static int sxg_allocate_buffer_memory(struct adapter_t *adapter, u32 Size,
enum sxg_buffer_type BufferType);
-static void sxg_allocate_rcvblock_complete(struct adapter_t *adapter, void *RcvBlock,
- dma_addr_t PhysicalAddress,
- u32 Length);
+static void sxg_allocate_rcvblock_complete(struct adapter_t *adapter,
+ void *RcvBlock,
+ dma_addr_t PhysicalAddress,
+ u32 Length);
static void sxg_allocate_sgl_buffer_complete(struct adapter_t *adapter,
struct sxg_scatter_gather *SxgSgl,
dma_addr_t PhysicalAddress,
u32 Length);
static void sxg_mcast_init_crc32(void);
-
static int sxg_entry_open(struct net_device *dev);
static int sxg_entry_halt(struct net_device *dev);
static int sxg_ioctl(struct net_device *dev, struct ifreq *rq, int cmd);
static int sxg_send_packets(struct sk_buff *skb, struct net_device *dev);
static int sxg_transmit_packet(struct adapter_t *adapter, struct sk_buff *skb);
-static void sxg_dumb_sgl(struct sxg_x64_sgl *pSgl, struct sxg_scatter_gather *SxgSgl);
+static void sxg_dumb_sgl(struct sxg_x64_sgl *pSgl,
+ struct sxg_scatter_gather *SxgSgl);
static void sxg_handle_interrupt(struct adapter_t *adapter);
static int sxg_process_isr(struct adapter_t *adapter, u32 MessageId);
static u32 sxg_process_event_queue(struct adapter_t *adapter, u32 RssId);
static void sxg_complete_slow_send(struct adapter_t *adapter);
-static struct sk_buff *sxg_slow_receive(struct adapter_t *adapter, struct sxg_event *Event);
+static struct sk_buff *sxg_slow_receive(struct adapter_t *adapter,
+ struct sxg_event *Event);
static void sxg_process_rcv_error(struct adapter_t *adapter, u32 ErrorStatus);
static bool sxg_mac_filter(struct adapter_t *adapter,
struct ether_header *EtherHdr, ushort length);
static int sxg_phy_init(struct adapter_t *adapter);
static void sxg_link_event(struct adapter_t *adapter);
static enum SXG_LINK_STATE sxg_get_link_state(struct adapter_t *adapter);
-static void sxg_link_state(struct adapter_t *adapter, enum SXG_LINK_STATE LinkState);
+static void sxg_link_state(struct adapter_t *adapter,
+ enum SXG_LINK_STATE LinkState);
static int sxg_write_mdio_reg(struct adapter_t *adapter,
u32 DevAddr, u32 RegAddr, u32 Value);
static int sxg_read_mdio_reg(struct adapter_t *adapter,
static unsigned int sxg_first_init = 1;
static char *sxg_banner =
- "Alacritech SLIC Technology(tm) Server and Storage 10Gbe Accelerator (Non-Accelerated)\n";
+ "Alacritech SLIC Technology(tm) Server and Storage \
+ 10Gbe Accelerator (Non-Accelerated)\n";
static int sxg_debug = 1;
static int debug = -1;
#define DRV_NAME "sxg"
#define DRV_VERSION "1.0.1"
#define DRV_AUTHOR "Alacritech, Inc. Engineering"
-#define DRV_DESCRIPTION "Alacritech SLIC Techonology(tm) Non-Accelerated 10Gbe Driver"
-#define DRV_COPYRIGHT "Copyright 2000-2008 Alacritech, Inc. All rights reserved."
+#define DRV_DESCRIPTION \
+ "Alacritech SLIC Techonology(tm) Non-Accelerated 10Gbe Driver"
+#define DRV_COPYRIGHT \
+ "Copyright 2000-2008 Alacritech, Inc. All rights reserved."
MODULE_AUTHOR(DRV_AUTHOR);
MODULE_DESCRIPTION(DRV_DESCRIPTION);
* Return
* int
*/
-static bool sxg_download_microcode(struct adapter_t *adapter, enum SXG_UCODE_SEL UcodeSel)
+static bool sxg_download_microcode(struct adapter_t *adapter,
+ enum SXG_UCODE_SEL UcodeSel)
{
struct sxg_hw_regs *HwRegs = adapter->HwRegs;
u32 Section;
u32 ThisSectionSize;
u32 *Instruction = NULL;
u32 BaseAddress, AddressOffset, Address;
-/* u32 Failure; */
+ /* u32 Failure; */
u32 ValueRead;
u32 i;
u32 numSections = 0;
break;
}
BaseAddress = sectionStart[Section];
- ThisSectionSize = sectionSize[Section] / 12; /* Size in instructions */
+ /* Size in instructions */
+ ThisSectionSize = sectionSize[Section] / 12;
for (AddressOffset = 0; AddressOffset < ThisSectionSize;
AddressOffset++) {
Address = BaseAddress + AddressOffset;
break;
}
BaseAddress = sectionStart[Section];
- ThisSectionSize = sectionSize[Section] / 12; /* Size in instructions */
+ /* Size in instructions */
+ ThisSectionSize = sectionSize[Section] / 12;
for (AddressOffset = 0; AddressOffset < ThisSectionSize;
AddressOffset++) {
Address = BaseAddress + AddressOffset;
DBG_ERROR("sxg: %s PARITY ERROR\n",
__func__);
- return (FALSE); /* Parity error */
+ return FALSE; /* Parity error */
}
ASSERT((ValueRead & MICROCODE_ADDRESS_MASK) == Address);
/* Read the instruction back and compare */
if (ValueRead != *Instruction) {
DBG_ERROR("sxg: %s MISCOMPARE LOW\n",
__func__);
- return (FALSE); /* Miscompare */
+ return FALSE; /* Miscompare */
}
READ_REG(HwRegs->UcodeDataMiddle, ValueRead);
if (ValueRead != *(Instruction + 1)) {
DBG_ERROR("sxg: %s MISCOMPARE MIDDLE\n",
__func__);
- return (FALSE); /* Miscompare */
+ return FALSE; /* Miscompare */
}
READ_REG(HwRegs->UcodeDataHigh, ValueRead);
if (ValueRead != *(Instruction + 2)) {
DBG_ERROR("sxg: %s MISCOMPARE HIGH\n",
__func__);
- return (FALSE); /* Miscompare */
+ return FALSE; /* Miscompare */
}
/* Advance 3 u32S to start of next instruction */
Instruction += 3;
if (i == 10000) {
DBG_ERROR("sxg: %s TIMEOUT\n", __func__);
- return (FALSE); /* Timeout */
+ return FALSE; /* Timeout */
}
/*
* Now write the LoadSync register. This is used to
* sxg_allocate_resources - Allocate memory and locks
*
* Arguments -
- * adapter - A pointer to our adapter structure
+ * adapter - A pointer to our adapter structure
*
- * Return
- * int
+ * Return - int
*/
static int sxg_allocate_resources(struct adapter_t *adapter)
{
int status;
u32 i;
u32 RssIds, IsrCount;
-/* struct sxg_xmt_ring *XmtRing; */
-/* struct sxg_rcv_ring *RcvRing; */
+ /* struct sxg_xmt_ring *XmtRing; */
+ /* struct sxg_rcv_ring *RcvRing; */
DBG_ERROR("%s ENTER\n", __func__);
(unsigned int)(sizeof(struct sxg_xmt_ring) * 1));
/*
- * Start with big items first - receive and transmit rings. At the moment
- * I'm going to keep the ring size fixed and adjust the
- * TCBs if we fail. Later we might consider reducing the ring size as well..
+ * Start with big items first - receive and transmit rings.
+ * At the moment I'm going to keep the ring size fixed and
+ * adjust the TCBs if we fail. Later we might
+ * consider reducing the ring size as well..
*/
adapter->XmtRings = pci_alloc_consistent(adapter->pcidev,
- sizeof(struct sxg_xmt_ring) *
- 1,
- &adapter->PXmtRings);
+ sizeof(struct sxg_xmt_ring) *
+ 1,
+ &adapter->PXmtRings);
DBG_ERROR("%s XmtRings[%p]\n", __func__, adapter->XmtRings);
if (!adapter->XmtRings) {
* a corresponding descriptor block at once. See sxghw.h:SXG_RCV_BLOCK
*/
for (i = 0; i < SXG_INITIAL_RCV_DATA_BUFFERS;
- i += SXG_RCV_DESCRIPTORS_PER_BLOCK) {
- sxg_allocate_buffer_memory(adapter,
- SXG_RCV_BLOCK_SIZE(adapter->
- ReceiveBufferSize),
+ i += SXG_RCV_DESCRIPTORS_PER_BLOCK) {
+ sxg_allocate_buffer_memory(adapter,
+ SXG_RCV_BLOCK_SIZE(adapter->ReceiveBufferSize),
SXG_BUFFER_TYPE_RCV);
}
/*
- * NBL resource allocation can fail in the 'AllocateComplete' routine, which
- * doesn't return status. Make sure we got the number of buffers we requested
+ * NBL resource allocation can fail in the 'AllocateComplete' routine,
+ * which doesn't return status. Make sure we got the number of buffers
+ * we requested
*/
if (adapter->FreeRcvBufferCount < SXG_INITIAL_RCV_DATA_BUFFERS) {
SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_NOISY, "XAResF6",
/* Allocate event queues. */
adapter->EventRings = pci_alloc_consistent(adapter->pcidev,
- sizeof(struct sxg_event_ring) *
- RssIds,
- &adapter->PEventRings);
+ sizeof(struct sxg_event_ring) *
+ RssIds,
+ &adapter->PEventRings);
if (!adapter->EventRings) {
- /* Caller will call SxgFreeAdapter to clean up above allocations */
+ /* Caller will call SxgFreeAdapter to clean up above
+ * allocations */
SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_NOISY, "XAResF8",
adapter, SXG_MAX_ENTRIES, 0, 0);
status = STATUS_RESOURCES;
adapter->Isr = pci_alloc_consistent(adapter->pcidev,
IsrCount, &adapter->PIsr);
if (!adapter->Isr) {
- /* Caller will call SxgFreeAdapter to clean up above allocations */
+ /* Caller will call SxgFreeAdapter to clean up above
+ * allocations */
SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_NOISY, "XAResF9",
adapter, SXG_MAX_ENTRIES, 0, 0);
status = STATUS_RESOURCES;
pci_read_config_word(pcidev, PCI_COMMAND, &pci_command);
DBG_ERROR("sxg: %s PCI command[%4.4x]\n", __func__, pci_command);
/* Set the command register */
- new_command = pci_command | (PCI_COMMAND_MEMORY | /* Memory Space Enable */
- PCI_COMMAND_MASTER | /* Bus master enable */
- PCI_COMMAND_INVALIDATE | /* Memory write and invalidate */
- PCI_COMMAND_PARITY | /* Parity error response */
- PCI_COMMAND_SERR | /* System ERR */
- PCI_COMMAND_FAST_BACK); /* Fast back-to-back */
+ new_command = pci_command | (
+ /* Memory Space Enable */
+ PCI_COMMAND_MEMORY |
+ /* Bus master enable */
+ PCI_COMMAND_MASTER |
+ /* Memory write and invalidate */
+ PCI_COMMAND_INVALIDATE |
+ /* Parity error response */
+ PCI_COMMAND_PARITY |
+ /* System ERR */
+ PCI_COMMAND_SERR |
+ /* Fast back-to-back */
+ PCI_COMMAND_FAST_BACK);
if (pci_command != new_command) {
DBG_ERROR("%s -- Updating PCI COMMAND register %4.4x->%4.4x.\n",
__func__, pci_command, new_command);
}
}
-static unsigned char temp_mac_address[6] = { 0x00, 0xab, 0xcd, 0xef, 0x12, 0x69 };
+static unsigned char temp_mac_address[6] =
+ { 0x00, 0xab, 0xcd, 0xef, 0x12, 0x69 };
/*
* sxg_read_config
* @adapter : Pointer to the adapter structure for the card
unsigned long status;
unsigned long i;
- data = pci_alloc_consistent(adapter->pcidev, sizeof(struct sw_cfg_data), &p_addr);
+ data = pci_alloc_consistent(adapter->pcidev,
+ sizeof(struct sw_cfg_data), &p_addr);
if(!data) {
/*
* We cant get even this much memory. Raise a hell
* Get out of here
*/
- printk(KERN_ERR"%s : Could not allocate memory for reading EEPROM\n", __FUNCTION__);
+ printk(KERN_ERR"%s : Could not allocate memory for reading \
+ EEPROM\n", __FUNCTION__);
return -ENOMEM;
}
}
switch(status) {
- case SXG_CFG_LOAD_EEPROM: /*Config read from EEPROM succeeded */
- case SXG_CFG_LOAD_FLASH: /* onfig read from Flash succeeded */
- /* Copy the MAC address to adapter structure */
- memcpy(temp_mac_address, data->MacAddr[0].MacAddr, 6);
- /* TODO: We are not doing the remaining part : FRU, etc */
- break;
-
- case SXG_CFG_TIMEOUT:
- case SXG_CFG_LOAD_INVALID:
- case SXG_CFG_LOAD_ERROR:
- default: /* Fix default handler later */
- printk(KERN_WARNING"%s : We could not read the config word."
- "Status = %ld\n", __FUNCTION__, status);
- break;
+ /* Config read from EEPROM succeeded */
+ case SXG_CFG_LOAD_EEPROM:
+ /* Config read from Flash succeeded */
+ case SXG_CFG_LOAD_FLASH:
+ /* Copy the MAC address to adapter structure */
+ memcpy(temp_mac_address, data->MacAddr[0].MacAddr, 6);
+ /* TODO: We are not doing the remaining part : FRU,
+ * etc
+ */
+ break;
+ case SXG_CFG_TIMEOUT:
+ case SXG_CFG_LOAD_INVALID:
+ case SXG_CFG_LOAD_ERROR:
+ default: /* Fix default handler later */
+ printk(KERN_WARNING"%s : We could not read the config \
+ word. Status = %ld\n", __FUNCTION__, status);
+ break;
}
- pci_free_consistent(adapter->pcidev, sizeof(struct sw_cfg_data), data, p_addr);
+ pci_free_consistent(adapter->pcidev, sizeof(struct sw_cfg_data), data,
+ p_addr);
if (adapter->netdev) {
memcpy(adapter->netdev->dev_addr, adapter->currmacaddr, 6);
memcpy(adapter->netdev->perm_addr, adapter->currmacaddr, 6);
goto err_out_free_mmio_region;
}
- DBG_ERROR
- ("sxg: %s found Alacritech SXG PCI, MMIO at %p, start[%lx] len[%lx], IRQ %d.\n",
- __func__, memmapped_ioaddr, mmio_start, mmio_len, pcidev->irq);
+ DBG_ERROR("sxg: %s found Alacritech SXG PCI, MMIO at %p, start[%lx] \
+ len[%lx], IRQ %d.\n", __func__, memmapped_ioaddr, mmio_start,
+ mmio_len, pcidev->irq);
adapter->HwRegs = (void *)memmapped_ioaddr;
adapter->base_addr = memmapped_ioaddr;
adapter->ReceiveBufferSize = SXG_RCV_DATA_BUFFER_SIZE;
}
-/*
- * status = SXG_READ_EEPROM(adapter);
- * if (!status) {
- * goto sxg_init_bad;
- * }
- */
+ /*
+ * status = SXG_READ_EEPROM(adapter);
+ * if (!status) {
+ * goto sxg_init_bad;
+ * }
+ */
DBG_ERROR("sxg: %s ENTER sxg_config_pci\n", __func__);
sxg_config_pci(pcidev);
netdev->set_multicast_list = sxg_mcast_set_list;
strcpy(netdev->name, "eth%d");
-/* strcpy(netdev->name, pci_name(pcidev)); */
+ /* strcpy(netdev->name, pci_name(pcidev)); */
if ((err = register_netdev(netdev))) {
DBG_ERROR("Cannot register net device, aborting. %s\n",
netdev->name);
}
DBG_ERROR
- ("sxg: %s addr 0x%lx, irq %d, MAC addr %02X:%02X:%02X:%02X:%02X:%02X\n",
+ ("sxg: %s addr 0x%lx, irq %d, MAC addr \
+ %02X:%02X:%02X:%02X:%02X:%02X\n",
netdev->name, netdev->base_addr, pcidev->irq, netdev->dev_addr[0],
netdev->dev_addr[1], netdev->dev_addr[2], netdev->dev_addr[3],
netdev->dev_addr[4], netdev->dev_addr[5]);
-/*sxg_init_bad: */
+ /* sxg_init_bad: */
ASSERT(status == FALSE);
-/* sxg_free_adapter(adapter); */
+ /* sxg_free_adapter(adapter); */
DBG_ERROR("sxg: %s EXIT status[%x] jiffies[%lx] cpu %d\n", __func__,
status, jiffies, smp_processor_id());
* sxg_isr - Process an line-based interrupt
*
* Arguments:
- * Context - Our adapter structure
+ * Context - Our adapter structure
* QueueDefault - Output parameter to queue to default CPU
- * TargetCpus - Output bitmap to schedule DPC's
+ * TargetCpus - Output bitmap to schedule DPC's
*
- * Return Value:
- * TRUE if our interrupt
+ * Return Value: TRUE if our interrupt
*/
static irqreturn_t sxg_isr(int irq, void *dev_id)
{
struct net_device *dev = (struct net_device *) dev_id;
struct adapter_t *adapter = (struct adapter_t *) netdev_priv(dev);
-/* u32 CpuMask = 0, i; */
+ /* u32 CpuMask = 0, i; */
adapter->Stats.NumInts++;
if (adapter->Isr[0] == 0) {
adapter->IsrCopy[0] = adapter->Isr[0];
adapter->Isr[0] = 0;
WRITE_REG(adapter->UcodeRegs[0].Icr, SXG_ICR(0, SXG_ICR_MASK), TRUE);
-/* ASSERT(adapter->IsrDpcsPending == 0); */
+ /* ASSERT(adapter->IsrDpcsPending == 0); */
#if XXXTODO /* RSS Stuff */
/*
* If RSS is enabled and the ISR specifies SXG_ISR_EVENT, then
for (i = 0;
i < adapter->RssSystemInfo->ProcessorInfo.RssCpuCount;
i++) {
- struct sxg_event_ring *EventRing = &adapter->EventRings[i];
+ struct sxg_event_ring *EventRing =
+ &adapter->EventRings[i];
struct sxg_event *Event =
&EventRing->Ring[adapter->NextEvent[i]];
unsigned char Cpu =
}
}
}
- /* Now, either schedule the CPUs specified by the CpuMask,
+ /*
+ * Now, either schedule the CPUs specified by the CpuMask,
* or queue default
*/
if (CpuMask) {
static void sxg_handle_interrupt(struct adapter_t *adapter)
{
-/* unsigned char RssId = 0; */
+ /* unsigned char RssId = 0; */
u32 NewIsr;
if (++debug_inthandler < 20) {
}
/* Card crash */
if (Isr & SXG_ISR_DEAD) {
- /* Set aside the crash info and set the adapter state to RESET */
- adapter->CrashCpu =
- (unsigned char)((Isr & SXG_ISR_CPU) >>
- SXG_ISR_CPU_SHIFT);
+ /*
+ * Set aside the crash info and set the adapter state
+ * to RESET
+ */
+ adapter->CrashCpu = (unsigned char)
+ ((Isr & SXG_ISR_CPU) >> SXG_ISR_CPU_SHIFT);
adapter->CrashLocation = (ushort) (Isr & SXG_ISR_CRASH);
adapter->Dead = TRUE;
DBG_ERROR("%s: ISR_DEAD %x, CPU: %d\n", __func__,
}
/* Dump */
if (Isr & SXG_ISR_UPC) {
- ASSERT(adapter->DumpCmdRunning); /* Maybe change when debug is added.. */
+ /* Maybe change when debug is added.. */
+ ASSERT(adapter->DumpCmdRunning);
adapter->DumpCmdRunning = FALSE;
}
/* Link event */
if (Isr & SXG_ISR_BREAK) {
/*
* At the moment AGDB isn't written to support interactive
- * debug sessions. When it is, this interrupt will be used
- * to signal AGDB that it has hit a breakpoint. For now, ASSERT.
+ * debug sessions. When it is, this interrupt will be used to
+ * signal AGDB that it has hit a breakpoint. For now, ASSERT.
*/
ASSERT(0);
}
adapter->NextEvent);
switch (Event->Code) {
case EVENT_CODE_BUFFERS:
- ASSERT(!(Event->CommandIndex & 0xFF00)); /* struct sxg_ring_info Head & Tail == unsigned char */
+ /* struct sxg_ring_info Head & Tail == unsigned char */
+ ASSERT(!(Event->CommandIndex & 0xFF00));
sxg_complete_descriptor_blocks(adapter,
Event->CommandIndex);
break;
* capability of an indication list.
*/
#else
-/* CHECK skb_pull(skb, INIC_RCVBUF_HEADSIZE); */
- rx_bytes = Event->Length; /* (rcvbuf->length & IRHDDR_FLEN_MSK); */
+ /* CHECK skb_pull(skb, INIC_RCVBUF_HEADSIZE); */
+ /* (rcvbuf->length & IRHDDR_FLEN_MSK); */
+ rx_bytes = Event->Length;
adapter->stats.rx_packets++;
adapter->stats.rx_bytes += rx_bytes;
#if SXG_OFFLOAD_IP_CHECKSUM
default:
DBG_ERROR("%s: ERROR Invalid EventCode %d\n",
__func__, Event->Code);
-/* ASSERT(0); */
+ /* ASSERT(0); */
}
/*
* See if we need to restock card receive buffers.
case SXG_SGL_DUMB:
{
struct sk_buff *skb;
- struct sxg_scatter_gather *SxgSgl = (struct sxg_scatter_gather *)ContextType;
+ struct sxg_scatter_gather *SxgSgl =
+ (struct sxg_scatter_gather *)ContextType;
/* Dumb-nic send. Command context is the dumb-nic SGL */
skb = (struct sk_buff *)ContextType;
0, 0);
printk("ASK:sxg_complete_slow_send: freeing an skb [%p]\n", skb);
ASSERT(adapter->Stats.XmtQLen);
- adapter->Stats.XmtQLen--; /* within XmtZeroLock */
+ adapter->Stats.XmtQLen--;/* within XmtZeroLock */
adapter->Stats.XmtOk++;
/*
- * Now drop the lock and complete the send back to
- * Microsoft. We need to drop the lock because
- * Microsoft can come back with a chimney send, which
- * results in a double trip in SxgTcpOuput
+ * Now drop the lock and complete the send
+ * back to Microsoft. We need to drop the lock
+ * because Microsoft can come back with a
+ * chimney send, which results in a double trip
+ * in SxgTcpOuput
*/
spin_unlock(&adapter->XmtZeroLock);
SXG_COMPLETE_DUMB_SEND(adapter, skb);
* adapter - A pointer to our adapter structure
* Event - Receive event
*
- * Return
- * skb
+ * Return - skb
*/
-static struct sk_buff *sxg_slow_receive(struct adapter_t *adapter, struct sxg_event *Event)
+static struct sk_buff *sxg_slow_receive(struct adapter_t *adapter,
+ struct sxg_event *Event)
{
struct sxg_rcv_data_buffer_hdr *RcvDataBufferHdr;
struct sk_buff *Packet;
goto drop;
}
- printk("ASK:sxg_slow_receive: event host handle %p\n", RcvDataBufferHdr);
+ printk("ASK:sxg_slow_receive:event host handle %p\n", RcvDataBufferHdr);
data = SXG_RECEIVE_DATA_LOCATION(RcvDataBufferHdr);
for (i = 0; i < 32; i++)
dptr += sprintf(dptr, "%02x ", (unsigned)data[i]);
printk("ASK:sxg_slow_receive: data %s\n", dstr);
- /* memcpy(SXG_RECEIVE_DATA_LOCATION(RcvDataBufferHdr), RcvDataBufferHdr->VirtualAddress, Event->Length);*/
+ /*
+ * memcpy(SXG_RECEIVE_DATA_LOCATION(RcvDataBufferHdr),
+ * RcvDataBufferHdr->VirtualAddress, Event->Length);
+ */
/* Change buffer state to UPSTREAM */
RcvDataBufferHdr->State = SXG_BUFFER_UPSTREAM;
}
#if XXXTODO /* VLAN stuff */
/* If there's a VLAN tag, extract it and validate it */
- if (((struct ether_header*) (SXG_RECEIVE_DATA_LOCATION(RcvDataBufferHdr)))->
- EtherType == ETHERTYPE_VLAN) {
+ if (((struct ether_header *)
+ (SXG_RECEIVE_DATA_LOCATION(RcvDataBufferHdr)))->EtherType
+ == ETHERTYPE_VLAN) {
if (SxgExtractVlanHeader(adapter, RcvDataBufferHdr, Event) !=
STATUS_SUCCESS) {
SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_NOISY,
Packet = RcvDataBufferHdr->SxgDumbRcvPacket;
SXG_ADJUST_RCV_PACKET(Packet, RcvDataBufferHdr, Event);
Packet->protocol = eth_type_trans(Packet, adapter->netdev);
- printk("ASK:sxg_slow_receive: protocol %x\n", (unsigned) Packet->protocol);
+ printk("ASK:sxg_slow_receive: protocol %x\n",
+ (unsigned) Packet->protocol);
SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_IMPORTANT, "DumbRcv",
RcvDataBufferHdr, Packet, Event->Length, 0);
* adapter - Adapter structure
* ErrorStatus - 4-byte receive error status
*
- * Return Value:
- * None
+ * Return Value : None
*/
static void sxg_process_rcv_error(struct adapter_t *adapter, u32 ErrorStatus)
{
* pether - Ethernet header
* length - Frame length
*
- * Return Value:
- * TRUE if the frame is to be allowed
+ * Return Value : TRUE if the frame is to be allowed
*/
-static bool sxg_mac_filter(struct adapter_t *adapter, struct ether_header *EtherHdr,
- ushort length)
+static bool sxg_mac_filter(struct adapter_t *adapter,
+ struct ether_header *EtherHdr, ushort length)
{
bool EqualAddr;
static int sxg_ioctl(struct net_device *dev, struct ifreq *rq, int cmd)
{
ASSERT(rq);
-/* DBG_ERROR("sxg: %s cmd[%x] rq[%p] dev[%p]\n", __func__, cmd, rq, dev); */
+/* DBG_ERROR("sxg: %s cmd[%x] rq[%p] dev[%p]\n", __func__, cmd, rq, dev);*/
switch (cmd) {
case SIOCSLICSETINTAGG:
{
-/* struct adapter_t *adapter = (struct adapter_t *) netdev_priv(dev); */
+ /* struct adapter_t *adapter = (struct adapter_t *)
+ * netdev_priv(dev);
+ */
u32 data[7];
u32 intagg;
if (copy_from_user(data, rq->ifr_data, 28)) {
- DBG_ERROR
- ("copy_from_user FAILED getting initial params\n");
+ DBG_ERROR("copy_from_user FAILED getting \
+ initial params\n");
return -EFAULT;
}
intagg = data[0];
}
default:
-/* DBG_ERROR("sxg: %s UNSUPPORTED[%x]\n", __func__, cmd); */
+ /* DBG_ERROR("sxg: %s UNSUPPORTED[%x]\n", __func__, cmd); */
return -EOPNOTSUPP;
}
return 0;
* sxg_send_packets - Send a skb packet
*
* Arguments:
- * skb - The packet to send
- * dev - Our linux net device that refs our adapter
+ * skb - The packet to send
+ * dev - Our linux net device that refs our adapter
*
* Return:
* 0 regardless of outcome XXXTODO refer to e1000 driver
/* reject & complete all the packets if they cant be sent */
if (status != STATUS_SUCCESS) {
#if XXXTODO
-/* sxg_send_packets_fail(adapter, skb, status); */
+ /* sxg_send_packets_fail(adapter, skb, status); */
#else
SXG_DROP_DUMB_SEND(adapter, skb);
adapter->stats.tx_dropped++;
* adapter - Pointer to our adapter structure
* skb - The packet to be sent
*
- * Return -
- * STATUS of send
+ * Return - STATUS of send
*/
static int sxg_transmit_packet(struct adapter_t *adapter, struct sk_buff *skb)
{
/* Call the common sxg_dumb_sgl routine to complete the send. */
sxg_dumb_sgl(pSgl, SxgSgl);
- /* Return success sxg_dumb_sgl (or something later) will complete it. */
+ /* Return success sxg_dumb_sgl (or something later) will complete it.*/
return (STATUS_SUCCESS);
}
* Return Value:
* None.
*/
-static void sxg_dumb_sgl(struct sxg_x64_sgl *pSgl, struct sxg_scatter_gather *SxgSgl)
+static void sxg_dumb_sgl(struct sxg_x64_sgl *pSgl,
+ struct sxg_scatter_gather *SxgSgl)
{
struct adapter_t *adapter = SxgSgl->adapter;
struct sk_buff *skb = SxgSgl->DumbPacket;
struct sxg_xmt_ring *XmtRing = &adapter->XmtRings[0];
struct sxg_ring_info *XmtRingInfo = &adapter->XmtRingZeroInfo;
struct sxg_cmd *XmtCmd = NULL;
-/* u32 Index = 0; */
+ /* u32 Index = 0; */
u32 DataLength = skb->len;
-/* unsigned int BufLen; */
-/* u32 SglOffset; */
+ /* unsigned int BufLen; */
+ /* u32 SglOffset; */
u64 phys_addr;
unsigned char*data;
int i;
* Fill in the command
* Copy out the first SGE to the command and adjust for offset
*/
- phys_addr =
- pci_map_single(adapter->pcidev, skb->data, skb->len,
+ phys_addr = pci_map_single(adapter->pcidev, skb->data, skb->len,
PCI_DMA_TODEVICE);
memset(XmtCmd, '\0', sizeof(*XmtCmd));
XmtCmd->Buffer.FirstSgeAddress = phys_addr;
adapter->Stats.XmtErrors++;
SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_IMPORTANT, "DumSGFal",
pSgl, SxgSgl, XmtRingInfo->Head, XmtRingInfo->Tail);
-
- SXG_COMPLETE_DUMB_SEND(adapter, SxgSgl->DumbPacket); /* SxgSgl->DumbPacket is the skb */
+ /* SxgSgl->DumbPacket is the skb */
+ SXG_COMPLETE_DUMB_SEND(adapter, SxgSgl->DumbPacket);
}
/*
WRITE_REG(HwRegs->MacConfig0, 0, TRUE);
/* Configure MAC */
- WRITE_REG(HwRegs->MacConfig1, (AXGMAC_CFG1_XMT_PAUSE | /* Allow sending of pause */
- AXGMAC_CFG1_XMT_EN | /* Enable XMT */
- AXGMAC_CFG1_RCV_PAUSE | /* Enable detection of pause */
- AXGMAC_CFG1_RCV_EN | /* Enable receive */
- AXGMAC_CFG1_SHORT_ASSERT | /* short frame detection */
- AXGMAC_CFG1_CHECK_LEN | /* Verify frame length */
- AXGMAC_CFG1_GEN_FCS | /* Generate FCS */
- AXGMAC_CFG1_PAD_64), /* Pad frames to 64 bytes */
- TRUE);
+ WRITE_REG(HwRegs->MacConfig1, (
+ /* Allow sending of pause */
+ AXGMAC_CFG1_XMT_PAUSE |
+ /* Enable XMT */
+ AXGMAC_CFG1_XMT_EN |
+ /* Enable detection of pause */
+ AXGMAC_CFG1_RCV_PAUSE |
+ /* Enable receive */
+ AXGMAC_CFG1_RCV_EN |
+ /* short frame detection */
+ AXGMAC_CFG1_SHORT_ASSERT |
+ /* Verify frame length */
+ AXGMAC_CFG1_CHECK_LEN |
+ /* Generate FCS */
+ AXGMAC_CFG1_GEN_FCS |
+ /* Pad frames to 64 bytes */
+ AXGMAC_CFG1_PAD_64),
+ TRUE);
/* Set AXGMAC max frame length if jumbo. Not needed for standard MTU */
if (adapter->JumboEnabled) {
/*
* Per information given by Aeluros, wait 100 ms after removing reset.
- * It's not enough to wait for the self-clearing reset bit in reg 0 to clear.
+ * It's not enough to wait for the self-clearing reset bit in reg 0 to
+ * clear.
*/
mdelay(100);
- /* Verify the PHY has come up by checking that the Reset bit has cleared. */
- status = sxg_read_mdio_reg(adapter, MIIM_DEV_PHY_PMA, /* PHY PMA/PMD module */
- PHY_PMA_CONTROL1, /* PMA/PMD control register */
- &Value);
- DBG_ERROR("After sxg_read_mdio_reg Value[%x] fail=%x\n", Value, (Value & PMA_CONTROL1_RESET));
+ /* Verify the PHY has come up by checking that the Reset bit has
+ * cleared.
+ */
+ status = sxg_read_mdio_reg(adapter,
+ MIIM_DEV_PHY_PMA, /* PHY PMA/PMD module */
+ PHY_PMA_CONTROL1, /* PMA/PMD control register */
+ &Value);
+ DBG_ERROR("After sxg_read_mdio_reg Value[%x] fail=%x\n", Value,
+ (Value & PMA_CONTROL1_RESET));
if (status != STATUS_SUCCESS)
return (STATUS_FAILURE);
if (Value & PMA_CONTROL1_RESET) /* reset complete if bit is 0 */
return (STATUS_FAILURE);
/* Enable the Link Alarm */
- status = sxg_write_mdio_reg(adapter, MIIM_DEV_PHY_PMA, /* PHY PMA/PMD module */
- LASI_CONTROL, /* LASI control register */
- LASI_CTL_LS_ALARM_ENABLE); /* enable link alarm bit */
+
+ /* MIIM_DEV_PHY_PMA - PHY PMA/PMD module
+ * LASI_CONTROL - LASI control register
+ * LASI_CTL_LS_ALARM_ENABLE - enable link alarm bit
+ */
+ status = sxg_write_mdio_reg(adapter, MIIM_DEV_PHY_PMA,
+ LASI_CONTROL,
+ LASI_CTL_LS_ALARM_ENABLE);
if (status != STATUS_SUCCESS)
return (STATUS_FAILURE);
/* XXXTODO - temporary - verify bit is set */
- status = sxg_read_mdio_reg(adapter, MIIM_DEV_PHY_PMA, /* PHY PMA/PMD module */
- LASI_CONTROL, /* LASI control register */
+
+ /* MIIM_DEV_PHY_PMA - PHY PMA/PMD module
+ * LASI_CONTROL - LASI control register
+ */
+ status = sxg_read_mdio_reg(adapter, MIIM_DEV_PHY_PMA,
+ LASI_CONTROL,
&Value);
+
if (status != STATUS_SUCCESS)
return (STATUS_FAILURE);
if (!(Value & LASI_CTL_LS_ALARM_ENABLE)) {
DBG_ERROR("ENTER %s\n", __func__);
- /* Read a register to identify the PHY type */
- status = sxg_read_mdio_reg(adapter, MIIM_DEV_PHY_PMA, /* PHY PMA/PMD module */
- 0xC205, /* PHY ID register (?) */
- &Value); /* XXXTODO - add def */
+ /* MIIM_DEV_PHY_PMA - PHY PMA/PMD module
+ * 0xC205 - PHY ID register (?)
+ * &Value - XXXTODO - add def
+ */
+ status = sxg_read_mdio_reg(adapter, MIIM_DEV_PHY_PMA,
+ 0xC205,
+ &Value);
if (status != STATUS_SUCCESS)
return (STATUS_FAILURE);
- if (Value == 0x0012) { /* 0x0012 == AEL2005C PHY(?) - XXXTODO - add def */
- DBG_ERROR
- ("AEL2005C PHY detected. Downloading PHY microcode.\n");
+ if (Value == 0x0012) {
+ /* 0x0012 == AEL2005C PHY(?) - XXXTODO - add def */
+ DBG_ERROR("AEL2005C PHY detected. Downloading PHY \
+ microcode.\n");
/* Initialize AEL2005C PHY and download PHY microcode */
for (p = PhyUcode; p->Addr != 0xFFFF; p++) {
/* if address == 0, data == sleep time in ms */
mdelay(p->Data);
} else {
- /* write the given data to the specified address */
- status = sxg_write_mdio_reg(adapter, MIIM_DEV_PHY_PMA, /* PHY PMA/PMD module */
- p->Addr, /* PHY address */
- p->Data); /* PHY data */
+ /* write the given data to the specified address */
+ status = sxg_write_mdio_reg(adapter,
+ MIIM_DEV_PHY_PMA,
+ /* PHY address */
+ p->Addr,
+ /* PHY data */
+ p->Data);
if (status != STATUS_SUCCESS)
return (STATUS_FAILURE);
}
mdelay(10);
/* Now clear the alarm by reading the LASI status register. */
- status = sxg_read_mdio_reg(adapter, MIIM_DEV_PHY_PMA, /* PHY PMA/PMD module */
- LASI_STATUS, /* LASI status register */
+ /* MIIM_DEV_PHY_PMA - PHY PMA/PMD module */
+ status = sxg_read_mdio_reg(adapter, MIIM_DEV_PHY_PMA,
+ /* LASI status register */
+ LASI_STATUS,
&Value);
if (status != STATUS_SUCCESS) {
DBG_ERROR("Error reading LASI Status MDIO register!\n");
sxg_link_state(adapter, SXG_LINK_DOWN);
-/* ASSERT(0); */
+ /* ASSERT(0); */
}
ASSERT(Value & LASI_STATUS_LS_ALARM);
*/
DBG_ERROR("SXG: sxg_link_event: Can't get here!\n");
DBG_ERROR("SXG: Link Status == 0x%08X.\n", Value);
-/* ASSERT(0); */
+ /* ASSERT(0); */
}
DBG_ERROR("EXIT %s\n", __func__);
* Per the Xenpak spec (and the IEEE 10Gb spec?), the link is up if
* the following 3 bits (from 3 different MDIO registers) are all true.
*/
- status = sxg_read_mdio_reg(adapter, MIIM_DEV_PHY_PMA, /* PHY PMA/PMD module */
- PHY_PMA_RCV_DET, /* PMA/PMD Receive Signal Detect register */
+
+ /* MIIM_DEV_PHY_PMA - PHY PMA/PMD module */
+ status = sxg_read_mdio_reg(adapter, MIIM_DEV_PHY_PMA,
+ /* PMA/PMD Receive Signal Detect register */
+ PHY_PMA_RCV_DET,
&Value);
if (status != STATUS_SUCCESS)
goto bad;
if (!(Value & PMA_RCV_DETECT))
return (SXG_LINK_DOWN);
- status = sxg_read_mdio_reg(adapter, MIIM_DEV_PHY_PCS, /* PHY PCS module */
- PHY_PCS_10G_STATUS1, /* PCS 10GBASE-R Status 1 register */
+ /* MIIM_DEV_PHY_PCS - PHY PCS module */
+ status = sxg_read_mdio_reg(adapter, MIIM_DEV_PHY_PCS,
+ /* PCS 10GBASE-R Status 1 register */
+ PHY_PCS_10G_STATUS1,
&Value);
if (status != STATUS_SUCCESS)
goto bad;
if (!(Value & PCS_10B_BLOCK_LOCK))
return (SXG_LINK_DOWN);
- status = sxg_read_mdio_reg(adapter, MIIM_DEV_PHY_XS, /* PHY XS module */
- PHY_XS_LANE_STATUS, /* XS Lane Status register */
+ status = sxg_read_mdio_reg(adapter, MIIM_DEV_PHY_XS,/* PHY XS module */
+ /* XS Lane Status register */
+ PHY_XS_LANE_STATUS,
&Value);
if (status != STATUS_SUCCESS)
goto bad;
return (SXG_LINK_UP);
bad:
- /* An error occurred reading an MDIO register. This shouldn't happen. */
+ /* An error occurred reading an MDIO register. This shouldn't happen. */
DBG_ERROR("Error reading an MDIO register!\n");
ASSERT(0);
return (SXG_LINK_DOWN);
* Return
* None
*/
-static void sxg_link_state(struct adapter_t *adapter, enum SXG_LINK_STATE LinkState)
+static void sxg_link_state(struct adapter_t *adapter,
+ enum SXG_LINK_STATE LinkState)
{
SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_IMPORTANT, "LnkINDCT",
adapter, LinkState, adapter->LinkState, adapter->State);
if (LinkState == adapter->LinkState) {
/* Nothing changed.. */
spin_unlock(&adapter->AdapterLock);
- DBG_ERROR("EXIT #0 %s\n", __func__);
+ DBG_ERROR("EXIT #0 %s. Link status = %d\n",
+ __func__, LinkState);
return;
}
/* Save the adapter state */
u32 DevAddr, u32 RegAddr, u32 Value)
{
struct sxg_hw_regs *HwRegs = adapter->HwRegs;
- u32 AddrOp; /* Address operation (written to MIIM field reg) */
- u32 WriteOp; /* Write operation (written to MIIM field reg) */
- u32 Cmd; /* Command (written to MIIM command reg) */
+ /* Address operation (written to MIIM field reg) */
+ u32 AddrOp;
+ /* Write operation (written to MIIM field reg) */
+ u32 WriteOp;
+ u32 Cmd;/* Command (written to MIIM command reg) */
u32 ValueRead;
u32 Timeout;
-/* DBG_ERROR("ENTER %s\n", __func__); */
+ /* DBG_ERROR("ENTER %s\n", __func__); */
SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_NOISY, "WrtMDIO",
adapter, 0, 0, 0);
}
} while (ValueRead & AXGMAC_AMIIM_INDC_BUSY);
-/* DBG_ERROR("EXIT %s\n", __func__); */
+ /* DBG_ERROR("EXIT %s\n", __func__); */
return (STATUS_SUCCESS);
}
* adapter - A pointer to our adapter structure
* DevAddr - MDIO device number being addressed
* RegAddr - register address for the specified MDIO device
- * pValue - pointer to where to put data read from the MDIO register
+ * pValue - pointer to where to put data read from the MDIO register
*
* Return
* status
u32 DevAddr, u32 RegAddr, u32 *pValue)
{
struct sxg_hw_regs *HwRegs = adapter->HwRegs;
- u32 AddrOp; /* Address operation (written to MIIM field reg) */
- u32 ReadOp; /* Read operation (written to MIIM field reg) */
- u32 Cmd; /* Command (written to MIIM command reg) */
+ u32 AddrOp; /* Address operation (written to MIIM field reg) */
+ u32 ReadOp; /* Read operation (written to MIIM field reg) */
+ u32 Cmd; /* Command (written to MIIM command reg) */
u32 ValueRead;
u32 Timeout;
SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_NOISY, "WrtMDIO",
adapter, 0, 0, 0);
- DBG_ERROR("ENTER %s\n", __FUNCTION__);
+ DBG_ERROR("ENTER %s\n", __FUNCTION__);
/* Ensure values don't exceed field width */
DevAddr &= 0x001F; /* 5-bit field */
READ_REG(HwRegs->MacAmiimField, *pValue);
*pValue &= 0xFFFF; /* data is in the lower 16 bits */
- DBG_ERROR("EXIT %s\n", __FUNCTION__);
+ DBG_ERROR("EXIT %s\n", __FUNCTION__);
return (STATUS_SUCCESS);
}
* Functions to obtain the CRC corresponding to the destination mac address.
* This is a standard ethernet CRC in that it is a 32-bit, reflected CRC using
* the polynomial:
- * x^32 + x^26 + x^23 + x^22 + x^16 + x^12 + x^11 + x^10 + x^8 + x^7 + x^5 + x^4 + x^2 + x^1.
+ * x^32 + x^26 + x^23 + x^22 + x^16 + x^12 + x^11 + x^10 + x^8 + x^7 + x^5
+ * + x^4 + x^2 + x^1.
*
- * After the CRC for the 6 bytes is generated (but before the value is complemented),
- * we must then transpose the value and return bits 30-23.
+ * After the CRC for the 6 bytes is generated (but before the value is
+ * complemented), we must then transpose the value and return bits 30-23.
*/
-static u32 sxg_crc_table[256]; /* Table of CRC's for all possible byte values */
+static u32 sxg_crc_table[256];/* Table of CRC's for all possible byte values */
+static u32 sxg_crc_init; /* Is table initialized */
-/*
- * Contruct the CRC32 table
- */
+/* Contruct the CRC32 table */
static void sxg_mcast_init_crc32(void)
{
- u32 c; /* CRC shit reg */
- u32 e = 0; /* Poly X-or pattern */
- int i; /* counter */
+ u32 c; /* CRC shit reg */
+ u32 e = 0; /* Poly X-or pattern */
+ int i; /* counter */
int k; /* byte being shifted into crc */
static int p[] = { 0, 1, 2, 4, 5, 7, 8, 10, 11, 12, 16, 22, 23, 26 };
}
}
-static u32 sxg_crc_init; /* Is table initialized */
/*
* Return the MAC hast as described above.
*/
if (adapter->MacFilter & (MAC_ALLMCAST | MAC_PROMISC)) {
/*
- * Turn on all multicast addresses. We have to do this for promiscuous
- * mode as well as ALLMCAST mode. It saves the Microcode from having
- * to keep state about the MAC configuration.
+ * Turn on all multicast addresses. We have to do this for
+ * promiscuous mode as well as ALLMCAST mode. It saves the
+ * Microcode from having keep state about the MAC configuration
+ */
+ /* DBG_ERROR("sxg: %s macopts = MAC_ALLMCAST | MAC_PROMISC\n
+ * SLUT MODE!!!\n",__func__);
*/
-/* DBG_ERROR("sxg: %s macopts = MAC_ALLMCAST | MAC_PROMISC\n SLUT MODE!!!\n",__func__); */
WRITE_REG(sxg_regs->McastLow, 0xFFFFFFFF, FLUSH);
WRITE_REG(sxg_regs->McastHigh, 0xFFFFFFFF, FLUSH);
-/* DBG_ERROR("%s (%s) WRITE to slic_regs slic_mcastlow&high 0xFFFFFFFF\n",__func__, adapter->netdev->name); */
+ /* DBG_ERROR("%s (%s) WRITE to slic_regs slic_mcastlow&high \
+ * 0xFFFFFFFF\n",__func__, adapter->netdev->name);
+ */
} else {
/*
- * Commit our multicast mast to the SLIC by writing to the multicast
- * address mask registers
+ * Commit our multicast mast to the SLIC by writing to the
+ * multicast address mask registers
*/
DBG_ERROR("%s (%s) WRITE mcastlow[%lx] mcasthigh[%lx]\n",
__func__, adapter->netdev->name,
}
/*
- * sxg_allocate_rcvblock_complete - Complete a receive descriptor block allocation
+ * sxg_allocate_rcvblock_complete - Complete a receive descriptor
+ * block allocation
*
* Arguments -
* adapter - A pointer to our adapter structure
RcvDataBufferHdr =
(struct sxg_rcv_data_buffer_hdr*) (RcvDataBuffer +
- SXG_RCV_DATA_BUFFER_HDR_OFFSET
- (BufferSize));
+ SXG_RCV_DATA_BUFFER_HDR_OFFSET
+ (BufferSize));
RcvDataBufferHdr->VirtualAddress = RcvDataBuffer;
- RcvDataBufferHdr->State = SXG_BUFFER_UPSTREAM; /* For FREE macro assertion */
+ /* For FREE macro assertion */
+ RcvDataBufferHdr->State = SXG_BUFFER_UPSTREAM;
RcvDataBufferHdr->Size =
SXG_RCV_BUFFER_DATA_SIZE(BufferSize);
SXG_ALLOCATE_RCV_PACKET(adapter, RcvDataBufferHdr);
/* ASK hardcoded 2048 */
- RcvDataBufferHdr->PhysicalAddress = pci_map_single(adapter->pcidev,
+ RcvDataBufferHdr->PhysicalAddress =
+ pci_map_single(adapter->pcidev,
RcvDataBufferHdr->SxgDumbRcvPacket->data,
2048,
PCI_DMA_FROMDEVICE);
InsertTailList(&adapter->AllRcvBlocks, &RcvBlockHdr->AllList);
spin_unlock(&adapter->RcvQLock);
- /* Now free the contained receive data buffers that we initialized above */
+ /* Now free the contained receive data buffers that we
+ * initialized above */
RcvDataBuffer = RcvBlock;
for (i = 0, Paddr = PhysicalAddress;
i < SXG_RCV_DESCRIPTORS_PER_BLOCK;
i++, Paddr += BufferSize, RcvDataBuffer += BufferSize) {
- RcvDataBufferHdr = (struct sxg_rcv_data_buffer_hdr*) (RcvDataBuffer +
- SXG_RCV_DATA_BUFFER_HDR_OFFSET
+ RcvDataBufferHdr = (struct sxg_rcv_data_buffer_hdr*)
+ (RcvDataBuffer + SXG_RCV_DATA_BUFFER_HDR_OFFSET
(BufferSize));
spin_lock(&adapter->RcvQLock);
SXG_FREE_RCV_DATA_BUFFER(adapter, RcvDataBufferHdr);
SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_NOISY, "XAlRBlk",
adapter, RcvBlock, Length, 0);
return;
- fail:
+fail:
/* Free any allocated resources */
if (RcvBlock) {
RcvDataBuffer = RcvBlock;
i++, RcvDataBuffer += BufferSize) {
RcvDataBufferHdr =
(struct sxg_rcv_data_buffer_hdr *) (RcvDataBuffer +
- SXG_RCV_DATA_BUFFER_HDR_OFFSET
+ SXG_RCV_DATA_BUFFER_HDR_OFFSET
(BufferSize));
SXG_FREE_RCV_PACKET(RcvDataBufferHdr);
}
spin_lock(&adapter->SglQLock);
adapter->AllSglBufferCount++;
memset(SxgSgl, 0, sizeof(struct sxg_scatter_gather));
- SxgSgl->PhysicalAddress = PhysicalAddress; /* *PhysicalAddress; */
- SxgSgl->adapter = adapter; /* Initialize backpointer once */
+ /* *PhysicalAddress; */
+ SxgSgl->PhysicalAddress = PhysicalAddress;
+ /* Initialize backpointer once */
+ SxgSgl->adapter = adapter;
InsertTailList(&adapter->AllSglBuffers, &SxgSgl->AllList);
spin_unlock(&adapter->SglQLock);
SxgSgl->State = SXG_BUFFER_BUSY;
static void sxg_adapter_set_hwaddr(struct adapter_t *adapter)
{
-/*
- * DBG_ERROR ("%s ENTER card->config_set[%x] port[%d] physport[%d] funct#[%d]\n", __func__,
- * card->config_set, adapter->port, adapter->physport, adapter->functionnumber);
- * sxg_dbg_macaddrs(adapter);
- */
+ /*
+ * DBG_ERROR ("%s ENTER card->config_set[%x] port[%d] physport[%d] \
+ * funct#[%d]\n", __func__, card->config_set,
+ * adapter->port, adapter->physport, adapter->functionnumber);
+ *
+ * sxg_dbg_macaddrs(adapter);
+ */
+ memcpy(adapter->macaddr, temp_mac_address,
+ sizeof(struct sxg_config_mac));
+ /* DBG_ERROR ("%s AFTER copying from config.macinfo into currmacaddr\n",
+ * __FUNCTION__);
+ */
+
+ /* sxg_dbg_macaddrs(adapter); */
- memcpy(adapter->macaddr, temp_mac_address, sizeof(struct sxg_config_mac));
-/* DBG_ERROR ("%s AFTER copying from config.macinfo into currmacaddr\n", __func__); */
-/* sxg_dbg_macaddrs(adapter); */
if (!(adapter->currmacaddr[0] ||
adapter->currmacaddr[1] ||
adapter->currmacaddr[2] ||
memcpy(adapter->netdev->dev_addr, adapter->currmacaddr, 6);
memcpy(adapter->netdev->perm_addr, adapter->currmacaddr, 6);
}
-/* DBG_ERROR ("%s EXIT port %d\n", __func__, adapter->port); */
+ /* DBG_ERROR ("%s EXIT port %d\n", __func__, adapter->port); */
sxg_dbg_macaddrs(adapter);
}
* status
*/
static int sxg_fill_descriptor_block(struct adapter_t *adapter,
- struct sxg_rcv_descriptor_block_hdr
- *RcvDescriptorBlockHdr)
+ struct sxg_rcv_descriptor_block_hdr *RcvDescriptorBlockHdr)
{
u32 i;
struct sxg_ring_info *RcvRingInfo = &adapter->RcvRingZeroInfo;
RcvRingInfo, RingDescriptorCmd, RcvDescriptorBlockHdr);
ASSERT(RingDescriptorCmd);
RcvDescriptorBlockHdr->State = SXG_BUFFER_ONCARD;
- RcvDescriptorBlock =
- (struct sxg_rcv_descriptor_block *) RcvDescriptorBlockHdr->VirtualAddress;
+ RcvDescriptorBlock = (struct sxg_rcv_descriptor_block *)
+ RcvDescriptorBlockHdr->VirtualAddress;
/* Fill in the descriptor block */
for (i = 0; i < SXG_RCV_DESCRIPTORS_PER_BLOCK; i++) {
SXG_REINIATIALIZE_PACKET(RcvDataBufferHdr->SxgDumbRcvPacket);
RcvDataBufferHdr->State = SXG_BUFFER_ONCARD;
RcvDescriptorBlock->Descriptors[i].VirtualAddress =
- (void *)RcvDataBufferHdr;
+ (void *)RcvDataBufferHdr;
if (i == 0)
- printk("ASK:sxg_fill_descriptor_block: first virt address %p\n", RcvDataBufferHdr);
+ printk("ASK:sxg_fill_descriptor_block: first virt \
+ address %p\n", RcvDataBufferHdr);
if (i == (SXG_RCV_DESCRIPTORS_PER_BLOCK - 1))
- printk("ASK:sxg_fill_descriptor_block: last virt address %p\n", RcvDataBufferHdr);
+ printk("ASK:sxg_fill_descriptor_block: last virt \
+ address %p\n", RcvDataBufferHdr);
RcvDescriptorBlock->Descriptors[i].PhysicalAddress =
RcvDataBufferHdr->PhysicalAddress;
ReceiveBufferSize),
SXG_BUFFER_TYPE_RCV);
}
- printk("ASK:sxg_stock_rcv_buffers: RcvBuffersOnCard %d\n", adapter->RcvBuffersOnCard);
+ printk("ASK:sxg_stock_rcv_buffers: RcvBuffersOnCard %d\n",
+ adapter->RcvBuffersOnCard);
/* Now grab the RcvQLock lock and proceed */
spin_lock(&adapter->RcvQLock);
while (adapter->RcvBuffersOnCard < SXG_RCV_DATA_BUFFERS) {
* header. The card will be restocked later via the
* RcvBuffersOnCard test
*/
- if (sxg_fill_descriptor_block(adapter, RcvDescriptorBlockHdr) ==
- STATUS_FAILURE) {
+ if (sxg_fill_descriptor_block(adapter,
+ RcvDescriptorBlockHdr) == STATUS_FAILURE)
SXG_FREE_RCV_DESCRIPTOR_BLOCK(adapter,
RcvDescriptorBlockHdr);
- }
}
spin_unlock(&adapter->RcvQLock);
SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_NOISY, "XCRBlks",
.suspend = sxgpm_suspend,
.resume = sxgpm_resume,
#endif
-/* .shutdown = slic_shutdown, MOOK_INVESTIGATE */
+ /* .shutdown = slic_shutdown, MOOK_INVESTIGATE */
};
static int __init sxg_module_init(void)
u64 DumbXmtUcastBytes; /* OID_GEN_DIRECTED_BYTES_XMIT */
u64 DumbXmtMcastBytes; /* OID_GEN_MULTICAST_BYTES_XMIT */
u64 DumbXmtBcastBytes; /* OID_GEN_BROADCAST_BYTES_XMIT */
- u64 XmtErrors; /* OID_GEN_XMIT_ERROR */
+ u64 XmtErrors; /* OID_GEN_XMIT_ERROR */
u64 XmtDiscards; /* OID_GEN_XMIT_DISCARDS */
- u64 XmtOk; /* OID_GEN_XMIT_OK */
- u64 XmtQLen; /* OID_GEN_TRANSMIT_QUEUE_LENGTH */
+ u64 XmtOk; /* OID_GEN_XMIT_OK */
+ u64 XmtQLen; /* OID_GEN_TRANSMIT_QUEUE_LENGTH */
u64 XmtZeroFull; /* Transmit ring zero full */
/* Rcv */
- u32 RcvNBL; /* Offload recieve NBL count */
+ u32 RcvNBL; /* Offload recieve NBL count */
u64 DumbRcvBytes; /* dumbnic recv bytes */
u64 DumbRcvUcastBytes; /* OID_GEN_DIRECTED_BYTES_RCV */
u64 DumbRcvMcastBytes; /* OID_GEN_MULTICAST_BYTES_RCV */
/* DUMB-NIC Send path definitions */
-#define SXG_COMPLETE_DUMB_SEND(_pAdapt, _skb) { \
- ASSERT(_skb); \
- dev_kfree_skb_irq(_skb); \
+#define SXG_COMPLETE_DUMB_SEND(_pAdapt, _skb) { \
+ ASSERT(_skb); \
+ dev_kfree_skb_irq(_skb); \
}
-#define SXG_DROP_DUMB_SEND(_pAdapt, _skb) { \
- ASSERT(_skb); \
- dev_kfree_skb(_skb); \
+#define SXG_DROP_DUMB_SEND(_pAdapt, _skb) { \
+ ASSERT(_skb); \
+ dev_kfree_skb(_skb); \
}
/*
/* Indications array size */
#define SXG_RCV_ARRAYSIZE 64
-#define SXG_ALLOCATE_RCV_PACKET(_pAdapt, _RcvDataBufferHdr) { \
- struct sk_buff * skb; \
- skb = netdev_alloc_skb(_pAdapt->netdev, 2048); \
- if (skb) { \
- (_RcvDataBufferHdr)->skb = skb; \
- skb->next = NULL; \
- } else { \
- (_RcvDataBufferHdr)->skb = NULL; \
- } \
+#define SXG_ALLOCATE_RCV_PACKET(_pAdapt, _RcvDataBufferHdr) { \
+ struct sk_buff * skb; \
+ skb = netdev_alloc_skb(_pAdapt->netdev, 2048); \
+ if (skb) { \
+ (_RcvDataBufferHdr)->skb = skb; \
+ skb->next = NULL; \
+ } else { \
+ (_RcvDataBufferHdr)->skb = NULL; \
+ } \
}
-#define SXG_FREE_RCV_PACKET(_RcvDataBufferHdr) { \
- if((_RcvDataBufferHdr)->skb) { \
- dev_kfree_skb((_RcvDataBufferHdr)->skb); \
- } \
+#define SXG_FREE_RCV_PACKET(_RcvDataBufferHdr) { \
+ if((_RcvDataBufferHdr)->skb) { \
+ dev_kfree_skb((_RcvDataBufferHdr)->skb); \
+ } \
}
/*
* If we fill up our array of packet pointers, then indicate this
* block up now and start on a new one.
*/
-#define SXG_ADD_RCV_PACKET(_pAdapt, _Packet, _PrevPacket, _IndicationList, _NumPackets) { \
- (_IndicationList)[_NumPackets] = (_Packet); \
- (_NumPackets)++; \
- if((_NumPackets) == SXG_RCV_ARRAYSIZE) { \
- SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_NOISY, "IndicRcv", \
- (_NumPackets), 0, 0, 0); \
- netif_rx((_IndicationList),(_NumPackets)); \
- (_NumPackets) = 0; \
- } \
+#define SXG_ADD_RCV_PACKET(_pAdapt, _Packet, _PrevPacket, _IndicationList, \
+ _NumPackets) { \
+ (_IndicationList)[_NumPackets] = (_Packet); \
+ (_NumPackets)++; \
+ if((_NumPackets) == SXG_RCV_ARRAYSIZE) { \
+ SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_NOISY, "IndicRcv", \
+ (_NumPackets), 0, 0, 0); \
+ netif_rx((_IndicationList),(_NumPackets)); \
+ (_NumPackets) = 0; \
+ } \
}
-#define SXG_INDICATE_PACKETS(_pAdapt, _IndicationList, _NumPackets) { \
- if(_NumPackets) { \
- SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_NOISY, "IndicRcv", \
- (_NumPackets), 0, 0, 0); \
- netif_rx((_IndicationList),(_NumPackets)); \
- (_NumPackets) = 0; \
- } \
+#define SXG_INDICATE_PACKETS(_pAdapt, _IndicationList, _NumPackets) { \
+ if(_NumPackets) { \
+ SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_NOISY, "IndicRcv", \
+ (_NumPackets), 0, 0, 0); \
+ netif_rx((_IndicationList),(_NumPackets)); \
+ (_NumPackets) = 0; \
+ } \
}
-#define SXG_REINIATIALIZE_PACKET(_Packet) \
- {} /*_NdisReinitializePacket(_Packet)*/ /* this is not necessary with an skb */
+#define SXG_REINIATIALIZE_PACKET(_Packet) \
+ {} /*_NdisReinitializePacket(_Packet)*/
+ /* this is not necessary with an skb */
/* Definitions to initialize Dumb-nic Receive NBLs */
-#define SXG_RCV_PACKET_BUFFER_HDR(_Packet) (((struct sxg_rcv_nbl_reserved *)((_Packet)->MiniportReservedEx))->RcvDataBufferHdr)
+#define SXG_RCV_PACKET_BUFFER_HDR(_Packet) (((struct sxg_rcv_nbl_reserved *)\
+ ((_Packet)->MiniportReservedEx))->RcvDataBufferHdr)
-#define SXG_RCV_SET_CHECKSUM_INFO(_Packet, _Cpi) \
- NDIS_PER_PACKET_INFO_FROM_PACKET((_Packet), TcpIpChecksumPacketInfo) = (PVOID)(_Cpi)
+#define SXG_RCV_SET_CHECKSUM_INFO(_Packet, _Cpi) \
+ NDIS_PER_PACKET_INFO_FROM_PACKET((_Packet), \
+ TcpIpChecksumPacketInfo) = (PVOID)(_Cpi)
#define SXG_RCV_SET_TOEPLITZ(_Packet, _Toeplitz, _Type, _Function) { \
- NDIS_PACKET_SET_HASH_VALUE((_Packet), (_Toeplitz)); \
- NDIS_PACKET_SET_HASH_TYPE((_Packet), (_Type)); \
- NDIS_PACKET_SET_HASH_FUNCTION((_Packet), (_Function)); \
+ NDIS_PACKET_SET_HASH_VALUE((_Packet), (_Toeplitz)); \
+ NDIS_PACKET_SET_HASH_TYPE((_Packet), (_Type)); \
+ NDIS_PACKET_SET_HASH_FUNCTION((_Packet), (_Function)); \
}
-#define SXG_RCV_SET_VLAN_INFO(_Packet, _VlanId, _Priority) { \
- NDIS_PACKET_8021Q_INFO _Packet8021qInfo; \
- _Packet8021qInfo.TagHeader.VlanId = (_VlanId); \
- _Packet8021qInfo.TagHeader.UserPriority = (_Priority); \
+#define SXG_RCV_SET_VLAN_INFO(_Packet, _VlanId, _Priority) { \
+ NDIS_PACKET_8021Q_INFO _Packet8021qInfo; \
+ _Packet8021qInfo.TagHeader.VlanId = (_VlanId); \
+ _Packet8021qInfo.TagHeader.UserPriority = (_Priority); \
NDIS_PER_PACKET_INFO_FROM_PACKET((_Packet), Ieee8021QNetBufferListInfo) = \
- _Packet8021qInfo.Value; \
+ _Packet8021qInfo.Value; \
}
-#define SXG_ADJUST_RCV_PACKET(_Packet, _RcvDataBufferHdr, _Event) { \
- SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_NOISY, "DumbRcv", \
- (_RcvDataBufferHdr), (_Packet), \
- (_Event)->Status, 0); \
- ASSERT((_Event)->Length <= (_RcvDataBufferHdr)->Size); \
+#define SXG_ADJUST_RCV_PACKET(_Packet, _RcvDataBufferHdr, _Event) { \
+ SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_NOISY, "DumbRcv", \
+ (_RcvDataBufferHdr), (_Packet), \
+ (_Event)->Status, 0); \
+ ASSERT((_Event)->Length <= (_RcvDataBufferHdr)->Size); \
skb_put(Packet, (_Event)->Length); \
}
* Macros to free a receive data buffer and receive data descriptor block
* NOTE - Lock must be held with RCV macros
*/
-#define SXG_GET_RCV_DATA_BUFFER(_pAdapt, _Hdr) { \
- struct list_entry *_ple; \
- _Hdr = NULL; \
- if((_pAdapt)->FreeRcvBufferCount) { \
- ASSERT(!(IsListEmpty(&(_pAdapt)->FreeRcvBuffers))); \
- _ple = RemoveHeadList(&(_pAdapt)->FreeRcvBuffers); \
- (_Hdr) = container_of(_ple, struct sxg_rcv_data_buffer_hdr, FreeList); \
- (_pAdapt)->FreeRcvBufferCount--; \
- ASSERT((_Hdr)->State == SXG_BUFFER_FREE); \
- } \
+#define SXG_GET_RCV_DATA_BUFFER(_pAdapt, _Hdr) { \
+ struct list_entry *_ple; \
+ _Hdr = NULL; \
+ if((_pAdapt)->FreeRcvBufferCount) { \
+ ASSERT(!(IsListEmpty(&(_pAdapt)->FreeRcvBuffers))); \
+ _ple = RemoveHeadList(&(_pAdapt)->FreeRcvBuffers); \
+ (_Hdr) = container_of(_ple, struct sxg_rcv_data_buffer_hdr, \
+ FreeList); \
+ (_pAdapt)->FreeRcvBufferCount--; \
+ ASSERT((_Hdr)->State == SXG_BUFFER_FREE); \
+ } \
}
-#define SXG_FREE_RCV_DATA_BUFFER(_pAdapt, _Hdr) { \
- SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_NOISY, "RtnDHdr", \
- (_Hdr), (_pAdapt)->FreeRcvBufferCount, \
- (_Hdr)->State, (_Hdr)->VirtualAddress); \
-/* SXG_RESTORE_MDL_OFFSET(_Hdr); */ \
- (_pAdapt)->FreeRcvBufferCount++; \
- ASSERT(((_pAdapt)->AllRcvBlockCount * SXG_RCV_DESCRIPTORS_PER_BLOCK) >= (_pAdapt)->FreeRcvBufferCount); \
- ASSERT((_Hdr)->State != SXG_BUFFER_FREE); \
- (_Hdr)->State = SXG_BUFFER_FREE; \
- InsertTailList(&(_pAdapt)->FreeRcvBuffers, &((_Hdr)->FreeList)); \
+#define SXG_FREE_RCV_DATA_BUFFER(_pAdapt, _Hdr) { \
+ SXG_TRACE(TRACE_SXG, SxgTraceBuffer, TRACE_NOISY, "RtnDHdr", \
+ (_Hdr), (_pAdapt)->FreeRcvBufferCount, \
+ (_Hdr)->State, (_Hdr)->VirtualAddress); \
+/* SXG_RESTORE_MDL_OFFSET(_Hdr); */ \
+ (_pAdapt)->FreeRcvBufferCount++; \
+ ASSERT(((_pAdapt)->AllRcvBlockCount * SXG_RCV_DESCRIPTORS_PER_BLOCK) \
+ >= (_pAdapt)->FreeRcvBufferCount); \
+ ASSERT((_Hdr)->State != SXG_BUFFER_FREE); \
+ (_Hdr)->State = SXG_BUFFER_FREE; \
+ InsertTailList(&(_pAdapt)->FreeRcvBuffers, &((_Hdr)->FreeList)); \
}
-#define SXG_FREE_RCV_DESCRIPTOR_BLOCK(_pAdapt, _Hdr) { \
- ASSERT((_Hdr)->State != SXG_BUFFER_FREE); \
- (_Hdr)->State = SXG_BUFFER_FREE; \
- (_pAdapt)->FreeRcvBlockCount++; \
+#define SXG_FREE_RCV_DESCRIPTOR_BLOCK(_pAdapt, _Hdr) { \
+ ASSERT((_Hdr)->State != SXG_BUFFER_FREE); \
+ (_Hdr)->State = SXG_BUFFER_FREE; \
+ (_pAdapt)->FreeRcvBlockCount++; \
ASSERT((_pAdapt)->AllRcvBlockCount >= (_pAdapt)->FreeRcvBlockCount); \
- InsertTailList(&(_pAdapt)->FreeRcvBlocks, &(_Hdr)->FreeList); \
+ InsertTailList(&(_pAdapt)->FreeRcvBlocks, &(_Hdr)->FreeList); \
}
/* SGL macros */
-#define SXG_FREE_SGL_BUFFER(_pAdapt, _Sgl, _NB) { \
- spin_lock(&(_pAdapt)->SglQLock); \
- (_pAdapt)->FreeSglBufferCount++; \
- ASSERT((_pAdapt)->AllSglBufferCount >= (_pAdapt)->FreeSglBufferCount);\
- ASSERT(!((_Sgl)->State & SXG_BUFFER_FREE)); \
- (_Sgl)->State = SXG_BUFFER_FREE; \
- InsertTailList(&(_pAdapt)->FreeSglBuffers, &(_Sgl)->FreeList); \
- spin_unlock(&(_pAdapt)->SglQLock); \
+#define SXG_FREE_SGL_BUFFER(_pAdapt, _Sgl, _NB) { \
+ spin_lock(&(_pAdapt)->SglQLock); \
+ (_pAdapt)->FreeSglBufferCount++; \
+ ASSERT((_pAdapt)->AllSglBufferCount >= (_pAdapt)->FreeSglBufferCount); \
+ ASSERT(!((_Sgl)->State & SXG_BUFFER_FREE)); \
+ (_Sgl)->State = SXG_BUFFER_FREE; \
+ InsertTailList(&(_pAdapt)->FreeSglBuffers, &(_Sgl)->FreeList); \
+ spin_unlock(&(_pAdapt)->SglQLock); \
}
/*
* and not grabbing it avoids a possible double-trip.
*/
#define SXG_GET_SGL_BUFFER(_pAdapt, _Sgl) { \
- struct list_entry *_ple; \
+ struct list_entry *_ple; \
if ((_pAdapt->FreeSglBufferCount < SXG_MIN_SGL_BUFFERS) && \
(_pAdapt->AllSglBufferCount < SXG_MAX_SGL_BUFFERS) && \
(_pAdapt->AllocationsPending == 0)) { \
if((_pAdapt)->FreeSglBufferCount) { \
ASSERT(!(IsListEmpty(&(_pAdapt)->FreeSglBuffers))); \
_ple = RemoveHeadList(&(_pAdapt)->FreeSglBuffers); \
- (_Sgl) = container_of(_ple, struct sxg_scatter_gather, FreeList); \
+ (_Sgl) = container_of(_ple, struct sxg_scatter_gather, \
+ FreeList); \
(_pAdapt)->FreeSglBufferCount--; \
ASSERT((_Sgl)->State == SXG_BUFFER_FREE); \
(_Sgl)->State = SXG_BUFFER_BUSY; \
* Linked list of multicast addresses.
*/
struct sxg_multicast_address {
- unsigned char Address[6];
+ unsigned char Address[6];
struct sxg_multicast_address *Next;
};
#define SXG_FAST_SEND_BUFFER 1
#define SXG_RECEIVE_BUFFER 2
-#define SXG_INIT_BUFFER(_Buffer, _Type) { \
- (_Buffer)->Type = (_Type); \
- if((_Type) == SXG_RECEIVE_BUFFER) { \
- (_Buffer)->Direction = 0; \
- } else { \
+#define SXG_INIT_BUFFER(_Buffer, _Type) { \
+ (_Buffer)->Type = (_Type); \
+ if((_Type) == SXG_RECEIVE_BUFFER) { \
+ (_Buffer)->Direction = 0; \
+ } else { \
(_Buffer)->Direction = NDIS_SG_LIST_WRITE_TO_DEVICE; \
- } \
- (_Buffer)->Bytes = 0; \
- (_Buffer)->Head = NULL; \
- (_Buffer)->Tail = NULL; \
+ } \
+ (_Buffer)->Bytes = 0; \
+ (_Buffer)->Head = NULL; \
+ (_Buffer)->Tail = NULL; \
}
-#define SXG_RSS_CPU_COUNT(_pAdapt) \
+#define SXG_RSS_CPU_COUNT(_pAdapt) \
((_pAdapt)->RssEnabled ? NR_CPUS : 1)
/* DRIVER and ADAPTER structures */
/* Microcode file selection codes */
enum SXG_UCODE_SEL {
- SXG_UCODE_SAHARA, /* Sahara ucode */
- SXG_UCODE_SDIAGCPU, /* Sahara CPU diagnostic ucode */
- SXG_UCODE_SDIAGSYS /* Sahara system diagnostic ucode */
+ SXG_UCODE_SAHARA, /* Sahara ucode */
+ SXG_UCODE_SDIAGCPU, /* Sahara CPU diagnostic ucode */
+ SXG_UCODE_SDIAGSYS /* Sahara system diagnostic ucode */
};
/* This probably lives in a proto.h file. Move later */
#define SXG_MULTICAST_PACKET(_pether) ((_pether)->ether_dhost[0] & 0x01)
-#define SXG_BROADCAST_PACKET(_pether) ((*(u32 *)(_pether)->ether_dhost == 0xFFFFFFFF) && \
- (*(u16 *)&(_pether)->ether_dhost[4] == 0xFFFF))
+#define SXG_BROADCAST_PACKET(_pether) \
+ ((*(u32 *)(_pether)->ether_dhost == 0xFFFFFFFF) && \
+ (*(u16 *)&(_pether)->ether_dhost[4] == 0xFFFF))
/* For DbgPrints */
#define SXG_ID DPFLTR_IHVNETWORK_ID
* Mojave supports 16K, Oasis supports 16K-1, so
* just set this at 15K, shouldnt make that much of a diff.
*/
-#define DUMP_BUF_SIZE 0x3C00
+#define DUMP_BUF_SIZE 0x3C00
#endif
#define MIN(a, b) ((u32)(a) < (u32)(b) ? (a) : (b))
#define MAX(a, b) ((u32)(a) > (u32)(b) ? (a) : (b))
struct mcast_address {
- unsigned char address[6];
+ unsigned char address[6];
struct mcast_address *next;
};
-#define CARD_DOWN 0x00000000
-#define CARD_UP 0x00000001
-#define CARD_FAIL 0x00000002
-#define CARD_DIAG 0x00000003
-#define CARD_SLEEP 0x00000004
+#define CARD_DOWN 0x00000000
+#define CARD_UP 0x00000001
+#define CARD_FAIL 0x00000002
+#define CARD_DIAG 0x00000003
+#define CARD_SLEEP 0x00000004
-#define ADAPT_DOWN 0x00
-#define ADAPT_UP 0x01
-#define ADAPT_FAIL 0x02
-#define ADAPT_RESET 0x03
-#define ADAPT_SLEEP 0x04
+#define ADAPT_DOWN 0x00
+#define ADAPT_UP 0x01
+#define ADAPT_FAIL 0x02
+#define ADAPT_RESET 0x03
+#define ADAPT_SLEEP 0x04
#define ADAPT_FLAGS_BOOTTIME 0x0001
#define ADAPT_FLAGS_IS64BIT 0x0002
#define ADAPT_FLAGS_STATS_TIMER_SET 0x0080
#define ADAPT_FLAGS_RESET_TIMER_SET 0x0100
-#define LINK_DOWN 0x00
-#define LINK_CONFIG 0x01
-#define LINK_UP 0x02
+#define LINK_DOWN 0x00
+#define LINK_CONFIG 0x01
+#define LINK_UP 0x02
-#define LINK_10MB 0x00
-#define LINK_100MB 0x01
-#define LINK_AUTOSPEED 0x02
-#define LINK_1000MB 0x03
-#define LINK_10000MB 0x04
+#define LINK_10MB 0x00
+#define LINK_100MB 0x01
+#define LINK_AUTOSPEED 0x02
+#define LINK_1000MB 0x03
+#define LINK_10000MB 0x04
-#define LINK_HALFD 0x00
-#define LINK_FULLD 0x01
-#define LINK_AUTOD 0x02
+#define LINK_HALFD 0x00
+#define LINK_FULLD 0x01
+#define LINK_AUTOD 0x02
-#define MAC_DIRECTED 0x00000001
-#define MAC_BCAST 0x00000002
-#define MAC_MCAST 0x00000004
-#define MAC_PROMISC 0x00000008
-#define MAC_LOOPBACK 0x00000010
-#define MAC_ALLMCAST 0x00000020
+#define MAC_DIRECTED 0x00000001
+#define MAC_BCAST 0x00000002
+#define MAC_MCAST 0x00000004
+#define MAC_PROMISC 0x00000008
+#define MAC_LOOPBACK 0x00000010
+#define MAC_ALLMCAST 0x00000020
#define SLIC_DUPLEX(x) ((x==LINK_FULLD) ? "FDX" : "HDX")
-#define SLIC_SPEED(x) ((x==LINK_100MB) ? "100Mb" : ((x==LINK_1000MB) ? "1000Mb" : " 10Mb"))
+#define SLIC_SPEED(x) ((x==LINK_100MB) ? "100Mb" : \
+ ((x==LINK_1000MB) ? "1000Mb" : " 10Mb"))
#define SLIC_LINKSTATE(x) ((x==LINK_DOWN) ? "Down" : "Up ")
#define SLIC_ADAPTER_STATE(x) ((x==ADAPT_UP) ? "UP" : "Down")
#define SLIC_CARD_STATE(x) ((x==CARD_UP) ? "UP" : "Down")
#define NUM_CFG_REGS 64
struct physcard {
- struct adapter_t *adapter[SLIC_MAX_PORTS];
- struct physcard *next;
+ struct adapter_t *adapter[SLIC_MAX_PORTS];
+ struct physcard *next;
unsigned int adapters_allocd;
};
/* PSXG_DUMP_CMD DumpBuffer; */ /* 68k - Cmd and Buffer */
/* dma_addr_t PDumpBuffer; */ /* Physical address */
/*#endif */ /* SXG_FAILURE_DUMP */
-
};
#if SLIC_DUMP_ENABLED
(largestat) += ((newstat) - (oldstat)); \
}
-#define ETHER_EQ_ADDR(_AddrA, _AddrB, _Result) \
-{ \
- _Result = TRUE; \
- if (*(u32 *)(_AddrA) != *(u32 *)(_AddrB)) \
- _Result = FALSE; \
- if (*(u16 *)(&((_AddrA)[4])) != *(u16 *)(&((_AddrB)[4]))) \
- _Result = FALSE; \
+#define ETHER_EQ_ADDR(_AddrA, _AddrB, _Result) \
+{ \
+ _Result = TRUE; \
+ if (*(u32 *)(_AddrA) != *(u32 *)(_AddrB)) \
+ _Result = FALSE; \
+ if (*(u16 *)(&((_AddrA)[4])) != *(u16 *)(&((_AddrB)[4]))) \
+ _Result = FALSE; \
}
#define ETHERMAXFRAME 1514
#if defined(CONFIG_X86_64) || defined(CONFIG_IA64)
#define SXG_GET_ADDR_LOW(_addr) (u32)((u64)(_addr) & 0x00000000FFFFFFFF)
-#define SXG_GET_ADDR_HIGH(_addr) (u32)(((u64)(_addr) >> 32) & 0x00000000FFFFFFFF)
+#define SXG_GET_ADDR_HIGH(_addr) \
+ (u32)(((u64)(_addr) >> 32) & 0x00000000FFFFFFFF)
#else
#define SXG_GET_ADDR_LOW(_addr) (u32)_addr
#define SXG_GET_ADDR_HIGH(_addr) (u32)0
#define FLUSH TRUE
#define DONT_FLUSH FALSE
-#define SIOCSLICDUMPCARD SIOCDEVPRIVATE+9
-#define SIOCSLICSETINTAGG SIOCDEVPRIVATE+10
-#define SIOCSLICTRACEDUMP SIOCDEVPRIVATE+11
+#define SIOCSLICDUMPCARD (SIOCDEVPRIVATE+9)
+#define SIOCSLICSETINTAGG (SIOCDEVPRIVATE+10)
+#define SIOCSLICTRACEDUMP (SIOCDEVPRIVATE+11)
#endif /* __SXG_DRIVER_H__ */
struct list_entry *nle_blink;
};
-#define InitializeListHead(l) \
+#define InitializeListHead(l) \
(l)->nle_flink = (l)->nle_blink = (l)
-#define IsListEmpty(h) \
+#define IsListEmpty(h) \
((h)->nle_flink == (h))
-#define RemoveEntryList(e) \
- do { \
- list_entry *b; \
- list_entry *f; \
- \
- f = (e)->nle_flink; \
- b = (e)->nle_blink; \
- b->nle_flink = f; \
- f->nle_blink = b; \
+#define RemoveEntryList(e) \
+ do { \
+ list_entry *b; \
+ list_entry *f; \
+ \
+ f = (e)->nle_flink; \
+ b = (e)->nle_blink; \
+ b->nle_flink = f; \
+ f->nle_blink = b; \
} while (0)
/* These two have to be inlined since they return things. */
-static __inline struct list_entry *RemoveHeadList(struct list_entry *l)
+static inline struct list_entry *RemoveHeadList(struct list_entry *l)
{
struct list_entry *f;
struct list_entry *e;
return (e);
}
-static __inline struct list_entry *RemoveTailList(struct list_entry *l)
+static inline struct list_entry *RemoveTailList(struct list_entry *l)
{
struct list_entry *b;
struct list_entry *e;
return (e);
}
-#define InsertTailList(l, e) \
- do { \
- struct list_entry *b; \
- \
- b = (l)->nle_blink; \
- (e)->nle_flink = (l); \
- (e)->nle_blink = b; \
- b->nle_flink = (e); \
- (l)->nle_blink = (e); \
+#define InsertTailList(l, e) \
+ do { \
+ struct list_entry *b; \
+ \
+ b = (l)->nle_blink; \
+ (e)->nle_flink = (l); \
+ (e)->nle_blink = b; \
+ b->nle_flink = (e); \
+ (l)->nle_blink = (e); \
} while (0)
-#define InsertHeadList(l, e) \
- do { \
- struct list_entry *f; \
- \
- f = (l)->nle_flink; \
- (e)->nle_flink = f; \
- (e)->nle_blink = l; \
- f->nle_blink = (e); \
- (l)->nle_flink = (e); \
+#define InsertHeadList(l, e) \
+ do { \
+ struct list_entry *f; \
+ \
+ f = (l)->nle_flink; \
+ (e)->nle_flink = f; \
+ (e)->nle_blink = l; \
+ f->nle_blink = (e); \
+ (l)->nle_flink = (e); \
} while (0)
#define ATK_DEBUG 1
#if ATK_DEBUG
-#define SLIC_TIMESTAMP(value) { \
- struct timeval timev; \
- do_gettimeofday(&timev); \
- value = timev.tv_sec*1000000 + timev.tv_usec; \
+#define SLIC_TIMESTAMP(value) { \
+ struct timeval timev; \
+ do_gettimeofday(&timev); \
+ value = timev.tv_sec*1000000 + timev.tv_usec; \
}
#else
#define SLIC_TIMESTAMP(value)
/* SXG DEFINES */
#ifdef ATKDBG
-#define SXG_TIMESTAMP(value) { \
- struct timeval timev; \
- do_gettimeofday(&timev); \
- value = timev.tv_sec*1000000 + timev.tv_usec; \
+#define SXG_TIMESTAMP(value) { \
+ struct timeval timev; \
+ do_gettimeofday(&timev); \
+ value = timev.tv_sec*1000000 + timev.tv_usec; \
}
#else
#define SXG_TIMESTAMP(value)
#endif
-#define WRITE_REG(reg,value,flush) sxg_reg32_write((®), (value), (flush))
-#define WRITE_REG64(a,reg,value,cpu) sxg_reg64_write((a),(®),(value),(cpu))
+#define WRITE_REG(reg,value,flush) \
+ sxg_reg32_write((®), (value), (flush))
+#define WRITE_REG64(a,reg,value,cpu) \
+ sxg_reg64_write((a),(®),(value),(cpu))
#define READ_REG(reg,value) (value) = readl((void __iomem *)(®))
#endif /* _SLIC_OS_SPECIFIC_H_ */
#define SXG_ASSERT_ENABLED
#ifdef SXG_ASSERT_ENABLED
#ifndef ASSERT
-#define ASSERT(a) \
- { \
- if (!(a)) { \
- DBG_ERROR("ASSERT() Failure: file %s, function %s line %d\n",\
- __FILE__, __func__, __LINE__); \
- } \
+#define ASSERT(a) \
+ { \
+ if (!(a)) { \
+ DBG_ERROR("ASSERT() Failure: file %s, function %s line %d\n", \
+ __FILE__, __func__, __LINE__); \
+ } \
}
#endif
#else
* parameters.
*/
struct trace_entry {
- char name[8]; /* 8 character name - like 's'i'm'b'a'r'c'v' */
- u32 time; /* Current clock tic */
- unsigned char cpu; /* Current CPU */
- unsigned char irql; /* Current IRQL */
- unsigned char driver; /* The driver which added the trace call */
- unsigned char pad2; /* pad to 4 byte boundary - will probably get used */
- u32 arg1; /* Caller arg1 */
- u32 arg2; /* Caller arg2 */
- u32 arg3; /* Caller arg3 */
- u32 arg4; /* Caller arg4 */
+ char name[8];/* 8 character name - like 's'i'm'b'a'r'c'v' */
+ u32 time; /* Current clock tic */
+ unsigned char cpu; /* Current CPU */
+ unsigned char irql; /* Current IRQL */
+ unsigned char driver;/* The driver which added the trace call */
+ /* pad to 4 byte boundary - will probably get used */
+ unsigned char pad2;
+ u32 arg1; /* Caller arg1 */
+ u32 arg2; /* Caller arg2 */
+ u32 arg3; /* Caller arg3 */
+ u32 arg4; /* Caller arg4 */
};
/* Driver types for driver field in struct trace_entry */
#define TRACE_ENTRIES 1024
struct sxg_trace_buffer {
- unsigned int size; /* aid for windbg extension */
- unsigned int in; /* Where to add */
- unsigned int level; /* Current Trace level */
- spinlock_t lock; /* For MP tracing */
- struct trace_entry entries[TRACE_ENTRIES];/* The circular buffer */
+ /* aid for windbg extension */
+ unsigned int size;
+ unsigned int in; /* Where to add */
+ unsigned int level; /* Current Trace level */
+ spinlock_t lock; /* For MP tracing */
+ struct trace_entry entries[TRACE_ENTRIES];/* The circular buffer */
};
/*
/*The trace macro. This is active only if ATK_TRACE_ENABLED is set. */
#if ATK_TRACE_ENABLED
#define SXG_TRACE(tdriver, buffer, tlevel, tname, a1, a2, a3, a4) { \
- if ((buffer) && ((buffer)->level >= (tlevel))) { \
- unsigned int trace_irql = 0; /* ?????? FIX THIS */ \
- unsigned int trace_len; \
- struct trace_entry *trace_entry; \
- struct timeval timev; \
- \
- spin_lock(&(buffer)->lock); \
- trace_entry = &(buffer)->entries[(buffer)->in]; \
- do_gettimeofday(&timev); \
- \
- memset(trace_entry->name, 0, 8); \
- trace_len = strlen(tname); \
- trace_len = trace_len > 8 ? 8 : trace_len; \
- memcpy(trace_entry->name, (tname), trace_len); \
- trace_entry->time = timev.tv_usec; \
- trace_entry->cpu = (unsigned char)(smp_processor_id() & 0xFF); \
+ if ((buffer) && ((buffer)->level >= (tlevel))) { \
+ unsigned int trace_irql = 0;/* ?????? FIX THIS */\
+ unsigned int trace_len; \
+ struct trace_entry *trace_entry; \
+ struct timeval timev; \
+ \
+ spin_lock(&(buffer)->lock); \
+ trace_entry = &(buffer)->entries[(buffer)->in]; \
+ do_gettimeofday(&timev); \
+ \
+ memset(trace_entry->name, 0, 8); \
+ trace_len = strlen(tname); \
+ trace_len = trace_len > 8 ? 8 : trace_len; \
+ memcpy(trace_entry->name, (tname), trace_len); \
+ trace_entry->time = timev.tv_usec; \
+ trace_entry->cpu = (unsigned char)(smp_processor_id() & 0xFF);\
trace_entry->driver = (tdriver); \
trace_entry->irql = trace_irql; \
trace_entry->arg1 = (ulong)(a1); \
/* UCODE Registers */
struct sxg_ucode_regs {
/* Address 0 - 0x3F = Command codes 0-15 for TCB 0. Excode 0 */
- u32 Icr; /* Code = 0 (extended), ExCode = 0 - Int control */
- u32 RsvdReg1; /* Code = 1 - TOE -NA */
- u32 RsvdReg2; /* Code = 2 - TOE -NA */
- u32 RsvdReg3; /* Code = 3 - TOE -NA */
- u32 RsvdReg4; /* Code = 4 - TOE -NA */
- u32 RsvdReg5; /* Code = 5 - TOE -NA */
- u32 CardUp; /* Code = 6 - Microcode initialized when 1 */
- u32 RsvdReg7; /* Code = 7 - TOE -NA */
- u32 ConfigStat; /* Code = 8 - Configuration data load status */
- u32 RsvdReg9; /* Code = 9 - TOE -NA */
- u32 CodeNotUsed[6]; /* Codes 10-15 not used. ExCode = 0 */
+ u32 Icr; /* Code = 0 (extended), ExCode = 0 - Int control */
+ u32 RsvdReg1; /* Code = 1 - TOE -NA */
+ u32 RsvdReg2; /* Code = 2 - TOE -NA */
+ u32 RsvdReg3; /* Code = 3 - TOE -NA */
+ u32 RsvdReg4; /* Code = 4 - TOE -NA */
+ u32 RsvdReg5; /* Code = 5 - TOE -NA */
+ u32 CardUp; /* Code = 6 - Microcode initialized when 1 */
+ u32 RsvdReg7; /* Code = 7 - TOE -NA */
+ u32 ConfigStat; /* Code = 8 - Configuration data load status */
+ u32 RsvdReg9; /* Code = 9 - TOE -NA */
+ u32 CodeNotUsed[6]; /* Codes 10-15 not used. ExCode = 0 */
/* This brings us to ExCode 1 at address 0x40 = Interrupt status pointer */
- u32 Isp; /* Code = 0 (extended), ExCode = 1 */
- u32 PadEx1[15]; /* Codes 1-15 not used with extended codes */
+ u32 Isp; /* Code = 0 (extended), ExCode = 1 */
+ u32 PadEx1[15]; /* Codes 1-15 not used with extended codes */
/* ExCode 2 = Interrupt Status Register */
- u32 Isr; /* Code = 0 (extended), ExCode = 2 */
+ u32 Isr; /* Code = 0 (extended), ExCode = 2 */
u32 PadEx2[15];
/* ExCode 3 = Event base register. Location of event rings */
- u32 EventBase; /* Code = 0 (extended), ExCode = 3 */
+ u32 EventBase; /* Code = 0 (extended), ExCode = 3 */
u32 PadEx3[15];
/* ExCode 4 = Event ring size */
- u32 EventSize; /* Code = 0 (extended), ExCode = 4 */
+ u32 EventSize; /* Code = 0 (extended), ExCode = 4 */
u32 PadEx4[15];
/* ExCode 5 = TCB Buffers base address */
- u32 TcbBase; /* Code = 0 (extended), ExCode = 5 */
+ u32 TcbBase; /* Code = 0 (extended), ExCode = 5 */
u32 PadEx5[15];
/* ExCode 6 = TCB Composite Buffers base address */
- u32 TcbCompBase; /* Code = 0 (extended), ExCode = 6 */
+ u32 TcbCompBase; /* Code = 0 (extended), ExCode = 6 */
u32 PadEx6[15];
/* ExCode 7 = Transmit ring base address */
- u32 XmtBase; /* Code = 0 (extended), ExCode = 7 */
+ u32 XmtBase; /* Code = 0 (extended), ExCode = 7 */
u32 PadEx7[15];
/* ExCode 8 = Transmit ring size */
- u32 XmtSize; /* Code = 0 (extended), ExCode = 8 */
+ u32 XmtSize; /* Code = 0 (extended), ExCode = 8 */
u32 PadEx8[15];
/* ExCode 9 = Receive ring base address */
- u32 RcvBase; /* Code = 0 (extended), ExCode = 9 */
+ u32 RcvBase; /* Code = 0 (extended), ExCode = 9 */
u32 PadEx9[15];
/* ExCode 10 = Receive ring size */
- u32 RcvSize; /* Code = 0 (extended), ExCode = 10 */
+ u32 RcvSize; /* Code = 0 (extended), ExCode = 10 */
u32 PadEx10[15];
/* ExCode 11 = Read EEPROM/Flash Config */
- u32 Config; /* Code = 0 (extended), ExCode = 11 */
+ u32 Config; /* Code = 0 (extended), ExCode = 11 */
u32 PadEx11[15];
/* ExCode 12 = Multicast bits 31:0 */
- u32 McastLow; /* Code = 0 (extended), ExCode = 12 */
+ u32 McastLow; /* Code = 0 (extended), ExCode = 12 */
u32 PadEx12[15];
/* ExCode 13 = Multicast bits 63:32 */
- u32 McastHigh; /* Code = 0 (extended), ExCode = 13 */
+ u32 McastHigh; /* Code = 0 (extended), ExCode = 13 */
u32 PadEx13[15];
/* ExCode 14 = Ping */
- u32 Ping; /* Code = 0 (extended), ExCode = 14 */
+ u32 Ping; /* Code = 0 (extended), ExCode = 14 */
u32 PadEx14[15];
/* ExCode 15 = Link MTU */
- u32 LinkMtu; /* Code = 0 (extended), ExCode = 15 */
+ u32 LinkMtu; /* Code = 0 (extended), ExCode = 15 */
u32 PadEx15[15];
/* ExCode 16 = Download synchronization */
- u32 LoadSync; /* Code = 0 (extended), ExCode = 16 */
+ u32 LoadSync; /* Code = 0 (extended), ExCode = 16 */
u32 PadEx16[15];
/* ExCode 17 = Upper DRAM address bits on 32-bit systems */
- u32 Upper; /* Code = 0 (extended), ExCode = 17 */
+ u32 Upper; /* Code = 0 (extended), ExCode = 17 */
u32 PadEx17[15];
/* ExCode 18 = Slowpath Send Index Address */
- u32 SPSendIndex; /* Code = 0 (extended), ExCode = 18 */
+ u32 SPSendIndex; /* Code = 0 (extended), ExCode = 18 */
u32 PadEx18[15];
/* ExCode 19 = Get ucode statistics */
- u32 GetUcodeStats; /* Code = 0 (extended), ExCode = 19 */
+ u32 GetUcodeStats; /* Code = 0 (extended), ExCode = 19 */
u32 PadEx19[15];
/* ExCode 20 = Aggregation - See sxgmisc.c:SxgSetInterruptAggregation */
- u32 Aggregation; /* Code = 0 (extended), ExCode = 20 */
+ u32 Aggregation; /* Code = 0 (extended), ExCode = 20 */
u32 PadEx20[15];
/* ExCode 21 = Receive MDL push timer */
- u32 PushTicks; /* Code = 0 (extended), ExCode = 21 */
+ u32 PushTicks; /* Code = 0 (extended), ExCode = 21 */
u32 PadEx21[15];
/* ExCode 22 = ACK Frequency */
- u32 AckFrequency; /* Code = 0 (extended), ExCode = 22 */
+ u32 AckFrequency; /* Code = 0 (extended), ExCode = 22 */
u32 PadEx22[15];
/* ExCode 23 = TOE NA */
u32 RsvdReg23;
u32 RsvdReg24;
u32 PadEx24[15];
/* ExCode 25 = TOE NA */
- u32 RsvdReg25; /* Code = 0 (extended), ExCode = 25 */
+ u32 RsvdReg25; /* Code = 0 (extended), ExCode = 25 */
u32 PadEx25[15];
/* ExCode 26 = Receive checksum requirements */
- u32 ReceiveChecksum; /* Code = 0 (extended), ExCode = 26 */
+ u32 ReceiveChecksum; /* Code = 0 (extended), ExCode = 26 */
u32 PadEx26[15];
/* ExCode 27 = RSS Requirements */
- u32 Rss; /* Code = 0 (extended), ExCode = 27 */
+ u32 Rss; /* Code = 0 (extended), ExCode = 27 */
u32 PadEx27[15];
/* ExCode 28 = RSS Table */
- u32 RssTable; /* Code = 0 (extended), ExCode = 28 */
+ u32 RssTable; /* Code = 0 (extended), ExCode = 28 */
u32 PadEx28[15];
/* ExCode 29 = Event ring release entries */
- u32 EventRelease; /* Code = 0 (extended), ExCode = 29 */
+ u32 EventRelease; /* Code = 0 (extended), ExCode = 29 */
u32 PadEx29[15];
/* ExCode 30 = Number of receive bufferlist commands on ring 0 */
- u32 RcvCmd; /* Code = 0 (extended), ExCode = 30 */
+ u32 RcvCmd; /* Code = 0 (extended), ExCode = 30 */
u32 PadEx30[15];
/* ExCode 31 = slowpath transmit command - Data[31:0] = 1 */
- u32 XmtCmd; /* Code = 0 (extended), ExCode = 31 */
+ u32 XmtCmd; /* Code = 0 (extended), ExCode = 31 */
u32 PadEx31[15];
/* ExCode 32 = Dump command */
- u32 DumpCmd; /* Code = 0 (extended), ExCode = 32 */
+ u32 DumpCmd; /* Code = 0 (extended), ExCode = 32 */
u32 PadEx32[15];
/* ExCode 33 = Debug command */
- u32 DebugCmd; /* Code = 0 (extended), ExCode = 33 */
+ u32 DebugCmd; /* Code = 0 (extended), ExCode = 33 */
u32 PadEx33[15];
/*
* There are 128 possible extended commands - each of account for 16
* base. As extended codes are added, reduce the first array value in
* the following field
*/
- u32 PadToNextCpu[94][16]; /* 94 = 128 - 34 (34 = Excodes 0 - 33) */
+ u32 PadToNextCpu[94][16]; /* 94 = 128 - 34 (34 = Excodes 0 - 33)*/
};
/* Interrupt control register (0) values */
((((_MessageId) << SXG_ICR_MSGID_SHIFT) & \
SXG_ICR_MSGID_MASK) | (_Data))
-#define SXG_MIN_AGG_DEFAULT 0x0010 /* Minimum aggregation default */
-#define SXG_MAX_AGG_DEFAULT 0x0040 /* Maximum aggregation default */
-#define SXG_MAX_AGG_SHIFT 16 /* Maximum in top 16 bits of register */
-#define SXG_AGG_XMT_DISABLE 0x80000000 /* Disable interrupt aggregation on xmt */
+#define SXG_MIN_AGG_DEFAULT 0x0010 /* Minimum aggregation default */
+#define SXG_MAX_AGG_DEFAULT 0x0040 /* Maximum aggregation default */
+#define SXG_MAX_AGG_SHIFT 16 /* Maximum in top 16 bits of register */
+/* Disable interrupt aggregation on xmt */
+#define SXG_AGG_XMT_DISABLE 0x80000000
/* The Microcode supports up to 8 RSS queues */
#define SXG_MAX_RSS 8
* Status returned by ucode in the ConfigStat reg (see above) when attempted
* to load configuration data from the EEPROM/Flash.
*/
-#define SXG_CFG_TIMEOUT 1 /* init value - timeout if unchanged */
-#define SXG_CFG_LOAD_EEPROM 2 /* config data loaded from EEPROM */
-#define SXG_CFG_LOAD_FLASH 3 /* config data loaded from flash */
-#define SXG_CFG_LOAD_INVALID 4 /* no valid config data found */
-#define SXG_CFG_LOAD_ERROR 5 /* hardware error */
+#define SXG_CFG_TIMEOUT 1 /* init value - timeout if unchanged */
+#define SXG_CFG_LOAD_EEPROM 2 /* config data loaded from EEPROM */
+#define SXG_CFG_LOAD_FLASH 3 /* config data loaded from flash */
+#define SXG_CFG_LOAD_INVALID 4 /* no valid config data found */
+#define SXG_CFG_LOAD_ERROR 5 /* hardware error */
#define SXG_CHECK_FOR_HANG_TIME 5
* struct sxg_ucode_regs definition above
*/
struct sxg_tcb_regs {
- u32 ExCode; /* Extended codes - see SXG_UCODE_REGS */
- u32 Xmt; /* Code = 1 - # of Xmt descriptors added to ring */
- u32 Rcv; /* Code = 2 - # of Rcv descriptors added to ring */
- u32 Rsvd1; /* Code = 3 - TOE NA */
- u32 Rsvd2; /* Code = 4 - TOE NA */
- u32 Rsvd3; /* Code = 5 - TOE NA */
- u32 Invalid1; /* Code = 6 - Reserved for "CardUp" see above */
- u32 Rsvd4; /* Code = 7 - TOE NA */
- u32 Invalid2; /* Code = 8 - Reserved for "ConfigStat" see above */
- u32 Rsvd5; /* Code = 9 - TOE NA */
- u32 Pad[6]; /* Codes 10-15 - Not used. */
+ u32 ExCode; /* Extended codes - see SXG_UCODE_REGS */
+ u32 Xmt; /* Code = 1 - # of Xmt descriptors added to ring */
+ u32 Rcv; /* Code = 2 - # of Rcv descriptors added to ring */
+ u32 Rsvd1; /* Code = 3 - TOE NA */
+ u32 Rsvd2; /* Code = 4 - TOE NA */
+ u32 Rsvd3; /* Code = 5 - TOE NA */
+ u32 Invalid1; /* Code = 6 - Reserved for "CardUp" see above */
+ u32 Rsvd4; /* Code = 7 - TOE NA */
+ u32 Invalid2; /* Code = 8 - Reserved for "ConfigStat" see above */
+ u32 Rsvd5; /* Code = 9 - TOE NA */
+ u32 Pad[6]; /* Codes 10-15 - Not used. */
};
/***************************************************************************
#define SXG_ISR_ERR 0x80000000 /* Error */
#define SXG_ISR_EVENT 0x40000000 /* Event ring event */
#define SXG_ISR_NONE1 0x20000000 /* Not used */
-#define SXG_ISR_UPC 0x10000000 /* Dump/debug command complete */
+#define SXG_ISR_UPC 0x10000000 /* Dump/debug command complete*/
#define SXG_ISR_LINK 0x08000000 /* Link event */
#define SXG_ISR_PDQF 0x04000000 /* Processed data queue full */
#define SXG_ISR_RMISS 0x02000000 /* Drop - no host buf */
*/
#define EVENT_RING_SIZE 4096
#define EVENT_RING_BATCH 16 /* Hand entries back 16 at a time. */
-#define EVENT_BATCH_LIMIT 256 /* Stop processing events after 4096 (256 * 16) */
+/* Stop processing events after 4096 (256 * 16) */
+#define EVENT_BATCH_LIMIT 256
struct sxg_event_ring {
struct sxg_event Ring[EVENT_RING_SIZE];
* offloaded connections, 10:4 if we support 2k and so on.
*/
#define SXG_TCB_BUCKET_SHIFT 4
-#define SXG_TCB_PER_BUCKET 16
-#define SXG_TCB_BUCKET_MASK 0xFF0 /* Bucket portion of TCB ID */
-#define SXG_TCB_ELEMENT_MASK 0x00F /* Element within bucket */
-#define SXG_TCB_BUCKETS 256 /* 256 * 16 = 4k */
+#define SXG_TCB_PER_BUCKET 16
+#define SXG_TCB_BUCKET_MASK 0xFF0 /* Bucket portion of TCB ID */
+#define SXG_TCB_ELEMENT_MASK 0x00F /* Element within bucket */
+#define SXG_TCB_BUCKETS 256 /* 256 * 16 = 4k */
#define SXG_TCB_BUFFER_SIZE 512 /* ASSERT format is correct */
-#define SXG_TCB_RCVQ_SIZE 736
+#define SXG_TCB_RCVQ_SIZE 736
#define SXG_TCB_COMPOSITE_BUFFER_SIZE 1024
-#define SXG_LOCATE_TCP_FRAME_HDR(_TcpObject, _IPv6) \
- (((_TcpObject)->VlanId) ? \
- ((_IPv6) ? /* Vlan frame header = yes */ \
- &(_TcpObject)->CompBuffer->Frame.HasVlan.TcpIp6.SxgTcp : \
- &(_TcpObject)->CompBuffer->Frame.HasVlan.TcpIp.SxgTcp) : \
- ((_IPv6) ? /* Vlan frame header = No */ \
- &(_TcpObject)->CompBuffer->Frame.NoVlan.TcpIp6.SxgTcp : \
+#define SXG_LOCATE_TCP_FRAME_HDR(_TcpObject, _IPv6) \
+ (((_TcpObject)->VlanId) ? \
+ ((_IPv6) ? /* Vlan frame header = yes */ \
+ &(_TcpObject)->CompBuffer->Frame.HasVlan.TcpIp6.SxgTcp: \
+ &(_TcpObject)->CompBuffer->Frame.HasVlan.TcpIp.SxgTcp): \
+ ((_IPv6) ? /* Vlan frame header = No */ \
+ &(_TcpObject)->CompBuffer->Frame.NoVlan.TcpIp6.SxgTcp : \
&(_TcpObject)->CompBuffer->Frame.NoVlan.TcpIp.SxgTcp))
-#define SXG_LOCATE_IP_FRAME_HDR(_TcpObject) \
- (_TcpObject)->VlanId ? \
- &(_TcpObject)->CompBuffer->Frame.HasVlan.TcpIp.Ip : \
+#define SXG_LOCATE_IP_FRAME_HDR(_TcpObject) \
+ (_TcpObject)->VlanId ? \
+ &(_TcpObject)->CompBuffer->Frame.HasVlan.TcpIp.Ip: \
&(_TcpObject)->CompBuffer->Frame.NoVlan.TcpIp.Ip
-#define SXG_LOCATE_IP6_FRAME_HDR(_TcpObject) \
- (_TcpObject)->VlanId ? \
- &(_TcpObject)->CompBuffer->Frame.HasVlan.TcpIp6.Ip : \
+#define SXG_LOCATE_IP6_FRAME_HDR(TcpObject) \
+ (_TcpObject)->VlanId ? \
+ &(_TcpObject)->CompBuffer->Frame.HasVlan.TcpIp6.Ip: \
&(_TcpObject)->CompBuffer->Frame.NoVlan.TcpIp6.Ip
#if DBG
* Obviously this is DBG only. Maybe remove later, or #if 0 so we
* can set it when needed
*/
-#define SXG_DBG_HOP_LIMIT(_TcpObject, _FastPath) { \
- PIPV6_HDR _Ip6FrameHdr; \
- if((_TcpObject)->IPv6) { \
- _Ip6FrameHdr = SXG_LOCATE_IP6_FRAME_HDR((_TcpObject)); \
- if(_FastPath) { \
- _Ip6FrameHdr->HopLimit = (_TcpObject)->Cached.TtlOrHopLimit - 2; \
- } else { \
- _Ip6FrameHdr->HopLimit = (_TcpObject)->Cached.TtlOrHopLimit - 1; \
- } \
- } \
+#define SXG_DBG_HOP_LIMIT(_TcpObject, _FastPath) { \
+ PIPV6_HDR _Ip6FrameHdr; \
+ if ((_TcpObject)->IPv6) { \
+ _Ip6FrameHdr = SXG_LOCATE_IP6_FRAME_HDR((_TcpObject)); \
+ if (_FastPath) { \
+ _Ip6FrameHdr->HopLimit = \
+ (_TcpObject)->Cached.TtlOrHopLimit - 2; \
+ } else { \
+ _Ip6FrameHdr->HopLimit = \
+ (_TcpObject)->Cached.TtlOrHopLimit - 1; \
+ } \
+ } \
}
#else
/* Do nothing with free build */
/* Structure and macros to manage a ring */
struct sxg_ring_info {
- unsigned char Head; /* Where we add entries - Note unsigned char:RING_SIZE */
+ /* Where we add entries - Note unsigned char:RING_SIZE */
+ unsigned char Head;
unsigned char Tail; /* Where we pull off completed entries */
ushort Size; /* Ring size - Must be multiple of 2 */
void * Context[SXG_MAX_RING_SIZE]; /* Shadow ring */
};
-#define SXG_INITIALIZE_RING(_ring, _size) { \
- (_ring).Head = 0; \
- (_ring).Tail = 0; \
- (_ring).Size = (_size); \
+#define SXG_INITIALIZE_RING(_ring, _size) { \
+ (_ring).Head = 0; \
+ (_ring).Tail = 0; \
+ (_ring).Size = (_size); \
}
-#define SXG_ADVANCE_INDEX(_index, _size) ((_index) = ((_index) + 1) & ((_size) - 1))
-#define SXG_PREVIOUS_INDEX(_index, _size) (((_index) - 1) &((_size) - 1))
+
+#define SXG_ADVANCE_INDEX(_index, _size) \
+ ((_index) = ((_index) + 1) & ((_size) - 1))
+#define SXG_PREVIOUS_INDEX(_index, _size) \
+ (((_index) - 1) &((_size) - 1))
#define SXG_RING_EMPTY(_ring) ((_ring)->Head == (_ring)->Tail)
-#define SXG_RING_FULL(_ring) ((((_ring)->Head + 1) & ((_ring)->Size - 1)) == (_ring)->Tail)
-#define SXG_RING_ADVANCE_HEAD(_ring) SXG_ADVANCE_INDEX((_ring)->Head, ((_ring)->Size))
-#define SXG_RING_RETREAT_HEAD(_ring) ((_ring)->Head = \
- SXG_PREVIOUS_INDEX((_ring)->Head, (_ring)->Size))
-#define SXG_RING_ADVANCE_TAIL(_ring) { \
- ASSERT((_ring)->Tail != (_ring)->Head); \
- SXG_ADVANCE_INDEX((_ring)->Tail, ((_ring)->Size)); \
+#define SXG_RING_FULL(_ring) \
+ ((((_ring)->Head + 1) & ((_ring)->Size - 1)) == (_ring)->Tail)
+#define SXG_RING_ADVANCE_HEAD(_ring) \
+ SXG_ADVANCE_INDEX((_ring)->Head, ((_ring)->Size))
+#define SXG_RING_RETREAT_HEAD(_ring) ((_ring)->Head = \
+ SXG_PREVIOUS_INDEX((_ring)->Head, (_ring)->Size))
+#define SXG_RING_ADVANCE_TAIL(_ring) { \
+ ASSERT((_ring)->Tail != (_ring)->Head); \
+ SXG_ADVANCE_INDEX((_ring)->Tail, ((_ring)->Size)); \
}
/*
* Set cmd to the next available ring entry, set the shadow context
* entry and advance the ring.
* The appropriate lock must be held when calling this macro
*/
-#define SXG_GET_CMD(_ring, _ringinfo, _cmd, _context) { \
- if(SXG_RING_FULL(_ringinfo)) { \
- (_cmd) = NULL; \
- } else { \
- (_cmd) = &(_ring)->Descriptors[(_ringinfo)->Head]; \
+#define SXG_GET_CMD(_ring, _ringinfo, _cmd, _context) { \
+ if(SXG_RING_FULL(_ringinfo)) { \
+ (_cmd) = NULL; \
+ } else { \
+ (_cmd) = &(_ring)->Descriptors[(_ringinfo)->Head]; \
(_ringinfo)->Context[(_ringinfo)->Head] = (void *)(_context);\
- SXG_RING_ADVANCE_HEAD(_ringinfo); \
- } \
+ SXG_RING_ADVANCE_HEAD(_ringinfo); \
+ } \
}
/*
* NOTE - The appopriate lock MUST NOT BE DROPPED between the SXG_GET_CMD
* and SXG_ABORT_CMD calls.
*/
-#define SXG_ABORT_CMD(_ringinfo) { \
- ASSERT(!(SXG_RING_EMPTY(_ringinfo))); \
- SXG_RING_RETREAT_HEAD(_ringinfo); \
- (_ringinfo)->Context[(_ringinfo)->Head] = NULL; \
+#define SXG_ABORT_CMD(_ringinfo) { \
+ ASSERT(!(SXG_RING_EMPTY(_ringinfo))); \
+ SXG_RING_RETREAT_HEAD(_ringinfo); \
+ (_ringinfo)->Context[(_ringinfo)->Head] = NULL; \
}
/*
* For the given ring, return a pointer to the tail cmd and context,
* clear the context and advance the tail
*/
-#define SXG_RETURN_CMD(_ring, _ringinfo, _cmd, _context) { \
- (_cmd) = &(_ring)->Descriptors[(_ringinfo)->Tail]; \
+#define SXG_RETURN_CMD(_ring, _ringinfo, _cmd, _context) { \
+ (_cmd) = &(_ring)->Descriptors[(_ringinfo)->Tail]; \
(_context) = (_ringinfo)->Context[(_ringinfo)->Tail]; \
- (_ringinfo)->Context[(_ringinfo)->Tail] = NULL; \
- SXG_RING_ADVANCE_TAIL(_ringinfo); \
+ (_ringinfo)->Context[(_ringinfo)->Tail] = NULL; \
+ SXG_RING_ADVANCE_TAIL(_ringinfo); \
}
/***************************************************************
union {
u32 Rsvd1; /* TOE NA */
u32 SgeOffset; /* Slowpath - 2nd SGE offset */
- u32 Resid; /* MDL completion - clobbers update */
+ /* MDL completion - clobbers update */
+ u32 Resid;
};
union {
u32 TotalLength; /* Total transfer length */
* Further complicating matters is the fact that the receive
* buffers must be variable in length in order to accomodate
* jumbo frame configurations. We configure the buffer
- * length so that the buffer and it's corresponding struct sxg_rcv_data_buffer_hdr
- * structure add up to an even boundary. Then we place the
- * remaining data structures after 128 of them as shown in
- * the following diagram:
+ * length so that the buffer and it's corresponding struct
+ * sxg_rcv_data_buffer_hdr structure add up to an even
+ * boundary. Then we place the remaining data structures after 128
+ * of them as shown in the following diagram:
*
* _________________________________________
* | |
*/
#define SXG_RCV_DATA_BUFFERS 8192 /* Amount to give to the card */
#define SXG_INITIAL_RCV_DATA_BUFFERS 16384 /* Initial pool of buffers */
-#define SXG_MIN_RCV_DATA_BUFFERS 4096 /* Minimum amount and when to get more */
+/* Minimum amount and when to get more */
+#define SXG_MIN_RCV_DATA_BUFFERS 4096
#define SXG_MAX_RCV_BLOCKS 256 /* = 32k receive buffers */
/* Receive buffer header */
struct list_entry FreeList; /* Free queue of buffers */
unsigned char State; /* See SXG_BUFFER state above */
unsigned char Status; /* Event status (to log PUSH) */
- struct sk_buff * skb; /* Double mapped (nbl and pkt) */
+ struct sk_buff * skb; /* Double mapped (nbl and pkt)*/
};
/*
*/
#define SxgDumbRcvPacket skb
-#define SXG_RCV_DATA_HDR_SIZE 256 /* Space for struct sxg_rcv_data_buffer_hdr */
-#define SXG_RCV_DATA_BUFFER_SIZE 2048 /* Non jumbo = 2k including HDR */
-#define SXG_RCV_JUMBO_BUFFER_SIZE 10240 /* jumbo = 10k including HDR */
+/* Space for struct sxg_rcv_data_buffer_hdr */
+#define SXG_RCV_DATA_HDR_SIZE 256
+/* Non jumbo = 2k including HDR */
+#define SXG_RCV_DATA_BUFFER_SIZE 2048
+#define SXG_RCV_JUMBO_BUFFER_SIZE 10240 /* jumbo = 10k including HDR */
/* Receive data descriptor */
struct sxg_rcv_data_descriptor {
union {
struct sk_buff *VirtualAddress; /* Host handle */
- u64 ForceTo8Bytes; /* Force x86 to 8-byte boundary */
+ u64 ForceTo8Bytes; /*Force x86 to 8-byte boundary*/
};
dma_addr_t PhysicalAddress;
};
/* Receive descriptor block header */
struct sxg_rcv_descriptor_block_hdr {
- void *VirtualAddress; /* start of 2k buffer */
- dma_addr_t PhysicalAddress; /* ..and it's physical address */
- struct list_entry FreeList; /* free queue of descriptor blocks */
- unsigned char State; /* see sxg_buffer state above */
+ void *VirtualAddress; /* start of 2k buffer */
+ dma_addr_t PhysicalAddress; /* ..and it's physical address */
+ struct list_entry FreeList;/* free queue of descriptor blocks */
+ unsigned char State; /* see sxg_buffer state above */
};
/* Receive block header */
struct sxg_rcv_block_hdr {
void *VirtualAddress; /* Start of virtual memory */
- dma_addr_t PhysicalAddress; /* ..and it's physical address */
- struct list_entry AllList; /* Queue of all SXG_RCV_BLOCKS */
+ dma_addr_t PhysicalAddress; /* ..and it's physical address*/
+ struct list_entry AllList; /* Queue of all SXG_RCV_BLOCKS*/
};
/* Macros to determine data structure offsets into receive block */
-#define SXG_RCV_BLOCK_SIZE(_Buffersize) \
+#define SXG_RCV_BLOCK_SIZE(_Buffersize) \
(((_Buffersize) * SXG_RCV_DESCRIPTORS_PER_BLOCK) + \
- (sizeof(struct sxg_rcv_descriptor_block)) + \
- (sizeof(struct sxg_rcv_descriptor_block_hdr)) + \
+ (sizeof(struct sxg_rcv_descriptor_block)) + \
+ (sizeof(struct sxg_rcv_descriptor_block_hdr)) + \
(sizeof(struct sxg_rcv_block_hdr)))
#define SXG_RCV_BUFFER_DATA_SIZE(_Buffersize) \
((_Buffersize) - SXG_RCV_DATA_HDR_SIZE)
#define SXG_RCV_DATA_BUFFER_HDR_OFFSET(_Buffersize) \
((_Buffersize) - SXG_RCV_DATA_HDR_SIZE)
-#define SXG_RCV_DESCRIPTOR_BLOCK_OFFSET(_Buffersize) \
+#define SXG_RCV_DESCRIPTOR_BLOCK_OFFSET(_Buffersize) \
((_Buffersize) * SXG_RCV_DESCRIPTORS_PER_BLOCK)
-#define SXG_RCV_DESCRIPTOR_BLOCK_HDR_OFFSET(_Buffersize) \
+#define SXG_RCV_DESCRIPTOR_BLOCK_HDR_OFFSET(_Buffersize) \
(((_Buffersize) * SXG_RCV_DESCRIPTORS_PER_BLOCK) + \
(sizeof(struct sxg_rcv_descriptor_block)))
#define SXG_RCV_BLOCK_HDR_OFFSET(_Buffersize) \
/* Scatter gather list buffer */
#define SXG_INITIAL_SGL_BUFFERS 8192 /* Initial pool of SGL buffers */
-#define SXG_MIN_SGL_BUFFERS 2048 /* Minimum amount and when to get more */
-#define SXG_MAX_SGL_BUFFERS 16384 /* Maximum to allocate (note ADAPT:ushort) */
+#define SXG_MIN_SGL_BUFFERS 2048 /* Minimum amount and when to get more*/
+/* Maximum to allocate (note ADAPT:ushort) */
+#define SXG_MAX_SGL_BUFFERS 16384
/*
- * SXG_SGL_POOL_PROPERTIES - This structure is used to define a pool of SGL buffers.
- * These buffers are allocated out of shared memory and used to
+ * SXG_SGL_POOL_PROPERTIES - This structure is used to define a pool of SGL
+ * buffers. These buffers are allocated out of shared memory and used to
* contain a physical scatter gather list structure that is shared
* with the card.
*
/*
* At the moment I'm going to statically initialize 4 pools:
- * 100k buffer pool: The vast majority of the expected buffers are expected to
- * be less than or equal to 100k. At 30 entries per and
- * 8k initial buffers amounts to ~4MB of memory
- * NOTE - This used to be 64K with 20 entries, but during
- * WHQL NDIS 6.0 Testing (2c_mini6stress) MS does their
- * best to send absurd NBL's with ridiculous SGLs, we
- * have received 400byte sends contained in SGL's that
- * have 28 entries
- * 1M buffer pool: Buffers between 64k and 1M. Allocate 256 initial buffers
- * with 300 entries each => ~2MB of memory
- * 5M buffer pool: Not expected often, if at all. 32 initial buffers
- * at 1500 entries each => ~1MB of memory
+ * 100k buffer pool: The vast majority of the expected buffers are expected
+ * to be less than or equal to 100k. At 30 entries per and
+ * 8k initial buffers amounts to ~4MB of memory
+ * NOTE - This used to be 64K with 20 entries, but during
+ * WHQL NDIS 6.0 Testing (2c_mini6stress) MS does their
+ * best to send absurd NBL's with ridiculous SGLs, we
+ * have received 400byte sends contained in SGL's that
+ * have 28 entries
+ * 1M buffer pool: Buffers between 64k and 1M. Allocate 256 initial
+ * buffers with 300 entries each => ~2MB of memory
+ * 5M buffer pool: Not expected often, if at all. 32 initial buffers
+ * at 1500 entries each => ~1MB of memory
* 10M buffer pool: Not expected at all, except under pathelogical conditions.
- * Allocate one at initialization time.
- * Note - 10M is the current limit of what we can
- * realistically support due to the sahara SGL
- * bug described in the SAHARA SGL WORKAROUND below
- *
- * We will likely adjust the number of pools and/or pool properties over time..
+ * Allocate one at initialization time.
+ * Note - 10M is the current limit of what we can realistically
+ * support due to the sahara SGL bug described in the
+ * SAHARA SGL WORKAROUND below. We will likely adjust the
+ * number of pools and/or pool properties over time.
*/
#define SXG_NUM_SGL_POOLS 4
-#define INITIALIZE_SGL_POOL_PROPERTIES \
-struct sxg_sgl_pool_properties SxgSglPoolProperties[SXG_NUM_SGL_POOLS] = \
-{ \
- { 102400, 30, 8192, 2048, 16384, 256}, \
- { 1048576, 300, 256, 128, 1024, 16}, \
- { 5252880, 1500, 32, 16, 512, 0}, \
- {10485760, 2700, 2, 4, 32, 0}, \
+#define INITIALIZE_SGL_POOL_PROPERTIES \
+struct sxg_sgl_pool_properties SxgSglPoolProperties[SXG_NUM_SGL_POOLS] =\
+{ \
+ { 102400, 30, 8192, 2048, 16384, 256}, \
+ { 1048576, 300, 256, 128, 1024, 16}, \
+ { 5252880, 1500, 32, 16, 512, 0}, \
+ {10485760, 2700, 2, 4, 32, 0}, \
};
extern struct sxg_sgl_pool_properties SxgSglPoolProperties[];
-#define SXG_MAX_SGL_BUFFER_SIZE \
+#define SXG_MAX_SGL_BUFFER_SIZE \
SxgSglPoolProperties[SXG_NUM_SGL_POOLS - 1].NBSize
/*
* We currently workaround this issue by allocating SGL buffers
* in 64k blocks and skipping over buffers that straddle the boundary.
*/
-#define SXG_INVALID_SGL(_SxgSgl) \
- (((_SxgSgl)->PhysicalAddress.LowPart & 0xFFFF0000) != \
- (((_SxgSgl)->PhysicalAddress.LowPart + \
+#define SXG_INVALID_SGL(_SxgSgl) \
+ (((_SxgSgl)->PhysicalAddress.LowPart & 0xFFFF0000) != \
+ (((_SxgSgl)->PhysicalAddress.LowPart + \
SXG_SGL_SIZE((_SxgSgl)->Pool)) & 0xFFFF0000))
/*
* struct sxg_sgl_block_hdr, plus one for padding
*/
#define SXG_SGL_BLOCK_SIZE 65536
-#define SXG_SGL_ALLOCATION_SIZE(_Pool) SXG_SGL_BLOCK_SIZE + SXG_SGL_SIZE(_Pool)
+#define SXG_SGL_ALLOCATION_SIZE(_Pool) \
+ SXG_SGL_BLOCK_SIZE + SXG_SGL_SIZE(_Pool)
struct sxg_sgl_block_hdr {
- ushort Pool; /* Associated SGL pool */
- struct list_entry List; /* struct sxg_scatter_gather blocks */
- dma64_addr_t PhysicalAddress;/* physical address */
+ ushort Pool; /* Associated SGL pool */
+ /* struct sxg_scatter_gather blocks */
+ struct list_entry List;
+ dma64_addr_t PhysicalAddress;/* physical address */
};
/*
* The following definition denotes the maximum block of memory that the
- * card can DMA to. It is specified in the call to NdisMRegisterScatterGatherDma.
+ * card can DMA to.It is specified in the call to NdisMRegisterScatterGatherDma.
* For now, use the same value as used in the Slic/Oasis driver, which
* is 128M. That should cover any expected MDL that I can think of.
*/
/* Self identifying structure type */
enum SXG_SGL_TYPE {
- SXG_SGL_DUMB, /* Dumb NIC SGL */
- SXG_SGL_SLOW, /* Slowpath protocol header - see below */
- SXG_SGL_CHIMNEY /* Chimney offload SGL */
+ SXG_SGL_DUMB, /* Dumb NIC SGL */
+ SXG_SGL_SLOW, /* Slowpath protocol header - see below */
+ SXG_SGL_CHIMNEY /* Chimney offload SGL */
};
/*
ushort Pool; /* Associated SGL pool */
ushort Entries; /* SGL total entries */
void * adapter; /* Back pointer to adapter */
- struct list_entry FreeList; /* Free struct sxg_scatter_gather blocks */
- struct list_entry AllList; /* All struct sxg_scatter_gather blocks */
+ /* Free struct sxg_scatter_gather blocks */
+ struct list_entry FreeList;
+ /* All struct sxg_scatter_gather blocks */
+ struct list_entry AllList;
dma_addr_t PhysicalAddress;/* physical address */
unsigned char State; /* See SXG_BUFFER state above */
unsigned char CmdIndex; /* Command ring index */
struct sk_buff *DumbPacket; /* Associated Packet */
- u32 Direction; /* For asynchronous completions */
+ /* For asynchronous completions */
+ u32 Direction;
u32 CurOffset; /* Current SGL offset */
u32 SglRef; /* SGL reference count */
struct vlan_hdr VlanTag; /* VLAN tag to be inserted into SGL */
struct sxg_x64_sgl Sgl; /* SGL handed to card */
};
-/* Note - the "- 1" is because struct sxg_scatter_gather=>struct sxg_x64_sgl includes 1 SGE.. */
+/*
+ * Note - the "- 1" is because struct sxg_scatter_gather=>struct sxg_x64_sgl
+ * includes 1 SGE..
+ */
#define SXG_SGL_SIZE(_Pool) \
(sizeof(struct sxg_scatter_gather) + \
((SxgSglPoolProperties[_Pool].SGEntries - 1) * \
#if defined(CONFIG_X86_64)
#define SXG_SGL_BUFFER(_SxgSgl) (&_SxgSgl->Sgl)
-#define SXG_SGL_BUFFER_LENGTH(_SxgSgl) ((_SxgSgl)->Entries * sizeof(struct sxg_x64_sge))
+#define SXG_SGL_BUFFER_LENGTH(_SxgSgl) ((_SxgSgl)->Entries * \
+ sizeof(struct sxg_x64_sge))
#define SXG_SGL_BUF_SIZE sizeof(struct sxg_x64_sgl)
#elif defined(CONFIG_X86)
/* Force NDIS to give us it's own buffer so we can reformat to our own */
u32 ERDrops; /* Rcv drops due to ER full */
u32 NBDrops; /* Rcv drops due to out of host buffers */
u32 PQDrops; /* Rcv drops due to PDQ full */
- u32 BFDrops; /* Rcv drops due to bad frame: no link addr match, frlen > max */
+ /* Rcv drops due to bad frame: no link addr match, frlen > max */
+ u32 BFDrops;
u32 UPDrops; /* Rcv drops due to UPFq full */
u32 XNoBufs; /* Xmt drop due to no DRAM Xmit buffer or PxyBuf */
};
#define SSID_FUNC_MASK 0xF000 /* Subsystem function mask */
/* Base SSID's */
-#define SSID_SAHARA_PROTO 0x0018 /* 100022 Sahara prototype (XenPak) board */
+/* 100022 Sahara prototype (XenPak) board */
+#define SSID_SAHARA_PROTO 0x0018
#define SSID_SAHARA_FIBER 0x0019 /* 100023 Sahara 1-port fiber board */
#define SSID_SAHARA_COPPER 0x001A /* 100024 Sahara 1-port copper board */
/* Useful SSID macros */
-#define SSID_BASE(ssid) ((ssid) & SSID_BASE_MASK) /* isolate base SSID bits */
-#define SSID_OEM(ssid) ((ssid) & SSID_OEM_MASK) /* isolate SSID OEM bits */
-#define SSID_FUNC(ssid) ((ssid) & SSID_FUNC_MASK) /* isolate SSID function bits */
+/* isolate base SSID bits */
+#define SSID_BASE(ssid) ((ssid) & SSID_BASE_MASK)
+/* isolate SSID OEM bits */
+#define SSID_OEM(ssid) ((ssid) & SSID_OEM_MASK)
+/* isolate SSID function bits */
+#define SSID_FUNC(ssid) ((ssid) & SSID_FUNC_MASK)
/* HW Register Space */
#pragma pack(push, 1)
struct sxg_hw_regs {
- u32 Reset; /* Write 0xdead to invoke soft reset */
- u32 Pad1; /* No register defined at offset 4 */
- u32 InterruptMask0; /* Deassert legacy interrupt on function 0 */
- u32 InterruptMask1; /* Deassert legacy interrupt on function 1 */
- u32 UcodeDataLow; /* Store microcode instruction bits 31-0 */
+ u32 Reset; /* Write 0xdead to invoke soft reset */
+ u32 Pad1; /* No register defined at offset 4 */
+ u32 InterruptMask0; /* Deassert legacy interrupt on function 0 */
+ u32 InterruptMask1; /* Deassert legacy interrupt on function 1 */
+ u32 UcodeDataLow; /* Store microcode instruction bits 31-0 */
u32 UcodeDataMiddle; /* Store microcode instruction bits 63-32 */
- u32 UcodeDataHigh; /* Store microcode instruction bits 95-64 */
- u32 UcodeAddr; /* Store microcode address - See flags below */
- u32 PadTo0x80[24]; /* Pad to Xcv configuration registers */
- u32 MacConfig0; /* 0x80 - AXGMAC Configuration Register 0 */
- u32 MacConfig1; /* 0x84 - AXGMAC Configuration Register 1 */
- u32 MacConfig2; /* 0x88 - AXGMAC Configuration Register 2 */
- u32 MacConfig3; /* 0x8C - AXGMAC Configuration Register 3 */
- u32 MacAddressLow; /* 0x90 - AXGMAC MAC Station Address - octets 1-4 */
- u32 MacAddressHigh; /* 0x94 - AXGMAC MAC Station Address - octets 5-6 */
+ u32 UcodeDataHigh; /* Store microcode instruction bits 95-64 */
+ u32 UcodeAddr; /* Store microcode address - See flags below */
+ u32 PadTo0x80[24]; /* Pad to Xcv configuration registers */
+ u32 MacConfig0; /* 0x80 - AXGMAC Configuration Register 0 */
+ u32 MacConfig1; /* 0x84 - AXGMAC Configuration Register 1 */
+ u32 MacConfig2; /* 0x88 - AXGMAC Configuration Register 2 */
+ u32 MacConfig3; /* 0x8C - AXGMAC Configuration Register 3 */
+ u32 MacAddressLow; /* 0x90 - AXGMAC MAC Station Address - octets 1-4 */
+ u32 MacAddressHigh; /* 0x94 - AXGMAC MAC Station Address - octets 5-6 */
u32 MacReserved1[2]; /* 0x98 - AXGMAC Reserved */
- u32 MacMaxFrameLen; /* 0xA0 - AXGMAC Maximum Frame Length */
+ u32 MacMaxFrameLen; /* 0xA0 - AXGMAC Maximum Frame Length */
u32 MacReserved2[2]; /* 0xA4 - AXGMAC Reserved */
- u32 MacRevision; /* 0xAC - AXGMAC Revision Level Register */
+ u32 MacRevision; /* 0xAC - AXGMAC Revision Level Register */
u32 MacReserved3[4]; /* 0xB0 - AXGMAC Reserved */
- u32 MacAmiimCmd; /* 0xC0 - AXGMAC AMIIM Command Register */
- u32 MacAmiimField; /* 0xC4 - AXGMAC AMIIM Field Register */
- u32 MacAmiimConfig; /* 0xC8 - AXGMAC AMIIM Configuration Register */
- u32 MacAmiimLink; /* 0xCC - AXGMAC AMIIM Link Fail Vector Register */
+ u32 MacAmiimCmd; /* 0xC0 - AXGMAC AMIIM Command Register */
+ u32 MacAmiimField; /* 0xC4 - AXGMAC AMIIM Field Register */
+ u32 MacAmiimConfig; /* 0xC8 - AXGMAC AMIIM Configuration Register */
+ u32 MacAmiimLink; /* 0xCC - AXGMAC AMIIM Link Fail Vector Register */
u32 MacAmiimIndicator; /* 0xD0 - AXGMAC AMIIM Indicator Registor */
u32 PadTo0x100[11]; /* 0xD4 - 0x100 - Pad */
- u32 XmtConfig; /* 0x100 - Transmit Configuration Register */
- u32 RcvConfig; /* 0x104 - Receive Configuration Register 1 */
+ u32 XmtConfig; /* 0x100 - Transmit Configuration Register */
+ u32 RcvConfig; /* 0x104 - Receive Configuration Register 1 */
u32 LinkAddress0Low; /* 0x108 - Link address 0 */
u32 LinkAddress0High; /* 0x10C - Link address 0 */
u32 LinkAddress1Low; /* 0x110 - Link address 1 */
u32 ClearStats; /* 0x17C - Clear Stats */
u32 XmtErrorsLow; /* 0x180 - Transmit stats - errors */
u32 XmtErrorsHigh; /* 0x184 - Transmit stats - errors */
- u32 XmtFramesLow; /* 0x188 - Transmit stats - frame count */
- u32 XmtFramesHigh; /* 0x18C - Transmit stats - frame count */
- u32 XmtBytesLow; /* 0x190 - Transmit stats - byte count */
- u32 XmtBytesHigh; /* 0x194 - Transmit stats - byte count */
+ u32 XmtFramesLow; /* 0x188 - Transmit stats - frame count */
+ u32 XmtFramesHigh; /* 0x18C - Transmit stats - frame count */
+ u32 XmtBytesLow; /* 0x190 - Transmit stats - byte count */
+ u32 XmtBytesHigh; /* 0x194 - Transmit stats - byte count */
u32 XmtTcpSegmentsLow; /* 0x198 - Transmit stats - TCP segments */
u32 XmtTcpSegmentsHigh; /* 0x19C - Transmit stats - TCP segments */
u32 XmtTcpBytesLow; /* 0x1A0 - Transmit stats - TCP bytes */
#define MICROCODE_ADDRESS_GO 0x80000000 /* Start microcode */
#define MICROCODE_ADDRESS_WRITE 0x40000000 /* Store microcode */
#define MICROCODE_ADDRESS_READ 0x20000000 /* Read microcode */
-#define MICROCODE_ADDRESS_PARITY 0x10000000 /* Parity error detected */
+#define MICROCODE_ADDRESS_PARITY 0x10000000/* Parity error detected */
#define MICROCODE_ADDRESS_MASK 0x00001FFF /* Address bits */
/* Link Address Registers */
-#define LINK_ADDRESS_ENABLE 0x80000000 /* Applied to link address high */
+/* Applied to link address high */
+#define LINK_ADDRESS_ENABLE 0x80000000
/* Microsoft register space size */
#define SXG_UCODEREG_MEMSIZE 0x40000 /* 256k */
*/
#define SXG_ADDRESS_CODE_SHIFT 2 /* Base command code */
#define SXG_ADDRESS_CODE_MASK 0x0000003C
-#define SXG_ADDRESS_EXCODE_SHIFT 6 /* Extended (or sub) command code */
+/* Extended (or sub) command code */
+#define SXG_ADDRESS_EXCODE_SHIFT 6
#define SXG_ADDRESS_EXCODE_MASK 0x00001FC0
#define SXG_ADDRESS_CPUID_SHIFT 13 /* CPU */
#define SXG_ADDRESS_CPUID_MASK 0x0003E000
-#define SXG_REGISTER_SIZE_PER_CPU 0x00002000 /* Used to sanity check UCODE_REGS structure */
+/* Used to sanity check UCODE_REGS structure */
+#define SXG_REGISTER_SIZE_PER_CPU 0x00002000
/* Sahara receive sequencer status values */
-#define SXG_RCV_STATUS_ATTN 0x80000000 /* Attention */
-#define SXG_RCV_STATUS_TRANSPORT_MASK 0x3F000000 /* Transport mask */
-#define SXG_RCV_STATUS_TRANSPORT_ERROR 0x20000000 /* Transport error */
-#define SXG_RCV_STATUS_TRANSPORT_CSUM 0x23000000 /* Transport cksum error */
-#define SXG_RCV_STATUS_TRANSPORT_UFLOW 0x22000000 /* Transport underflow */
-#define SXG_RCV_STATUS_TRANSPORT_HDRLEN 0x20000000 /* Transport header length */
-#define SXG_RCV_STATUS_TRANSPORT_FLAGS 0x10000000 /* Transport flags detected */
-#define SXG_RCV_STATUS_TRANSPORT_OPTS 0x08000000 /* Transport options detected */
-#define SXG_RCV_STATUS_TRANSPORT_SESS_MASK 0x07000000 /* Transport DDP */
-#define SXG_RCV_STATUS_TRANSPORT_DDP 0x06000000 /* Transport DDP */
-#define SXG_RCV_STATUS_TRANSPORT_iSCSI 0x05000000 /* Transport iSCSI */
-#define SXG_RCV_STATUS_TRANSPORT_NFS 0x04000000 /* Transport NFS */
-#define SXG_RCV_STATUS_TRANSPORT_FTP 0x03000000 /* Transport FTP */
-#define SXG_RCV_STATUS_TRANSPORT_HTTP 0x02000000 /* Transport HTTP */
-#define SXG_RCV_STATUS_TRANSPORT_SMB 0x01000000 /* Transport SMB */
-#define SXG_RCV_STATUS_NETWORK_MASK 0x00FF0000 /* Network mask */
-#define SXG_RCV_STATUS_NETWORK_ERROR 0x00800000 /* Network error */
-#define SXG_RCV_STATUS_NETWORK_CSUM 0x00830000 /* Network cksum error */
-#define SXG_RCV_STATUS_NETWORK_UFLOW 0x00820000 /* Network underflow error */
-#define SXG_RCV_STATUS_NETWORK_HDRLEN 0x00800000 /* Network header length */
-#define SXG_RCV_STATUS_NETWORK_OFLOW 0x00400000 /* Network overflow detected */
-#define SXG_RCV_STATUS_NETWORK_MCAST 0x00200000 /* Network multicast detected */
-#define SXG_RCV_STATUS_NETWORK_OPTIONS 0x00100000 /* Network options detected */
-#define SXG_RCV_STATUS_NETWORK_OFFSET 0x00080000 /* Network offset detected */
-#define SXG_RCV_STATUS_NETWORK_FRAGMENT 0x00040000 /* Network fragment detected */
-#define SXG_RCV_STATUS_NETWORK_TRANS_MASK 0x00030000 /* Network transport type mask */
-#define SXG_RCV_STATUS_NETWORK_UDP 0x00020000 /* UDP */
-#define SXG_RCV_STATUS_NETWORK_TCP 0x00010000 /* TCP */
-#define SXG_RCV_STATUS_IPONLY 0x00008000 /* IP-only not TCP */
-#define SXG_RCV_STATUS_PKT_PRI 0x00006000 /* Receive priority */
-#define SXG_RCV_STATUS_PKT_PRI_SHFT 13 /* Receive priority shift */
-#define SXG_RCV_STATUS_PARITY 0x00001000 /* MAC Receive RAM parity error */
-#define SXG_RCV_STATUS_ADDRESS_MASK 0x00000F00 /* Link address detection mask */
-#define SXG_RCV_STATUS_ADDRESS_D 0x00000B00 /* Link address D */
-#define SXG_RCV_STATUS_ADDRESS_C 0x00000A00 /* Link address C */
-#define SXG_RCV_STATUS_ADDRESS_B 0x00000900 /* Link address B */
-#define SXG_RCV_STATUS_ADDRESS_A 0x00000800 /* Link address A */
-#define SXG_RCV_STATUS_ADDRESS_BCAST 0x00000300 /* Link address broadcast */
-#define SXG_RCV_STATUS_ADDRESS_MCAST 0x00000200 /* Link address multicast */
-#define SXG_RCV_STATUS_ADDRESS_CMCAST 0x00000100 /* Link control multicast */
-#define SXG_RCV_STATUS_LINK_MASK 0x000000FF /* Link status mask */
-#define SXG_RCV_STATUS_LINK_ERROR 0x00000080 /* Link error */
-#define SXG_RCV_STATUS_LINK_MASK 0x000000FF /* Link status mask */
-#define SXG_RCV_STATUS_LINK_PARITY 0x00000087 /* RcvMacQ parity error */
-#define SXG_RCV_STATUS_LINK_EARLY 0x00000086 /* Data early */
-#define SXG_RCV_STATUS_LINK_BUFOFLOW 0x00000085 /* Buffer overflow */
-#define SXG_RCV_STATUS_LINK_CODE 0x00000084 /* Link code error */
-#define SXG_RCV_STATUS_LINK_DRIBBLE 0x00000083 /* Dribble nibble */
-#define SXG_RCV_STATUS_LINK_CRC 0x00000082 /* CRC error */
-#define SXG_RCV_STATUS_LINK_OFLOW 0x00000081 /* Link overflow */
-#define SXG_RCV_STATUS_LINK_UFLOW 0x00000080 /* Link underflow */
-#define SXG_RCV_STATUS_LINK_8023 0x00000020 /* 802.3 */
-#define SXG_RCV_STATUS_LINK_SNAP 0x00000010 /* Snap */
-#define SXG_RCV_STATUS_LINK_VLAN 0x00000008 /* VLAN */
-#define SXG_RCV_STATUS_LINK_TYPE_MASK 0x00000007 /* Network type mask */
-#define SXG_RCV_STATUS_LINK_CONTROL 0x00000003 /* Control packet */
-#define SXG_RCV_STATUS_LINK_IPV6 0x00000002 /* IPv6 packet */
-#define SXG_RCV_STATUS_LINK_IPV4 0x00000001 /* IPv4 packet */
+#define SXG_RCV_STATUS_ATTN 0x80000000 /* Attention */
+#define SXG_RCV_STATUS_TRANSPORT_MASK 0x3F000000 /* Transport mask */
+#define SXG_RCV_STATUS_TRANSPORT_ERROR 0x20000000 /* Transport error */
+/* Transport cksum error */
+#define SXG_RCV_STATUS_TRANSPORT_CSUM 0x23000000
+/* Transport underflow */
+#define SXG_RCV_STATUS_TRANSPORT_UFLOW 0x22000000
+ /* Transport header length */
+#define SXG_RCV_STATUS_TRANSPORT_HDRLEN 0x20000000
+/* Transport flags detected */
+#define SXG_RCV_STATUS_TRANSPORT_FLAGS 0x10000000
+ /* Transport options detected */
+#define SXG_RCV_STATUS_TRANSPORT_OPTS 0x08000000
+#define SXG_RCV_STATUS_TRANSPORT_SESS_MASK 0x07000000 /* Transport DDP */
+#define SXG_RCV_STATUS_TRANSPORT_DDP 0x06000000 /* Transport DDP */
+#define SXG_RCV_STATUS_TRANSPORT_iSCSI 0x05000000 /* Transport iSCSI */
+#define SXG_RCV_STATUS_TRANSPORT_NFS 0x04000000 /* Transport NFS */
+#define SXG_RCV_STATUS_TRANSPORT_FTP 0x03000000 /* Transport FTP */
+#define SXG_RCV_STATUS_TRANSPORT_HTTP 0x02000000 /* Transport HTTP */
+#define SXG_RCV_STATUS_TRANSPORT_SMB 0x01000000 /* Transport SMB */
+#define SXG_RCV_STATUS_NETWORK_MASK 0x00FF0000 /* Network mask */
+#define SXG_RCV_STATUS_NETWORK_ERROR 0x00800000 /* Network error */
+/* Network cksum error */
+#define SXG_RCV_STATUS_NETWORK_CSUM 0x00830000
+/* Network underflow error */
+#define SXG_RCV_STATUS_NETWORK_UFLOW 0x00820000
+ /* Network header length */
+#define SXG_RCV_STATUS_NETWORK_HDRLEN 0x00800000
+ /* Network overflow detected */
+#define SXG_RCV_STATUS_NETWORK_OFLOW 0x00400000
+/* Network multicast detected */
+#define SXG_RCV_STATUS_NETWORK_MCAST 0x00200000
+/* Network options detected */
+#define SXG_RCV_STATUS_NETWORK_OPTIONS 0x00100000
+/* Network offset detected */
+#define SXG_RCV_STATUS_NETWORK_OFFSET 0x00080000
+/* Network fragment detected */
+#define SXG_RCV_STATUS_NETWORK_FRAGMENT 0x00040000
+/* Network transport type mask */
+#define SXG_RCV_STATUS_NETWORK_TRANS_MASK 0x00030000
+#define SXG_RCV_STATUS_NETWORK_UDP 0x00020000 /* UDP */
+#define SXG_RCV_STATUS_NETWORK_TCP 0x00010000 /* TCP */
+#define SXG_RCV_STATUS_IPONLY 0x00008000 /* IP-only not TCP */
+/* Receive priority */
+#define SXG_RCV_STATUS_PKT_PRI 0x00006000
+/* Receive priority shift */
+#define SXG_RCV_STATUS_PKT_PRI_SHFT 13
+/* MAC Receive RAM parity error */
+#define SXG_RCV_STATUS_PARITY 0x00001000
+/* Link address detection mask */
+#define SXG_RCV_STATUS_ADDRESS_MASK 0x00000F00
+
+#define SXG_RCV_STATUS_ADDRESS_D 0x00000B00 /* Link address D */
+#define SXG_RCV_STATUS_ADDRESS_C 0x00000A00 /* Link address C */
+#define SXG_RCV_STATUS_ADDRESS_B 0x00000900 /* Link address B */
+#define SXG_RCV_STATUS_ADDRESS_A 0x00000800 /* Link address A */
+/* Link address broadcast */
+#define SXG_RCV_STATUS_ADDRESS_BCAST 0x00000300
+ /* Link address multicast */
+#define SXG_RCV_STATUS_ADDRESS_MCAST 0x00000200
+/* Link control multicast */
+#define SXG_RCV_STATUS_ADDRESS_CMCAST 0x00000100
+/* Link status mask */
+#define SXG_RCV_STATUS_LINK_MASK 0x000000FF
+#define SXG_RCV_STATUS_LINK_ERROR 0x00000080 /* Link error */
+/* Link status mask */
+#define SXG_RCV_STATUS_LINK_MASK 0x000000FF
+/* RcvMacQ parity error */
+#define SXG_RCV_STATUS_LINK_PARITY 0x00000087
+#define SXG_RCV_STATUS_LINK_EARLY 0x00000086 /* Data early */
+#define SXG_RCV_STATUS_LINK_BUFOFLOW 0x00000085 /* Buffer overflow */
+#define SXG_RCV_STATUS_LINK_CODE 0x00000084 /* Link code error */
+#define SXG_RCV_STATUS_LINK_DRIBBLE 0x00000083 /* Dribble nibble */
+#define SXG_RCV_STATUS_LINK_CRC 0x00000082 /* CRC error */
+#define SXG_RCV_STATUS_LINK_OFLOW 0x00000081 /* Link overflow */
+#define SXG_RCV_STATUS_LINK_UFLOW 0x00000080 /* Link underflow */
+#define SXG_RCV_STATUS_LINK_8023 0x00000020 /* 802.3 */
+#define SXG_RCV_STATUS_LINK_SNAP 0x00000010 /* Snap */
+#define SXG_RCV_STATUS_LINK_VLAN 0x00000008 /* VLAN */
+/* Network type mask */
+#define SXG_RCV_STATUS_LINK_TYPE_MASK 0x00000007
+#define SXG_RCV_STATUS_LINK_CONTROL 0x00000003 /* Control packet */
+#define SXG_RCV_STATUS_LINK_IPV6 0x00000002 /* IPv6 packet */
+#define SXG_RCV_STATUS_LINK_IPV4 0x00000001 /* IPv4 packet */
/* Sahara receive and transmit configuration registers */
-#define RCV_CONFIG_RESET 0x80000000 /* RcvConfig register reset */
-#define RCV_CONFIG_ENABLE 0x40000000 /* Enable the receive logic */
-#define RCV_CONFIG_ENPARSE 0x20000000 /* Enable the receive parser */
-#define RCV_CONFIG_SOCKET 0x10000000 /* Enable the socket detector */
-#define RCV_CONFIG_RCVBAD 0x08000000 /* Receive all bad frames */
-#define RCV_CONFIG_CONTROL 0x04000000 /* Receive all control frames */
-#define RCV_CONFIG_RCVPAUSE 0x02000000 /* Enable pause transmit when attn */
-#define RCV_CONFIG_TZIPV6 0x01000000 /* Include TCP port w/ IPv6 toeplitz */
-#define RCV_CONFIG_TZIPV4 0x00800000 /* Include TCP port w/ IPv4 toeplitz */
-#define RCV_CONFIG_FLUSH 0x00400000 /* Flush buffers */
-#define RCV_CONFIG_PRIORITY_MASK 0x00300000 /* Priority level */
-#define RCV_CONFIG_CONN_MASK 0x000C0000 /* Number of connections */
-#define RCV_CONFIG_CONN_4K 0x00000000 /* 4k connections */
-#define RCV_CONFIG_CONN_2K 0x00040000 /* 2k connections */
-#define RCV_CONFIG_CONN_1K 0x00080000 /* 1k connections */
-#define RCV_CONFIG_CONN_512 0x000C0000 /* 512 connections */
-#define RCV_CONFIG_HASH_MASK 0x00030000 /* Hash depth */
-#define RCV_CONFIG_HASH_8 0x00000000 /* Hash depth 8 */
-#define RCV_CONFIG_HASH_16 0x00010000 /* Hash depth 16 */
-#define RCV_CONFIG_HASH_4 0x00020000 /* Hash depth 4 */
-#define RCV_CONFIG_HASH_2 0x00030000 /* Hash depth 2 */
-#define RCV_CONFIG_BUFLEN_MASK 0x0000FFF0 /* Buffer length bits 15:4. ie multiple of 16. */
-#define RCV_CONFIG_SKT_DIS 0x00000008 /* Disable socket detection on attn */
+/* RcvConfig register reset */
+#define RCV_CONFIG_RESET 0x80000000
+/* Enable the receive logic */
+#define RCV_CONFIG_ENABLE 0x40000000
+/* Enable the receive parser */
+#define RCV_CONFIG_ENPARSE 0x20000000
+/* Enable the socket detector */
+#define RCV_CONFIG_SOCKET 0x10000000
+#define RCV_CONFIG_RCVBAD 0x08000000 /* Receive all bad frames */
+/* Receive all control frames */
+#define RCV_CONFIG_CONTROL 0x04000000
+/* Enable pause transmit when attn */
+#define RCV_CONFIG_RCVPAUSE 0x02000000
+/* Include TCP port w/ IPv6 toeplitz */
+#define RCV_CONFIG_TZIPV6 0x01000000
+/* Include TCP port w/ IPv4 toeplitz */
+#define RCV_CONFIG_TZIPV4 0x00800000
+#define RCV_CONFIG_FLUSH 0x00400000 /* Flush buffers */
+#define RCV_CONFIG_PRIORITY_MASK 0x00300000 /* Priority level */
+#define RCV_CONFIG_CONN_MASK 0x000C0000 /* Number of connections */
+#define RCV_CONFIG_CONN_4K 0x00000000 /* 4k connections */
+#define RCV_CONFIG_CONN_2K 0x00040000 /* 2k connections */
+#define RCV_CONFIG_CONN_1K 0x00080000 /* 1k connections */
+#define RCV_CONFIG_CONN_512 0x000C0000 /* 512 connections */
+#define RCV_CONFIG_HASH_MASK 0x00030000 /* Hash depth */
+#define RCV_CONFIG_HASH_8 0x00000000 /* Hash depth 8 */
+#define RCV_CONFIG_HASH_16 0x00010000 /* Hash depth 16 */
+#define RCV_CONFIG_HASH_4 0x00020000 /* Hash depth 4 */
+#define RCV_CONFIG_HASH_2 0x00030000 /* Hash depth 2 */
+/* Buffer length bits 15:4. ie multiple of 16. */
+#define RCV_CONFIG_BUFLEN_MASK 0x0000FFF0
+/* Disable socket detection on attn */
+#define RCV_CONFIG_SKT_DIS 0x00000008
/*
* Macro to determine RCV_CONFIG_BUFLEN based on maximum frame size.
* We add 18 bytes for Sahara receive status and padding, plus 4 bytes for CRC,
* and round up to nearest 16 byte boundary
*/
-#define RCV_CONFIG_BUFSIZE(_MaxFrame) ((((_MaxFrame) + 22) + 15) & RCV_CONFIG_BUFLEN_MASK)
-
-#define XMT_CONFIG_RESET 0x80000000 /* XmtConfig register reset */
-#define XMT_CONFIG_ENABLE 0x40000000 /* Enable transmit logic */
-#define XMT_CONFIG_MAC_PARITY 0x20000000 /* Inhibit MAC RAM parity error */
-#define XMT_CONFIG_BUF_PARITY 0x10000000 /* Inhibit D2F buffer parity error */
-#define XMT_CONFIG_MEM_PARITY 0x08000000 /* Inhibit 1T SRAM parity error */
-#define XMT_CONFIG_INVERT_PARITY 0x04000000 /* Invert MAC RAM parity */
-#define XMT_CONFIG_INITIAL_IPID 0x0000FFFF /* Initial IPID */
+#define RCV_CONFIG_BUFSIZE(_MaxFrame) \
+ ((((_MaxFrame) + 22) + 15) & RCV_CONFIG_BUFLEN_MASK)
+
+/* XmtConfig register reset */
+#define XMT_CONFIG_RESET 0x80000000
+#define XMT_CONFIG_ENABLE 0x40000000 /* Enable transmit logic */
+/* Inhibit MAC RAM parity error */
+#define XMT_CONFIG_MAC_PARITY 0x20000000
+/* Inhibit D2F buffer parity error */
+#define XMT_CONFIG_BUF_PARITY 0x10000000
+/* Inhibit 1T SRAM parity error */
+#define XMT_CONFIG_MEM_PARITY 0x08000000
+#define XMT_CONFIG_INVERT_PARITY 0x04000000 /* Invert MAC RAM parity */
+#define XMT_CONFIG_INITIAL_IPID 0x0000FFFF /* Initial IPID */
/*
* A-XGMAC Registers - Occupy 0x80 - 0xD4 of the struct sxg_hw_regs
* Full register descriptions can be found in axgmac.pdf
*/
/* A-XGMAC Configuration Register 0 */
-#define AXGMAC_CFG0_SUB_RESET 0x80000000 /* Sub module reset */
-#define AXGMAC_CFG0_RCNTRL_RESET 0x00400000 /* Receive control reset */
-#define AXGMAC_CFG0_RFUNC_RESET 0x00200000 /* Receive function reset */
-#define AXGMAC_CFG0_TCNTRL_RESET 0x00040000 /* Transmit control reset */
-#define AXGMAC_CFG0_TFUNC_RESET 0x00020000 /* Transmit function reset */
-#define AXGMAC_CFG0_MII_RESET 0x00010000 /* MII Management reset */
+#define AXGMAC_CFG0_SUB_RESET 0x80000000 /* Sub module reset */
+#define AXGMAC_CFG0_RCNTRL_RESET 0x00400000 /* Receive control reset */
+#define AXGMAC_CFG0_RFUNC_RESET 0x00200000 /* Receive function reset */
+#define AXGMAC_CFG0_TCNTRL_RESET 0x00040000 /* Transmit control reset */
+#define AXGMAC_CFG0_TFUNC_RESET 0x00020000 /* Transmit function reset */
+#define AXGMAC_CFG0_MII_RESET 0x00010000 /* MII Management reset */
/* A-XGMAC Configuration Register 1 */
-#define AXGMAC_CFG1_XMT_PAUSE 0x80000000 /* Allow the sending of Pause frames */
-#define AXGMAC_CFG1_XMT_EN 0x40000000 /* Enable transmit */
-#define AXGMAC_CFG1_RCV_PAUSE 0x20000000 /* Allow the detection of Pause frames */
-#define AXGMAC_CFG1_RCV_EN 0x10000000 /* Enable receive */
-#define AXGMAC_CFG1_XMT_STATE 0x04000000 /* Current transmit state - READ ONLY */
-#define AXGMAC_CFG1_RCV_STATE 0x01000000 /* Current receive state - READ ONLY */
-#define AXGMAC_CFG1_XOFF_SHORT 0x00001000 /* Only pause for 64 slot on XOFF */
-#define AXGMAC_CFG1_XMG_FCS1 0x00000400 /* Delay transmit FCS 1 4-byte word */
-#define AXGMAC_CFG1_XMG_FCS2 0x00000800 /* Delay transmit FCS 2 4-byte words */
-#define AXGMAC_CFG1_XMG_FCS3 0x00000C00 /* Delay transmit FCS 3 4-byte words */
-#define AXGMAC_CFG1_RCV_FCS1 0x00000100 /* Delay receive FCS 1 4-byte word */
-#define AXGMAC_CFG1_RCV_FCS2 0x00000200 /* Delay receive FCS 2 4-byte words */
-#define AXGMAC_CFG1_RCV_FCS3 0x00000300 /* Delay receive FCS 3 4-byte words */
-#define AXGMAC_CFG1_PKT_OVERRIDE 0x00000080 /* Per-packet override enable */
-#define AXGMAC_CFG1_SWAP 0x00000040 /* Byte swap enable */
-#define AXGMAC_CFG1_SHORT_ASSERT 0x00000020 /* ASSERT srdrpfrm on short frame (<64) */
-#define AXGMAC_CFG1_RCV_STRICT 0x00000010 /* RCV only 802.3AE when CLEAR */
-#define AXGMAC_CFG1_CHECK_LEN 0x00000008 /* Verify frame length */
-#define AXGMAC_CFG1_GEN_FCS 0x00000004 /* Generate FCS */
-#define AXGMAC_CFG1_PAD_MASK 0x00000003 /* Mask for pad bits */
-#define AXGMAC_CFG1_PAD_64 0x00000001 /* Pad frames to 64 bytes */
-#define AXGMAC_CFG1_PAD_VLAN 0x00000002 /* Detect VLAN and pad to 68 bytes */
-#define AXGMAC_CFG1_PAD_68 0x00000003 /* Pad to 68 bytes */
+/* Allow the sending of Pause frames */
+#define AXGMAC_CFG1_XMT_PAUSE 0x80000000
+#define AXGMAC_CFG1_XMT_EN 0x40000000 /* Enable transmit */
+/* Allow the detection of Pause frames */
+#define AXGMAC_CFG1_RCV_PAUSE 0x20000000
+#define AXGMAC_CFG1_RCV_EN 0x10000000 /* Enable receive */
+/* Current transmit state - READ ONLY */
+#define AXGMAC_CFG1_XMT_STATE 0x04000000
+/* Current receive state - READ ONLY */
+#define AXGMAC_CFG1_RCV_STATE 0x01000000
+/* Only pause for 64 slot on XOFF */
+#define AXGMAC_CFG1_XOFF_SHORT 0x00001000
+/* Delay transmit FCS 1 4-byte word */
+#define AXGMAC_CFG1_XMG_FCS1 0x00000400
+/* Delay transmit FCS 2 4-byte words */
+#define AXGMAC_CFG1_XMG_FCS2 0x00000800
+/* Delay transmit FCS 3 4-byte words */
+#define AXGMAC_CFG1_XMG_FCS3 0x00000C00
+/* Delay receive FCS 1 4-byte word */
+#define AXGMAC_CFG1_RCV_FCS1 0x00000100
+/* Delay receive FCS 2 4-byte words */
+#define AXGMAC_CFG1_RCV_FCS2 0x00000200
+/* Delay receive FCS 3 4-byte words */
+#define AXGMAC_CFG1_RCV_FCS3 0x00000300
+/* Per-packet override enable */
+#define AXGMAC_CFG1_PKT_OVERRIDE 0x00000080
+#define AXGMAC_CFG1_SWAP 0x00000040 /* Byte swap enable */
+/* ASSERT srdrpfrm on short frame (<64) */
+#define AXGMAC_CFG1_SHORT_ASSERT 0x00000020
+/* RCV only 802.3AE when CLEAR */
+#define AXGMAC_CFG1_RCV_STRICT 0x00000010
+#define AXGMAC_CFG1_CHECK_LEN 0x00000008 /* Verify frame length */
+#define AXGMAC_CFG1_GEN_FCS 0x00000004 /* Generate FCS */
+#define AXGMAC_CFG1_PAD_MASK 0x00000003 /* Mask for pad bits */
+#define AXGMAC_CFG1_PAD_64 0x00000001 /* Pad frames to 64 bytes */
+/* Detect VLAN and pad to 68 bytes */
+#define AXGMAC_CFG1_PAD_VLAN 0x00000002
+#define AXGMAC_CFG1_PAD_68 0x00000003 /* Pad to 68 bytes */
/* A-XGMAC Configuration Register 2 */
-#define AXGMAC_CFG2_GEN_PAUSE 0x80000000 /* Generate single pause frame (test) */
-#define AXGMAC_CFG2_LF_MANUAL 0x08000000 /* Manual link fault sequence */
-#define AXGMAC_CFG2_LF_AUTO 0x04000000 /* Auto link fault sequence */
-#define AXGMAC_CFG2_LF_REMOTE 0x02000000 /* Remote link fault (READ ONLY) */
-#define AXGMAC_CFG2_LF_LOCAL 0x01000000 /* Local link fault (READ ONLY) */
-#define AXGMAC_CFG2_IPG_MASK 0x001F0000 /* Inter packet gap */
+/* Generate single pause frame (test) */
+#define AXGMAC_CFG2_GEN_PAUSE 0x80000000
+/* Manual link fault sequence */
+#define AXGMAC_CFG2_LF_MANUAL 0x08000000
+/* Auto link fault sequence */
+#define AXGMAC_CFG2_LF_AUTO 0x04000000
+/* Remote link fault (READ ONLY) */
+#define AXGMAC_CFG2_LF_REMOTE 0x02000000
+/* Local link fault (READ ONLY) */
+#define AXGMAC_CFG2_LF_LOCAL 0x01000000
+#define AXGMAC_CFG2_IPG_MASK 0x001F0000 /* Inter packet gap */
#define AXGMAC_CFG2_IPG_SHIFT 16
-#define AXGMAC_CFG2_PAUSE_XMT 0x00008000 /* Pause transmit module */
-#define AXGMAC_CFG2_IPG_EXTEN 0x00000020 /* Enable IPG extension algorithm */
-#define AXGMAC_CFG2_IPGEX_MASK 0x0000001F /* IPG extension */
+#define AXGMAC_CFG2_PAUSE_XMT 0x00008000 /* Pause transmit module */
+/* Enable IPG extension algorithm */
+#define AXGMAC_CFG2_IPG_EXTEN 0x00000020
+#define AXGMAC_CFG2_IPGEX_MASK 0x0000001F /* IPG extension */
/* A-XGMAC Configuration Register 3 */
-#define AXGMAC_CFG3_RCV_DROP 0xFFFF0000 /* Receive frame drop filter */
-#define AXGMAC_CFG3_RCV_DONT_CARE 0x0000FFFF /* Receive frame don't care filter */
+/* Receive frame drop filter */
+#define AXGMAC_CFG3_RCV_DROP 0xFFFF0000
+/* Receive frame don't care filter */
+#define AXGMAC_CFG3_RCV_DONT_CARE 0x0000FFFF
/* A-XGMAC Station Address Register - Octets 1-4 */
-#define AXGMAC_SARLOW_OCTET_ONE 0xFF000000 /* First octet */
-#define AXGMAC_SARLOW_OCTET_TWO 0x00FF0000 /* Second octet */
-#define AXGMAC_SARLOW_OCTET_THREE 0x0000FF00 /* Third octet */
-#define AXGMAC_SARLOW_OCTET_FOUR 0x000000FF /* Fourth octet */
+#define AXGMAC_SARLOW_OCTET_ONE 0xFF000000 /* First octet */
+#define AXGMAC_SARLOW_OCTET_TWO 0x00FF0000 /* Second octet */
+#define AXGMAC_SARLOW_OCTET_THREE 0x0000FF00 /* Third octet */
+#define AXGMAC_SARLOW_OCTET_FOUR 0x000000FF /* Fourth octet */
/* A-XGMAC Station Address Register - Octets 5-6 */
-#define AXGMAC_SARHIGH_OCTET_FIVE 0xFF000000 /* Fifth octet */
-#define AXGMAC_SARHIGH_OCTET_SIX 0x00FF0000 /* Sixth octet */
+#define AXGMAC_SARHIGH_OCTET_FIVE 0xFF000000 /* Fifth octet */
+#define AXGMAC_SARHIGH_OCTET_SIX 0x00FF0000 /* Sixth octet */
/* A-XGMAC Maximum frame length register */
-#define AXGMAC_MAXFRAME_XMT 0x3FFF0000 /* Maximum transmit frame length */
+/* Maximum transmit frame length */
+#define AXGMAC_MAXFRAME_XMT 0x3FFF0000
#define AXGMAC_MAXFRAME_XMT_SHIFT 16
-#define AXGMAC_MAXFRAME_RCV 0x0000FFFF /* Maximum receive frame length */
+/* Maximum receive frame length */
+#define AXGMAC_MAXFRAME_RCV 0x0000FFFF
/*
* This register doesn't need to be written for standard MTU.
* For jumbo, I'll just statically define the value here. This
/* A-XGMAC AMIIM Command Register */
#define AXGMAC_AMIIM_CMD_START 0x00000008 /* Command start */
#define AXGMAC_AMIIM_CMD_MASK 0x00000007 /* Command */
-#define AXGMAC_AMIIM_CMD_LEGACY_WRITE 1 /* 10/100/1000 Mbps Phy Write */
-#define AXGMAC_AMIIM_CMD_LEGACY_READ 2 /* 10/100/1000 Mbps Phy Read */
+/* 10/100/1000 Mbps Phy Write */
+#define AXGMAC_AMIIM_CMD_LEGACY_WRITE 1
+/* 10/100/1000 Mbps Phy Read */
+#define AXGMAC_AMIIM_CMD_LEGACY_READ 2
#define AXGMAC_AMIIM_CMD_MONITOR_SINGLE 3 /* Monitor single PHY */
-#define AXGMAC_AMIIM_CMD_MONITOR_MULTIPLE 4 /* Monitor multiple contiguous PHYs */
-#define AXGMAC_AMIIM_CMD_10G_OPERATION 5 /* Present AMIIM Field Reg */
-#define AXGMAC_AMIIM_CMD_CLEAR_LINK_FAIL 6 /* Clear Link Fail Bit in MIIM */
+/* Monitor multiple contiguous PHYs */
+#define AXGMAC_AMIIM_CMD_MONITOR_MULTIPLE 4
+/* Present AMIIM Field Reg */
+#define AXGMAC_AMIIM_CMD_10G_OPERATION 5
+/* Clear Link Fail Bit in MIIM */
+#define AXGMAC_AMIIM_CMD_CLEAR_LINK_FAIL 6
/* A-XGMAC AMIIM Field Register */
#define AXGMAC_AMIIM_FIELD_ST 0xC0000000 /* 2-bit ST field */
#define AXGMAC_AMIIM_FIELD_ST_SHIFT 30
#define AXGMAC_AMIIM_FIELD_OP 0x30000000 /* 2-bit OP field */
#define AXGMAC_AMIIM_FIELD_OP_SHIFT 28
-#define AXGMAC_AMIIM_FIELD_PORT_ADDR 0x0F800000 /* Port address field (hstphyadx in spec) */
+/* Port address field (hstphyadx in spec) */
+#define AXGMAC_AMIIM_FIELD_PORT_ADDR 0x0F800000
#define AXGMAC_AMIIM_FIELD_PORT_SHIFT 23
-#define AXGMAC_AMIIM_FIELD_DEV_ADDR 0x007C0000 /* Device address field (hstregadx in spec) */
+/* Device address field (hstregadx in spec) */
+#define AXGMAC_AMIIM_FIELD_DEV_ADDR 0x007C0000
#define AXGMAC_AMIIM_FIELD_DEV_SHIFT 18
#define AXGMAC_AMIIM_FIELD_TA 0x00030000 /* 2-bit TA field */
#define AXGMAC_AMIIM_FIELD_TA_SHIFT 16
-#define AXGMAC_AMIIM_FIELD_DATA 0x0000FFFF // Data field
+#define AXGMAC_AMIIM_FIELD_DATA 0x0000FFFF /* Data field */
/* Values for the AXGMAC_AMIIM_FIELD_OP field in the A-XGMAC AMIIM Field Register */
#define MIIM_OP_ADDR 0 /* MIIM Address set operation */
#define MIIM_OP_READ 2 /* MIIM Read register operation */
#define MIIM_OP_ADDR_SHIFT (MIIM_OP_ADDR << AXGMAC_AMIIM_FIELD_OP_SHIFT)
-/* Values for the AXGMAC_AMIIM_FIELD_PORT_ADDR field in the A-XGMAC AMIIM Field Register */
+/*
+ * Values for the AXGMAC_AMIIM_FIELD_PORT_ADDR field in the A-XGMAC AMIIM
+ * Field Register
+ */
#define MIIM_PORT_NUM 1 /* All Sahara MIIM modules use port 1 */
-/* Values for the AXGMAC_AMIIM_FIELD_DEV_ADDR field in the A-XGMAC AMIIM Field Register */
-#define MIIM_DEV_PHY_PMA 1 /* PHY PMA/PMD module MIIM device number */
-#define MIIM_DEV_PHY_PCS 3 /* PHY PCS module MIIM device number */
-#define MIIM_DEV_PHY_XS 4 /* PHY XS module MIIM device number */
+/*
+ * Values for the AXGMAC_AMIIM_FIELD_DEV_ADDR field in the A-XGMAC AMIIM
+ * Field Register
+ */
+/* PHY PMA/PMD module MIIM device number */
+#define MIIM_DEV_PHY_PMA 1
+/* PHY PCS module MIIM device number */
+#define MIIM_DEV_PHY_PCS 3
+/* PHY XS module MIIM device number */
+#define MIIM_DEV_PHY_XS 4
#define MIIM_DEV_XGXS 5 /* XGXS MIIM device number */
-/* Values for the AXGMAC_AMIIM_FIELD_TA field in the A-XGMAC AMIIM Field Register */
+/*
+ * Values for the AXGMAC_AMIIM_FIELD_TA field in the A-XGMAC AMIIM Field
+ * Register
+ */
#define MIIM_TA_10GB 2 /* set to 2 for 10 GB operation */
/* A-XGMAC AMIIM Configuration Register */
-#define AXGMAC_AMIIM_CFG_NOPREAM 0x00000080 /* Bypass preamble of mngmt frame */
-#define AXGMAC_AMIIM_CFG_HALF_CLOCK 0x0000007F /* half-clock duration of MDC output */
+/* Bypass preamble of mngmt frame */
+#define AXGMAC_AMIIM_CFG_NOPREAM 0x00000080
+/* half-clock duration of MDC output */
+#define AXGMAC_AMIIM_CFG_HALF_CLOCK 0x0000007F
/* A-XGMAC AMIIM Indicator Register */
-#define AXGMAC_AMIIM_INDC_LINK 0x00000010 /* Link status from legacy PHY or MMD */
-#define AXGMAC_AMIIM_INDC_MPHY 0x00000008 /* Multiple phy operation in progress */
-#define AXGMAC_AMIIM_INDC_SPHY 0x00000004 /* Single phy operation in progress */
-#define AXGMAC_AMIIM_INDC_MON 0x00000002 /* Single or multiple monitor cmd */
-#define AXGMAC_AMIIM_INDC_BUSY 0x00000001 /* Set until cmd operation complete */
+/* Link status from legacy PHY or MMD */
+#define AXGMAC_AMIIM_INDC_LINK 0x00000010
+/* Multiple phy operation in progress */
+#define AXGMAC_AMIIM_INDC_MPHY 0x00000008
+/* Single phy operation in progress */
+#define AXGMAC_AMIIM_INDC_SPHY 0x00000004
+/* Single or multiple monitor cmd */
+#define AXGMAC_AMIIM_INDC_MON 0x00000002
+/* Set until cmd operation complete */
+#define AXGMAC_AMIIM_INDC_BUSY 0x00000001
/* Link Status and Control Register */
#define LS_PHY_CLR_RESET 0x80000000 /* Clear reset signal to PHY */
#define LS_SERDES_POWER_DOWN 0x40000000 /* Power down the Sahara Serdes */
#define LS_XGXS_ENABLE 0x20000000 /* Enable the XAUI XGXS logic */
-#define LS_XGXS_CTL 0x10000000 /* Hold XAUI XGXS logic reset until Serdes is up */
-#define LS_SERDES_DOWN 0x08000000 /* When 0, XAUI Serdes is up and initialization is complete */
-#define LS_TRACE_DOWN 0x04000000 /* When 0, Trace Serdes is up and initialization is complete */
-#define LS_PHY_CLK_25MHZ 0x02000000 /* Set PHY clock to 25 MHz (else 156.125 MHz) */
+/* Hold XAUI XGXS logic reset until Serdes is up */
+#define LS_XGXS_CTL 0x10000000
+/* When 0, XAUI Serdes is up and initialization is complete */
+#define LS_SERDES_DOWN 0x08000000
+/* When 0, Trace Serdes is up and initialization is complete */
+#define LS_TRACE_DOWN 0x04000000
+/* Set PHY clock to 25 MHz (else 156.125 MHz) */
+#define LS_PHY_CLK_25MHZ 0x02000000
#define LS_PHY_CLK_EN 0x01000000 /* Enable clock to PHY */
#define LS_XAUI_LINK_UP 0x00000010 /* XAUI link is up */
-#define LS_XAUI_LINK_CHNG 0x00000008 /* XAUI link status has changed */
+/* XAUI link status has changed */
+#define LS_XAUI_LINK_CHNG 0x00000008
#define LS_LINK_ALARM 0x00000004 /* Link alarm pin */
-#define LS_ATTN_CTRL_MASK 0x00000003 /* Mask link attention control bits */
+/* Mask link attention control bits */
+#define LS_ATTN_CTRL_MASK 0x00000003
#define LS_ATTN_ALARM 0x00000000 /* 00 => Attn on link alarm */
-#define LS_ATTN_ALARM_OR_STAT_CHNG 0x00000001 /* 01 => Attn on link alarm or status change */
-#define LS_ATTN_STAT_CHNG 0x00000002 /* 10 => Attn on link status change */
+/* 01 => Attn on link alarm or status change */
+#define LS_ATTN_ALARM_OR_STAT_CHNG 0x00000001
+/* 10 => Attn on link status change */
+#define LS_ATTN_STAT_CHNG 0x00000002
#define LS_ATTN_NONE 0x00000003 /* 11 => no Attn */
/* Link Address High Registers */
-#define LINK_ADDR_ENABLE 0x80000000 /* Enable this link address */
+#define LINK_ADDR_ENABLE 0x80000000 /* Enable this link address */
/*
#define XGXS_ADDRESS_STATUS1 0x0001 /* XS Status 1 */
#define XGXS_ADDRESS_DEVID_LOW 0x0002 /* XS Device ID (low) */
#define XGXS_ADDRESS_DEVID_HIGH 0x0003 /* XS Device ID (high) */
-#define XGXS_ADDRESS_SPEED 0x0004 /* XS Speed ability */
+#define XGXS_ADDRESS_SPEED 0x0004 /* XS Speed ability */
#define XGXS_ADDRESS_DEV_LOW 0x0005 /* XS Devices in package */
#define XGXS_ADDRESS_DEV_HIGH 0x0006 /* XS Devices in package */
#define XGXS_ADDRESS_STATUS2 0x0008 /* XS Status 2 */
#define XGXS_ADDRESS_PKGID_lOW 0x000E /* XS Package Identifier */
-#define XGXS_ADDRESS_PKGID_HIGH 0x000F /* XS Package Identifier */
+#define XGXS_ADDRESS_PKGID_HIGH 0x000F /* XS Package Identifier */
#define XGXS_ADDRESS_LANE_STATUS 0x0018 /* 10G XGXS Lane Status */
#define XGXS_ADDRESS_TEST_CTRL 0x0019 /* 10G XGXS Test Control */
#define XGXS_ADDRESS_RESET_LO1 0x8000 /* Vendor-Specific Reset Lo 1 */
#define XGXS_CONTROL1_SPEED1 0x2000 /* 0 = unspecified, 1 = 10Gb+ */
#define XGXS_CONTROL1_LOWPOWER 0x0400 /* 1 = Low power mode */
#define XGXS_CONTROL1_SPEED2 0x0040 /* Same as SPEED1 (?) */
-#define XGXS_CONTROL1_SPEED 0x003C /* Everything reserved except zero (?) */
+/* Everything reserved except zero (?) */
+#define XGXS_CONTROL1_SPEED 0x003C
/* XS Status 1 register bit definitions */
#define XGXS_STATUS1_FAULT 0x0080 /* Fault detected */
#define XGXS_DEVICES_PCS 0x0008 /* PCS Present */
#define XGXS_DEVICES_WIS 0x0004 /* WIS Present */
#define XGXS_DEVICES_PMD 0x0002 /* PMD/PMA Present */
-#define XGXS_DEVICES_CLAUSE22 0x0001 /* Clause 22 registers present */
+#define XGXS_DEVICES_CLAUSE22 0x0001 /* Clause 22 registers present*/
/* XS Devices High register bit definitions */
#define XGXS_DEVICES_VENDOR2 0x8000 /* Vendor specific device 2 */
#define XGXS_PKGID_HIGH_REV 0x000F /* Revision Number */
/* XS Lane Status register bit definitions */
-#define XGXS_LANE_PHY 0x1000 /* PHY/DTE lane alignment status */
+#define XGXS_LANE_PHY 0x1000 /* PHY/DTE lane alignment status */
#define XGXS_LANE_PATTERN 0x0800 /* Pattern testing ability */
#define XGXS_LANE_LOOPBACK 0x0400 /* PHY loopback ability */
#define XGXS_LANE_SYNC3 0x0008 /* Lane 3 sync */
*
* Full register descriptions can be found in PHY/XENPAK/IEEE specs
*/
-/* LASI (Link Alarm Status Interrupt) Registers (located in MIIM_DEV_PHY_PMA device) */
+/*
+ * LASI (Link Alarm Status Interrupt) Registers (located in
+ * MIIM_DEV_PHY_PMA device)
+ */
#define LASI_RX_ALARM_CONTROL 0x9000 /* LASI RX_ALARM Control */
#define LASI_TX_ALARM_CONTROL 0x9001 /* LASI TX_ALARM Control */
#define LASI_CONTROL 0x9002 /* LASI Control */
#define LASI_STATUS 0x9005 /* LASI Status */
/* LASI_CONTROL bit definitions */
-#define LASI_CTL_RX_ALARM_ENABLE 0x0004 /* Enable RX_ALARM interrupts */
-#define LASI_CTL_TX_ALARM_ENABLE 0x0002 /* Enable TX_ALARM interrupts */
-#define LASI_CTL_LS_ALARM_ENABLE 0x0001 /* Enable Link Status interrupts */
+/* Enable RX_ALARM interrupts */
+#define LASI_CTL_RX_ALARM_ENABLE 0x0004
+/* Enable TX_ALARM interrupts */
+#define LASI_CTL_TX_ALARM_ENABLE 0x0002
+/* Enable Link Status interrupts */
+#define LASI_CTL_LS_ALARM_ENABLE 0x0001
/* LASI_STATUS bit definitions */
#define LASI_STATUS_RX_ALARM 0x0004 /* RX_ALARM status */
/* PHY registers - PMA/PMD (device 1) */
#define PHY_PMA_CONTROL1 0x0000 /* PMA/PMD Control 1 */
#define PHY_PMA_STATUS1 0x0001 /* PMA/PMD Status 1 */
-#define PHY_PMA_RCV_DET 0x000A /* PMA/PMD Receive Signal Detect */
+#define PHY_PMA_RCV_DET 0x000A /* PMA/PMD Receive Signal Detect */
/* other PMA/PMD registers exist and can be defined as needed */
/* PHY registers - PCS (device 3) */
#define PMA_CONTROL1_RESET 0x8000 /* PMA/PMD reset */
/* PHY_PMA_RCV_DET register bit definitions */
-#define PMA_RCV_DETECT 0x0001 /* PMA/PMD receive signal detect */
+#define PMA_RCV_DETECT 0x0001 /* PMA/PMD receive signal detect */
/* PHY_PCS_10G_STATUS1 register bit definitions */
-#define PCS_10B_BLOCK_LOCK 0x0001 /* PCS 10GBASE-R locked to receive blocks */
+#define PCS_10B_BLOCK_LOCK 0x0001 /* PCS 10GBASE-R locked to receive blocks */
/* PHY_XS_LANE_STATUS register bit definitions */
#define XS_LANE_ALIGN 0x1000 /* XS transmit lanes aligned */
#pragma pack(push, 1)
struct xmt_desc {
ushort XmtLen; /* word 0, bits [15:0] - transmit length */
- unsigned char XmtCtl; /* word 0, bits [23:16] - transmit control byte */
- unsigned char Cmd; /* word 0, bits [31:24] - transmit command plus misc. */
- u32 XmtBufId; /* word 1, bits [31:0] - transmit buffer ID */
- unsigned char TcpStrt; /* word 2, bits [7:0] - byte address of TCP header */
- unsigned char IpStrt; /* word 2, bits [15:8] - byte address of IP header */
- ushort IpCkSum; /* word 2, bits [31:16] - partial IP checksum */
- ushort TcpCkSum; /* word 3, bits [15:0] - partial TCP checksum */
+ /* word 0, bits [23:16] - transmit control byte */
+ unsigned char XmtCtl;
+ /* word 0, bits [31:24] - transmit command plus misc. */
+ unsigned char Cmd;
+ /* word 1, bits [31:0] - transmit buffer ID */
+ u32 XmtBufId;
+ /* word 2, bits [7:0] - byte address of TCP header */
+ unsigned char TcpStrt;
+ /* word 2, bits [15:8] - byte address of IP header */
+ unsigned char IpStrt;
+ /* word 2, bits [31:16] - partial IP checksum */
+ ushort IpCkSum;
+ /* word 3, bits [15:0] - partial TCP checksum */
+ ushort TcpCkSum;
ushort Rsvd1; /* word 3, bits [31:16] - PAD */
u32 Rsvd2; /* word 4, bits [31:0] - PAD */
u32 Rsvd3; /* word 5, bits [31:0] - PAD */
#define XMT_DESC_CMD_CSUM_INSERT 1 /* checksum insert descriptor */
#define XMT_DESC_CMD_FORMAT 2 /* format descriptor */
#define XMT_DESC_CMD_PRIME 3 /* prime descriptor */
-#define XMT_DESC_CMD_CODE_SHFT 6 /* comand code shift (shift to bits [31:30] in word 0) */
+/* comand code shift (shift to bits [31:30] in word 0) */
+#define XMT_DESC_CMD_CODE_SHFT 6
/* shifted command codes */
-#define XMT_RAW_SEND (XMT_DESC_CMD_RAW_SEND << XMT_DESC_CMD_CODE_SHFT)
-#define XMT_CSUM_INSERT (XMT_DESC_CMD_CSUM_INSERT << XMT_DESC_CMD_CODE_SHFT)
-#define XMT_FORMAT (XMT_DESC_CMD_FORMAT << XMT_DESC_CMD_CODE_SHFT)
-#define XMT_PRIME (XMT_DESC_CMD_PRIME << XMT_DESC_CMD_CODE_SHFT)
+#define XMT_RAW_SEND (XMT_DESC_CMD_RAW_SEND << XMT_DESC_CMD_CODE_SHFT)
+#define XMT_CSUM_INSERT (XMT_DESC_CMD_CSUM_INSERT << XMT_DESC_CMD_CODE_SHFT)
+#define XMT_FORMAT (XMT_DESC_CMD_FORMAT << XMT_DESC_CMD_CODE_SHFT)
+#define XMT_PRIME (XMT_DESC_CMD_PRIME << XMT_DESC_CMD_CODE_SHFT)
/*
* struct xmt_desc Control Byte (XmtCtl) definitions
* NOTE: These bits do not work on Sahara (Rev A)!
*/
-#define XMT_CTL_PAUSE_FRAME 0x80 /* current frame is a pause control frame (for statistics) */
-#define XMT_CTL_CONTROL_FRAME 0x40 /* current frame is a control frame (for statistics) */
+/* current frame is a pause control frame (for statistics) */
+#define XMT_CTL_PAUSE_FRAME 0x80
+/* current frame is a control frame (for statistics) */
+#define XMT_CTL_CONTROL_FRAME 0x40
#define XMT_CTL_PER_PKT_QUAL 0x20 /* per packet qualifier */
#define XMT_CTL_PAD_MODE_NONE 0x00 /* do not pad frame */
#define XMT_CTL_PAD_MODE_64 0x08 /* pad frame to 64 bytes */
-#define XMT_CTL_PAD_MODE_VLAN_68 0x10 /* pad frame to 64 bytes, and VLAN frames to 68 bytes */
+/* pad frame to 64 bytes, and VLAN frames to 68 bytes */
+#define XMT_CTL_PAD_MODE_VLAN_68 0x10
#define XMT_CTL_PAD_MODE_68 0x18 /* pad frame to 68 bytes */
-#define XMT_CTL_GEN_FCS 0x04 /* generate FCS (CRC) for this frame */
+/* generate FCS (CRC) for this frame */
+#define XMT_CTL_GEN_FCS 0x04
#define XMT_CTL_DELAY_FCS_0 0x00 /* do not delay FCS calcution */
-#define XMT_CTL_DELAY_FCS_1 0x01 /* delay FCS calculation by 1 (4-byte) word */
-#define XMT_CTL_DELAY_FCS_2 0x02 /* delay FCS calculation by 2 (4-byte) words */
-#define XMT_CTL_DELAY_FCS_3 0x03 /* delay FCS calculation by 3 (4-byte) words */
+/* delay FCS calculation by 1 (4-byte) word */
+#define XMT_CTL_DELAY_FCS_1 0x01
+/* delay FCS calculation by 2 (4-byte) words */
+#define XMT_CTL_DELAY_FCS_2 0x02
+/* delay FCS calculation by 3 (4-byte) words */
+#define XMT_CTL_DELAY_FCS_3 0x03
/* struct xmt_desc XmtBufId definition */
-#define XMT_BUF_ID_SHFT 8 /* The Xmt buffer ID is formed by dividing */
- /* the buffer (DRAM) address by 256 (or << 8) */
+/*
+ * The Xmt buffer ID is formed by dividing the buffer (DRAM) address
+ * by 256 (or << 8)
+ */
+
+#define XMT_BUF_ID_SHFT 8
/* Receiver Sequencer Definitions */
/* Receive Event Queue (queues 3 - 6) bit definitions */
-#define RCV_EVTQ_RBFID_MASK 0x0000FFFF /* bit mask for the Receive Buffer ID */
+/* bit mask for the Receive Buffer ID */
+#define RCV_EVTQ_RBFID_MASK 0x0000FFFF
/* Receive Buffer ID definition */
-#define RCV_BUF_ID_SHFT 5 /* The Rcv buffer ID is formed by dividing */
- /* the buffer (DRAM) address by 32 (or << 5) */
+/*
+ * The Rcv buffer ID is formed by dividing the buffer (DRAM) address
+ * by 32 (or << 5)
+ */
+#define RCV_BUF_ID_SHFT 5
/*
* Format of the 18 byte Receive Buffer returned by the
union {
ushort TcpCsum; /* TCP checksum */
struct {
- unsigned char TcpCsumL; /* lower 8 bits of the TCP checksum */
- unsigned char LinkHash; /* Link hash (multicast frames only) */
+ /* lower 8 bits of the TCP checksum */
+ unsigned char TcpCsumL;
+ /* Link hash (multicast frames only) */
+ unsigned char LinkHash;
};
};
- ushort SktHash; /* Socket hash */
- unsigned char TcpHdrOffset; /* TCP header offset into packet */
- unsigned char IpHdrOffset; /* IP header offset into packet */
- u32 TpzHash; /* Toeplitz hash */
- ushort Reserved; /* Reserved */
+ ushort SktHash; /* Socket hash */
+ unsigned char TcpHdrOffset; /* TCP header offset into packet */
+ unsigned char IpHdrOffset; /* IP header offset into packet */
+ u32 TpzHash; /* Toeplitz hash */
+ ushort Reserved; /* Reserved */
};
#pragma pack(pop)
/* Queue definitions */
/* Ingress (read only) queue numbers */
-#define PXY_BUF_Q 0 /* Proxy Buffer Queue */
-#define HST_EVT_Q 1 /* Host Event Queue */
-#define XMT_BUF_Q 2 /* Transmit Buffer Queue */
-#define SKT_EVL_Q 3 /* RcvSqr Socket Event Low Priority Queue */
-#define RCV_EVL_Q 4 /* RcvSqr Rcv Event Low Priority Queue */
-#define SKT_EVH_Q 5 /* RcvSqr Socket Event High Priority Queue */
-#define RCV_EVH_Q 6 /* RcvSqr Rcv Event High Priority Queue */
-#define DMA_RSP_Q 7 /* Dma Response Queue - one per CPU context */
+#define PXY_BUF_Q 0 /* Proxy Buffer Queue */
+#define HST_EVT_Q 1 /* Host Event Queue */
+#define XMT_BUF_Q 2 /* Transmit Buffer Queue */
+#define SKT_EVL_Q 3 /* RcvSqr Socket Event Low Priority Queue */
+#define RCV_EVL_Q 4 /* RcvSqr Rcv Event Low Priority Queue */
+#define SKT_EVH_Q 5 /* RcvSqr Socket Event High Priority Queue */
+#define RCV_EVH_Q 6 /* RcvSqr Rcv Event High Priority Queue */
+#define DMA_RSP_Q 7 /* Dma Response Queue - one per CPU context */
/* Local (read/write) queue numbers */
-#define LOCAL_A_Q 8 /* Spare local Queue */
-#define LOCAL_B_Q 9 /* Spare local Queue */
-#define LOCAL_C_Q 10 /* Spare local Queue */
-#define FSM_EVT_Q 11 /* Finite-State-Machine Event Queue */
-#define SBF_PAL_Q 12 /* System Buffer Physical Address (low) Queue */
-#define SBF_PAH_Q 13 /* System Buffer Physical Address (high) Queue */
-#define SBF_VAL_Q 14 /* System Buffer Virtual Address (low) Queue */
-#define SBF_VAH_Q 15 /* System Buffer Virtual Address (high) Queue */
+#define LOCAL_A_Q 8 /* Spare local Queue */
+#define LOCAL_B_Q 9 /* Spare local Queue */
+#define LOCAL_C_Q 10 /* Spare local Queue */
+#define FSM_EVT_Q 11 /* Finite-State-Machine Event Queue */
+#define SBF_PAL_Q 12 /* System Buffer Physical Address (low) Queue */
+#define SBF_PAH_Q 13 /* System Buffer Physical Address (high) Queue*/
+#define SBF_VAL_Q 14 /* System Buffer Virtual Address (low) Queue */
+#define SBF_VAH_Q 15 /* System Buffer Virtual Address (high) Queue */
/* Egress (write only) queue numbers */
-#define H2G_CMD_Q 16 /* Host to GlbRam DMA Command Queue */
-#define H2D_CMD_Q 17 /* Host to DRAM DMA Command Queue */
-#define G2H_CMD_Q 18 /* GlbRam to Host DMA Command Queue */
-#define G2D_CMD_Q 19 /* GlbRam to DRAM DMA Command Queue */
-#define D2H_CMD_Q 20 /* DRAM to Host DMA Command Queue */
-#define D2G_CMD_Q 21 /* DRAM to GlbRam DMA Command Queue */
-#define D2D_CMD_Q 22 /* DRAM to DRAM DMA Command Queue */
-#define PXL_CMD_Q 23 /* Low Priority Proxy Command Queue */
-#define PXH_CMD_Q 24 /* High Priority Proxy Command Queue */
-#define RSQ_CMD_Q 25 /* Receive Sequencer Command Queue */
-#define RCV_BUF_Q 26 /* Receive Buffer Queue */
+#define H2G_CMD_Q 16 /* Host to GlbRam DMA Command Queue */
+#define H2D_CMD_Q 17 /* Host to DRAM DMA Command Queue */
+#define G2H_CMD_Q 18 /* GlbRam to Host DMA Command Queue */
+#define G2D_CMD_Q 19 /* GlbRam to DRAM DMA Command Queue */
+#define D2H_CMD_Q 20 /* DRAM to Host DMA Command Queue */
+#define D2G_CMD_Q 21 /* DRAM to GlbRam DMA Command Queue */
+#define D2D_CMD_Q 22 /* DRAM to DRAM DMA Command Queue */
+#define PXL_CMD_Q 23 /* Low Priority Proxy Command Queue */
+#define PXH_CMD_Q 24 /* High Priority Proxy Command Queue */
+#define RSQ_CMD_Q 25 /* Receive Sequencer Command Queue */
+#define RCV_BUF_Q 26 /* Receive Buffer Queue */
/* Bit definitions for the Proxy Command queues (PXL_CMD_Q and PXH_CMD_Q) */
-#define PXY_COPY_EN 0x00200000 /* enable copy of xmt descriptor to xmt command queue */
-#define PXY_SIZE_16 0x00000000 /* copy 16 bytes */
-#define PXY_SIZE_32 0x00100000 /* copy 32 bytes */
+/* enable copy of xmt descriptor to xmt command queue */
+#define PXY_COPY_EN 0x00200000
+#define PXY_SIZE_16 0x00000000 /* copy 16 bytes */
+#define PXY_SIZE_32 0x00100000 /* copy 32 bytes */
/* SXG EEPROM/Flash Configuration Definitions */
/* Location of configuration data in EEPROM or Flash */
-#define EEPROM_CONFIG_START_ADDR 0x00 /* start addr for config info in EEPROM */
-#define FLASH_CONFIG_START_ADDR 0x80 /* start addr for config info in Flash */
+/* start addr for config info in EEPROM */
+#define EEPROM_CONFIG_START_ADDR 0x00
+/* start addr for config info in Flash */
+#define FLASH_CONFIG_START_ADDR 0x80
/* Configuration data section defines */
#define HW_CFG_SECTION_SIZE 512 /* size of H/W section */
#define HW_CFG_SECTION_SIZE_A 256 /* size of H/W section (Sahara rev A) */
-#define SW_CFG_SECTION_START 512 /* starting location (offset) of S/W section */
-#define SW_CFG_SECTION_START_A 256 /* starting location (offset) of S/W section (Sahara rev A) */
+/* starting location (offset) of S/W section */
+#define SW_CFG_SECTION_START 512
+/* starting location (offset) of S/W section (Sahara rev A) */
+#define SW_CFG_SECTION_START_A 256
#define SW_CFG_SECTION_SIZE 128 /* size of S/W section */
+/*
+ * H/W configuration data magic word Goes in Addr field of first
+ * struct hw_cfg_data entry
+ */
+#define HW_CFG_MAGIC_WORD 0xA5A5
+/*
+ * H/W configuration data terminator Goes in Addr field of last
+ * struct hw_cfg_data entry
+ */
+#define HW_CFG_TERMINATOR 0xFFFF
-#define HW_CFG_MAGIC_WORD 0xA5A5 /* H/W configuration data magic word */
- /* Goes in Addr field of first struct hw_cfg_data entry */
-#define HW_CFG_TERMINATOR 0xFFFF /* H/W configuration data terminator */
- /* Goes in Addr field of last struct hw_cfg_data entry */
#define SW_CFG_MAGIC_WORD 0x5A5A /* S/W configuration data magic word */
#pragma pack(push, 1)
* Read by the Sahara hardware
*/
struct hw_cfg_data {
- ushort Addr;
- ushort Data;
+ ushort Addr;
+ ushort Data;
};
/*
* Number of struct hw_cfg_data structures to put in the configuration data
- * data structure (struct sxg_config or struct sxg_config_a). The number is computed
- * to fill the entire H/W config section of the structure.
+ * data structure (struct sxg_config or struct sxg_config_a). The number is
+ * computed to fill the entire H/W config section of the structure.
*/
-#define NUM_HW_CFG_ENTRIES (HW_CFG_SECTION_SIZE / sizeof(struct hw_cfg_data))
-#define NUM_HW_CFG_ENTRIES_A (HW_CFG_SECTION_SIZE_A / sizeof(struct hw_cfg_data))
+#define NUM_HW_CFG_ENTRIES \
+ (HW_CFG_SECTION_SIZE / sizeof(struct hw_cfg_data))
+#define NUM_HW_CFG_ENTRIES_A \
+ (HW_CFG_SECTION_SIZE_A / sizeof(struct hw_cfg_data))
/* MAC address structure */
struct sxg_config_mac {
- unsigned char MacAddr[6]; /* MAC Address */
+ unsigned char MacAddr[6]; /* MAC Address */
};
/* FRU data structure */
* at compile time.
*/
compile_time_assert (offsetof(struct sxg_config, SwCfg) == SW_CFG_SECTION_START);
-compile_time_assert (sizeof(struct sxg_config) == HW_CFG_SECTION_SIZE + SW_CFG_SECTION_SIZE);
+compile_time_assert (sizeof(struct sxg_config) == HW_CFG_SECTION_SIZE
+ + SW_CFG_SECTION_SIZE);
-compile_time_assert (offsetof(struct sxg_config_a, SwCfg) == SW_CFG_SECTION_START_A);
-compile_time_assert (sizeof(struct sxg_config_a) == HW_CFG_SECTION_SIZE_A + SW_CFG_SECTION_SIZE);
+compile_time_assert (offsetof(struct sxg_config_a, SwCfg)
+ == SW_CFG_SECTION_START_A);
+compile_time_assert (sizeof(struct sxg_config_a) == HW_CFG_SECTION_SIZE_A
+ + SW_CFG_SECTION_SIZE);
#endif
/*
* Structure used to pass information between driver and user-mode
*/
struct adapt_userinfo {
bool LinkUp;
- /* u32 LinkState; * use LinkUp - any need for other states? */
+ /* use LinkUp - any need for other states? */
+ /* u32 LinkState; */
u32 LinkSpeed; /* not currently needed */
u32 LinkDuplex; /* not currently needed */
- u32 Port; /* not currently needed */
+ u32 Port; /* not currently needed */
u32 PhysPort; /* not currently needed */
ushort PciLanes;
unsigned char MacAddr[6];
/* Sahara (ASIC level) defines */
#define SAHARA_GRAM_SIZE 0x020000 /* GRAM size - 128 KB */
#define SAHARA_DRAM_SIZE 0x200000 /* DRAM size - 2 MB */
-#define SAHARA_QRAM_SIZE 0x004000 /* QRAM size - 16K entries (64 KB) */
-#define SAHARA_WCS_SIZE 0x002000 /* WCS - 8K instructions (x 108 bits) */
+/* QRAM size - 16K entries (64 KB) */
+#define SAHARA_QRAM_SIZE 0x004000
+/* WCS - 8K instructions (x 108 bits) */
+#define SAHARA_WCS_SIZE 0x002000
/* Arabia (board level) defines */
#define FLASH_SIZE 0x080000 /* 512 KB (4 Mb) */
-#define EEPROM_SIZE_XFMR 1024 /* EEPROM size (bytes), including xfmr area */
-#define EEPROM_SIZE_NO_XFMR 640 /* EEPROM size excluding xfmr area (512 + 128) */
-#define EEPROM_SIZE_REV_A 512 /* EEPROM size for Sahara rev A */
+/* EEPROM size (bytes), including xfmr area */
+#define EEPROM_SIZE_XFMR 1024
+/* EEPROM size excluding xfmr area (512 + 128) */
+#define EEPROM_SIZE_NO_XFMR 640
+/* EEPROM size for Sahara rev A */
+#define EEPROM_SIZE_REV_A 512
* type of transceiver.
*/
-/* Download for AEL2005C PHY with SR/LR transceiver (10GBASE-SR or 10GBASE-LR) */
+/*
+ * Download for AEL2005C PHY with SR/LR transceiver
+ * (10GBASE-SR or 10GBASE-LR)
+ */
static struct phy_ucode PhyUcode[] = {
/*
* NOTE: An address of 0 is a special case. When the download routine