble contains code to write |
| the address of the original F (the fn being wrapped) into a |
| 'hidden' guest state register _NRADDR. The wrapper can later |
| read this register using a client request and make a |
| non-redirected call to it using another client-request-like |
| magic macro. |
| |
| - For platforms that use the AIX ABI (including ppc64-linux), it |
| is necessary to have a preamble even for replacement functions |
| (not just for wrappers), because it is necessary to switch the |
| R2 register (constant-pool pointer) to a different value when |
| swizzling the program counter. |
| |
| Hence the preamble pushes both R2 and LR (the return address) |
| on a small 16-entry stack in the guest state and sets R2 to an |
| appropriate value for the wrapper/replacement fn. LR is then |
| set so that the wrapper/replacement fn returns to a magic IR |
| stub which restores R2 and LR and returns. |
| |
| It's all hugely ugly and fragile. And it places a stringent |
| requirement on m_debuginfo to find out the correct R2 (toc |
| pointer) value for the wrapper/replacement function. So much |
| so that m_redir will refuse to honour a redirect-to-me request |
| if it cannot find (by asking m_debuginfo) a plausible R2 value |
| for 'me'. |
| |
| Because this mechanism maintains a shadow stack of (R2,LR) |
| pairs in the guest state, it will fail if the |
| wrapper/redirection function, or anything it calls, longjumps |
| out past the wrapper, because then the magic return stub will |
| not be run and so the shadow stack will not be popped. So it |
| will quickly fill up. Fortunately none of this applies to |
| {x86,amd64,ppc32}-linux; on those platforms, wrappers can |
| longjump and recurse arbitrarily and everything should work |
| fine. |
| |
| Note that copying the preamble verbatim may cause complications |
| for your instrumenter if you shadow IR temporaries. See big |
| comment in MC_(instrument) in memcheck/mc_translate.c for |
| details. |
| */ |
| IRSB*(*instrument)(VgCallbackClosure* closure, |
| IRSB* sb_in, |
| VexGuestLayout* layout, |
| VexGuestExtents* vge, |
| VexArchInfo* archinfo_host, |
| IRType gWordTy, |
| IRType hWordTy), |
| |
| // Finish up, print out any results, etc. `exitcode' is program's exit |
| // code. The shadow can be found with VG_(get_exit_status_shadow)(). |
| void (*fini)(Int) |
| ); |
| |
| /* ------------------------------------------------------------------ */ |
| /* Details */ |
| |
| /* Default value for avg_translations_sizeB (in bytes), indicating typical |
| code expansion of about 6:1. */ |
| #define VG_DEFAULT_TRANS_SIZEB 172 |
| |
| /* Information used in the startup message. `name' also determines the |
| string used for identifying suppressions in a suppression file as |
| belonging to this tool. `version' can be NULL, in which case (not |
| surprisingly) no version info is printed; this mechanism is designed for |
| tools distributed with Valgrind that share a version number with |
| Valgrind. Other tools not distributed as part of Valgrind should |
| probably have their own version number. */ |
| extern void VG_(details_name) ( const HChar* name ); |
| extern void VG_(details_version) ( const HChar* version ); |
| extern void VG_(details_description) ( const HChar* description ); |
| extern void VG_(details_copyright_author) ( const HChar* copyright_author ); |
| |
| /* Average size of a translation, in bytes, so that the translation |
| storage machinery can allocate memory appropriately. Not critical, |
| setting is optional. */ |
| extern void VG_(details_avg_translation_sizeB) ( UInt size ); |
| |
| /* String printed if an `tl_assert' assertion fails or VG_(tool_panic) |
| is called. Should probably be an email address. */ |
| extern void VG_(details_bug_reports_to) ( const HChar* bug_reports_to ); |
| |
| /* ------------------------------------------------------------------ */ |
| /* Needs */ |
| |
| /* Should __libc_freeres() be run? Bugs in it can crash the tool. */ |
| extern void VG_(needs_libc_freeres) ( void ); |
| |
| /* Want to have errors detected by Valgrind's core reported? Includes: |
| - pthread API errors (many; eg. unlocking a non-locked mutex) |
| [currently disabled] |
| - invalid file descriptors to syscalls like read() and write() |
| - bad signal numbers passed to sigaction() |
| - attempt to install signal handler for SIGKILL or SIGSTOP */ |
| extern void VG_(needs_core_errors) ( void ); |
| |
| /* Booleans that indicate extra operations are defined; if these are True, |
| the corresponding template functions (given below) must be defined. A |
| lot like being a member of a type class. */ |
| |
| /* Want to report errors from tool? This implies use of suppressions, too. */ |
| extern void VG_(needs_tool_errors) ( |
| // Identify if two errors are equal, or close enough. This function is |
| // only called if e1 and e2 will have the same error kind. `res' indicates |
| // how close is "close enough". `res' should be passed on as necessary, |
| // eg. if the Error's `extra' part contains an ExeContext, `res' should be |
| // passed to VG_(eq_ExeContext)() if the ExeContexts are considered. Other |
| // than that, probably don't worry about it unless you have lots of very |
| // similar errors occurring. |
| Bool (*eq_Error)(VgRes res, Error* e1, Error* e2), |
| |
| // We give tools a chance to have a look at errors |
| // just before they are printed. That is, before_pp_Error is |
| // called just before pp_Error itself. This gives the tool a |
| // chance to look at the just-about-to-be-printed error, so as to |
| // emit any arbitrary output if wants to, before the error itself |
| // is printed. This functionality was added to allow Helgrind to |
| // print thread-announcement messages immediately before the |
| // errors that refer to them. |
| void (*before_pp_Error)(Error* err), |
| |
| // Print error context. |
| void (*pp_Error)(Error* err), |
| |
| // Should the core indicate which ThreadId each error comes from? |
| Bool show_ThreadIDs_for_errors, |
| |
| // Should fill in any details that could be postponed until after the |
| // decision whether to ignore the error (ie. details not affecting the |
| // result of VG_(tdict).tool_eq_Error()). This saves time when errors |
| // are ignored. |
| // Yuk. |
| // Return value: must be the size of the `extra' part in bytes -- used by |
| // the core to make a copy. |
| UInt (*update_extra)(Error* err), |
| |
| // Return value indicates recognition. If recognised, must set skind using |
| // VG_(set_supp_kind)(). |
| Bool (*recognised_suppression)(Char* name, Supp* su), |
| |
| // Read any extra info for this suppression kind. Most likely for filling |
| // in the `extra' and `string' parts (with VG_(set_supp_{extra, string})()) |
| // of a suppression if necessary. Should return False if a syntax error |
| // occurred, True otherwise. bufpp and nBufp are the same as for |
| // VG_(get_line). |
| Bool (*read_extra_suppression_info)(Int fd, Char** bufpp, SizeT* nBufp, |
| Supp* su), |
| |
| // This should just check the kinds match and maybe some stuff in the |
| // `string' and `extra' field if appropriate (using VG_(get_supp_*)() to |
| // get the relevant suppression parts). |
| Bool (*error_matches_suppression)(Error* err, Supp* su), |
| |
| // This should return the suppression name, for --gen-suppressions, or NULL |
| // if that error type cannot be suppressed. This is the inverse of |
| // VG_(tdict).tool_recognised_suppression(). |
| const HChar* (*get_error_name)(Error* err), |
| |
| // This should print into buf[0..nBuf-1] any extra info for the |
| // error, for --gen-suppressions, but not including any leading |
| // spaces nor a trailing newline. When called, buf[0 .. nBuf-1] |
| // will be zero filled, and it is expected and checked that the |
| // last element is still zero after the call. In other words the |
| // tool may not overrun the buffer, and this is checked for. If |
| // there is any info printed in the buffer, return True, otherwise |
| // do nothing, and return False. This function is the inverse of |
| // VG_(tdict).tool_read_extra_suppression_info(). |
| Bool (*print_extra_suppression_info)(Error* err, |
| /*OUT*/HChar* buf, Int nBuf) |
| ); |
| |
| /* Is information kept by the tool about specific instructions or |
| translations? (Eg. for cachegrind there are cost-centres for every |
| instruction, stored in a per-translation fashion.) If so, the info |
| may have to be discarded when translations are unloaded (eg. due to |
| .so unloading, or otherwise at the discretion of m_transtab, eg |
| when the table becomes too full) to avoid stale information being |
| reused for new translations. */ |
| extern void VG_(needs_superblock_discards) ( |
| // Discard any information that pertains to specific translations |
| // or instructions within the address range given. There are two |
| // possible approaches. |
| // - If info is being stored at a per-translation level, use orig_addr |
| // to identify which translation is being discarded. Each translation |
| // will be discarded exactly once. |
| // This orig_addr will match the closure->nraddr which was passed to |
| // to instrument() (see extensive comments above) when this |
| // translation was made. Note that orig_addr won't necessarily be |
| // the same as the first address in "extents". |
| // - If info is being stored at a per-instruction level, you can get |
| // the address range(s) being discarded by stepping through "extents". |
| // Note that any single instruction may belong to more than one |
| // translation, and so could be covered by the "extents" of more than |
| // one call to this function. |
| // Doing it the first way (as eg. Cachegrind does) is probably easier. |
| void (*discard_superblock_info)(Addr64 orig_addr, VexGuestExtents extents) |
| ); |
| |
| /* Tool defines its own command line options? */ |
| extern void VG_(needs_command_line_options) ( |
| // Return True if option was recognised, False if it wasn't (but also see |
| // below). Presumably sets some state to record the option as well. |
| // |
| // Nb: tools can assume that the argv will never disappear. So they can, |
| // for example, store a pointer to a string within an option, rather than |
| // having to make a copy. |
| // |
| // Options (and combinations of options) should be checked in this function |
| // if possible rather than in post_clo_init(), and if they are bad then |
| // VG_(fmsg_bad_option)() should be called. This ensures that the |
| // messaging is consistent with command line option errors from the core. |
| Bool (*process_cmd_line_option)(Char* argv), |
| |
| // Print out command line usage for options for normal tool operation. |
| void (*print_usage)(void), |
| |
| // Print out command line usage for options for debugging the tool. |
| void (*print_debug_usage)(void) |
| ); |
| |
| /* Tool defines its own client requests? */ |
| extern void VG_(needs_client_requests) ( |
| // If using client requests, the number of the first request should be equal |
| // to VG_USERREQ_TOOL_BASE('X', 'Y'), where 'X' and 'Y' form a suitable two |
| // character identification for the string. The second and subsequent |
| // requests should follow. |
| // |
| // This function should use the VG_IS_TOOL_USERREQ macro (in |
| // include/valgrind.h) to first check if it's a request for this tool. Then |
| // should handle it if it's recognised (and return True), or return False if |
| // not recognised. arg_block[0] holds the request number, any further args |
| // from the request are in arg_block[1..]. 'ret' is for the return value... |
| // it should probably be filled, if only with 0. |
| Bool (*handle_client_request)(ThreadId tid, UWord* arg_block, UWord* ret) |
| ); |
| |
| /* Tool does stuff before and/or after system calls? */ |
| // Nb: If either of the pre_ functions malloc() something to return, the |
| // corresponding post_ function had better free() it! |
| // Also, the args are the 'original args' -- that is, it may be |
| // that the syscall pre-wrapper will modify the args before the |
| // syscall happens. So these args are the original, un-modified |
| // args. Finally, nArgs merely indicates the length of args[..], |
| // it does not indicate how many of those values are actually |
| // relevant to the syscall. args[0 .. nArgs-1] is guaranteed |
| // to be defined and to contain all the args for this syscall, |
| // possibly including some trailing zeroes. |
| extern void VG_(needs_syscall_wrapper) ( |
| void (* pre_syscall)(ThreadId tid, UInt syscallno, |
| UWord* args, UInt nArgs), |
| void (*post_syscall)(ThreadId tid, UInt syscallno, |
| UWord* args, UInt nArgs, SysRes res) |
| ); |
| |
| /* Are tool-state sanity checks performed? */ |
| // Can be useful for ensuring a tool's correctness. cheap_sanity_check() |
| // is called very frequently; expensive_sanity_check() is called less |
| // frequently and can be more involved. |
| extern void VG_(needs_sanity_checks) ( |
| Bool(*cheap_sanity_check)(void), |
| Bool(*expensive_sanity_check)(void) |
| ); |
| |
| /* Do we need to see variable type and location information? */ |
| extern void VG_(needs_var_info) ( void ); |
| |
| /* Does the tool replace malloc() and friends with its own versions? |
| This has to be combined with the use of a vgpreload_<tool>.so module |
| or it won't work. See massif/Makefile.am for how to build it. */ |
| // The 'p' prefix avoids GCC complaints about overshadowing global names. |
| extern void VG_(needs_malloc_replacement)( |
| void* (*pmalloc) ( ThreadId tid, SizeT n ), |
| void* (*p__builtin_new) ( ThreadId tid, SizeT n ), |
| void* (*p__builtin_vec_new) ( ThreadId tid, SizeT n ), |
| void* (*pmemalign) ( ThreadId tid, SizeT align, SizeT n ), |
| void* (*pcalloc) ( ThreadId tid, SizeT nmemb, SizeT size1 ), |
| void (*pfree) ( ThreadId tid, void* p ), |
| void (*p__builtin_delete) ( ThreadId tid, void* p ), |
| void (*p__builtin_vec_delete) ( ThreadId tid, void* p ), |
| void* (*prealloc) ( ThreadId tid, void* p, SizeT new_size ), |
| SizeT (*pmalloc_usable_size) ( ThreadId tid, void* p), |
| SizeT client_malloc_redzone_szB |
| ); |
| |
| /* Can the tool do XML output? This is a slight misnomer, because the tool |
| * is not requesting the core to do anything, rather saying "I can handle |
| * it". */ |
| extern void VG_(needs_xml_output) ( void ); |
| |
| /* Does the tool want to have one final pass over the IR after tree |
| building but before instruction selection? If so specify the |
| function here. */ |
| extern void VG_(needs_final_IR_tidy_pass) ( IRSB*(*final_tidy)(IRSB*) ); |
| |
| |
| /* ------------------------------------------------------------------ */ |
| /* Core events to track */ |
| |
| /* Part of the core from which this call was made. Useful for determining |
| what kind of error message should be emitted. */ |
| typedef |
| enum { Vg_CoreStartup=1, Vg_CoreSignal, Vg_CoreSysCall, |
| // This is for platforms where syscall args are passed on the |
| // stack; although pre_mem_read is the callback that will be |
| // called, such an arg should be treated (with respect to |
| // presenting information to the user) as if it was passed in a |
| // register, ie. like pre_reg_read. |
| Vg_CoreSysCallArgInMem, |
| Vg_CoreTranslate, Vg_CoreClientReq |
| } CorePart; |
| |
| /* Events happening in core to track. To be notified, pass a callback |
| function to the appropriate function. To ignore an event, don't do |
| anything (the default is for events to be ignored). |
| |
| Note that most events aren't passed a ThreadId. If the event is one called |
| from generated code (eg. new_mem_stack_*), you can use |
| VG_(get_running_tid)() to find it. Otherwise, it has to be passed in, |
| as in pre_mem_read, and so the event signature will require changing. |
| |
| Memory events (Nb: to track heap allocation/freeing, a tool must replace |
| malloc() et al. See above how to do this.) |
| |
| These ones occur at startup, upon some signals, and upon some syscalls. |
| |
| For new_mem_brk and new_mem_stack_signal, the supplied ThreadId |
| indicates the thread for whom the new memory is being allocated. |
| |
| For new_mem_startup and new_mem_mmap, the di_handle argument is a |
| handle which can be used to retrieve debug info associated with the |
| mapping or allocation (because it is of a file that Valgrind has |
| decided to read debug info from). If the value is zero, there is |
| no associated debug info. If the value exceeds zero, it can be |
| supplied as an argument to selected queries in m_debuginfo. |
| */ |
| void VG_(track_new_mem_startup) (void(*f)(Addr a, SizeT len, |
| Bool rr, Bool ww, Bool xx, |
| ULong di_handle)); |
| void VG_(track_new_mem_stack_signal)(void(*f)(Addr a, SizeT len, ThreadId tid)); |
| void VG_(track_new_mem_brk) (void(*f)(Addr a, SizeT len, ThreadId tid)); |
| void VG_(track_new_mem_mmap) (void(*f)(Addr a, SizeT len, |
| Bool rr, Bool ww, Bool xx, |
| ULong di_handle)); |
| |
| void VG_(track_copy_mem_remap) (void(*f)(Addr from, Addr to, SizeT len)); |
| void VG_(track_change_mem_mprotect) (void(*f)(Addr a, SizeT len, |
| Bool rr, Bool ww, Bool xx)); |
| void VG_(track_die_mem_stack_signal)(void(*f)(Addr a, SizeT len)); |
| void VG_(track_die_mem_brk) (void(*f)(Addr a, SizeT len)); |
| void VG_(track_die_mem_munmap) (void(*f)(Addr a, SizeT len)); |
| |
| /* These ones are called when SP changes. A tool could track these itself |
| (except for ban_mem_stack) but it's much easier to use the core's help. |
| |
| The specialised ones are called in preference to the general one, if they |
| are defined. These functions are called a lot if they are used, so |
| specialising can optimise things significantly. If any of the |
| specialised cases are defined, the general case must be defined too. |
| |
| Nb: all the specialised ones must use the VG_REGPARM(n) attribute. |
| |
| For the _new functions, a tool may specify with with-ECU |
| (ExeContext Unique) or without-ECU version for each size, but not |
| both. If the with-ECU version is supplied, then the core will |
| arrange to pass, as the ecu argument, a 32-bit int which uniquely |
| identifies the instruction moving the stack pointer down. This |
| 32-bit value is as obtained from VG_(get_ECU_from_ExeContext). |
| VG_(get_ExeContext_from_ECU) can then be used to retrieve the |
| associated depth-1 ExeContext for the location. All this |
| complexity is provided to support origin tracking in Memcheck. |
| */ |
| void VG_(track_new_mem_stack_4_w_ECU) (VG_REGPARM(2) void(*f)(Addr new_ESP, UInt ecu)); |
| void VG_(track_new_mem_stack_8_w_ECU) (VG_REGPARM(2) void(*f)(Addr new_ESP, UInt ecu)); |
| void VG_(track_new_mem_stack_12_w_ECU) (VG_REGPARM(2) void(*f)(Addr new_ESP, UInt ecu)); |
| void VG_(track_new_mem_stack_16_w_ECU) (VG_REGPARM(2) void(*f)(Addr new_ESP, UInt ecu)); |
| void VG_(track_new_mem_stack_32_w_ECU) (VG_REGPARM(2) void(*f)(Addr new_ESP, UInt ecu)); |
| void VG_(track_new_mem_stack_112_w_ECU)(VG_REGPARM(2) void(*f)(Addr new_ESP, UInt ecu)); |
| void VG_(track_new_mem_stack_128_w_ECU)(VG_REGPARM(2) void(*f)(Addr new_ESP, UInt ecu)); |
| void VG_(track_new_mem_stack_144_w_ECU)(VG_REGPARM(2) void(*f)(Addr new_ESP, UInt ecu)); |
| void VG_(track_new_mem_stack_160_w_ECU)(VG_REGPARM(2) void(*f)(Addr new_ESP, UInt ecu)); |
| void VG_(track_new_mem_stack_w_ECU) (void(*f)(Addr a, SizeT len, |
| UInt ecu)); |
| |
| void VG_(track_new_mem_stack_4) (VG_REGPARM(1) void(*f)(Addr new_ESP)); |
| void VG_(track_new_mem_stack_8) (VG_REGPARM(1) void(*f)(Addr new_ESP)); |
| void VG_(track_new_mem_stack_12) (VG_REGPARM(1) void(*f)(Addr new_ESP)); |
| void VG_(track_new_mem_stack_16) (VG_REGPARM(1) void(*f)(Addr new_ESP)); |
| void VG_(track_new_mem_stack_32) (VG_REGPARM(1) void(*f)(Addr new_ESP)); |
| void VG_(track_new_mem_stack_112)(VG_REGPARM(1) void(*f)(Addr new_ESP)); |
| void VG_(track_new_mem_stack_128)(VG_REGPARM(1) void(*f)(Addr new_ESP)); |
| void VG_(track_new_mem_stack_144)(VG_REGPARM(1) void(*f)(Addr new_ESP)); |
| void VG_(track_new_mem_stack_160)(VG_REGPARM(1) void(*f)(Addr new_ESP)); |
| void VG_(track_new_mem_stack) (void(*f)(Addr a, SizeT len)); |
| |
| void VG_(track_die_mem_stack_4) (VG_REGPARM(1) void(*f)(Addr die_ESP)); |
| void VG_(track_die_mem_stack_8) (VG_REGPARM(1) void(*f)(Addr die_ESP)); |
| void VG_(track_die_mem_stack_12) (VG_REGPARM(1) void(*f)(Addr die_ESP)); |
| void VG_(track_die_mem_stack_16) (VG_REGPARM(1) void(*f)(Addr die_ESP)); |
| void VG_(track_die_mem_stack_32) (VG_REGPARM(1) void(*f)(Addr die_ESP)); |
| void VG_(track_die_mem_stack_112)(VG_REGPARM(1) void(*f)(Addr die_ESP)); |
| void VG_(track_die_mem_stack_128)(VG_REGPARM(1) void(*f)(Addr die_ESP)); |
| void VG_(track_die_mem_stack_144)(VG_REGPARM(1) void(*f)(Addr die_ESP)); |
| void VG_(track_die_mem_stack_160)(VG_REGPARM(1) void(*f)(Addr die_ESP)); |
| void VG_(track_die_mem_stack) (void(*f)(Addr a, SizeT len)); |
| |
| /* Used for redzone at end of thread stacks */ |
| void VG_(track_ban_mem_stack) (void(*f)(Addr a, SizeT len)); |
| |
| /* These ones occur around syscalls, signal handling, etc */ |
| void VG_(track_pre_mem_read) (void(*f)(CorePart part, ThreadId tid, |
| const HChar* s, Addr a, SizeT size)); |
| void VG_(track_pre_mem_read_asciiz)(void(*f)(CorePart part, ThreadId tid, |
| const HChar* s, Addr a)); |
| void VG_(track_pre_mem_write) (void(*f)(CorePart part, ThreadId tid, |
| const HChar* s, Addr a, SizeT size)); |
| void VG_(track_post_mem_write) (void(*f)(CorePart part, ThreadId tid, |
| Addr a, SizeT size)); |
| |
| /* Register events. Use VG_(set_shadow_state_area)() to set the shadow regs |
| for these events. */ |
| void VG_(track_pre_reg_read) (void(*f)(CorePart part, ThreadId tid, |
| const HChar* s, PtrdiffT guest_state_offset, |
| SizeT size)); |
| void VG_(track_post_reg_write)(void(*f)(CorePart part, ThreadId tid, |
| PtrdiffT guest_state_offset, |
| SizeT size)); |
| |
| /* This one is called for malloc() et al if they are replaced by a tool. */ |
| void VG_(track_post_reg_write_clientcall_return)( |
| void(*f)(ThreadId tid, PtrdiffT guest_state_offset, SizeT size, Addr f)); |
| |
| |
| /* Scheduler events (not exhaustive) */ |
| |
| /* Called when 'tid' starts or stops running client code blocks. |
| Gives the total dispatched block count at that event. Note, this |
| is not the same as 'tid' holding the BigLock (the lock that ensures |
| that only one thread runs at a time): a thread can hold the lock |
| for other purposes (making translations, etc) yet not be running |
| client blocks. Obviously though, a thread must hold the lock in |
| order to run client code blocks, so the times bracketed by |
| 'start_client_code'..'stop_client_code' are a subset of the times |
| when thread 'tid' holds the cpu lock. |
| */ |
| void VG_(track_start_client_code)( |
| void(*f)(ThreadId tid, ULong blocks_dispatched) |
| ); |
| void VG_(track_stop_client_code)( |
| void(*f)(ThreadId tid, ULong blocks_dispatched) |
| ); |
| |
| |
| /* Thread events (not exhaustive) |
| |
| ll_create: low level thread creation. Called before the new thread |
| has run any instructions (or touched any memory). In fact, called |
| immediately before the new thread has come into existence; the new |
| thread can be assumed to exist when notified by this call. |
| |
| ll_exit: low level thread exit. Called after the exiting thread |
| has run its last instruction. |
| |
| The _ll_ part makes it clear these events are not to do with |
| pthread_create or pthread_exit/pthread_join (etc), which are a |
| higher level abstraction synthesised by libpthread. What you can |
| be sure of from _ll_create/_ll_exit is the absolute limits of each |
| thread's lifetime, and hence be assured that all memory references |
| made by the thread fall inside the _ll_create/_ll_exit pair. This |
| is important for tools that need a 100% accurate account of which |
| thread is responsible for every memory reference in the process. |
| |
| pthread_create/join/exit do not give this property. Calls/returns |
| to/from them happen arbitrarily far away from the relevant |
| low-level thread create/quit event. In general a few hundred |
| instructions; hence a few hundred(ish) memory references could get |
| misclassified each time. |
| |
| pre_thread_first_insn: is called when the thread is all set up and |
| ready to go (stack in place, etc) but has not executed its first |
| instruction yet. Gives threading tools a chance to ask questions |
| about the thread (eg, what is its initial client stack pointer) |
| that are not easily answered at pre_thread_ll_create time. |
| |
| For a given thread, the call sequence is: |
| ll_create (in the parent's context) |
| first_insn (in the child's context) |
| ll_exit (in the child's context) |
| */ |
| void VG_(track_pre_thread_ll_create) (void(*f)(ThreadId tid, ThreadId child)); |
| void VG_(track_pre_thread_first_insn)(void(*f)(ThreadId tid)); |
| void VG_(track_pre_thread_ll_exit) (void(*f)(ThreadId tid)); |
| |
| |
| /* Signal events (not exhaustive) |
| |
| ... pre_send_signal, post_send_signal ... |
| |
| Called before a signal is delivered; `alt_stack' indicates if it is |
| delivered on an alternative stack. */ |
| void VG_(track_pre_deliver_signal) (void(*f)(ThreadId tid, Int sigNo, |
| Bool alt_stack)); |
| /* Called after a signal is delivered. Nb: unfortunately, if the signal |
| handler longjmps, this won't be called. */ |
| void VG_(track_post_deliver_signal)(void(*f)(ThreadId tid, Int sigNo)); |
| |
| #endif // __PUB_TOOL_TOOLIFACE_H |
| |
| /*--------------------------------------------------------------------*/ |
| /*--- end ---*/ |
| /*--------------------------------------------------------------------*/ |