/* * V8 DTrace ustack helper for annotating native stack traces with JavaScript * function names. We start with a frame pointer (arg1) and emit a string * describing the current function. We do this by chasing pointers to extract * the function's name (if any) and the filename and line number where the * function is defined. * * To use the helper, run node, then use the jstack() DTrace action to capture * a JavaScript stacktrace. You may need to tune the dtrace_helper_actions_max * kernel variable to 128. */ #include #include /* * V8 represents small integers (SMI) using the upper 31 bits of a 32/64-bit * value. To extract the actual integer value, we must shift it over. */ #define IS_SMI(value) \ ((value & V8_SmiTagMask) == V8_SmiTag) #define SMI_VALUE(value) \ ((uint32_t) ((value) >> V8_SmiValueShift)) #define NO_SHARED_FUNCTION_NAME_SENTINEL NULL /* * Heap objects usually start off with a Map pointer, itself another heap * object. However, during garbage collection, the low order bits of the * pointer (which are normally 01) are used to record GC state. Of course, we * have no idea if we're in GC or not, so we must always normalize the pointer. */ #define V8_MAP_PTR(ptr) \ ((ptr & ~V8_HeapObjectTagMask) | V8_HeapObjectTag) #define V8_TYPE_SCRIPT(type) \ ((type) == V8_IT_SCRIPT) /* * Determine the encoding and representation of a V8 string. */ #define V8_TYPE_STRING(type) \ (((type) & V8_IsNotStringMask) == V8_StringTag) #define V8_STRENC_ASCII(type) \ (((type) & V8_StringEncodingMask) == V8_AsciiStringTag) #define V8_STRREP_SEQ(type) \ (((type) & V8_StringRepresentationMask) == V8_SeqStringTag) #define V8_STRREP_CONS(type) \ (((type) & V8_StringRepresentationMask) == V8_ConsStringTag) #define V8_STRREP_EXT(type) \ (((type) & V8_StringRepresentationMask) == V8_ExternalStringTag) /* * String type predicates */ #define ASCII_SEQSTR(value) \ (V8_TYPE_STRING(value) && V8_STRENC_ASCII(value) && V8_STRREP_SEQ(value)) #define TWOBYTE_SEQSTR(value) \ (V8_TYPE_STRING(value) && !V8_STRENC_ASCII(value) && V8_STRREP_SEQ(value)) #define IS_CONSSTR(value) \ (V8_TYPE_STRING(value) && V8_STRREP_CONS(value)) #define ASCII_EXTSTR(value) \ (V8_TYPE_STRING(value) && V8_STRENC_ASCII(value) && V8_STRREP_EXT(value)) /* * General helper macros */ #define COPYIN_UINT8(addr) (*(uint8_t*) copyin((addr), sizeof(uint8_t))) #define COPYIN_UINT32(addr) (*(uint32_t*) copyin((addr), sizeof(uint32_t))) #define COPYIN_UINT64(addr) (*(uint64_t*) copyin((addr), sizeof(uint64_t))) #if defined(__i386) # define COPYIN_PTR(addr) COPYIN_UINT32(addr) # define off_t uint32_t # define APPEND_PTR(p) APPEND_PTR_32(p) #else # define COPYIN_PTR(addr) COPYIN_UINT64(addr) # define off_t uint64_t # define APPEND_PTR(p) APPEND_PTR_64(p) #endif #define APPEND_CHR(c) (this->buf[this->off++] = (c)) #define APPEND_CHR4(s0, s1, s2, s3) \ APPEND_CHR(s0); \ APPEND_CHR(s1); \ APPEND_CHR(s2); \ APPEND_CHR(s3); #define APPEND_CHR8(s0, s1, s2, s3, s4, s5, s6, s7) \ APPEND_CHR4(s0, s1, s2, s3) \ APPEND_CHR4(s4, s5, s6, s7) #define APPEND_DGT(i, d) \ (((i) / (d)) ? APPEND_CHR('0' + ((i)/(d) % 10)) : 0) #define APPEND_NUM(i) \ APPEND_DGT((i), 100000); \ APPEND_DGT((i), 10000); \ APPEND_DGT((i), 1000); \ APPEND_DGT((i), 100); \ APPEND_DGT((i), 10); \ APPEND_DGT((i), 1); #define APPEND_HEX(d) \ APPEND_CHR((d) < 10 ? '0' + (d) : 'a' - 10 + (d)) #define APPEND_PTR_32(p) \ APPEND_HEX((p >> 28) & 0xf); \ APPEND_HEX((p >> 24) & 0xf); \ APPEND_HEX((p >> 20) & 0xf); \ APPEND_HEX((p >> 16) & 0xf); \ APPEND_HEX((p >> 12) & 0xf); \ APPEND_HEX((p >> 8) & 0xf); \ APPEND_HEX((p >> 4) & 0xf); \ APPEND_HEX((p) & 0xf); #define APPEND_PTR_64(p) \ APPEND_PTR_32(p >> 32) \ APPEND_PTR_32(p) /* * The following macros are used to output ASCII SeqStrings, ConsStrings, and * Node.js ExternalStrings. To represent each string, we use three fields: * * "str": a pointer to the string itself * * "len": the string length * * "attrs": the type identifier for the string, which indicates the * encoding and representation. We're only interested in strings * whose representation is one of: * * SeqOneByteString stored directly as a char array inside the object * * SeqTwoByteString stored as a UTF-16 char array inside the object * * ConsString pointer to two strings that should be concatenated * * ExternalString pointer to a char* outside the V8 heap */ /* * Load "len" and "attrs" for the given "str". */ #define LOAD_STRFIELDS(str, len, attrs) \ len = SMI_VALUE(COPYIN_PTR(str + V8_OFF_STR_LENGTH)); \ this->map = V8_MAP_PTR(COPYIN_PTR(str + V8_OFF_HEAPOBJ_MAP)); \ attrs = COPYIN_UINT8(this->map + V8_OFF_MAP_ATTRS); #define APPEND_SEQSTR(str, len, attrs) \ APPEND_SEQONEBYTESTR(str, len, attrs) \ APPEND_SEQTWOBYTESTR(str, len, attrs) /* * Print out the given SeqOneByteString, or do nothing if the string is not an ASCII * SeqOneByteString. */ #define APPEND_SEQONEBYTESTR(str, len, attrs) \ dtrace:helper:ustack: \ /!this->done && len > 0 && ASCII_SEQSTR(attrs)/ \ { \ copyinto(str + V8_OFF_STR_CHARS, len, this->buf + this->off); \ this->off += len; \ } /* * LOOP_ITER: macro to paste "block" while "ivar" is less than "dynmax" and * "statmax". The subsequent LOOP_{4,8} macros facilitate pasting the same * thing 4 and 8 times, respectively. Like much of the rest of the code in this * file, this is regrettably necessary given the constraints under which we're * expected to run. */ #define LOOP_ITER(ivar, dynmax, statmax, block) \ ((ivar) < (dynmax)) && ((ivar) < (statmax)) && (block); (ivar)++; #define LOOP_4(block) \ block \ block \ block \ block \ #define LOOP_8(block) \ LOOP_4(block) \ LOOP_4(block) /* * Print out the given SeqTwoByteString, or do nothing if the string is not an ASCII * SeqTwoByteString. NOTE: if you bump MAX_TWOBYTESTR_CHARS, you'll also need * to modify the LOOP_* macro calls below to match. */ #define MAX_TWOBYTESTR_CHARS 128 #define MAX_TWOBYTESTR_BYTES (2 * MAX_TWOBYTESTR_CHARS) #define TO_ASCII(c) ((c) < 128 ? (c) : '?') #define APPEND_SEQTWOBYTESTR(str, len, attrs) \ dtrace:helper:ustack: \ /!this->done && len > 0 && TWOBYTE_SEQSTR(attrs)/ \ { \ this->i = 0; \ this->stbuf = (uint16_t *)alloca(MAX_TWOBYTESTR_BYTES + 2); \ copyinto(str + V8_OFF_TWOBYTESTR_CHARS, \ MAX_TWOBYTESTR_BYTES, this->stbuf); \ this->stbuf[MAX_TWOBYTESTR_BYTES - 1] = '\0'; \ this->stbuf[MAX_TWOBYTESTR_BYTES] = '\0'; \ \ LOOP_8(LOOP_8(LOOP_4(LOOP_ITER(this->i, len, \ MAX_TWOBYTESTR_CHARS, \ APPEND_CHR(TO_ASCII(this->stbuf[this->i])))))) \ \ this->i = 0; \ this->stbuf = 0; \ } /* * Print out the given Node.js ExternalString, or do nothing if the string is * not an ASCII ExternalString. */ #define APPEND_NODESTR(str, len, attrs) \ dtrace:helper:ustack: \ /!this->done && len > 0 && ASCII_EXTSTR(attrs)/ \ { \ this->resource = COPYIN_PTR(str + V8_OFF_EXTSTR_RSRC); \ this->dataptr = COPYIN_PTR(this->resource + NODE_OFF_EXTSTR_DATA); \ copyinto(this->dataptr, len, this->buf + this->off); \ this->off += len; \ } /* * Recall that each ConsString points to two other strings which are * semantically concatenated. Of course, these strings may themselves by * ConsStrings, but in D we can only expand this recursion to a finite level. * Thankfully, function and script names are generally not more than a few * levels deep, so we unroll the expansion up to three levels. Even this is * pretty hairy: we use strings "s0", ..., "s13", (each with "str", "len", and * "attr" fields -- see above) to store the expanded strings. We expand the * original string into s0 and s7, then s0 into s1 and s4, etc: * * * +---- str ----+ * / \ <-- 1st expansion * / \ * s0 s7 * / \ / \ * / \ / \ <-- 2nd expansion * / \ / \ * s1 s4 s8 s11 * / \ / \ / \ / \ <-- 3rd expansion * s2 s3 s5 s6 s9 s10 s12 s13 * * Of course, for a given string, any of these expansions may not be needed. * For example, we may expand str and find that s0 is already a SeqString, * while s7 requires further expansion. So when we expand a ConsString, we * zero the length of the string itself, and then at the end we print out * all non-zero-length strings in order (including both internal nodes and * leafs in the tree above) to get the final output. */ #define EXPAND_START() \ dtrace:helper:ustack: \ /!this->done/ \ { \ this->s0str = this->s1str = this->s2str = (off_t) 0; \ this->s3str = this->s4str = this->s5str = (off_t) 0; \ this->s6str = this->s7str = this->s8str = (off_t) 0; \ this->s9str = this->s10str = this->s11str = (off_t) 0; \ this->s12str = this->s13str = (off_t) 0; \ \ this->s0len = this->s1len = this->s2len = (off_t) 0; \ this->s3len = this->s4len = this->s5len = (off_t) 0; \ this->s6len = this->s7len = this->s8len = (off_t) 0; \ this->s9len = this->s10len = this->s11len = (off_t) 0; \ this->s12len = this->s13len = (off_t) 0; \ \ this->s0attrs = this->s1attrs = this->s2attrs = 0; \ this->s3attrs = this->s4attrs = this->s5attrs = 0; \ this->s6attrs = this->s7attrs = this->s8attrs = 0; \ this->s9attrs = this->s10attrs = this->s11attrs = 0; \ this->s12attrs = this->s13attrs = 0; \ } /* * Expand the ConsString "str" (represented by "str", "len", and "attrs") into * strings "s1" (represented by "s1s", "s1l", and "s1a") and "s2" (represented * by "s2s", "s2l", "s2a"). If "str" is not a ConsString, do nothing. */ #define EXPAND_STR(str, len, attrs, s1s, s1l, s1a, s2s, s2l, s2a) \ dtrace:helper:ustack: \ /!this->done && len > 0 && IS_CONSSTR(attrs)/ \ { \ len = 0; \ \ s1s = COPYIN_PTR(str + V8_OFF_CONSSTR_CAR); \ LOAD_STRFIELDS(s1s, s1l, s1a) \ \ s2s = COPYIN_PTR(str + V8_OFF_CONSSTR_CDR); \ LOAD_STRFIELDS(s2s, s2l, s2a) \ } /* * Print out a ConsString by expanding it up to three levels and printing out * the resulting SeqStrings. */ #define APPEND_CONSSTR(str, len, attrs) \ EXPAND_START() \ EXPAND_STR(str, len, attrs, \ this->s0str, this->s0len, this->s0attrs, \ this->s7str, this->s7len, this->s7attrs) \ EXPAND_STR(this->s0str, this->s0len, this->s0attrs, \ this->s1str, this->s1len, this->s1attrs, \ this->s4str, this->s4len, this->s4attrs) \ EXPAND_STR(this->s1str, this->s1len, this->s1attrs, \ this->s2str, this->s2len, this->s2attrs, \ this->s3str, this->s3len, this->s3attrs) \ EXPAND_STR(this->s4str, this->s4len, this->s4attrs, \ this->s5str, this->s5len, this->s5attrs, \ this->s6str, this->s6len, this->s6attrs) \ EXPAND_STR(this->s7str, this->s7len, this->s7attrs, \ this->s8str, this->s8len, this->s8attrs, \ this->s11str, this->s11len, this->s11attrs) \ EXPAND_STR(this->s8str, this->s8len, this->s8attrs, \ this->s9str, this->s9len, this->s9attrs, \ this->s10str, this->s10len, this->s10attrs) \ EXPAND_STR(this->s11str, this->s11len, this->s11attrs, \ this->s12str, this->s12len, this->s12attrs, \ this->s13str, this->s13len, this->s13attrs) \ \ APPEND_SEQSTR(str, len, attrs) \ APPEND_SEQSTR(this->s0str, this->s0len, this->s0attrs) \ APPEND_SEQSTR(this->s1str, this->s1len, this->s1attrs) \ APPEND_SEQSTR(this->s2str, this->s2len, this->s2attrs) \ APPEND_SEQSTR(this->s3str, this->s3len, this->s3attrs) \ APPEND_SEQSTR(this->s4str, this->s4len, this->s4attrs) \ APPEND_SEQSTR(this->s5str, this->s5len, this->s5attrs) \ APPEND_SEQSTR(this->s6str, this->s6len, this->s6attrs) \ APPEND_SEQSTR(this->s7str, this->s7len, this->s7attrs) \ APPEND_SEQSTR(this->s8str, this->s8len, this->s8attrs) \ APPEND_SEQSTR(this->s9str, this->s9len, this->s9attrs) \ APPEND_SEQSTR(this->s10str, this->s10len, this->s10attrs) \ APPEND_SEQSTR(this->s11str, this->s11len, this->s11attrs) \ APPEND_SEQSTR(this->s12str, this->s12len, this->s12attrs) \ APPEND_SEQSTR(this->s13str, this->s13len, this->s13attrs) \ /* * Print out the given SeqString, ConsString, or ExternalString. * APPEND_CONSSTR implicitly handles SeqStrings as the degenerate case of an * expanded ConsString. */ #define APPEND_V8STR(str, len, attrs) \ APPEND_CONSSTR(str, len, attrs) \ APPEND_NODESTR(str, len, attrs) /* * In this first clause we initialize all variables. We must explicitly clear * them because they may contain values left over from previous iterations. */ dtrace:helper:ustack: { /* input */ this->fp = arg1; /* output/flow control */ this->buf = (char*) alloca(128); this->off = 0; this->done = 0; /* program state */ this->ctx = (off_t) 0; this->marker = (off_t) 0; this->func = (off_t) 0; this->shared = (off_t) 0; this->map = (off_t) 0; this->attrs = 0; this->funcrawnamestr = (off_t) 0; this->hassharedname = 0; this->funcnamelen = 0; this->funcnameattrs = 0; this->script = (off_t) 0; this->scriptattrs = 0; this->scriptnamestr = (off_t) 0; this->scriptnamelen = 0; this->scriptnameattrs = 0; this->position = 0; this->line_ends = (off_t) 0; this->le_attrs = 0; /* binary search fields */ this->bsearch_min = 0; this->bsearch_max = 0; this->ii = 0; } /* * Like V8, we first check if we've got an ArgumentsAdaptorFrame. We've got * nothing to add for such frames, so we bail out quickly. */ dtrace:helper:ustack: { this->ctx = COPYIN_PTR(this->fp + V8_OFF_FP_CONTEXT); } dtrace:helper:ustack: /IS_SMI(this->ctx) && SMI_VALUE(this->ctx) == V8_FT_ADAPTOR/ { this->done = 1; APPEND_CHR8('<','<',' ','a','d','a','p','t'); APPEND_CHR8('o','r',' ','>','>','\0','\0','\0'); stringof(this->buf); } /* * Check for other common frame types for which we also have nothing to add. */ dtrace:helper:ustack: /!this->done/ { this->marker = COPYIN_PTR(this->fp + V8_OFF_FP_CONTEXT); } dtrace:helper:ustack: /!this->done && IS_SMI(this->marker) && SMI_VALUE(this->marker) == V8_FT_ENTRY/ { this->done = 1; APPEND_CHR8('<','<',' ','e','n','t','r','y'); APPEND_CHR4(' ','>','>','\0'); stringof(this->buf); } dtrace:helper:ustack: /!this->done && IS_SMI(this->marker) && SMI_VALUE(this->marker) == V8_FT_ENTRYCONSTRUCT/ { this->done = 1; APPEND_CHR8('<','<',' ','e','n','t','r','y'); APPEND_CHR8('_','c','o','n','s','t','r','u'); APPEND_CHR4('t',' ','>','>'); APPEND_CHR('\0'); stringof(this->buf); } dtrace:helper:ustack: /!this->done && IS_SMI(this->marker) && SMI_VALUE(this->marker) == V8_FT_EXIT/ { this->done = 1; APPEND_CHR8('<','<',' ','e','x','i','t',' '); APPEND_CHR4('>','>','\0','\0'); stringof(this->buf); } dtrace:helper:ustack: /!this->done && IS_SMI(this->marker) && SMI_VALUE(this->marker) == V8_FT_INTERNAL/ { this->done = 1; APPEND_CHR8('<','<',' ','i','n','t','e','r'); APPEND_CHR8('n','a','l',' ','>','>','\0','\0'); stringof(this->buf); } dtrace:helper:ustack: /!this->done && IS_SMI(this->marker) && SMI_VALUE(this->marker) == V8_FT_CONSTRUCT/ { this->done = 1; APPEND_CHR8('<','<',' ','c','o','n','s','t'); APPEND_CHR8('r','u','c','t','o','r',' ','>'); APPEND_CHR4('>','\0','\0','\0'); stringof(this->buf); } dtrace:helper:ustack: /!this->done && IS_SMI(this->marker) && SMI_VALUE(this->marker) == V8_FT_STUB/ { this->done = 1; APPEND_CHR8('<','<',' ','s','t','u','b',' '); APPEND_CHR4('>','>','\0','\0'); stringof(this->buf); } /* * Now check for internal frames that we can only identify by seeing that * there's a Code object where there would be a JSFunction object for a * JavaScriptFrame. */ dtrace:helper:ustack: /!this->done/ { this->func = COPYIN_PTR(this->fp + V8_OFF_FP_FUNC); this->map = V8_MAP_PTR(COPYIN_PTR(this->func + V8_OFF_HEAPOBJ_MAP)); this->attrs = COPYIN_UINT8(this->map + V8_OFF_MAP_ATTRS); } dtrace:helper:ustack: /!this->done && this->attrs == V8_IT_CODE/ { this->done = 1; APPEND_CHR8('<','<',' ','i','n','t','e','r'); APPEND_CHR8('n','a','l',' ','c','o','d','e'); APPEND_CHR4(' ','>','>','\0'); stringof(this->buf); } /* * At this point, we're either looking at a JavaScriptFrame or an * OptimizedFrame. For now, we assume JavaScript and start by grabbing the * function name. */ dtrace:helper:ustack: /!this->done/ { this->map = 0; this->attrs = 0; this->shared = COPYIN_PTR(this->func + V8_OFF_FUNC_SHARED); this->funcrawnamestr = COPYIN_PTR(this->shared + V8_OFF_RAW_NAME); this->hassharedname = this->funcrawnamestr != NO_SHARED_FUNCTION_NAME_SENTINEL; } dtrace:helper:ustack: /!this->done && this->hassharedname/ { LOAD_STRFIELDS(this->funcrawnamestr, this->funcnamelen, this->funcnameattrs); } dtrace:helper:ustack: /!this->done && this->funcnamelen == 0/ { /* * This is an anonymous function, but if it was invoked as a method of * some object then V8 will have computed an inferred name that we can * include in the stack trace. */ APPEND_CHR8('(','a','n','o','n',')',' ','a'); APPEND_CHR('s'); APPEND_CHR(' '); this->funcrawnamestr = COPYIN_PTR(this->shared + V8_OFF_SHARED_IDENT); LOAD_STRFIELDS(this->funcrawnamestr, this->funcnamelen, this->funcnameattrs); } dtrace:helper:ustack: /!this->done && this->funcnamelen == 0/ { APPEND_CHR('('); APPEND_CHR4('a','n','o','n'); APPEND_CHR(')'); } APPEND_V8STR(this->funcrawnamestr, this->funcnamelen, this->funcnameattrs) /* * Now look for the name of the script where the function was defined. The * "script" itself may be undefined for special functions like "RegExp". */ dtrace:helper:ustack: /!this->done/ { this->script = COPYIN_PTR(this->shared + V8_OFF_SHARED_SCRIPT); this->map = V8_MAP_PTR(COPYIN_PTR(this->script + V8_OFF_HEAPOBJ_MAP)); this->scriptattrs = COPYIN_UINT8(this->map + V8_OFF_MAP_ATTRS); } dtrace:helper:ustack: /!this->done && !V8_TYPE_SCRIPT(this->scriptattrs)/ { APPEND_CHR('\0'); this->done = 1; stringof(this->buf); } dtrace:helper:ustack: /!this->done/ { this->scriptnamestr = COPYIN_PTR(this->script + V8_OFF_SCRIPT_NAME); LOAD_STRFIELDS(this->scriptnamestr, this->scriptnamelen, this->scriptnameattrs); } dtrace:helper:ustack: /!this->done && this->scriptnamelen != 0/ { APPEND_CHR4(' ','a','t',' '); } APPEND_V8STR(this->scriptnamestr, this->scriptnamelen, this->scriptnameattrs) /* * Now look for file position and line number information. */ dtrace:helper:ustack: /!this->done/ { this->position = COPYIN_UINT32(this->shared + V8_OFF_SHARED_FUNIDENT); this->line_ends = COPYIN_PTR(this->script + V8_OFF_SCRIPT_LENDS); this->map = V8_MAP_PTR(COPYIN_PTR(this->line_ends + V8_OFF_HEAPOBJ_MAP)); this->le_attrs = COPYIN_UINT8(this->map + V8_OFF_MAP_ATTRS); } dtrace:helper:ustack: /!this->done && this->le_attrs != V8_IT_FIXEDARRAY && this->position == 0/ { APPEND_CHR('\0'); this->done = 1; stringof(this->buf); } dtrace:helper:ustack: /!this->done && this->le_attrs != V8_IT_FIXEDARRAY/ { /* * If the line number array was not a valid FixedArray, it's probably * undefined because V8 has not had to compute it yet. In this case we * just show the raw position and call it a day. */ APPEND_CHR4(' ','p','o','s'); APPEND_CHR(' '); APPEND_NUM(SMI_VALUE(this->position)); APPEND_CHR('\0'); this->done = 1; stringof(this->buf); } /* * At this point, we've got both a position in the script and an array * describing where each line of the file ends. We can use this to compute the * line number by binary searching the array. (This is also what V8 does when * computing stack traces.) */ dtrace:helper:ustack: /!this->done/ { /* initialize binary search */ this->bsearch_line = this->position < SMI_VALUE(COPYIN_PTR(this->line_ends + V8_OFF_FA_DATA)) ? 1 : 0; this->bsearch_min = 0; this->bsearch_max = this->bsearch_line != 0 ? 0 : SMI_VALUE(COPYIN_PTR(this->line_ends + V8_OFF_FA_SIZE)) - 1; } /* * Of course, we can't iterate the binary search indefinitely, so we hardcode 15 * iterations. That's enough to precisely identify the line number in files up * to 32768 lines of code. */ #define BSEARCH_LOOP \ dtrace:helper:ustack: \ /!this->done && this->bsearch_max >= 1/ \ { \ this->ii = (this->bsearch_min + this->bsearch_max) >> 1; \ } \ \ dtrace:helper:ustack: \ /!this->done && this->bsearch_max >= 1 && \ this->position > SMI_VALUE( \ COPYIN_PTR(this->line_ends + V8_OFF_FA_DATA + \ this->ii * sizeof (uint32_t)))/ \ { \ this->bsearch_min = this->ii + 1; \ } \ \ dtrace:helper:ustack: \ /!this->done && this->bsearch_max >= 1 && \ this->position <= SMI_VALUE( \ COPYIN_PTR(this->line_ends + V8_OFF_FA_DATA + \ (this->ii - 1) * sizeof (uint32_t)))/ \ { \ this->bsearch_max = this->ii - 1; \ } BSEARCH_LOOP BSEARCH_LOOP BSEARCH_LOOP BSEARCH_LOOP BSEARCH_LOOP BSEARCH_LOOP BSEARCH_LOOP BSEARCH_LOOP BSEARCH_LOOP BSEARCH_LOOP BSEARCH_LOOP BSEARCH_LOOP BSEARCH_LOOP BSEARCH_LOOP BSEARCH_LOOP dtrace:helper:ustack: /!this->done && !this->bsearch_line/ { this->bsearch_line = this->ii + 1; } dtrace:helper:ustack: /!this->done/ { APPEND_CHR(' '); APPEND_CHR4('l','i','n','e'); APPEND_CHR(' '); APPEND_NUM(this->bsearch_line); APPEND_CHR('\0'); this->done = 1; stringof(this->buf); } /* vim: set tabstop=8 softtabstop=8 shiftwidth=8 noexpandtab: */