From 367adc91fb9834eb35b168048fd54705621c3f21 Mon Sep 17 00:00:00 2001 From: Irit Katriel <1055913+iritkatriel@users.noreply.github.com> Date: Mon, 3 Jun 2024 10:36:20 +0100 Subject: [PATCH] gh-119786: move exception handling doc to InternalDocs (#119815) --- InternalDocs/{index.md => README.md} | 4 + InternalDocs/exception_handling.md | 201 +++++++++++++++++++++++++++ Objects/exception_handling_notes.txt | 182 ------------------------ 3 files changed, 205 insertions(+), 182 deletions(-) rename InternalDocs/{index.md => README.md} (92%) create mode 100644 InternalDocs/exception_handling.md delete mode 100644 Objects/exception_handling_notes.txt diff --git a/InternalDocs/index.md b/InternalDocs/README.md similarity index 92% rename from InternalDocs/index.md rename to InternalDocs/README.md index 32b66a254bcf2c..e69e27d1542990 100644 --- a/InternalDocs/index.md +++ b/InternalDocs/README.md @@ -10,3 +10,7 @@ to hold for other implementations of the Python language. The core dev team attempts to keep this documentation up to date. If it is not, please report that through the [issue tracker](https://github.com/python/cpython/issues). + + +[Exception Handling](exception_handling.md) + diff --git a/InternalDocs/exception_handling.md b/InternalDocs/exception_handling.md new file mode 100644 index 00000000000000..22d9c3bf7933f1 --- /dev/null +++ b/InternalDocs/exception_handling.md @@ -0,0 +1,201 @@ +Description of exception handling +--------------------------------- + +Python uses a technique known as "zero-cost" exception handling, which +minimizes the cost of supporting exceptions. In the common case (where +no exception is raised) the cost is reduced to zero (or close to zero). +The cost of raising an exception is increased, but not by much. + +The following code: + +``` +try: + g(0) +except: + res = "fail" + +``` + +compiles into intermediate code like the following: + +``` + RESUME 0 + + 1 SETUP_FINALLY 8 (to L1) + + 2 LOAD_NAME 0 (g) + PUSH_NULL + LOAD_CONST 0 (0) + CALL 1 + POP_TOP + POP_BLOCK + + -- L1: PUSH_EXC_INFO + + 3 POP_TOP + + 4 LOAD_CONST 1 ('fail') + STORE_NAME 1 (res) +``` + +`SETUP_FINALLY` and `POP_BLOCK` are pseudo-instructions. This means +that they can appear in intermediate code but they are not bytecode +instructions. `SETUP_FINALLY` specifies that henceforth, exceptions +are handled by the code at label L1. The `POP_BLOCK` instruction +reverses the effect of the last `SETUP` instruction, so that the +active exception handler reverts to what it was before. + +`SETUP_FINALLY` and `POP_BLOCK` have no effect when no exceptions +are raised. The idea of zero-cost exception handling is to replace +these pseudo-instructions by metadata which is stored alongside the +bytecode, and which is inspected only when an exception occurs. +This metadata is the exception table, and it is stored in the code +object's `co_exceptiontable` field. + +When the pseudo-instructions are translated into bytecode, +`SETUP_FINALLY` and `POP_BLOCK` are removed, and the exception +table is constructed, mapping each instruction to the exception +handler that covers it, if any. Instructions which are not +covered by any exception handler within the same code object's +bytecode, do not appear in the exception table at all. + +For the code object in our example above, the table has a single +entry specifying that all instructions that were between the +`SETUP_FINALLY` and the `POP_BLOCK` are covered by the exception +handler located at label `L1`. + +Handling Exceptions +------------------- + +At runtime, when an exception occurs, the interpreter looks up +the offset of the current instruction in the exception table. If +it finds a handler, control flow transfers to it. Otherwise, the +exception bubbles up to the caller, and the caller's frame is +checked for a handler covering the `CALL` instruction. This +repeats until a handler is found or the topmost frame is reached. +If no handler is found, the program terminates. During unwinding, +the traceback is constructed as each frame is added to it. + +Along with the location of an exception handler, each entry of the +exception table also contains the stack depth of the `try` instruction +and a boolean `lasti` value, which indicates whether the instruction +offset of the raising instruction should be pushed to the stack. + +Handling an exception, once an exception table entry is found, consists +of the following steps: + + 1. pop values from the stack until it matches the stack depth for the handler. + 2. if `lasti` is true, then push the offset that the exception was raised at. + 3. push the exception to the stack. + 4. jump to the target offset and resume execution. + + +Reraising Exceptions and `lasti` +-------------------------------- + +The purpose of pushing `lasti` to the stack is for cases where an exception +needs to be re-raised, and be associated with the original instruction that +raised it. This happens, for example, at the end of a `finally` block, when +any in-flight exception needs to be propagated on. As the frame's instruction +pointer now points into the finally block, a `RERAISE` instruction +(with `oparg > 0`) sets it to the `lasti` value from the stack. + +Format of the exception table +----------------------------- + +Conceptually, the exception table consists of a sequence of 5-tuples: +``` + 1. `start-offset` (inclusive) + 2. `end-offset` (exclusive) + 3. `target` + 4. `stack-depth` + 5. `push-lasti` (boolean) +``` + +All offsets and lengths are in code units, not bytes. + +We want the format to be compact, but quickly searchable. +For it to be compact, it needs to have variable sized entries so that we can store common (small) offsets compactly, but handle large offsets if needed. +For it to be searchable quickly, we need to support binary search giving us log(n) performance in all cases. +Binary search typically assumes fixed size entries, but that is not necessary, as long as we can identify the start of an entry. + +It is worth noting that the size (end-start) is always smaller than the end, so we encode the entries as: + `start, size, target, depth, push-lasti`. + +Also, sizes are limited to 2**30 as the code length cannot exceed 2**31 and each code unit takes 2 bytes. +It also happens that depth is generally quite small. + +So, we need to encode: +``` + `start` (up to 30 bits) + `size` (up to 30 bits) + `target` (up to 30 bits) + `depth` (up to ~8 bits) + `lasti` (1 bit) +``` + +We need a marker for the start of the entry, so the first byte of entry will have the most significant bit set. +Since the most significant bit is reserved for marking the start of an entry, we have 7 bits per byte to encode offsets. +Encoding uses a standard varint encoding, but with only 7 bits instead of the usual 8. +The 8 bits of a byte are (msb left) SXdddddd where S is the start bit. X is the extend bit meaning that the next byte is required to extend the offset. + +In addition, we combine `depth` and `lasti` into a single value, `((depth<<1)+lasti)`, before encoding. + +For example, the exception entry: +``` + `start`: 20 + `end`: 28 + `target`: 100 + `depth`: 3 + `lasti`: False +``` + +is encoded by first converting to the more compact four value form: +``` + `start`: 20 + `size`: 8 + `target`: 100 + `depth<<1+lasti`: 6 +``` + +which is then encoded as: +``` + 148 (MSB + 20 for start) + 8 (size) + 65 (Extend bit + 1) + 36 (Remainder of target, 100 == (1<<6)+36) + 6 +``` + +for a total of five bytes. + + +Script to parse the exception table +----------------------------------- + +``` +def parse_varint(iterator): + b = next(iterator) + val = b & 63 + while b&64: + val <<= 6 + b = next(iterator) + val |= b&63 + return val +``` +``` +def parse_exception_table(code): + iterator = iter(code.co_exceptiontable) + try: + while True: + start = parse_varint(iterator)*2 + length = parse_varint(iterator)*2 + end = start + length - 2 # Present as inclusive, not exclusive + target = parse_varint(iterator)*2 + dl = parse_varint(iterator) + depth = dl >> 1 + lasti = bool(dl&1) + yield start, end, target, depth, lasti + except StopIteration: + return +``` diff --git a/Objects/exception_handling_notes.txt b/Objects/exception_handling_notes.txt deleted file mode 100644 index 387ef935ce739e..00000000000000 --- a/Objects/exception_handling_notes.txt +++ /dev/null @@ -1,182 +0,0 @@ -Description of exception handling in Python 3.11 ------------------------------------------------- - -Python 3.11 uses what is known as "zero-cost" exception handling. -Prior to 3.11, exceptions were handled by a runtime stack of "blocks". - -In zero-cost exception handling, the cost of supporting exceptions is minimized. -In the common case (where no exception is raised) the cost is reduced -to zero (or close to zero). -The cost of raising an exception is increased, but not by much. - -The following code: - -def f(): - try: - g(0) - except: - return "fail" - -compiles as follows in 3.10: - - 2 0 SETUP_FINALLY 7 (to 16) - - 3 2 LOAD_GLOBAL 0 (g) - 4 LOAD_CONST 1 (0) - 6 CALL_NO_KW 1 - 8 POP_TOP - 10 POP_BLOCK - 12 LOAD_CONST 0 (None) - 14 RETURN_VALUE - - 4 >> 16 POP_TOP - 18 POP_TOP - 20 POP_TOP - - 5 22 POP_EXCEPT - 24 LOAD_CONST 3 ('fail') - 26 RETURN_VALUE - -Note the explicit instructions to push and pop from the "block" stack: -SETUP_FINALLY and POP_BLOCK. - -In 3.11, the SETUP_FINALLY and POP_BLOCK are eliminated, replaced with -a table to determine where to jump to when an exception is raised. - - 1 0 RESUME 0 - - 2 2 NOP - - 3 4 LOAD_GLOBAL 1 (g + NULL) - 16 LOAD_CONST 1 (0) - 18 PRECALL 1 - 22 CALL 1 - 32 POP_TOP - 34 LOAD_CONST 0 (None) - 36 RETURN_VALUE - >> 38 PUSH_EXC_INFO - - 4 40 POP_TOP - - 5 42 POP_EXCEPT - 44 LOAD_CONST 2 ('fail') - 46 RETURN_VALUE - >> 48 COPY 3 - 50 POP_EXCEPT - 52 RERAISE 1 -ExceptionTable: - 4 to 32 -> 38 [0] - 38 to 40 -> 48 [1] lasti - -(Note this code is from 3.11, later versions may have slightly different bytecode.) - -If an instruction raises an exception then its offset is used to find the target to jump to. -For example, the CALL at offset 22, falls into the range 4 to 32. -So, if g() raises an exception, then control jumps to offset 38. - - -Unwinding ---------- - -When an exception is raised, the current instruction offset is used to find following: -target to jump to, stack depth, and 'lasti', which determines whether the instruction -offset of the raising instruction should be pushed. - -This information is stored in the exception table, described below. - -If there is no relevant entry, the exception bubbles up to the caller. - -If there is an entry, then: - 1. pop values from the stack until it matches the stack depth for the handler. - 2. if 'lasti' is true, then push the offset that the exception was raised at. - 3. push the exception to the stack. - 4. jump to the target offset and resume execution. - - -Format of the exception table ------------------------------ - -Conceptually, the exception table consists of a sequence of 5-tuples: - 1. start-offset (inclusive) - 2. end-offset (exclusive) - 3. target - 4. stack-depth - 5. push-lasti (boolean) - -All offsets and lengths are in instructions, not bytes. - -We want the format to be compact, but quickly searchable. -For it to be compact, it needs to have variable sized entries so that we can store common (small) offsets compactly, but handle large offsets if needed. -For it to be searchable quickly, we need to support binary search giving us log(n) performance in all cases. -Binary search typically assumes fixed size entries, but that is not necessary, as long as we can identify the start of an entry. - -It is worth noting that the size (end-start) is always smaller than the end, so we encode the entries as: - start, size, target, depth, push-lasti - -Also, sizes are limited to 2**30 as the code length cannot exceed 2**31 and each instruction takes 2 bytes. -It also happens that depth is generally quite small. - -So, we need to encode: - start (up to 30 bits) - size (up to 30 bits) - target (up to 30 bits) - depth (up to ~8 bits) - lasti (1 bit) - -We need a marker for the start of the entry, so the first byte of entry will have the most significant bit set. -Since the most significant bit is reserved for marking the start of an entry, we have 7 bits per byte to encode offsets. -Encoding uses a standard varint encoding, but with only 7 bits instead of the usual 8. -The 8 bits of a bit are (msb left) SXdddddd where S is the start bit. X is the extend bit meaning that the next byte is required to extend the offset. - -In addition, we will combine depth and lasti into a single value, ((depth<<1)+lasti), before encoding. - -For example, the exception entry: - start: 20 - end: 28 - target: 100 - depth: 3 - lasti: False - -is encoded first by converting to the more compact four value form: - start: 20 - size: 8 - target: 100 - depth<<1+lasti: 6 - -which is then encoded as: - 148 (MSB + 20 for start) - 8 (size) - 65 (Extend bit + 1) - 36 (Remainder of target, 100 == (1<<6)+36) - 6 - -for a total of five bytes. - - - -Script to parse the exception table ------------------------------------ - -def parse_varint(iterator): - b = next(iterator) - val = b & 63 - while b&64: - val <<= 6 - b = next(iterator) - val |= b&63 - return val - -def parse_exception_table(code): - iterator = iter(code.co_exceptiontable) - try: - while True: - start = parse_varint(iterator)*2 - length = parse_varint(iterator)*2 - end = start + length - 2 # Present as inclusive, not exclusive - target = parse_varint(iterator)*2 - dl = parse_varint(iterator) - depth = dl >> 1 - lasti = bool(dl&1) - yield start, end, target, depth, lasti - except StopIteration: - return