:orphan: # PetscDeviceContextDestroy Frees a `PetscDeviceContext` ## Synopsis ``` #include PetscErrorCode PetscDeviceContextDestroy(PetscDeviceContext *dctx) ``` Not Collective ## Input Parameter - ***dctx -*** The `PetscDeviceContext` ## Notes No implicit synchronization occurs due to this routine, all resources are released completely asynchronously w.r.t. the host. If one needs to guarantee access to the data produced on `dctx`'s stream the user is responsible for calling `PetscDeviceContextSynchronize()` before calling this routine. ## DAG representation ```none time -> -> dctx - |= CALL =| ``` ## Developer Notes `dctx` is never actually "destroyed" in the classical sense. It is returned to an ever growing pool of `PetscDeviceContext`s. There are currently no limits on the size of the pool, this should perhaps be implemented. ## Asynchronous API Notes This routine is explicitly marked as exhibiting asynchronous behavior. Asynchronous behavior implies that routines launching operations on (or associated with) a `PetscDeviceContext` may return to the caller before the operation has completed. Sequential Consistency: Operations using the _same_ `PetscDeviceContext` which access objects or memory regions are ordered per the language specification. Operations using _separate_ `PetscDeviceContext`s which access the _same_ object or memory region are strongly write-ordered. That is, the following operations: - `write-write` - `write-read` - `read-write` are strongly ordered. Formally: _Given an operation `A-B` (e.g. `A` = `write`, `B` = `read`) on an object or memory region `M` such that `A` "happens-before" `B`, where `A` uses `PetscDeviceContext` `X` and `B` uses `PetscDeviceContext` `Y`, then `B` shall not begin before `A` completes. This implies that any side-effects resulting from `A` are also observed by `B`._ Note the omission of `read-read`; there is no implied ordering between separate `PetscDeviceContext`s for consecutive reads. Operations using _separate_ `PetscDeviceContext`s which access _separate_ objects or memory regions may execute in an arbitrary order and offer no guarantee of sequential consistency. Memory Consistency: If this routine modifies the participating object(s) then -- unless otherwise stated -- the contents of any externally held references to internal data structures should be considered to be in an undefined state. A well-defined state can only be restored by re-acquiring these references through the appropriate API or by calling `PetscDeviceContextSynchronize()`. Unless otherwise stated, exceptions to this rule are: - References returned by the routine itself. If a routine returns a pointer, the value of the top-most pointer is guaranteed to always be valid. For example, given a routine which asynchronously allocates memory and returns a pointer to the memory, the value of said pointer is immediately valid but dereferencing the pointer may not be. - References to structures. If a routine returns a `PetscFoo`, or array thereof then the objects themselves are always valid (though their member variables `PetscFoo->data` may not be). ## See Also `PetscDeviceContextCreate()`, `PetscDeviceContextSetDevice()`, `PetscDeviceContextSetUp()`, `PetscDeviceContextSynchronize()` ## Level beginner ## Location src/sys/objects/device/interface/dcontext.cxx --- [Edit on GitLab](https://gitlab.com/petsc/petsc/-/edit/release/src/sys/objects/device/interface/dcontext.cxx) [Index of all Sys routines](index.md) [Table of Contents for all manual pages](/manualpages/index.md) [Index of all manual pages](/manualpages/singleindex.md)