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ftmemsim-valgrind/addrcheck/ac_main.c
Nicholas Nethercote f1689b96db Changed lots of files for the new core/ + skin/ directory structure: 
- changed lots of Makefile.am files
   - changed configure.in
   - changed lots of #include lines for changed file names
   - changed lots of file headers n footers for changed file names
   - changed vg_regtest to handle new directory structure -- recursively
     traverses subdirectories for .vgtest test files
   - changed lots of paths in memcheck/ regression test expected outputs


git-svn-id: svn://svn.valgrind.org/valgrind/trunk@1090
2002-09-23 11:21:57 +00:00

2588 lines
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/*--------------------------------------------------------------------*/
/*--- The AddrCheck skin: like MemCheck, but only does address ---*/
/*--- checking. No definedness checking. ---*/
/*--- ac_main.c ---*/
/*--------------------------------------------------------------------*/
/*
This file is part of Valgrind, an x86 protected-mode emulator
designed for debugging and profiling binaries on x86-Unixes.
Copyright (C) 2000-2002 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.
*/
#include "ac_include.h"
//#include "vg_profile.c"
/*------------------------------------------------------------*/
/*--- Defns ---*/
/*------------------------------------------------------------*/
/* These many bytes below %ESP are considered addressible if we're
doing the --workaround-gcc296-bugs hack. */
#define VG_GCC296_BUG_STACK_SLOP 1024
typedef
enum {
/* Bad syscall params */
ParamSupp,
/* Memory errors in core (pthread ops, signal handling) */
CoreMemSupp,
/* Invalid read/write attempt at given size */
Addr1Supp, Addr2Supp, Addr4Supp, Addr8Supp,
/* Invalid or mismatching free */
FreeSupp
}
AddrCheckSuppKind;
/* What kind of error it is. */
typedef
enum { CoreMemErr,
AddrErr,
ParamErr, UserErr, /* behaves like an anonymous ParamErr */
FreeErr, FreeMismatchErr
}
AddrCheckErrorKind;
/* What kind of memory access is involved in the error? */
typedef
enum { ReadAxs, WriteAxs, ExecAxs }
AxsKind;
/* Extra context for memory errors */
typedef
struct {
/* AddrErr */
AxsKind axskind;
/* AddrErr */
Int size;
/* AddrErr, FreeErr, FreeMismatchErr, ParamErr, UserErr */
AcAddrInfo addrinfo;
/* ParamErr, UserErr, CoreMemErr */
Bool isWrite;
}
AddrCheckError;
/*------------------------------------------------------------*/
/*--- Comparing and printing errors ---*/
/*------------------------------------------------------------*/
static __inline__
void clear_AcAddrInfo ( AcAddrInfo* ai )
{
ai->akind = Unknown;
ai->blksize = 0;
ai->rwoffset = 0;
ai->lastchange = NULL;
ai->stack_tid = VG_INVALID_THREADID;
ai->maybe_gcc = False;
}
static __inline__
void clear_AddrCheckError ( AddrCheckError* err_extra )
{
err_extra->axskind = ReadAxs;
err_extra->size = 0;
clear_AcAddrInfo ( &err_extra->addrinfo );
err_extra->isWrite = False;
}
__attribute__((unused))
static Bool eq_AcAddrInfo ( VgRes res, AcAddrInfo* ai1, AcAddrInfo* ai2 )
{
if (ai1->akind != Undescribed
&& ai2->akind != Undescribed
&& ai1->akind != ai2->akind)
return False;
if (ai1->akind == Freed || ai1->akind == Mallocd) {
if (ai1->blksize != ai2->blksize)
return False;
if (!VG_(eq_ExeContext)(res, ai1->lastchange, ai2->lastchange))
return False;
}
return True;
}
/* Compare error contexts, to detect duplicates. Note that if they
are otherwise the same, the faulting addrs and associated rwoffsets
are allowed to be different. */
Bool SK_(eq_SkinError) ( VgRes res,
SkinError* e1, SkinError* e2 )
{
AddrCheckError* e1_extra = e1->extra;
AddrCheckError* e2_extra = e2->extra;
switch (e1->ekind) {
case CoreMemErr:
if (e1_extra->isWrite != e2_extra->isWrite) return False;
if (e2->ekind != CoreMemErr) return False;
if (e1->string == e2->string) return True;
if (0 == VG_(strcmp)(e1->string, e2->string)) return True;
return False;
case UserErr:
case ParamErr:
if (e1_extra->isWrite != e2_extra->isWrite)
return False;
if (e1->ekind == ParamErr
&& 0 != VG_(strcmp)(e1->string, e2->string))
return False;
return True;
case FreeErr:
case FreeMismatchErr:
/* JRS 2002-Aug-26: comparing addrs seems overkill and can
cause excessive duplication of errors. Not even AddrErr
below does that. So don't compare either the .addr field
or the .addrinfo fields. */
/* if (e1->addr != e2->addr) return False; */
/* if (!eq_AcAddrInfo(res, &e1_extra->addrinfo, &e2_extra->addrinfo))
return False;
*/
return True;
case AddrErr:
/* if (e1_extra->axskind != e2_extra->axskind) return False; */
if (e1_extra->size != e2_extra->size) return False;
/*
if (!eq_AcAddrInfo(res, &e1_extra->addrinfo, &e2_extra->addrinfo))
return False;
*/
return True;
default:
VG_(printf)("Error:\n unknown AddrCheck error code %d\n", e1->ekind);
VG_(panic)("unknown error code in SK_(eq_SkinError)");
}
}
static void pp_AcAddrInfo ( Addr a, AcAddrInfo* ai )
{
switch (ai->akind) {
case Stack:
VG_(message)(Vg_UserMsg,
" Address 0x%x is on thread %d's stack",
a, ai->stack_tid);
break;
case Unknown:
if (ai->maybe_gcc) {
VG_(message)(Vg_UserMsg,
" Address 0x%x is just below %%esp. Possibly a bug in GCC/G++",
a);
VG_(message)(Vg_UserMsg,
" v 2.96 or 3.0.X. To suppress, use: --workaround-gcc296-bugs=yes");
} else {
VG_(message)(Vg_UserMsg,
" Address 0x%x is not stack'd, malloc'd or free'd", a);
}
break;
case Freed: case Mallocd: {
UInt delta;
UChar* relative;
if (ai->rwoffset < 0) {
delta = (UInt)(- ai->rwoffset);
relative = "before";
} else if (ai->rwoffset >= ai->blksize) {
delta = ai->rwoffset - ai->blksize;
relative = "after";
} else {
delta = ai->rwoffset;
relative = "inside";
}
{
VG_(message)(Vg_UserMsg,
" Address 0x%x is %d bytes %s a block of size %d %s",
a, delta, relative,
ai->blksize,
ai->akind==Mallocd ? "alloc'd"
: ai->akind==Freed ? "free'd"
: "client-defined");
}
VG_(pp_ExeContext)(ai->lastchange);
break;
}
default:
VG_(panic)("pp_AcAddrInfo");
}
}
void SK_(pp_SkinError) ( SkinError* err, void (*pp_ExeContext)(void) )
{
AddrCheckError* err_extra = err->extra;
switch (err->ekind) {
case CoreMemErr:
if (err_extra->isWrite) {
VG_(message)(Vg_UserMsg,
"%s contains unaddressable byte(s)", err->string );
} else {
VG_(message)(Vg_UserMsg,
"%s contains unaddressable byte(s)", err->string );
}
pp_ExeContext();
break;
case AddrErr:
switch (err_extra->axskind) {
case ReadAxs:
case WriteAxs:
/* These two aren't actually differentiated ever. */
VG_(message)(Vg_UserMsg, "Invalid memory access of size %d",
err_extra->size );
break;
case ExecAxs:
VG_(message)(Vg_UserMsg, "Jump to the invalid address "
"stated on the next line");
break;
default:
VG_(panic)("pp_SkinError(axskind)");
}
pp_ExeContext();
pp_AcAddrInfo(err->addr, &err_extra->addrinfo);
break;
case FreeErr:
VG_(message)(Vg_UserMsg,"Invalid free() / delete / delete[]");
/* fall through */
case FreeMismatchErr:
if (err->ekind == FreeMismatchErr)
VG_(message)(Vg_UserMsg,
"Mismatched free() / delete / delete []");
pp_ExeContext();
pp_AcAddrInfo(err->addr, &err_extra->addrinfo);
break;
case ParamErr:
if (err_extra->isWrite) {
VG_(message)(Vg_UserMsg,
"Syscall param %s contains unaddressable byte(s)",
err->string );
} else {
VG_(message)(Vg_UserMsg,
"Syscall param %s contains uninitialised or "
"unaddressable byte(s)",
err->string);
}
pp_ExeContext();
pp_AcAddrInfo(err->addr, &err_extra->addrinfo);
break;
case UserErr:
if (err_extra->isWrite) {
VG_(message)(Vg_UserMsg,
"Unaddressable byte(s) found during client check request");
} else {
VG_(message)(Vg_UserMsg,
"Uninitialised or "
"unaddressable byte(s) found during client check request");
}
pp_ExeContext();
pp_AcAddrInfo(err->addr, &err_extra->addrinfo);
break;
default:
VG_(printf)("Error:\n unknown AddrCheck error code %d\n", err->ekind);
VG_(panic)("unknown error code in SK_(pp_SkinError)");
}
}
/*------------------------------------------------------------*/
/*--- Recording errors ---*/
/*------------------------------------------------------------*/
/* Describe an address as best you can, for error messages,
putting the result in ai. */
static void describe_addr ( Addr a, AcAddrInfo* ai )
{
ShadowChunk* sc;
ThreadId tid;
/* Nested functions, yeah. Need the lexical scoping of 'a'. */
/* Closure for searching thread stacks */
Bool addr_is_in_bounds(Addr stack_min, Addr stack_max)
{
return (stack_min <= a && a <= stack_max);
}
/* Closure for searching malloc'd and free'd lists */
Bool addr_is_in_block(ShadowChunk *sh_ch)
{
return VG_(addr_is_in_block) ( a, sh_ch->data, sh_ch->size );
}
/* Perhaps it's on a thread's stack? */
tid = VG_(any_matching_thread_stack)(addr_is_in_bounds);
if (tid != VG_INVALID_THREADID) {
ai->akind = Stack;
ai->stack_tid = tid;
return;
}
/* Search for a recently freed block which might bracket it. */
sc = SK_(any_matching_freed_ShadowChunks)(addr_is_in_block);
if (NULL != sc) {
ai->akind = Freed;
ai->blksize = sc->size;
ai->rwoffset = (Int)(a) - (Int)(sc->data);
ai->lastchange = (ExeContext*)sc->skin_extra[0];
return;
}
/* Search for a currently malloc'd block which might bracket it. */
sc = VG_(any_matching_mallocd_ShadowChunks)(addr_is_in_block);
if (NULL != sc) {
ai->akind = Mallocd;
ai->blksize = sc->size;
ai->rwoffset = (Int)(a) - (Int)(sc->data);
ai->lastchange = (ExeContext*)sc->skin_extra[0];
return;
}
/* Clueless ... */
ai->akind = Unknown;
return;
}
/* Creates a copy of the err_extra, updates the copy with address info if
necessary, sticks the copy into the SkinError. */
void SK_(dup_extra_and_update)(SkinError* err)
{
AddrCheckError* err_extra;
err_extra = VG_(malloc)(sizeof(AddrCheckError));
*err_extra = *((AddrCheckError*)err->extra);
if (err_extra->addrinfo.akind == Undescribed)
describe_addr ( err->addr, &(err_extra->addrinfo) );
err->extra = err_extra;
}
/* Is this address within some small distance below %ESP? Used only
for the --workaround-gcc296-bugs kludge. */
Bool VG_(is_just_below_ESP)( Addr esp, Addr aa )
{
if ((UInt)esp > (UInt)aa
&& ((UInt)esp - (UInt)aa) <= VG_GCC296_BUG_STACK_SLOP)
return True;
else
return False;
}
static
void sk_record_address_error ( Addr a, Int size, Bool isWrite )
{
AddrCheckError err_extra;
Bool just_below_esp;
just_below_esp
= VG_(is_just_below_ESP)( VG_(get_stack_pointer)(), a );
/* If this is caused by an access immediately below %ESP, and the
user asks nicely, we just ignore it. */
if (SK_(clo_workaround_gcc296_bugs) && just_below_esp)
return;
clear_AddrCheckError( &err_extra );
err_extra.axskind = isWrite ? WriteAxs : ReadAxs;
err_extra.size = size;
err_extra.addrinfo.akind = Undescribed;
err_extra.addrinfo.maybe_gcc = just_below_esp;
VG_(maybe_record_error)( NULL, AddrErr, a, /*s*/NULL, &err_extra );
}
/* These ones are called from non-generated code */
/* This is for memory errors in pthread functions, as opposed to pthread API
errors which are found by the core. */
void SK_(record_core_mem_error) ( ThreadState* tst, Bool isWrite, Char* msg )
{
AddrCheckError err_extra;
clear_AddrCheckError( &err_extra );
err_extra.isWrite = isWrite;
VG_(maybe_record_error)( tst, CoreMemErr, /*addr*/0, msg, &err_extra );
}
void SK_(record_param_error) ( ThreadState* tst, Addr a, Bool isWrite,
Char* msg )
{
AddrCheckError err_extra;
vg_assert(NULL != tst);
clear_AddrCheckError( &err_extra );
err_extra.addrinfo.akind = Undescribed;
err_extra.isWrite = isWrite;
VG_(maybe_record_error)( tst, ParamErr, a, msg, &err_extra );
}
void SK_(record_jump_error) ( ThreadState* tst, Addr a )
{
AddrCheckError err_extra;
vg_assert(NULL != tst);
clear_AddrCheckError( &err_extra );
err_extra.axskind = ExecAxs;
err_extra.addrinfo.akind = Undescribed;
VG_(maybe_record_error)( tst, AddrErr, a, /*s*/NULL, &err_extra );
}
void SK_(record_free_error) ( ThreadState* tst, Addr a )
{
AddrCheckError err_extra;
vg_assert(NULL != tst);
clear_AddrCheckError( &err_extra );
err_extra.addrinfo.akind = Undescribed;
VG_(maybe_record_error)( tst, FreeErr, a, /*s*/NULL, &err_extra );
}
void SK_(record_freemismatch_error) ( ThreadState* tst, Addr a )
{
AddrCheckError err_extra;
vg_assert(NULL != tst);
clear_AddrCheckError( &err_extra );
err_extra.addrinfo.akind = Undescribed;
VG_(maybe_record_error)( tst, FreeMismatchErr, a, /*s*/NULL, &err_extra );
}
void SK_(record_user_error) ( ThreadState* tst, Addr a, Bool isWrite )
{
AddrCheckError err_extra;
vg_assert(NULL != tst);
clear_AddrCheckError( &err_extra );
err_extra.addrinfo.akind = Undescribed;
err_extra.isWrite = isWrite;
VG_(maybe_record_error)( tst, UserErr, a, /*s*/NULL, &err_extra );
}
/*------------------------------------------------------------*/
/*--- Suppressions ---*/
/*------------------------------------------------------------*/
#define STREQ(s1,s2) (s1 != NULL && s2 != NULL \
&& VG_(strcmp)((s1),(s2))==0)
Bool SK_(recognised_suppression) ( Char* name, SuppKind *skind )
{
if (STREQ(name, "Param")) *skind = ParamSupp;
else if (STREQ(name, "CoreMem")) *skind = CoreMemSupp;
else if (STREQ(name, "Addr1")) *skind = Addr1Supp;
else if (STREQ(name, "Addr2")) *skind = Addr2Supp;
else if (STREQ(name, "Addr4")) *skind = Addr4Supp;
else if (STREQ(name, "Addr8")) *skind = Addr8Supp;
else if (STREQ(name, "Free")) *skind = FreeSupp;
else
return False;
return True;
}
Bool SK_(read_extra_suppression_info) ( Int fd, Char* buf, Int nBuf,
SkinSupp *s )
{
Bool eof;
if (s->skind == ParamSupp) {
eof = VG_(getLine) ( fd, buf, nBuf );
if (eof) return False;
s->string = VG_(strdup)(buf);
}
return True;
}
extern Bool SK_(error_matches_suppression)(SkinError* err, SkinSupp* su)
{
UInt su_size;
AddrCheckError* err_extra = err->extra;
switch (su->skind) {
case ParamSupp:
return (err->ekind == ParamErr && STREQ(su->string, err->string));
case CoreMemSupp:
return (err->ekind == CoreMemErr && STREQ(su->string, err->string));
case Addr1Supp: su_size = 1; goto addr_case;
case Addr2Supp: su_size = 2; goto addr_case;
case Addr4Supp: su_size = 4; goto addr_case;
case Addr8Supp: su_size = 8; goto addr_case;
addr_case:
return (err->ekind == AddrErr && err_extra->size != su_size);
case FreeSupp:
return (err->ekind == FreeErr || err->ekind == FreeMismatchErr);
default:
VG_(printf)("Error:\n"
" unknown AddrCheck suppression type %d\n", su->skind);
VG_(panic)("unknown suppression type in "
"SK_(error_matches_suppression)");
}
}
# undef STREQ
/*--------------------------------------------------------------------*/
/*--- Part of the AddrCheck skin: Maintain bitmaps of memory, ---*/
/*--- tracking the accessibility (A) each byte. ---*/
/*--------------------------------------------------------------------*/
#define DEBUG(fmt, args...) //VG_(printf)(fmt, ## args)
/*------------------------------------------------------------*/
/*--- Command line options ---*/
/*------------------------------------------------------------*/
Bool SK_(clo_partial_loads_ok) = True;
Int SK_(clo_freelist_vol) = 1000000;
Bool SK_(clo_leak_check) = False;
VgRes SK_(clo_leak_resolution) = Vg_LowRes;
Bool SK_(clo_show_reachable) = False;
Bool SK_(clo_workaround_gcc296_bugs) = False;
Bool SK_(clo_cleanup) = True;
/*------------------------------------------------------------*/
/*--- Profiling events ---*/
/*------------------------------------------------------------*/
typedef
enum {
VgpCheckMem = VgpFini+1,
VgpSetMem
}
VgpSkinCC;
/*------------------------------------------------------------*/
/*--- Low-level support for memory checking. ---*/
/*------------------------------------------------------------*/
/* All reads and writes are checked against a memory map, which
records the state of all memory in the process. The memory map is
organised like this:
The top 16 bits of an address are used to index into a top-level
map table, containing 65536 entries. Each entry is a pointer to a
second-level map, which records the accesibililty and validity
permissions for the 65536 bytes indexed by the lower 16 bits of the
address. Each byte is represented by one bit, indicating
accessibility. So each second-level map contains 8192 bytes. This
two-level arrangement conveniently divides the 4G address space
into 64k lumps, each size 64k bytes.
All entries in the primary (top-level) map must point to a valid
secondary (second-level) map. Since most of the 4G of address
space will not be in use -- ie, not mapped at all -- there is a
distinguished secondary map, which indicates `not addressible and
not valid' writeable for all bytes. Entries in the primary map for
which the entire 64k is not in use at all point at this
distinguished map.
[...] lots of stuff deleted due to out of date-ness
As a final optimisation, the alignment and address checks for
4-byte loads and stores are combined in a neat way. The primary
map is extended to have 262144 entries (2^18), rather than 2^16.
The top 3/4 of these entries are permanently set to the
distinguished secondary map. For a 4-byte load/store, the
top-level map is indexed not with (addr >> 16) but instead f(addr),
where
f( XXXX XXXX XXXX XXXX ____ ____ ____ __YZ )
= ____ ____ ____ __YZ XXXX XXXX XXXX XXXX or
= ____ ____ ____ __ZY XXXX XXXX XXXX XXXX
ie the lowest two bits are placed above the 16 high address bits.
If either of these two bits are nonzero, the address is misaligned;
this will select a secondary map from the upper 3/4 of the primary
map. Because this is always the distinguished secondary map, a
(bogus) address check failure will result. The failure handling
code can then figure out whether this is a genuine addr check
failure or whether it is a possibly-legitimate access at a
misaligned address. */
/*------------------------------------------------------------*/
/*--- Crude profiling machinery. ---*/
/*------------------------------------------------------------*/
#ifdef VG_PROFILE_MEMORY
#define N_PROF_EVENTS 150
static UInt event_ctr[N_PROF_EVENTS];
static void init_prof_mem ( void )
{
Int i;
for (i = 0; i < N_PROF_EVENTS; i++)
event_ctr[i] = 0;
}
static void done_prof_mem ( void )
{
Int i;
for (i = 0; i < N_PROF_EVENTS; i++) {
if ((i % 10) == 0)
VG_(printf)("\n");
if (event_ctr[i] > 0)
VG_(printf)( "prof mem event %2d: %d\n", i, event_ctr[i] );
}
VG_(printf)("\n");
}
#define PROF_EVENT(ev) \
do { vg_assert((ev) >= 0 && (ev) < N_PROF_EVENTS); \
event_ctr[ev]++; \
} while (False);
#else
static void init_prof_mem ( void ) { }
static void done_prof_mem ( void ) { }
#define PROF_EVENT(ev) /* */
#endif
/* Event index. If just the name of the fn is given, this means the
number of calls to the fn. Otherwise it is the specified event.
10 alloc_secondary_map
20 get_abit
21 get_vbyte
22 set_abit
23 set_vbyte
24 get_abits4_ALIGNED
25 get_vbytes4_ALIGNED
30 set_address_range_perms
31 set_address_range_perms(lower byte loop)
32 set_address_range_perms(quadword loop)
33 set_address_range_perms(upper byte loop)
35 make_noaccess
36 make_writable
37 make_readable
40 copy_address_range_state
41 copy_address_range_state(byte loop)
42 check_writable
43 check_writable(byte loop)
44 check_readable
45 check_readable(byte loop)
46 check_readable_asciiz
47 check_readable_asciiz(byte loop)
50 make_aligned_word_NOACCESS
51 make_aligned_word_WRITABLE
60 helperc_LOADV4
61 helperc_STOREV4
62 helperc_LOADV2
63 helperc_STOREV2
64 helperc_LOADV1
65 helperc_STOREV1
70 rim_rd_V4_SLOWLY
71 rim_wr_V4_SLOWLY
72 rim_rd_V2_SLOWLY
73 rim_wr_V2_SLOWLY
74 rim_rd_V1_SLOWLY
75 rim_wr_V1_SLOWLY
80 fpu_read
81 fpu_read aligned 4
82 fpu_read aligned 8
83 fpu_read 2
84 fpu_read 10
85 fpu_write
86 fpu_write aligned 4
87 fpu_write aligned 8
88 fpu_write 2
89 fpu_write 10
90 fpu_read_check_SLOWLY
91 fpu_read_check_SLOWLY(byte loop)
92 fpu_write_check_SLOWLY
93 fpu_write_check_SLOWLY(byte loop)
100 is_plausible_stack_addr
101 handle_esp_assignment
102 handle_esp_assignment(-4)
103 handle_esp_assignment(+4)
104 handle_esp_assignment(-12)
105 handle_esp_assignment(-8)
106 handle_esp_assignment(+16)
107 handle_esp_assignment(+12)
108 handle_esp_assignment(0)
109 handle_esp_assignment(+8)
110 handle_esp_assignment(-16)
111 handle_esp_assignment(+20)
112 handle_esp_assignment(-20)
113 handle_esp_assignment(+24)
114 handle_esp_assignment(-24)
120 vg_handle_esp_assignment_SLOWLY
121 vg_handle_esp_assignment_SLOWLY(normal; move down)
122 vg_handle_esp_assignment_SLOWLY(normal; move up)
123 vg_handle_esp_assignment_SLOWLY(normal)
124 vg_handle_esp_assignment_SLOWLY(>= HUGE_DELTA)
*/
/*------------------------------------------------------------*/
/*--- Function declarations. ---*/
/*------------------------------------------------------------*/
static void vgmext_ACCESS4_SLOWLY ( Addr a );
static void vgmext_ACCESS2_SLOWLY ( Addr a );
static void vgmext_ACCESS1_SLOWLY ( Addr a );
static void fpu_ACCESS_check_SLOWLY ( Addr addr, Int size );
/*------------------------------------------------------------*/
/*--- Data defns. ---*/
/*------------------------------------------------------------*/
typedef
struct {
UChar abits[8192];
}
AcSecMap;
static AcSecMap* primary_map[ /*65536*/ 262144 ];
static AcSecMap distinguished_secondary_map;
#define IS_DISTINGUISHED_SM(smap) \
((smap) == &distinguished_secondary_map)
#define ENSURE_MAPPABLE(addr,caller) \
do { \
if (IS_DISTINGUISHED_SM(primary_map[(addr) >> 16])) { \
primary_map[(addr) >> 16] = alloc_secondary_map(caller); \
/* VG_(printf)("new 2map because of %p\n", addr); */ \
} \
} while(0)
#define BITARR_SET(aaa_p,iii_p) \
do { \
UInt iii = (UInt)iii_p; \
UChar* aaa = (UChar*)aaa_p; \
aaa[iii >> 3] |= (1 << (iii & 7)); \
} while (0)
#define BITARR_CLEAR(aaa_p,iii_p) \
do { \
UInt iii = (UInt)iii_p; \
UChar* aaa = (UChar*)aaa_p; \
aaa[iii >> 3] &= ~(1 << (iii & 7)); \
} while (0)
#define BITARR_TEST(aaa_p,iii_p) \
(0 != (((UChar*)aaa_p)[ ((UInt)iii_p) >> 3 ] \
& (1 << (((UInt)iii_p) & 7)))) \
#define VGM_BIT_VALID 0
#define VGM_BIT_INVALID 1
#define VGM_NIBBLE_VALID 0
#define VGM_NIBBLE_INVALID 0xF
#define VGM_BYTE_VALID 0
#define VGM_BYTE_INVALID 0xFF
#define VGM_WORD_VALID 0
#define VGM_WORD_INVALID 0xFFFFFFFF
#define VGM_EFLAGS_VALID 0xFFFFFFFE
#define VGM_EFLAGS_INVALID 0xFFFFFFFF /* not used */
static void init_shadow_memory ( void )
{
Int i;
for (i = 0; i < 8192; i++) /* Invalid address */
distinguished_secondary_map.abits[i] = VGM_BYTE_INVALID;
/* These entries gradually get overwritten as the used address
space expands. */
for (i = 0; i < 65536; i++)
primary_map[i] = &distinguished_secondary_map;
/* These ones should never change; it's a bug in Valgrind if they do. */
for (i = 65536; i < 262144; i++)
primary_map[i] = &distinguished_secondary_map;
}
void SK_(post_clo_init) ( void )
{
}
void SK_(fini) ( void )
{
VG_(print_malloc_stats)();
if (VG_(clo_verbosity) == 1) {
if (!SK_(clo_leak_check))
VG_(message)(Vg_UserMsg,
"For a detailed leak analysis, rerun with: --leak-check=yes");
VG_(message)(Vg_UserMsg,
"For counts of detected errors, rerun with: -v");
}
if (SK_(clo_leak_check)) SK_(detect_memory_leaks)();
done_prof_mem();
}
/*------------------------------------------------------------*/
/*--- Basic bitmap management, reading and writing. ---*/
/*------------------------------------------------------------*/
/* Allocate and initialise a secondary map. */
static AcSecMap* alloc_secondary_map ( __attribute__ ((unused))
Char* caller )
{
AcSecMap* map;
UInt i;
PROF_EVENT(10);
/* Mark all bytes as invalid access and invalid value. */
/* It just happens that a AcSecMap occupies exactly 18 pages --
although this isn't important, so the following assert is
spurious. */
vg_assert(0 == (sizeof(AcSecMap) % VKI_BYTES_PER_PAGE));
map = VG_(get_memory_from_mmap)( sizeof(AcSecMap), caller );
for (i = 0; i < 8192; i++)
map->abits[i] = VGM_BYTE_INVALID; /* Invalid address */
/* VG_(printf)("ALLOC_2MAP(%s)\n", caller ); */
return map;
}
/* Basic reading/writing of the bitmaps, for byte-sized accesses. */
static __inline__ UChar get_abit ( Addr a )
{
AcSecMap* sm = primary_map[a >> 16];
UInt sm_off = a & 0xFFFF;
PROF_EVENT(20);
# if 0
if (IS_DISTINGUISHED_SM(sm))
VG_(message)(Vg_DebugMsg,
"accessed distinguished 2ndary (A)map! 0x%x\n", a);
# endif
return BITARR_TEST(sm->abits, sm_off)
? VGM_BIT_INVALID : VGM_BIT_VALID;
}
static __inline__ void set_abit ( Addr a, UChar abit )
{
AcSecMap* sm;
UInt sm_off;
PROF_EVENT(22);
ENSURE_MAPPABLE(a, "set_abit");
sm = primary_map[a >> 16];
sm_off = a & 0xFFFF;
if (abit)
BITARR_SET(sm->abits, sm_off);
else
BITARR_CLEAR(sm->abits, sm_off);
}
/* Reading/writing of the bitmaps, for aligned word-sized accesses. */
static __inline__ UChar get_abits4_ALIGNED ( Addr a )
{
AcSecMap* sm;
UInt sm_off;
UChar abits8;
PROF_EVENT(24);
# ifdef VG_DEBUG_MEMORY
vg_assert(IS_ALIGNED4_ADDR(a));
# endif
sm = primary_map[a >> 16];
sm_off = a & 0xFFFF;
abits8 = sm->abits[sm_off >> 3];
abits8 >>= (a & 4 /* 100b */); /* a & 4 is either 0 or 4 */
abits8 &= 0x0F;
return abits8;
}
/*------------------------------------------------------------*/
/*--- Setting permissions over address ranges. ---*/
/*------------------------------------------------------------*/
static void set_address_range_perms ( Addr a, UInt len,
UInt example_a_bit )
{
UChar abyte8;
UInt sm_off;
AcSecMap* sm;
PROF_EVENT(30);
if (len == 0)
return;
if (len > 100 * 1000 * 1000) {
VG_(message)(Vg_UserMsg,
"Warning: set address range perms: "
"large range %u, a %d",
len, example_a_bit );
}
VGP_PUSHCC(VgpSetMem);
/* Requests to change permissions of huge address ranges may
indicate bugs in our machinery. 30,000,000 is arbitrary, but so
far all legitimate requests have fallen beneath that size. */
/* 4 Mar 02: this is just stupid; get rid of it. */
/* vg_assert(len < 30000000); */
/* Check the permissions make sense. */
vg_assert(example_a_bit == VGM_BIT_VALID
|| example_a_bit == VGM_BIT_INVALID);
/* In order that we can charge through the address space at 8
bytes/main-loop iteration, make up some perms. */
abyte8 = (example_a_bit << 7)
| (example_a_bit << 6)
| (example_a_bit << 5)
| (example_a_bit << 4)
| (example_a_bit << 3)
| (example_a_bit << 2)
| (example_a_bit << 1)
| (example_a_bit << 0);
# ifdef VG_DEBUG_MEMORY
/* Do it ... */
while (True) {
PROF_EVENT(31);
if (len == 0) break;
set_abit ( a, example_a_bit );
set_vbyte ( a, vbyte );
a++;
len--;
}
# else
/* Slowly do parts preceding 8-byte alignment. */
while (True) {
PROF_EVENT(31);
if (len == 0) break;
if ((a % 8) == 0) break;
set_abit ( a, example_a_bit );
a++;
len--;
}
if (len == 0) {
VGP_POPCC(VgpSetMem);
return;
}
vg_assert((a % 8) == 0 && len > 0);
/* Once aligned, go fast. */
while (True) {
PROF_EVENT(32);
if (len < 8) break;
ENSURE_MAPPABLE(a, "set_address_range_perms(fast)");
sm = primary_map[a >> 16];
sm_off = a & 0xFFFF;
sm->abits[sm_off >> 3] = abyte8;
a += 8;
len -= 8;
}
if (len == 0) {
VGP_POPCC(VgpSetMem);
return;
}
vg_assert((a % 8) == 0 && len > 0 && len < 8);
/* Finish the upper fragment. */
while (True) {
PROF_EVENT(33);
if (len == 0) break;
set_abit ( a, example_a_bit );
a++;
len--;
}
# endif
/* Check that zero page and highest page have not been written to
-- this could happen with buggy syscall wrappers. Today
(2001-04-26) had precisely such a problem with __NR_setitimer. */
vg_assert(SK_(cheap_sanity_check)());
VGP_POPCC(VgpSetMem);
}
/* Set permissions for address ranges ... */
void SK_(make_noaccess) ( Addr a, UInt len )
{
PROF_EVENT(35);
DEBUG("SK_(make_noaccess)(%p, %x)\n", a, len);
set_address_range_perms ( a, len, VGM_BIT_INVALID );
}
void SK_(make_accessible) ( Addr a, UInt len )
{
PROF_EVENT(36);
DEBUG("SK_(make_accessible)(%p, %x)\n", a, len);
set_address_range_perms ( a, len, VGM_BIT_VALID );
}
/* Block-copy permissions (needed for implementing realloc()). */
static void copy_address_range_state ( Addr src, Addr dst, UInt len )
{
UInt i;
DEBUG("copy_address_range_state\n");
PROF_EVENT(40);
for (i = 0; i < len; i++) {
UChar abit = get_abit ( src+i );
PROF_EVENT(41);
set_abit ( dst+i, abit );
}
}
/* Check permissions for address range. If inadequate permissions
exist, *bad_addr is set to the offending address, so the caller can
know what it is. */
Bool SK_(check_writable) ( Addr a, UInt len, Addr* bad_addr )
{
UInt i;
UChar abit;
PROF_EVENT(42);
for (i = 0; i < len; i++) {
PROF_EVENT(43);
abit = get_abit(a);
if (abit == VGM_BIT_INVALID) {
if (bad_addr != NULL) *bad_addr = a;
return False;
}
a++;
}
return True;
}
Bool SK_(check_readable) ( Addr a, UInt len, Addr* bad_addr )
{
UInt i;
UChar abit;
PROF_EVENT(44);
DEBUG("SK_(check_readable)\n");
for (i = 0; i < len; i++) {
abit = get_abit(a);
PROF_EVENT(45);
if (abit != VGM_BIT_VALID) {
if (bad_addr != NULL) *bad_addr = a;
return False;
}
a++;
}
return True;
}
/* Check a zero-terminated ascii string. Tricky -- don't want to
examine the actual bytes, to find the end, until we're sure it is
safe to do so. */
Bool SK_(check_readable_asciiz) ( Addr a, Addr* bad_addr )
{
UChar abit;
PROF_EVENT(46);
DEBUG("SK_(check_readable_asciiz)\n");
while (True) {
PROF_EVENT(47);
abit = get_abit(a);
if (abit != VGM_BIT_VALID) {
if (bad_addr != NULL) *bad_addr = a;
return False;
}
/* Ok, a is safe to read. */
if (* ((UChar*)a) == 0) return True;
a++;
}
}
/*------------------------------------------------------------*/
/*--- Memory event handlers ---*/
/*------------------------------------------------------------*/
/* Setting permissions for aligned words. This supports fast stack
operations. */
static void make_noaccess_aligned ( Addr a, UInt len )
{
AcSecMap* sm;
UInt sm_off;
UChar mask;
Addr a_past_end = a + len;
VGP_PUSHCC(VgpSetMem);
PROF_EVENT(50);
# ifdef VG_DEBUG_MEMORY
vg_assert(IS_ALIGNED4_ADDR(a));
vg_assert(IS_ALIGNED4_ADDR(len));
# endif
for ( ; a < a_past_end; a += 4) {
ENSURE_MAPPABLE(a, "make_noaccess_aligned");
sm = primary_map[a >> 16];
sm_off = a & 0xFFFF;
mask = 0x0F;
mask <<= (a & 4 /* 100b */); /* a & 4 is either 0 or 4 */
/* mask now contains 1s where we wish to make address bits
invalid (1s). */
sm->abits[sm_off >> 3] |= mask;
}
VGP_POPCC(VgpSetMem);
}
static void make_writable_aligned ( Addr a, UInt len )
{
AcSecMap* sm;
UInt sm_off;
UChar mask;
Addr a_past_end = a + len;
VGP_PUSHCC(VgpSetMem);
PROF_EVENT(51);
# ifdef VG_DEBUG_MEMORY
vg_assert(IS_ALIGNED4_ADDR(a));
vg_assert(IS_ALIGNED4_ADDR(len));
# endif
for ( ; a < a_past_end; a += 4) {
ENSURE_MAPPABLE(a, "make_writable_aligned");
sm = primary_map[a >> 16];
sm_off = a & 0xFFFF;
mask = 0x0F;
mask <<= (a & 4 /* 100b */); /* a & 4 is either 0 or 4 */
/* mask now contains 1s where we wish to make address bits
invalid (0s). */
sm->abits[sm_off >> 3] &= ~mask;
}
VGP_POPCC(VgpSetMem);
}
static
void check_is_writable ( CorePart part, ThreadState* tst,
Char* s, UInt base, UInt size )
{
Bool ok;
Addr bad_addr;
VGP_PUSHCC(VgpCheckMem);
/* VG_(message)(Vg_DebugMsg,"check is writable: %x .. %x",
base,base+size-1); */
ok = SK_(check_writable) ( base, size, &bad_addr );
if (!ok) {
switch (part) {
case Vg_CoreSysCall:
SK_(record_param_error) ( tst, bad_addr, /*isWrite =*/True, s );
break;
case Vg_CorePThread:
case Vg_CoreSignal:
SK_(record_core_mem_error)( tst, /*isWrite=*/True, s );
break;
default:
VG_(panic)("check_is_readable: Unknown or unexpected CorePart");
}
}
VGP_POPCC(VgpCheckMem);
}
static
void check_is_readable ( CorePart part, ThreadState* tst,
Char* s, UInt base, UInt size )
{
Bool ok;
Addr bad_addr;
VGP_PUSHCC(VgpCheckMem);
/* VG_(message)(Vg_DebugMsg,"check is readable: %x .. %x",
base,base+size-1); */
ok = SK_(check_readable) ( base, size, &bad_addr );
if (!ok) {
switch (part) {
case Vg_CoreSysCall:
SK_(record_param_error) ( tst, bad_addr, /*isWrite =*/False, s );
break;
case Vg_CorePThread:
SK_(record_core_mem_error)( tst, /*isWrite=*/False, s );
break;
/* If we're being asked to jump to a silly address, record an error
message before potentially crashing the entire system. */
case Vg_CoreTranslate:
SK_(record_jump_error)( tst, bad_addr );
break;
default:
VG_(panic)("check_is_readable: Unknown or unexpected CorePart");
}
}
VGP_POPCC(VgpCheckMem);
}
static
void check_is_readable_asciiz ( CorePart part, ThreadState* tst,
Char* s, UInt str )
{
Bool ok = True;
Addr bad_addr;
/* VG_(message)(Vg_DebugMsg,"check is readable asciiz: 0x%x",str); */
VGP_PUSHCC(VgpCheckMem);
vg_assert(part == Vg_CoreSysCall);
ok = SK_(check_readable_asciiz) ( (Addr)str, &bad_addr );
if (!ok) {
SK_(record_param_error) ( tst, bad_addr, /*is_writable =*/False, s );
}
VGP_POPCC(VgpCheckMem);
}
static
void addrcheck_new_mem_startup( Addr a, UInt len, Bool rr, Bool ww, Bool xx )
{
// JJJ: this ignores the permissions and just makes it readable, like the
// old code did, AFAICT
DEBUG("new_mem_startup(%p, %u, rr=%u, ww=%u, xx=%u)\n", a,len,rr,ww,xx);
SK_(make_accessible)(a, len);
}
static
void addrcheck_new_mem_heap ( Addr a, UInt len, Bool is_inited )
{
SK_(make_accessible)(a, len);
}
static
void addrcheck_set_perms (Addr a, UInt len,
Bool nn, Bool rr, Bool ww, Bool xx)
{
DEBUG("addrcheck_set_perms(%p, %u, nn=%u, rr=%u ww=%u, xx=%u)\n",
a, len, nn, rr, ww, xx);
if (rr || ww || xx) {
SK_(make_accessible)(a, len);
} else {
SK_(make_noaccess)(a, len);
}
}
/*------------------------------------------------------------*/
/*--- Functions called directly from generated code. ---*/
/*------------------------------------------------------------*/
static __inline__ UInt rotateRight16 ( UInt x )
{
/* Amazingly, gcc turns this into a single rotate insn. */
return (x >> 16) | (x << 16);
}
static __inline__ UInt shiftRight16 ( UInt x )
{
return x >> 16;
}
/* Read/write 1/2/4 sized V bytes, and emit an address error if
needed. */
/* SK_(helperc_ACCESS{1,2,4}) handle the common case fast.
Under all other circumstances, it defers to the relevant _SLOWLY
function, which can handle all situations.
*/
__attribute__ ((regparm(1)))
void SK_(helperc_ACCESS4) ( Addr a )
{
# ifdef VG_DEBUG_MEMORY
return vgmext_ACCESS4_SLOWLY(a);
# else
UInt sec_no = rotateRight16(a) & 0x3FFFF;
AcSecMap* sm = primary_map[sec_no];
UInt a_off = (a & 0xFFFF) >> 3;
UChar abits = sm->abits[a_off];
abits >>= (a & 4);
abits &= 15;
PROF_EVENT(60);
if (abits == VGM_NIBBLE_VALID) {
/* Handle common case quickly: a is suitably aligned, is mapped,
and is addressible. So just return. */
return;
} else {
/* Slow but general case. */
vgmext_ACCESS4_SLOWLY(a);
}
# endif
}
__attribute__ ((regparm(1)))
void SK_(helperc_ACCESS2) ( Addr a )
{
# ifdef VG_DEBUG_MEMORY
return vgmext_ACCESS2_SLOWLY(a);
# else
UInt sec_no = rotateRight16(a) & 0x1FFFF;
AcSecMap* sm = primary_map[sec_no];
UInt a_off = (a & 0xFFFF) >> 3;
PROF_EVENT(62);
if (sm->abits[a_off] == VGM_BYTE_VALID) {
/* Handle common case quickly. */
return;
} else {
/* Slow but general case. */
vgmext_ACCESS2_SLOWLY(a);
}
# endif
}
__attribute__ ((regparm(1)))
void SK_(helperc_ACCESS1) ( Addr a )
{
# ifdef VG_DEBUG_MEMORY
return vgmext_ACCESS1_SLOWLY(a);
# else
UInt sec_no = shiftRight16(a);
AcSecMap* sm = primary_map[sec_no];
UInt a_off = (a & 0xFFFF) >> 3;
PROF_EVENT(64);
if (sm->abits[a_off] == VGM_BYTE_VALID) {
/* Handle common case quickly. */
return;
} else {
/* Slow but general case. */
vgmext_ACCESS1_SLOWLY(a);
}
# endif
}
/*------------------------------------------------------------*/
/*--- Fallback functions to handle cases that the above ---*/
/*--- VG_(helperc_ACCESS{1,2,4}) can't manage. ---*/
/*------------------------------------------------------------*/
static void vgmext_ACCESS4_SLOWLY ( Addr a )
{
Bool a0ok, a1ok, a2ok, a3ok;
PROF_EVENT(70);
/* First establish independently the addressibility of the 4 bytes
involved. */
a0ok = get_abit(a+0) == VGM_BIT_VALID;
a1ok = get_abit(a+1) == VGM_BIT_VALID;
a2ok = get_abit(a+2) == VGM_BIT_VALID;
a3ok = get_abit(a+3) == VGM_BIT_VALID;
/* Now distinguish 3 cases */
/* Case 1: the address is completely valid, so:
- no addressing error
*/
if (a0ok && a1ok && a2ok && a3ok) {
return;
}
/* Case 2: the address is completely invalid.
- emit addressing error
*/
/* VG_(printf)("%p (%d %d %d %d)\n", a, a0ok, a1ok, a2ok, a3ok); */
if (!SK_(clo_partial_loads_ok)
|| ((a & 3) != 0)
|| (!a0ok && !a1ok && !a2ok && !a3ok)) {
sk_record_address_error( a, 4, False );
return;
}
/* Case 3: the address is partially valid.
- no addressing error
Case 3 is only allowed if SK_(clo_partial_loads_ok) is True
(which is the default), and the address is 4-aligned.
If not, Case 2 will have applied.
*/
vg_assert(SK_(clo_partial_loads_ok));
{
return;
}
}
static void vgmext_ACCESS2_SLOWLY ( Addr a )
{
/* Check the address for validity. */
Bool aerr = False;
PROF_EVENT(72);
if (get_abit(a+0) != VGM_BIT_VALID) aerr = True;
if (get_abit(a+1) != VGM_BIT_VALID) aerr = True;
/* If an address error has happened, report it. */
if (aerr) {
sk_record_address_error( a, 2, False );
}
}
static void vgmext_ACCESS1_SLOWLY ( Addr a )
{
/* Check the address for validity. */
Bool aerr = False;
PROF_EVENT(74);
if (get_abit(a+0) != VGM_BIT_VALID) aerr = True;
/* If an address error has happened, report it. */
if (aerr) {
sk_record_address_error( a, 1, False );
}
}
/* ---------------------------------------------------------------------
FPU load and store checks, called from generated code.
------------------------------------------------------------------ */
__attribute__ ((regparm(2)))
void SK_(fpu_ACCESS_check) ( Addr addr, Int size )
{
/* Ensure the read area is both addressible and valid (ie,
readable). If there's an address error, don't report a value
error too; but if there isn't an address error, check for a
value error.
Try to be reasonably fast on the common case; wimp out and defer
to fpu_ACCESS_check_SLOWLY for everything else. */
AcSecMap* sm;
UInt sm_off, a_off;
Addr addr4;
PROF_EVENT(80);
# ifdef VG_DEBUG_MEMORY
fpu_ACCESS_check_SLOWLY ( addr, size );
# else
if (size == 4) {
if (!IS_ALIGNED4_ADDR(addr)) goto slow4;
PROF_EVENT(81);
/* Properly aligned. */
sm = primary_map[addr >> 16];
sm_off = addr & 0xFFFF;
a_off = sm_off >> 3;
if (sm->abits[a_off] != VGM_BYTE_VALID) goto slow4;
/* Properly aligned and addressible. */
return;
slow4:
fpu_ACCESS_check_SLOWLY ( addr, 4 );
return;
}
if (size == 8) {
if (!IS_ALIGNED4_ADDR(addr)) goto slow8;
PROF_EVENT(82);
/* Properly aligned. Do it in two halves. */
addr4 = addr + 4;
/* First half. */
sm = primary_map[addr >> 16];
sm_off = addr & 0xFFFF;
a_off = sm_off >> 3;
if (sm->abits[a_off] != VGM_BYTE_VALID) goto slow8;
/* First half properly aligned and addressible. */
/* Second half. */
sm = primary_map[addr4 >> 16];
sm_off = addr4 & 0xFFFF;
a_off = sm_off >> 3;
if (sm->abits[a_off] != VGM_BYTE_VALID) goto slow8;
/* Second half properly aligned and addressible. */
/* Both halves properly aligned and addressible. */
return;
slow8:
fpu_ACCESS_check_SLOWLY ( addr, 8 );
return;
}
/* Can't be bothered to huff'n'puff to make these (allegedly) rare
cases go quickly. */
if (size == 2) {
PROF_EVENT(83);
fpu_ACCESS_check_SLOWLY ( addr, 2 );
return;
}
if (size == 10) {
PROF_EVENT(84);
fpu_ACCESS_check_SLOWLY ( addr, 10 );
return;
}
if (size == 28 || size == 108) {
PROF_EVENT(84); /* XXX assign correct event number */
fpu_ACCESS_check_SLOWLY ( addr, size );
return;
}
VG_(printf)("size is %d\n", size);
VG_(panic)("fpu_ACCESS_check: unhandled size");
# endif
}
/* ---------------------------------------------------------------------
Slow, general cases for FPU access checks.
------------------------------------------------------------------ */
void fpu_ACCESS_check_SLOWLY ( Addr addr, Int size )
{
Int i;
Bool aerr = False;
PROF_EVENT(90);
for (i = 0; i < size; i++) {
PROF_EVENT(91);
if (get_abit(addr+i) != VGM_BIT_VALID)
aerr = True;
}
if (aerr) {
sk_record_address_error( addr, size, False );
}
}
/*------------------------------------------------------------*/
/*--- Shadow chunks info ---*/
/*------------------------------------------------------------*/
static __inline__
void set_where( ShadowChunk* sc, ExeContext* ec )
{
sc->skin_extra[0] = (UInt)ec;
}
static __inline__
ExeContext *get_where( ShadowChunk* sc )
{
return (ExeContext*)sc->skin_extra[0];
}
void SK_(complete_shadow_chunk) ( ShadowChunk* sc, ThreadState* tst )
{
set_where( sc, VG_(get_ExeContext) ( tst ) );
}
/*------------------------------------------------------------*/
/*--- Postponing free()ing ---*/
/*------------------------------------------------------------*/
/* Holds blocks after freeing. */
static ShadowChunk* vg_freed_list_start = NULL;
static ShadowChunk* vg_freed_list_end = NULL;
static Int vg_freed_list_volume = 0;
static __attribute__ ((unused))
Int count_freelist ( void )
{
ShadowChunk* sc;
Int n = 0;
for (sc = vg_freed_list_start; sc != NULL; sc = sc->next)
n++;
return n;
}
static __attribute__ ((unused))
void freelist_sanity ( void )
{
ShadowChunk* sc;
Int n = 0;
/* VG_(printf)("freelist sanity\n"); */
for (sc = vg_freed_list_start; sc != NULL; sc = sc->next)
n += sc->size;
vg_assert(n == vg_freed_list_volume);
}
/* Put a shadow chunk on the freed blocks queue, possibly freeing up
some of the oldest blocks in the queue at the same time. */
static void add_to_freed_queue ( ShadowChunk* sc )
{
ShadowChunk* sc1;
/* Put it at the end of the freed list */
if (vg_freed_list_end == NULL) {
vg_assert(vg_freed_list_start == NULL);
vg_freed_list_end = vg_freed_list_start = sc;
vg_freed_list_volume = sc->size;
} else {
vg_assert(vg_freed_list_end->next == NULL);
vg_freed_list_end->next = sc;
vg_freed_list_end = sc;
vg_freed_list_volume += sc->size;
}
sc->next = NULL;
/* Release enough of the oldest blocks to bring the free queue
volume below vg_clo_freelist_vol. */
while (vg_freed_list_volume > SK_(clo_freelist_vol)) {
/* freelist_sanity(); */
vg_assert(vg_freed_list_start != NULL);
vg_assert(vg_freed_list_end != NULL);
sc1 = vg_freed_list_start;
vg_freed_list_volume -= sc1->size;
/* VG_(printf)("volume now %d\n", vg_freed_list_volume); */
vg_assert(vg_freed_list_volume >= 0);
if (vg_freed_list_start == vg_freed_list_end) {
vg_freed_list_start = vg_freed_list_end = NULL;
} else {
vg_freed_list_start = sc1->next;
}
sc1->next = NULL; /* just paranoia */
VG_(freeShadowChunk) ( sc1 );
}
}
/* Return the first shadow chunk satisfying the predicate p. */
ShadowChunk* SK_(any_matching_freed_ShadowChunks)
( Bool (*p) ( ShadowChunk* ))
{
ShadowChunk* sc;
/* No point looking through freed blocks if we're not keeping
them around for a while... */
for (sc = vg_freed_list_start; sc != NULL; sc = sc->next)
if (p(sc))
return sc;
return NULL;
}
void SK_(alt_free) ( ShadowChunk* sc, ThreadState* tst )
{
/* Record where freed */
set_where( sc, VG_(get_ExeContext) ( tst ) );
/* Put it out of harm's way for a while. */
add_to_freed_queue ( sc );
}
/*------------------------------------------------------------*/
/*--- Our instrumenter ---*/
/*------------------------------------------------------------*/
#define uInstr1 VG_(newUInstr1)
#define uInstr2 VG_(newUInstr2)
#define uLiteral VG_(setLiteralField)
#define newTemp VG_(getNewTemp)
UCodeBlock* SK_(instrument)(UCodeBlock* cb_in, Addr orig_addr)
{
/* Use this rather than eg. -1 because it's a UInt. */
#define INVALID_DATA_SIZE 999999
UCodeBlock* cb;
Int i;
UInstr* u_in;
Int t_addr, t_size;
cb = VG_(allocCodeBlock)();
cb->nextTemp = cb_in->nextTemp;
for (i = 0; i < cb_in->used; i++) {
t_addr = t_size = INVALID_TEMPREG;
u_in = &cb_in->instrs[i];
switch (u_in->opcode) {
case NOP: case CALLM_E: case CALLM_S:
break;
/* For memory-ref instrs, copy the data_addr into a temporary to be
* passed to the cachesim_* helper at the end of the instruction.
*/
case LOAD:
t_addr = u_in->val1;
goto do_LOAD_or_STORE;
case STORE: t_addr = u_in->val2;
goto do_LOAD_or_STORE;
do_LOAD_or_STORE:
uInstr1(cb, CCALL, 0, TempReg, t_addr);
switch (u_in->size) {
case 4: VG_(setCCallFields)(cb, (Addr)&SK_(helperc_ACCESS4),
1, 1, False );
break;
case 2: VG_(setCCallFields)(cb, (Addr)&SK_(helperc_ACCESS2),
1, 1, False );
break;
case 1: VG_(setCCallFields)(cb, (Addr)&SK_(helperc_ACCESS1),
1, 1, False );
break;
default:
VG_(panic)("addrcheck::SK_(instrument):LOAD/STORE");
}
VG_(copyUInstr)(cb, u_in);
break;
case FPU_R:
case FPU_W:
t_addr = u_in->val2;
t_size = newTemp(cb);
uInstr2(cb, MOV, 4, Literal, 0, TempReg, t_size);
uLiteral(cb, u_in->size);
uInstr2(cb, CCALL, 0, TempReg, t_addr, TempReg, t_size);
VG_(setCCallFields)(cb, (Addr)&SK_(fpu_ACCESS_check),
2, 2, False );
VG_(copyUInstr)(cb, u_in);
break;
default:
VG_(copyUInstr)(cb, u_in);
break;
}
}
VG_(freeCodeBlock)(cb_in);
return cb;
}
/*------------------------------------------------------------*/
/*--- Low-level address-space scanning, for the leak ---*/
/*--- detector. ---*/
/*------------------------------------------------------------*/
static
jmp_buf memscan_jmpbuf;
static
void vg_scan_all_valid_memory_sighandler ( Int sigNo )
{
__builtin_longjmp(memscan_jmpbuf, 1);
}
/* Safely (avoiding SIGSEGV / SIGBUS) scan the entire valid address
space and pass the addresses and values of all addressible,
defined, aligned words to notify_word. This is the basis for the
leak detector. Returns the number of calls made to notify_word. */
UInt VG_(scan_all_valid_memory) ( void (*notify_word)( Addr, UInt ) )
{
/* All volatile, because some gccs seem paranoid about longjmp(). */
volatile UInt res, numPages, page, primaryMapNo, nWordsNotified;
volatile Addr pageBase, addr;
volatile AcSecMap* sm;
volatile UChar abits;
volatile UInt page_first_word;
vki_ksigaction sigbus_saved;
vki_ksigaction sigbus_new;
vki_ksigaction sigsegv_saved;
vki_ksigaction sigsegv_new;
vki_ksigset_t blockmask_saved;
vki_ksigset_t unblockmask_new;
/* Temporarily install a new sigsegv and sigbus handler, and make
sure SIGBUS, SIGSEGV and SIGTERM are unblocked. (Perhaps the
first two can never be blocked anyway?) */
sigbus_new.ksa_handler = vg_scan_all_valid_memory_sighandler;
sigbus_new.ksa_flags = VKI_SA_ONSTACK | VKI_SA_RESTART;
sigbus_new.ksa_restorer = NULL;
res = VG_(ksigemptyset)( &sigbus_new.ksa_mask );
vg_assert(res == 0);
sigsegv_new.ksa_handler = vg_scan_all_valid_memory_sighandler;
sigsegv_new.ksa_flags = VKI_SA_ONSTACK | VKI_SA_RESTART;
sigsegv_new.ksa_restorer = NULL;
res = VG_(ksigemptyset)( &sigsegv_new.ksa_mask );
vg_assert(res == 0+0);
res = VG_(ksigemptyset)( &unblockmask_new );
res |= VG_(ksigaddset)( &unblockmask_new, VKI_SIGBUS );
res |= VG_(ksigaddset)( &unblockmask_new, VKI_SIGSEGV );
res |= VG_(ksigaddset)( &unblockmask_new, VKI_SIGTERM );
vg_assert(res == 0+0+0);
res = VG_(ksigaction)( VKI_SIGBUS, &sigbus_new, &sigbus_saved );
vg_assert(res == 0+0+0+0);
res = VG_(ksigaction)( VKI_SIGSEGV, &sigsegv_new, &sigsegv_saved );
vg_assert(res == 0+0+0+0+0);
res = VG_(ksigprocmask)( VKI_SIG_UNBLOCK, &unblockmask_new, &blockmask_saved );
vg_assert(res == 0+0+0+0+0+0);
/* The signal handlers are installed. Actually do the memory scan. */
numPages = 1 << (32-VKI_BYTES_PER_PAGE_BITS);
vg_assert(numPages == 1048576);
vg_assert(4096 == (1 << VKI_BYTES_PER_PAGE_BITS));
nWordsNotified = 0;
for (page = 0; page < numPages; page++) {
pageBase = page << VKI_BYTES_PER_PAGE_BITS;
primaryMapNo = pageBase >> 16;
sm = primary_map[primaryMapNo];
if (IS_DISTINGUISHED_SM(sm)) continue;
if (__builtin_setjmp(memscan_jmpbuf) == 0) {
/* try this ... */
page_first_word = * (volatile UInt*)pageBase;
/* we get here if we didn't get a fault */
/* Scan the page */
for (addr = pageBase; addr < pageBase+VKI_BYTES_PER_PAGE; addr += 4) {
abits = get_abits4_ALIGNED(addr);
if (abits == VGM_NIBBLE_VALID) {
nWordsNotified++;
notify_word ( addr, *(UInt*)addr );
}
}
} else {
/* We get here if reading the first word of the page caused a
fault, which in turn caused the signal handler to longjmp.
Ignore this page. */
if (0)
VG_(printf)(
"vg_scan_all_valid_memory_sighandler: ignoring page at %p\n",
(void*)pageBase
);
}
}
/* Restore signal state to whatever it was before. */
res = VG_(ksigaction)( VKI_SIGBUS, &sigbus_saved, NULL );
vg_assert(res == 0 +0);
res = VG_(ksigaction)( VKI_SIGSEGV, &sigsegv_saved, NULL );
vg_assert(res == 0 +0 +0);
res = VG_(ksigprocmask)( VKI_SIG_SETMASK, &blockmask_saved, NULL );
vg_assert(res == 0 +0 +0 +0);
return nWordsNotified;
}
/*------------------------------------------------------------*/
/*--- Detecting leaked (unreachable) malloc'd blocks. ---*/
/*------------------------------------------------------------*/
/* A block is either
-- Proper-ly reached; a pointer to its start has been found
-- Interior-ly reached; only an interior pointer to it has been found
-- Unreached; so far, no pointers to any part of it have been found.
*/
typedef
enum { Unreached, Interior, Proper }
Reachedness;
/* A block record, used for generating err msgs. */
typedef
struct _LossRecord {
struct _LossRecord* next;
/* Where these lost blocks were allocated. */
ExeContext* allocated_at;
/* Their reachability. */
Reachedness loss_mode;
/* Number of blocks and total # bytes involved. */
UInt total_bytes;
UInt num_blocks;
}
LossRecord;
/* Find the i such that ptr points at or inside the block described by
shadows[i]. Return -1 if none found. This assumes that shadows[]
has been sorted on the ->data field. */
#ifdef VG_DEBUG_LEAKCHECK
/* Used to sanity-check the fast binary-search mechanism. */
static Int find_shadow_for_OLD ( Addr ptr,
ShadowChunk** shadows,
Int n_shadows )
{
Int i;
Addr a_lo, a_hi;
PROF_EVENT(70);
for (i = 0; i < n_shadows; i++) {
PROF_EVENT(71);
a_lo = shadows[i]->data;
a_hi = ((Addr)shadows[i]->data) + shadows[i]->size - 1;
if (a_lo <= ptr && ptr <= a_hi)
return i;
}
return -1;
}
#endif
static Int find_shadow_for ( Addr ptr,
ShadowChunk** shadows,
Int n_shadows )
{
Addr a_mid_lo, a_mid_hi;
Int lo, mid, hi, retVal;
PROF_EVENT(70);
/* VG_(printf)("find shadow for %p = ", ptr); */
retVal = -1;
lo = 0;
hi = n_shadows-1;
while (True) {
PROF_EVENT(71);
/* invariant: current unsearched space is from lo to hi,
inclusive. */
if (lo > hi) break; /* not found */
mid = (lo + hi) / 2;
a_mid_lo = shadows[mid]->data;
a_mid_hi = ((Addr)shadows[mid]->data) + shadows[mid]->size - 1;
if (ptr < a_mid_lo) {
hi = mid-1;
continue;
}
if (ptr > a_mid_hi) {
lo = mid+1;
continue;
}
vg_assert(ptr >= a_mid_lo && ptr <= a_mid_hi);
retVal = mid;
break;
}
# ifdef VG_DEBUG_LEAKCHECK
vg_assert(retVal == find_shadow_for_OLD ( ptr, shadows, n_shadows ));
# endif
/* VG_(printf)("%d\n", retVal); */
return retVal;
}
static void sort_malloc_shadows ( ShadowChunk** shadows, UInt n_shadows )
{
Int incs[14] = { 1, 4, 13, 40, 121, 364, 1093, 3280,
9841, 29524, 88573, 265720,
797161, 2391484 };
Int lo = 0;
Int hi = n_shadows-1;
Int i, j, h, bigN, hp;
ShadowChunk* v;
PROF_EVENT(72);
bigN = hi - lo + 1; if (bigN < 2) return;
hp = 0; while (incs[hp] < bigN) hp++; hp--;
for (; hp >= 0; hp--) {
PROF_EVENT(73);
h = incs[hp];
i = lo + h;
while (1) {
PROF_EVENT(74);
if (i > hi) break;
v = shadows[i];
j = i;
while (shadows[j-h]->data > v->data) {
PROF_EVENT(75);
shadows[j] = shadows[j-h];
j = j - h;
if (j <= (lo + h - 1)) break;
}
shadows[j] = v;
i++;
}
}
}
/* Globals, for the callback used by SK_(detect_memory_leaks). */
static ShadowChunk** vglc_shadows;
static Int vglc_n_shadows;
static Reachedness* vglc_reachedness;
static Addr vglc_min_mallocd_addr;
static Addr vglc_max_mallocd_addr;
static
void vg_detect_memory_leaks_notify_addr ( Addr a, UInt word_at_a )
{
Int sh_no;
Addr ptr;
/* Rule out some known causes of bogus pointers. Mostly these do
not cause much trouble because only a few false pointers can
ever lurk in these places. This mainly stops it reporting that
blocks are still reachable in stupid test programs like this
int main (void) { char* a = malloc(100); return 0; }
which people seem inordinately fond of writing, for some reason.
Note that this is a complete kludge. It would be better to
ignore any addresses corresponding to valgrind.so's .bss and
.data segments, but I cannot think of a reliable way to identify
where the .bss segment has been put. If you can, drop me a
line.
*/
if (VG_(within_stack)(a)) return;
if (VG_(within_m_state_static)(a)) return;
if (a == (Addr)(&vglc_min_mallocd_addr)) return;
if (a == (Addr)(&vglc_max_mallocd_addr)) return;
/* OK, let's get on and do something Useful for a change. */
ptr = (Addr)word_at_a;
if (ptr >= vglc_min_mallocd_addr && ptr <= vglc_max_mallocd_addr) {
/* Might be legitimate; we'll have to investigate further. */
sh_no = find_shadow_for ( ptr, vglc_shadows, vglc_n_shadows );
if (sh_no != -1) {
/* Found a block at/into which ptr points. */
vg_assert(sh_no >= 0 && sh_no < vglc_n_shadows);
vg_assert(ptr < vglc_shadows[sh_no]->data
+ vglc_shadows[sh_no]->size);
/* Decide whether Proper-ly or Interior-ly reached. */
if (ptr == vglc_shadows[sh_no]->data) {
if (0) VG_(printf)("pointer at %p to %p\n", a, word_at_a );
vglc_reachedness[sh_no] = Proper;
} else {
if (vglc_reachedness[sh_no] == Unreached)
vglc_reachedness[sh_no] = Interior;
}
}
}
}
void SK_(detect_memory_leaks) ( void )
{
Int i;
Int blocks_leaked, bytes_leaked;
Int blocks_dubious, bytes_dubious;
Int blocks_reachable, bytes_reachable;
Int n_lossrecords;
UInt bytes_notified;
LossRecord* errlist;
LossRecord* p;
PROF_EVENT(76);
/* VG_(get_malloc_shadows) allocates storage for shadows */
vglc_shadows = VG_(get_malloc_shadows)( &vglc_n_shadows );
if (vglc_n_shadows == 0) {
vg_assert(vglc_shadows == NULL);
VG_(message)(Vg_UserMsg,
"No malloc'd blocks -- no leaks are possible.\n");
return;
}
VG_(message)(Vg_UserMsg,
"searching for pointers to %d not-freed blocks.",
vglc_n_shadows );
sort_malloc_shadows ( vglc_shadows, vglc_n_shadows );
/* Sanity check; assert that the blocks are now in order and that
they don't overlap. */
for (i = 0; i < vglc_n_shadows-1; i++) {
vg_assert( ((Addr)vglc_shadows[i]->data)
< ((Addr)vglc_shadows[i+1]->data) );
vg_assert( ((Addr)vglc_shadows[i]->data) + vglc_shadows[i]->size
< ((Addr)vglc_shadows[i+1]->data) );
}
vglc_min_mallocd_addr = ((Addr)vglc_shadows[0]->data);
vglc_max_mallocd_addr = ((Addr)vglc_shadows[vglc_n_shadows-1]->data)
+ vglc_shadows[vglc_n_shadows-1]->size - 1;
vglc_reachedness
= VG_(malloc)( vglc_n_shadows * sizeof(Reachedness) );
for (i = 0; i < vglc_n_shadows; i++)
vglc_reachedness[i] = Unreached;
/* Do the scan of memory. */
bytes_notified
= VG_(scan_all_valid_memory)( &vg_detect_memory_leaks_notify_addr )
* VKI_BYTES_PER_WORD;
VG_(message)(Vg_UserMsg, "checked %d bytes.", bytes_notified);
blocks_leaked = bytes_leaked = 0;
blocks_dubious = bytes_dubious = 0;
blocks_reachable = bytes_reachable = 0;
for (i = 0; i < vglc_n_shadows; i++) {
if (vglc_reachedness[i] == Unreached) {
blocks_leaked++;
bytes_leaked += vglc_shadows[i]->size;
}
else if (vglc_reachedness[i] == Interior) {
blocks_dubious++;
bytes_dubious += vglc_shadows[i]->size;
}
else if (vglc_reachedness[i] == Proper) {
blocks_reachable++;
bytes_reachable += vglc_shadows[i]->size;
}
}
VG_(message)(Vg_UserMsg, "");
VG_(message)(Vg_UserMsg, "definitely lost: %d bytes in %d blocks.",
bytes_leaked, blocks_leaked );
VG_(message)(Vg_UserMsg, "possibly lost: %d bytes in %d blocks.",
bytes_dubious, blocks_dubious );
VG_(message)(Vg_UserMsg, "still reachable: %d bytes in %d blocks.",
bytes_reachable, blocks_reachable );
/* Common up the lost blocks so we can print sensible error
messages. */
n_lossrecords = 0;
errlist = NULL;
for (i = 0; i < vglc_n_shadows; i++) {
/* 'where' stored in 'skin_extra' field */
ExeContext* where = get_where ( vglc_shadows[i] );
for (p = errlist; p != NULL; p = p->next) {
if (p->loss_mode == vglc_reachedness[i]
&& VG_(eq_ExeContext) ( SK_(clo_leak_resolution),
p->allocated_at,
where) ) {
break;
}
}
if (p != NULL) {
p->num_blocks ++;
p->total_bytes += vglc_shadows[i]->size;
} else {
n_lossrecords ++;
p = VG_(malloc)(sizeof(LossRecord));
p->loss_mode = vglc_reachedness[i];
p->allocated_at = where;
p->total_bytes = vglc_shadows[i]->size;
p->num_blocks = 1;
p->next = errlist;
errlist = p;
}
}
for (i = 0; i < n_lossrecords; i++) {
LossRecord* p_min = NULL;
UInt n_min = 0xFFFFFFFF;
for (p = errlist; p != NULL; p = p->next) {
if (p->num_blocks > 0 && p->total_bytes < n_min) {
n_min = p->total_bytes;
p_min = p;
}
}
vg_assert(p_min != NULL);
if ( (!SK_(clo_show_reachable)) && p_min->loss_mode == Proper) {
p_min->num_blocks = 0;
continue;
}
VG_(message)(Vg_UserMsg, "");
VG_(message)(
Vg_UserMsg,
"%d bytes in %d blocks are %s in loss record %d of %d",
p_min->total_bytes, p_min->num_blocks,
p_min->loss_mode==Unreached ? "definitely lost" :
(p_min->loss_mode==Interior ? "possibly lost"
: "still reachable"),
i+1, n_lossrecords
);
VG_(pp_ExeContext)(p_min->allocated_at);
p_min->num_blocks = 0;
}
VG_(message)(Vg_UserMsg, "");
VG_(message)(Vg_UserMsg, "LEAK SUMMARY:");
VG_(message)(Vg_UserMsg, " definitely lost: %d bytes in %d blocks.",
bytes_leaked, blocks_leaked );
VG_(message)(Vg_UserMsg, " possibly lost: %d bytes in %d blocks.",
bytes_dubious, blocks_dubious );
VG_(message)(Vg_UserMsg, " still reachable: %d bytes in %d blocks.",
bytes_reachable, blocks_reachable );
if (!SK_(clo_show_reachable)) {
VG_(message)(Vg_UserMsg,
"Reachable blocks (those to which a pointer was found) are not shown.");
VG_(message)(Vg_UserMsg,
"To see them, rerun with: --show-reachable=yes");
}
VG_(message)(Vg_UserMsg, "");
VG_(free) ( vglc_shadows );
VG_(free) ( vglc_reachedness );
}
/* ---------------------------------------------------------------------
Sanity check machinery (permanently engaged).
------------------------------------------------------------------ */
/* Check that nobody has spuriously claimed that the first or last 16
pages (64 KB) of address space have become accessible. Failure of
the following do not per se indicate an internal consistency
problem, but they are so likely to that we really want to know
about it if so. */
Bool SK_(cheap_sanity_check) ( void )
{
if (IS_DISTINGUISHED_SM(primary_map[0]) &&
IS_DISTINGUISHED_SM(primary_map[65535]))
return True;
else
return False;
}
Bool SK_(expensive_sanity_check) ( void )
{
Int i;
/* Make sure nobody changed the distinguished secondary. */
for (i = 0; i < 8192; i++)
if (distinguished_secondary_map.abits[i] != VGM_BYTE_INVALID)
return False;
/* Make sure that the upper 3/4 of the primary map hasn't
been messed with. */
for (i = 65536; i < 262144; i++)
if (primary_map[i] != & distinguished_secondary_map)
return False;
return True;
}
/* ---------------------------------------------------------------------
Debugging machinery (turn on to debug). Something of a mess.
------------------------------------------------------------------ */
#if 0
/* Print the value tags on the 8 integer registers & flag reg. */
static void uint_to_bits ( UInt x, Char* str )
{
Int i;
Int w = 0;
/* str must point to a space of at least 36 bytes. */
for (i = 31; i >= 0; i--) {
str[w++] = (x & ( ((UInt)1) << i)) ? '1' : '0';
if (i == 24 || i == 16 || i == 8)
str[w++] = ' ';
}
str[w++] = 0;
vg_assert(w == 36);
}
/* Caution! Not vthread-safe; looks in VG_(baseBlock), not the thread
state table. */
static void vg_show_reg_tags ( void )
{
Char buf1[36];
Char buf2[36];
UInt z_eax, z_ebx, z_ecx, z_edx,
z_esi, z_edi, z_ebp, z_esp, z_eflags;
z_eax = VG_(baseBlock)[VGOFF_(sh_eax)];
z_ebx = VG_(baseBlock)[VGOFF_(sh_ebx)];
z_ecx = VG_(baseBlock)[VGOFF_(sh_ecx)];
z_edx = VG_(baseBlock)[VGOFF_(sh_edx)];
z_esi = VG_(baseBlock)[VGOFF_(sh_esi)];
z_edi = VG_(baseBlock)[VGOFF_(sh_edi)];
z_ebp = VG_(baseBlock)[VGOFF_(sh_ebp)];
z_esp = VG_(baseBlock)[VGOFF_(sh_esp)];
z_eflags = VG_(baseBlock)[VGOFF_(sh_eflags)];
uint_to_bits(z_eflags, buf1);
VG_(message)(Vg_DebugMsg, "efl %\n", buf1);
uint_to_bits(z_eax, buf1);
uint_to_bits(z_ebx, buf2);
VG_(message)(Vg_DebugMsg, "eax %s ebx %s\n", buf1, buf2);
uint_to_bits(z_ecx, buf1);
uint_to_bits(z_edx, buf2);
VG_(message)(Vg_DebugMsg, "ecx %s edx %s\n", buf1, buf2);
uint_to_bits(z_esi, buf1);
uint_to_bits(z_edi, buf2);
VG_(message)(Vg_DebugMsg, "esi %s edi %s\n", buf1, buf2);
uint_to_bits(z_ebp, buf1);
uint_to_bits(z_esp, buf2);
VG_(message)(Vg_DebugMsg, "ebp %s esp %s\n", buf1, buf2);
}
/* For debugging only. Scan the address space and touch all allegedly
addressible words. Useful for establishing where Valgrind's idea of
addressibility has diverged from what the kernel believes. */
static
void zzzmemscan_notify_word ( Addr a, UInt w )
{
}
void zzzmemscan ( void )
{
Int n_notifies
= VG_(scan_all_valid_memory)( zzzmemscan_notify_word );
VG_(printf)("zzzmemscan: n_bytes = %d\n", 4 * n_notifies );
}
#endif
#if 0
static Int zzz = 0;
void show_bb ( Addr eip_next )
{
VG_(printf)("[%4d] ", zzz);
vg_show_reg_tags( &VG_(m_shadow );
VG_(translate) ( eip_next, NULL, NULL, NULL );
}
#endif /* 0 */
/*------------------------------------------------------------*/
/*--- Syscall wrappers ---*/
/*------------------------------------------------------------*/
void* SK_(pre_syscall) ( ThreadId tid, UInt syscallno, Bool isBlocking )
{
Int sane = SK_(cheap_sanity_check)();
return (void*)sane;
}
void SK_(post_syscall) ( ThreadId tid, UInt syscallno,
void* pre_result, Int res, Bool isBlocking )
{
Int sane_before_call = (Int)pre_result;
Bool sane_after_call = SK_(cheap_sanity_check)();
if ((Int)sane_before_call && (!sane_after_call)) {
VG_(message)(Vg_DebugMsg, "post-syscall: ");
VG_(message)(Vg_DebugMsg,
"probable sanity check failure for syscall number %d\n",
syscallno );
VG_(panic)("aborting due to the above ... bye!");
}
}
/*------------------------------------------------------------*/
/*--- Setup ---*/
/*------------------------------------------------------------*/
void SK_(written_shadow_regs_values)( UInt* gen_reg_value, UInt* eflags_value )
{
*gen_reg_value = VGM_WORD_VALID;
*eflags_value = VGM_EFLAGS_VALID;
}
Bool SK_(process_cmd_line_option)(Char* arg)
{
# define STREQ(s1,s2) (0==VG_(strcmp_ws)((s1),(s2)))
# define STREQN(nn,s1,s2) (0==VG_(strncmp_ws)((s1),(s2),(nn)))
if (STREQ(arg, "--partial-loads-ok=yes"))
SK_(clo_partial_loads_ok) = True;
else if (STREQ(arg, "--partial-loads-ok=no"))
SK_(clo_partial_loads_ok) = False;
else if (STREQN(15, arg, "--freelist-vol=")) {
SK_(clo_freelist_vol) = (Int)VG_(atoll)(&arg[15]);
if (SK_(clo_freelist_vol) < 0) SK_(clo_freelist_vol) = 0;
}
else if (STREQ(arg, "--leak-check=yes"))
SK_(clo_leak_check) = True;
else if (STREQ(arg, "--leak-check=no"))
SK_(clo_leak_check) = False;
else if (STREQ(arg, "--leak-resolution=low"))
SK_(clo_leak_resolution) = Vg_LowRes;
else if (STREQ(arg, "--leak-resolution=med"))
SK_(clo_leak_resolution) = Vg_MedRes;
else if (STREQ(arg, "--leak-resolution=high"))
SK_(clo_leak_resolution) = Vg_HighRes;
else if (STREQ(arg, "--show-reachable=yes"))
SK_(clo_show_reachable) = True;
else if (STREQ(arg, "--show-reachable=no"))
SK_(clo_show_reachable) = False;
else if (STREQ(arg, "--workaround-gcc296-bugs=yes"))
SK_(clo_workaround_gcc296_bugs) = True;
else if (STREQ(arg, "--workaround-gcc296-bugs=no"))
SK_(clo_workaround_gcc296_bugs) = False;
else if (STREQ(arg, "--cleanup=yes"))
SK_(clo_cleanup) = True;
else if (STREQ(arg, "--cleanup=no"))
SK_(clo_cleanup) = False;
else
return False;
return True;
#undef STREQ
#undef STREQN
}
Char* SK_(usage)(void)
{
return
" --partial-loads-ok=no|yes too hard to explain here; see manual [yes]\n"
" --freelist-vol=<number> volume of freed blocks queue [1000000]\n"
" --leak-check=no|yes search for memory leaks at exit? [no]\n"
" --leak-resolution=low|med|high\n"
" amount of bt merging in leak check [low]\n"
" --show-reachable=no|yes show reachable blocks in leak check? [no]\n"
" --workaround-gcc296-bugs=no|yes self explanatory [no]\n"
" --check-addrVs=no|yes experimental lighterweight checking? [yes]\n"
" yes == Valgrind's original behaviour\n"
"\n"
" --cleanup=no|yes improve after instrumentation? [yes]\n";
}
/*------------------------------------------------------------*/
/*--- Setup ---*/
/*------------------------------------------------------------*/
void SK_(pre_clo_init)(VgNeeds* needs, VgTrackEvents* track)
{
needs->name = "addrcheck";
needs->description = "a fine-grained address checker";
needs->core_errors = True;
needs->skin_errors = True;
needs->run_libc_freeres = True;
needs->sizeof_shadow_block = 1;
needs->basic_block_discards = False;
needs->shadow_regs = False;
needs->command_line_options = True;
needs->client_requests = True;
needs->extended_UCode = False;
needs->syscall_wrapper = True;
needs->alternative_free = True;
needs->sanity_checks = True;
VG_(register_compact_helper)((Addr) & SK_(helperc_ACCESS4));
VG_(register_compact_helper)((Addr) & SK_(helperc_ACCESS2));
VG_(register_compact_helper)((Addr) & SK_(helperc_ACCESS1));
VG_(register_compact_helper)((Addr) & SK_(fpu_ACCESS_check));
/* Events to track */
track->new_mem_startup = & addrcheck_new_mem_startup;
track->new_mem_heap = & addrcheck_new_mem_heap;
track->new_mem_stack = & SK_(make_accessible);
track->new_mem_stack_aligned = & make_writable_aligned;
track->new_mem_stack_signal = & SK_(make_accessible);
track->new_mem_brk = & SK_(make_accessible);
track->new_mem_mmap = & addrcheck_set_perms;
track->copy_mem_heap = & copy_address_range_state;
track->copy_mem_remap = & copy_address_range_state;
track->change_mem_mprotect = & addrcheck_set_perms;
track->ban_mem_heap = & SK_(make_noaccess);
track->ban_mem_stack = & SK_(make_noaccess);
track->die_mem_heap = & SK_(make_noaccess);
track->die_mem_stack = & SK_(make_noaccess);
track->die_mem_stack_aligned = & make_noaccess_aligned;
track->die_mem_stack_signal = & SK_(make_noaccess);
track->die_mem_brk = & SK_(make_noaccess);
track->die_mem_munmap = & SK_(make_noaccess);
track->bad_free = & SK_(record_free_error);
track->mismatched_free = & SK_(record_freemismatch_error);
track->pre_mem_read = & check_is_readable;
track->pre_mem_read_asciiz = & check_is_readable_asciiz;
track->pre_mem_write = & check_is_writable;
track->post_mem_write = & SK_(make_accessible);
init_shadow_memory();
init_prof_mem();
VGP_(register_profile_event) ( VgpSetMem, "set-mem-perms" );
VGP_(register_profile_event) ( VgpCheckMem, "check-mem-perms" );
}
/*--------------------------------------------------------------------*/
/*--- end ac_main.c ---*/
/*--------------------------------------------------------------------*/
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