On 08/19/2011 01:50 AM, Jonathan M Davis wrote:
On Thursday, August 18, 2011 16:00 Timon Gehr wrote:
On 08/19/2011 12:35 AM, Jonathan M Davis wrote:
On Thursday, August 18, 2011 14:33 jdrewsen wrote:
Den 17-08-2011 18:21, Timon Gehr skrev:
On 08/17/2011 05:58 PM, Jonathan M Davis wrote:
On Wednesday, August 17, 2011 11:30:06 Steven Schveighoffer wrote:
On Wed, 17 Aug 2011 11:05:56 -0400, jdrewsen<jdrew...@nospam.com>
wrote:
Den 17-08-2011 15:51, Steven Schveighoffer skrev:
On Wed, 17 Aug 2011 05:43:00 -0400, Jonas Drewsen
<jdrew...@nospam.com>
wrote:
On 17/08/11 00.21, Jonathan M Davis wrote:
On Tuesday, August 16, 2011 12:32 Martin Nowak wrote:
On Tue, 16 Aug 2011 20:48:51 +0200,
jdrewsen<jdrew...@nospam.com>
wrote:
Den 16-08-2011 18:55, Martin Nowak skrev:
On Tue, 16 Aug 2011 15:13:40 +0200,
dsimcha<dsim...@yahoo.com>
wrote:
On 8/16/2011 7:48 AM, Jonas Drewsen wrote:
Hi all,
This is a review request for the curl wrapper. Please
read the
"known
issues" in the top of the source file and if possible
suggest a
solution.
We also need somebody for running the review process.
Anyone?
Code:
https://github.com/jcd/phobos/blob/curl-wrapper/etc/curl
.d
Docs:
http://freeze.steamwinter.com/D/web/phobos/etc_curl.html
Demolish!
/Jonas
From a quick look, this looks very well thought out. I'll
review
it
more thoroughly when I have more time. A few
questions/comments
from a
quick look at the docs:
Does the async stuff use D threads, or does Curl have its
own
async
API?
In your examples for postData, you have onReceive a
ubyte[] and
write
it out to console. Did you mean to cast this to some kind
of
string?
For onReceive, what's the purpose of the return value?
If/when this module makes it into Phobos, are we going to
start
including a libcurl binary with DMD distributions so that
std.curl
feels truly **standard** and requires zero extra
configuration?
I was also wondering about the async handling. In the
long-term
I'd like
to see a bigger picture for async handling in phobos
(offering
some kind
of futures, maybe event-loops etc.).
Though this is not a requirement for the curl wrapper now.
std.parallelism also has some kind of this stuff and file
reading
would
benefit from it too.
This has been discussed before and I also think this is very
important.
But before that I think some kind of package management should
be
prioritized (A DIP11 implementaion or a more traditional
solution).
One thing I spotted at a quick glance, sending to be filled
buffers to
another thread should not be done by casting to shared not
immutable.
I'm not entirely sure what you mean. There is no use of shared
buffers
in the wrapper. I do cast the buffer between mutable/immutable
because
only immutable or by value data can be passed using
std.concurrency.
Since the buffers are only used by the thread that currently
has the
buffer this is safe. I've previously asked for a non-cast
solution
(ie.
some kind of move between threads semantic for
std.concurrency) but
was
advised that this was the way to do it.
martin
Pardon the typo. What I meant is that AFAIK casting from
immutable to
mutable has undefined behavior.
The intended method for sending a uint[] buffer to another
thread is
to
cast that
buffer to shared (cast(shared(uint[])) and casting away the
shared
on the
receiving side.
It is allowed to send shared data using std.concurrency.
Casting away immutability and then altering data is undefined.
Actually
casting it away is defined. So, if you have data in one thread
that
you know
is unique, you can cast it to immutable (or
std.exception.assumeUnique to do
it) and then send it to another thread. On that thread, you can
then
cast it
to mutable and alter it.
However, you're circumventing the type system when you do this.
So,
you have
to be very careful. You're throwing away the guarantees that the
compiler
makes with regards to const and immutable. It _is_ guaranteed to
work
though.
And I'm not sure that there's really any difference between
casting
to shared
and back and casting to immutable and back. In both cases, you're
circumventing the type system. The main difference would be that
if
you
screwed up with immutable and cast away immutable on something
that
really was
immutable rather than something that you cast to immutable just
to send it to
another thread, then you could a segfault when you tried to alter
it,
since it
could be in ROM.
- Jonathan M Davis
Yeah I know you have to be careful when doing these kind of
things. I
ran into the problem of sending buffers between threads (using
std.concurrency) so that they could be reused. There isn't any
"move ownership" support in place so Andrei suggested I could do
it by casting immutable.
If anyone knows of a cleaner way to do this please tell.
casting to shared and back. Passing shared data should be supported
by std.concurrency, and casting away shared is defined as long as
you know
only one thread owns the data after casting.
-Steve
Why is this cleaner than casting to immutable and back?
Once it's immutable, it can never be mutable again. Casting to
immutable is a one-way street. Yes, you can cast to mutable, but you
still can't change the data unless you want undefined behavior.
Shared is not like that, an item can be thread-local, then shared,
then thread local again, all the time being mutable. It also
reflects better what the process is (I'm sharing this data with
another thread, then that
thread is taking ownership). There's still the possibility to screw
up, but at least you are not in undefined territory in the
correctly-implemented case.
Are you sure? As I understand it, there's no real difference between
casting to
immutable and back and casting to shared and back. Both circumvent the
type
system. In the one case, the type system guarantees that the data
can't be
altered, and you're breaking that guarantee, because you know that it
_can_
be, since you created the data and know that it's actually mutable.
No. As soon as the data is typed as immutable anywhere it cannot be
changed anymore. You only break guarantees if you actually try to
change the data (otherwise std.typecons.assumeUnique would perform its
job outside defined behavior btw)
I'm thinking down the same lines as Jonathan. Is the behavior for
immutable casts that you describe specified in the language reference
somewhere?
I have no problem with using shared casts instead of immutable - I just
want make sure it is really needed.
The behavior of casting a way const or immutable on a value and then
mutating it is undefined by the language, because you're breaking the
language's guarantees and what happens depends entirely on whether the
actual object was actually immutable. However, in the case of casting to
immutable and then casting back, you _know_ that the object is mutable,
so there's no problem. You're just circumventing the type system which
throws away the guarantees that it gives you about immutability, which
could screw up optimizations if you had actually did more than just pass
the variable around. But that's just not happening here.
As for casting to and from shared and mutating the object, I don't see
how it is any more defined than casting to and from immutable and then
mutating the object is. In both cases, you circumvented the type system,
which breaks the compiler's guarantees and risks bugs if you actually do
more than just pass the variable around before casting it back to being
thread-local and mutable.
- Jonathan M Davis
As long as the data is not being shared between multiple threads after
it's sharedness has been cast away, you are well in defined area,
because you are NOT breaking anything.
The _only_ reason that you're not breaking anything is because you are being
careful and making sure that the data is not actually shared between threads.
You're _still_ circumventing the type system and breaking the guarantee that a
non-shared variable is not shared between threads. _You_ are the one
guaranteeing that the variable is only on one thread, not the compiler. And
when you cast away immutable, _you_ are the one guaranteeing that immutable
data is not being mutated, not the compiler. And in this case, you can make
that guarantee in exactly the same way that you can guarantee that the
variable which was cast to shared and back to be passed across threads isn't
actually shared between threads once it has been passed.
The crucial difference between immutable and shared is, that something
that is immutable will always be immutable, but being shared or not may
change dynamically.
Casting to immutable is a one-way-street, while casting to shared is not.
Casting to immutable does not make the data magically immutable.
Yes it does. That is quite exactly the definition of it.
It makes it
so that the compiler treats it as immutable.
The compiler is irrelevant, the fact that one compiler generates
assembly that behaves as you'd like it to behave does not mean the code
is valid.
Casting from immutable makes it
so that the compiler treats it as mutable. It does not alter whether the data
is actually immutable.
'Actually immutable' means that the variable is never changed. The
language spec says that if an immutable variable is not 'actually
immutable', your program is in error, even if immutability has been
explicitly cast away.
Casting away immutable and altering data is undefined,
because it depends entirely on whether the data is actually immutable or not.
Just to make sure we agree on that: knowing why it is undefined does not
imply there are cases where it is actually defined.
If it isn't, and you don't have any other references to the data (or none of
the other references are immutable), then you don't break _anything_ by
mutating the variable after having cast away immutable.
If you believe the spec, you do break validity of your code even if the
variable is not visible from another place after the cast. There is
currently afaik no reason why such code would *have* to be broken, but
that is what the spec says, because it categorically bans changing
variables that were cast from immutable.
With both shared and immutable, casting it away is circumnventing the type
system. In both cases, _you_ must make sure that you code in a way which does
not violate the guarantees that the compiler normally makes about those types.
If you do violate those guarantees (e.g. by sharing non-shared data across
threads or by mutating data which really was immutable), then you have a bug,
and what happens is dependent on the compiler implementation and on your code.
Agreed, and this means what happens is undefined and such code is invalid.
But if you don't violate those guarantees, then your program is fine. It's the
same for both shared and immutable. It's just that the bugs that you're likely
to get when you violate those guarantees are likely to be quite different.
- Jonathan M Davis
Yes, I agree. And in this specific case you do violate the language
guarantees about immutable variables when you change the variable after
casting it back to mutable. Even if it was typed mutable sometime
before, and even if it is the sole reference in the whole program.
Therefore the behavior of the current implementation is undefined under
the current spec, and changing the transfer protocol to use shared
instead of immutable would fix this. (while generating near-identical
assembly output with the current DMD)
