CAF_ABI.md

OpenCoarrays Application Binary Interface (ABI)

Download this file as a PDF document here.

• To Do
• Implementation status
• Definitions and types
• Provided functions

This document describes the OpenCoarrays application binary interface (ABI) through which a compiler accesses coarray functionality. As such, the target audience for this document is compiler developers. Most application developers need only write standard-conforming Fortran 2008 or 2018 and compile their code with the OpenCoarrays caf compiler wrapper without knowledge of the ABI.

The actual function names in this document have a PREFIX in the source code to avoid name clashes. The prefix can be vendor-specific.

Warning

This document may be out of date.

To Do

• Discuss the current draft
• Add missing functions of the current gfortran implementation
• Address the TODO items
• Extend the functions to match a sensible set
• Update the implementation status, especially for the ARMCI library

Implementation status

The library implementation in this directory should be ABI-compatible with the wording below, except for some int errmsg_len vs. size_t changes that have not yet been implemented.

Definitions and types

2.1 caf_token_t

Typedef of type void * on the compiler side. Can be any data type on the library side.

2.2 caf_register_t

Type indicating which kind of coarray variable should be registered.

typedef enum caf_register_t {
  CAF_REGTYPE_COARRAY_STATIC,
  CAF_REGTYPE_COARRAY_ALLOC,
  CAF_REGTYPE_LOCK_STATIC,
  CAF_REGTYPE_LOCK_ALLOC,
  CAF_REGTYPE_CRITICAL,
  CAF_REGTYPE_EVENT_STATIC,
  CAF_REGTYPE_EVENT_ALLOC
  }
caf_register_t;

TODO: Check whether this set is complete and makes sense

2.3 caf_token_t

In terms of the processor, an opaque pointer, which is used to identify a coarray. The exact content is implementation-defined by the library.

2.4 Stat values

#define STAT_UNLOCKED           0
#define STAT_LOCKED             1
#define STAT_LOCKED_OTHER_IMAGE 2
#define STAT_STOPPED_IMAGE      6000

TODO: Define more, allow room for lib-specific values, update for TS18508. Do we need to take care of special vendor choices?

Note: Some values have to be such that they differ from certain other values.

Provided functions

3.1 Initialization function

void caf_init (int *argc, char ***argv)

This function shall be called at startup of the program before the Fortran main program. It takes as arguments the command-line arguments of the program. It is permitted to pass to NULL pointers as argument; if non-NULL, the library is permitted to modify the arguments.

Argument	intent	description
argc	inout	An integer pointer with the number of arguments passed to the program or NULL.
argv	inout	A pointer to an array of strings with the command-line arguments or NULL.

Note: The function is modeled after the initialization function of the Message Passing Interface (MPI) specification. Due to the way coarray registration (3.5) works, it might not be the first call to the libaray. If the main program is not written in Fortran and only a library uses coarrays, it can happen that this function is never called. Therefore, it is recommended that the library does not rely on the passed arguments and whether the call has been done.

GCC: In gfortran, the function is generated when the Fortran main program is compiled with -fcoarray=lib; the call happens before the run-time library initialiation such that changes to the command-line arguments will be visible when the command-line intrinsics are invoked.

3.2 Finalization function

void caf_finish (void)

This function shall be called at the end of the program to permit a graceful shutdown.

Note: It is recommended to add this call at the end of the Fortran main program and when invoking STOP. To ensure that the shutdown is also performed for programs where this function is not explicitly invoked, for instance non-Fortran programs or calls to the system's exit() function, the library can use a destructor function. Note that programs can also be terminated using the ERROR STOP statement, which is handled via its own library call.

GCC: In gfortran, this function is called at the end of the Fortran main program and when before the program stops with a STOP command, the respective file has been compiled with the -fcoarray=lib option.

3.3 Querying the image number

int caf_this_image (int distance)

This function returns the current image number, which is a positive number.

Argument	description
distance	As specified for the this_image intrinsic in TS18508. Shall be a nonnegative number.

Note: If the Fortran intrinsic this_image() is invoked without an argument, which is the only permitted form in Fortran 2008, the processor shall pass 0 as first argument.

GCC: (No special note.)

3.4 Querying the maximal number of images

int caf_num_images (int distance, int failed)

This function returns the number of images in the current team, if distance is 0 or the number of images in the parent team at the specified distance. If failed is -1, the function returns the number of all images at the specified distance; if it is 0, the function returns the number of non-failed images, and if it is 1, it returns the number of failed images.

Argument	description
distance	the distance from this image to the ancestor. Shall be positive.
failed	shall be -1, 0, or 1

Note: This function follows TS18508. If the num_image intrinsic has no arguments, the processor shall pass distance = 0 and failed = -1 to the function.

GCC: (No special note.)

3.5 Registering coarrays

void *caf_register (size_t size, caf_register_t type, caf_token_t *token, int *stat, char *errmsg, int errmsg_len)

Allocates memory for a coarray and creates a token to identify the coarray. The function is called for both coarrays with SAVE attribute and using an explicit ALLOCATE statement. If an error occurs and STAT is a NULL pointer, the function shall abort with printing an error message and starting the error termination. If no error occurs and STAT= is present, it shall be set to zero. Otherwise, it shall be set to a positive value and, if not-@code{NULL}, @var{ERRMSG} shall be set to a string describing the failure. The function returns a pointer to the requested memory for the local image as a call to malloc would do.

For CAF_REGTYPE_COARRAY_STATIC and CAF_REGTYPE_COARRAY_ALLOC, the passed size is the byte size requested. For CAF_REGTYPE_LOCK_STATIC, CAF_REGTYPE_LOCK_ALLOC and CAF_REGTYPE_CRITICAL it is the array size or one for a scalar.

Argument	description
size	For normal coarrays, the byte size of the coarray to be allocated; for lock types, the number of elements.
type	one of the caf_register_t types. Possible values: CAF_REGTYPE_COARRAY_STATIC - for nonallocatable coarrays CAF_REGTYPE_COARRAY_ALLOC - for allocatable coarrays CAF_REGTYPE_LOCK_STATIC - for nonallocatable lock variables CAF_REGTYPE_LOCK_ALLOC - for allocatable lock variables CAF_REGTYPE_CRITICAL - for lock variables used for critical sections
token	intent(out) An opaque pointer identifying the coarray.
stat	intent(out) For allocatable coarrays, stores the STAT=; may be NULL
errmsg	intent(out) When an error occurs, this will be set to an error message; may be NULL
errmgs_len	the buffer size of errmsg.

TODO:

• Check whether the locking should be handled like that and whether one needs more, e.g. for locking types in DT?
• Check whether one needs an additional function for to register coarrays which are in static memory and used without memory allocation, i.e. just to register the address.
• Check whether we need an explicit SYNC ALL at the beginning of the main program or whether we can do without.
• Does TS18508 require more for SAVE within teams or within blocks?

Note: Non-allocatable coarrays have to be registered prior use from remote images. In order to guarantee this, they have to be registered before the main program. This can be achieved by creating constructor functions. When using caf_register, also non-allocatable coarrays the memory is allocated and no static memory is used.

For normal coarrays, the returned pointer is used for accesses on the local image. For lock types, the value shall only used for checking the allocation status. Note that for critical blocks, the locking is only required on one image; in the locking statement, the processor shall always pass always an image index of one for critical-section lock variables (CAF_REGTYPE_CRITICAL).

GCC: (no special notes)

TODO: Change errmsg_len to size_t

3.6 Deregistering coarrays

void caf_deregister (const caf_token_t *token, int *stat, char *errmsg, size_t errmsg_len)

Called to free the memory of a coarray; the processor calls this function for automatic and explicit deallocation. In case of an error, this function shall fail with an error message, unless the STAT= variable is not null.

Argument	intent	description
token	inout	An opaque pointer identifying the coarray.
stat	out	For allocatable coarrays, stores the STAT=; may be NULL
errmsg	out	When an error occurs, this will be set to an error message, may be NULL
errmgs_len		the buffersize of errmsg.

Note: The implementation is permitted to set the token to NULL. However, it is not required to do so. For nonalloatable coarrays this function is never called. If a cleanup is required, it has to be handled via the finish, stop and error stop functions, and via destructors.

GCC: (no special notes)

TODO: Change errmsg_len to size_t

3.7 Sending data from a local image to a remote image

void caf_send (caf_token_t token, size_t offset, int image_index,
               gfc_descriptor_t *dest, caf_vector_t *dst_vector,
               gfc_descriptor_t *src, int dst_kind, int src_kind)

Called to send a scalar, an array section or whole array from a local to a remote image identified by the image_index.

Argument	description
token	intent(in) An opaque pointer identifying the coarray.
offset	By which amount of bytes the actual data is shifted compared to the base address of the coarray.
image_index	The ID of the remote image; must be a positive number.
dest	intent(in) Array descriptor for the remote image for the bounds and the size. The base_addr shall not be accessed.
dst_vector	intent(in) If not NULL, it contains the vector subscript of the destination array; the values are relative to the dimension triplet of the dest argument.
src	intent(in) Array descriptor of the local array to be transferred to the remote image
dst_kind	Kind of the destination argument
src_kind	Kind of the source argument

Note: It is permitted to have image_id equal the current image; the memory of the send-to and the send-from might (partially) overlap in that case. The implementation has to take care that it handles this case. Note that the assignment of a scalar to an array is permitted. In addition, the library has to handle numeric-type conversion and for strings, padding and different character kinds.

GCC: Currently, it uses gfortran's private array descriptor. A change to TS29113's array descriptor is planned; when that's done, the additional kind arguments will be removed. Note that the kind arguments permit to distiniguish the character kinds and real/complex kinds 10 and 16, which have the same byte size.

TODO FOR SEND*:

• Wait is missing
• Assignment to an address instead of using a token, to handle caf[i]%allocatable%alloc_array(:,:) = ... Or some other means to handle those.
• Image index: How to handle references to other TEAMS?

OTHER TODOs:

• 3.x TODO: Handle GET and remote-to-remote communication
• 3.y TODO: Handle ATOMIC, LOCK, CRITICAL
• 3.z TODO Teams and error recovery

3.8 Getting data from a remote image

void caf_get_desc (caf_token_t token, size_t offset,
                   int image_index, gfc_descriptor_t *src,
                   caf_vector_t *src_vector, gfc_descriptor_t *dest,
                   int src_kind, int dst_kind)

Called to get an array section or whole array from a a remote, image identified by the image_index.

Argument	description
token	intent(in) An opaque pointer identifying the coarray.
offset	By which amount of bytes the actual data is shifted compared to the base address of the coarray.
image_index	The ID of the remote image; must be a positive number.
dest	intent(out) Array descriptor of the local array to which the data will be transferred
src	intent(in) Array descriptor for the remote image for the bounds and the size. The base_addr shall not be accessed.
src_vector	intent(int) If not NULL, it contains the vector subscript of the destination array; the values are relative to the dimension triplet of the dest argument.
dst_kind	Kind of the destination argument
src_kind	Kind of the source argument

Note: It is permitted to have image_id equal the current image; the memory of the send-to and the send-from might (partially) overlap in that case. The implementation has to take care that it handles this case. Note that the library has to handle numeric-type conversion and for strings, padding and different character kinds.

GCC: Currently, it uses gfortran's private array descriptor. A change to TS29113's array descriptor is planned; when that's done, the additional kind arguments will be removed. Note that the kind arguments permit to distinguish the character kinds and real/complex kinds 10 and 16, which have the same byte size.

3.9 Sending data between remote images

void caf_sendget (caf_token_t dst_token, size_t dst_offset,
                  int dst_image_index, gfc_descriptor_t *dest,
                  caf_vector_t *dst_vector, caf_token_t src_token,
                  size_t src_offset, int src_image_index,
                  gfc_descriptor_t *src, caf_vector_t *src_vector,
                  int dst_kind, int src_kind)

Called to send a scalar, an array section or whole array from a remote image identified by the src_image_index to a remote image identified by the dst_image_index.

Argument	description
dst_token	intent(in) An opaque pointer identifying the destination coarray.
dst_offset	By which amount of bytes the actual data is shifted compared to the base address of the destination coarray.
dst_image_index	The ID of the destination remote image; must be a positive number.
dest	intent(in) Array descriptor for the destination remote image for the bounds and the size. The base_addr shall not be accessed.
dst_vector	intent(int) If not NULL, it contains the vector subscript of the destination array; the values are relative to the dimension triplet of the dest argument.
src_token	intent(in) An opaque pointer identifying the source coarray.
src_offset	By which amount of bytes the actual data is shifted compared to the base address of the source coarray.
src_image_index	The ID of the source remote image; must be a positive number.
src	intent(in) Array descriptor of the local array to be transferred to the remote image
src_vector	intent(in) Array descriptor of the local array to be transferred to the remote image
dst_kind	Kind of the destination argument
src_kind	Kind of the source argument

Note: It is permitted to have image_id equal the current image; the memory of the send-to and the send-from might (partially) overlap in that case. The implementation has to take care that it handles this case. Note that the assignment of a scalar to an array is permitted. In addition, the library has to handle numeric-type conversion and for strings, padding and different character kinds.

GCC: Currently, it uses gfortran's private array descriptor. A change to TS29113's array descriptor is planned; when that's done, the additional kind arguments will be removed. Note that the kind arguments permit to distinguish the character kinds and real/complex kinds 10 and 16, which have the same byte size.

3.10 Barriers

3.10.1 All-Image Barrier

void caf_sync_all (int *stat, char *errmsg, size_t errmsg_len)

Barrier which waits for all other images, pending asynchronous communication and other data transfer.

Argument	description
stat	Status variable, if NULL, failures are fatal. If non-null, assigned 0 on success, and a stat code (cf. 2.3) in case of an error.
errmsg	If not NULL: Ignored unless stat is present; unmodified when successful, otherwise, an error message is copied into the variable.
errmsg_len	Maximal length of the error string, which is not '\0' terminated. The string should be padded by blanks.

Note: For portability, consider only using 7bit ASCII characters in the error message.

GCC: Implemented in GCC 4.x using an int argument for the length. Currently, size_t is not implemented.

3.10.2 Barrier for Selected Images

void sync_images (int count, int images[], int *stat,
                  char *errmsg, size_t errmsg_len)

Argument	description
count	Size of the array "images"; has value -1 for sync images(*) and value 0 for a zero-sized array.
image	list of images to be synced with.
stat	Status variable, if NULL, failures are fatal. If non-null, assigned 0 on success, and a stat code (cf. 2.3) in case of an error.
errmsg	If not NULL: Ignored unless stat is present; unmodified when successful, otherwise, an error message is copied into the variable.
errmsg_len	Maximal length of the error string, which is not \0 terminated. The string should be padded by blanks.

Note: For portability, consider only using 7bit ASCII characters in the error message. Note that the list can contain also the ID of this_image or can be an empty set. Example use is that image 1 syncs with all others (i.e sync images(*)) and the others sync only with that image (sync image(1)). Or for point-to point communication (sync image([left_image, right_image]).

GCC: Implemented in GCC 4.x using an int argument for the error-string length. Currently, size_t is not implemented.

3.11 Error abort

void error_stop_str (const char *string, int32_t str_len);
void error_stop (int32_t exit_error_code)

TODO

• Fix this description by filling-in the missing bits
• STOP vs ERROR STOP handling. Currently, STOP calls finalize and then the normal STOP while for ERROR STOP directly calls the library
• F2008 requires that one prints the raised exceptions with STOP and ERROR STOP. libgfortran's STOP and ERROR STOP do so - the current implementation for ERROR STOP does not.

3.11 Locking and unlocking

3.11.1 Locking a lock variable

void caf_lock (caf_token_t token, size_t index, int image_index,
               int *aquired_lock, int *stat, char *errmsg,
               int errmsg_len)

Acquire a lock on the given image on a scalar locking variable or for the given array element for an array-valued variable. If the acquired_lock is NULL, the function return after having obtained the lock. If it is non-null, the result is is assigned the value true (one) when the lock could be obtained and false (zero) otherwise. Locking a lock variable which has already been locked by the same image is an error.

Argument	arguments
token	intent(in) An opaque pointer identifying the coarray.
index	Array index; first array index is 0. For scalars, it is always 0.
image_index	The ID of the remote image; must be a positive number.
aquired_lock	intent(out) If not NULL, it returns whether lock could be obtained
stat	intent(out) For allocatable coarrays, stores the STAT=; may be NULL
errmsg	intent(out) When an error occurs, this will be set to an error message; may be NULL
errmsg_len	the buffer size of errmsg.

Note: This function is also called for critical sections; for those, the array index is always zero and the image index is one. Libraries are permitted to use other images for critical-section locking variables.

GCC: (no special notes)

TODO: Change errmsg_len to size_t

3.11.2 Unlocking a lock variable

void caf_unlock (caf_token_t token, size_t index, int image_index,
                 int *stat, char *errmsg, int errmsg_len)

Release a lock on the given image on a scalar locking variable or for the given array element for an array-valued variable. Unlocking a lock variable which is unlocked or has been locked by a different image is an error.

Argument	description
token	intent(in) An opaque pointer identifying the coarray.
index	Array index; first array index is 0. For scalars, it is always 0.
image_index	The ID of the remote image; must be a positive number.
stat	intent(out) For allocatable coarrays, stores the STAT=; may be NULL
errmsg	intent(out) When an error occurs, this will be set to an error message; may be NULL
errmsg_len	the buffer size of errmsg.

Note: This function is also called for critical sections; for those, the array index is always zero and the image index is one. Libraries are permitted to use other images for critical-section locking variables.

GCC: (no special notes)

TODO: Change errmsg_len to size_t

---