canputnext(9F) Kernel Functions for Drivers canputnext(9F)NAME
canputnext, bcanputnext - test for room in next module's message queue
SYNOPSIS
#include <sys/stream.h>
int canputnext(queue_t *q);
int bcanputnext(queue_t *q, unsigned char pri);
INTERFACE LEVEL
Architecture independent level 1 (DDI/DKI).
PARAMETERS
q Pointer to a message queue belonging to the invoking module.
pri Minimum priority level.
DESCRIPTION
The invocation canputnext(q); is an atomic equivalent of the canput(q->q_next); routine. That is, the STREAMS framework provides whatever
mutual exclusion is necessary to insure that dereferencing q through its q_next field and then invoking canput(9F) proceeds without inter-
ference from other threads.
bcanputnext(q, pri); is the equivalent of the bcanput(q->q_next, pri); routine.
canputnext(q); and bcanputnext(q, pri); should always be used in preference to canput(q->q_next); and bcanput(q->q_next, pri); respec-
tively.
See canput(9F) and bcanput(9F) for further details.
RETURN VALUES
1 If the message queue is not full.
0 If the queue is full.
CONTEXT
canputnext() and bcanputnext() can be called from user or interrupt context.
WARNINGS
Drivers are responsible for both testing a queue with canputnext() or bcanputnext() and refraining from placing a message on the queue if
the queue is full.
SEE ALSO bcanput(9F), canput(9F)
Writing Device Drivers
STREAMS Programming Guide
SunOS 5.10 31 Jan 1993 canputnext(9F)
Check Out this Related Man Page
srv(9E) Driver Entry Points srv(9E)NAME
srv - service queued messages
SYNOPSIS
#include <sys/types.h>
#include <sys/stream.h>
#include <sys/stropts.h>
#include <sys/ddi.h>
#include <sys/sunddi.h>
intprefixrsrv(queue_t *q);
/* read side */
intprefixwsrv(queue_t *q);
/* write side */
INTERFACE LEVEL
Architecture independent level 1 (DDI/DKI). This entry point is required for STREAMS.
ARGUMENTS
q Pointer to the queue(9S) structure.
DESCRIPTION
The optional service srv() routine may be included in a STREAMS module or driver for many possible reasons, including:
o to provide greater control over the flow of messages in a stream;
o to make it possible to defer the processing of some messages to avoid depleting system resources;
o to combine small messages into larger ones, or break large messages into smaller ones;
o to recover from resource allocation failure. A module's or driver's put(9E) routine can test for the availability of a resource, and
if it is not available, enqueue the message for later processing by the srv() routine.
A message is first passed to a module's or driver's put(9E) routine, which may or may not do some processing. It must then either:
o Pass the message to the next stream component with putnext(9F).
o If a srv() routine has been included, it may call putq(9F) to place the message on the queue.
Once a message has been enqueued, the STREAMS scheduler controls the service routine's invocation. The scheduler calls the service routines
in FIFO order. The scheduler cannot guarantee a maximum delay srv() routine to be called except that it will happen before any user level
process are run.
Every stream component (stream head, module or driver) has limit values it uses to implement flow control. Each component should check the
tunable high and low water marks to stop and restart the flow of message processing. Flow control limits apply only between two adjacent
components with srv() routines.
STREAMS messages can be defined to have up to 256 different priorities to support requirements for multiple bands of data flow. At a mini-
mum, a stream must distinguish between normal (priority zero) messages and high priority messages (such as M_IOCACK). High priority mes-
sages are always placed at the head of the srv() routine's queue, after any other enqueued high priority messages. Next are messages from
all included priority bands, which are enqueued in decreasing order of priority. Each priority band has its own flow control limits. If a
flow controlled band is stopped, all lower priority bands are also stopped.
Once the STREAMS scheduler calls a srv() routine, it must process all messages on its queue. The following steps are general guidelines for
processing messages. Keep in mind that many of the details of how a srv() routine should be written depend of the implementation, the
direction of flow (upstream or downstream), and whether it is for a module or a driver.
1. Use getq(9F) to get the next enqueued message.
2. If the message is high priority, process (if appropriate) and pass to the next stream component with putnext(9F).
3. If it is not a high priority message (and therefore subject to flow control), attempt to send it to the next stream component with a
srv() routine. Use bcanputnext(9F) to determine if this can be done.
4. If the message cannot be passed, put it back on the queue with putbq(9F). If it can be passed, process (if appropriate) and pass with
putnext().
RETURN VALUES
Ignored.
SEE ALSO put(9E), bcanput(9F), bcanputnext(9F), canput(9F), canputnext(9F), getq(9F), nulldev(9F), putbq(9F), putnext(9F), putq(9F), qinit(9S),
queue(9S)
Writing Device Drivers
STREAMS Programming Guide
WARNINGS
Each stream module must specify a read and a write service srv() routine. If a service routine is not needed (because the put() routine
processes all messages), a NULL pointer should be placed in module's qinit(9S) structure. Do not use nulldev(9F) instead of the NULL
pointer. Use ofnulldev(9F) for a srv() routine can result in flow control errors.
SunOS 5.10 12 Nov 1992 srv(9E)