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https://github.com/AsahiLinux/u-boot
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028ab6b598
Add support for the Xilinx ML300 platform * Patch by Stephan Linz, 17 Feb 2004: Fix watchdog support for NIOS * Patch by Josh Fryman, 16 Feb 2004: Fix byte-swapping for cfi_flash.c for different bus widths * Patch by Jon Diekema, 14 Jeb 2004: Remove duplicate "FPGA Support" notes from the README file
482 lines
16 KiB
C
482 lines
16 KiB
C
/******************************************************************************
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*
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* Author: Xilinx, Inc.
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*
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*
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* This program is free software; you can redistribute it and/or modify it
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* under the terms of the GNU General Public License as published by the
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* Free Software Foundation; either version 2 of the License, or (at your
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* option) any later version.
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*
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*
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* XILINX IS PROVIDING THIS DESIGN, CODE, OR INFORMATION "AS IS" AS A
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* COURTESY TO YOU. BY PROVIDING THIS DESIGN, CODE, OR INFORMATION AS
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* ONE POSSIBLE IMPLEMENTATION OF THIS FEATURE, APPLICATION OR STANDARD,
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* XILINX IS MAKING NO REPRESENTATION THAT THIS IMPLEMENTATION IS FREE
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* FROM ANY CLAIMS OF INFRINGEMENT, AND YOU ARE RESPONSIBLE FOR OBTAINING
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* ANY THIRD PARTY RIGHTS YOU MAY REQUIRE FOR YOUR IMPLEMENTATION.
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* XILINX EXPRESSLY DISCLAIMS ANY WARRANTY WHATSOEVER WITH RESPECT TO
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* THE ADEQUACY OF THE IMPLEMENTATION, INCLUDING BUT NOT LIMITED TO ANY
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* WARRANTIES OR REPRESENTATIONS THAT THIS IMPLEMENTATION IS FREE FROM
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* CLAIMS OF INFRINGEMENT, IMPLIED WARRANTIES OF MERCHANTABILITY AND
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* FITNESS FOR A PARTICULAR PURPOSE.
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*
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*
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* Xilinx hardware products are not intended for use in life support
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* appliances, devices, or systems. Use in such applications is
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* expressly prohibited.
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*
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*
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* (c) Copyright 2002-2004 Xilinx Inc.
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* All rights reserved.
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*
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*
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* You should have received a copy of the GNU General Public License along
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* with this program; if not, write to the Free Software Foundation, Inc.,
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* 675 Mass Ave, Cambridge, MA 02139, USA.
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*
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******************************************************************************/
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/*****************************************************************************/
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/**
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*
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* @file xemac_polled.c
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*
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* Contains functions used when the driver is in polled mode. Use the
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* XEmac_SetOptions() function to put the driver into polled mode.
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*
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* <pre>
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* MODIFICATION HISTORY:
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*
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* Ver Who Date Changes
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* ----- ---- -------- -----------------------------------------------
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* 1.00a rpm 07/31/01 First release
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* 1.00b rpm 02/20/02 Repartitioned files and functions
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* 1.00c rpm 12/05/02 New version includes support for simple DMA
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* </pre>
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*
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******************************************************************************/
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/***************************** Include Files *********************************/
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#include "xbasic_types.h"
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#include "xemac_i.h"
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#include "xio.h"
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#include "xipif_v1_23_b.h" /* Uses v1.23b of the IPIF */
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/************************** Constant Definitions *****************************/
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/**************************** Type Definitions *******************************/
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/***************** Macros (Inline Functions) Definitions *********************/
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/************************** Variable Definitions *****************************/
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/************************** Function Prototypes ******************************/
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/*****************************************************************************/
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/**
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*
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* Send an Ethernet frame in polled mode. The device/driver must be in polled
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* mode before calling this function. The driver writes the frame directly to
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* the MAC's packet FIFO, then enters a loop checking the device status for
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* completion or error. Statistics are updated if an error occurs. The buffer
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* to be sent must be word-aligned.
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*
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* It is assumed that the upper layer software supplies a correctly formatted
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* Ethernet frame, including the destination and source addresses, the
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* type/length field, and the data field. It is also assumed that upper layer
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* software does not append FCS at the end of the frame.
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*
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* @param InstancePtr is a pointer to the XEmac instance to be worked on.
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* @param BufPtr is a pointer to a word-aligned buffer containing the Ethernet
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* frame to be sent.
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* @param ByteCount is the size of the Ethernet frame.
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*
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* @return
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*
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* - XST_SUCCESS if the frame was sent successfully
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* - XST_DEVICE_IS_STOPPED if the device has not yet been started
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* - XST_NOT_POLLED if the device is not in polled mode
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* - XST_FIFO_NO_ROOM if there is no room in the EMAC's length FIFO for this frame
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* - XST_FIFO_ERROR if the FIFO was overrun or underrun. This error is critical
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* and requires the caller to reset the device.
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* - XST_EMAC_COLLISION if the send failed due to excess deferral or late
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* collision
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*
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* @note
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*
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* There is the possibility that this function will not return if the hardware
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* is broken (i.e., it never sets the status bit indicating that transmission is
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* done). If this is of concern to the user, the user should provide protection
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* from this problem - perhaps by using a different timer thread to monitor the
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* PollSend thread. On a 10Mbps MAC, it takes about 1.21 msecs to transmit a
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* maximum size Ethernet frame (1518 bytes). On a 100Mbps MAC, it takes about
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* 121 usecs to transmit a maximum size Ethernet frame.
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*
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* @internal
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*
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* The EMAC uses FIFOs behind its length and status registers. For this reason,
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* it is important to keep the length, status, and data FIFOs in sync when
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* reading or writing to them.
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*
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******************************************************************************/
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XStatus
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XEmac_PollSend(XEmac * InstancePtr, u8 * BufPtr, u32 ByteCount)
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{
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u32 IntrStatus;
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u32 XmitStatus;
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XStatus Result;
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XASSERT_NONVOID(InstancePtr != NULL);
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XASSERT_NONVOID(BufPtr != NULL);
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XASSERT_NONVOID(ByteCount > XEM_HDR_SIZE); /* send at least 1 byte */
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XASSERT_NONVOID(InstancePtr->IsReady == XCOMPONENT_IS_READY);
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/*
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* Be sure the device is configured for polled mode and it is started
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*/
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if (!InstancePtr->IsPolled) {
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return XST_NOT_POLLED;
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}
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if (InstancePtr->IsStarted != XCOMPONENT_IS_STARTED) {
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return XST_DEVICE_IS_STOPPED;
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}
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/*
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* Check for overruns and underruns for the transmit status and length
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* FIFOs and make sure the send packet FIFO is not deadlocked. Any of these
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* conditions is bad enough that we do not want to continue. The upper layer
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* software should reset the device to resolve the error.
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*/
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IntrStatus = XIIF_V123B_READ_IISR(InstancePtr->BaseAddress);
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/*
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* Overrun errors
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*/
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if (IntrStatus & (XEM_EIR_XMIT_SFIFO_OVER_MASK |
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XEM_EIR_XMIT_LFIFO_OVER_MASK)) {
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InstancePtr->Stats.XmitOverrunErrors++;
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InstancePtr->Stats.FifoErrors++;
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return XST_FIFO_ERROR;
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}
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/*
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* Underrun errors
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*/
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if (IntrStatus & (XEM_EIR_XMIT_SFIFO_UNDER_MASK |
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XEM_EIR_XMIT_LFIFO_UNDER_MASK)) {
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InstancePtr->Stats.XmitUnderrunErrors++;
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InstancePtr->Stats.FifoErrors++;
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return XST_FIFO_ERROR;
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}
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if (XPF_V100B_IS_DEADLOCKED(&InstancePtr->SendFifo)) {
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InstancePtr->Stats.FifoErrors++;
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return XST_FIFO_ERROR;
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}
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/*
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* Before writing to the data FIFO, make sure the length FIFO is not
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* full. The data FIFO might not be full yet even though the length FIFO
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* is. This avoids an overrun condition on the length FIFO and keeps the
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* FIFOs in sync.
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*/
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if (IntrStatus & XEM_EIR_XMIT_LFIFO_FULL_MASK) {
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/*
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* Clear the latched LFIFO_FULL bit so next time around the most
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* current status is represented
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*/
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XIIF_V123B_WRITE_IISR(InstancePtr->BaseAddress,
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XEM_EIR_XMIT_LFIFO_FULL_MASK);
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return XST_FIFO_NO_ROOM;
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}
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/*
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* This is a non-blocking write. The packet FIFO returns an error if there
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* is not enough room in the FIFO for this frame.
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*/
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Result =
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XPacketFifoV100b_Write(&InstancePtr->SendFifo, BufPtr, ByteCount);
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if (Result != XST_SUCCESS) {
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return Result;
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}
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/*
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* Loop on the MAC's status to wait for any pause to complete.
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*/
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IntrStatus = XIIF_V123B_READ_IISR(InstancePtr->BaseAddress);
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while ((IntrStatus & XEM_EIR_XMIT_PAUSE_MASK) != 0) {
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IntrStatus = XIIF_V123B_READ_IISR(InstancePtr->BaseAddress);
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/*
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* Clear the pause status from the transmit status register
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*/
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XIIF_V123B_WRITE_IISR(InstancePtr->BaseAddress,
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IntrStatus & XEM_EIR_XMIT_PAUSE_MASK);
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}
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/*
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* Set the MAC's transmit packet length register to tell it to transmit
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*/
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XIo_Out32(InstancePtr->BaseAddress + XEM_TPLR_OFFSET, ByteCount);
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/*
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* Loop on the MAC's status to wait for the transmit to complete. The
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* transmit status is in the FIFO when the XMIT_DONE bit is set.
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*/
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do {
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IntrStatus = XIIF_V123B_READ_IISR(InstancePtr->BaseAddress);
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}
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while ((IntrStatus & XEM_EIR_XMIT_DONE_MASK) == 0);
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XmitStatus = XIo_In32(InstancePtr->BaseAddress + XEM_TSR_OFFSET);
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InstancePtr->Stats.XmitFrames++;
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InstancePtr->Stats.XmitBytes += ByteCount;
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/*
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* Check for various errors, bump statistics, and return an error status.
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*/
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/*
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* Overrun errors
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*/
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if (IntrStatus & (XEM_EIR_XMIT_SFIFO_OVER_MASK |
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XEM_EIR_XMIT_LFIFO_OVER_MASK)) {
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InstancePtr->Stats.XmitOverrunErrors++;
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InstancePtr->Stats.FifoErrors++;
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return XST_FIFO_ERROR;
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}
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/*
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* Underrun errors
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*/
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if (IntrStatus & (XEM_EIR_XMIT_SFIFO_UNDER_MASK |
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XEM_EIR_XMIT_LFIFO_UNDER_MASK)) {
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InstancePtr->Stats.XmitUnderrunErrors++;
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InstancePtr->Stats.FifoErrors++;
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return XST_FIFO_ERROR;
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}
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/*
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* Clear the interrupt status register of transmit statuses
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*/
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XIIF_V123B_WRITE_IISR(InstancePtr->BaseAddress,
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IntrStatus & XEM_EIR_XMIT_ALL_MASK);
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/*
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* Collision errors are stored in the transmit status register
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* instead of the interrupt status register
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*/
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if (XmitStatus & XEM_TSR_EXCESS_DEFERRAL_MASK) {
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InstancePtr->Stats.XmitExcessDeferral++;
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return XST_EMAC_COLLISION_ERROR;
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}
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if (XmitStatus & XEM_TSR_LATE_COLLISION_MASK) {
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InstancePtr->Stats.XmitLateCollisionErrors++;
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return XST_EMAC_COLLISION_ERROR;
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}
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return XST_SUCCESS;
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}
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/*****************************************************************************/
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/**
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*
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* Receive an Ethernet frame in polled mode. The device/driver must be in polled
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* mode before calling this function. The driver receives the frame directly
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* from the MAC's packet FIFO. This is a non-blocking receive, in that if there
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* is no frame ready to be received at the device, the function returns with an
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* error. The MAC's error status is not checked, so statistics are not updated
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* for polled receive. The buffer into which the frame will be received must be
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* word-aligned.
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*
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* @param InstancePtr is a pointer to the XEmac instance to be worked on.
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* @param BufPtr is a pointer to a word-aligned buffer into which the received
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* Ethernet frame will be copied.
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* @param ByteCountPtr is both an input and an output parameter. It is a pointer
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* to a 32-bit word that contains the size of the buffer on entry into the
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* function and the size the received frame on return from the function.
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*
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* @return
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*
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* - XST_SUCCESS if the frame was sent successfully
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* - XST_DEVICE_IS_STOPPED if the device has not yet been started
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* - XST_NOT_POLLED if the device is not in polled mode
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* - XST_NO_DATA if there is no frame to be received from the FIFO
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* - XST_BUFFER_TOO_SMALL if the buffer to receive the frame is too small for
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* the frame waiting in the FIFO.
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*
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* @note
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*
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* Input buffer must be big enough to hold the largest Ethernet frame. Buffer
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* must also be 32-bit aligned.
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*
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* @internal
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*
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* The EMAC uses FIFOs behind its length and status registers. For this reason,
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* it is important to keep the length, status, and data FIFOs in sync when
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* reading or writing to them.
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*
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******************************************************************************/
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XStatus
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XEmac_PollRecv(XEmac * InstancePtr, u8 * BufPtr, u32 * ByteCountPtr)
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{
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XStatus Result;
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u32 PktLength;
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u32 IntrStatus;
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XASSERT_NONVOID(InstancePtr != NULL);
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XASSERT_NONVOID(BufPtr != NULL);
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XASSERT_NONVOID(ByteCountPtr != NULL);
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XASSERT_NONVOID(InstancePtr->IsReady == XCOMPONENT_IS_READY);
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/*
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* Be sure the device is configured for polled mode and it is started
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*/
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if (!InstancePtr->IsPolled) {
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return XST_NOT_POLLED;
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}
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if (InstancePtr->IsStarted != XCOMPONENT_IS_STARTED) {
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return XST_DEVICE_IS_STOPPED;
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}
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/*
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* Make sure the buffer is big enough to hold the maximum frame size.
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* We need to do this because as soon as we read the MAC's packet length
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* register, which is actually a FIFO, we remove that length from the
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* FIFO. We do not want to read the length FIFO without also reading the
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* data FIFO since this would get the FIFOs out of sync. So we have to
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* make this restriction.
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*/
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if (*ByteCountPtr < XEM_MAX_FRAME_SIZE) {
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return XST_BUFFER_TOO_SMALL;
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}
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/*
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* First check for packet FIFO deadlock and return an error if it has
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* occurred. A reset by the caller is necessary to correct this problem.
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*/
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if (XPF_V100B_IS_DEADLOCKED(&InstancePtr->RecvFifo)) {
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InstancePtr->Stats.FifoErrors++;
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return XST_FIFO_ERROR;
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}
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/*
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* Get the interrupt status to know what happened (whether an error occurred
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* and/or whether frames have been received successfully). When clearing the
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* intr status register, clear only statuses that pertain to receive.
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*/
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IntrStatus = XIIF_V123B_READ_IISR(InstancePtr->BaseAddress);
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XIIF_V123B_WRITE_IISR(InstancePtr->BaseAddress,
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IntrStatus & XEM_EIR_RECV_ALL_MASK);
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/*
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* Check receive errors and bump statistics so the caller will have a clue
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* as to why data may not have been received. We continue on if an error
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* occurred since there still may be frames that were received successfully.
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*/
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if (IntrStatus & (XEM_EIR_RECV_LFIFO_OVER_MASK |
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XEM_EIR_RECV_DFIFO_OVER_MASK)) {
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InstancePtr->Stats.RecvOverrunErrors++;
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InstancePtr->Stats.FifoErrors++;
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}
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if (IntrStatus & XEM_EIR_RECV_LFIFO_UNDER_MASK) {
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InstancePtr->Stats.RecvUnderrunErrors++;
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InstancePtr->Stats.FifoErrors++;
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}
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/*
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* General receive errors
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*/
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if (IntrStatus & XEM_EIR_RECV_ERROR_MASK) {
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if (IntrStatus & XEM_EIR_RECV_MISSED_FRAME_MASK) {
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InstancePtr->Stats.RecvMissedFrameErrors =
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XIo_In32(InstancePtr->BaseAddress +
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XEM_RMFC_OFFSET);
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}
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if (IntrStatus & XEM_EIR_RECV_COLLISION_MASK) {
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InstancePtr->Stats.RecvCollisionErrors =
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XIo_In32(InstancePtr->BaseAddress + XEM_RCC_OFFSET);
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}
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if (IntrStatus & XEM_EIR_RECV_FCS_ERROR_MASK) {
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InstancePtr->Stats.RecvFcsErrors =
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XIo_In32(InstancePtr->BaseAddress +
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XEM_RFCSEC_OFFSET);
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}
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if (IntrStatus & XEM_EIR_RECV_LEN_ERROR_MASK) {
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InstancePtr->Stats.RecvLengthFieldErrors++;
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}
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if (IntrStatus & XEM_EIR_RECV_SHORT_ERROR_MASK) {
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InstancePtr->Stats.RecvShortErrors++;
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}
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if (IntrStatus & XEM_EIR_RECV_LONG_ERROR_MASK) {
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InstancePtr->Stats.RecvLongErrors++;
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}
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if (IntrStatus & XEM_EIR_RECV_ALIGN_ERROR_MASK) {
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InstancePtr->Stats.RecvAlignmentErrors =
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XIo_In32(InstancePtr->BaseAddress +
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XEM_RAEC_OFFSET);
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}
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}
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/*
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* Before reading from the length FIFO, make sure the length FIFO is not
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* empty. We could cause an underrun error if we try to read from an
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* empty FIFO.
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*/
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if ((IntrStatus & XEM_EIR_RECV_DONE_MASK) == 0) {
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return XST_NO_DATA;
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}
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/*
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* Determine, from the MAC, the length of the next packet available
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* in the data FIFO (there should be a non-zero length here)
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*/
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PktLength = XIo_In32(InstancePtr->BaseAddress + XEM_RPLR_OFFSET);
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if (PktLength == 0) {
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return XST_NO_DATA;
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}
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/*
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* Write the RECV_DONE bit in the status register to clear it. This bit
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* indicates the RPLR is non-empty, and we know it's set at this point.
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* We clear it so that subsequent entry into this routine will reflect the
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* current status. This is done because the non-empty bit is latched in the
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* IPIF, which means it may indicate a non-empty condition even though
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* there is something in the FIFO.
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*/
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XIIF_V123B_WRITE_IISR(InstancePtr->BaseAddress, XEM_EIR_RECV_DONE_MASK);
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/*
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* We assume that the MAC never has a length bigger than the largest
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* Ethernet frame, so no need to make another check here.
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*/
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/*
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* This is a non-blocking read. The FIFO returns an error if there is
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* not at least the requested amount of data in the FIFO.
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*/
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Result =
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XPacketFifoV100b_Read(&InstancePtr->RecvFifo, BufPtr, PktLength);
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if (Result != XST_SUCCESS) {
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return Result;
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}
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InstancePtr->Stats.RecvFrames++;
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InstancePtr->Stats.RecvBytes += PktLength;
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*ByteCountPtr = PktLength;
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return XST_SUCCESS;
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}
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