| blob | e75ab94e10f788a372570689dd4d6ff017a81c53 |
5 #define NAME_CHARS \
6 "0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ_abcdefghijklmnopqrstuvwxyz"
8 /* all_name_chars(s): true iff all chars in s are valid NAME_CHARS */
10 static int
12 {
20 }
24 }
26 }
28 static void
30 {
31 Py_ssize_t i;
37 }
39 }
40 }
43 PyCodeObject *
49 {
51 Py_ssize_t i;
52 /* Check argument types */
66 }
71 /* Intern selected string constants */
79 }
106 }
108 }
111 #define OFF(x) offsetof(PyCodeObject, x)
129 };
131 /* Helper for code_new: return a shallow copy of a tuple that is
132 guaranteed to contain exact strings, by converting string subclasses
133 to exact strings and complaining if a non-string is found. */
136 {
150 }
153 PyExc_TypeError,
154 "name tuples must contain only "
159 }
167 }
168 }
170 }
173 }
183 {
214 PyExc_ValueError,
217 }
221 PyExc_ValueError,
224 }
234 else
240 else
249 cleanup:
255 }
257 static void
259 {
272 }
276 {
292 }
294 static int
296 {
321 normalize:
326 else
328 }
330 static long
332 {
352 }
354 /* XXX code objects need to participate in GC? */
356 PyTypeObject PyCode_Type = {
395 };
397 /* All about c_lnotab.
399 c_lnotab is an array of unsigned bytes disguised as a Python string. In -O
400 mode, SET_LINENO opcodes aren't generated, and bytecode offsets are mapped
401 to source code line #s (when needed for tracebacks) via c_lnotab instead.
402 The array is conceptually a list of
403 (bytecode offset increment, line number increment)
404 pairs. The details are important and delicate, best illustrated by example:
406 byte code offset source code line number
407 0 1
408 6 2
409 50 7
410 350 307
411 361 308
413 The first trick is that these numbers aren't stored, only the increments
414 from one row to the next (this doesn't really work, but it's a start):
416 0, 1, 6, 1, 44, 5, 300, 300, 11, 1
418 The second trick is that an unsigned byte can't hold negative values, or
419 values larger than 255, so (a) there's a deep assumption that byte code
420 offsets and their corresponding line #s both increase monotonically, and (b)
421 if at least one column jumps by more than 255 from one row to the next, more
422 than one pair is written to the table. In case #b, there's no way to know
423 from looking at the table later how many were written. That's the delicate
424 part. A user of c_lnotab desiring to find the source line number
425 corresponding to a bytecode address A should do something like this
427 lineno = addr = 0
428 for addr_incr, line_incr in c_lnotab:
429 addr += addr_incr
430 if addr > A:
431 return lineno
432 lineno += line_incr
434 In order for this to work, when the addr field increments by more than 255,
435 the line # increment in each pair generated must be 0 until the remaining addr
436 increment is < 256. So, in the example above, com_set_lineno should not (as
437 was actually done until 2.2) expand 300, 300 to 255, 255, 45, 45, but to
438 255, 0, 45, 255, 0, 45.
439 */
441 int
443 {
453 }
455 }
457 /*
458 Check whether the current instruction is at the start of a line.
460 */
462 /* The theory of SET_LINENO-less tracing.
464 In a nutshell, we use the co_lnotab field of the code object
465 to tell when execution has moved onto a different line.
467 As mentioned above, the basic idea is so set things up so
468 that
470 *instr_lb <= frame->f_lasti < *instr_ub
472 is true so long as execution does not change lines.
474 This is all fairly simple. Digging the information out of
475 co_lnotab takes some work, but is conceptually clear.
477 Somewhat harder to explain is why we don't *always* call the
478 line trace function when the above test fails.
480 Consider this code:
482 1: def f(a):
483 2: if a:
484 3: print 1
485 4: else:
486 5: print 2
488 which compiles to this:
490 2 0 LOAD_FAST 0 (a)
491 3 JUMP_IF_FALSE 9 (to 15)
492 6 POP_TOP
494 3 7 LOAD_CONST 1 (1)
495 10 PRINT_ITEM
496 11 PRINT_NEWLINE
497 12 JUMP_FORWARD 6 (to 21)
498 >> 15 POP_TOP
500 5 16 LOAD_CONST 2 (2)
501 19 PRINT_ITEM
502 20 PRINT_NEWLINE
503 >> 21 LOAD_CONST 0 (None)
504 24 RETURN_VALUE
506 If 'a' is false, execution will jump to instruction at offset
507 15 and the co_lnotab will claim that execution has moved to
508 line 3. This is at best misleading. In this case we could
509 associate the POP_TOP with line 4, but that doesn't make
510 sense in all cases (I think).
512 What we do is only call the line trace function if the co_lnotab
513 indicates we have jumped to the *start* of a line, i.e. if the
514 current instruction offset matches the offset given for the
515 start of a line by the co_lnotab.
517 This also takes care of the situation where 'a' is true.
518 Execution will jump from instruction offset 12 to offset 21.
519 Then the co_lnotab would imply that execution has moved to line
520 5, which is again misleading.
522 Why do we set f_lineno when tracing? Well, consider the code
523 above when 'a' is true. If stepping through this with 'n' in
524 pdb, you would stop at line 1 with a "call" type event, then
525 line events on lines 2 and 3, then a "return" type event -- but
526 you would be shown line 5 during this event. This is a change
527 from the behaviour in 2.2 and before, and I've found it
528 confusing in practice. By setting and using f_lineno when
529 tracing, one can report a line number different from that
530 suggested by f_lasti on this one occasion where it's desirable.
531 */
534 int
536 {
547 /* possible optimization: if f->f_lasti == instr_ub
548 (likely to be a common case) then we already know
549 instr_lb -- if we stored the matching value of p
550 somwhere we could skip the first while loop. */
552 /* see comments in compile.c for the description of
553 co_lnotab. A point to remember: increments to p
554 should come in pairs -- although we don't care about
555 the line increments here, treating them as byte
556 increments gets confusing, to say the least. */
567 }
569 /* If lasti and addr don't match exactly, we don't want to
570 change the lineno slot on the frame or execute a trace
571 function. Return -1 instead.
572 */
581 }
583 }
586 }
589 }