Entry points must be implemented by a device-specific network driver that has been designed to interface with GLDv2.
The gld_mac_info(9S) structure is the main structure for communication between the device-specific driver and the GLDv2 module. See the gld(7D) man page. Some elements in that structure are function pointers to the entry points that are described here. The device-specific driver must, in its attach(9E) routine, initialize these function pointers before calling gld_register().
int prefix_reset(gld_mac_info_t *macinfo);
int prefix_start(gld_mac_info_t *macinfo);
int prefix_stop(gld_mac_info_t *macinfo);
gldm_stop() disables the device from generating any interrupts and stops the driver from calling gld_recv() for delivering data packets to GLDv2. GLDv2 depends on the gldm_stop() routine to ensure that the device will no longer interrupt. gldm_stop() must do so without fail. This function should always return GLD_SUCCESS.
int prefix_set_mac_addr(gld_mac_info_t *macinfo, unsigned char *macaddr);
gldm_set_mac_addr() sets the physical address that the hardware is to use for receiving data. This function enables the device to be programmed through the passed MAC address macaddr. If sufficient resources are currently not available to carry out the request, gldm_set_mac_add() should return GLD_NORESOURCES. If the requested function is not supported, gldm_set_mac_add() should return GLD_NOTSUPPORTED.
int prefix_set_multicast(gld_mac_info_t *macinfo, unsigned char *multicastaddr, int multiflag);
gldm_set_multicast() enables and disables device-level reception of specific multicast addresses. If the third argument multiflag is set to GLD_MULTI_ENABLE, then gldm_set_multicast() sets the interface to receive packets with the multicast address. gldm_set_multicast() uses the multicast address that is pointed to by the second argument. If multiflag is set to GLD_MULTI_DISABLE, the driver is allowed to disable reception of the specified multicast address.
This function is called whenever GLDv2 wants to enable or disable reception of a multicast, group, or functional address. GLDv2 makes no assumptions about how the device does multicast support and calls this function to enable or disable a specific multicast address. Some devices might use a hash algorithm and a bitmask to enable collections of multicast addresses. This procedure is allowed, and GLDv2 filters out any superfluous packets. If disabling an address could result in disabling more than one address at the device level, the device driver should keep any necessary information. This approach avoids disabling an address that GLDv2 has enabled but not disabled.
gldm_set_multicast() is not called to enable a particular multicast address that is already enabled. Similarly, gldm_set_multicast() is not called to disable an address that is not currently enabled. GLDv2 keeps track of multiple requests for the same multicast address. GLDv2 only calls the driver's entry point when the first request to enable, or the last request to disable, a particular multicast address is made. If sufficient resources are currently not available to carry out the request, the function should return GLD_NORESOURCES. The function should return GLD_NOTSUPPORTED if the requested function is not supported.
int prefix_set_promiscuous(gld_mac_info_t *macinfo, int promiscflag);
gldm_set_promiscuous() enables and disables promiscuous mode. This function is called whenever GLDv2 wants to enable or disable the reception of all packets on the medium. The function can also be limited to multicast packets on the medium. If the second argument promiscflag is set to the value of GLD_MAC_PROMISC_PHYS, then the function enables physical-level promiscuous mode. Physical-level promiscuous mode causes the reception of all packets on the medium. If promiscflag is set to GLD_MAC_PROMISC_MULTI, then reception of all multicast packets are enabled. If promiscflag is set to GLD_MAC_PROMISC_NONE, then promiscuous mode is disabled.
In promiscuous multicast mode, drivers for devices without multicast-only promiscuous mode must set the device to physical promiscuous mode. This approach ensures that all multicast packets are received. In this case, the routine should return GLD_SUCCESS. The GLDv2 software filters out any superfluous packets. If sufficient resources are currently not available to carry out the request, the function should return GLD_NORESOURCES. The gld_set_promiscuous() function should return GLD_NOTSUPPORTED if the requested function is not supported.
For forward compatibility, gldm_set_promiscuous() routines should treat any unrecognized values for promiscflag as though these values were GLD_MAC_PROMISC_PHYS.
int prefix_send(gld_mac_info_t *macinfo, mblk_t *mp);
gldm_send() queues a packet to the device for transmission. This routine is passed a STREAMS message containing the packet to be sent. The message might include multiple message blocks. The send() routine must traverse all the message blocks in the message to access the entire packet to be sent. The driver should be prepared to handle and skip over any zero-length message continuation blocks in the chain. The driver should also check that the packet does not exceed the maximum allowable packet size. The driver must pad the packet, if necessary, to the minimum allowable packet size. If the send routine successfully transmits or queues the packet, GLD_SUCCESS should be returned.
The send routine should return GLD_NORESOURCES if the packet for transmission cannot be immediately accepted. In this case, GLDv2 retries later. If gldm_send() ever returns GLD_NORESOURCES, the driver must call gld_sched() at a later time when resources have become available. This call to gld_sched() informs GLDv2 to retry packets that the driver previously failed to queue for transmission. (If the driver's gldm_stop() routine is called, the driver is absolved from this obligation until the driver returns GLD_NORESOURCES from the gldm_send() routine. However, extra calls to gld_sched() do not cause incorrect operation.)
If the driver's send routine returns GLD_SUCCESS, then the driver is responsible for freeing the message when the message is no longer needed. If the hardware uses DMA to read the data directly, the driver must not free the message until the hardware has completely read the data. In this case, the driver can free the message in the interrupt routine. Alternatively, the driver can reclaim the buffer at the start of a future send operation. If the send routine returns anything other than GLD_SUCCESS, then the driver must not free the message. Return GLD_NOLINK if gldm_send() is called when there is no physical connection to the network or link partner.
int prefix_intr(gld_mac_info_t *macinfo);
gldm_intr() is called when the device might have interrupted. Because interrupts can be shared with other devices, the driver must check the device status to determine whether that device actually caused the interrupt. If the device that the driver controls did not cause the interrupt, then this routine must return DDI_INTR_UNCLAIMED. Otherwise, the driver must service the interrupt and return DDI_INTR_CLAIMED. If the interrupt was caused by successful receipt of a packet, this routine should put the received packet into a STREAMS message of type M_DATA and pass that message to gld_recv().
gld_recv() passes the inbound packet upstream to the appropriate next layer of the network protocol stack. The routine must correctly set the b_rptr and b_wptr members of the STREAMS message before calling gld_recv().
The driver should avoid holding mutex or other locks during the call to gld_recv(). In particular, locks that could be taken by a transmit thread must not be held during a call to gld_recv(). In some cases, the interrupt thread that calls gld_recv() sends an outgoing packet, which results in a call to the driver's gldm_send() routine. If gldm_send() tries to acquire a mutex that is held by gldm_intr() when gld_recv() is called, a panic occurs due to recursive mutex entry. If other driver entry points attempt to acquire a mutex that the driver holds across a call to gld_recv(), deadlock can result.
The interrupt code should increment statistics counters for any errors. Errors include the failure to allocate a buffer that is needed for the received data and any hardware-specific errors, such as CRC errors or framing errors.
int prefix_get_stats(gld_mac_info_t *macinfo, struct gld_stats *stats);
gldm_get_stats() gathers statistics from the hardware, driver private counters, or both, and updates the gld_stats(9S) structure pointed to by stats. This routine is called by GLDv2 for statistics requests. GLDv2 uses the gldm_get_stats() mechanism to acquire device-dependent statistics from the driver before GLDv2 composes the reply to the statistics request. See the gld_stats(9S), gld(7D), and qreply(9F) man pages for more information about defined statistics counters.
int prefix_ioctl(gld_mac_info_t *macinfo, queue_t *q, mblk_t *mp);
gldm_ioctl() implements any device-specific ioctl commands. This element is allowed to be null if the driver does not implement any ioctl functions. The driver is responsible for converting the message block into an ioctl reply message and calling the qreply(9F) function before returning GLD_SUCCESS. This function should always return GLD_SUCCESS. The driver should report any errors as needed in a message to be passed to qreply(9F). If the gldm_ioctl element is specified as NULL, GLDv2 returns a message of type M_IOCNAK with an error of EINVAL.