static unsigned long int _stol( const CHAR_TYPE *nptr,CHAR_TYPE **endptr,int base,int who)
{
const CHAR_TYPE *p;
const CHAR_TYPE *startp;
int digit;
unsigned long int value;
unsigned long int prev_value;
CHAR_TYPE sign;
char overflow; /*overflow is used as a flag so it does not
*need to be of type CHAR_TYPE */
if( endptr != NULL ) *endptr = (CHAR_TYPE *)nptr;
p = nptr;
while( __F_NAME(isspace,iswspace)(*p) ) ++p;
sign = *p;
if( sign == '+' || sign == '-' ) ++p;
if( base == 0 ) {
if( hexstr(p) ) base = 16;
else if( *p == '0' ) base = 8;
else base = 10;
}
if( base < 2 || base > 36 ) {
__set_errno( EDOM );
return( 0 );
}
if( base == 16 ) {
if( hexstr(p) ) p += 2; /* skip over '0x' */
}
startp = p;
overflow = 0;
value = 0;
for(;;) {
digit = radix_value( *p );
if( digit >= base ) break;
if( value > nearly_overflowing[base-2] ) overflow = 1;
prev_value = value;
value = value * base + digit;
if( value < prev_value ) overflow = 1;
++p;
}
if( p == startp ) p = nptr;
if( endptr != NULL ) *endptr = (CHAR_TYPE *)p;
if( who == 1 ) {
if( value >= 0x80000000 ) {
if( value == 0x80000000 && sign == '-' ) {
; /* OK */
} else {
overflow = 1;
}
}
}
if( overflow ) {
__set_errno( ERANGE );
if( who == 0 ) return( ULONG_MAX );
if( sign == '-' ) return( LONG_MIN );
return( LONG_MAX );
}
if( sign == '-' ) value = - value;
return( value );
}
paddr_t
strtopaddr(const char *nptr, char **endptr, int base) {
const char *p;
const char *startp;
int digit;
paddr_t value;
if(endptr != NULL) *endptr = (char *)nptr;
p = nptr;
if(base == 0) {
if(hexstr(p)) base = 16;
else if(*p == '0') base = 8;
else base = 10;
}
if(base == 16) {
if(hexstr(p)) p += 2; /* skip over '0x' */
}
startp = p;
value = 0;
for(;;) {
digit = radix_value(*p);
if(digit >= base) break;
value = value * base + digit;
++p;
}
if(p == startp) p = nptr;
if(endptr != NULL) *endptr = (char *)p;
return value;
}
gboolean simpleprng_verify_buffer(
simpleprng_state_t *state,
gpointer buf,
size_t len)
{
guint8 *p = buf;
while (len--) {
guint64 count = state->count;
guint8 expected = simpleprng_rand_byte(state);
guint8 got = *p;
if (expected != got) {
int remaining = MIN(len, 16);
guint8 expbytes[16] = { expected };
char *gotstr = hexstr(p, remaining);
char *expstr;
int i;
for (i = 1; i < remaining; i++)
expbytes[i] = simpleprng_rand_byte(state);
expstr = hexstr(expbytes, remaining);
g_fprintf(stderr,
"random value mismatch at offset %ju: got %s, expected %s\n",
(uintmax_t)count, gotstr, expstr);
g_free(gotstr);
g_free(expstr);
return FALSE;
}
p++;
}
return TRUE;
}
VOID PageTest()
{
ADDRINT addr = 0x123456;
string pageAddr1 = hexstr(GetPageOfAddr(addr));
string pageAddr2 = ptrstr(MemPageRange((void*)addr).Base());
TEST(pageAddr1 == pageAddr2, "GetPageOfAddr or MemPageRange failed");
}
void
load_file_ino(ino32_t ino, const char *fn, uintptr_t loadadr, unsigned interactive, int part)
/* fn: for message only */
{
union ufs_dinode dinode;
size_t sz;
struct loadinfo inf;
char buf[32];
if (ino == 0 || ufs_get_inode(ino, &dinode))
return; /* not found */
print(str_loading); /* "loading " */
print(fn);
print(str_at); /* " at 0x" */
print(hexstr(buf, loadadr));
print(str_dddot); /* "..." */
sz = DI_SIZE(&dinode);
ufs_read(&dinode, (void *) loadadr, 0, sz);
print(str_done); /* "done\r\n" */
/* digest executable format */
inf.sec_size = sz;
inf.entry_offset = 0;
if (xi_load(&inf, (void *) loadadr)) {
print(fn);
print(str_ukfmt); /* ": unknown format -- exec from top\r\n" */
}
/* pass control to the secondary boot */
dispatch(interactive, loadadr, loadadr + inf.sec_size, part,
loadadr + inf.entry_offset);
}
static int
cmdreq(Dev *d, int type, int req, int value, int index, uchar *data, int count)
{
int ndata, n;
uchar *wp;
uchar buf[8];
char *hd, *rs;
assert(d != nil);
if(data == nil){
wp = buf;
ndata = 0;
}else{
ndata = count;
wp = emallocz(8+ndata, 0);
}
wp[0] = type;
wp[1] = req;
PUT2(wp+2, value);
PUT2(wp+4, index);
PUT2(wp+6, count);
if(data != nil)
memmove(wp+8, data, ndata);
if(usbdebug>2){
hd = hexstr(wp, ndata+8);
rs = reqstr(type, req);
fprint(2, "%s: %s val %d|%d idx %d cnt %d out[%d] %s\n",
d->dir, rs, value>>8, value&0xFF,
index, count, ndata+8, hd);
free(hd);
}
static VOID foo_after(ADDRINT returnIp)
{
printf("foo after called\n");
// May not be executed if exception occurs in previous statement
printf("Caller IP = %s\n", hexstr(returnIp).c_str());
}
static char*
seprintconf(char *s, char *e, Usbdev *d, int ci)
{
int i;
Conf *c;
char *hd;
c = d->conf[ci];
s = seprint(s, e, "\tconf: cval %d attrib %x %d mA\n",
c->cval, c->attrib, c->milliamps);
for(i = 0; i < Niface; i++)
if(c->iface[i] == nil)
break;
else
s = seprintiface(s, e, c->iface[i]);
for(i = 0; i < Nddesc; i++)
if(d->ddesc[i] == nil)
break;
else if(d->ddesc[i]->conf == c){
hd = hexstr((uint8_t*)&d->ddesc[i]->data,
d->ddesc[i]->data.bLength);
s = seprint(s, e, "\t\tdev desc %x[%d]: %s\n",
d->ddesc[i]->data.bDescriptorType,
d->ddesc[i]->data.bLength, hd);
free(hd);
}
return s;
}
int quoted(char **pp) /* pick up next thing after a \\ */
/* and increment *pp */
{
char *p = *pp;
int c;
if ((c = *p++) == 't')
c = '\t';
else if (c == 'n')
c = '\n';
else if (c == 'f')
c = '\f';
else if (c == 'r')
c = '\r';
else if (c == 'b')
c = '\b';
else if (c == '\\')
c = '\\';
else if (c == 'x') { /* hexadecimal goo follows */
c = hexstr(&p); /* this adds a null if number is invalid */
} else if (isoctdigit(c)) { /* \d \dd \ddd */
int n = c - '0';
if (isoctdigit(*p)) {
n = 8 * n + *p++ - '0';
if (isoctdigit(*p))
n = 8 * n + *p++ - '0';
}
c = n;
} /* else */
/* c = c; */
*pp = p;
return c;
}
VOID CheckFlagsNoInline(ADDRINT app_flags)
{
if ((app_flags & FLAGSET) != FLAGSET)
{
cerr << "Noinline failed: app_flags= " << hexstr(app_flags) << endl;
exit(-1);
}
}
string StringUtil::toHEX(unsigned int number)
{
char hexVal[20];
sprintf(hexVal, "%x", number);
string hexstr(hexVal);
memset(&hexVal[0], 0, sizeof(hexVal));
return hexstr;
}
string StringUtil::toOCTAL(unsigned long long number)
{
char hexVal[20];
sprintf(hexVal, "%llo", number);
string hexstr(hexVal);
memset(&hexVal[0], 0, sizeof(hexVal));
return hexstr;
}
// protect a page read-only
VOID SANDBOX::ProtectPage(const char * page)
{
int result = mprotect(const_cast<char *>(page), PageSize, PROT_READ);
if (result != 0)
{
Error("Can't read-protect page " + hexstr(page) + "\n" + strerror(errno));
}
}
/* We simply allocate space for the dis-assembled instruction strings and
* let them leak.
*/
static char const * formatInstruction(INS ins)
{
ADDRINT ip = INS_Address(ins);
string formatted = hexstr(ip) + " " + INS_Disassemble(ins);
char * res = new char [formatted.length()+1];
strcpy (res, formatted.c_str());
return res;
}
// check bytes in given address range
VOID SANDBOX::CheckAddressRange(const char * beginAddr, const char * endAddr)
{
const char * beginPage = Addr2Page(beginAddr);
const char * endPage = Addr2Page(endAddr);
for (const char * page = beginPage; page <= endPage; page += PageSize)
{
const char * pageEnd = page + PageSize - 1;
const char * beginCheckAddr = beginAddr > page ? beginAddr : page;
const char * endCheckAddr = endAddr < pageEnd ? endAddr : pageEnd;
size_t size = endCheckAddr - beginCheckAddr + 1;
const char * pageFrameStart = _pages[page];
if (pageFrameStart == NULL)
{
// note: this might also trigger if PIN has not found all the code
// of a routine
Error("Instruction address range " + hexstr(beginCheckAddr) +
" - " + hexstr(endCheckAddr) + " was not found\n"
"during initial code discovery.\n" +
"\n"
"The application is trying to execute instructions which were not in\n"
"the original application.\n"
"This might be due to a buffer overflow.\n"
"\n"
"Terminating the application!\n");
}
const char * pageFrameBeginCheckAddr = pageFrameStart + Addr2Offset(beginCheckAddr);
if (memcmp(beginCheckAddr, pageFrameBeginCheckAddr, size) != 0)
{
Error("Instruction address range " + hexstr(beginCheckAddr) +
" - " + hexstr(endCheckAddr) + " is corrupted.\n" +
"\n"
"The application code has been corrupted during execution.\n"
"This might be due to a buffer overflow.\n"
"\n"
"Terminating the application!\n");
}
}
}
char *Wchan::find_sym(unsigned long addr)
{
// use binary search to find symbol; return malloced string
int l = 0, r = sysmap_size;
for (;;)
{
unsigned long a;
char buf[80];
int m = (l + r) / 2;
m = beginning_of_line(m);
if (m == l)
{
// see if there is a line further down
while (m < r - 1 && sysmap[m] != '\n')
m++;
if (m < r - 1)
{
m++;
}
else
{
if (r == sysmap_size)
{
// after last item, probably in a
// module. give hex addr
return hexstr(addr);
}
m = l;
sscanf(sysmap + m, "%lx %*c %s", &a, buf);
// strip leading sys_ or do_ to reduce field
// width
char *p = buf;
if (strncmp(buf, "do_", 3) == 0)
p += 3;
if (strncmp(buf, "sys_", 4) == 0)
p += 4;
return strdup(p);
}
}
sscanf(sysmap + m, "%lx %*c %s", &a, buf);
if (addr < a)
{
r = m;
}
else
{
l = m;
}
}
}
static void
audio_endpoint(Dev *, Desc *dd)
{
byte *b = (uchar*)&dd->data;
int n = dd->data.bLength;
char *hd;
switch(b[2]){
case 0x01:
if(usbdebug){
fprint(2, "CS_ENDPOINT for attributes 0x%x, lockdelayunits %d, lockdelay %#ux, ",
b[3], b[4], b[5] | (b[6]<<8));
if(b[3] & has_setspeed)
fprint(2, "has sampling-frequency control");
else
fprint(2, "does not have sampling-frequency control");
if(b[3] & 0x1<<1)
fprint(2, ", has pitch control");
else
fprint(2, ", does not have pitch control");
if(b[3] & 0x1<<7)
fprint(2, ", max packets only");
fprint(2, "\n");
}
if(dd->conf == nil)
sysfatal("conf == nil");
if(dd->iface == nil)
sysfatal("iface == nil");
if(dd->altc == nil)
sysfatal("alt == nil");
if(dd->altc->aux == nil)
dd->altc->aux= mallocz(sizeof(Audioalt),1);
((Audioalt*)dd->altc->aux)->caps |= b[3];
break;
case 0x02:
if(usbdebug){
fprint(2, "CS_INTERFACE FORMAT_TYPE %d, channels %d, subframesize %d, resolution %d, freqtype %d, ",
b[3], b[4], b[5], b[6], b[7]);
fprint(2, "freq0 %d, freq1 %d\n",
b[8] | (b[9]<<8) | (b[10]<<16), b[11] | (b[12]<<8) | (b[13]<<16));
}
break;
default:
if(usbdebug){
hd = hexstr(b, n);
fprint(2, "CS_INTERFACE: %s\n", hd);
free(hd);
}
}
}
void
quoted(char **s, char **to, char *end) /* handle escaped sequence */
{
char *p = *s;
char *t = *to;
wchar_t c;
switch(c = *p++) {
case 't':
c = '\t';
break;
case 'n':
c = '\n';
break;
case 'f':
c = '\f';
break;
case 'r':
c = '\r';
break;
case 'b':
c = '\b';
break;
default:
if (t < end-1) /* all else must be escaped */
*t++ = '\\';
if (c == 'x') { /* hexadecimal goo follows */
c = hexstr(&p);
if (t < end-MB_CUR_MAX)
t += wctomb(t, c);
else overflow();
*to = t;
*s = p;
return;
} else if (isoctdigit(c)) { /* \d \dd \ddd */
c -= '0';
if (isoctdigit(*p)) {
c = 8 * c + *p++ - '0';
if (isoctdigit(*p))
c = 8 * c + *p++ - '0';
}
}
break;
}
if (t < end-1)
*t++ = c;
*s = p;
*to = t;
}
void
dumpmem(int *ptr, int sz, int ustack)
{
int i, val;
for (i = 0; i < sz; i++) {
if ((i & 7) == 0)
printf("\n%s: ", hexstr((int)ptr, 6));
else
printf(" ");
/*
if (ustack == 1) {
if ((val = fuword(ptr++)) == -1)
break;
} else {
if (ustack == 0 && (ptr < KSADDR || ptr > KSADDR+(NBPG/4-1)))
break;
*/
val = *ptr++;
/* } */
printf("%s", hexstr(val, 8));
}
printf("\n");
}
int XPortTTY_Tx(SXPortTTY* pPort, void* pData, int iSize)
{
if (!pPort) return -1;
int iTx = write(pPort->iFile, pData, iSize);
fsync(pPort->iFile);
if (XPortTTY_LogFile)
{
char* pcHex = hexstr(pData, iSize);
if (iTx == iSize)
fprintf((FILE*)XPortTTY_LogFile, "TTY Tx %d %s\n", iSize, pcHex);
else
fprintf((FILE*)XPortTTY_LogFile, "TTY Tx Err %d %s (tx=%d)\n", iSize, pcHex, iTx);
free(pcHex);
}
return iTx;
}
void
regdump(int *rp /* must not be register */, int sbytes)
{
static int doingdump = 0;
int i;
int s;
if (doingdump)
return;
s = splhigh();
doingdump = 1;
/* printf("pid = %d, pc = %s, ", u.u_procp->p_pid, hexstr(rp[PC], 8)); */
printf("pc = %s, ", hexstr(rp[PC], 8));
printf("ps = %s, ", hexstr(rp[PS], 4));
printf("sfc = %s, ", hexstr(getsfc(), 4));
printf("dfc = %s\n", hexstr(getdfc(), 4));
/*
printf("p0 = %x@%s, ",
u.u_pcb.pcb_p0lr, hexstr((int)u.u_pcb.pcb_p0br, 8));
printf("p1 = %x@%s\n\n",
u.u_pcb.pcb_p1lr, hexstr((int)u.u_pcb.pcb_p1br, 8));
*/
printf("Registers:\n ");
for (i = 0; i < 8; i++)
printf(" %d", i);
printf("\ndreg:");
for (i = 0; i < 8; i++)
printf(" %s", hexstr(rp[i], 8));
printf("\nareg:");
for (i = 0; i < 8; i++)
printf(" %s", hexstr(rp[i+8], 8));
if (sbytes > 0) {
/* if (rp[PS] & PSL_S) { */
printf("\n\nKernel stack (%s):",
hexstr((int)(((int *)&rp)-1), 8));
dumpmem(((int *)&rp)-1, sbytes, 0);
/*
} else {
printf("\n\nUser stack (%s):", hexstr(rp[SP], 8));
dumpmem((int *)rp[SP], sbytes, 1);
}
*/
}
doingdump = 0;
splx(s);
}
static int checkSyscalls(BOOL verbose)
{
int successes = 0;
if (verbose)
{
cerr << "Key Call" << endl;
}
for (UINT32 key = SYSCALL_KEY_FIRST; key < SYSCALL_KEY_END; key++)
{
UINT32 syscallNumber = PIN_GetWindowsSyscallFromKey (SYSCALL_KEY(key));
if (verbose)
{
cerr << decstr(key,3) << " " << hexstr(syscallNumber,4) << endl;
}
// Some system calls are not available on some versions of the OS,
// e.g.
// NtCreateUserProcess is only available on Vista (and later)
// NtCreateThreadEx is only available on Vista (and later)
if (syscallNumber == SYSCALL_NUMBER_INVALID)
{
continue;
}
SYSCALL_KEY secondKey = PIN_GetKeyFromWindowsSyscall(syscallNumber);
if (secondKey != key)
{
continue;
}
successes++;
}
return successes;
}
int XPortTTY_Rx(SXPortTTY* pPort, void* pData, int iSize)
{
if (!pPort) return -1;
int iRx = read(pPort->iFile, pData, iSize);
int iCnt = iRx;
if ((iCnt > 0) && (iCnt < iSize))
while (iCnt < iSize)
if ((iRx = read(pPort->iFile, pData + iCnt, iSize - iCnt)) <= 0) break;
else iCnt += iRx;
if (XPortTTY_LogFile)
{
char* pcHex = hexstr(pData, iSize);
pcHex[2*iCnt] = 0;
fprintf((FILE*)XPortTTY_LogFile, "TTY Rx %d %s (cnt=%d rx=%d)\n", iSize, pcHex, iCnt, iRx);
// if (iHub == iRx == iSize)
// fprintf((FILE*)XHub_LogFile, "HUB%d Rx %d %s\n", pPort - pPort->pHub->sPort, iSize, pcHex);
// else
// fprintf((FILE*)XHub_LogFile, "HUB%d Rx Err %d %s (tx=%d hub=%d)\n", pPort - pPort->pHub->sPort, iSize, pcHex, iRx, iHub);
free(pcHex);
}
return iCnt;
}
// allocate a new page
const char * SANDBOX::AllocatePage(const char * page)
{
const char * pageFrameStart = reinterpret_cast<const char *>
#if defined(TARGET_MAC)
// Mac OS
(mmap(0, PageSize, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANON, -1, 0));
#else
// linux
(mmap(0, PageSize, PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANONYMOUS, -1, 0));
#endif
if (pageFrameStart == MAP_FAILED)
{
Error("Can't get page frame for page " + hexstr(page) + "\n" + strerror(errno));
}
_pages[page] = pageFrameStart;
return pageFrameStart;
}
std::string tohexstr(Word x)
{
return std::string(hexstr(x));
}
std::string tohexstr(Byte x)
{
return std::string(hexstr(x));
}
void
audio_interface(Dev *_1, Desc *dd)
{
byte *b = (uint8_t*)&dd->data;
byte *bb = b;
int nb = dd->data.bLength;
int ctl, ch, u, x;
byte *p;
int class, subclass;
Audioalt *aa;
char *hd;
class = Class(dd->iface->csp);
subclass = Subclass(dd->iface->csp);
dprint(2, "%d.%d: ", class, subclass);
switch (subclass){
case 1: // control
switch (b[2]){
case 0x01:
dprint(2, "Class-Specific AC Interface Header Descriptor\n");
dprint(2, "\tAudioDevClass release (bcd)%c%c%c%c, "
"TotalLength %d, InCollection %d aInterfaceNr %d\n",
'0'+((b[4]>>4)&0xf), '0'+(b[4]&0xf),
'0'+((b[3]>>4)&0xf), '0'+(b[3]&0xf),
b[5]|(b[6]<<8), b[7], b[8]);
break;
case 0x02: // input
dprint(2, "Audio Input Terminal Descriptor\n");
dprint(2, "\tbTerminalId %d, wTerminalType "
"0x%x (%s), bAssocTerminal %d bNrChannels %d, "
"wChannelConfig %d, iChannelNames %d iTerminal %d\n",
b[3], b[4]|(b[5]<<8),
namefor(terminal_types, b[4]|(b[5]<<8)),
b[6], b[7], b[8]|(b[9]<<8), b[10], b[11]);
if((b[4]|b[5]<<8) == 0x101){
if(verbose)
fprint(2, "Audio output unit %d\n", b[3]);
/* USB streaming input: play interface */
units[Play][nunits[Play]++] = b[3];
}else{
if(verbose)
fprint(2, "Dev can record from %s\n",
namefor(terminal_types, b[4]|(b[5]<<8)));
/* Non-USB input: record interface */
units[Record][nunits[Record]++] = b[3];
}
break;
case 0x03: // output
if(usbdebug){
fprint(2, "Audio Output Terminal Descriptor\n");
fprint(2, "\tbTerminalId %d, wTerminalType 0x%x (%s), bAssocTerminal %d bSourceId %d, iTerminal %d\n",
b[3], b[4]|(b[5]<<8),
namefor(terminal_types, b[4]|(b[5]<<8)),
b[6], b[7], b[8]);
}
if((b[4]|b[5]<<8) == 0x101){
if(verbose)
fprint(2, "Audio input unit %d\n", b[3]);
/* USB streaming output: record interface */
units[Record][nunits[Record]++] = b[3];
if(verbose)
fprint(2, "Dev can play to %s\n",
namefor(terminal_types, b[4]|(b[5]<<8)));
/* Non-USB output: play interface */
units[Play][nunits[Play]++] = b[3];
}
break;
case 0x04:
if(verbose)
fprint(2, "Audio Mixer Unit %d\n", b[3]);
if(usbdebug){
fprint(2, "\t%d bytes:", nb);
for(ctl = 0; ctl < nb; ctl++)
fprint(2, " 0x%2.2x", b[ctl]);
fprint(2, "\n\tbUnitId %d, bNrInPins %d", b[3], b[4]);
}
if(b[4]){
dprint(2, ", baSourceIDs: [%d", b[5]);
u = findunit(b[5]);
for(ctl = 1; ctl < b[4]; ctl++){
if(u < 0)
u = findunit(b[5+ctl]);
else if((x = findunit(b[5+ctl])) >= 0 && u != x && verbose)
fprint(2, "\tMixer %d for I & O \n", b[3]);
dprint(2, ", %d", b[5+ctl]);
}
dprint(2, "]\n");
if(u >= 0){
units[u][nunits[u]++] = b[3];
if(mixerid[u] >= 0)
fprint(2, "Second mixer (%d, %d) on %s\n",
mixerid[u], b[3], u?"record":"playback");
mixerid[u] = b[3];
}
if(usbdebug){
fprint(2, "Channels %d, config %d, ",
b[ctl+5], b[ctl+5+1] | b[ctl+5+2] << 8);
x = b[ctl+5] * b[4];
fprint(2, "programmable: %d bits, 0x", x);
x = (x + 7) >> 3;
while(x--)
fprint(2, "%2.2x", b[ctl+x+5+4]);
}
}
break;
case 0x05:
if(verbose)
fprint(2, "Audio Selector Unit %d\n", b[3]);
dprint(2, "\tbUnitId %d, bNrInPins %d", b[3], b[4]);
if(b[4]){
u = findunit(b[5]);
dprint(2, ", baSourceIDs: %s [%d",
u?"record":"playback", b[5]);
for(ctl = 1; ctl < b[4]; ctl++){
if(u < 0)
u = findunit(b[5+ctl]);
else if((x = findunit(b[5+ctl])) >= 0 &&
u != x && verbose)
fprint(2, "\tSelector %d for I & O\n", b[3]);
dprint(2, ", %d", b[5+ctl]);
}
dprint(2, "]\n");
if(u >= 0){
units[u][nunits[u]++] = b[3];
if(selectorid[u] >= 0)
fprint(2, "Second selector (%d, %d) on %s\n", selectorid[u], b[3], u?"record":"playback");
selectorid[u] = b[3];
controls[u][Selector_control].readable = 1;
controls[u][Selector_control].settable = 1;
controls[u][Selector_control].chans = 0;
}
}
break;
case 0x06: // feature
if(verbose) fprint(2, "Audio Feature Unit %d", b[3]);
dprint(2, "\tbUnitId %d, bSourceId %d, bControlSize %d\n",
b[3], b[4], b[5]);
u = findunit(b[4]);
if(u >= 0){
if(verbose) fprint(2, " for %s\n", u?"Record":"Playback");
units[u][nunits[u]++] = b[3];
if(featureid[u] >= 0)
if(verbose)
fprint(2, "Second feature unit (%d, %d)"
" on %s\n", featureid[u], b[3],
u?"record":"playback");
featureid[u] = b[3];
}else
if(verbose) fprint(2, ", not known what for\n");
p = b + 6;
for(ctl = 1; ctl < 0x0b; ctl++)
if((1<<(ctl-1)) & (b[6] | ((b[5]>1)?(b[7]<<8):0))){
if(verbose)
fprint(2, "\t%s control on master channel\n",
controls[0][ctl].name);
if(u >= 0){
controls[u][ctl].readable = 1;
controls[u][ctl].settable = 1;
controls[u][ctl].chans = 0;
}
}
p += (b[5]>1)?2:1;
for(ch = 0; ch < (nb - 8)/b[5]; ch++){
for(ctl = 1; ctl < 0x0b; ctl++)
if((1<<(ctl-1)) & (p[0] | ((b[5]>1)?(p[1]<<8):0))){
if(verbose)
fprint(2, "\t%s control on channel %d\n",
controls[0][ctl].name, ch+1);
if(u >= 0){
controls[u][ctl].readable = 1;
controls[u][ctl].settable = 1;
controls[u][ctl].chans |= 1 <<(ch+1);
}
}
p += (b[5]>1)?2:1;
}
break;
default:
hd = hexstr(bb, nb);
fprint(2, "audio control unknown: %s\n", hd);
free(hd);
}
break;
case 2: // stream
switch (b[2]){
case 0x01:
dprint(2, "Audio stream for TerminalID %d, delay %d, format_tag %#ux\n",
b[3], b[4], b[5] | (b[6]<<8));
break;
case 0x02:
aa = (Audioalt *)dd->altc->aux;
if(aa == nil){
aa = mallocz(sizeof(Audioalt), 1);
dd->altc->aux = aa;
}
if(verbose){
if(b[4] <= 2)
fprint(2, "Interface %d: %s, %d bits, ",
dd->iface->id, (b[4] == 1)?"mono":"stereo", b[6]);
else
fprint(2, "Interface %d, %d channels, %d bits, ",
dd->iface->id, b[4], b[6]);
}
if(b[7] == 0){
if(verbose)
fprint(2, "frequency variable between %d and %d\n",
b[8] | b[9]<<8 | b[10]<<16, b[11] | b[12]<<8 | b[13]<<16);
aa->minfreq = b[8] | b[9]<<8 | b[10]<<16;
aa->maxfreq = b[11] | b[12]<<8 | b[13]<<16;
aa->caps |= has_contfreq;
}else{
if(verbose)
fprint(2, "discrete frequencies are:");
for(ch = 0; ch < b[7] && ch < 8; ch++){
aa->freqs[ch] = b[8+3*ch] | b[9+3*ch]<<8 | b[10+3*ch]<<16;
if(verbose)
fprint(2, " %d", b[8+3*ch] | b[9+3*ch]<<8 | b[10+3*ch]<<16);
}
if(ch < 8)
aa->freqs[ch] = -1;
if(verbose)
fprint(2, "\n");
if(ch > 1)
aa->caps |= has_discfreq; /* more than one frequency */
else
aa->caps |= onefreq; /* only one frequency */
}
aa->nchan = b[4];
aa->res = b[6];
aa->subframesize = b[5];
break;
default:
if(usbdebug){
hd = hexstr(bb, nb);
fprint(2, "audio stream unknown: %s\n", hd);
free(hd);
}
}
break;
case 3: // midi
default:
if(usbdebug){
hd = hexstr(bb, nb);
fprint(2, "Unknown audio stream type: CS_INTERFACE: %s\n", hd);
free(hd);
}
}
}
// Replay the image log.
// We run this before the each instruction of the code as an analysis routine.
// So we eat up the image loads one instruction at a time!
// We can also call it before PIN_StartProgram, to check that queuing
// the replay calls up works.
//
static void ReplayImageEntry()
{
if (feof(imgLog))
return;
char tag = fgetc(imgLog);
switch (tag)
{
case 'L':
{
string imageName;
ADDRINT startAddr;
ADDRINT offset;
USIZE size;
BOOL mainExe;
vector<RTN_INFO> rtns;
ParseImageLoadLine(imageName, &startAddr, &size, &offset, &mainExe, &rtns);
if (KnobVerbose)
fprintf (stderr, "Replaying load for %s, address: %llx offset: %llx, size: %lx\n", imageName.c_str(), (unsigned long long)startAddr, (unsigned long long)offset, (long)size);
// Create a temporary IMG object
IMG img = IMG_CreateAt(imageName.c_str(), startAddr, size, offset, mainExe);
ASSERT(IMG_Valid(img), "IMG_CreateAt for " + imageName + " is invalid");
// Populate the IMG object with recorded RTNs
PIN_LockClient();
for (vector<RTN_INFO>::iterator it = rtns.begin(); it < rtns.end(); it++)
{
RTN rtn = RTN_CreateAt(it->startAddr, it->name);
ASSERT(RTN_Valid(rtn), "Failed to create RTN " + it->name + " at address " + hexstr(it->startAddr));
}
// And, finally, inform Pin that it is all there, which will invoke
// image load callbacks.
IMG_ReplayImageLoad(img);
PIN_UnlockClient();
break;
}
case 'U':
{
string imageName;
ParseImageUnloadLine(imageName);
IMG img = FindNamedImg(imageName);
if (KnobVerbose)
fprintf (stderr, "Replaying unload for %s\n", imageName.c_str());
// And, finally, inform Pin that it has gone, which will invoke
// image unload callbacks.
PIN_LockClient();
PIN_ReplayImageUnload(img);
PIN_UnlockClient();
break;
}
default:
fprintf (trace, "Unexpected line in log file starting with '%c'\n", tag);
exit(1);
}
}
int
fsrestore(int argc, char *argv[])
{
int i, j, status;
int block, bytes;
int blk, nblks, size, mark;
struct partition *pp;
printf("Current SCSI device = ID %d\n", scsi_device);
getline("Is it sure ? (y/n) ", cons_buf);
if ((cons_buf[0] != 'y') && (cons_buf[0] != 'Y'))
return ST_ERROR;
st_rewind(rst0);
st_skip(rst0);
status = stread(rst0, index, LABEL_SIZE);
st_skip(rst0);
for (i = 0; i < MAXPARTITIONS; i++) {
pp = &(lp->d_partitions[i]);
if (pp->p_size > 0) {
printf("%c: ", i + 'A');
printf("size = %d(0x%s), ",
pp->p_size, hexstr(pp->p_size, 8));
printf("offset = %d(0x%s)\n",
pp->p_offset, hexstr(pp->p_offset, 8));
blk = pp->p_offset;
nblks = pp->p_size;
size = nblks << DEV_BSHIFT;
block = BUF_BLOCK;
bytes = BUF_BYTES;
mark = nblks / block;
if (nblks % block)
mark++;
for (j = 0; j < mark; j++)
printf("-");
for (j = 0; j < mark; j++)
printf("%c", '\x08');
while (nblks > 0) {
if (nblks < block) {
block = nblks;
bytes = nblks << DEV_BSHIFT;
}
if (stread(rst0, dump_buf, bytes) != bytes) {
printf("tape read failed !!!\n");
return ST_ERROR;
}
if (!scsi_write(blk, dump_buf, bytes)) {
printf("disk write failed !!!\n");
return ST_ERROR;
}
blk += block;
nblks -= block;
size -= bytes;
printf("#");
}
st_skip(rst0);
printf("\n\n");
}
}
return ST_NORMAL;
}
int
fsdump(int argc, char *argv[])
{
int i, j, io;
int status;
int block, bytes;
int scsi_id, blk, nblks, size, mark;
struct stat boot_stat;
struct partition *pp;
scsi_id = scsi_device;
printf("Current SCSI device = ID %d\n", scsi_id);
getline("Is it sure ? (y/n) ", cons_buf);
if ((cons_buf[0] != 'y') && (cons_buf[0] != 'Y'))
return ST_ERROR;
scsi_read_raw(scsi_id, 0, 1, index, LABEL_SIZE);
for (i = 0; i < MAXPARTITIONS; i++) {
pp = &(lp->d_partitions[i]);
if ((i != 0) &&
(i != 3) &&
(i != 4) &&
(i != 5)) {
pp->p_size = 0;
}
if (i == 5 && argc > 1 && !strcmp(argv[1], "tailor"))
pp->p_size = 0;
}
st_rewind(rst0);
printf("Boot Program ");
io = open("sd(0,0)boot", 0);
if (io >= 0) {
printf("read ... ");
size = read(io, dump_buf, 1048576);
close(io);
printf("%d bytes ... ", size);
if (size <= 0) {
printf("failed\n");
return ST_ERROR;
}
boot_stat.st_size = size;
}
printf("write ... ");
status = stwrite(rst0, dump_buf, size);
st_write_EOF(rst0);
if (status < size) {
printf("failed\n");
return ST_ERROR;
}
printf("done\n");
printf("disklabel (index)\t");
printf("write ... ");
status = stwrite(rst0, index, LABEL_SIZE);
st_write_EOF(rst0);
if (status < LABEL_SIZE) {
printf("failed\n");
return ST_ERROR;
}
printf("done\n\n");
for (i = 0; i < MAXPARTITIONS; i++) {
pp = &(lp->d_partitions[i]);
if (pp->p_size > 0) {
printf("%c: ", i + 'A');
printf("size = %d(0x%s), ",
pp->p_size, hexstr(pp->p_size, 8));
printf("offset = %d(0x%s)\n",
pp->p_offset, hexstr(pp->p_offset, 8));
blk = pp->p_offset;
nblks = pp->p_size;
size = nblks << DEV_BSHIFT;
block = BUF_BLOCK;
bytes = BUF_BYTES;
mark = nblks / block;
if (nblks % block)
mark++;
for (j = 0; j < mark; j++)
printf("-");
for (j = 0; j < mark; j++)
printf("%c", '\x08');
while (nblks > 0) {
if (nblks < block) {
block = nblks;
bytes = nblks << DEV_BSHIFT;
}
if (!scsi_read_raw(scsi_id, blk, block,
dump_buf, bytes)) {
printf("disk read failed !!!\n");
return ST_ERROR;
}
if (stwrite(rst0, dump_buf, bytes) < bytes) {
printf("tape write failed !!!\n");
return ST_ERROR;
}
blk += block;
nblks -= block;
size -= bytes;
printf("#");
}
st_write_EOF(rst0);
printf("\n\n");
}
}
return ST_NORMAL;
}
