1 | \chapter{Exception Features} |
---|
2 | \label{c:features} |
---|
3 | |
---|
4 | This chapter covers the design and user interface of the \CFA EHM |
---|
5 | and begins with a general overview of EHMs. It is not a strict |
---|
6 | definition of all EHMs nor an exhaustive list of all possible features. |
---|
7 | However, it does cover the most common structure and features found in them. |
---|
8 | |
---|
9 | \section{Overview of EHMs} |
---|
10 | % We should cover what is an exception handling mechanism and what is an |
---|
11 | % exception before this. Probably in the introduction. Some of this could |
---|
12 | % move there. |
---|
13 | \subsection{Raise / Handle} |
---|
14 | An exception operation has two main parts: raise and handle. |
---|
15 | These terms are sometimes known as throw and catch but this work uses |
---|
16 | throw/catch as a particular kind of raise/handle. |
---|
17 | These are the two parts that the user writes and may |
---|
18 | be the only two pieces of the EHM that have any syntax in a language. |
---|
19 | |
---|
20 | \paragraph{Raise} |
---|
21 | The raise is the starting point for exception handling, |
---|
22 | by raising an exception, which passes it to |
---|
23 | the EHM. |
---|
24 | |
---|
25 | Some well known examples include the @throw@ statements of \Cpp and Java and |
---|
26 | the \code{Python}{raise} statement of Python. In real systems, a raise may |
---|
27 | perform some other work (such as memory management) but for the |
---|
28 | purposes of this overview that can be ignored. |
---|
29 | |
---|
30 | \paragraph{Handle} |
---|
31 | The primary purpose of an EHM is to run some user code to handle a raised |
---|
32 | exception. This code is given, along with some other information, |
---|
33 | in a handler. |
---|
34 | |
---|
35 | A handler has three common features: the previously mentioned user code, a |
---|
36 | region of code it guards and an exception label/condition that matches |
---|
37 | against the raised exception. |
---|
38 | Only raises inside the guarded region and raising exceptions that match the |
---|
39 | label can be handled by a given handler. |
---|
40 | If multiple handlers could can handle an exception, |
---|
41 | EHMs define a rule to pick one, such as ``best match" or ``first found". |
---|
42 | |
---|
43 | The @try@ statements of \Cpp, Java and Python are common examples. All three |
---|
44 | also show another common feature of handlers: they are grouped by the guarded |
---|
45 | region. |
---|
46 | |
---|
47 | \subsection{Propagation} |
---|
48 | After an exception is raised comes what is usually the biggest step for the |
---|
49 | EHM: finding and setting up the handler for execution. |
---|
50 | The propagation from raise to |
---|
51 | handler can be broken up into three different tasks: searching for a handler, |
---|
52 | matching against the handler and installing the handler. |
---|
53 | |
---|
54 | \paragraph{Searching} |
---|
55 | The EHM begins by searching for handlers that might be used to handle |
---|
56 | the exception. |
---|
57 | The search will find handlers that have the raise site in their guarded |
---|
58 | region. |
---|
59 | The search includes handlers in the current function, as well as any in |
---|
60 | callers on the stack that have the function call in their guarded region. |
---|
61 | |
---|
62 | \paragraph{Matching} |
---|
63 | Each handler found is with the raised exception. The exception |
---|
64 | label defines a condition that is used with the exception and decides if |
---|
65 | there is a match or not. |
---|
66 | % |
---|
67 | In languages where the first match is used, this step is intertwined with |
---|
68 | searching; a match check is performed immediately after the search finds |
---|
69 | a handler. |
---|
70 | |
---|
71 | \paragraph{Installing} |
---|
72 | After a handler is chosen, it must be made ready to run. |
---|
73 | The implementation can vary widely to fit with the rest of the |
---|
74 | design of the EHM. The installation step might be trivial or it could be |
---|
75 | the most expensive step in handling an exception. The latter tends to be the |
---|
76 | case when stack unwinding is involved. |
---|
77 | |
---|
78 | If a matching handler is not guaranteed to be found, the EHM needs a |
---|
79 | different course of action for this case. |
---|
80 | This situation only occurs with unchecked exceptions as checked exceptions |
---|
81 | (such as in Java) can make the guarantee. |
---|
82 | The unhandled action is usually very general, such as aborting the program. |
---|
83 | |
---|
84 | \paragraph{Hierarchy} |
---|
85 | A common way to organize exceptions is in a hierarchical structure. |
---|
86 | This pattern comes from object-orientated languages where the |
---|
87 | exception hierarchy is a natural extension of the object hierarchy. |
---|
88 | |
---|
89 | Consider the following exception hierarchy: |
---|
90 | \begin{center} |
---|
91 | \input{exception-hierarchy} |
---|
92 | \end{center} |
---|
93 | A handler labeled with any given exception can handle exceptions of that |
---|
94 | type or any child type of that exception. The root of the exception hierarchy |
---|
95 | (here \code{C}{exception}) acts as a catch-all, leaf types catch single types |
---|
96 | and the exceptions in the middle can be used to catch different groups of |
---|
97 | related exceptions. |
---|
98 | |
---|
99 | This system has some notable advantages, such as multiple levels of grouping, |
---|
100 | the ability for libraries to add new exception types and the isolation |
---|
101 | between different sub-hierarchies. |
---|
102 | This design is used in \CFA even though it is not a object-orientated |
---|
103 | language, so different tools are used to create the hierarchy. |
---|
104 | |
---|
105 | % Could I cite the rational for the Python IO exception rework? |
---|
106 | |
---|
107 | \subsection{Completion} |
---|
108 | After the handler has finished, the entire exception operation has to complete |
---|
109 | and continue executing somewhere else. This step is usually simple, |
---|
110 | both logically and in its implementation, as the installation of the handler |
---|
111 | is usually set up to do most of the work. |
---|
112 | |
---|
113 | The EHM can return control to many different places, where |
---|
114 | the most common are after the handler definition (termination) |
---|
115 | and after the raise (resumption). |
---|
116 | |
---|
117 | \subsection{Communication} |
---|
118 | For effective exception handling, additional information is often passed |
---|
119 | from the raise to the handler and back again. |
---|
120 | So far, only communication of the exception's identity is covered. |
---|
121 | A common communication method for adding information to an exception |
---|
122 | is putting fields into the exception instance |
---|
123 | and giving the handler access to them. |
---|
124 | % You can either have pointers/references in the exception, or have p/rs to |
---|
125 | % the exception when it doesn't have to be copied. |
---|
126 | Passing references or pointers allows data at the raise location to be |
---|
127 | updated, passing information in both directions. |
---|
128 | |
---|
129 | \section{Virtuals} |
---|
130 | \label{s:virtuals} |
---|
131 | A common feature in many programming languages is a tool to pair code |
---|
132 | (behaviour) with data. |
---|
133 | In \CFA this is done with the virtual system, |
---|
134 | which allow type information to be abstracted away, recovered and allow |
---|
135 | operations to be performed on the abstract objects. |
---|
136 | |
---|
137 | Virtual types and casts are not part of \CFA's EHM nor are they required for |
---|
138 | an EHM. |
---|
139 | However, one of the best ways to support an exception hierarchy |
---|
140 | is via a virtual hierarchy and dispatch system. |
---|
141 | Ideally, the virtual system would have been part of \CFA before the work |
---|
142 | on exception handling began, but unfortunately it was not. |
---|
143 | Hence, only the features and framework needed for the EHM were |
---|
144 | designed and implemented for this thesis. |
---|
145 | Other features were considered to ensure that |
---|
146 | the structure could accommodate other desirable features in the future |
---|
147 | but are not implemented. |
---|
148 | The rest of this section only discusses the implemented subset of the |
---|
149 | virtual system design. |
---|
150 | |
---|
151 | The virtual system supports multiple ``trees" of types. Each tree is |
---|
152 | a simple hierarchy with a single root type. Each type in a tree has exactly |
---|
153 | one parent -- except for the root type which has zero parents -- and any |
---|
154 | number of children. |
---|
155 | Any type that belongs to any of these trees is called a virtual type. |
---|
156 | % A type's ancestors are its parent and its parent's ancestors. |
---|
157 | % The root type has no ancestors. |
---|
158 | % A type's descendants are its children and its children's descendants. |
---|
159 | |
---|
160 | For the purposes of illustration, a proposed, but unimplemented, syntax |
---|
161 | will be used. Each virtual type is represented by a trait with an annotation |
---|
162 | that makes it a virtual type. This annotation is empty for a root type, which |
---|
163 | creates a new tree: |
---|
164 | \begin{cfa} |
---|
165 | trait root_type(T) virtual() {} |
---|
166 | \end{cfa} |
---|
167 | The annotation may also refer to any existing virtual type to make this new |
---|
168 | type a child of that type and part of the same tree. The parent may itself |
---|
169 | be a child or a root type and may have any number of existing children. |
---|
170 | |
---|
171 | % OK, for some reason the b and t positioning options are reversed here. |
---|
172 | \begin{minipage}[b]{0.6\textwidth} |
---|
173 | \begin{cfa} |
---|
174 | trait child_a(T) virtual(root_type) {} |
---|
175 | trait grandchild(T) virtual(child_a) {} |
---|
176 | trait child_b(T) virtual(root_type) {} |
---|
177 | \end{cfa} |
---|
178 | \end{minipage} |
---|
179 | \begin{minipage}{0.4\textwidth} |
---|
180 | \begin{center} |
---|
181 | \input{virtual-tree} |
---|
182 | \end{center} |
---|
183 | \end{minipage} |
---|
184 | |
---|
185 | Every virtual type also has a list of virtual members and a unique id. |
---|
186 | Both are stored in a virtual table. |
---|
187 | Every instance of a virtual type also has a pointer to a virtual table stored |
---|
188 | in it, although there is no per-type virtual table as in many other languages. |
---|
189 | |
---|
190 | The list of virtual members is accumulated from the root type down the tree. |
---|
191 | Every virtual type |
---|
192 | inherits the list of virtual members from its parent and may add more |
---|
193 | virtual members to the end of the list which are passed on to its children. |
---|
194 | Again, using the unimplemented syntax this might look like: |
---|
195 | \begin{cfa} |
---|
196 | trait root_type(T) virtual() { |
---|
197 | const char * to_string(T const & this); |
---|
198 | unsigned int size; |
---|
199 | } |
---|
200 | |
---|
201 | trait child_type(T) virtual(root_type) { |
---|
202 | char * irrelevant_function(int, char); |
---|
203 | } |
---|
204 | \end{cfa} |
---|
205 | % Consider adding a diagram, but we might be good with the explanation. |
---|
206 | |
---|
207 | As @child_type@ is a child of @root_type@, it has the virtual members of |
---|
208 | @root_type@ (@to_string@ and @size@) as well as the one it declared |
---|
209 | (@irrelevant_function@). |
---|
210 | |
---|
211 | It is important to note that these are virtual members, and may contain |
---|
212 | arbitrary fields, functions or otherwise. |
---|
213 | The names ``size" and ``align" are reserved for the size and alignment of the |
---|
214 | virtual type, and are always automatically initialized as such. |
---|
215 | The other special case is uses of the trait's polymorphic argument |
---|
216 | (@T@ in the example), which are always updated to refer to the current |
---|
217 | virtual type. This allows functions that refer to the polymorphic argument |
---|
218 | to act as traditional virtual methods (@to_string@ in the example), as the |
---|
219 | object can always be passed to a virtual method in its virtual table. |
---|
220 | |
---|
221 | Up until this point, the virtual system is similar to ones found in |
---|
222 | object-oriented languages, but this is where \CFA diverges. |
---|
223 | Objects encapsulate a single set of methods in each type, |
---|
224 | universally across the entire program, |
---|
225 | and indeed all programs that use that type definition. |
---|
226 | The only way to change any method is to inherit and define a new type with |
---|
227 | its own universal implementation. In this sense, |
---|
228 | these object-oriented types are ``closed" and cannot be altered. |
---|
229 | % Because really they are class oriented. |
---|
230 | |
---|
231 | In \CFA, types do not encapsulate any code. |
---|
232 | Whether or not a type satisfies any given assertion, and hence any trait, is |
---|
233 | context sensitive. Types can begin to satisfy a trait, stop satisfying it or |
---|
234 | satisfy the same trait at any lexical location in the program. |
---|
235 | In this sense, a type's implementation in the set of functions and variables |
---|
236 | that allow it to satisfy a trait is ``open" and can change |
---|
237 | throughout the program. |
---|
238 | This capability means it is impossible to pick a single set of functions |
---|
239 | that represent a type's implementation across a program. |
---|
240 | |
---|
241 | \CFA side-steps this issue by not having a single virtual table for each |
---|
242 | type. A user can define virtual tables that are filled in at their |
---|
243 | declaration and given a name. Anywhere that name is visible, even if it is |
---|
244 | defined locally inside a function (although in this case the user must ensure |
---|
245 | it outlives any objects that use it), it can be used. |
---|
246 | Specifically, a virtual type is ``bound" to a virtual table that |
---|
247 | sets the virtual members for that object. The virtual members can be accessed |
---|
248 | through the object. |
---|
249 | |
---|
250 | This means virtual tables are declared and named in \CFA. |
---|
251 | They are declared as variables, using the type |
---|
252 | @vtable(VIRTUAL_TYPE)@ and any valid name. For example: |
---|
253 | \begin{cfa} |
---|
254 | vtable(virtual_type_name) table_name; |
---|
255 | \end{cfa} |
---|
256 | |
---|
257 | Like any variable, they may be forward declared with the @extern@ keyword. |
---|
258 | Forward declaring virtual tables is relatively common. |
---|
259 | Many virtual types have an ``obvious" implementation that works in most |
---|
260 | cases. |
---|
261 | A pattern that has appeared in the early work using virtuals is to |
---|
262 | implement a virtual table with the the obvious definition and place a forward |
---|
263 | declaration of it in the header beside the definition of the virtual type. |
---|
264 | |
---|
265 | Even on the full declaration, no initializer should be used. |
---|
266 | Initialization is automatic. |
---|
267 | The type id and special virtual members ``size" and ``align" only depend on |
---|
268 | the virtual type, which is fixed given the type of the virtual table, and |
---|
269 | so the compiler fills in a fixed value. |
---|
270 | The other virtual members are resolved using the best match to the member's |
---|
271 | name and type, in the same context as the virtual table is declared using |
---|
272 | \CFA's normal resolution rules. |
---|
273 | |
---|
274 | While much of the virtual infrastructure has been created, |
---|
275 | it is currently only used |
---|
276 | internally for exception handling. The only user-level feature is the virtual |
---|
277 | cast, which is the same as the \Cpp \code{C++}{dynamic_cast}. |
---|
278 | \label{p:VirtualCast} |
---|
279 | \begin{cfa} |
---|
280 | (virtual TYPE)EXPRESSION |
---|
281 | \end{cfa} |
---|
282 | Note, the syntax and semantics matches a C-cast, rather than the function-like |
---|
283 | \Cpp syntax for special casts. Both the type of @EXPRESSION@ and @TYPE@ must be |
---|
284 | pointers to virtual types. |
---|
285 | The cast dynamically checks if the @EXPRESSION@ type is the same or a sub-type |
---|
286 | of @TYPE@, and if true, returns a pointer to the |
---|
287 | @EXPRESSION@ object, otherwise it returns @0p@ (null pointer). |
---|
288 | This allows the expression to be used as both a cast and a type check. |
---|
289 | |
---|
290 | \section{Exceptions} |
---|
291 | |
---|
292 | The syntax for declaring an exception is the same as declaring a structure |
---|
293 | except the keyword: |
---|
294 | \begin{cfa} |
---|
295 | exception TYPE_NAME { |
---|
296 | FIELDS |
---|
297 | }; |
---|
298 | \end{cfa} |
---|
299 | |
---|
300 | Fields are filled in the same way as a structure as well. However, an extra |
---|
301 | field is added that contains the pointer to the virtual table. |
---|
302 | It must be explicitly initialized by the user when the exception is |
---|
303 | constructed. |
---|
304 | |
---|
305 | Here is an example of declaring an exception type along with a virtual table, |
---|
306 | assuming the exception has an ``obvious" implementation and a default |
---|
307 | virtual table makes sense. |
---|
308 | |
---|
309 | \begin{minipage}[t]{0.4\textwidth} |
---|
310 | Header (.hfa): |
---|
311 | \begin{cfa} |
---|
312 | exception Example { |
---|
313 | int data; |
---|
314 | }; |
---|
315 | |
---|
316 | extern vtable(Example) |
---|
317 | example_base_vtable; |
---|
318 | \end{cfa} |
---|
319 | \end{minipage} |
---|
320 | \begin{minipage}[t]{0.6\textwidth} |
---|
321 | Implementation (.cfa): |
---|
322 | \begin{cfa} |
---|
323 | vtable(Example) example_base_vtable |
---|
324 | \end{cfa} |
---|
325 | \vfil |
---|
326 | \end{minipage} |
---|
327 | |
---|
328 | %\subsection{Exception Details} |
---|
329 | This is the only interface needed when raising and handling exceptions. |
---|
330 | However, it is actually a shorthand for a more complex |
---|
331 | trait-based interface. |
---|
332 | |
---|
333 | The language views exceptions through a series of traits. |
---|
334 | If a type satisfies them, then it can be used as an exception. The following |
---|
335 | is the base trait all exceptions need to match. |
---|
336 | \begin{cfa} |
---|
337 | trait is_exception(exceptT &, virtualT &) { |
---|
338 | // Numerous imaginary assertions. |
---|
339 | }; |
---|
340 | \end{cfa} |
---|
341 | The trait is defined over two types: the exception type and the virtual table |
---|
342 | type. Each exception type should have a single virtual table type. |
---|
343 | There are no actual assertions in this trait because the trait system |
---|
344 | cannot express them yet (adding such assertions would be part of |
---|
345 | completing the virtual system). The imaginary assertions would probably come |
---|
346 | from a trait defined by the virtual system, and state that the exception type |
---|
347 | is a virtual type, |
---|
348 | that that the type is a descendant of @exception_t@ (the base exception type) |
---|
349 | and allow the user to find the virtual table type. |
---|
350 | |
---|
351 | % I did have a note about how it is the programmer's responsibility to make |
---|
352 | % sure the function is implemented correctly. But this is true of every |
---|
353 | % similar system I know of (except Agda's I guess) so I took it out. |
---|
354 | |
---|
355 | There are two more traits for exceptions defined as follows: |
---|
356 | \begin{cfa} |
---|
357 | trait is_termination_exception( |
---|
358 | exceptT &, virtualT & | is_exception(exceptT, virtualT)) { |
---|
359 | void defaultTerminationHandler(exceptT &); |
---|
360 | }; |
---|
361 | |
---|
362 | trait is_resumption_exception( |
---|
363 | exceptT &, virtualT & | is_exception(exceptT, virtualT)) { |
---|
364 | void defaultResumptionHandler(exceptT &); |
---|
365 | }; |
---|
366 | \end{cfa} |
---|
367 | Both traits ensure a pair of types is an exception type and |
---|
368 | its virtual table type, |
---|
369 | and defines one of the two default handlers. The default handlers are used |
---|
370 | as fallbacks and are discussed in detail in \autoref{s:ExceptionHandling}. |
---|
371 | |
---|
372 | However, all three of these traits can be tricky to use directly. |
---|
373 | While there is a bit of repetition required, |
---|
374 | the largest issue is that the virtual table type is mangled and not in a user |
---|
375 | facing way. So, these three macros are provided to wrap these traits to |
---|
376 | simplify referring to the names: |
---|
377 | @IS_EXCEPTION@, @IS_TERMINATION_EXCEPTION@ and @IS_RESUMPTION_EXCEPTION@. |
---|
378 | |
---|
379 | All three take one or two arguments. The first argument is the name of the |
---|
380 | exception type. The macro passes its unmangled and mangled form to the trait. |
---|
381 | The second (optional) argument is a parenthesized list of polymorphic |
---|
382 | arguments. This argument is only used with polymorphic exceptions and the |
---|
383 | list is passed to both types. |
---|
384 | In the current set-up, the two types always have the same polymorphic |
---|
385 | arguments, so these macros can be used without losing flexibility. |
---|
386 | |
---|
387 | For example, consider a function that is polymorphic over types that have a |
---|
388 | defined arithmetic exception: |
---|
389 | \begin{cfa} |
---|
390 | forall(Num | IS_EXCEPTION(Arithmetic, (Num))) |
---|
391 | void some_math_function(Num & left, Num & right); |
---|
392 | \end{cfa} |
---|
393 | |
---|
394 | \section{Exception Handling} |
---|
395 | \label{s:ExceptionHandling} |
---|
396 | As stated, |
---|
397 | \CFA provides two kinds of exception handling: termination and resumption. |
---|
398 | These twin operations are the core of \CFA's exception handling mechanism. |
---|
399 | This section covers the general patterns shared by the two operations and |
---|
400 | then goes on to cover the details of each individual operation. |
---|
401 | |
---|
402 | Both operations follow the same set of steps. |
---|
403 | First, a user raises an exception. |
---|
404 | Second, the exception propagates up the stack, searching for a handler. |
---|
405 | Third, if a handler is found, the exception is caught and the handler is run. |
---|
406 | After that control continues at a raise-dependent location. |
---|
407 | As an alternate to the third step, |
---|
408 | if a handler is not found, a default handler is run and, if it returns, |
---|
409 | then control |
---|
410 | continues after the raise. |
---|
411 | |
---|
412 | The differences between the two operations include how propagation is |
---|
413 | performed, where execution continues after an exception is handled |
---|
414 | and which default handler is run. |
---|
415 | |
---|
416 | \subsection{Termination} |
---|
417 | \label{s:Termination} |
---|
418 | Termination handling is the familiar kind of handling |
---|
419 | used in most programming |
---|
420 | languages with exception handling. |
---|
421 | It is a dynamic, non-local goto. If the raised exception is matched and |
---|
422 | handled, the stack is unwound and control (usually) continues in the function |
---|
423 | on the call stack that defined the handler. |
---|
424 | Termination is commonly used when an error has occurred and recovery is |
---|
425 | impossible locally. |
---|
426 | |
---|
427 | % (usually) Control can continue in the current function but then a different |
---|
428 | % control flow construct should be used. |
---|
429 | |
---|
430 | A termination raise is started with the @throw@ statement: |
---|
431 | \begin{cfa} |
---|
432 | throw EXPRESSION; |
---|
433 | \end{cfa} |
---|
434 | The expression must return a reference to a termination exception, where the |
---|
435 | termination exception is any type that satisfies the trait |
---|
436 | @is_termination_exception@ at the call site. |
---|
437 | Through \CFA's trait system, the trait functions are implicitly passed into the |
---|
438 | throw code for use by the EHM. |
---|
439 | A new @defaultTerminationHandler@ can be defined in any scope to |
---|
440 | change the throw's behaviour when a handler is not found (see below). |
---|
441 | |
---|
442 | The throw copies the provided exception into managed memory to ensure |
---|
443 | the exception is not destroyed if the stack is unwound. |
---|
444 | It is the user's responsibility to ensure the original exception is cleaned |
---|
445 | up whether the stack is unwound or not. Allocating it on the stack is |
---|
446 | usually sufficient. |
---|
447 | |
---|
448 | % How to say propagation starts, its first sub-step is the search. |
---|
449 | Then propagation starts with the search. \CFA uses a ``first match" rule so |
---|
450 | matching is performed with the copied exception as the search key. |
---|
451 | It starts from the raise site and proceeds towards base of the stack, |
---|
452 | from callee to caller. |
---|
453 | At each stack frame, a check is made for termination handlers defined by the |
---|
454 | @catch@ clauses of a @try@ statement. |
---|
455 | \begin{cfa} |
---|
456 | try { |
---|
457 | GUARDED_BLOCK |
---|
458 | } catch (EXCEPTION_TYPE$\(_1\)$ * [NAME$\(_1\)$]) { |
---|
459 | HANDLER_BLOCK$\(_1\)$ |
---|
460 | } catch (EXCEPTION_TYPE$\(_2\)$ * [NAME$\(_2\)$]) { |
---|
461 | HANDLER_BLOCK$\(_2\)$ |
---|
462 | } |
---|
463 | \end{cfa} |
---|
464 | When viewed on its own, a try statement simply executes the statements |
---|
465 | in the \snake{GUARDED_BLOCK} and when those are finished, |
---|
466 | the try statement finishes. |
---|
467 | |
---|
468 | However, while the guarded statements are being executed, including any |
---|
469 | invoked functions, all the handlers in these statements are included in the |
---|
470 | search path. |
---|
471 | Hence, if a termination exception is raised, these handlers may be matched |
---|
472 | against the exception and may handle it. |
---|
473 | |
---|
474 | Exception matching checks the handler in each catch clause in the order |
---|
475 | they appear, top to bottom. If the representation of the raised exception type |
---|
476 | is the same or a descendant of @EXCEPTION_TYPE@$_i$, then @NAME@$_i$ |
---|
477 | (if provided) is |
---|
478 | bound to a pointer to the exception and the statements in @HANDLER_BLOCK@$_i$ |
---|
479 | are executed. If control reaches the end of the handler, the exception is |
---|
480 | freed and control continues after the try statement. |
---|
481 | |
---|
482 | If no termination handler is found during the search, then the default handler |
---|
483 | (\defaultTerminationHandler) visible at the raise statement is called. |
---|
484 | Through \CFA's trait system the best match at the raise statement is used. |
---|
485 | This function is run and is passed the copied exception. |
---|
486 | If the default handler finishes, control continues after the raise statement. |
---|
487 | |
---|
488 | There is a global @defaultTerminationHandler@ that is polymorphic over all |
---|
489 | termination exception types. |
---|
490 | The global default termination handler performs a cancellation |
---|
491 | (as described in \vref{s:Cancellation}) |
---|
492 | on the current stack with the copied exception. |
---|
493 | Since it is so general, a more specific handler can be defined, |
---|
494 | overriding the default behaviour for the specific exception types. |
---|
495 | |
---|
496 | For example, consider an error reading a configuration file. |
---|
497 | This is most likely a problem with the configuration file (@config_error@), |
---|
498 | but the function could have been passed the wrong file name (@arg_error@). |
---|
499 | In this case the function could raise one exception and then, if it is |
---|
500 | unhandled, raise the other. |
---|
501 | This is not usual behaviour for either exception so changing the |
---|
502 | default handler will be done locally: |
---|
503 | \begin{cfa} |
---|
504 | { |
---|
505 | void defaultTerminationHandler(config_error &) { |
---|
506 | throw (arg_error){arg_vt}; |
---|
507 | } |
---|
508 | throw (config_error){config_vt}; |
---|
509 | } |
---|
510 | \end{cfa} |
---|
511 | |
---|
512 | \subsection{Resumption} |
---|
513 | \label{s:Resumption} |
---|
514 | |
---|
515 | Resumption exception handling is less familar form of exception handling, |
---|
516 | but is |
---|
517 | just as old~\cite{Goodenough75} and is simpler in many ways. |
---|
518 | It is a dynamic, non-local function call. If the raised exception is |
---|
519 | matched, a closure is taken from up the stack and executed, |
---|
520 | after which the raising function continues executing. |
---|
521 | The common uses for resumption exceptions include |
---|
522 | potentially repairable errors, where execution can continue in the same |
---|
523 | function once the error is corrected, and |
---|
524 | ignorable events, such as logging where nothing needs to happen and control |
---|
525 | should always continue from the raise site. |
---|
526 | |
---|
527 | Except for the changes to fit into that pattern, resumption exception |
---|
528 | handling is symmetric with termination exception handling, by design |
---|
529 | (see \autoref{s:Termination}). |
---|
530 | |
---|
531 | A resumption raise is started with the @throwResume@ statement: |
---|
532 | \begin{cfa} |
---|
533 | throwResume EXPRESSION; |
---|
534 | \end{cfa} |
---|
535 | % The new keywords are currently ``experimental" and not used in this work. |
---|
536 | It works much the same way as the termination raise, except the |
---|
537 | type must satisfy the \snake{is_resumption_exception} that uses the |
---|
538 | default handler: \defaultResumptionHandler. |
---|
539 | This can be specialized for particular exception types. |
---|
540 | |
---|
541 | At run-time, no exception copy is made. Since |
---|
542 | resumption does not unwind the stack nor otherwise remove values from the |
---|
543 | current scope, there is no need to manage memory to keep the exception |
---|
544 | allocated. |
---|
545 | |
---|
546 | Then propagation starts with the search, |
---|
547 | following the same search path as termination, |
---|
548 | from the raise site to the base of stack and top of try statement to bottom. |
---|
549 | However, the handlers on try statements are defined by @catchResume@ clauses. |
---|
550 | \begin{cfa} |
---|
551 | try { |
---|
552 | GUARDED_BLOCK |
---|
553 | } catchResume (EXCEPTION_TYPE$\(_1\)$ * [NAME$\(_1\)$]) { |
---|
554 | HANDLER_BLOCK$\(_1\)$ |
---|
555 | } catchResume (EXCEPTION_TYPE$\(_2\)$ * [NAME$\(_2\)$]) { |
---|
556 | HANDLER_BLOCK$\(_2\)$ |
---|
557 | } |
---|
558 | \end{cfa} |
---|
559 | Note that termination handlers and resumption handlers may be used together |
---|
560 | in a single try statement, intermixing @catch@ and @catchResume@ freely. |
---|
561 | Each type of handler only interacts with exceptions from the matching |
---|
562 | kind of raise. |
---|
563 | Like @catch@ clauses, @catchResume@ clauses have no effect if an exception |
---|
564 | is not raised. |
---|
565 | |
---|
566 | The matching rules are exactly the same as well. |
---|
567 | The first major difference here is that after |
---|
568 | @EXCEPTION_TYPE@$_i$ is matched and @NAME@$_i$ is bound to the exception, |
---|
569 | @HANDLER_BLOCK@$_i$ is executed right away without first unwinding the stack. |
---|
570 | After the block has finished running, control jumps to the raise site, where |
---|
571 | the just handled exception came from, and continues executing after it, |
---|
572 | not after the try statement. |
---|
573 | |
---|
574 | For instance, a resumption used to send messages to the logger may not |
---|
575 | need to be handled at all. Putting the following default handler |
---|
576 | at the global scope can make handling that exception optional by default. |
---|
577 | \begin{cfa} |
---|
578 | void defaultResumptionHandler(log_message &) { |
---|
579 | // Nothing, it is fine not to handle logging. |
---|
580 | } |
---|
581 | // ... No change at raise sites. ... |
---|
582 | throwResume (log_message){strlit_log, "Begin event processing."} |
---|
583 | \end{cfa} |
---|
584 | |
---|
585 | \subsubsection{Resumption Marking} |
---|
586 | \label{s:ResumptionMarking} |
---|
587 | A key difference between resumption and termination is that resumption does |
---|
588 | not unwind the stack. A side effect is that, when a handler is matched |
---|
589 | and run, its try block (the guarded statements) and every try statement |
---|
590 | searched before it are still on the stack. Their presence can lead to |
---|
591 | the recursive resumption problem.\cite{Buhr00a} |
---|
592 | % Other possible citation is MacLaren77, but the form is different. |
---|
593 | |
---|
594 | The recursive resumption problem is any situation where a resumption handler |
---|
595 | ends up being called while it is running. |
---|
596 | Consider a trivial case: |
---|
597 | \begin{cfa} |
---|
598 | try { |
---|
599 | throwResume (E &){}; |
---|
600 | } catchResume(E *) { |
---|
601 | throwResume (E &){}; |
---|
602 | } |
---|
603 | \end{cfa} |
---|
604 | When this code is executed, the guarded @throwResume@ starts a |
---|
605 | search and matches the handler in the @catchResume@ clause. This |
---|
606 | call is placed on the stack above the try-block. |
---|
607 | Now the second raise in the handler searches the same try block, |
---|
608 | matches again and then puts another instance of the |
---|
609 | same handler on the stack leading to infinite recursion. |
---|
610 | |
---|
611 | While this situation is trivial and easy to avoid, much more complex cycles |
---|
612 | can form with multiple handlers and different exception types. |
---|
613 | To prevent all of these cases, each try statement is ``marked" from the |
---|
614 | time the exception search reaches it to either when a handler completes |
---|
615 | handling that exception or when the search reaches the base |
---|
616 | of the stack. |
---|
617 | While a try statement is marked, its handlers are never matched, effectively |
---|
618 | skipping over it to the next try statement. |
---|
619 | |
---|
620 | \begin{center} |
---|
621 | \input{stack-marking} |
---|
622 | \end{center} |
---|
623 | |
---|
624 | There are other sets of marking rules that could be used. |
---|
625 | For instance, marking just the handlers that caught the exception |
---|
626 | would also prevent recursive resumption. |
---|
627 | However, the rules selected mirror what happens with termination, |
---|
628 | so this reduces the amount of rules and patterns a programmer has to know. |
---|
629 | |
---|
630 | The marked try statements are the ones that would be removed from |
---|
631 | the stack for a termination exception, \ie those on the stack |
---|
632 | between the handler and the raise statement. |
---|
633 | This symmetry applies to the default handler as well, as both kinds of |
---|
634 | default handlers are run at the raise statement, rather than (physically |
---|
635 | or logically) at the bottom of the stack. |
---|
636 | % In early development having the default handler happen after |
---|
637 | % unmarking was just more useful. We assume that will continue. |
---|
638 | |
---|
639 | \section{Conditional Catch} |
---|
640 | Both termination and resumption handler clauses can be given an additional |
---|
641 | condition to further control which exceptions they handle: |
---|
642 | \begin{cfa} |
---|
643 | catch (EXCEPTION_TYPE * [NAME] ; CONDITION) |
---|
644 | \end{cfa} |
---|
645 | First, the same semantics is used to match the exception type. Second, if the |
---|
646 | exception matches, @CONDITION@ is executed. The condition expression may |
---|
647 | reference all names in scope at the beginning of the try block and @NAME@ |
---|
648 | introduced in the handler clause. If the condition is true, then the handler |
---|
649 | matches. Otherwise, the exception search continues as if the exception type |
---|
650 | did not match. |
---|
651 | |
---|
652 | The condition matching allows finer matching by checking |
---|
653 | more kinds of information than just the exception type. |
---|
654 | \begin{cfa} |
---|
655 | try { |
---|
656 | handle1 = open( f1, ... ); |
---|
657 | handle2 = open( f2, ... ); |
---|
658 | handle3 = open( f3, ... ); |
---|
659 | ... |
---|
660 | } catch( IOFailure * f ; fd( f ) == f1 ) { |
---|
661 | // Only handle IO failure for f1. |
---|
662 | } catch( IOFailure * f ; fd( f ) == f3 ) { |
---|
663 | // Only handle IO failure for f3. |
---|
664 | } |
---|
665 | // Handle a failure relating to f2 further down the stack. |
---|
666 | \end{cfa} |
---|
667 | In this example, the file that experienced the IO error is used to decide |
---|
668 | which handler should be run, if any at all. |
---|
669 | |
---|
670 | \begin{comment} |
---|
671 | % I know I actually haven't got rid of them yet, but I'm going to try |
---|
672 | % to write it as if I had and see if that makes sense: |
---|
673 | \section{Reraising} |
---|
674 | \label{s:Reraising} |
---|
675 | Within the handler block or functions called from the handler block, it is |
---|
676 | possible to reraise the most recently caught exception with @throw@ or |
---|
677 | @throwResume@, respectively. |
---|
678 | \begin{cfa} |
---|
679 | try { |
---|
680 | ... |
---|
681 | } catch( ... ) { |
---|
682 | ... throw; |
---|
683 | } catchResume( ... ) { |
---|
684 | ... throwResume; |
---|
685 | } |
---|
686 | \end{cfa} |
---|
687 | The only difference between a raise and a reraise is that reraise does not |
---|
688 | create a new exception; instead it continues using the current exception, \ie |
---|
689 | no allocation and copy. However the default handler is still set to the one |
---|
690 | visible at the raise point, and hence, for termination could refer to data that |
---|
691 | is part of an unwound stack frame. To prevent this problem, a new default |
---|
692 | handler is generated that does a program-level abort. |
---|
693 | \end{comment} |
---|
694 | |
---|
695 | \subsection{Comparison with Reraising} |
---|
696 | In languages without conditional catch -- that is, no ability to match an |
---|
697 | exception based on something other than its type -- it can be mimicked |
---|
698 | by matching all exceptions of the right type, checking any additional |
---|
699 | conditions inside the handler and re-raising the exception if it does not |
---|
700 | match those. |
---|
701 | |
---|
702 | Here is a minimal example comparing both patterns, using @throw;@ |
---|
703 | (no operand) to start a re-raise. |
---|
704 | \begin{center} |
---|
705 | \begin{tabular}{l r} |
---|
706 | \begin{cfa} |
---|
707 | try { |
---|
708 | do_work_may_throw(); |
---|
709 | } catch(exception_t * exc ; |
---|
710 | can_handle(exc)) { |
---|
711 | handle(exc); |
---|
712 | } |
---|
713 | |
---|
714 | |
---|
715 | |
---|
716 | \end{cfa} |
---|
717 | & |
---|
718 | \begin{cfa} |
---|
719 | try { |
---|
720 | do_work_may_throw(); |
---|
721 | } catch(exception_t * exc) { |
---|
722 | if (can_handle(exc)) { |
---|
723 | handle(exc); |
---|
724 | } else { |
---|
725 | throw; |
---|
726 | } |
---|
727 | } |
---|
728 | \end{cfa} |
---|
729 | \end{tabular} |
---|
730 | \end{center} |
---|
731 | At first glance, catch-and-reraise may appear to just be a quality-of-life |
---|
732 | feature, but there are some significant differences between the two |
---|
733 | strategies. |
---|
734 | |
---|
735 | A simple difference that is more important for \CFA than many other languages |
---|
736 | is that the raise site changes with a re-raise, but does not with a |
---|
737 | conditional catch. |
---|
738 | This is important in \CFA because control returns to the raise site to run |
---|
739 | the per-site default handler. Because of this, only a conditional catch can |
---|
740 | allow the original raise to continue. |
---|
741 | |
---|
742 | The more complex issue comes from the difference in how conditional |
---|
743 | catches and re-raises handle multiple handlers attached to a single try |
---|
744 | statement. A conditional catch will continue checking later handlers while |
---|
745 | a re-raise will skip them. |
---|
746 | If the different handlers could handle some of the same exceptions, |
---|
747 | translating a try statement that uses one to use the other can quickly |
---|
748 | become non-trivial: |
---|
749 | |
---|
750 | \noindent |
---|
751 | Original, with conditional catch: |
---|
752 | \begin{cfa} |
---|
753 | ... |
---|
754 | } catch (an_exception * e ; check_a(e)) { |
---|
755 | handle_a(e); |
---|
756 | } catch (exception_t * e ; check_b(e)) { |
---|
757 | handle_b(e); |
---|
758 | } |
---|
759 | \end{cfa} |
---|
760 | Translated, with re-raise: |
---|
761 | \begin{cfa} |
---|
762 | ... |
---|
763 | } catch (exception_t * e) { |
---|
764 | an_exception * an_e = (virtual an_exception *)e; |
---|
765 | if (an_e && check_a(an_e)) { |
---|
766 | handle_a(an_e); |
---|
767 | } else if (check_b(e)) { |
---|
768 | handle_b(e); |
---|
769 | } else { |
---|
770 | throw; |
---|
771 | } |
---|
772 | } |
---|
773 | \end{cfa} |
---|
774 | (There is a simpler solution if @handle_a@ never raises exceptions, |
---|
775 | using nested try statements.) |
---|
776 | |
---|
777 | % } catch (an_exception * e ; check_a(e)) { |
---|
778 | % handle_a(e); |
---|
779 | % } catch (exception_t * e ; !(virtual an_exception *)e && check_b(e)) { |
---|
780 | % handle_b(e); |
---|
781 | % } |
---|
782 | % |
---|
783 | % } catch (an_exception * e) |
---|
784 | % if (check_a(e)) { |
---|
785 | % handle_a(e); |
---|
786 | % } else throw; |
---|
787 | % } catch (exception_t * e) |
---|
788 | % if (check_b(e)) { |
---|
789 | % handle_b(e); |
---|
790 | % } else throw; |
---|
791 | % } |
---|
792 | In similar simple examples, translating from re-raise to conditional catch |
---|
793 | takes less code but it does not have a general, trivial solution either. |
---|
794 | |
---|
795 | So, given that the two patterns do not trivially translate into each other, |
---|
796 | it becomes a matter of which on should be encouraged and made the default. |
---|
797 | From the premise that if a handler could handle an exception then it |
---|
798 | should, it follows that checking as many handlers as possible is preferred. |
---|
799 | So, conditional catch and checking later handlers is a good default. |
---|
800 | |
---|
801 | \section{Finally Clauses} |
---|
802 | \label{s:FinallyClauses} |
---|
803 | Finally clauses are used to perform unconditional cleanup when leaving a |
---|
804 | scope and are placed at the end of a try statement after any handler clauses: |
---|
805 | \begin{cfa} |
---|
806 | try { |
---|
807 | GUARDED_BLOCK |
---|
808 | } ... // any number or kind of handler clauses |
---|
809 | ... finally { |
---|
810 | FINALLY_BLOCK |
---|
811 | } |
---|
812 | \end{cfa} |
---|
813 | The @FINALLY_BLOCK@ is executed when the try statement is removed from the |
---|
814 | stack, including when the @GUARDED_BLOCK@ finishes, any termination handler |
---|
815 | finishes or during an unwind. |
---|
816 | The only time the block is not executed is if the program is exited before |
---|
817 | the stack is unwound. |
---|
818 | |
---|
819 | Execution of the finally block should always finish, meaning control runs off |
---|
820 | the end of the block. This requirement ensures control always continues as if |
---|
821 | the finally clause is not present, \ie finally is for cleanup, not changing |
---|
822 | control flow. |
---|
823 | Because of this requirement, local control flow out of the finally block |
---|
824 | is forbidden. The compiler precludes any @break@, @continue@, @fallthru@ or |
---|
825 | @return@ that causes control to leave the finally block. Other ways to leave |
---|
826 | the finally block, such as a @longjmp@ or termination are much harder to check, |
---|
827 | and at best require additional run-time overhead, and so are only |
---|
828 | discouraged. |
---|
829 | |
---|
830 | Not all languages with unwinding have finally clauses. Notably, \Cpp does |
---|
831 | without it as destructors, and the RAII design pattern, serve a similar role. |
---|
832 | Although destructors and finally clauses can be used for the same cases, |
---|
833 | they have their own strengths, similar to top-level function and lambda |
---|
834 | functions with closures. |
---|
835 | Destructors take more work to create, but if there is clean-up code |
---|
836 | that needs to be run every time a type is used, they are much easier |
---|
837 | to set up for each use. % It's automatic. |
---|
838 | On the other hand, finally clauses capture the local context, so are easy to |
---|
839 | use when the cleanup is not dependent on the type of a variable or requires |
---|
840 | information from multiple variables. |
---|
841 | |
---|
842 | \section{Cancellation} |
---|
843 | \label{s:Cancellation} |
---|
844 | Cancellation is a stack-level abort, which can be thought of as as an |
---|
845 | uncatchable termination. It unwinds the entire current stack, and if |
---|
846 | possible, forwards the cancellation exception to a different stack. |
---|
847 | |
---|
848 | Cancellation is not an exception operation like termination or resumption. |
---|
849 | There is no special statement for starting a cancellation; instead the standard |
---|
850 | library function @cancel_stack@ is called, passing an exception. Unlike a |
---|
851 | raise, this exception is not used in matching, only to pass information about |
---|
852 | the cause of the cancellation. |
---|
853 | Finally, as no handler is provided, there is no default handler. |
---|
854 | |
---|
855 | After @cancel_stack@ is called, the exception is copied into the EHM's memory |
---|
856 | and the current stack is unwound. |
---|
857 | The behaviour after that depends on the kind of stack being cancelled. |
---|
858 | |
---|
859 | \paragraph{Main Stack} |
---|
860 | The main stack is the one used by |
---|
861 | the program's main function at the start of execution, |
---|
862 | and is the only stack in a sequential program. |
---|
863 | After the main stack is unwound, there is a program-level abort. |
---|
864 | |
---|
865 | The first reason for this behaviour is for sequential programs where there |
---|
866 | is only one stack, and hence no stack to pass information to. |
---|
867 | Second, even in concurrent programs, the main stack has no dependency |
---|
868 | on another stack and no reliable way to find another living stack. |
---|
869 | Finally, keeping the same behaviour in both sequential and concurrent |
---|
870 | programs is simple and easy to understand. |
---|
871 | |
---|
872 | \paragraph{Thread Stack} |
---|
873 | A thread stack is created for a \CFA @thread@ object or object that satisfies |
---|
874 | the @is_thread@ trait. |
---|
875 | After a thread stack is unwound, the exception is stored until another |
---|
876 | thread attempts to join with it. Then the exception @ThreadCancelled@, |
---|
877 | which stores a reference to the thread and to the exception passed to the |
---|
878 | cancellation, is reported from the join to the joining thread. |
---|
879 | There is one difference between an explicit join (with the @join@ function) |
---|
880 | and an implicit join (from a destructor call). The explicit join takes the |
---|
881 | default handler (@defaultResumptionHandler@) from its calling context while |
---|
882 | the implicit join provides its own, which does a program abort if the |
---|
883 | @ThreadCancelled@ exception cannot be handled. |
---|
884 | |
---|
885 | The communication and synchronization are done here because threads only have |
---|
886 | two structural points (not dependent on user-code) where |
---|
887 | communication/synchronization happens: start and join. |
---|
888 | Since a thread must be running to perform a cancellation (and cannot be |
---|
889 | cancelled from another stack), the cancellation must be after start and |
---|
890 | before the join, so join is used. |
---|
891 | |
---|
892 | % TODO: Find somewhere to discuss unwind collisions. |
---|
893 | The difference between the explicit and implicit join is for safety and |
---|
894 | debugging. It helps prevent unwinding collisions by avoiding throwing from |
---|
895 | a destructor and prevents cascading the error across multiple threads if |
---|
896 | the user is not equipped to deal with it. |
---|
897 | It is always possible to add an explicit join if that is the desired behaviour. |
---|
898 | |
---|
899 | With explicit join and a default handler that triggers a cancellation, it is |
---|
900 | possible to cascade an error across any number of threads, |
---|
901 | alternating between the resumption (possibly termination) and cancellation, |
---|
902 | cleaning up each |
---|
903 | in turn, until the error is handled or the main thread is reached. |
---|
904 | |
---|
905 | \paragraph{Coroutine Stack} |
---|
906 | A coroutine stack is created for a @coroutine@ object or object that |
---|
907 | satisfies the @is_coroutine@ trait. |
---|
908 | After a coroutine stack is unwound, control returns to the @resume@ function |
---|
909 | that most recently resumed it. @resume@ reports a |
---|
910 | @CoroutineCancelled@ exception, which contains a reference to the cancelled |
---|
911 | coroutine and the exception used to cancel it. |
---|
912 | The @resume@ function also takes the \defaultResumptionHandler{} from the |
---|
913 | caller's context and passes it to the internal report. |
---|
914 | |
---|
915 | A coroutine only knows of two other coroutines, |
---|
916 | its starter and its last resumer. |
---|
917 | The starter has a much more distant connection, while the last resumer just |
---|
918 | (in terms of coroutine state) called resume on this coroutine, so the message |
---|
919 | is passed to the latter. |
---|
920 | |
---|
921 | With a default handler that triggers a cancellation, it is possible to |
---|
922 | cascade an error across any number of coroutines, |
---|
923 | alternating between the resumption (possibly termination) and cancellation, |
---|
924 | cleaning up each in turn, |
---|
925 | until the error is handled or a thread stack is reached. |
---|