xref: /titanic_41/usr/src/man/man9f/csx_DupHandle.9f (revision 2c2d21e98a95cba5687ec6574c974a5c6c4a6adb)
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Copyright (c) 1996, Sun Microsystems, Inc. All Rights Reserved
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You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE or http://www.opensolaris.org/os/licensing. See the License for the specific language governing permissions and limitations under the License.
When distributing Covered Code, include this CDDL HEADER in each file and include the License file at usr/src/OPENSOLARIS.LICENSE. If applicable, add the following below this CDDL HEADER, with the fields enclosed by brackets "[]" replaced with your own identifying information: Portions Copyright [yyyy] [name of copyright owner]
CSX_DUPHANDLE 9F "Jul 19, 1996"
NAME
csx_DupHandle - duplicate access handle
SYNOPSIS

#include <sys/pccard.h>



int32_t csx_DupHandle(acc_handle_t handle1, acc_handle_t *handle2,
 uint32_t flags);
INTERFACE LEVEL

Solaris DDI Specific (Solaris DDI)

PARAMETERS
handle1

The access handle returned from csx_RequestIO(9F) or csx_RequestWindow(9F) that is to be duplicated.

handle2

A pointer to the newly-created duplicated data access handle.

flags

The access attributes that will be applied to the new handle.

DESCRIPTION

This function duplicates the handle, handle1, into a new handle, handle2, that has the access attributes specified in the flags argument. Both the original handle and the new handle are active and can be used with the common access functions.

Both handles must be explicitly freed when they are no longer necessary.

The flags argument is bit-mapped. The following bits are defined:

WIN_ACC_NEVER_SWAP Host endian byte ordering
WIN_ACC_BIG_ENDIAN Big endian byte ordering
WIN_ACC_LITTLE_ENDIAN Little endian byte ordering
WIN_ACC_STRICT_ORDER Program ordering references
WIN_ACC_UNORDERED_OK May re-order references
WIN_ACC_MERGING_OK Merge stores to consecutive locations
WIN_ACC_LOADCACHING_OK May cache load operations
WIN_ACC_STORECACHING_OK May cache store operations

WIN_ACC_BIG_ENDIAN and WIN_ACC_LITTLE_ENDIAN describe the endian characteristics of the device as big endian or little endian, respectively. Even though most of the devices will have the same endian characteristics as their busses, there are examples of devices with an I/O processor that has opposite endian characteristics of the busses. When WIN_ACC_BIG_ENDIAN or WIN_ACC_LITTLE_ENDIAN is set, byte swapping will automatically be performed by the system if the host machine and the device data formats have opposite endian characteristics. The implementation may take advantage of hardware platform byte swapping capabilities. When WIN_ACC_NEVER_SWAP is specified, byte swapping will not be invoked in the data access functions. The ability to specify the order in which the CPU will reference data is provided by the following flags bits. Only one of the following bits may be specified: WIN_ACC_STRICT_ORDER

The data references must be issued by a CPU in program order. Strict ordering is the default behavior.

WIN_ACC_UNORDERED_OK

The CPU may re-order the data references. This includes all kinds of re-ordering (that is, a load followed by a store may be replaced by a store followed by a load).

WIN_ACC_MERGING_OK

The CPU may merge individual stores to consecutive locations. For example, the CPU may turn two consecutive byte stores into one halfword store. It may also batch individual loads. For example, the CPU may turn two consecutive byte loads into one halfword load. Setting this bit also implies re-ordering.

WIN_ACC_LOADCACHING_OK

The CPU may cache the data it fetches and reuse it until another store occurs. The default behavior is to fetch new data on every load. Setting this bit also implies merging and re-ordering.

WIN_ACC_STORECACHING_OK

The CPU may keep the data in the cache and push it to the device (perhaps with other data) at a later time. The default behavior is to push the data right away. Setting this bit also implies load caching, merging, and re-ordering.

These values are advisory, not mandatory. For example, data can be ordered without being merged or cached, even though a driver requests unordered, merged and cached together.

RETURN VALUES
CS_SUCCESS

Successful operation.

CS_FAILURE

Error in flags argument or handle could not be duplicated for some reason.

CS_UNSUPPORTED_FUNCTION

No PCMCIA hardware installed.

CONTEXT

This function may be called from user or kernel context.

SEE ALSO

csx_Get8(9F), csx_GetMappedAddr(9F), csx_Put8(9F), csx_RepGet8(9F), csx_RepPut8(9F), csx_RequestIO(9F), csx_RequestWindow(9F)

PC Card 95 Standard, PCMCIA/JEIDA