+/** @file\r
+ Provides basic function upon network adapter card.\r
+\r
+Copyright (c) 2006, Intel Corporation\r
+All rights reserved. This program and the accompanying materials\r
+are licensed and made available under the terms and conditions of the BSD License\r
+which accompanies this distribution. The full text of the license may be found at\r
+http://opensource.org/licenses/bsd-license.php\r
+\r
+THE PROGRAM IS DISTRIBUTED UNDER THE BSD LICENSE ON AN "AS IS" BASIS,\r
+WITHOUT WARRANTIES OR REPRESENTATIONS OF ANY KIND, EITHER EXPRESS OR IMPLIED.\r
+\r
+**/\r
+\r
+#include "Undi32.h"\r
+\r
+UINT8 basic_config_cmd[22] = {\r
+ 22, 0x08,\r
+ 0, 0,\r
+ 0, (UINT8)0x80,\r
+ 0x32, 0x03,\r
+ 1, 0,\r
+ 0x2E, 0,\r
+ 0x60, 0,\r
+ (UINT8)0xf2, 0x48,\r
+ 0, 0x40,\r
+ (UINT8)0xf2, (UINT8)0x80, // 0x40=Force full-duplex\r
+ 0x3f, 0x05,\r
+};\r
+\r
+//\r
+// How to wait for the command unit to accept a command.\r
+// Typically this takes 0 ticks.\r
+//\r
+#define wait_for_cmd_done(cmd_ioaddr) \\r
+{ \\r
+ INT16 wait_count = 2000; \\r
+ while ((InByte (AdapterInfo, cmd_ioaddr) != 0) && --wait_count >= 0) \\r
+ DelayIt (AdapterInfo, 10); \\r
+ if (wait_count == 0) \\r
+ DelayIt (AdapterInfo, 50); \\r
+}\r
+\r
+\r
+/**\r
+ This function calls the MemIo callback to read a byte from the device's\r
+ address space\r
+ Since UNDI3.0 uses the TmpMemIo function (instead of the callback routine)\r
+ which also takes the UniqueId parameter (as in UNDI3.1 spec) we don't have\r
+ to make undi3.0 a special case\r
+\r
+ @param Port Which port to read from.\r
+\r
+ @retval Results The data read from the port.\r
+\r
+**/\r
+// TODO: AdapterInfo - add argument and description to function comment\r
+UINT8\r
+InByte (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ IN UINT32 Port\r
+ )\r
+{\r
+ UINT8 Results;\r
+\r
+ (*AdapterInfo->Mem_Io) (\r
+ AdapterInfo->Unique_ID,\r
+ PXE_MEM_READ,\r
+ 1,\r
+ (UINT64)Port,\r
+ (UINT64) (UINTN) &Results\r
+ );\r
+ return Results;\r
+}\r
+\r
+\r
+/**\r
+ This function calls the MemIo callback to read a word from the device's\r
+ address space\r
+ Since UNDI3.0 uses the TmpMemIo function (instead of the callback routine)\r
+ which also takes the UniqueId parameter (as in UNDI3.1 spec) we don't have\r
+ to make undi3.0 a special case\r
+\r
+ @param Port Which port to read from.\r
+\r
+ @retval Results The data read from the port.\r
+\r
+**/\r
+// TODO: AdapterInfo - add argument and description to function comment\r
+UINT16\r
+InWord (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ IN UINT32 Port\r
+ )\r
+{\r
+ UINT16 Results;\r
+\r
+ (*AdapterInfo->Mem_Io) (\r
+ AdapterInfo->Unique_ID,\r
+ PXE_MEM_READ,\r
+ 2,\r
+ (UINT64)Port,\r
+ (UINT64)(UINTN)&Results\r
+ );\r
+ return Results;\r
+}\r
+\r
+\r
+/**\r
+ This function calls the MemIo callback to read a dword from the device's\r
+ address space\r
+ Since UNDI3.0 uses the TmpMemIo function (instead of the callback routine)\r
+ which also takes the UniqueId parameter (as in UNDI3.1 spec) we don't have\r
+ to make undi3.0 a special case\r
+\r
+ @param Port Which port to read from.\r
+\r
+ @retval Results The data read from the port.\r
+\r
+**/\r
+// TODO: AdapterInfo - add argument and description to function comment\r
+UINT32\r
+InLong (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ IN UINT32 Port\r
+ )\r
+{\r
+ UINT32 Results;\r
+\r
+ (*AdapterInfo->Mem_Io) (\r
+ AdapterInfo->Unique_ID,\r
+ PXE_MEM_READ,\r
+ 4,\r
+ (UINT64)Port,\r
+ (UINT64)(UINTN)&Results\r
+ );\r
+ return Results;\r
+}\r
+\r
+\r
+/**\r
+ This function calls the MemIo callback to write a byte from the device's\r
+ address space\r
+ Since UNDI3.0 uses the TmpMemIo function (instead of the callback routine)\r
+ which also takes the UniqueId parameter (as in UNDI3.1 spec) we don't have\r
+ to make undi3.0 a special case\r
+\r
+ @param Data Data to write to Port.\r
+ @param Port Which port to write to.\r
+\r
+ @return none\r
+\r
+**/\r
+// TODO: AdapterInfo - add argument and description to function comment\r
+VOID\r
+OutByte (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ IN UINT8 Data,\r
+ IN UINT32 Port\r
+ )\r
+{\r
+ UINT8 Val;\r
+\r
+ Val = Data;\r
+ (*AdapterInfo->Mem_Io) (\r
+ AdapterInfo->Unique_ID,\r
+ PXE_MEM_WRITE,\r
+ 1,\r
+ (UINT64)Port,\r
+ (UINT64)(UINTN)(UINTN)&Val\r
+ );\r
+ return ;\r
+}\r
+\r
+\r
+/**\r
+ This function calls the MemIo callback to write a word from the device's\r
+ address space\r
+ Since UNDI3.0 uses the TmpMemIo function (instead of the callback routine)\r
+ which also takes the UniqueId parameter (as in UNDI3.1 spec) we don't have\r
+ to make undi3.0 a special case\r
+\r
+ @param Data Data to write to Port.\r
+ @param Port Which port to write to.\r
+\r
+ @return none\r
+\r
+**/\r
+// TODO: AdapterInfo - add argument and description to function comment\r
+VOID\r
+OutWord (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ IN UINT16 Data,\r
+ IN UINT32 Port\r
+ )\r
+{\r
+ UINT16 Val;\r
+\r
+ Val = Data;\r
+ (*AdapterInfo->Mem_Io) (\r
+ AdapterInfo->Unique_ID,\r
+ PXE_MEM_WRITE,\r
+ 2,\r
+ (UINT64)Port,\r
+ (UINT64)(UINTN)&Val\r
+ );\r
+ return ;\r
+}\r
+\r
+\r
+/**\r
+ This function calls the MemIo callback to write a dword from the device's\r
+ address space\r
+ Since UNDI3.0 uses the TmpMemIo function (instead of the callback routine)\r
+ which also takes the UniqueId parameter (as in UNDI3.1 spec) we don't have\r
+ to make undi3.0 a special case\r
+\r
+ @param Data Data to write to Port.\r
+ @param Port Which port to write to.\r
+\r
+ @return none\r
+\r
+**/\r
+// TODO: AdapterInfo - add argument and description to function comment\r
+VOID\r
+OutLong (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ IN UINT32 Data,\r
+ IN UINT32 Port\r
+ )\r
+{\r
+ UINT32 Val;\r
+\r
+ Val = Data;\r
+ (*AdapterInfo->Mem_Io) (\r
+ AdapterInfo->Unique_ID,\r
+ PXE_MEM_WRITE,\r
+ 4,\r
+ (UINT64)Port,\r
+ (UINT64)(UINTN)&Val\r
+ );\r
+ return ;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+ @param MemAddr TODO: add argument description\r
+ @param Size TODO: add argument description\r
+ @param Direction TODO: add argument description\r
+ @param MappedAddr TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+UINTN\r
+MapIt (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ IN UINT64 MemAddr,\r
+ IN UINT32 Size,\r
+ IN UINT32 Direction,\r
+ OUT UINT64 MappedAddr\r
+ )\r
+{\r
+ UINT64 *PhyAddr;\r
+\r
+ PhyAddr = (UINT64 *) (UINTN) MappedAddr;\r
+ //\r
+ // mapping is different for theold and new NII protocols\r
+ //\r
+ if (AdapterInfo->VersionFlag == 0x30) {\r
+ if (AdapterInfo->Virt2Phys_30 == (VOID *) NULL) {\r
+ *PhyAddr = (UINT64) AdapterInfo->MemoryPtr;\r
+ } else {\r
+ (*AdapterInfo->Virt2Phys_30) (MemAddr, (UINT64) (UINTN) PhyAddr);\r
+ }\r
+\r
+ if (*PhyAddr > FOUR_GIGABYTE) {\r
+ return PXE_STATCODE_INVALID_PARAMETER;\r
+ }\r
+ } else {\r
+ if (AdapterInfo->Map_Mem == (VOID *) NULL) {\r
+ //\r
+ // this UNDI cannot handle addresses beyond 4 GB without a map routine\r
+ //\r
+ if (MemAddr > FOUR_GIGABYTE) {\r
+ return PXE_STATCODE_INVALID_PARAMETER;\r
+ } else {\r
+ *PhyAddr = MemAddr;\r
+ }\r
+ } else {\r
+ (*AdapterInfo->Map_Mem) (\r
+ AdapterInfo->Unique_ID,\r
+ MemAddr,\r
+ Size,\r
+ Direction,\r
+ MappedAddr\r
+ );\r
+ }\r
+ }\r
+\r
+ return PXE_STATCODE_SUCCESS;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+ @param MemAddr TODO: add argument description\r
+ @param Size TODO: add argument description\r
+ @param Direction TODO: add argument description\r
+ @param MappedAddr TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+VOID\r
+UnMapIt (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ IN UINT64 MemAddr,\r
+ IN UINT32 Size,\r
+ IN UINT32 Direction,\r
+ IN UINT64 MappedAddr\r
+ )\r
+{\r
+ if (AdapterInfo->VersionFlag > 0x30) {\r
+ //\r
+ // no mapping service\r
+ //\r
+ if (AdapterInfo->UnMap_Mem != (VOID *) NULL) {\r
+ (*AdapterInfo->UnMap_Mem) (\r
+ AdapterInfo->Unique_ID,\r
+ MemAddr,\r
+ Size,\r
+ Direction,\r
+ MappedAddr\r
+ );\r
+\r
+ }\r
+ }\r
+\r
+ return ;\r
+}\r
+\r
+\r
+/**\r
+\r
+ @param AdapterInfo Pointer to the NIC data structure\r
+ information which the UNDI driver is\r
+ layering on..\r
+\r
+\r
+**/\r
+// TODO: MicroSeconds - add argument and description to function comment\r
+VOID\r
+DelayIt (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ UINT16 MicroSeconds\r
+ )\r
+{\r
+ if (AdapterInfo->VersionFlag == 0x30) {\r
+ (*AdapterInfo->Delay_30) (MicroSeconds);\r
+ } else {\r
+ (*AdapterInfo->Delay) (AdapterInfo->Unique_ID, MicroSeconds);\r
+ }\r
+}\r
+\r
+\r
+/**\r
+\r
+ @param AdapterInfo Pointer to the NIC data structure\r
+ information which the UNDI driver is\r
+ layering on..\r
+\r
+\r
+**/\r
+// TODO: flag - add argument and description to function comment\r
+VOID\r
+BlockIt (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ UINT32 flag\r
+ )\r
+{\r
+ if (AdapterInfo->VersionFlag == 0x30) {\r
+ (*AdapterInfo->Block_30) (flag);\r
+ } else {\r
+ (*AdapterInfo->Block) (AdapterInfo->Unique_ID, flag);\r
+ }\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+UINT8\r
+Load_Base_Regs (\r
+ NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ //\r
+ // we will use the linear (flat) memory model and fill our base registers\r
+ // with 0's so that the entire physical address is our offset\r
+ //\r
+ //\r
+ // we reset the statistics totals here because this is where we are loading stats addr\r
+ //\r
+ AdapterInfo->RxTotals = 0;\r
+ AdapterInfo->TxTotals = 0;\r
+\r
+ //\r
+ // Load the statistics block address.\r
+ //\r
+ wait_for_cmd_done (AdapterInfo->ioaddr + SCBCmd);\r
+ OutLong (AdapterInfo, (UINT32) AdapterInfo->stat_phy_addr, AdapterInfo->ioaddr + SCBPointer);\r
+ OutByte (AdapterInfo, CU_STATSADDR, AdapterInfo->ioaddr + SCBCmd);\r
+ AdapterInfo->statistics->done_marker = 0;\r
+\r
+ wait_for_cmd_done (AdapterInfo->ioaddr + SCBCmd);\r
+ OutLong (AdapterInfo, 0, AdapterInfo->ioaddr + SCBPointer);\r
+ OutByte (AdapterInfo, RX_ADDR_LOAD, AdapterInfo->ioaddr + SCBCmd);\r
+\r
+ wait_for_cmd_done (AdapterInfo->ioaddr + SCBCmd);\r
+ OutLong (AdapterInfo, 0, AdapterInfo->ioaddr + SCBPointer);\r
+ OutByte (AdapterInfo, CU_CMD_BASE, AdapterInfo->ioaddr + SCBCmd);\r
+\r
+ return 0;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+ @param cmd_ptr TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+UINT8\r
+IssueCB (\r
+ NIC_DATA_INSTANCE *AdapterInfo,\r
+ TxCB *cmd_ptr\r
+ )\r
+{\r
+ UINT16 status;\r
+\r
+ wait_for_cmd_done (AdapterInfo->ioaddr + SCBCmd);\r
+\r
+ //\r
+ // read the CU status, if it is idle, write the address of cb_ptr\r
+ // in the scbpointer and issue a cu_start,\r
+ // if it is suspended, remove the suspend bit in the previous command\r
+ // block and issue a resume\r
+ //\r
+ // Ensure that the CU Active Status bit is not on from previous CBs.\r
+ //\r
+ status = InWord (AdapterInfo, AdapterInfo->ioaddr + SCBStatus);\r
+\r
+ //\r
+ // Skip acknowledging the interrupt if it is not already set\r
+ //\r
+\r
+ //\r
+ // ack only the cna the integer\r
+ //\r
+ if ((status & SCB_STATUS_CNA) != 0) {\r
+ OutWord (AdapterInfo, SCB_STATUS_CNA, AdapterInfo->ioaddr + SCBStatus);\r
+\r
+ }\r
+\r
+ if ((status & SCB_STATUS_CU_MASK) == SCB_STATUS_CU_IDLE) {\r
+ //\r
+ // give a cu_start\r
+ //\r
+ OutLong (AdapterInfo, cmd_ptr->PhysTCBAddress, AdapterInfo->ioaddr + SCBPointer);\r
+ OutByte (AdapterInfo, CU_START, AdapterInfo->ioaddr + SCBCmd);\r
+ } else {\r
+ //\r
+ // either active or suspended, give a resume\r
+ //\r
+\r
+ cmd_ptr->PrevTCBVirtualLinkPtr->cb_header.command &= ~(CmdSuspend | CmdIntr);\r
+ OutByte (AdapterInfo, CU_RESUME, AdapterInfo->ioaddr + SCBCmd);\r
+ }\r
+\r
+ return 0;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+UINT8\r
+Configure (\r
+ NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ //\r
+ // all command blocks are of TxCB format\r
+ //\r
+ TxCB *cmd_ptr;\r
+ UINT8 *data_ptr;\r
+ volatile INT16 Index;\r
+ UINT8 my_filter;\r
+\r
+ cmd_ptr = GetFreeCB (AdapterInfo);\r
+ data_ptr = (UINT8 *) (&cmd_ptr->PhysTBDArrayAddres);\r
+\r
+ //\r
+ // start the config data right after the command header\r
+ //\r
+ for (Index = 0; Index < sizeof (basic_config_cmd); Index++) {\r
+ data_ptr[Index] = basic_config_cmd[Index];\r
+ }\r
+\r
+ my_filter = (UINT8) ((AdapterInfo->Rx_Filter & PXE_OPFLAGS_RECEIVE_FILTER_PROMISCUOUS) ? 1 : 0);\r
+ my_filter = (UINT8) (my_filter | ((AdapterInfo->Rx_Filter & PXE_OPFLAGS_RECEIVE_FILTER_BROADCAST) ? 0 : 2));\r
+\r
+ data_ptr[15] = (UINT8) (data_ptr[15] | my_filter);\r
+ data_ptr[19] = (UINT8) (AdapterInfo->Duplex ? 0xC0 : 0x80);\r
+ data_ptr[21] = (UINT8) ((AdapterInfo->Rx_Filter & PXE_OPFLAGS_RECEIVE_FILTER_ALL_MULTICAST) ? 0x0D : 0x05);\r
+\r
+ //\r
+ // check if we have to use the AUI port instead\r
+ //\r
+ if ((AdapterInfo->PhyRecord[0] & 0x8000) != 0) {\r
+ data_ptr[15] |= 0x80;\r
+ data_ptr[8] = 0;\r
+ }\r
+\r
+ BlockIt (AdapterInfo, TRUE);\r
+ cmd_ptr->cb_header.command = CmdSuspend | CmdConfigure;\r
+\r
+ IssueCB (AdapterInfo, cmd_ptr);\r
+ wait_for_cmd_done (AdapterInfo->ioaddr + SCBCmd);\r
+\r
+ BlockIt (AdapterInfo, FALSE);\r
+\r
+ CommandWaitForCompletion (cmd_ptr, AdapterInfo);\r
+\r
+ //\r
+ // restore the cb values for tx\r
+ //\r
+ cmd_ptr->PhysTBDArrayAddres = cmd_ptr->PhysArrayAddr;\r
+ cmd_ptr->ByteCount = cmd_ptr->Threshold = cmd_ptr->TBDCount = 0;\r
+ //\r
+ // fields beyond the immediatedata are assumed to be safe\r
+ // add the CB to the free list again\r
+ //\r
+ SetFreeCB (AdapterInfo, cmd_ptr);\r
+ return 0;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+UINT8\r
+E100bSetupIAAddr (\r
+ NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ //\r
+ // all command blocks are of TxCB format\r
+ //\r
+ TxCB *cmd_ptr;\r
+ UINT16 *data_ptr;\r
+ UINT16 *eaddrs;\r
+\r
+ eaddrs = (UINT16 *) AdapterInfo->CurrentNodeAddress;\r
+\r
+ cmd_ptr = GetFreeCB (AdapterInfo);\r
+ data_ptr = (UINT16 *) (&cmd_ptr->PhysTBDArrayAddres);\r
+\r
+ //\r
+ // AVOID a bug (?!) here by marking the command already completed.\r
+ //\r
+ cmd_ptr->cb_header.command = (CmdSuspend | CmdIASetup);\r
+ cmd_ptr->cb_header.status = 0;\r
+ data_ptr[0] = eaddrs[0];\r
+ data_ptr[1] = eaddrs[1];\r
+ data_ptr[2] = eaddrs[2];\r
+\r
+ BlockIt (AdapterInfo, TRUE);\r
+ IssueCB (AdapterInfo, cmd_ptr);\r
+ wait_for_cmd_done (AdapterInfo->ioaddr + SCBCmd);\r
+ BlockIt (AdapterInfo, FALSE);\r
+\r
+ CommandWaitForCompletion (cmd_ptr, AdapterInfo);\r
+\r
+ //\r
+ // restore the cb values for tx\r
+ //\r
+ cmd_ptr->PhysTBDArrayAddres = cmd_ptr->PhysArrayAddr;\r
+ cmd_ptr->ByteCount = cmd_ptr->Threshold = cmd_ptr->TBDCount = 0;\r
+ //\r
+ // fields beyond the immediatedata are assumed to be safe\r
+ // add the CB to the free list again\r
+ //\r
+ SetFreeCB (AdapterInfo, cmd_ptr);\r
+ return 0;\r
+}\r
+\r
+\r
+/**\r
+ Instructs the NIC to stop receiving packets.\r
+\r
+ @param AdapterInfo Pointer to the NIC data structure\r
+ information which the UNDI driver is\r
+ layering on..\r
+\r
+\r
+**/\r
+VOID\r
+StopRU (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ if (AdapterInfo->Receive_Started) {\r
+\r
+ //\r
+ // Todo: verify that we must wait for previous command completion.\r
+ //\r
+ wait_for_cmd_done (AdapterInfo->ioaddr + SCBCmd);\r
+\r
+ //\r
+ // Disable interrupts, and stop the chip's Rx process.\r
+ //\r
+ OutWord (AdapterInfo, INT_MASK, AdapterInfo->ioaddr + SCBCmd);\r
+ OutWord (AdapterInfo, INT_MASK | RX_ABORT, AdapterInfo->ioaddr + SCBCmd);\r
+\r
+ AdapterInfo->Receive_Started = FALSE;\r
+ }\r
+\r
+ return ;\r
+}\r
+\r
+\r
+/**\r
+ Instructs the NIC to start receiving packets.\r
+\r
+ @param AdapterInfo Pointer to the NIC data structure\r
+ information which the UNDI driver is\r
+ layering on..\r
+\r
+ @retval 0 Successful\r
+ @retval -1 Already Started\r
+\r
+**/\r
+INT8\r
+StartRU (\r
+ NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+\r
+ if (AdapterInfo->Receive_Started) {\r
+ //\r
+ // already started\r
+ //\r
+ return -1;\r
+ }\r
+\r
+ AdapterInfo->cur_rx_ind = 0;\r
+ AdapterInfo->Int_Status = 0;\r
+\r
+ wait_for_cmd_done (AdapterInfo->ioaddr + SCBCmd);\r
+\r
+ OutLong (AdapterInfo, (UINT32) AdapterInfo->rx_phy_addr, AdapterInfo->ioaddr + SCBPointer);\r
+ OutByte (AdapterInfo, RX_START, AdapterInfo->ioaddr + SCBCmd);\r
+\r
+ wait_for_cmd_done (AdapterInfo->ioaddr + SCBCmd);\r
+\r
+ AdapterInfo->Receive_Started = TRUE;\r
+ return 0;\r
+}\r
+\r
+\r
+/**\r
+ Configures the chip. This routine expects the NIC_DATA_INSTANCE structure to be filled in.\r
+\r
+ @param AdapterInfo Pointer to the NIC data structure\r
+ information which the UNDI driver is\r
+ layering on..\r
+\r
+ @retval 0 Successful\r
+ @retval PXE_STATCODE_NOT_ENOUGH_MEMORY Insufficient length of locked memory\r
+ @retval other Failure initializing chip\r
+\r
+**/\r
+UINTN\r
+E100bInit (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ PCI_CONFIG_HEADER *CfgHdr;\r
+ UINTN stat;\r
+ UINTN rx_size;\r
+ UINTN tx_size;\r
+\r
+ if (AdapterInfo->MemoryLength < MEMORY_NEEDED) {\r
+ return PXE_STATCODE_NOT_ENOUGH_MEMORY;\r
+ }\r
+\r
+ stat = MapIt (\r
+ AdapterInfo,\r
+ AdapterInfo->MemoryPtr,\r
+ AdapterInfo->MemoryLength,\r
+ TO_AND_FROM_DEVICE,\r
+ (UINT64)(UINTN) &AdapterInfo->Mapped_MemoryPtr\r
+ );\r
+\r
+ if (stat != 0) {\r
+ return stat;\r
+ }\r
+\r
+ CfgHdr = (PCI_CONFIG_HEADER *) &(AdapterInfo->Config[0]);\r
+\r
+ //\r
+ // fill in the ioaddr, int... from the config space\r
+ //\r
+ AdapterInfo->int_num = CfgHdr->int_line;\r
+\r
+ //\r
+ // we don't need to validate integer number, what if they don't want to assign one?\r
+ // if (AdapterInfo->int_num == 0 || AdapterInfo->int_num == 0xff)\r
+ // return PXE_STATCODE_DEVICE_FAILURE;\r
+ //\r
+ AdapterInfo->ioaddr = 0;\r
+ AdapterInfo->VendorID = CfgHdr->VendorID;\r
+ AdapterInfo->DeviceID = CfgHdr->DeviceID;\r
+ AdapterInfo->RevID = CfgHdr->RevID;\r
+ AdapterInfo->SubVendorID = CfgHdr->SubVendorID;\r
+ AdapterInfo->SubSystemID = CfgHdr->SubSystemID;\r
+ AdapterInfo->flash_addr = 0;\r
+\r
+ //\r
+ // Read the station address EEPROM before doing the reset.\r
+ // Perhaps this should even be done before accepting the device,\r
+ // then we wouldn't have a device name with which to report the error.\r
+ //\r
+ if (E100bReadEepromAndStationAddress (AdapterInfo) != 0) {\r
+ return PXE_STATCODE_DEVICE_FAILURE;\r
+\r
+ }\r
+ //\r
+ // ## calculate the buffer #s depending on memory given\r
+ // ## calculate the rx and tx ring pointers\r
+ //\r
+\r
+ AdapterInfo->TxBufCnt = TX_BUFFER_COUNT;\r
+ AdapterInfo->RxBufCnt = RX_BUFFER_COUNT;\r
+ rx_size = (AdapterInfo->RxBufCnt * sizeof (RxFD));\r
+ tx_size = (AdapterInfo->TxBufCnt * sizeof (TxCB));\r
+ AdapterInfo->rx_ring = (RxFD *) (UINTN) (AdapterInfo->MemoryPtr);\r
+ AdapterInfo->tx_ring = (TxCB *) (UINTN) (AdapterInfo->MemoryPtr + rx_size);\r
+ AdapterInfo->statistics = (struct speedo_stats *) (UINTN) (AdapterInfo->MemoryPtr + rx_size + tx_size);\r
+\r
+ AdapterInfo->rx_phy_addr = AdapterInfo->Mapped_MemoryPtr;\r
+ AdapterInfo->tx_phy_addr = AdapterInfo->Mapped_MemoryPtr + rx_size;\r
+ AdapterInfo->stat_phy_addr = AdapterInfo->tx_phy_addr + tx_size;\r
+\r
+ //\r
+ // auto detect.\r
+ //\r
+ AdapterInfo->PhyAddress = 0xFF;\r
+ AdapterInfo->Rx_Filter = PXE_OPFLAGS_RECEIVE_FILTER_BROADCAST;\r
+ AdapterInfo->Receive_Started = FALSE;\r
+ AdapterInfo->mcast_list.list_len = 0;\r
+ return InitializeChip (AdapterInfo);\r
+}\r
+\r
+\r
+/**\r
+ Sets the interrupt state for the NIC.\r
+\r
+ @param AdapterInfo Pointer to the NIC data structure\r
+ information which the UNDI driver is\r
+ layering on..\r
+\r
+ @retval 0 Successful\r
+\r
+**/\r
+UINT8\r
+E100bSetInterruptState (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ //\r
+ // don't set receive interrupt if receiver is disabled...\r
+ //\r
+ UINT16 cmd_word;\r
+\r
+ if ((AdapterInfo->int_mask & PXE_OPFLAGS_INTERRUPT_RECEIVE) != 0) {\r
+ cmd_word = InWord (AdapterInfo, AdapterInfo->ioaddr + SCBCmd);\r
+ cmd_word &= ~INT_MASK;\r
+ OutWord (AdapterInfo, cmd_word, AdapterInfo->ioaddr + SCBCmd);\r
+ } else {\r
+ //\r
+ // disable ints, should not be given for SW Int.\r
+ //\r
+ OutWord (AdapterInfo, INT_MASK, AdapterInfo->ioaddr + SCBCmd);\r
+ }\r
+\r
+ if ((AdapterInfo->int_mask & PXE_OPFLAGS_INTERRUPT_SOFTWARE) != 0) {\r
+ //\r
+ // reset the bit in our mask, it is only one time!!\r
+ //\r
+ AdapterInfo->int_mask &= ~(PXE_OPFLAGS_INTERRUPT_SOFTWARE);\r
+ cmd_word = InWord (AdapterInfo, AdapterInfo->ioaddr + SCBCmd);\r
+ cmd_word |= DRVR_INT;\r
+ OutWord (AdapterInfo, cmd_word, AdapterInfo->ioaddr + SCBCmd);\r
+ }\r
+\r
+ return 0;\r
+}\r
+//\r
+// we are not going to disable broadcast for the WOL's sake!\r
+//\r
+\r
+/**\r
+ Instructs the NIC to start receiving packets.\r
+\r
+ @param AdapterInfo Pointer to the NIC data structure\r
+ information which the UNDI driver is\r
+ layering on.. new_filter\r
+ - cpb -\r
+ cpbsize -\r
+\r
+ @retval 0 Successful\r
+ @retval -1 Already Started\r
+\r
+**/\r
+UINTN\r
+E100bSetfilter (\r
+ NIC_DATA_INSTANCE *AdapterInfo,\r
+ UINT16 new_filter,\r
+ UINT64 cpb,\r
+ UINT32 cpbsize\r
+ )\r
+{\r
+ PXE_CPB_RECEIVE_FILTERS *mc_list = (PXE_CPB_RECEIVE_FILTERS *) (UINTN)cpb;\r
+ UINT16 cfg_flt;\r
+ UINT16 old_filter;\r
+ UINT16 Index;\r
+ UINT16 Index2;\r
+ UINT16 mc_count;\r
+ TxCB *cmd_ptr;\r
+ struct MC_CB_STRUCT *data_ptr;\r
+ UINT16 mc_byte_cnt;\r
+\r
+ old_filter = AdapterInfo->Rx_Filter;\r
+\r
+ //\r
+ // only these bits need a change in the configuration\r
+ // actually change in bcast requires configure but we ignore that change\r
+ //\r
+ cfg_flt = PXE_OPFLAGS_RECEIVE_FILTER_PROMISCUOUS |\r
+ PXE_OPFLAGS_RECEIVE_FILTER_ALL_MULTICAST;\r
+\r
+ if ((old_filter & cfg_flt) != (new_filter & cfg_flt)) {\r
+ XmitWaitForCompletion (AdapterInfo);\r
+\r
+ if (AdapterInfo->Receive_Started) {\r
+ StopRU (AdapterInfo);\r
+ }\r
+\r
+ AdapterInfo->Rx_Filter = (UINT8) (new_filter | PXE_OPFLAGS_RECEIVE_FILTER_BROADCAST);\r
+ Configure (AdapterInfo);\r
+ }\r
+\r
+ //\r
+ // check if mcast setting changed\r
+ //\r
+ if ( ((new_filter & PXE_OPFLAGS_RECEIVE_FILTER_FILTERED_MULTICAST) !=\r
+ (old_filter & PXE_OPFLAGS_RECEIVE_FILTER_FILTERED_MULTICAST) ) ||\r
+ (mc_list != NULL) ) {\r
+\r
+\r
+ if (mc_list != NULL) {\r
+ mc_count = AdapterInfo->mcast_list.list_len = (UINT16) (cpbsize / PXE_MAC_LENGTH);\r
+\r
+ for (Index = 0; (Index < mc_count && Index < MAX_MCAST_ADDRESS_CNT); Index++) {\r
+ for (Index2 = 0; Index2 < PXE_MAC_LENGTH; Index2++) {\r
+ AdapterInfo->mcast_list.mc_list[Index][Index2] = mc_list->MCastList[Index][Index2];\r
+ }\r
+ }\r
+ }\r
+\r
+ //\r
+ // are we setting the list or resetting??\r
+ //\r
+ if ((new_filter & PXE_OPFLAGS_RECEIVE_FILTER_FILTERED_MULTICAST) != 0) {\r
+ //\r
+ // we are setting a new list!\r
+ //\r
+ mc_count = AdapterInfo->mcast_list.list_len;\r
+ //\r
+ // count should be the actual # of bytes in the list\r
+ // so multiply this with 6\r
+ //\r
+ mc_byte_cnt = (UINT16) ((mc_count << 2) + (mc_count << 1));\r
+ AdapterInfo->Rx_Filter |= PXE_OPFLAGS_RECEIVE_FILTER_FILTERED_MULTICAST;\r
+ } else {\r
+ //\r
+ // disabling the list in the NIC.\r
+ //\r
+ mc_byte_cnt = mc_count = 0;\r
+ AdapterInfo->Rx_Filter &= (~PXE_OPFLAGS_RECEIVE_FILTER_FILTERED_MULTICAST);\r
+ }\r
+\r
+ //\r
+ // before issuing any new command!\r
+ //\r
+ XmitWaitForCompletion (AdapterInfo);\r
+\r
+ if (AdapterInfo->Receive_Started) {\r
+ StopRU (AdapterInfo);\r
+\r
+ }\r
+\r
+ cmd_ptr = GetFreeCB (AdapterInfo);\r
+ if (cmd_ptr == NULL) {\r
+ return PXE_STATCODE_QUEUE_FULL;\r
+ }\r
+ //\r
+ // fill the command structure and issue\r
+ //\r
+ data_ptr = (struct MC_CB_STRUCT *) (&cmd_ptr->PhysTBDArrayAddres);\r
+ //\r
+ // first 2 bytes are the count;\r
+ //\r
+ data_ptr->count = mc_byte_cnt;\r
+ for (Index = 0; Index < mc_count; Index++) {\r
+ for (Index2 = 0; Index2 < PXE_HWADDR_LEN_ETHER; Index2++) {\r
+ data_ptr->m_list[Index][Index2] = AdapterInfo->mcast_list.mc_list[Index][Index2];\r
+ }\r
+ }\r
+\r
+ cmd_ptr->cb_header.command = CmdSuspend | CmdMulticastList;\r
+ cmd_ptr->cb_header.status = 0;\r
+\r
+ BlockIt (AdapterInfo, TRUE);\r
+ IssueCB (AdapterInfo, cmd_ptr);\r
+ wait_for_cmd_done (AdapterInfo->ioaddr + SCBCmd);\r
+\r
+ BlockIt (AdapterInfo, FALSE);\r
+\r
+ CommandWaitForCompletion (cmd_ptr, AdapterInfo);\r
+\r
+ cmd_ptr->PhysTBDArrayAddres = cmd_ptr->PhysArrayAddr;\r
+ cmd_ptr->ByteCount = cmd_ptr->Threshold = cmd_ptr->TBDCount = 0;\r
+ //\r
+ // fields beyond the immediatedata are assumed to be safe\r
+ // add the CB to the free list again\r
+ //\r
+ SetFreeCB (AdapterInfo, cmd_ptr);\r
+ }\r
+\r
+ if (new_filter != 0) {\r
+ //\r
+ // enable unicast and start the RU\r
+ //\r
+ AdapterInfo->Rx_Filter = (UINT8) (AdapterInfo->Rx_Filter | (new_filter | PXE_OPFLAGS_RECEIVE_FILTER_UNICAST));\r
+ StartRU (AdapterInfo);\r
+ } else {\r
+ //\r
+ // may be disabling everything!\r
+ //\r
+ if (AdapterInfo->Receive_Started) {\r
+ StopRU (AdapterInfo);\r
+ }\r
+\r
+ AdapterInfo->Rx_Filter |= (~PXE_OPFLAGS_RECEIVE_FILTER_UNICAST);\r
+ }\r
+\r
+ return 0;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+ @param cpb TODO: add argument description\r
+ @param opflags TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+UINTN\r
+E100bTransmit (\r
+ NIC_DATA_INSTANCE *AdapterInfo,\r
+ UINT64 cpb,\r
+ UINT16 opflags\r
+ )\r
+{\r
+ PXE_CPB_TRANSMIT_FRAGMENTS *tx_ptr_f;\r
+ PXE_CPB_TRANSMIT *tx_ptr_1;\r
+ TxCB *tcb_ptr;\r
+ UINT64 Tmp_ptr;\r
+ UINTN stat;\r
+ INT32 Index;\r
+ UINT16 wait_sec;\r
+\r
+ tx_ptr_1 = (PXE_CPB_TRANSMIT *) (UINTN) cpb;\r
+ tx_ptr_f = (PXE_CPB_TRANSMIT_FRAGMENTS *) (UINTN) cpb;\r
+\r
+ //\r
+ // stop reentrancy here\r
+ //\r
+ if (AdapterInfo->in_transmit) {\r
+ return PXE_STATCODE_BUSY;\r
+\r
+ }\r
+\r
+ AdapterInfo->in_transmit = TRUE;\r
+\r
+ //\r
+ // Prevent interrupts from changing the Tx ring from underneath us.\r
+ //\r
+ // Calculate the Tx descriptor entry.\r
+ //\r
+ if ((tcb_ptr = GetFreeCB (AdapterInfo)) == NULL) {\r
+ AdapterInfo->in_transmit = FALSE;\r
+ return PXE_STATCODE_QUEUE_FULL;\r
+ }\r
+\r
+ AdapterInfo->TxTotals++;\r
+\r
+ tcb_ptr->cb_header.command = (CmdSuspend | CmdTx | CmdTxFlex);\r
+ tcb_ptr->cb_header.status = 0;\r
+\r
+ //\r
+ // no immediate data, set EOF in the ByteCount\r
+ //\r
+ tcb_ptr->ByteCount = 0x8000;\r
+\r
+ //\r
+ // The data region is always in one buffer descriptor, Tx FIFO\r
+ // threshold of 256.\r
+ // 82557 multiplies the threashold value by 8, so give 256/8\r
+ //\r
+ tcb_ptr->Threshold = 32;\r
+ if ((opflags & PXE_OPFLAGS_TRANSMIT_FRAGMENTED) != 0) {\r
+\r
+ if (tx_ptr_f->FragCnt > MAX_XMIT_FRAGMENTS) {\r
+ SetFreeCB (AdapterInfo, tcb_ptr);\r
+ AdapterInfo->in_transmit = FALSE;\r
+ return PXE_STATCODE_INVALID_PARAMETER;\r
+ }\r
+\r
+ tcb_ptr->TBDCount = (UINT8) tx_ptr_f->FragCnt;\r
+\r
+ for (Index = 0; Index < tx_ptr_f->FragCnt; Index++) {\r
+ stat = MapIt (\r
+ AdapterInfo,\r
+ tx_ptr_f->FragDesc[Index].FragAddr,\r
+ tx_ptr_f->FragDesc[Index].FragLen,\r
+ TO_DEVICE,\r
+ (UINT64)(UINTN) &Tmp_ptr\r
+ );\r
+ if (stat != 0) {\r
+ SetFreeCB (AdapterInfo, tcb_ptr);\r
+ AdapterInfo->in_transmit = FALSE;\r
+ return PXE_STATCODE_INVALID_PARAMETER;\r
+ }\r
+\r
+ tcb_ptr->TBDArray[Index].phys_buf_addr = (UINT32) Tmp_ptr;\r
+ tcb_ptr->TBDArray[Index].buf_len = tx_ptr_f->FragDesc[Index].FragLen;\r
+ }\r
+\r
+ tcb_ptr->free_data_ptr = tx_ptr_f->FragDesc[0].FragAddr;\r
+\r
+ } else {\r
+ //\r
+ // non fragmented case\r
+ //\r
+ tcb_ptr->TBDCount = 1;\r
+ stat = MapIt (\r
+ AdapterInfo,\r
+ tx_ptr_1->FrameAddr,\r
+ tx_ptr_1->DataLen + tx_ptr_1->MediaheaderLen,\r
+ TO_DEVICE,\r
+ (UINT64)(UINTN) &Tmp_ptr\r
+ );\r
+ if (stat != 0) {\r
+ SetFreeCB (AdapterInfo, tcb_ptr);\r
+ AdapterInfo->in_transmit = FALSE;\r
+ return PXE_STATCODE_INVALID_PARAMETER;\r
+ }\r
+\r
+ tcb_ptr->TBDArray[0].phys_buf_addr = (UINT32) (Tmp_ptr);\r
+ tcb_ptr->TBDArray[0].buf_len = tx_ptr_1->DataLen + tx_ptr_1->MediaheaderLen;\r
+ tcb_ptr->free_data_ptr = tx_ptr_1->FrameAddr;\r
+ }\r
+\r
+ //\r
+ // must wait for previous command completion only if it was a non-transmit\r
+ //\r
+ BlockIt (AdapterInfo, TRUE);\r
+ IssueCB (AdapterInfo, tcb_ptr);\r
+ BlockIt (AdapterInfo, FALSE);\r
+\r
+ //\r
+ // see if we need to wait for completion here\r
+ //\r
+ if ((opflags & PXE_OPFLAGS_TRANSMIT_BLOCK) != 0) {\r
+ //\r
+ // don't wait for more than 1 second!!!\r
+ //\r
+ wait_sec = 1000;\r
+ while (tcb_ptr->cb_header.status == 0) {\r
+ DelayIt (AdapterInfo, 10);\r
+ wait_sec--;\r
+ if (wait_sec == 0) {\r
+ break;\r
+ }\r
+ }\r
+ //\r
+ // we need to un-map any mapped buffers here\r
+ //\r
+ if ((opflags & PXE_OPFLAGS_TRANSMIT_FRAGMENTED) != 0) {\r
+\r
+ for (Index = 0; Index < tx_ptr_f->FragCnt; Index++) {\r
+ Tmp_ptr = tcb_ptr->TBDArray[Index].phys_buf_addr;\r
+ UnMapIt (\r
+ AdapterInfo,\r
+ tx_ptr_f->FragDesc[Index].FragAddr,\r
+ tx_ptr_f->FragDesc[Index].FragLen,\r
+ TO_DEVICE,\r
+ (UINT64) Tmp_ptr\r
+ );\r
+ }\r
+ } else {\r
+ Tmp_ptr = tcb_ptr->TBDArray[0].phys_buf_addr;\r
+ UnMapIt (\r
+ AdapterInfo,\r
+ tx_ptr_1->FrameAddr,\r
+ tx_ptr_1->DataLen + tx_ptr_1->MediaheaderLen,\r
+ TO_DEVICE,\r
+ (UINT64) Tmp_ptr\r
+ );\r
+ }\r
+\r
+ if (tcb_ptr->cb_header.status == 0) {\r
+ SetFreeCB (AdapterInfo, tcb_ptr);\r
+ AdapterInfo->in_transmit = FALSE;\r
+ return PXE_STATCODE_DEVICE_FAILURE;\r
+ }\r
+\r
+ SetFreeCB (AdapterInfo, tcb_ptr);\r
+ }\r
+ //\r
+ // CB will be set free later in get_status (or when we run out of xmit buffers\r
+ //\r
+ AdapterInfo->in_transmit = FALSE;\r
+\r
+ return 0;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+ @param cpb TODO: add argument description\r
+ @param db TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+UINTN\r
+E100bReceive (\r
+ NIC_DATA_INSTANCE *AdapterInfo,\r
+ UINT64 cpb,\r
+ UINT64 db\r
+ )\r
+{\r
+ PXE_CPB_RECEIVE *rx_cpbptr;\r
+ PXE_DB_RECEIVE *rx_dbptr;\r
+ RxFD *rx_ptr;\r
+ INT32 status;\r
+ INT32 Index;\r
+ UINT16 pkt_len;\r
+ UINT16 ret_code;\r
+ PXE_FRAME_TYPE pkt_type;\r
+ UINT16 Tmp_len;\r
+ EtherHeader *hdr_ptr;\r
+ ret_code = PXE_STATCODE_NO_DATA;\r
+ pkt_type = PXE_FRAME_TYPE_NONE;\r
+ status = InWord (AdapterInfo, AdapterInfo->ioaddr + SCBStatus);\r
+ AdapterInfo->Int_Status = (UINT16) (AdapterInfo->Int_Status | status);\r
+ //\r
+ // acknoledge the interrupts\r
+ //\r
+ OutWord (AdapterInfo, (UINT16) (status & 0xfc00), (UINT32) (AdapterInfo->ioaddr + SCBStatus));\r
+\r
+ //\r
+ // include the prev ints as well\r
+ //\r
+ status = AdapterInfo->Int_Status;\r
+ rx_cpbptr = (PXE_CPB_RECEIVE *) (UINTN) cpb;\r
+ rx_dbptr = (PXE_DB_RECEIVE *) (UINTN) db;\r
+\r
+ rx_ptr = &AdapterInfo->rx_ring[AdapterInfo->cur_rx_ind];\r
+\r
+ //\r
+ // be in a loop just in case (we may drop a pkt)\r
+ //\r
+ while ((status = rx_ptr->cb_header.status) & RX_COMPLETE) {\r
+\r
+ AdapterInfo->RxTotals++;\r
+ //\r
+ // If we own the next entry, it's a new packet. Send it up.\r
+ //\r
+ if (rx_ptr->forwarded) {\r
+ goto FreeRFD;\r
+\r
+ }\r
+\r
+ //\r
+ // discard bad frames\r
+ //\r
+\r
+ //\r
+ // crc, align, dma overrun, too short, receive error (v22 no coll)\r
+ //\r
+ if ((status & 0x0D90) != 0) {\r
+ goto FreeRFD;\r
+\r
+ }\r
+\r
+ //\r
+ // make sure the status is OK\r
+ //\r
+ if ((status & 0x02000) == 0) {\r
+ goto FreeRFD;\r
+ }\r
+\r
+ pkt_len = (UINT16) (rx_ptr->ActualCount & 0x3fff);\r
+\r
+ if (pkt_len != 0) {\r
+\r
+ Tmp_len = pkt_len;\r
+ if (pkt_len > rx_cpbptr->BufferLen) {\r
+ Tmp_len = (UINT16) rx_cpbptr->BufferLen;\r
+ }\r
+\r
+ CopyMem ((INT8 *) (UINTN) rx_cpbptr->BufferAddr, (INT8 *) &rx_ptr->RFDBuffer, Tmp_len);\r
+\r
+ hdr_ptr = (EtherHeader *) &rx_ptr->RFDBuffer;\r
+ //\r
+ // fill the CDB and break the loop\r
+ //\r
+\r
+ //\r
+ // includes header\r
+ //\r
+ rx_dbptr->FrameLen = pkt_len;\r
+ rx_dbptr->MediaHeaderLen = PXE_MAC_HEADER_LEN_ETHER;\r
+\r
+ for (Index = 0; Index < PXE_HWADDR_LEN_ETHER; Index++) {\r
+ if (hdr_ptr->dest_addr[Index] != AdapterInfo->CurrentNodeAddress[Index]) {\r
+ break;\r
+ }\r
+ }\r
+\r
+ if (Index >= PXE_HWADDR_LEN_ETHER) {\r
+ pkt_type = PXE_FRAME_TYPE_UNICAST;\r
+ } else {\r
+ for (Index = 0; Index < PXE_HWADDR_LEN_ETHER; Index++) {\r
+ if (hdr_ptr->dest_addr[Index] != AdapterInfo->BroadcastNodeAddress[Index]) {\r
+ break;\r
+ }\r
+ }\r
+\r
+ if (Index >= PXE_HWADDR_LEN_ETHER) {\r
+ pkt_type = PXE_FRAME_TYPE_BROADCAST;\r
+ } else {\r
+ if ((hdr_ptr->dest_addr[0] & 1) == 1) {\r
+ //\r
+ // mcast\r
+ //\r
+\r
+ pkt_type = PXE_FRAME_TYPE_FILTERED_MULTICAST;\r
+ } else {\r
+ pkt_type = PXE_FRAME_TYPE_PROMISCUOUS;\r
+ }\r
+ }\r
+ }\r
+\r
+ rx_dbptr->Type = pkt_type;\r
+ rx_dbptr->Protocol = hdr_ptr->type;\r
+\r
+ for (Index = 0; Index < PXE_HWADDR_LEN_ETHER; Index++) {\r
+ rx_dbptr->SrcAddr[Index] = hdr_ptr->src_addr[Index];\r
+ rx_dbptr->DestAddr[Index] = hdr_ptr->dest_addr[Index];\r
+ }\r
+\r
+ rx_ptr->forwarded = TRUE;\r
+ //\r
+ // success\r
+ //\r
+ ret_code = 0;\r
+ Recycle_RFD (AdapterInfo, AdapterInfo->cur_rx_ind);\r
+ AdapterInfo->cur_rx_ind++;\r
+ if (AdapterInfo->cur_rx_ind == AdapterInfo->RxBufCnt) {\r
+ AdapterInfo->cur_rx_ind = 0;\r
+ }\r
+ break;\r
+ }\r
+\r
+FreeRFD:\r
+ Recycle_RFD (AdapterInfo, AdapterInfo->cur_rx_ind);\r
+ AdapterInfo->cur_rx_ind++;\r
+ if (AdapterInfo->cur_rx_ind == AdapterInfo->RxBufCnt) {\r
+ AdapterInfo->cur_rx_ind = 0;\r
+ }\r
+\r
+ rx_ptr = &AdapterInfo->rx_ring[AdapterInfo->cur_rx_ind];\r
+ }\r
+\r
+ if (pkt_type == PXE_FRAME_TYPE_NONE) {\r
+ AdapterInfo->Int_Status &= (~SCB_STATUS_FR);\r
+ }\r
+\r
+ status = InWord (AdapterInfo, AdapterInfo->ioaddr + SCBStatus);\r
+ if ((status & SCB_RUS_NO_RESOURCES) != 0) {\r
+ //\r
+ // start the receive unit here!\r
+ // leave all the filled frames,\r
+ //\r
+ SetupReceiveQueues (AdapterInfo);\r
+ OutLong (AdapterInfo, (UINT32) AdapterInfo->rx_phy_addr, AdapterInfo->ioaddr + SCBPointer);\r
+ OutWord (AdapterInfo, RX_START, AdapterInfo->ioaddr + SCBCmd);\r
+ AdapterInfo->cur_rx_ind = 0;\r
+ }\r
+\r
+ return ret_code;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+INT16\r
+E100bReadEepromAndStationAddress (\r
+ NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ INT32 Index;\r
+ INT32 Index2;\r
+ UINT16 sum;\r
+ UINT16 eeprom_len;\r
+ UINT8 addr_len;\r
+ UINT16 *eedata;\r
+\r
+ eedata = (UINT16 *) (&AdapterInfo->NVData[0]);\r
+\r
+ sum = 0;\r
+ addr_len = E100bGetEepromAddrLen (AdapterInfo);\r
+\r
+ //\r
+ // in words\r
+ //\r
+ AdapterInfo->NVData_Len = eeprom_len = (UINT16) (1 << addr_len);\r
+ for (Index2 = 0, Index = 0; Index < eeprom_len; Index++) {\r
+ UINT16 value;\r
+ value = E100bReadEeprom (AdapterInfo, Index, addr_len);\r
+ eedata[Index] = value;\r
+ sum = (UINT16) (sum + value);\r
+ if (Index < 3) {\r
+ AdapterInfo->PermNodeAddress[Index2++] = (UINT8) value;\r
+ AdapterInfo->PermNodeAddress[Index2++] = (UINT8) (value >> 8);\r
+ }\r
+ }\r
+\r
+ if (sum != 0xBABA) {\r
+ return -1;\r
+ }\r
+\r
+ for (Index = 0; Index < PXE_HWADDR_LEN_ETHER; Index++) {\r
+ AdapterInfo->CurrentNodeAddress[Index] = AdapterInfo->PermNodeAddress[Index];\r
+ }\r
+\r
+ for (Index = 0; Index < PXE_HWADDR_LEN_ETHER; Index++) {\r
+ AdapterInfo->BroadcastNodeAddress[Index] = 0xff;\r
+ }\r
+\r
+ for (Index = PXE_HWADDR_LEN_ETHER; Index < PXE_MAC_LENGTH; Index++) {\r
+ AdapterInfo->CurrentNodeAddress[Index] = 0;\r
+ AdapterInfo->PermNodeAddress[Index] = 0;\r
+ AdapterInfo->BroadcastNodeAddress[Index] = 0;\r
+ }\r
+\r
+ return 0;\r
+}\r
+\r
+//\r
+// CBList is a circular linked list\r
+// 1) When all are free, Tail->next == Head and FreeCount == # allocated\r
+// 2) When none are free, Tail == Head and FreeCount == 0\r
+// 3) when one is free, Tail == Head and Freecount == 1\r
+// 4) First non-Free frame is always at Tail->next\r
+//\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+UINT8\r
+SetupCBlink (\r
+ NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ TxCB *head_ptr;\r
+ TxCB *tail_ptr;\r
+ TxCB *cur_ptr;\r
+ INT32 Index;\r
+ UINTN array_off;\r
+\r
+ cur_ptr = &(AdapterInfo->tx_ring[0]);\r
+ array_off = (UINTN) (&cur_ptr->TBDArray) - (UINTN) cur_ptr;\r
+ for (Index = 0; Index < AdapterInfo->TxBufCnt; Index++) {\r
+ cur_ptr[Index].cb_header.status = 0;\r
+ cur_ptr[Index].cb_header.command = 0;\r
+\r
+ cur_ptr[Index].PhysTCBAddress =\r
+ (UINT32) AdapterInfo->tx_phy_addr + (Index * sizeof (TxCB));\r
+\r
+ cur_ptr[Index].PhysArrayAddr = (UINT32)(cur_ptr[Index].PhysTCBAddress + array_off);\r
+ cur_ptr[Index].PhysTBDArrayAddres = (UINT32)(cur_ptr[Index].PhysTCBAddress + array_off);\r
+\r
+ cur_ptr->free_data_ptr = (UINT64) 0;\r
+\r
+ if (Index < AdapterInfo->TxBufCnt - 1) {\r
+ cur_ptr[Index].cb_header.link = cur_ptr[Index].PhysTCBAddress + sizeof (TxCB);\r
+ cur_ptr[Index].NextTCBVirtualLinkPtr = &cur_ptr[Index + 1];\r
+ cur_ptr[Index + 1].PrevTCBVirtualLinkPtr = &cur_ptr[Index];\r
+ }\r
+ }\r
+\r
+ head_ptr = &cur_ptr[0];\r
+ tail_ptr = &cur_ptr[AdapterInfo->TxBufCnt - 1];\r
+ tail_ptr->cb_header.link = head_ptr->PhysTCBAddress;\r
+ tail_ptr->NextTCBVirtualLinkPtr = head_ptr;\r
+ head_ptr->PrevTCBVirtualLinkPtr = tail_ptr;\r
+\r
+ AdapterInfo->FreeCBCount = AdapterInfo->TxBufCnt;\r
+ AdapterInfo->FreeTxHeadPtr = head_ptr;\r
+ //\r
+ // set tail of the free list, next to this would be either in use\r
+ // or the head itself\r
+ //\r
+ AdapterInfo->FreeTxTailPtr = tail_ptr;\r
+\r
+ AdapterInfo->xmit_done_head = AdapterInfo->xmit_done_tail = 0;\r
+\r
+ return 0;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+TxCB *\r
+GetFreeCB (\r
+ NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ TxCB *free_cb_ptr;\r
+\r
+ //\r
+ // claim any hanging free CBs\r
+ //\r
+ if (AdapterInfo->FreeCBCount <= 1) {\r
+ CheckCBList (AdapterInfo);\r
+ }\r
+\r
+ //\r
+ // don't use up the last CB problem if the previous CB that the CU used\r
+ // becomes the last CB we submit because of the SUSPEND bit we set.\r
+ // the CU thinks it was never cleared.\r
+ //\r
+\r
+ if (AdapterInfo->FreeCBCount <= 1) {\r
+ return NULL;\r
+ }\r
+\r
+ BlockIt (AdapterInfo, TRUE);\r
+ free_cb_ptr = AdapterInfo->FreeTxHeadPtr;\r
+ AdapterInfo->FreeTxHeadPtr = free_cb_ptr->NextTCBVirtualLinkPtr;\r
+ --AdapterInfo->FreeCBCount;\r
+ BlockIt (AdapterInfo, FALSE);\r
+ return free_cb_ptr;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+ @param cb_ptr TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+VOID\r
+SetFreeCB (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ IN TxCB *cb_ptr\r
+ )\r
+{\r
+ //\r
+ // here we assume cb are returned in the order they are taken out\r
+ // and we link the newly freed cb at the tail of free cb list\r
+ //\r
+ cb_ptr->cb_header.status = 0;\r
+ cb_ptr->free_data_ptr = (UINT64) 0;\r
+\r
+ AdapterInfo->FreeTxTailPtr = cb_ptr;\r
+ ++AdapterInfo->FreeCBCount;\r
+ return ;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param ind TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+UINT16\r
+next (\r
+ IN UINT16 ind\r
+ )\r
+{\r
+ UINT16 Tmp;\r
+\r
+ Tmp = (UINT16) (ind + 1);\r
+ if (Tmp >= (TX_BUFFER_COUNT << 1)) {\r
+ Tmp = 0;\r
+ }\r
+\r
+ return Tmp;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+UINT16\r
+CheckCBList (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ TxCB *Tmp_ptr;\r
+ UINT16 cnt;\r
+\r
+ cnt = 0;\r
+ while (1) {\r
+ Tmp_ptr = AdapterInfo->FreeTxTailPtr->NextTCBVirtualLinkPtr;\r
+ if ((Tmp_ptr->cb_header.status & CMD_STATUS_MASK) != 0) {\r
+ //\r
+ // check if Q is full\r
+ //\r
+ if (next (AdapterInfo->xmit_done_tail) != AdapterInfo->xmit_done_head) {\r
+ AdapterInfo->xmit_done[AdapterInfo->xmit_done_tail] = Tmp_ptr->free_data_ptr;\r
+\r
+ UnMapIt (\r
+ AdapterInfo,\r
+ Tmp_ptr->free_data_ptr,\r
+ Tmp_ptr->TBDArray[0].buf_len,\r
+ TO_DEVICE,\r
+ (UINT64) Tmp_ptr->TBDArray[0].phys_buf_addr\r
+ );\r
+\r
+ AdapterInfo->xmit_done_tail = next (AdapterInfo->xmit_done_tail);\r
+ }\r
+\r
+ SetFreeCB (AdapterInfo, Tmp_ptr);\r
+ } else {\r
+ break;\r
+ }\r
+ }\r
+\r
+ return cnt;\r
+}\r
+//\r
+// Description : Initialize the RFD list list by linking each element together\r
+// in a circular list. The simplified memory model is used.\r
+// All data is in the RFD. The RFDs are linked together and the\r
+// last one points back to the first one. When the current RFD\r
+// is processed (frame received), its EL bit is set and the EL\r
+// bit in the previous RXFD is cleared.\r
+// Allocation done during INIT, this is making linked list.\r
+//\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+UINT8\r
+SetupReceiveQueues (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ RxFD *rx_ptr;\r
+ RxFD *tail_ptr;\r
+ UINT16 Index;\r
+\r
+ AdapterInfo->cur_rx_ind = 0;\r
+ rx_ptr = (&AdapterInfo->rx_ring[0]);\r
+\r
+ for (Index = 0; Index < AdapterInfo->RxBufCnt; Index++) {\r
+ rx_ptr[Index].cb_header.status = 0;\r
+ rx_ptr[Index].cb_header.command = 0;\r
+ rx_ptr[Index].RFDSize = RX_BUFFER_SIZE;\r
+ rx_ptr[Index].ActualCount = 0;\r
+ //\r
+ // RBDs not used, simple memory model\r
+ //\r
+ rx_ptr[Index].rx_buf_addr = (UINT32) (-1);\r
+\r
+ //\r
+ // RBDs not used, simple memory model\r
+ //\r
+ rx_ptr[Index].forwarded = FALSE;\r
+\r
+ //\r
+ // don't use Tmp_ptr if it is beyond the last one\r
+ //\r
+ if (Index < AdapterInfo->RxBufCnt - 1) {\r
+ rx_ptr[Index].cb_header.link = (UINT32) AdapterInfo->rx_phy_addr + ((Index + 1) * sizeof (RxFD));\r
+ }\r
+ }\r
+\r
+ tail_ptr = (&AdapterInfo->rx_ring[AdapterInfo->RxBufCnt - 1]);\r
+ tail_ptr->cb_header.link = (UINT32) AdapterInfo->rx_phy_addr;\r
+\r
+ //\r
+ // set the EL bit\r
+ //\r
+ tail_ptr->cb_header.command = 0xC000;\r
+ AdapterInfo->RFDTailPtr = tail_ptr;\r
+ return 0;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+ @param rx_index TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+VOID\r
+Recycle_RFD (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ IN UINT16 rx_index\r
+ )\r
+{\r
+ RxFD *rx_ptr;\r
+ RxFD *tail_ptr;\r
+ //\r
+ // change the EL bit and change the AdapterInfo->RxTailPtr\r
+ // rx_ptr is assumed to be the head of the Q\r
+ // AdapterInfo->rx_forwarded[rx_index] = FALSE;\r
+ //\r
+ rx_ptr = &AdapterInfo->rx_ring[rx_index];\r
+ tail_ptr = AdapterInfo->RFDTailPtr;\r
+ //\r
+ // set el_bit and suspend bit\r
+ //\r
+ rx_ptr->cb_header.command = 0xc000;\r
+ rx_ptr->cb_header.status = 0;\r
+ rx_ptr->ActualCount = 0;\r
+ rx_ptr->forwarded = FALSE;\r
+ AdapterInfo->RFDTailPtr = rx_ptr;\r
+ //\r
+ // resetting the el_bit.\r
+ //\r
+ tail_ptr->cb_header.command = 0;\r
+ //\r
+ // check the receive unit, fix if there is any problem\r
+ //\r
+ return ;\r
+}\r
+//\r
+// Serial EEPROM section.\r
+//\r
+// EEPROM_Ctrl bits.\r
+//\r
+#define EE_SHIFT_CLK 0x01 /* EEPROM shift clock. */\r
+#define EE_CS 0x02 /* EEPROM chip select. */\r
+#define EE_DI 0x04 /* EEPROM chip data in. */\r
+#define EE_WRITE_0 0x01\r
+#define EE_WRITE_1 0x05\r
+#define EE_DO 0x08 /* EEPROM chip data out. */\r
+#define EE_ENB (0x4800 | EE_CS)\r
+\r
+//\r
+// Delay between EEPROM clock transitions.\r
+// This will actually work with no delay on 33Mhz PCI.\r
+//\r
+#define eeprom_delay(nanosec) DelayIt (AdapterInfo, nanosec);\r
+\r
+//\r
+// The EEPROM commands include the alway-set leading bit.\r
+//\r
+#define EE_WRITE_CMD 5 // 101b\r
+#define EE_READ_CMD 6 // 110b\r
+#define EE_ERASE_CMD (7 << 6)\r
+\r
+VOID\r
+shift_bits_out (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ IN UINT16 val,\r
+ IN UINT8 num_bits\r
+ )\r
+/*++\r
+\r
+Routine Description:\r
+\r
+ TODO: Add function description\r
+\r
+Arguments:\r
+\r
+ AdapterInfo - TODO: add argument description\r
+ val - TODO: add argument description\r
+ num_bits - TODO: add argument description\r
+\r
+Returns:\r
+\r
+ TODO: add return values\r
+\r
+--*/\r
+{\r
+ INT32 Index;\r
+ UINT8 Tmp;\r
+ UINT32 EEAddr;\r
+\r
+ EEAddr = AdapterInfo->ioaddr + SCBeeprom;\r
+\r
+ for (Index = num_bits; Index >= 0; Index--) {\r
+ INT16 dataval;\r
+\r
+ //\r
+ // will be 0 or 4\r
+ //\r
+ dataval = (INT16) ((val & (1 << Index)) ? EE_DI : 0);\r
+\r
+ //\r
+ // mask off the data_in bit\r
+ //\r
+ Tmp = (UINT8) (InByte (AdapterInfo, EEAddr) &~EE_DI);\r
+ Tmp = (UINT8) (Tmp | dataval);\r
+ OutByte (AdapterInfo, Tmp, EEAddr);\r
+ eeprom_delay (100);\r
+ //\r
+ // raise the eeprom clock\r
+ //\r
+ OutByte (AdapterInfo, (UINT8) (Tmp | EE_SHIFT_CLK), EEAddr);\r
+ eeprom_delay (150);\r
+ //\r
+ // lower the eeprom clock\r
+ //\r
+ OutByte (AdapterInfo, (UINT8) (Tmp &~EE_SHIFT_CLK), EEAddr);\r
+ eeprom_delay (150);\r
+ }\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+UINT16\r
+shift_bits_in (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ UINT8 Tmp;\r
+ INT32 Index;\r
+ UINT16 retval;\r
+ UINT32 EEAddr;\r
+\r
+ EEAddr = AdapterInfo->ioaddr + SCBeeprom;\r
+\r
+ retval = 0;\r
+ for (Index = 15; Index >= 0; Index--) {\r
+ //\r
+ // raise the clock\r
+ //\r
+\r
+ //\r
+ // mask off the data_in bit\r
+ //\r
+ Tmp = InByte (AdapterInfo, EEAddr);\r
+ OutByte (AdapterInfo, (UINT8) (Tmp | EE_SHIFT_CLK), EEAddr);\r
+ eeprom_delay (100);\r
+ Tmp = InByte (AdapterInfo, EEAddr);\r
+ retval = (UINT16) ((retval << 1) | ((Tmp & EE_DO) ? 1 : 0));\r
+ //\r
+ // lower the clock\r
+ //\r
+ OutByte (AdapterInfo, (UINT8) (Tmp &~EE_SHIFT_CLK), EEAddr);\r
+ eeprom_delay (100);\r
+ }\r
+\r
+ return retval;\r
+}\r
+\r
+\r
+/**\r
+ This routine sets the EEPROM lockout bit to gain exclusive access to the\r
+ eeprom. the access bit is the most significant bit in the General Control\r
+ Register 2 in the SCB space.\r
+\r
+ @param AdapterInfo Pointer to the NIC data structure\r
+ information which the UNDI driver is\r
+ layering on..\r
+\r
+ @retval TRUE if it got the access\r
+ @retval FALSE if it fails to get the exclusive access\r
+\r
+**/\r
+BOOLEAN\r
+E100bSetEepromLockOut (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ UINTN wait;\r
+ UINT8 tmp;\r
+\r
+ if ((AdapterInfo->DeviceID == D102_DEVICE_ID) ||\r
+ (AdapterInfo->RevID >= D102_REVID)) {\r
+\r
+ wait = 500;\r
+\r
+ while (wait--) {\r
+\r
+ tmp = InByte (AdapterInfo, AdapterInfo->ioaddr + SCBGenCtrl2);\r
+ tmp |= GCR2_EEPROM_ACCESS_SEMAPHORE;\r
+ OutByte (AdapterInfo, tmp, AdapterInfo->ioaddr + SCBGenCtrl2);\r
+\r
+ DelayIt (AdapterInfo, 50);\r
+ tmp = InByte (AdapterInfo, AdapterInfo->ioaddr + SCBGenCtrl2);\r
+\r
+ if (tmp & GCR2_EEPROM_ACCESS_SEMAPHORE) {\r
+ return TRUE;\r
+ }\r
+ }\r
+\r
+ return FALSE;\r
+ }\r
+\r
+ return TRUE;\r
+}\r
+\r
+\r
+/**\r
+ This routine Resets the EEPROM lockout bit to giveup access to the\r
+ eeprom. the access bit is the most significant bit in the General Control\r
+ Register 2 in the SCB space.\r
+\r
+ @param AdapterInfo Pointer to the NIC data structure\r
+ information which the UNDI driver is\r
+ layering on..\r
+\r
+ @return None\r
+\r
+**/\r
+VOID\r
+E100bReSetEepromLockOut (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ UINT8 tmp;\r
+\r
+ if ((AdapterInfo->DeviceID == D102_DEVICE_ID) ||\r
+ (AdapterInfo->RevID >= D102_REVID)) {\r
+\r
+ tmp = InByte (AdapterInfo, AdapterInfo->ioaddr + SCBGenCtrl2);\r
+ tmp &= ~(GCR2_EEPROM_ACCESS_SEMAPHORE);\r
+ OutByte (AdapterInfo, tmp, AdapterInfo->ioaddr + SCBGenCtrl2);\r
+\r
+ DelayIt (AdapterInfo, 50);\r
+ }\r
+}\r
+\r
+\r
+/**\r
+ Using the NIC data structure information, read the EEPROM to get a Word of data for the MAC address.\r
+\r
+ @param AdapterInfo Pointer to the NIC data structure\r
+ information which the UNDI driver is\r
+ layering on..\r
+ @param Location Word offset into the MAC address to read.\r
+ @param AddrLen Number of bits of address length.\r
+\r
+ @retval RetVal The word read from the EEPROM.\r
+\r
+**/\r
+UINT16\r
+E100bReadEeprom (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ IN INT32 Location,\r
+ IN UINT8 AddrLen\r
+ )\r
+{\r
+ UINT16 RetVal;\r
+ UINT8 Tmp;\r
+\r
+ UINT32 EEAddr;\r
+ UINT16 ReadCmd;\r
+\r
+ EEAddr = AdapterInfo->ioaddr + SCBeeprom;\r
+ ReadCmd = (UINT16) (Location | (EE_READ_CMD << AddrLen));\r
+\r
+ RetVal = 0;\r
+\r
+ //\r
+ // get exclusive access to the eeprom first!\r
+ //\r
+ E100bSetEepromLockOut (AdapterInfo);\r
+\r
+ //\r
+ // eeprom control reg bits: x,x,x,x,DO,DI,CS,SK\r
+ // to write the opcode+data value out one bit at a time in DI starting at msb\r
+ // and then out a 1 to sk, wait, out 0 to SK and wait\r
+ // repeat this for all the bits to be written\r
+ //\r
+\r
+ //\r
+ // 11110010b\r
+ //\r
+ Tmp = (UINT8) (InByte (AdapterInfo, EEAddr) & 0xF2);\r
+ OutByte (AdapterInfo, (UINT8) (Tmp | EE_CS), EEAddr);\r
+\r
+ //\r
+ // 3 for the read opcode 110b\r
+ //\r
+ shift_bits_out (AdapterInfo, ReadCmd, (UINT8) (3 + AddrLen));\r
+\r
+ //\r
+ // read the eeprom word one bit at a time\r
+ //\r
+ RetVal = shift_bits_in (AdapterInfo);\r
+\r
+ //\r
+ // Terminate the EEPROM access and leave eeprom in a clean state.\r
+ //\r
+ Tmp = InByte (AdapterInfo, EEAddr);\r
+ Tmp &= ~(EE_CS | EE_DI);\r
+ OutByte (AdapterInfo, Tmp, EEAddr);\r
+\r
+ //\r
+ // raise the clock and lower the eeprom shift clock\r
+ //\r
+ OutByte (AdapterInfo, (UINT8) (Tmp | EE_SHIFT_CLK), EEAddr);\r
+ eeprom_delay (100);\r
+\r
+ OutByte (AdapterInfo, (UINT8) (Tmp &~EE_SHIFT_CLK), EEAddr);\r
+ eeprom_delay (100);\r
+\r
+ //\r
+ // giveup access to the eeprom\r
+ //\r
+ E100bReSetEepromLockOut (AdapterInfo);\r
+\r
+ return RetVal;\r
+}\r
+\r
+\r
+/**\r
+ Using the NIC data structure information, read the EEPROM to determine how many bits of address length\r
+ this EEPROM is in Words.\r
+\r
+ @param AdapterInfo Pointer to the NIC data structure\r
+ information which the UNDI driver is\r
+ layering on..\r
+\r
+ @retval RetVal The word read from the EEPROM.\r
+\r
+**/\r
+UINT8\r
+E100bGetEepromAddrLen (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ UINT8 Tmp;\r
+ UINT8 AddrLen;\r
+ UINT32 EEAddr;\r
+ //\r
+ // assume 64word eeprom (so,6 bits of address_length)\r
+ //\r
+ UINT16 ReadCmd;\r
+\r
+ EEAddr = AdapterInfo->ioaddr + SCBeeprom;\r
+ ReadCmd = (EE_READ_CMD << 6);\r
+\r
+ //\r
+ // get exclusive access to the eeprom first!\r
+ //\r
+ E100bSetEepromLockOut (AdapterInfo);\r
+\r
+ //\r
+ // address we are trying to read is 0\r
+ // eeprom control reg bits: x,x,x,x,DO,,DI,,CS,SK\r
+ // to write the opcode+data value out one bit at a time in DI starting at msb\r
+ // and then out a 1 to sk, wait, out 0 to SK and wait\r
+ // repeat this for all the bits to be written\r
+ //\r
+ Tmp = (UINT8) (InByte (AdapterInfo, EEAddr) & 0xF2);\r
+\r
+ //\r
+ // enable eeprom access\r
+ //\r
+ OutByte (AdapterInfo, (UINT8) (Tmp | EE_CS), EEAddr);\r
+\r
+ //\r
+ // 3 for opcode, 6 for the default address len\r
+ //\r
+ shift_bits_out (AdapterInfo, ReadCmd, (UINT8) (3 + 6));\r
+\r
+ //\r
+ // (in case of a 64 word eeprom).\r
+ // read the "dummy zero" from EE_DO to say that the address we wrote\r
+ // (six 0s) is accepted, write more zeros (until 8) to get a "dummy zero"\r
+ //\r
+\r
+ //\r
+ // assume the smallest\r
+ //\r
+ AddrLen = 6;\r
+ Tmp = InByte (AdapterInfo, EEAddr);\r
+ while ((AddrLen < 8) && ((Tmp & EE_DO) != 0)) {\r
+ OutByte (AdapterInfo, (UINT8) (Tmp &~EE_DI), EEAddr);\r
+ eeprom_delay (100);\r
+\r
+ //\r
+ // raise the eeprom clock\r
+ //\r
+ OutByte (AdapterInfo, (UINT8) (Tmp | EE_SHIFT_CLK), EEAddr);\r
+ eeprom_delay (150);\r
+\r
+ //\r
+ // lower the eeprom clock\r
+ //\r
+ OutByte (AdapterInfo, (UINT8) (Tmp &~EE_SHIFT_CLK), EEAddr);\r
+ eeprom_delay (150);\r
+ Tmp = InByte (AdapterInfo, EEAddr);\r
+ AddrLen++;\r
+ }\r
+\r
+ //\r
+ // read the eeprom word, even though we don't need this\r
+ //\r
+ shift_bits_in (AdapterInfo);\r
+\r
+ //\r
+ // Terminate the EEPROM access.\r
+ //\r
+ Tmp = InByte (AdapterInfo, EEAddr);\r
+ Tmp &= ~(EE_CS | EE_DI);\r
+ OutByte (AdapterInfo, Tmp, EEAddr);\r
+\r
+ //\r
+ // raise the clock and lower the eeprom shift clock\r
+ //\r
+ OutByte (AdapterInfo, (UINT8) (Tmp | EE_SHIFT_CLK), EEAddr);\r
+ eeprom_delay (100);\r
+\r
+ OutByte (AdapterInfo, (UINT8) (Tmp &~EE_SHIFT_CLK), EEAddr);\r
+ eeprom_delay (100);\r
+\r
+ //\r
+ // giveup access to the eeprom!\r
+ //\r
+ E100bReSetEepromLockOut (AdapterInfo);\r
+\r
+ return AddrLen;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+ @param DBaddr TODO: add argument description\r
+ @param DBsize TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+UINTN\r
+E100bStatistics (\r
+ NIC_DATA_INSTANCE *AdapterInfo,\r
+ UINT64 DBaddr,\r
+ UINT16 DBsize\r
+ )\r
+{\r
+ PXE_DB_STATISTICS db;\r
+ //\r
+ // wait upto one second (each wait is 100 micro s)\r
+ //\r
+ UINT32 Wait;\r
+ Wait = 10000;\r
+ wait_for_cmd_done (AdapterInfo->ioaddr + SCBCmd);\r
+\r
+ //\r
+ // Clear statistics done marker.\r
+ //\r
+ AdapterInfo->statistics->done_marker = 0;\r
+\r
+ //\r
+ // Issue statistics dump (or dump w/ reset) command.\r
+ //\r
+ OutByte (\r
+ AdapterInfo,\r
+ (UINT8) (DBsize ? CU_SHOWSTATS : CU_DUMPSTATS),\r
+ (UINT32) (AdapterInfo->ioaddr + SCBCmd)\r
+ );\r
+\r
+ //\r
+ // Wait for command to complete.\r
+ //\r
+ // zero the db here just to chew up a little more time.\r
+ //\r
+\r
+ ZeroMem ((VOID *) &db, sizeof db);\r
+\r
+ while (Wait != 0) {\r
+ //\r
+ // Wait a bit before checking.\r
+ //\r
+\r
+ DelayIt (AdapterInfo, 100);\r
+\r
+ //\r
+ // Look for done marker at end of statistics.\r
+ //\r
+\r
+ switch (AdapterInfo->statistics->done_marker) {\r
+ case 0xA005:\r
+ case 0xA007:\r
+ break;\r
+\r
+ default:\r
+ Wait--;\r
+ continue;\r
+ }\r
+\r
+ //\r
+ // if we did not "continue" from the above switch, we are done,\r
+ //\r
+ break;\r
+ }\r
+\r
+ //\r
+ // If this is a reset, we are out of here!\r
+ //\r
+ if (DBsize == 0) {\r
+ return PXE_STATCODE_SUCCESS;\r
+ }\r
+\r
+ //\r
+ // Convert NIC statistics counter format to EFI/UNDI\r
+ // specification statistics counter format.\r
+ //\r
+\r
+ //\r
+ // 54 3210 fedc ba98 7654 3210\r
+ // db.Supported = 01 0000 0100 1101 0001 0111;\r
+ //\r
+ db.Supported = 0x104D17;\r
+\r
+ //\r
+ // Statistics from the NIC\r
+ //\r
+\r
+ db.Data[0x01] = AdapterInfo->statistics->rx_good_frames;\r
+\r
+ db.Data[0x02] = AdapterInfo->statistics->rx_runt_errs;\r
+\r
+ db.Data[0x08] = AdapterInfo->statistics->rx_crc_errs +\r
+ AdapterInfo->statistics->rx_align_errs;\r
+\r
+ db.Data[0x04] = db.Data[0x02] +\r
+ db.Data[0x08] +\r
+ AdapterInfo->statistics->rx_resource_errs +\r
+ AdapterInfo->statistics->rx_overrun_errs;\r
+\r
+ db.Data[0x00] = db.Data[0x01] + db.Data[0x04];\r
+\r
+ db.Data[0x0B] = AdapterInfo->statistics->tx_good_frames;\r
+\r
+ db.Data[0x0E] = AdapterInfo->statistics->tx_coll16_errs +\r
+ AdapterInfo->statistics->tx_late_colls +\r
+ AdapterInfo->statistics->tx_underruns +\r
+ AdapterInfo->statistics->tx_one_colls +\r
+ AdapterInfo->statistics->tx_multi_colls;\r
+\r
+ db.Data[0x14] = AdapterInfo->statistics->tx_total_colls;\r
+\r
+ db.Data[0x0A] = db.Data[0x0B] +\r
+ db.Data[0x0E] +\r
+ AdapterInfo->statistics->tx_lost_carrier;\r
+\r
+ if (DBsize > sizeof db) {\r
+ DBsize = sizeof db;\r
+ }\r
+\r
+ CopyMem ((VOID *) (UINTN) DBaddr, (VOID *) &db, (UINTN) DBsize);\r
+\r
+ return PXE_STATCODE_SUCCESS;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+ @param OpFlags TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+UINTN\r
+E100bReset (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ IN INT32 OpFlags\r
+ )\r
+{\r
+\r
+ UINT16 save_filter;\r
+ //\r
+ // disable the interrupts\r
+ //\r
+ OutWord (AdapterInfo, INT_MASK, AdapterInfo->ioaddr + SCBCmd);\r
+\r
+ //\r
+ // wait for the tx queue to complete\r
+ //\r
+ CheckCBList (AdapterInfo);\r
+\r
+ XmitWaitForCompletion (AdapterInfo);\r
+\r
+ if (AdapterInfo->Receive_Started) {\r
+ StopRU (AdapterInfo);\r
+ }\r
+\r
+ InitializeChip (AdapterInfo);\r
+\r
+ //\r
+ // check the opflags and restart receive filters\r
+ //\r
+ if ((OpFlags & PXE_OPFLAGS_RESET_DISABLE_FILTERS) == 0) {\r
+\r
+ save_filter = AdapterInfo->Rx_Filter;\r
+ //\r
+ // if we give the filter same as Rx_Filter,\r
+ // this routine will not set mcast list (it thinks there is no change)\r
+ // to force it, we will reset that flag in the Rx_Filter\r
+ //\r
+ AdapterInfo->Rx_Filter &= (~PXE_OPFLAGS_RECEIVE_FILTER_FILTERED_MULTICAST);\r
+ E100bSetfilter (AdapterInfo, save_filter, (UINT64) 0, (UINT32) 0);\r
+ }\r
+\r
+ if ((OpFlags & PXE_OPFLAGS_RESET_DISABLE_INTERRUPTS) != 0) {\r
+ //\r
+ // disable the interrupts\r
+ //\r
+ AdapterInfo->int_mask = 0;\r
+ }\r
+ //\r
+ // else leave the interrupt in the pre-set state!!!\r
+ //\r
+ E100bSetInterruptState (AdapterInfo);\r
+\r
+ return 0;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+UINTN\r
+E100bShutdown (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ //\r
+ // disable the interrupts\r
+ //\r
+ OutWord (AdapterInfo, INT_MASK, AdapterInfo->ioaddr + SCBCmd);\r
+\r
+ //\r
+ // stop the receive unit\r
+ //\r
+ if (AdapterInfo->Receive_Started) {\r
+ StopRU (AdapterInfo);\r
+ }\r
+\r
+ //\r
+ // wait for the tx queue to complete\r
+ //\r
+ CheckCBList (AdapterInfo);\r
+ if (AdapterInfo->FreeCBCount != AdapterInfo->TxBufCnt) {\r
+ wait_for_cmd_done (AdapterInfo->ioaddr + SCBCmd);\r
+ }\r
+\r
+ //\r
+ // we do not want to reset the phy, it takes a long time to renegotiate the\r
+ // link after that (3-4 seconds)\r
+ //\r
+ InitializeChip (AdapterInfo);\r
+ SelectiveReset (AdapterInfo);\r
+ return 0;\r
+}\r
+\r
+\r
+/**\r
+ This routine will write a value to the specified MII register\r
+ of an external MDI compliant device (e.g. PHY 100). The command will\r
+ execute in polled mode.\r
+\r
+ @param AdapterInfo pointer to the structure that contains\r
+ the NIC's context.\r
+ @param RegAddress The MII register that we are writing to\r
+ @param PhyAddress The MDI address of the Phy component.\r
+ @param DataValue The value that we are writing to the MII\r
+ register.\r
+\r
+ @return nothing\r
+\r
+**/\r
+VOID\r
+MdiWrite (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ IN UINT8 RegAddress,\r
+ IN UINT8 PhyAddress,\r
+ IN UINT16 DataValue\r
+ )\r
+{\r
+ UINT32 WriteCommand;\r
+\r
+ WriteCommand = ((UINT32) DataValue) |\r
+ ((UINT32)(RegAddress << 16)) |\r
+ ((UINT32)(PhyAddress << 21)) |\r
+ ((UINT32)(MDI_WRITE << 26));\r
+\r
+ //\r
+ // Issue the write command to the MDI control register.\r
+ //\r
+ OutLong (AdapterInfo, WriteCommand, AdapterInfo->ioaddr + SCBCtrlMDI);\r
+\r
+ //\r
+ // wait 20usec before checking status\r
+ //\r
+ DelayIt (AdapterInfo, 20);\r
+\r
+ //\r
+ // poll for the mdi write to complete\r
+ while ((InLong (AdapterInfo, AdapterInfo->ioaddr + SCBCtrlMDI) &\r
+ MDI_PHY_READY) == 0){\r
+ DelayIt (AdapterInfo, 20);\r
+ }\r
+}\r
+\r
+\r
+/**\r
+ This routine will read a value from the specified MII register\r
+ of an external MDI compliant device (e.g. PHY 100), and return\r
+ it to the calling routine. The command will execute in polled mode.\r
+\r
+ @param AdapterInfo pointer to the structure that contains\r
+ the NIC's context.\r
+ @param RegAddress The MII register that we are reading from\r
+ @param PhyAddress The MDI address of the Phy component.\r
+ @param DataValue pointer to the value that we read from\r
+ the MII register.\r
+\r
+\r
+**/\r
+VOID\r
+MdiRead (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ IN UINT8 RegAddress,\r
+ IN UINT8 PhyAddress,\r
+ IN OUT UINT16 *DataValue\r
+ )\r
+{\r
+ UINT32 ReadCommand;\r
+\r
+ ReadCommand = ((UINT32) (RegAddress << 16)) |\r
+ ((UINT32) (PhyAddress << 21)) |\r
+ ((UINT32) (MDI_READ << 26));\r
+\r
+ //\r
+ // Issue the read command to the MDI control register.\r
+ //\r
+ OutLong (AdapterInfo, ReadCommand, AdapterInfo->ioaddr + SCBCtrlMDI);\r
+\r
+ //\r
+ // wait 20usec before checking status\r
+ //\r
+ DelayIt (AdapterInfo, 20);\r
+\r
+ //\r
+ // poll for the mdi read to complete\r
+ //\r
+ while ((InLong (AdapterInfo, AdapterInfo->ioaddr + SCBCtrlMDI) &\r
+ MDI_PHY_READY) == 0) {\r
+ DelayIt (AdapterInfo, 20);\r
+\r
+ }\r
+\r
+ *DataValue = InWord (AdapterInfo, AdapterInfo->ioaddr + SCBCtrlMDI);\r
+}\r
+\r
+\r
+/**\r
+ This routine will reset the PHY that the adapter is currently\r
+ configured to use.\r
+\r
+ @param AdapterInfo pointer to the structure that contains\r
+ the NIC's context.\r
+\r
+\r
+**/\r
+VOID\r
+PhyReset (\r
+ NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ UINT16 MdiControlReg;\r
+\r
+ MdiControlReg = (MDI_CR_AUTO_SELECT |\r
+ MDI_CR_RESTART_AUTO_NEG |\r
+ MDI_CR_RESET);\r
+\r
+ //\r
+ // Write the MDI control register with our new Phy configuration\r
+ //\r
+ MdiWrite (\r
+ AdapterInfo,\r
+ MDI_CONTROL_REG,\r
+ AdapterInfo->PhyAddress,\r
+ MdiControlReg\r
+ );\r
+\r
+ return ;\r
+}\r
+\r
+\r
+/**\r
+ This routine will detect what phy we are using, set the line\r
+ speed, FDX or HDX, and configure the phy if necessary.\r
+ The following combinations are supported:\r
+ - TX or T4 PHY alone at PHY address 1\r
+ - T4 or TX PHY at address 1 and MII PHY at address 0\r
+ - 82503 alone (10Base-T mode, no full duplex support)\r
+ - 82503 and MII PHY (TX or T4) at address 0\r
+ The sequence / priority of detection is as follows:\r
+ - PHY 1 with cable termination\r
+ - PHY 0 with cable termination\r
+ - PHY 1 (if found) without cable termination\r
+ - 503 interface\r
+ Additionally auto-negotiation capable (NWAY) and parallel\r
+ detection PHYs are supported. The flow-chart is described in\r
+ the 82557 software writer's manual.\r
+ NOTE: 1. All PHY MDI registers are read in polled mode.\r
+ 2. The routines assume that the 82557 has been RESET and we have\r
+ obtained the virtual memory address of the CSR.\r
+ 3. PhyDetect will not RESET the PHY.\r
+ 4. If FORCEFDX is set, SPEED should also be set. The driver will\r
+ check the values for inconsistency with the detected PHY\r
+ technology.\r
+ 5. PHY 1 (the PHY on the adapter) may have an address in the range\r
+ 1 through 31 inclusive. The driver will accept addresses in\r
+ this range.\r
+ 6. Driver ignores FORCEFDX and SPEED overrides if a 503 interface\r
+ is detected.\r
+\r
+ @param AdapterInfo pointer to the structure that contains\r
+ the NIC's context.\r
+\r
+ @retval TRUE If a Phy was detected, and configured\r
+ correctly.\r
+ @retval FALSE If a valid phy could not be detected and\r
+ configured.\r
+\r
+**/\r
+BOOLEAN\r
+PhyDetect (\r
+ NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ UINT16 *eedata;\r
+ UINT16 MdiControlReg;\r
+ UINT16 MdiStatusReg;\r
+ BOOLEAN FoundPhy1;\r
+ UINT8 ReNegotiateTime;\r
+\r
+ eedata = (UINT16 *) (&AdapterInfo->NVData[0]);\r
+\r
+ FoundPhy1 = FALSE;\r
+ ReNegotiateTime = 35;\r
+ //\r
+ // EEPROM word [6] contains the Primary PHY record in which the least 3 bits\r
+ // indicate the PHY address\r
+ // and word [7] contains the secondary PHY record\r
+ //\r
+ AdapterInfo->PhyRecord[0] = eedata[6];\r
+ AdapterInfo->PhyRecord[1] = eedata[7];\r
+ AdapterInfo->PhyAddress = (UINT8) (AdapterInfo->PhyRecord[0] & 7);\r
+\r
+ //\r
+ // Check for a phy address over-ride of 32 which indicates force use of 82503\r
+ // not detecting the link in this case\r
+ //\r
+ if (AdapterInfo->PhyAddress == 32) {\r
+ //\r
+ // 503 interface over-ride\r
+ // Record the current speed and duplex. We will be in half duplex\r
+ // mode unless the user used the force full duplex over-ride.\r
+ //\r
+ AdapterInfo->LinkSpeed = 10;\r
+ return (TRUE);\r
+ }\r
+\r
+ //\r
+ // If the Phy Address is between 1-31 then we must first look for phy 1,\r
+ // at that address.\r
+ //\r
+ if ((AdapterInfo->PhyAddress > 0) && (AdapterInfo->PhyAddress < 32)) {\r
+\r
+ //\r
+ // Read the MDI control and status registers at phy 1\r
+ // and check if we found a valid phy\r
+ //\r
+ MdiRead (\r
+ AdapterInfo,\r
+ MDI_CONTROL_REG,\r
+ AdapterInfo->PhyAddress,\r
+ &MdiControlReg\r
+ );\r
+\r
+ MdiRead (\r
+ AdapterInfo,\r
+ MDI_STATUS_REG,\r
+ AdapterInfo->PhyAddress,\r
+ &MdiStatusReg\r
+ );\r
+\r
+ if (!((MdiControlReg == 0xffff) ||\r
+ ((MdiStatusReg == 0) && (MdiControlReg == 0)))) {\r
+\r
+ //\r
+ // we have a valid phy1\r
+ // Read the status register again because of sticky bits\r
+ //\r
+ FoundPhy1 = TRUE;\r
+ MdiRead (\r
+ AdapterInfo,\r
+ MDI_STATUS_REG,\r
+ AdapterInfo->PhyAddress,\r
+ &MdiStatusReg\r
+ );\r
+\r
+ //\r
+ // If there is a valid link then use this Phy.\r
+ //\r
+ if (MdiStatusReg & MDI_SR_LINK_STATUS) {\r
+ return (SetupPhy(AdapterInfo));\r
+ }\r
+ }\r
+ }\r
+\r
+ //\r
+ // Next try to detect a PHY at address 0x00 because there was no Phy 1,\r
+ // or Phy 1 didn't have link, or we had a phy 0 over-ride\r
+ //\r
+\r
+ //\r
+ // Read the MDI control and status registers at phy 0\r
+ //\r
+ MdiRead (AdapterInfo, MDI_CONTROL_REG, 0, &MdiControlReg);\r
+ MdiRead (AdapterInfo, MDI_STATUS_REG, 0, &MdiStatusReg);\r
+\r
+ //\r
+ // check if we found a valid phy 0\r
+ //\r
+ if (((MdiControlReg == 0xffff) ||\r
+ ((MdiStatusReg == 0) && (MdiControlReg == 0)))) {\r
+\r
+ //\r
+ // we don't have a valid phy at address 0\r
+ // if phy address was forced to 0, then error out because we\r
+ // didn't find a phy at that address\r
+ //\r
+ if (AdapterInfo->PhyAddress == 0x0000) {\r
+ return (FALSE);\r
+ } else {\r
+ //\r
+ // at this point phy1 does not have link and there is no phy 0 at all\r
+ // if we are forced to detect the cable, error out here!\r
+ //\r
+ if (AdapterInfo->CableDetect != 0) {\r
+ return FALSE;\r
+\r
+ }\r
+\r
+ if (FoundPhy1) {\r
+ //\r
+ // no phy 0, but there is a phy 1 (no link I guess), so use phy 1\r
+ //\r
+ return SetupPhy (AdapterInfo);\r
+ } else {\r
+ //\r
+ // didn't find phy 0 or phy 1, so assume a 503 interface\r
+ //\r
+ AdapterInfo->PhyAddress = 32;\r
+\r
+ //\r
+ // Record the current speed and duplex. We'll be in half duplex\r
+ // mode unless the user used the force full duplex over-ride.\r
+ //\r
+ AdapterInfo->LinkSpeed = 10;\r
+ return (TRUE);\r
+ }\r
+ }\r
+ } else {\r
+ //\r
+ // We have a valid phy at address 0. If phy 0 has a link then we use\r
+ // phy 0. If Phy 0 doesn't have a link then we use Phy 1 (no link)\r
+ // if phy 1 is present, or phy 0 if phy 1 is not present\r
+ // If phy 1 was present, then we must isolate phy 1 before we enable\r
+ // phy 0 to see if Phy 0 has a link.\r
+ //\r
+ if (FoundPhy1) {\r
+ //\r
+ // isolate phy 1\r
+ //\r
+ MdiWrite (\r
+ AdapterInfo,\r
+ MDI_CONTROL_REG,\r
+ AdapterInfo->PhyAddress,\r
+ MDI_CR_ISOLATE\r
+ );\r
+\r
+ //\r
+ // wait 100 microseconds for the phy to isolate.\r
+ //\r
+ DelayIt (AdapterInfo, 100);\r
+ }\r
+\r
+ //\r
+ // Since this Phy is at address 0, we must enable it. So clear\r
+ // the isolate bit, and set the auto-speed select bit\r
+ //\r
+ MdiWrite (\r
+ AdapterInfo,\r
+ MDI_CONTROL_REG,\r
+ 0,\r
+ MDI_CR_AUTO_SELECT\r
+ );\r
+\r
+ //\r
+ // wait 100 microseconds for the phy to be enabled.\r
+ //\r
+ DelayIt (AdapterInfo, 100);\r
+\r
+ //\r
+ // restart the auto-negotion process\r
+ //\r
+ MdiWrite (\r
+ AdapterInfo,\r
+ MDI_CONTROL_REG,\r
+ 0,\r
+ MDI_CR_RESTART_AUTO_NEG | MDI_CR_AUTO_SELECT\r
+ );\r
+\r
+ //\r
+ // wait no more than 3.5 seconds for auto-negotiation to complete\r
+ //\r
+ while (ReNegotiateTime) {\r
+ //\r
+ // Read the status register twice because of sticky bits\r
+ //\r
+ MdiRead (AdapterInfo, MDI_STATUS_REG, 0, &MdiStatusReg);\r
+ MdiRead (AdapterInfo, MDI_STATUS_REG, 0, &MdiStatusReg);\r
+\r
+ if (MdiStatusReg & MDI_SR_AUTO_NEG_COMPLETE) {\r
+ break;\r
+ }\r
+\r
+ DelayIt (AdapterInfo, 100);\r
+ ReNegotiateTime--;\r
+ }\r
+\r
+ //\r
+ // Read the status register again because of sticky bits\r
+ //\r
+ MdiRead (AdapterInfo, MDI_STATUS_REG, 0, &MdiStatusReg);\r
+\r
+ //\r
+ // If the link was not set\r
+ //\r
+ if ((MdiStatusReg & MDI_SR_LINK_STATUS) == 0) {\r
+ //\r
+ // PHY1 does not have a link and phy 0 does not have a link\r
+ // do not proceed if we need to detect the link!\r
+ //\r
+ if (AdapterInfo->CableDetect != 0) {\r
+ return FALSE;\r
+ }\r
+\r
+ //\r
+ // the link wasn't set, so use phy 1 if phy 1 was present\r
+ //\r
+ if (FoundPhy1) {\r
+ //\r
+ // isolate phy 0\r
+ //\r
+ MdiWrite (AdapterInfo, MDI_CONTROL_REG, 0, MDI_CR_ISOLATE);\r
+\r
+ //\r
+ // wait 100 microseconds for the phy to isolate.\r
+ //\r
+ DelayIt (AdapterInfo, 100);\r
+\r
+ //\r
+ // Now re-enable PHY 1\r
+ //\r
+ MdiWrite (\r
+ AdapterInfo,\r
+ MDI_CONTROL_REG,\r
+ AdapterInfo->PhyAddress,\r
+ MDI_CR_AUTO_SELECT\r
+ );\r
+\r
+ //\r
+ // wait 100 microseconds for the phy to be enabled\r
+ //\r
+ DelayIt (AdapterInfo, 100);\r
+\r
+ //\r
+ // restart the auto-negotion process\r
+ //\r
+ MdiWrite (\r
+ AdapterInfo,\r
+ MDI_CONTROL_REG,\r
+ AdapterInfo->PhyAddress,\r
+ MDI_CR_RESTART_AUTO_NEG | MDI_CR_AUTO_SELECT\r
+ );\r
+\r
+ //\r
+ // Don't wait for it to complete (we didn't have link earlier)\r
+ //\r
+ return (SetupPhy (AdapterInfo));\r
+ }\r
+ }\r
+\r
+ //\r
+ // Definitely using Phy 0\r
+ //\r
+ AdapterInfo->PhyAddress = 0;\r
+ return (SetupPhy(AdapterInfo));\r
+ }\r
+}\r
+\r
+\r
+/**\r
+ This routine will setup phy 1 or phy 0 so that it is configured\r
+ to match a speed and duplex over-ride option. If speed or\r
+ duplex mode is not explicitly specified in the registry, the\r
+ driver will skip the speed and duplex over-ride code, and\r
+ assume the adapter is automatically setting the line speed, and\r
+ the duplex mode. At the end of this routine, any truly Phy\r
+ specific code will be executed (each Phy has its own quirks,\r
+ and some require that certain special bits are set).\r
+ NOTE: The driver assumes that SPEED and FORCEFDX are specified at the\r
+ same time. If FORCEDPX is set without speed being set, the driver\r
+ will encouter a fatal error and log a message into the event viewer.\r
+\r
+ @param AdapterInfo pointer to the structure that contains\r
+ the NIC's context.\r
+\r
+ @retval TRUE If the phy could be configured correctly\r
+ @retval FALSE If the phy couldn't be configured\r
+ correctly, because an unsupported\r
+ over-ride option was used\r
+\r
+**/\r
+BOOLEAN\r
+SetupPhy (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ UINT16 MdiControlReg;\r
+ UINT16 MdiStatusReg;\r
+ UINT16 MdiIdLowReg;\r
+ UINT16 MdiIdHighReg;\r
+ UINT16 MdiMiscReg;\r
+ UINT32 PhyId;\r
+ BOOLEAN ForcePhySetting;\r
+\r
+ ForcePhySetting = FALSE;\r
+\r
+ //\r
+ // If we are NOT forcing a setting for line speed or full duplex, then\r
+ // we won't force a link setting, and we'll jump down to the phy\r
+ // specific code.\r
+ //\r
+ if (((AdapterInfo->LinkSpeedReq) || (AdapterInfo->DuplexReq))) {\r
+ //\r
+ // Find out what kind of technology this Phy is capable of.\r
+ //\r
+ MdiRead (\r
+ AdapterInfo,\r
+ MDI_STATUS_REG,\r
+ AdapterInfo->PhyAddress,\r
+ &MdiStatusReg\r
+ );\r
+\r
+ //\r
+ // Read the MDI control register at our phy\r
+ //\r
+ MdiRead (\r
+ AdapterInfo,\r
+ MDI_CONTROL_REG,\r
+ AdapterInfo->PhyAddress,\r
+ &MdiControlReg\r
+ );\r
+\r
+ //\r
+ // Now check the validity of our forced option. If the force option is\r
+ // valid, then force the setting. If the force option is not valid,\r
+ // we'll set a flag indicating that we should error out.\r
+ //\r
+\r
+ //\r
+ // If speed is forced to 10mb\r
+ //\r
+ if (AdapterInfo->LinkSpeedReq == 10) {\r
+ //\r
+ // If half duplex is forced\r
+ //\r
+ if ((AdapterInfo->DuplexReq & PXE_FORCE_HALF_DUPLEX) != 0) {\r
+ if (MdiStatusReg & MDI_SR_10T_HALF_DPX) {\r
+\r
+ MdiControlReg &= ~(MDI_CR_10_100 | MDI_CR_AUTO_SELECT | MDI_CR_FULL_HALF);\r
+ ForcePhySetting = TRUE;\r
+ }\r
+ } else if ((AdapterInfo->DuplexReq & PXE_FORCE_FULL_DUPLEX) != 0) {\r
+\r
+ //\r
+ // If full duplex is forced\r
+ //\r
+ if (MdiStatusReg & MDI_SR_10T_FULL_DPX) {\r
+\r
+ MdiControlReg &= ~(MDI_CR_10_100 | MDI_CR_AUTO_SELECT);\r
+ MdiControlReg |= MDI_CR_FULL_HALF;\r
+ ForcePhySetting = TRUE;\r
+ }\r
+ } else {\r
+ //\r
+ // If auto duplex (we actually set phy to 1/2)\r
+ //\r
+ if (MdiStatusReg & (MDI_SR_10T_FULL_DPX | MDI_SR_10T_HALF_DPX)) {\r
+\r
+ MdiControlReg &= ~(MDI_CR_10_100 | MDI_CR_AUTO_SELECT | MDI_CR_FULL_HALF);\r
+ ForcePhySetting = TRUE;\r
+ }\r
+ }\r
+ }\r
+\r
+ //\r
+ // If speed is forced to 100mb\r
+ //\r
+ else if (AdapterInfo->LinkSpeedReq == 100) {\r
+ //\r
+ // If half duplex is forced\r
+ //\r
+ if ((AdapterInfo->DuplexReq & PXE_FORCE_HALF_DUPLEX) != 0) {\r
+ if (MdiStatusReg & (MDI_SR_TX_HALF_DPX | MDI_SR_T4_CAPABLE)) {\r
+\r
+ MdiControlReg &= ~(MDI_CR_AUTO_SELECT | MDI_CR_FULL_HALF);\r
+ MdiControlReg |= MDI_CR_10_100;\r
+ ForcePhySetting = TRUE;\r
+ }\r
+ } else if ((AdapterInfo->DuplexReq & PXE_FORCE_FULL_DUPLEX) != 0) {\r
+ //\r
+ // If full duplex is forced\r
+ //\r
+ if (MdiStatusReg & MDI_SR_TX_FULL_DPX) {\r
+ MdiControlReg &= ~MDI_CR_AUTO_SELECT;\r
+ MdiControlReg |= (MDI_CR_10_100 | MDI_CR_FULL_HALF);\r
+ ForcePhySetting = TRUE;\r
+ }\r
+ } else {\r
+ //\r
+ // If auto duplex (we set phy to 1/2)\r
+ //\r
+ if (MdiStatusReg & (MDI_SR_TX_HALF_DPX | MDI_SR_T4_CAPABLE)) {\r
+\r
+ MdiControlReg &= ~(MDI_CR_AUTO_SELECT | MDI_CR_FULL_HALF);\r
+ MdiControlReg |= MDI_CR_10_100;\r
+ ForcePhySetting = TRUE;\r
+ }\r
+ }\r
+ }\r
+\r
+ if (!ForcePhySetting) {\r
+ return (FALSE);\r
+ }\r
+\r
+ //\r
+ // Write the MDI control register with our new Phy configuration\r
+ //\r
+ MdiWrite (\r
+ AdapterInfo,\r
+ MDI_CONTROL_REG,\r
+ AdapterInfo->PhyAddress,\r
+ MdiControlReg\r
+ );\r
+\r
+ //\r
+ // wait 100 milliseconds for auto-negotiation to complete\r
+ //\r
+ DelayIt (AdapterInfo, 100);\r
+ }\r
+\r
+ //\r
+ // Find out specifically what Phy this is. We do this because for certain\r
+ // phys there are specific bits that must be set so that the phy and the\r
+ // 82557 work together properly.\r
+ //\r
+\r
+ MdiRead (\r
+ AdapterInfo,\r
+ PHY_ID_REG_1,\r
+ AdapterInfo->PhyAddress,\r
+ &MdiIdLowReg\r
+ );\r
+ MdiRead (\r
+ AdapterInfo,\r
+ PHY_ID_REG_2,\r
+ AdapterInfo->PhyAddress,\r
+ &MdiIdHighReg\r
+ );\r
+\r
+ PhyId = ((UINT32) MdiIdLowReg | ((UINT32) MdiIdHighReg << 16));\r
+\r
+ //\r
+ // And out the revsion field of the Phy ID so that we'll be able to detect\r
+ // future revs of the same Phy.\r
+ //\r
+ PhyId &= PHY_MODEL_REV_ID_MASK;\r
+\r
+ //\r
+ // Handle the National TX\r
+ //\r
+ if (PhyId == PHY_NSC_TX) {\r
+\r
+ MdiRead (\r
+ AdapterInfo,\r
+ NSC_CONG_CONTROL_REG,\r
+ AdapterInfo->PhyAddress,\r
+ &MdiMiscReg\r
+ );\r
+\r
+ MdiMiscReg |= (NSC_TX_CONG_TXREADY | NSC_TX_CONG_F_CONNECT);\r
+\r
+ MdiWrite (\r
+ AdapterInfo,\r
+ NSC_CONG_CONTROL_REG,\r
+ AdapterInfo->PhyAddress,\r
+ MdiMiscReg\r
+ );\r
+ }\r
+\r
+ FindPhySpeedAndDpx (AdapterInfo, PhyId);\r
+\r
+ //\r
+ // We put a hardware fix on to our adapters to work-around the PHY_100 errata\r
+ // described below. The following code is only compiled in, if we wanted\r
+ // to attempt a software workaround to the PHY_100 A/B step problem.\r
+ //\r
+\r
+ return (TRUE);\r
+}\r
+\r
+\r
+/**\r
+ This routine will figure out what line speed and duplex mode\r
+ the PHY is currently using.\r
+\r
+ @param AdapterInfo pointer to the structure that contains\r
+ the NIC's context.\r
+ @param PhyId The ID of the PHY in question.\r
+\r
+ @return NOTHING\r
+\r
+**/\r
+VOID\r
+FindPhySpeedAndDpx (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo,\r
+ IN UINT32 PhyId\r
+ )\r
+{\r
+ UINT16 MdiStatusReg;\r
+ UINT16 MdiMiscReg;\r
+ UINT16 MdiOwnAdReg;\r
+ UINT16 MdiLinkPartnerAdReg;\r
+\r
+ //\r
+ // If there was a speed and/or duplex override, then set our current\r
+ // value accordingly\r
+ //\r
+ AdapterInfo->LinkSpeed = AdapterInfo->LinkSpeedReq;\r
+ AdapterInfo->Duplex = (UINT8) ((AdapterInfo->DuplexReq & PXE_FORCE_FULL_DUPLEX) ?\r
+ FULL_DUPLEX : HALF_DUPLEX);\r
+\r
+ //\r
+ // If speed and duplex were forced, then we know our current settings, so\r
+ // we'll just return. Otherwise, we'll need to figure out what NWAY set\r
+ // us to.\r
+ //\r
+ if (AdapterInfo->LinkSpeed && AdapterInfo->Duplex) {\r
+ return ;\r
+\r
+ }\r
+ //\r
+ // If we didn't have a valid link, then we'll assume that our current\r
+ // speed is 10mb half-duplex.\r
+ //\r
+\r
+ //\r
+ // Read the status register twice because of sticky bits\r
+ //\r
+ MdiRead (\r
+ AdapterInfo,\r
+ MDI_STATUS_REG,\r
+ AdapterInfo->PhyAddress,\r
+ &MdiStatusReg\r
+ );\r
+ MdiRead (\r
+ AdapterInfo,\r
+ MDI_STATUS_REG,\r
+ AdapterInfo->PhyAddress,\r
+ &MdiStatusReg\r
+ );\r
+\r
+ //\r
+ // If there wasn't a valid link then use default speed & duplex\r
+ //\r
+ if (!(MdiStatusReg & MDI_SR_LINK_STATUS)) {\r
+\r
+ AdapterInfo->LinkSpeed = 10;\r
+ AdapterInfo->Duplex = HALF_DUPLEX;\r
+ return ;\r
+ }\r
+\r
+ //\r
+ // If this is an Intel PHY (a T4 PHY_100 or a TX PHY_TX), then read bits\r
+ // 1 and 0 of extended register 0, to get the current speed and duplex\r
+ // settings.\r
+ //\r
+ if ((PhyId == PHY_100_A) || (PhyId == PHY_100_C) || (PhyId == PHY_TX_ID)) {\r
+ //\r
+ // Read extended register 0\r
+ //\r
+ MdiRead (\r
+ AdapterInfo,\r
+ EXTENDED_REG_0,\r
+ AdapterInfo->PhyAddress,\r
+ &MdiMiscReg\r
+ );\r
+\r
+ //\r
+ // Get current speed setting\r
+ //\r
+ if (MdiMiscReg & PHY_100_ER0_SPEED_INDIC) {\r
+ AdapterInfo->LinkSpeed = 100;\r
+ } else {\r
+ AdapterInfo->LinkSpeed = 10;\r
+ }\r
+\r
+ //\r
+ // Get current duplex setting -- if bit is set then FDX is enabled\r
+ //\r
+ if (MdiMiscReg & PHY_100_ER0_FDX_INDIC) {\r
+ AdapterInfo->Duplex = FULL_DUPLEX;\r
+ } else {\r
+ AdapterInfo->Duplex = HALF_DUPLEX;\r
+ }\r
+\r
+ return ;\r
+ }\r
+ //\r
+ // Read our link partner's advertisement register\r
+ //\r
+ MdiRead (\r
+ AdapterInfo,\r
+ AUTO_NEG_LINK_PARTNER_REG,\r
+ AdapterInfo->PhyAddress,\r
+ &MdiLinkPartnerAdReg\r
+ );\r
+\r
+ //\r
+ // See if Auto-Negotiation was complete (bit 5, reg 1)\r
+ //\r
+ MdiRead (\r
+ AdapterInfo,\r
+ MDI_STATUS_REG,\r
+ AdapterInfo->PhyAddress,\r
+ &MdiStatusReg\r
+ );\r
+\r
+ //\r
+ // If a True NWAY connection was made, then we can detect speed/duplex by\r
+ // ANDing our adapter's advertised abilities with our link partner's\r
+ // advertised ablilities, and then assuming that the highest common\r
+ // denominator was chosed by NWAY.\r
+ //\r
+ if ((MdiLinkPartnerAdReg & NWAY_LP_ABILITY) &&\r
+ (MdiStatusReg & MDI_SR_AUTO_NEG_COMPLETE)) {\r
+\r
+ //\r
+ // Read our advertisement register\r
+ //\r
+ MdiRead (\r
+ AdapterInfo,\r
+ AUTO_NEG_ADVERTISE_REG,\r
+ AdapterInfo->PhyAddress,\r
+ &MdiOwnAdReg\r
+ );\r
+\r
+ //\r
+ // AND the two advertisement registers together, and get rid of any\r
+ // extraneous bits.\r
+ //\r
+ MdiOwnAdReg = (UINT16) (MdiOwnAdReg & (MdiLinkPartnerAdReg & NWAY_LP_ABILITY));\r
+\r
+ //\r
+ // Get speed setting\r
+ //\r
+ if (MdiOwnAdReg & (NWAY_AD_TX_HALF_DPX | NWAY_AD_TX_FULL_DPX | NWAY_AD_T4_CAPABLE)) {\r
+ AdapterInfo->LinkSpeed = 100;\r
+ } else {\r
+ AdapterInfo->LinkSpeed = 10;\r
+ }\r
+\r
+ //\r
+ // Get duplex setting -- use priority resolution algorithm\r
+ //\r
+ if (MdiOwnAdReg & (NWAY_AD_T4_CAPABLE)) {\r
+ AdapterInfo->Duplex = HALF_DUPLEX;\r
+ return ;\r
+ } else if (MdiOwnAdReg & (NWAY_AD_TX_FULL_DPX)) {\r
+ AdapterInfo->Duplex = FULL_DUPLEX;\r
+ return ;\r
+ } else if (MdiOwnAdReg & (NWAY_AD_TX_HALF_DPX)) {\r
+ AdapterInfo->Duplex = HALF_DUPLEX;\r
+ return ;\r
+ } else if (MdiOwnAdReg & (NWAY_AD_10T_FULL_DPX)) {\r
+ AdapterInfo->Duplex = FULL_DUPLEX;\r
+ return ;\r
+ } else {\r
+ AdapterInfo->Duplex = HALF_DUPLEX;\r
+ return ;\r
+ }\r
+ }\r
+\r
+ //\r
+ // If we are connected to a dumb (non-NWAY) repeater or hub, and the line\r
+ // speed was determined automatically by parallel detection, then we have\r
+ // no way of knowing exactly what speed the PHY is set to unless that PHY\r
+ // has a propietary register which indicates speed in this situation. The\r
+ // NSC TX PHY does have such a register. Also, since NWAY didn't establish\r
+ // the connection, the duplex setting should HALF duplex.\r
+ //\r
+ AdapterInfo->Duplex = HALF_DUPLEX;\r
+\r
+ if (PhyId == PHY_NSC_TX) {\r
+ //\r
+ // Read register 25 to get the SPEED_10 bit\r
+ //\r
+ MdiRead (\r
+ AdapterInfo,\r
+ NSC_SPEED_IND_REG,\r
+ AdapterInfo->PhyAddress,\r
+ &MdiMiscReg\r
+ );\r
+\r
+ //\r
+ // If bit 6 was set then we're at 10mb\r
+ //\r
+ if (MdiMiscReg & NSC_TX_SPD_INDC_SPEED) {\r
+ AdapterInfo->LinkSpeed = 10;\r
+ } else {\r
+ AdapterInfo->LinkSpeed = 100;\r
+ }\r
+ }\r
+\r
+ //\r
+ // If we don't know what line speed we are set at, then we'll default to\r
+ // 10mbs\r
+ //\r
+ else {\r
+ AdapterInfo->LinkSpeed = 10;\r
+ }\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+VOID\r
+XmitWaitForCompletion (\r
+ NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ TxCB *TxPtr;\r
+\r
+ if (AdapterInfo->FreeCBCount == AdapterInfo->TxBufCnt) {\r
+ return ;\r
+ }\r
+\r
+ //\r
+ // used xmit cb list starts right after the free tail (ends before the\r
+ // free head ptr)\r
+ //\r
+ TxPtr = AdapterInfo->FreeTxTailPtr->NextTCBVirtualLinkPtr;\r
+ while (TxPtr != AdapterInfo->FreeTxHeadPtr) {\r
+ CommandWaitForCompletion (TxPtr, AdapterInfo);\r
+ SetFreeCB (AdapterInfo, TxPtr);\r
+ TxPtr = TxPtr->NextTCBVirtualLinkPtr;\r
+ }\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param cmd_ptr TODO: add argument description\r
+ @param AdapterInfo TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+INT8\r
+CommandWaitForCompletion (\r
+ TxCB *cmd_ptr,\r
+ NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ INT16 wait;\r
+ wait = 5000;\r
+ while ((cmd_ptr->cb_header.status == 0) && (--wait > 0)) {\r
+ DelayIt (AdapterInfo, 10);\r
+ }\r
+\r
+ if (cmd_ptr->cb_header.status == 0) {\r
+ return -1;\r
+ }\r
+\r
+ return 0;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+INT8\r
+SoftwareReset (\r
+ NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ UINT8 tco_stat;\r
+ UINT16 wait;\r
+\r
+ tco_stat = 0;\r
+\r
+ //\r
+ // Reset the chip: stop Tx and Rx processes and clear counters.\r
+ // This takes less than 10usec and will easily finish before the next\r
+ // action.\r
+ //\r
+\r
+ OutLong (AdapterInfo, PORT_RESET, AdapterInfo->ioaddr + SCBPort);\r
+ //\r
+ // wait for 5 milli seconds here!\r
+ //\r
+ DelayIt (AdapterInfo, 5000);\r
+ //\r
+ // TCO Errata work around for 559s only\r
+ // -----------------------------------------------------------------------------------\r
+ // TCO Workaround Code\r
+ // haifa workaround\r
+ // -----------------------------------------------------------------------------------\r
+ // 1. Issue SW-RST ^^^ (already done above)\r
+ // 2. Issue a redundant Set CU Base CMD immediately\r
+ // Do not set the General Pointer before the Set CU Base cycle\r
+ // Do not check the SCB CMD before the Set CU Base cycle\r
+ // 3. Wait for the SCB-CMD to be cleared\r
+ // this indicates the transition to post-driver\r
+ // 4. Poll the TCO-Req bit in the PMDR to be cleared\r
+ // this indicates the tco activity has stopped for real\r
+ // 5. Proceed with the nominal Driver Init:\r
+ // Actual Set CU & RU Base ...\r
+ //\r
+ // Check for ICH2 device ID. If this is an ICH2,\r
+ // do the TCO workaround code.\r
+ //\r
+ if (AdapterInfo->VendorID == D102_DEVICE_ID ||\r
+ AdapterInfo->VendorID == ICH3_DEVICE_ID_1 ||\r
+ AdapterInfo->VendorID == ICH3_DEVICE_ID_2 ||\r
+ AdapterInfo->VendorID == ICH3_DEVICE_ID_3 ||\r
+ AdapterInfo->VendorID == ICH3_DEVICE_ID_4 ||\r
+ AdapterInfo->VendorID == ICH3_DEVICE_ID_5 ||\r
+ AdapterInfo->VendorID == ICH3_DEVICE_ID_6 ||\r
+ AdapterInfo->VendorID == ICH3_DEVICE_ID_7 ||\r
+ AdapterInfo->VendorID == ICH3_DEVICE_ID_8 ||\r
+ AdapterInfo->RevID >= 8) { // do the TCO fix\r
+ //\r
+ // donot load the scb pointer but just give load_cu cmd.\r
+ //\r
+ OutByte (AdapterInfo, CU_CMD_BASE, AdapterInfo->ioaddr + SCBCmd);\r
+ //\r
+ // wait for command to be accepted.\r
+ //\r
+ wait_for_cmd_done (AdapterInfo->ioaddr + SCBCmd);\r
+ //\r
+ // read PMDR register and check bit 1 in it to see if TCO is active\r
+ //\r
+\r
+ //\r
+ // wait for 5 milli seconds\r
+ //\r
+ wait = 5000;\r
+ while (wait) {\r
+ tco_stat = InByte (AdapterInfo, AdapterInfo->ioaddr + 0x1b);\r
+ if ((tco_stat & 2) == 0) {\r
+ //\r
+ // is the activity bit clear??\r
+ //\r
+ break;\r
+ }\r
+\r
+ wait--;\r
+ DelayIt (AdapterInfo, 1);\r
+ }\r
+\r
+ if ((tco_stat & 2) != 0) {\r
+ //\r
+ // not zero??\r
+ //\r
+ return -1;\r
+ }\r
+ }\r
+\r
+ return 0;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+UINT8\r
+SelectiveReset (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ UINT16 wait;\r
+ UINT32 stat;\r
+\r
+ wait = 10;\r
+ stat = 0;\r
+ OutLong (AdapterInfo, POR_SELECTIVE_RESET, AdapterInfo->ioaddr + SCBPort);\r
+ //\r
+ // wait for this to complete\r
+ //\r
+\r
+ //\r
+ // wait for 2 milli seconds here!\r
+ //\r
+ DelayIt (AdapterInfo, 2000);\r
+ while (wait > 0) {\r
+ wait--;\r
+ stat = InLong (AdapterInfo, AdapterInfo->ioaddr + SCBPort);\r
+ if (stat == 0) {\r
+ break;\r
+ }\r
+\r
+ //\r
+ // wait for 1 milli second\r
+ //\r
+ DelayIt (AdapterInfo, 1000);\r
+ }\r
+\r
+ if (stat != 0) {\r
+ return PXE_STATCODE_DEVICE_FAILURE;\r
+ }\r
+\r
+ return 0;\r
+}\r
+\r
+\r
+/**\r
+ TODO: Add function description\r
+\r
+ @param AdapterInfo TODO: add argument description\r
+\r
+ @return TODO: add return values\r
+\r
+**/\r
+UINT16\r
+InitializeChip (\r
+ IN NIC_DATA_INSTANCE *AdapterInfo\r
+ )\r
+{\r
+ UINT16 ret_val;\r
+ if (SoftwareReset (AdapterInfo) != 0) {\r
+ return PXE_STATCODE_DEVICE_FAILURE;\r
+ }\r
+\r
+ //\r
+ // disable interrupts\r
+ //\r
+ OutWord (AdapterInfo, INT_MASK, AdapterInfo->ioaddr + SCBCmd);\r
+\r
+ //\r
+ // Load the base registers with 0s (we will give the complete address as\r
+ // offset later when we issue any command\r
+ //\r
+ if ((ret_val = Load_Base_Regs (AdapterInfo)) != 0) {\r
+ return ret_val;\r
+ }\r
+\r
+ if ((ret_val = SetupCBlink (AdapterInfo)) != 0) {\r
+ return ret_val;\r
+ }\r
+\r
+ if ((ret_val = SetupReceiveQueues (AdapterInfo)) != 0) {\r
+ return ret_val;\r
+ }\r
+\r
+ //\r
+ // detect the PHY only if we need to detect the cable as requested by the\r
+ // initialize parameters\r
+ //\r
+ AdapterInfo->PhyAddress = 0xFF;\r
+\r
+ if (AdapterInfo->CableDetect != 0) {\r
+ if (!PhyDetect (AdapterInfo)) {\r
+ return PXE_STATCODE_DEVICE_FAILURE;\r
+ }\r
+ }\r
+\r
+ if ((ret_val = E100bSetupIAAddr (AdapterInfo)) != 0) {\r
+ return ret_val;\r
+ }\r
+\r
+ if ((ret_val = Configure (AdapterInfo)) != 0) {\r
+ return ret_val;\r
+ }\r
+\r
+ return 0;\r
+}\r