1. Revision History
1.1. Revision 2 - November 26th, 2018
Add §3.7 Footguns? section. Discuss implementation experience in more detail. Add exception inspection and reasoning. Add additional design decision information about customization points.
1.2. Revision 1 - October 7th, 2018
Add wording. Incorporate wording feedback. Eliminate CTAD design. Add a few more words about implementation experience.
1.3. Revision 0
Initial release.
2. Motivation
You’re right that code shouldn’t be using shared_ptr, I was trying to make it work with as little change as possible but after that and other more recent problems I’m finding a huge refactoring less and less avoidable. I’ll make sure to turn everything into unique_ptr (there is no shared ownership anyways).
Your out_ptr will still be massively helpful. — King_DuckZ, September 25th, 2018
Shared Code | |
---|---|
From libavformat
| |
Current Code | With Proposal |
|
|
We have very good tools for handling unique and shared resource semantics, alongside more coming with Intrusive Smart Pointers. Independently between several different companies, studios, and shops -- from VMWare and Microsoft to small game development startups -- a common type has been implemented. It has many names:
,
,
,
, WRL::ComPtrRef, a proposal on std-proposals and even unary operator& on CComPtr. It is universally focused on one task: making it so a smart pointer can be passed as a parameter to a function which uses an output pointer parameter in C API functions (e.g.,
).
This paper is a culmination of a private survey of types from the industry to propose a common, future-proof, high-performance
type that is easy to use. It makes interop with pointer types a little bit simpler and easier for everyone who has ever wanted something like
to behave properly.
In short: it’s a thing convertible to a
that updates the smart pointer it is created with when it goes out of scope.
3. Design Considerations
The core of
's (and
's) design revolves around avoiding the mistakes of the past, preventing continual modification of new smart pointers and outside smart pointers’s interfaces to perform the same task, and enabling some degree of performance efficiency without having to wrap every C API function.
3.1. Synopsis
The function template’s full specification is:
namespace std { template < class Pointer , class Smart , class ... Args > out_ptr_t < Smart , Pointer , Args ... > out_ptr ( Smart & s , Args && ... args ) noexcept ; template < class Smart , class ... Args > out_ptr_t < Smart , POINTER_OF ( Smart ), Args ... > out_ptr ( Smart & s , Args && ... args ) noexcept ; template < class Pointer , class Smart , class ... Args > inout_ptr_t < Smart , Pointer , Args ... > inout_ptr ( Smart & s , Args && ... args ) noexcept ; template < class Smart , class ... Args > inout_ptr_t < Smart , POINTER_OF ( Smart ), Args ... > inout_ptr ( Smart & s , Args && ... args ) noexcept ; }
Where
is the
type, then the
type, then
type in that order. The return type
and its sister type
are templated types and must at-minimum have the following:
template < class Smart , class Pointer , class ... Args > struct out_ptr_t { out_ptr_t ( Smart & , Args ...); ~ out_ptr_t () noexcept ; operator Pointer * () noexcept ; operator void ** () noexcept ; }; template < class Smart , class Pointer , class ... Args > struct inout_ptr_t { inout_ptr_t ( Smart & , Args ...); ~ inout_ptr_t () noexcept ; operator Pointer * () noexcept ; operator void ** () noexcept ; };
We specify "at minimum" because we expect users to override this type for their own shared, unique, handle-alike, reference-counting, and etc. smart pointers. The destructor of
calls
on the stored smart pointer of type
with the stored pointer of type
and arguments stored as
.
does the same, but with the additional caveat that the constructor for
also calls
, so that a
doesn’t double-delete a pointer that the expected re-allocating API used with
already handles.
We chose this extension point because the other options (ADL extension, friend ADL extension) have proven to not be very feasible in the long run of maintainability. While we are wary that users open up namespace
we also recognize that it is essentially the best way that someone can extend this type to pointers and handles that are _not_ part of the standard. If this only works with standard types -- and only standard types that are explicitly sanctioned -- then this type is almost certainly not worth it. See §3.8 Extension Points for more details.
3.2. Overview
/
are free functions meant to be used for C APIs:
error_num c_api_create_handle ( int seed_value , int ** p_handle ); error_num c_api_re_create_handle ( int seed_value , int ** p_handle ); void c_api_delete_handle ( int * handle ); struct resource_deleter { void operator ()( int * handle ) { c_api_delete_handle ( handle ); } };
Given a smart pointer, it can be used like so:
std :: unique_ptr < int , resource_deleter > resource ( nullptr ); error_num err = c_api_create_handle ( 24 , std :: out_ptr ( resource ) ); if ( err == C_API_ERROR_CONDITION ) { // handle errors } // resource.get() the out-value from the C API function
Or, in the re-create (reallocation) case:
std :: unique_ptr < int , resource_deleter > resource ( nullptr ); error_num err = c_api_re_create_handle ( 24 , std :: inout_ptr ( resource ) ); if ( err == C_API_ERROR_CONDITION ) { // handle errors } // resource.get() the out-value from the C API function
3.3. Safety
This implementation uses a pack of
in the signature of
to allow it to be used with other types whose
functions may require more than just the pointer value to form a valid and proper smart pointer. This is the case with
and
:
std :: shared_ptr < int > resource ( nullptr ); error_num err = c_api_create_handle ( 24 , std :: out_ptr ( resource , resource_deleter {}) ); if ( err == C_API_ERROR_CONDITION ) { // handle errors } // resource.get() the out-value from // the C API function
Additional arguments past the smart pointer stored in
's return type will perfectly forward these to whatever
or equivalent implementation requires them. If the underlying pointer does not require such things, it may be ignored or discarded (optionally, with a compiler error using a static assert that the argument will be ignored for the given type of smart pointer).
Of importance here is to note that
can and will overwrite any custom deleter present when called with just
. Therefore, we make it a compiler error to not pass in a second argument when using
without a deleter:
std :: shared_ptr < int > resource ( nullptr ); error_num err = c_api_create_handle ( 42 , std :: out_ptr ( resource ) ); // ERROR: deleter was changed // to an equivalent of // std::default_delete!
It is likely the intent of the programmer to also pass the fictional
function to this: the above constraint allows us to avoid such programmer mistakes.
3.4. Safety: Exceptions
This is two-fold. First, by placing the
call into the destructor of
/
, we can guarantee safety that trivial code does not have. For example, consider this abstracted form of the production code shown in the Tony Table:
std :: unique_ptr < int > num ( new int ()); // use, then have to prepare for some // c_api call int * raw_num = num . release (); if ( my_c_api_call ( & raw_num ) != 0 ) { // leak if the c api call does nothing!! throw std :: runtime_error ( "leaking memory!" ); } num . reset ( raw_num );
If the user used
, the value would be guaranteed to put back into the unique pointer, and then subsequently destroyed as the stack continued to be unwound.
Secondly, the destructor for
calls to
. The only case where this is questionable is with
: the creation of the passed-in deleter might throw, and thusly the call cannot be
. This means that the destructor might throw if
throws: in this case,
would be called.
3.5. Casting Support
There are also many APIs (COM-style APIs, base-class handle APIs, type-erasure APIs) where the initialization requires that the type passed to the function is of some fundamental (
) or base type that does not reflect what is stored exactly in the pointer. Therefore, it is necessary to sometimes specify what the underlying type
uses is stored as.
It is also important to note that going in the opposite direction is also highly desirable, especially in the case of doing API-hiding behind an e.g.
implementation.
supports both scenarios with an optional template argument to the function call.
3.5.1. Casting Support: builtin void **
Consider this DirectX Graphics Infrastructure Interface (DXGI) function on
:
HRESULT EnumAdapterByGpuPreference ( UINT Adapter , DXGI_GPU_PREFERENCE GpuPreference , REFIID riid , void ** ppvAdapter );
Using
, it becomes trivial to interface with it using an exemplary
:
HRESULT result = dxgi_factory . EnumAdapterByGpuPreference ( 0 , DXGI_GPU_PREFERENCE_MINIMUM_POWER , IID_IDXGIAdapter , std :: out_ptr ( adapter ) ); if ( FAILED ( result )) { // handle errors } // adapter.get() contains strongly-typed pointer
No manual casting,
fiddling, or
is required: the returned type from
handles that. This is because the
and
types have conversion operations to not only the detected
or
of the smart pointer, but a
conversion to
as well. While the size of
is not required by the C++ standard to be the same as the size of any other types pointer (except const/volatile qualified
), most C APIs that use this technique have already sanctioned the conversion from whatever type the API works with to
and, subsequently,
.
This idiom is also useful for the
base function for COM’s
, and for Vulkan’s
.
3.5.2. Casting Support: to arbitrary T
In many cases, there is a typical C structure or similar that C++ users are sanctioned to derive and extend with their own data, with the promise that as long as the pointed passed to the function has a base class or matching type. It also happens that someone needs to cast from a type-erased
to a more-derived type. There are also cases where the type stored in
uses
to override the
type, making
store the (fat, offset)
that is convertible to
.
For example, one technique detailed by a graphics develop helped them make an agnostic
type: a type-erased pointer for DirectX or a regular integer for OpenGL. This requires casting from a chunk of type-erased storage to a more concrete
or similar. Allowing for
to work on that level was critical for its usage in these cases.
It is imperative that the user be allowed to specify a casting parameter that the
/
, and that is done by simply adding a type when calling the desired function. Consider a specialized
where
is a typedef to a special
type:
struct fd { int handle ; fd () : fd ( nullptr ) {} fd ( std :: nullptr_t ) : handle ( static_cast < intptr_t > ( - 1 )) {} fd ( FILE * f ) #ifdef _WIN32 : handle ( f ? _fileno ( f ) : static_cast < intptr_t > ( - 1 )){ #else : handle ( f ? fileno ( f ) : static_cast < intptr_t > ( - 1 )) { #endif // Windows } explicit operator bool () const ; bool operator == ( std :: nullptr_t ) const ; bool operator != ( std :: nullptr_t ) const ; bool operator == ( const fd & fd ) const ; bool operator != ( const fd & fd ) const ; }; struct fd_deleter { using pointer = fd ; void operator ()( fd des ) const ; };
Casting in this case is cumbersome and often error-prone to do properly when interfacing with C or C++ standard library facilities. It becomes trivial with
:
std :: unique_ptr < int , fd_deleter > my_unique_fd ; auto err = fopen_s ( std :: out_ptr < FILE *> ( my_unique_fd ), "prod.csv" , "rb" ); // check err, then work with raw fd
This is an example of a codebase which works primarily off of file descriptors, but wants to interop with the standard C and C++ libraries. The cast here is valid and properly opens the file, while the
type handles converting in and out of the type safely and seamlessly, without going through extra effort or having to interact more closely with the POSIX API. This makes it easy to perform interop with a "high-level" or "convertible" type, while still working with the desired "low-level" or "native" type.
This also demonstrates
's ability to work with offset/fat/not-quite-exactly pointers, which are allowed by
and the upcoming std::retain_ptr.
The full example code for Windows and *Nix platforms is available as a compilable example.
3.6. Reallocation Support
In some cases, a function given a valid handle/pointer will delete that pointer on your behalf before performing an allocation in the same pointer. In these cases, just
is entirely redundant and dangerous because it will delete a pointer that it does not own. Therefore, there is a second abstraction called
, so aptly named because it is both an input (to be deleted) and an output (to be allocated post-delete).
's semantics are exactly like
's, just with the additional requirement that it calls
on the smart pointer upon constructing the temporary
.
This can be heavily optimized in the case of
, but to do so from the outside requires Undefined Behavior or modification of the standard library. See §5.2 For std::inout_ptr for further explication.
3.7. Footguns?
As far as we know and have designed this specification,
and
have no hidden or easy-to-access footguns. Originally,
was going to potentially include a runtime parameter to encapsulate the behavior of
: however, it was deemed much better design to separate the two out into separate functions. This also matched VMWare’s implementation experience with the type and generated far superior code. It also made it easier to know when to pick
versus
: one is for regular allocations that just create something new, the other is for the case when you need to reallocate into the pointer and thusly can save some instructions.
Furthermore, all examples of
/
include usage as a temporary to a function call. Let us assume someone wanted to get sufficiently clever:
std :: unique_ptr < int > u_ptr ; auto op = std :: out_ptr ( u_ptr ); int err = c_function_call ( op ); if ( err != 0 ) { throw std :: runtime_error () }
This still behaves the same: but,
will be called before the
goes out of scope. Unless the user performs extraordinary gymnastics to circumvent the typical lifetime of the factory-generated
, there are no footguns in regular and general usage.
3.8. Extension Points
A number of extension points were considered for this proposal. We have purposefully selected the ability to specialize the class template because it is the most flexible approach that allows library authors outside of the
namespace customize their types to work properly. This proposal rose primarily out of seeing many _different_ kinds of smart pointers handled in many codebases, from hobby to industry, that are currently not covered (and likely not to be covered in the near future) by the standard. Therefore, an extension mechanism that is available to library authors and users seems to be the most efficient.
It is also important that we limit the surface area in which the user can harm themselves and their users. ADL, for example, can cause supreme danger because the overloads of
and
are variadic forwarding templates which handle when a user might want to pass additional arguments to
or similar. This can be quite dangerous as it is ripe territory for ambiguities.
Class template specialization requires exactly matching arguments and does not suffer from potential convertibility in which other solutions might pick wrong overloads or select the wrong extension call because of mixed-namespace arguments. It also prevents build breaks from being introduced in subtle and hard-to-catch ways. It is also much less likely for someone to try to apply
or Concept constraints on their template class specializations to resolve ambiguities because of the exact-matching feature, as opposed to functions where partial and full specialization are hazardous and error-prone to get right.
Below are catalogued some explored and ultimately rejected customization points.
3.8.1. Rejected: just adding get_ref
to related non-shared pointers
This solution seeks to resolve performance problems and reseating issues by having
add a
function on itself that an
solution or C function user might take advantage of. The problem is this breaks encapsulation over its knee and destroys and integrity the pointer value has from
's invariant. Additionally, it means that all libraries have to provide a function on their types that they currently do not provide (and for very good reason). While tempting as low-hanging fruit, this is an extraordinary example of a simple design which has far-reaching, poor consequences.
3.8.2. Rejected: adding & operator
to this type
This is the same sin committed by Microsoft with
that ushered in the age of
with all due experience for Windows users. While proposed a few times throughout history (including in the early incubation tank of std-proposals), this is not a mistake the community should make twice.
3.8.3. Rejected: unrestricted ADL
works out fairly nicely as an extension point. Coming up with a fairly expansive name that is not as common as
and designating that to be the ADL extension point could be worth doing. Also creating callable Customization Point Objects that
before calling
in an unqualified manner is similar to the design decision ranges made.
Unfortunately, ADL is also entirely unconstrained once opened up in this manner. It takes careful programming and perhaps a bit of SFINAE to ensure there are no collisions, especially in the "base cases" users might want to specialize for. This can lead to brittle code that breaks when we ship updates to the desired ADL extension point, or users that under or over-constrain their version of the function. It exposes too much surface area for the programmer to load not a footgun but a landmine that either their future selves, coworkers, or left-behind future colleagues might get lost on.
It is a considerable contender but for the above reasons -- especially since
/
need to have unconstrained variadic arguments to pass additional extra arguments to pointers like
/
or
or the upcoming
-- it is rejected.
3.8.4. Rejected: restricted ADL using in-class friend functions
At first, this idea is tempting. It is used in abseil to e.g. provide hash customization and allows the implementer to access the internals of the pointer they are adding it to. Having a
function seems to cover the biggest risks (asides from template footguns in the previous section). In a world where building from source and owning your dependencies is ideal, or being able to freeze versions at will and edit code that you know is abandon-ware, this seems like the ideal solution that covers most use cases. It also seems to prevent the more naughty use cases of ADL.
Unfortunately, this requires opt-in from every author of a library type. This means that either you fork the library to your own version and patch it, maintain a patch in the case of an author who does not deem you adding that extension point useful, or just own the library and stay up to date. While feasible for large teams that have bandwidth to spend on this problem, this is problematic for smaller teams and hobby developers. It is a good way to do extension, but it is a novel idea and only tested within a few libraries. There are also issues of legality when performing modification to headers and compiled code directly to support this idiom:
as currently designed does not fall prey to such problems.
Already, users have sent me tweets and e-mails about extending this for their own types that they do not own. It would defeat the purpose of this type to require explicit opt-in.
4. Implementation Experience
This library has been brewed at many companies in their private implementations, and implementations in the wild are scattered throughout code bases with no unifying type. As noted in §2 Motivation, Microsoft has implemented this in
. Its earlier iteration --
-- simply overrode
. We assume they prefer the former after having forced the need with
for
. the WRL is a public library used in thousands of applications, and has an interface similar to the proposed
/
.
VMWare has a type that much more closely matches the specification in this paper, titled
. The primary author of this paper wrote and used
for over 5 years in their code base working primarily with graphics APIs such as DirectX and OpenGL, and more recently Vulkan. They have also seen a similar abstraction in the places they have interned at.
Similarly, Adobe’s Chromium project has its own version of out_ptr.
The primary author of [p0468] in pre-r0 days also implemented an overloaded
to handle interfacing with C APIs, but was quickly talked out of actually proposing it when doing the proposal. That author has joined in on this paper to continue to voice the need to make it easier to work with C APIs without having to wrap the function.
Given that many companies, studios and individuals have all invented the same type independently of one another, we believe this is a strong indicator of agreement on an existing practice that should see a proposal to the standard.
A full implementation with UB and friendly optimizations is available in the repository. The type has been privately used in many projects over the last four years, and this public implementation is already seeing use at companies today. It has been particularly helpful with many COM APIs, and the re-allocation support in
has been useful for FFMPEG’s functions which feature reallocation support in their functions (e.g.,
).
4.1. Why Not Wrap It?
A common point raised while using this abstraction is to simply "wrap the target function". We believe this to be a non-starter in many cases: there are thousands of C API functions and even the most dedicated of tools have trouble producing lean wrappers around them. This tends to work for one-off functions, but suffers scalability problems very quickly.
Templated intermediate wrapper functions which take a function, perfectly forwards arguments, and attempts to generate e.g. a
for the first argument and contain the boiler plate within itself also causes problems. Asides from the (perhaps minor) concern that such a wrapping function disrupts any auto-completion or tooling, the issue arises that C libraries -- even within themselves -- do not agree on where to place the
parameter and detecting it properly to write a generic function to automagically do it is hard. Even within the C standard library, some functions have output parameters in the beginning and others have it at the end. The disparity grows when users pick up libraries outside the standard.
5. Performance
Many C programmers in our various engineering shops and companies have taken note that manually re-initializing a
when internally the pointer value is already present has a measurable performance impact.
Teams eager to squeeze out performance realize they can only do this by relying on type-punning shenanigans to extract the actual value out of
: this is expressly undefined behavior. However, if an implementation of
could be friended or shipped by the standard library, it can be implemented without performance penalty.
Below are some graphs indicating the performance metrics of the code. 5 categories were measured:
-
"c_code": handwritten C code, which does not use this idiom
-
"clever": uses UB to alias the pointer value stored in
std :: unique_ptr -
"friendly": modifies VC++'s, libc++'s, and libstdc++'s
s to allow the implementation to friend thestd :: unique_ptr
implementation, to access the internals without UBout_ptr -
"manual": does the work by-hand using reset/release from a
std :: unique_ptr -
"simple": a
implementation that naively resetsout_ptr
The full JSON data for these benchmarks is available in the repository, as well as all of the code necessary to run the benchmarks across all platforms with a simple CMake build system.
5.1. For std :: out_ptr
You can observe two graphs for two common
usage scenarios, which are using the pointer locally and discarding it ("local"), and resetting a pre-existing pointer ("reset") for just an output pointer:
5.2. For std :: inout_ptr
The speed increase here is even more dramatic: reseating the pointer through
and
is much more expensive than simply aliasing a
directly. Places such as VMWare have to perform Undefined Behavior to get this level of performance with
: it would be much more prudent to allow both standard library vendors and users to be able to achieve this performance without hacks, tricks, and other I-promise-it-works-I-swear pledges.
6. Bikeshed
As with every proposal, naming, conventions and other tidbits not related to implementation are important. This section is for pinning down all the little details to make it suitable for the standard.
6.1. Alternative Specification
The authors of this proposal know of two ways to specify this proposal’s goals.
The authors have settled on the approach in §3.1 Synopsis. We believe this is the most robust and easiest to use: singular names tend to be easier to teach and use for both programmers and tools. We discuss the older techniques to uphold thorough discussion and inspection of the solution space.
The first way is to specify both functions
and
as factories, and then have their types named differently, such as
and
. The factory functions and their implementation will be fixed in place, and users would be able to (partially) specialize and customize
and
for types external to the stdlib for maximum performance tweaking and interop with types like
,
, and others. This is the direction this proposal takes.
The second way is to specify the class names to be
/
, and then used Template Argument Deduction for Class Templates from C++17 to give a function-like appearance to their usage. Users can still specialize for types external to the standard library. This approach is more Modern C++-like, but contains a caveat.
Part of this specification is that you can specify the stored pointer for the underlying implementation of
as shown in §3.5 Casting Support. Template Argument Deduction for Class Templates does not allow partial specialization (and for good reason, see the interesting example of
). The "Deduction Guides" (or CTAD) approach would accommodate §3.5 Casting Support using functions with a more explicit names, such as
and
.
6.2. Naming
Naming is hard, and therefore we provide a few names to duke it out in the Bikeshed Arena:
For the
part:
-
out_ptr
-
c_ptr
-
c_out_ptr
-
out_c_ptr
-
alloc_c_ptr
-
out_smart
-
ptrptr
-
ptr_to_ptr
-
ptr_to_smart
-
ptr_ref
For the
part:
-
inout_ptr
-
c_in_ptr
-
c_inout_ptr
-
inout_c_ptr
-
realloc_c_ptr
-
inout_smart,
-
realloc_ptr_to_ptr
-
realloc_ptr_to_smart
-
realloc_ptr_ref
As a pairing,
and
are the most cromulent and descriptive in the authors' opinions. The type names would follow suit as
and
. However, there is an argument for having a name that more appropriately captures the purpose of these abstractions. Therefore,
and
would be even better, and the shortest would be
and
.
7. Proposed Changes
The following wording is for the Library section, relative to [n4762]. This feature will go in the
header, and is added to §19.11 [utilities.smartptr], at the end as subsection 9.
7.1. Proposed Feature Test Macro and Header
This should be available with the rest of the smart pointers, and thusly be included by simply including
. If there is a desire for more fine-grained control, then we recommend the header
(subject to change based on bikeshed painting above). There has been some expressed desire for wanting to provide more fine-grained control of what entities the standard library produces when including headers: this paper does not explicitly propose adding such headers or doing such work, merely making a recommendation if this direction is desired by WG21.
The proposed feature test macro for this is
. The exposure of
denotes the existence of both
and
, as well as its customization points
and
.
7.2. Intent
The intent of this wording is to allow implementers the freedom to implement the return type from
as they so choose, so long as the following criteria is met:
-
the return type is of the name
/inout_ptr_t
and is a template with 3 template parameters;out_ptr_t -
the destructor of
/inout_ptr_t
properly re-seats the pointer owned/stored by whatever smart/fancy pointer is passed as the first argument toout_ptr_t
;out_ptr -
the proper implicit conversion operators are added to the type,
-
the standard library implementation itself does not specialize
/inout_ptr_t
's templates, either fully or partially, so that the user can override the behavior of these templates as they so choose;out_ptr_t -
used with thestd :: shared_ptr
orout_ptr
functions will produce a diagnostic if it is called without a second argument meant to be passed as the deleter to ainout_ptr
call; and. reset () -
used withstd :: shared_ptr
will always result in a diagnostic because it is impossible to completely release the resource from its shared ownership.inout_ptr_t
The goals of the wording are to not restrict implementation strategies (e.g., a
implementation as benchmarked above for
, or maybe a UB/IB implementation as also documented above). It is also explicitly meant to error for smart pointers whose
call may reset the stored deleter (á la
/
) and to catch programmer errors.
7.3. Proposed Wording
Append to §16.3.1 General [support.limits.general]'s Table 35 one additional entry:
Macro name Value __cpp_lib_out_ptr 201811L
Modify §19.10.1 In general [memory.general] as follows:
1 The header
defines several types and function templates that describe properties of pointers and pointer-like types, manage memory for containers and other template types, destroy objects, and construct multiple objects in uninitialized memory buffers (19.10.3–19.10.11). The header also defines the templates unique_ptr, shared_ptr, weak_ptr, out_ptr_t, inout_ptr_t, and various function templates that operate on objects of these types (19.11). Add §19.10.2 Definitions [memory.defns] as follows:
1 Definition: Let
denote a type that is:
POINTER_OF_OR ( T , U )
- —
if the qualified-id
T :: pointer is valid and denotes a type, or
T :: pointer - — otherwise,
if the qualified-id
typename T :: element_type * is valid and denotes a type, or
T :: element_type - — otherwise,
.
U 2 Definition: Let
denote a type that is defined as
POINTER_OF ( T )
POINTER_OF_OR ( T , typename std :: pointer_traits < T >:: element_type * )
Add to §19.10.3 (previously §19.10.2) Header
synopsis [memory.syn] the
,
,
and
functions and types:
// 19.11.9, out_ptr_t template < class Smart , class Pointer , class ... Args > struct out_ptr_t ; // 19.11.10, out_ptr template < class Pointer , class Smart , class ... Args > out_ptr_t < Smart , Pointer , Args ... > out_ptr ( Smart & s , Args && ... args ) noexcept ; template < class Smart , class ... Args > out_ptr_t < Smart , POINTER_OF ( Smart ), Args ... > out_ptr ( Smart & s , Args && ... args ) noexcept ; // 19.11.11, inout_ptr_t template < class Smart , class Pointer , class ... Args > struct inout_ptr_t ; // 19.11.12, inout_ptr template < class Pointer , class Smart , class ... Args > inout_ptr_t < Smart , Pointer , Args ... > inout_ptr ( Smart & s , Args && ... args ) noexcept ; template < class Smart , class ... Args > inout_ptr_t < Smart , POINTER_OF ( SMART ), Args ... > inout_ptr ( Smart & s , Args && ... args ) noexcept
Insert §19.11.9 [out_ptr.class]:
19.11.9 Class Template[out_ptr.class]
out_ptr_t 1 out_ptr_t is a type used with smart pointers (19.11) and types which are designed on the same principles to interoperate easily with functions that use output pointer parameters. [ Note — For example, a function of the form
— end note ].
void foo ( void ** ) 2 out_ptr_t may be specialized (12.6.5) for program-defined types and shall meet the observable behavior in the rest of this section.
namespace std { template < class Smart , class Pointer , class ... Args > struct out_ptr_t { // 19.11.9.1, constructors out_ptr_t ( Smart & , Args ...) noexcept ; out_ptr_t ( out_ptr_t && ) noexcept ; // 19.11.9.2, assignment out_ptr_t & operator = ( out_ptr_t && ) noexcept ; // 19.11.9.3, destructors ~ out_ptr_t (); // 19.11.9.4, conversion operators operator Pointer * () noexcept ; operator void ** () noexcept ; private : Smart * s ; // exposition only tuple < Args ... > a ; // exposition only Pointer p ; // exposition only }; } 2 If
is a specialization of
Smart and
shared_ptr , the program is ill-formed.
sizeof ...( Args ) == 0 shall meet the
Pointer requirements ((15.5.3.3 [nullablepointer.requirements])).
Cpp17NullablePointer 3 [ Note: It is typically a user error to reset a
without specifying a deleter, as
shared_ptr will replace a custom deleter with the default deleter upon usage of
std :: shared_ptr , as specified in 19.11.3.4. — end note ]
. reset () 19.11.9.1 Constructors [out_ptr.class.ctor]
out_ptr_t ( Smart & smart , Args && ... args ) noexcept ; 1 Effects: initializes
with
s ,
addressof ( smart ) with
a , and initializes
std :: forward < Args > ( args )... to an unspecified value of either
p or its value initialization.
smart . get () 2 [ Note: This allows an implementation and subsequent specializations to use values meaningful to the smart pointer and implementation. The program may not be able to depend on or observe the value of
through the conversion operator defined below. — end note ].
p
out_ptr_t ( out_ptr && rhs ) noexcept ; 2 Effects: initializes
with
s ,
std :: move ( rhs . s ) with
a , and
std :: move ( args )... with
p . Then sets
std :: move ( rhs . p ) to
rhs . p .
nullptr 19.11.9.2 Assignment [out_ptr.class.assign]
out_ptr_t & operator = ( out_ptr && rhs ) noexcept ; 1Effects: Equivalent to:
s = std :: move ( rhs . s ); a = std :: move ( rhs . a ); p = std :: move ( rhs . p ); rhs . p = nullptr ; return * this ; 19.11.9.3 Destructors [out_ptr.class.dtor]
~ out_ptr_t (); 1 Let
be
SP (19.10.2).
POINTER_OF_OR ( Smart , Pointer ) 2 Effects: Equivalent to:
where
- —
if
if ( p != nullptr ) { s -> reset ( static_cast < SP > ( p ), std :: forward < Args > ( args )... ); } is a valid member function on
reset ,
Smart - — otherwise
;
if ( p != nullptr ) { s = Smart ( static_cast < SP > ( p ), std :: forward < Args > ( args )... ); } are the arguments stored in
Args .
a 19.11.9.4 Conversions [out_ptr.class.conv]
operator Pointer * () noexcept ; operator void ** () noexcept ; 1 Constraints: The second conversion shall participate in conversion if
is not
Pointer .
void * 2 Effects: The first conversion returns a pointer to
. The second conversion return
p
reinterpret_cast < void **> ( static_cast < Pointer *> ( * this ));
Insert §19.11.10 [out_ptr]:
19.11.10 Function Template
[out_ptr]
out_ptr 1 out_ptr is a function template that produces an object of type out_ptr_t (19.11.9).
namespace std { template < class Pointer , class Smart , class ... Args > out_ptr_t < Smart , Pointer , Args ... > out_ptr ( Smart & s , Args && ... args ) noexcept ; template < class Smart , class ... Args > out_ptr_t < Smart , POINTER_OF ( Smart ), Args ... > out_ptr ( Smart & s , Args && ... args ) noexcept ; } 2 Effects: The first overload is Equivalent to:
return out_ptr < POINTER_OF ( Smart ) > ( s , std :: forward < Args > ( args )...); 3 Effects: The second overload is Equivalent to:
return out_ptr_t < Smart , Pointer , Args ... > ( s , std :: forward < Args > ( args )...);
Insert §19.11.11 [inout_ptr.class]:
19.11.11 Class Template[inout_ptr.class]
inout_ptr_t 1 inout_ptr_t is a type used with smart pointers (19.11) and types which are designed on the same principles to interoperate easily with functions that use output pointer parameters. [ Note: For example, a function of the form
— end note ].
void foo_realloc ( void ** ) 2 inout_ptr_t may be specialized (12.6.5) for program-defined types and shall meet the observable behavior in the rest of this section.
namespace std { template < class Smart , class Pointer , class ... Args > struct inout_ptr_t { // 19.11.11.1, constructors inout_ptr_t ( Smart & , Args ...) noexcept ; inout_ptr_t ( inout_ptr_t && ) noexcept ; // 19.11.11.2, assignment inout_ptr_t & operator = ( inout_ptr_t && ) noexcept ; // 19.11.11.3, destructors ~ inout_ptr_t (); // 19.11.11.4, conversion operators operator Pointer * () noexcept ; operator void ** () noexcept ; private : Smart * s ; // exposition only tuple < Args ... > a ; // exposition only Pointer p ; // exposition only }; } 2 If
is a specialization of
Smart and
shared_ptr , the program is ill-formed.
sizeof ...( Args ) == 0 shall meet the
Pointer requirements (15.5.3.3 [nullablepointer.requirements]).
Cpp17NullablePointer 3 [ Note: It is typically a user error to reset a
without specifying a deleter, as
shared_ptr will replace a custom deleter with the default deleter upon usage of
std :: shared_ptr , as specified in 19.11.3.4. — end note ]
. reset (...) 19.11.11.1 Constructors [inout_ptr.class.ctor]
inout_ptr_t ( Smart & smart , Args ... args ) noexcept ; 1 Effects: initializes
with
s ,
addressof ( smart ) with
a , and
std :: forward < Args > ( args )... to an unspecified value of either
p or
smart . get () .
smart . release () 2 [ Note: This allows an implementation and subsequent specializations pick an option which fits their type and implementation strategy. — end note ].
3 Remarks: if an implementation calls
, then it shall not call
smart . release () in the destructor.
s -> release ()
inout_ptr_t ( inout_ptr && rhs ) noexcept ; 4 Effects: initializes
with
s ,
std :: move ( rhs . s ) with
a , and
std :: move ( args )... with
p . Then sets
std :: move ( rhs . p ) to
rhs . p .
nullptr 19.11.11.2 Assignment [inout_ptr.class.assign]
inout_ptr_t & operator = ( inout_ptr && rhs ) noexcept ; 1 Effects: Equivalent to:
s = std :: move ( rhs . s ); a = std :: move ( rhs . a ); p = std :: move ( rhs . p ); rhs . p = nullptr ; return * this ; 19.11.11.3 Destructors [inout_ptr.class.dtor]
~ inout_ptr_t (); 1 Constraints: The expression
is well-formed.
smart . release () 2 Let
be
SP (19.10.2).
POINTER_OF_OR ( Smart , Pointer ) 3 Effects: Equivalent to:
- —
if the expression
s -> release (); if ( p != nullptr ) { s -> reset ( static_cast < SP > ( p ), std :: forward < Args > ( args )... ); } is well-formed,
s . reset (...) - — otherwise,
;
s -> release (); if ( p != nullptr ) { s = Smart ( static_cast < SP > ( p ), std :: forward < Args > ( args )... ); } 4 Remarks: if an implementation calls
or
s -> release () in the constructor, then it shall not call
smart . release () in the destructor.
s -> release () 19.11.11.4 Conversions [inout_ptr.class.conv]
operator Pointer * () noexcept ; operator void ** () noexcept ; 1 Constraints: The second conversion shall participate in conversion if
is not
Pointer .
void * 2 Effects: The first conversion returns a pointer to
. The second conversion returns
p
reinterpret_cast < void **> ( static_cast < Pointer *> ( * this ));
Insert §19.11.12 [inout_ptr]:
19.11.12 Function Template
[inout_ptr]
inout_ptr 1 inout_ptr is a function template that produces an object of type inout_ptr_t (19.11.11).
namespace std { template < class Pointer , class Smart , class ... Args > inout_ptr_t < Smart , Pointer , Args ... > inout_ptr ( Smart & s , Args && ... args ) noexcept template < class Smart , class ... Args > inout_ptr < Smart , POINTER_OF ( Smart ), Args ... > inout_ptr ( Smart & s , Args && ... args ) noexcept ; } 2 Effects: The first overload is Equivalent to:
return inout_ptr_t < Smart , Pointer , Args ... > ( s , std :: forward < Args > ( args )...); 3 Effects: The second overload is Equivalent to:
return inout_ptr < POINTER_OF ( Smart ) > ( s , std :: forward < Args > ( args )...);
8. Acknowledgements
Thank you to Lounge<C++>'s Cicada, melak47, rmf, and Puppy for reporting their initial experiences with such an abstraction nearly 5 years ago and helping JeanHeyd Meneide implement the first version of this.
Thank you to Mark Zeren for help in this investigation and analysis of the performance of smart pointers.
Thank you to Tim Song for reviewing the wording for this paper and vastly improving it.