diff options
author | nobody <nobody@localhost> | 2001-07-16 19:29:18 +0800 |
---|---|---|
committer | nobody <nobody@localhost> | 2001-07-16 19:29:18 +0800 |
commit | 29818ea40e49f660f2dbb25a1e0e9b260de3f1d7 (patch) | |
tree | 0b8906233912a717d50c36c848d64cdbe0cd923c /mail/README.async | |
parent | 89ddfcd774cd6ec3865d42d827eecc07dbf940d0 (diff) | |
download | gsoc2013-evolution-GAL_0_9_1.tar gsoc2013-evolution-GAL_0_9_1.tar.gz gsoc2013-evolution-GAL_0_9_1.tar.bz2 gsoc2013-evolution-GAL_0_9_1.tar.lz gsoc2013-evolution-GAL_0_9_1.tar.xz gsoc2013-evolution-GAL_0_9_1.tar.zst gsoc2013-evolution-GAL_0_9_1.zip |
This commit was manufactured by cvs2svn to create tag 'GAL_0_9_1'.GAL_0_9_1
svn path=/tags/GAL_0_9_1/; revision=11125
Diffstat (limited to 'mail/README.async')
-rw-r--r-- | mail/README.async | 366 |
1 files changed, 0 insertions, 366 deletions
diff --git a/mail/README.async b/mail/README.async deleted file mode 100644 index 3966b3a97b..0000000000 --- a/mail/README.async +++ /dev/null @@ -1,366 +0,0 @@ -******* -This document is absurdly, obscenely out of date. Don't read it. - - -- Peter Williams 7/2/2001 -******* - -Asynchronous Mailer Information -Peter Williams <peterw@helixcode.com> -8/4/2000 - -1. INTRODUCTION - -It's pretty clear that the Evolution mailer needs to be asynchronous in -some manner. Blocking the UI completely on IMAP calls or large disk reads -is unnacceptable, and it's really nice to be able to thread the message -view in the background, or do other things while a mailbox is downloading. - -The problem in making Evolution asynchronous is Camel. Camel is not -asynchronous for a few reasons. All of its interfaces are synchronous -- -calls like camel_store_get_folder, camel_folder_get_message, etc. can -take a very long time if they're being performed over a network or with -a large mbox mailbox file. However, these functions have no mechanism -for specifying that the operation is in progress but not complete, and -no mechanism for signaling when to operation does complete. - -2. WHY I DIDN'T MAKE CAMEL ASYNCHRONOUS - -It seems like it would be a good idea, then, to rewrite Camel to be -asynchonous. This presents several problems: - - * Many interfaces must be rewritten to support "completed" - callbacks, etc. Some of these interfaces are connected to - synchronous CORBA calls. - * Everything must be rewritten to be asynchonous. This includes - the CamelStore, CamelFolder, CamelMimeMessage, CamelProvider, - every subclass thereof, and all the code that touches these. - These include the files in camel/, mail/, filter/, and - composer/. The change would be a complete redesign for any - provider implementation. - * All the work on providers (IMAP, mh, mbox, nntp) up to this - point would be wasted. While they were being rewritten - evolution-mail would be useless. - -However, it is worth noting that the solution I chose is not optimal, -and I think that it would be worthwhile to write a libcamel2 or some -such thing that was designed from the ground up to work asynchronously. -Starting fresh from such a design would work, but trying to move the -existing code over would be more trouble than it's worth. - -3. WHY I MADE CAMEL THREADED - -If Camel was not going to be made asynchronous, really the only other -choice was to make it multithreaded. [1] No one has been particularly -excited by this plan, as debugging and writing MT-safe code is hard. -But there wasn't much of a choice, and I believed that a simple thread -wrapper could be written around Camel. - -The important thing to know is that while Camel is multithreaded, we -DO NOT and CANNOT share objects between threads. Instead, -evolution-mail sends a request to a dispatching thread, which performs -the action or queues it to be performed. (See section 4 for details) - -The goal that I was working towards is that there should be no calls -to camel made, ever, in the main thread. I didn't expect to and -didn't do this, but that was the intent. - -[1]. Well, we could fork off another process, but they share so much -data that this would be pretty impractical. - -4. IMPLEMENTATION - -a. CamelObject - -Threading presented a major problem regarding Camel. Camel is based -on the GTK Object system, and uses signals to communicate events. This -is okay in a nonthreaded application, but the GTK Object system is -not thread-safe. - -Particularly, signals and object allocations use static data. Using -either one inside Camel would guarantee that we'd be stuck with -random crashes forevermore. That's Bad (TM). - -There were two choices: make sure to limit our usage of GTK, or stop -using the GTK Object system. I decided to do the latter, as the -former would lead to a mess of "what GTK calls can we make" and -GDK_THREADS_ENTER and accidentally calling UI functions and upgrades -to GTK breaking everything. - -So I wrote a very very simple CamelObject system. It had three goals: - - * Be really straightforward, just encapsulate the type - heirarchy without all that GtkArg silliness or anything. - * Be as compatible as possible with the GTK Object system - to make porting easy - * Be threadsafe - -It supports: - - * Type inheritance - * Events (signals) - * Type checking - * Normal refcounting - * No unref/destroy messiness - * Threadsafety - * Class functions - -The entire code to the object system is in camel/camel-object.c. It's -a naive implementation and not full of features, but intentionally that -way. The main differences between GTK Objects and Camel Objects are: - - * s,gtk,camel,i of course - * Finalize is no longer a GtkObjectClass function. You specify - a finalize function along with an init function when declaring - a type, and it is called automatically and chained automatically. - * Declaring a type is a slightly different API - * The signal system is replaced with a not-so-clever event system. - Every event is equivalent to a NONE__POINTER signal. The syntax - is slightly different: a class "declares" an event and specifies - a name and a "prep func", that is called before the event is - triggered and can cancel it. - * There is only one CamelXXXClass in existence for every type. - All objects share it. - -There is a shell script, tools/make-camel-object.sh that will do all of -the common substitutions to make a file CamelObject-compatible. Usually -all that needs to be done is move the implementation of the finalize -event out of the class init, modify the get_type function, and replace -signals with events. - -Pitfalls in the transition that I ran into were: - - * gtk_object_ref -> camel_object_ref or you coredump - * some files return 'guint' instead of GtkType and must be changed - * Remove the #include <gtk/gtk.h> - * gtk_object_set_datas must be changed (This happened once; I - added a static hashtable) - * signals have to be fudged a bit to match the gpointer input - * the BAST_CASTARD option is on, meaning failed typecasts will - return NULL, almost guaranteeing a segfault -- gets those - bugs fixed double-quick! - -b. API -- mail_operation_spec - -I worked by creating a very specific definition of a "mail operation" -and wrote an engine to queue and dispatch them. - -A mail operation is defined by a structure mail_operation_spec -prototyped in mail-threads.h. It comes in three logical parts -- a -"setup" phase, executed in the main thread; a "do" phase, executed -in the dispatch thread; and a "cleanup" phase, executed in the main -thread. These three phases are guaranteed to be performed in order -and atomically with respect to other mail operations. - -Each of these phases is represented by a function pointer in the -mail_operation_spec structure. The function mail_operation_queue() is -called and passed a pointer to a mail_operation_spec and a user_data-style -pointer that fills in the operation's parameters. The "setup" callback -is called immediately, though that may change. - -Each callback is passed three parameters: a pointer to the user_data, -a pointer to the "operation data", and a pointer to a CamelException. -The "operation data" is allocated automatically and freed when the operation -completes. Internal data that needs to be shared between phases should -be stored here. The size allocated is specified in the mail_operation_spec -structure. - -Because all of the callbacks use Camel calls at some point, the -CamelException is provided as utility. The dispatcher will catch exceptions -and display error dialogs, unlike the synchronous code which lets -exceptions fall through the cracks fairly easily. - -I tried to implement all the operations following this convention. Basically -I used this skeleton code for all the operations, just filling in the -specifics: - -=================================== - -typedef struct operation_name_input_s { - parameters to operation -} operation_name_input_t; - -typedef struct operation_name_data_s { - internal data to operation, if any - (if none, omit the structure and set opdata_size to 0) -} operation_name_data_t; - -static gchar *describe_operation_name (gpointer in_data, gboolean gerund); -static void setup_operation_name (gpointer in_data, gpointer op_data, CamelException *ex); -static void do_operation_name (gpointer in_data, gpointer op_data, CamelException *ex); -static void cleanup_operation_name (gpointer in_data, gpointer op_data, CamelException *ex); - -static gchar *describe_operation_name (gpointer in_data, gboolean gerund) -{ - operation_name_input_t *input = (operation_name_input_t *) in_data; - - if (gerund) { - return a g_strdup'ed string describing what we're doing - } else { - return a g_strdup'ed string describing what we're about to do - } -} - -static void setup_operation_name (gpointer in_data, gpointer op_data, CamelException *ex) -{ - operation_name_input_t *input = (operation_name_input_t *) in_data; - operation_name_data_t *data = (operation_name_data_t *) op_data; - - verify that parameters are valid - - initialize op_data - - reference objects -} - -static void do_operation_name (gpointer in_data, gpointer op_data, CamelException *ex) -{ - operation_name_input_t *input = (operation_name_input_t *) in_data; - operation_name_data_t *data = (operation_name_data_t *) op_data; - - perform camel operations -} - -static void cleanup_operation_name (gpointer in_data, gpointer op_data, CamelException *ex) -{ - operation_name_input_t *input = (operation_name_input_t *) in_data; - operation_name_data_t *data = (operation_name_data_t *) op_data; - - perform UI updates - - free allocations - - dereference objects -} - -static const mail_operation_spec op_operation_name = { - describe_operation_name, - sizeof (operation_name_data_t), - setup_operation_name, - do_operation_name, - cleanup_operation_name -}; - -void -mail_do_operation_name (parameters) -{ - operation_name_input_t *input; - - input = g_new (operation_name_input_t, 1); - - store parameters in input - - mail_operation_queue (&op_operation_name, input, TRUE); -} - -=========================================== - -c. mail-ops.c - -Has been drawn and quartered. It has been split into: - - * mail-callbacks.c: the UI callbacks - * mail-tools.c: useful sequences wrapping common Camel operations - * mail-ops.c: implementations of all the mail_operation_specs - -An important part of mail-ops.c are the global functions -mail_tool_camel_lock_{up,down}. These simulate a recursize mutex around -camel. There are an extreme few, supposedly safe, calls to Camel made in -the main thread. These functions should go around evey call to Camel or -group thereof. I don't think they're necessary but it's nice to know -they're there. - -If you look at mail-tools.c, you'll notice that all the Camel calls are -protected with these functions. Remember that a mail tool is really -just another Camel call, so don't use them in the main thread either. - -All the mail operations are implemented in mail-ops.c EXCEPT: - - * filter-driver.c: the filter_mail operation - * message-list.c: the regenerate_messagelist operation - * message-thread.c: the thread_messages operation - -d. Using the operations - -The mail operations as implemented are very specific to evolution-mail. I -was thinking about leaving them mostly generic and then allowing extra -callbacks to be added to perform the more specific UI touches, but this -seemed kind of pointless. - -I basically looked through the code, found references to Camel, and split -the code into three parts -- the bit before the Camel calls, the bit after, -and the Camel calls. These were mapped onto the template, given a name, -and added to mail-ops.c. Additionally, I simplified the common tasks that -were taken care of in mail-tools.c, making some functions much simpler. - -Ninety-nine percent of the time, whatever operation is being done is being -done in a callback, so all that has to be done is this: - -================== - -void my_callback (GtkObject *obj, gchar *uid) -{ - camel_do_something (uid); -} - -==== becomes ==== - -void my_callback (GtkObject *obj, gchar *uid) -{ - mail_do_do_something (uid); -} - -================= - -There are, however, a few belligerents. Particularly, the function -mail_uri_to_folder returns a CamelFolder and yet should really be -asynchronous. This is called in a CORBA call that is sychronous, and -additionally is used in the filter code. - -I changed the first usage to return the folder immediately but -still fetch the CamelFolder asyncrhonously, and in the second case, -made filtering asynchronous, so the fact that the call is synchronous -doesn't matter. - -The function was renamed to mail_tool_uri_to_folder to emphasize that -it's a synchronous Camel call. - -e. The dispatcher - -mail_operation_queue () takes its parameters and assembles them in a -closure_t structure, which I abbreviate clur. It sets a timeout to -display a progress window if an operation is still running one second -later (we're not smart enough to check if it's the same operation, -but the issue is not a big deal). The other thread and some communication -pipes are created. - -The dispatcher thread sits in a loop reading from a pipe. Every time -the main thread queues an operation, it writes the closure_t into the pipe. -The dispatcher reads the closure, sends a STARTING message to the main -thread (see below for explanation), calls the callback specified in the -closure, and sends a FINISHED message. It then goes back to reading -from its pipe; it will either block until another operation comes along, -or find one right away and start it. This the pipe takes care of queueing -operations. - -The dispatch thread communicates with the main thread with another pipe; -however, the main thread has other things to do than read from the pipe, -so it adds registers a GIOReader that checks for messages in the glib -main loop. In addition to starting and finishing messages, the other -thread can communicate to the user using messages and a progress bar. -(This is currently implemented but unused.) - -5. ISSUES - - * Operations are queued and dequeued stupidly. Like if you click - on one message then click on another, the first will be retrieved - and displayed then overwritten by the second. Operations that could - be performed at the same time safely aren't. - * The CamelObject system is workable, but it'd be nice to work with - something established like the GtkObject - * The whole threading idea is not great. Concensus is that an - asynchronous interface is the Right Thing, eventually. - * Care still needs to be taken when designing evolution-mail code to - work with the asynchronous mail_do_ functions - * Some of the operations are extremely hacky. - * IMAP's timeout to send a NOOP had to be removed because we can't - use GTK. We need an alternative for this.
\ No newline at end of file |