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fsl_enet.c
1835 lines (1605 loc) · 64.6 KB
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fsl_enet.c
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/*
* Copyright (c) 2015 - 2016, Freescale Semiconductor, Inc.
* Copyright 2016-2017 NXP
*
* Redistribution and use in source and binary forms, with or without modification,
* are permitted provided that the following conditions are met:
*
* o Redistributions of source code must retain the above copyright notice, this list
* of conditions and the following disclaimer.
*
* o Redistributions in binary form must reproduce the above copyright notice, this
* list of conditions and the following disclaimer in the documentation and/or
* other materials provided with the distribution.
*
* o Neither the name of the copyright holder nor the names of its
* contributors may be used to endorse or promote products derived from this
* software without specific prior written permission.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND
* ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
* WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR
* ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES
* (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES;
* LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON
* ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS
* SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "fsl_enet.h"
/*******************************************************************************
* Definitions
******************************************************************************/
/*! @brief IPv4 PTP message IP version offset. */
#define ENET_PTP1588_IPVERSION_OFFSET 0x0EU
/*! @brief IPv4 PTP message UDP protocol offset. */
#define ENET_PTP1588_IPV4_UDP_PROTOCOL_OFFSET 0x17U
/*! @brief IPv4 PTP message UDP port offset. */
#define ENET_PTP1588_IPV4_UDP_PORT_OFFSET 0x24U
/*! @brief IPv4 PTP message UDP message type offset. */
#define ENET_PTP1588_IPV4_UDP_MSGTYPE_OFFSET 0x2AU
/*! @brief IPv4 PTP message UDP version offset. */
#define ENET_PTP1588_IPV4_UDP_VERSION_OFFSET 0x2BU
/*! @brief IPv4 PTP message UDP clock id offset. */
#define ENET_PTP1588_IPV4_UDP_CLKID_OFFSET 0x3EU
/*! @brief IPv4 PTP message UDP sequence id offset. */
#define ENET_PTP1588_IPV4_UDP_SEQUENCEID_OFFSET 0x48U
/*! @brief IPv4 PTP message UDP control offset. */
#define ENET_PTP1588_IPV4_UDP_CTL_OFFSET 0x4AU
/*! @brief IPv6 PTP message UDP protocol offset. */
#define ENET_PTP1588_IPV6_UDP_PROTOCOL_OFFSET 0x14U
/*! @brief IPv6 PTP message UDP port offset. */
#define ENET_PTP1588_IPV6_UDP_PORT_OFFSET 0x38U
/*! @brief IPv6 PTP message UDP message type offset. */
#define ENET_PTP1588_IPV6_UDP_MSGTYPE_OFFSET 0x3EU
/*! @brief IPv6 PTP message UDP version offset. */
#define ENET_PTP1588_IPV6_UDP_VERSION_OFFSET 0x3FU
/*! @brief IPv6 PTP message UDP clock id offset. */
#define ENET_PTP1588_IPV6_UDP_CLKID_OFFSET 0x52U
/*! @brief IPv6 PTP message UDP sequence id offset. */
#define ENET_PTP1588_IPV6_UDP_SEQUENCEID_OFFSET 0x5CU
/*! @brief IPv6 PTP message UDP control offset. */
#define ENET_PTP1588_IPV6_UDP_CTL_OFFSET 0x5EU
/*! @brief PTPv2 message Ethernet packet type offset. */
#define ENET_PTP1588_ETHL2_PACKETTYPE_OFFSET 0x0CU
/*! @brief PTPv2 message Ethernet message type offset. */
#define ENET_PTP1588_ETHL2_MSGTYPE_OFFSET 0x0EU
/*! @brief PTPv2 message Ethernet version type offset. */
#define ENET_PTP1588_ETHL2_VERSION_OFFSET 0X0FU
/*! @brief PTPv2 message Ethernet clock id offset. */
#define ENET_PTP1588_ETHL2_CLOCKID_OFFSET 0x22
/*! @brief PTPv2 message Ethernet sequence id offset. */
#define ENET_PTP1588_ETHL2_SEQUENCEID_OFFSET 0x2c
/*! @brief Packet type Ethernet IEEE802.3 for PTPv2. */
#define ENET_ETHERNETL2 0x88F7U
/*! @brief Packet type IPv4. */
#define ENET_IPV4 0x0800U
/*! @brief Packet type IPv6. */
#define ENET_IPV6 0x86ddU
/*! @brief Packet type VLAN. */
#define ENET_8021QVLAN 0x8100U
/*! @brief UDP protocol type. */
#define ENET_UDPVERSION 0x0011U
/*! @brief Packet IP version IPv4. */
#define ENET_IPV4VERSION 0x0004U
/*! @brief Packet IP version IPv6. */
#define ENET_IPV6VERSION 0x0006U
/*! @brief Ethernet mac address length. */
#define ENET_FRAME_MACLEN 6U
/*! @brief Ethernet VLAN header length. */
#define ENET_FRAME_VLAN_TAGLEN 4U
/*! @brief MDC frequency. */
#define ENET_MDC_FREQUENCY 2500000U
/*! @brief NanoSecond in one second. */
#define ENET_NANOSECOND_ONE_SECOND 1000000000U
/*! @brief Define a common clock cycle delays used for time stamp capture. */
#define ENET_1588TIME_DELAY_COUNT 10U
/*! @brief Defines the macro for converting constants from host byte order to network byte order. */
#define ENET_HTONS(n) __REV16(n)
#define ENET_HTONL(n) __REV(n)
#define ENET_NTOHS(n) __REV16(n)
#define ENET_NTOHL(n) __REV(n)
/* Typedef for interrupt handler. */
typedef void (*enet_isr_t)(ENET_Type *base, enet_handle_t *handle);
/*******************************************************************************
* Prototypes
******************************************************************************/
/*!
* @brief Get the ENET instance from peripheral base address.
*
* @param base ENET peripheral base address.
* @return ENET instance.
*/
uint32_t ENET_GetInstance(ENET_Type *base);
/*!
* @brief Set ENET MAC controller with the configuration.
*
* @param base ENET peripheral base address.
* @param config ENET Mac configuration.
* @param bufferConfig ENET buffer configuration.
* @param macAddr ENET six-byte mac address.
* @param srcClock_Hz ENET module clock source, normally it's system clock.
*/
static void ENET_SetMacController(ENET_Type *base,
const enet_config_t *config,
const enet_buffer_config_t *bufferConfig,
uint8_t *macAddr,
uint32_t srcClock_Hz);
/*!
* @brief Set ENET handler.
*
* @param base ENET peripheral base address.
* @param handle The ENET handle pointer.
* @param config ENET configuration stucture pointer.
* @param bufferConfig ENET buffer configuration.
*/
static void ENET_SetHandler(ENET_Type *base,
enet_handle_t *handle,
const enet_config_t *config,
const enet_buffer_config_t *bufferConfig);
/*!
* @brief Set ENET MAC transmit buffer descriptors.
*
* @param txBdStartAlign The aligned start address of ENET transmit buffer descriptors.
* is recommended to evenly divisible by 16.
* @param txBuffStartAlign The aligned start address of ENET transmit buffers, must be evenly divisible by 16.
* @param txBuffSizeAlign The aligned ENET transmit buffer size, must be evenly divisible by 16.
* @param txBdNumber The number of ENET transmit buffers.
*/
static void ENET_SetTxBufferDescriptors(volatile enet_tx_bd_struct_t *txBdStartAlign,
uint8_t *txBuffStartAlign,
uint32_t txBuffSizeAlign,
uint32_t txBdNumber);
/*!
* @brief Set ENET MAC receive buffer descriptors.
*
* @param rxBdStartAlign The aligned start address of ENET receive buffer descriptors.
* is recommended to evenly divisible by 16.
* @param rxBuffStartAlign The aligned start address of ENET receive buffers, must be evenly divisible by 16.
* @param rxBuffSizeAlign The aligned ENET receive buffer size, must be evenly divisible by 16.
* @param rxBdNumber The number of ENET receive buffers.
* @param enableInterrupt Enable/disables to generate the receive byte and frame interrupt.
* It's used for ENET_ENHANCEDBUFFERDESCRIPTOR_MODE enabled case.
*/
static void ENET_SetRxBufferDescriptors(volatile enet_rx_bd_struct_t *rxBdStartAlign,
uint8_t *rxBuffStartAlign,
uint32_t rxBuffSizeAlign,
uint32_t rxBdNumber,
bool enableInterrupt);
/*!
* @brief Updates the ENET read buffer descriptors.
*
* @param base ENET peripheral base address.
* @param handle The ENET handle pointer.
*/
static void ENET_UpdateReadBuffers(ENET_Type *base, enet_handle_t *handle);
#ifdef ENET_ENHANCEDBUFFERDESCRIPTOR_MODE
/*!
* @brief Parses the ENET frame for time-stamp process of PTP 1588 frame.
*
* @param data The ENET read data for frame parse.
* @param ptpTsData The ENET PTP message and time-stamp data pointer.
* @param isFastEnabled The fast parse flag.
* - true , Fast processing, only check if this is a PTP message.
* - false, Store the PTP message data after check the PTP message.
*/
static bool ENET_Ptp1588ParseFrame(uint8_t *data, enet_ptp_time_data_t *ptpTsData, bool isFastEnabled);
/*!
* @brief Updates the new PTP 1588 time-stamp to the time-stamp buffer ring.
*
* @param ptpTsDataRing The PTP message and time-stamp data ring pointer.
* @param ptpTimeData The new PTP 1588 time-stamp data pointer.
*/
static status_t ENET_Ptp1588UpdateTimeRing(enet_ptp_time_data_ring_t *ptpTsDataRing, enet_ptp_time_data_t *ptpTimeData);
/*!
* @brief Search up the right PTP 1588 time-stamp from the time-stamp buffer ring.
*
* @param ptpTsDataRing The PTP message and time-stamp data ring pointer.
* @param ptpTimeData The find out right PTP 1588 time-stamp data pointer with the specific PTP message.
*/
static status_t ENET_Ptp1588SearchTimeRing(enet_ptp_time_data_ring_t *ptpTsDataRing, enet_ptp_time_data_t *ptpTimedata);
/*!
* @brief Store the transmit time-stamp for event PTP frame in the time-stamp buffer ring.
*
* @param base ENET peripheral base address.
* @param handle The ENET handle pointer.
*/
static status_t ENET_StoreTxFrameTime(ENET_Type *base, enet_handle_t *handle);
/*!
* @brief Store the receive time-stamp for event PTP frame in the time-stamp buffer ring.
*
* @param base ENET peripheral base address.
* @param handle The ENET handle pointer.
* @param ptpTimeData The PTP 1588 time-stamp data pointer.
*/
static status_t ENET_StoreRxFrameTime(ENET_Type *base, enet_handle_t *handle, enet_ptp_time_data_t *ptpTimeData);
#endif /* ENET_ENHANCEDBUFFERDESCRIPTOR_MODE */
/*******************************************************************************
* Variables
******************************************************************************/
/*! @brief Pointers to enet handles for each instance. */
static enet_handle_t *s_ENETHandle[FSL_FEATURE_SOC_ENET_COUNT] = {NULL};
#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
/*! @brief Pointers to enet clocks for each instance. */
const clock_ip_name_t s_enetClock[] = ENET_CLOCKS;
#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
/*! @brief Pointers to enet transmit IRQ number for each instance. */
static const IRQn_Type s_enetTxIrqId[] = ENET_Transmit_IRQS;
/*! @brief Pointers to enet receive IRQ number for each instance. */
static const IRQn_Type s_enetRxIrqId[] = ENET_Receive_IRQS;
#if defined(ENET_ENHANCEDBUFFERDESCRIPTOR_MODE) && ENET_ENHANCEDBUFFERDESCRIPTOR_MODE
/*! @brief Pointers to enet timestamp IRQ number for each instance. */
static const IRQn_Type s_enetTsIrqId[] = ENET_1588_Timer_IRQS;
#endif /* ENET_ENHANCEDBUFFERDESCRIPTOR_MODE */
/*! @brief Pointers to enet error IRQ number for each instance. */
static const IRQn_Type s_enetErrIrqId[] = ENET_Error_IRQS;
/*! @brief Pointers to enet bases for each instance. */
static ENET_Type *const s_enetBases[] = ENET_BASE_PTRS;
/* ENET ISR for transactional APIs. */
static enet_isr_t s_enetTxIsr;
static enet_isr_t s_enetRxIsr;
static enet_isr_t s_enetErrIsr;
static enet_isr_t s_enetTsIsr;
/*******************************************************************************
* Code
******************************************************************************/
uint32_t ENET_GetInstance(ENET_Type *base)
{
uint32_t instance;
/* Find the instance index from base address mappings. */
for (instance = 0; instance < ARRAY_SIZE(s_enetBases); instance++)
{
if (s_enetBases[instance] == base)
{
break;
}
}
assert(instance < ARRAY_SIZE(s_enetBases));
return instance;
}
void ENET_GetDefaultConfig(enet_config_t *config)
{
/* Checks input parameter. */
assert(config);
/* Initializes the MAC configure structure to zero. */
memset(config, 0, sizeof(enet_config_t));
/* Sets MII mode, full duplex, 100Mbps for MAC and PHY data interface. */
config->miiMode = kENET_RmiiMode;
config->miiSpeed = kENET_MiiSpeed100M;
config->miiDuplex = kENET_MiiFullDuplex;
/* Sets the maximum receive frame length. */
config->rxMaxFrameLen = ENET_FRAME_MAX_FRAMELEN;
}
void ENET_Init(ENET_Type *base,
enet_handle_t *handle,
const enet_config_t *config,
const enet_buffer_config_t *bufferConfig,
uint8_t *macAddr,
uint32_t srcClock_Hz)
{
/* Checks input parameters. */
assert(handle);
assert(config);
assert(bufferConfig);
assert(bufferConfig->rxBdStartAddrAlign);
assert(bufferConfig->txBdStartAddrAlign);
assert(bufferConfig->rxBufferAlign);
assert(macAddr);
#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
uint32_t instance = ENET_GetInstance(base);
/* Ungate ENET clock. */
CLOCK_EnableClock(s_enetClock[instance]);
#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
/* Reset ENET module. */
ENET_Reset(base);
/* Initializes the ENET transmit buffer descriptors. */
ENET_SetTxBufferDescriptors(bufferConfig->txBdStartAddrAlign, bufferConfig->txBufferAlign,
bufferConfig->txBuffSizeAlign, bufferConfig->txBdNumber);
/* Initializes the ENET receive buffer descriptors. */
ENET_SetRxBufferDescriptors(bufferConfig->rxBdStartAddrAlign, bufferConfig->rxBufferAlign,
bufferConfig->rxBuffSizeAlign, bufferConfig->rxBdNumber,
!!(config->interrupt & (kENET_RxFrameInterrupt | kENET_RxBufferInterrupt)));
/* Initializes the ENET MAC controller. */
ENET_SetMacController(base, config, bufferConfig, macAddr, srcClock_Hz);
/* Set all buffers or data in handler for data transmit/receive process. */
ENET_SetHandler(base, handle, config, bufferConfig);
}
void ENET_Deinit(ENET_Type *base)
{
/* Disable interrupt. */
base->EIMR = 0;
/* Disable ENET. */
base->ECR &= ~ENET_ECR_ETHEREN_MASK;
#if !(defined(FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL) && FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL)
/* Disables the clock source. */
CLOCK_DisableClock(s_enetClock[ENET_GetInstance(base)]);
#endif /* FSL_SDK_DISABLE_DRIVER_CLOCK_CONTROL */
}
void ENET_SetCallback(enet_handle_t *handle, enet_callback_t callback, void *userData)
{
assert(handle);
/* Set callback and userData. */
handle->callback = callback;
handle->userData = userData;
}
static void ENET_SetHandler(ENET_Type *base,
enet_handle_t *handle,
const enet_config_t *config,
const enet_buffer_config_t *bufferConfig)
{
uint32_t instance = ENET_GetInstance(base);
memset(handle, 0, sizeof(enet_handle_t));
handle->rxBdBase = bufferConfig->rxBdStartAddrAlign;
handle->rxBdCurrent = bufferConfig->rxBdStartAddrAlign;
handle->txBdBase = bufferConfig->txBdStartAddrAlign;
handle->txBdCurrent = bufferConfig->txBdStartAddrAlign;
handle->txBdDirty = bufferConfig->txBdStartAddrAlign;
handle->rxBuffSizeAlign = bufferConfig->rxBuffSizeAlign;
handle->txBuffSizeAlign = bufferConfig->txBuffSizeAlign;
/* Save the handle pointer in the global variables. */
s_ENETHandle[instance] = handle;
/* Set the IRQ handler when the interrupt is enabled. */
if (config->interrupt & ENET_TX_INTERRUPT)
{
s_enetTxIsr = ENET_TransmitIRQHandler;
EnableIRQ(s_enetTxIrqId[instance]);
}
if (config->interrupt & ENET_RX_INTERRUPT)
{
s_enetRxIsr = ENET_ReceiveIRQHandler;
EnableIRQ(s_enetRxIrqId[instance]);
}
if (config->interrupt & ENET_ERR_INTERRUPT)
{
s_enetErrIsr = ENET_ErrorIRQHandler;
EnableIRQ(s_enetErrIrqId[instance]);
}
}
static void ENET_SetMacController(ENET_Type *base,
const enet_config_t *config,
const enet_buffer_config_t *bufferConfig,
uint8_t *macAddr,
uint32_t srcClock_Hz)
{
uint32_t rcr = 0;
uint32_t tcr = 0;
uint32_t ecr = 0;
uint32_t macSpecialConfig = config->macSpecialConfig;
uint32_t maxFrameLen = config->rxMaxFrameLen;
/* Maximum frame length check. */
if ((macSpecialConfig & kENET_ControlVLANTagEnable) && (maxFrameLen <= ENET_FRAME_MAX_FRAMELEN))
{
maxFrameLen = (ENET_FRAME_MAX_FRAMELEN + ENET_FRAME_VLAN_TAGLEN);
}
/* Configures MAC receive controller with user configure structure. */
rcr = ENET_RCR_NLC(!!(macSpecialConfig & kENET_ControlRxPayloadCheckEnable)) |
ENET_RCR_CFEN(!!(macSpecialConfig & kENET_ControlFlowControlEnable)) |
ENET_RCR_FCE(!!(macSpecialConfig & kENET_ControlFlowControlEnable)) |
ENET_RCR_PADEN(!!(macSpecialConfig & kENET_ControlRxPadRemoveEnable)) |
ENET_RCR_BC_REJ(!!(macSpecialConfig & kENET_ControlRxBroadCastRejectEnable)) |
ENET_RCR_PROM(!!(macSpecialConfig & kENET_ControlPromiscuousEnable)) | ENET_RCR_MII_MODE(1) |
ENET_RCR_RMII_MODE(config->miiMode) | ENET_RCR_RMII_10T(!config->miiSpeed) |
ENET_RCR_MAX_FL(maxFrameLen) | ENET_RCR_CRCFWD(1);
/* Receive setting for half duplex. */
if (config->miiDuplex == kENET_MiiHalfDuplex)
{
rcr |= ENET_RCR_DRT_MASK;
}
/* Sets internal loop only for MII mode. */
if ((config->macSpecialConfig & kENET_ControlMIILoopEnable) && (config->miiMode == kENET_MiiMode))
{
rcr |= ENET_RCR_LOOP_MASK;
rcr &= ~ENET_RCR_DRT_MASK;
}
base->RCR = rcr;
/* Configures MAC transmit controller: duplex mode, mac address insertion. */
tcr = base->TCR & ~(ENET_TCR_FDEN_MASK | ENET_TCR_ADDINS_MASK);
tcr |= ENET_TCR_FDEN(config->miiDuplex) | ENET_TCR_ADDINS(!!(macSpecialConfig & kENET_ControlMacAddrInsert));
base->TCR = tcr;
/* Configures receive and transmit accelerator. */
base->TACC = config->txAccelerConfig;
base->RACC = config->rxAccelerConfig;
/* Sets the pause duration and FIFO threshold for the flow control enabled case. */
if (macSpecialConfig & kENET_ControlFlowControlEnable)
{
uint32_t reemReg;
base->OPD = config->pauseDuration;
reemReg = ENET_RSEM_RX_SECTION_EMPTY(config->rxFifoEmptyThreshold);
#if defined (FSL_FEATURE_ENET_HAS_RECEIVE_STATUS_THRESHOLD) && FSL_FEATURE_ENET_HAS_RECEIVE_STATUS_THRESHOLD
reemReg |= ENET_RSEM_STAT_SECTION_EMPTY(config->rxFifoStatEmptyThreshold);
#endif /* FSL_FEATURE_ENET_HAS_RECEIVE_STATUS_THRESHOLD */
base->RSEM = reemReg;
}
/* FIFO threshold setting for store and forward enable/disable case. */
if (macSpecialConfig & kENET_ControlStoreAndFwdDisable)
{
/* Transmit fifo watermark settings. */
base->TFWR = config->txFifoWatermark & ENET_TFWR_TFWR_MASK;
/* Receive fifo full threshold settings. */
base->RSFL = config->rxFifoFullThreshold & ENET_RSFL_RX_SECTION_FULL_MASK;
}
else
{
/* Transmit fifo watermark settings. */
base->TFWR = ENET_TFWR_STRFWD_MASK;
base->RSFL = 0;
}
/* Enable store and forward when accelerator is enabled */
if (config->txAccelerConfig & (kENET_TxAccelIpCheckEnabled | kENET_TxAccelProtoCheckEnabled))
{
base->TFWR = ENET_TFWR_STRFWD_MASK;
}
if (config->rxAccelerConfig & (kENET_RxAccelIpCheckEnabled | kENET_RxAccelProtoCheckEnabled))
{
base->RSFL = 0;
}
/* Initializes transmit buffer descriptor rings start address, two start address should be aligned. */
base->TDSR = (uint32_t)bufferConfig->txBdStartAddrAlign;
base->RDSR = (uint32_t)bufferConfig->rxBdStartAddrAlign;
/* Initializes the maximum buffer size, the buffer size should be aligned. */
base->MRBR = bufferConfig->rxBuffSizeAlign;
/* Configures the Mac address. */
ENET_SetMacAddr(base, macAddr);
/* Initialize the SMI if uninitialized. */
if (!ENET_GetSMI(base))
{
ENET_SetSMI(base, srcClock_Hz, !!(config->macSpecialConfig & kENET_ControlSMIPreambleDisable));
}
/* Enables Ethernet interrupt and NVIC. */
#if defined(FSL_FEATURE_ENET_HAS_INTERRUPT_COALESCE) && FSL_FEATURE_ENET_HAS_INTERRUPT_COALESCE
if (config->intCoalesceCfg)
{
uint32_t intMask = (ENET_EIMR_TXB_MASK | ENET_EIMR_RXB_MASK);
/* Clear all buffer interrupts. */
base->EIMR &= ~intMask;
/* Set the interrupt coalescence. */
base->TXIC = ENET_TXIC_ICFT(config->intCoalesceCfg->txCoalesceFrameCount[0]) |
config->intCoalesceCfg->txCoalesceTimeCount[0] | ENET_TXIC_ICCS_MASK | ENET_TXIC_ICEN_MASK;
base->RXIC = ENET_RXIC_ICFT(config->intCoalesceCfg->rxCoalesceFrameCount[0]) |
config->intCoalesceCfg->rxCoalesceTimeCount[0] | ENET_RXIC_ICCS_MASK | ENET_RXIC_ICEN_MASK;
}
#endif /* FSL_FEATURE_ENET_HAS_INTERRUPT_COALESCE */
ENET_EnableInterrupts(base, config->interrupt);
/* ENET control register setting. */
ecr = base->ECR;
#ifdef ENET_ENHANCEDBUFFERDESCRIPTOR_MODE
/* Sets the 1588 enhanced feature. */
ecr |= ENET_ECR_EN1588_MASK;
#endif /* ENET_ENHANCEDBUFFERDESCRIPTOR_MODE */
/* Enables Ethernet module after all configuration except the buffer descriptor active. */
ecr |= ENET_ECR_ETHEREN_MASK | ENET_ECR_DBSWP_MASK;
base->ECR = ecr;
}
static void ENET_SetTxBufferDescriptors(volatile enet_tx_bd_struct_t *txBdStartAlign,
uint8_t *txBuffStartAlign,
uint32_t txBuffSizeAlign,
uint32_t txBdNumber)
{
assert(txBdStartAlign);
uint32_t count;
volatile enet_tx_bd_struct_t *curBuffDescrip = txBdStartAlign;
for (count = 0; count < txBdNumber; count++)
{
if (txBuffStartAlign != NULL)
{
/* Set data buffer address. */
curBuffDescrip->buffer = (uint8_t *)((uint32_t)&txBuffStartAlign[count * txBuffSizeAlign]);
}
else
{
/* User should provide the transmit buffer at a later time */
curBuffDescrip->buffer = NULL;
}
/* Initializes data length. */
curBuffDescrip->length = 0;
/* Sets the crc. */
curBuffDescrip->control = ENET_BUFFDESCRIPTOR_TX_TRANMITCRC_MASK;
/* Sets the last buffer descriptor with the wrap flag. */
if (count == txBdNumber - 1)
{
curBuffDescrip->control |= ENET_BUFFDESCRIPTOR_TX_WRAP_MASK;
}
#ifdef ENET_ENHANCEDBUFFERDESCRIPTOR_MODE
/* Enable transmit interrupt for store the transmit timestamp. */
curBuffDescrip->controlExtend1 |= ENET_BUFFDESCRIPTOR_TX_INTERRUPT_MASK;
#endif /* ENET_ENHANCEDBUFFERDESCRIPTOR_MODE */
/* Increase the index. */
curBuffDescrip++;
}
}
static void ENET_SetRxBufferDescriptors(volatile enet_rx_bd_struct_t *rxBdStartAlign,
uint8_t *rxBuffStartAlign,
uint32_t rxBuffSizeAlign,
uint32_t rxBdNumber,
bool enableInterrupt)
{
assert(rxBdStartAlign);
assert(rxBuffStartAlign);
volatile enet_rx_bd_struct_t *curBuffDescrip = rxBdStartAlign;
uint32_t count = 0;
/* Initializes receive buffer descriptors. */
for (count = 0; count < rxBdNumber; count++)
{
/* Set data buffer and the length. */
curBuffDescrip->buffer = (uint8_t *)(*((uint32_t *)(rxBuffStartAlign + count * 4)));
curBuffDescrip->length = 0;
/* Initializes the buffer descriptors with empty bit. */
curBuffDescrip->control = ENET_BUFFDESCRIPTOR_RX_EMPTY_MASK;
/* Sets the last buffer descriptor with the wrap flag. */
if (count == rxBdNumber - 1)
{
curBuffDescrip->control |= ENET_BUFFDESCRIPTOR_RX_WRAP_MASK;
}
#ifdef ENET_ENHANCEDBUFFERDESCRIPTOR_MODE
if (enableInterrupt)
{
/* Enable receive interrupt. */
curBuffDescrip->controlExtend1 |= ENET_BUFFDESCRIPTOR_RX_INTERRUPT_MASK;
}
else
{
curBuffDescrip->controlExtend1 = 0;
}
#endif /* ENET_ENHANCEDBUFFERDESCRIPTOR_MODE */
/* Increase the index. */
curBuffDescrip++;
}
}
void ENET_SetMII(ENET_Type *base, enet_mii_speed_t speed, enet_mii_duplex_t duplex)
{
uint32_t rcr = base->RCR;
uint32_t tcr = base->TCR;
/* Sets speed mode. */
if (kENET_MiiSpeed10M == speed)
{
rcr |= ENET_RCR_RMII_10T_MASK;
}
else
{
rcr &= ~ENET_RCR_RMII_10T_MASK;
}
/* Set duplex mode. */
if (duplex == kENET_MiiHalfDuplex)
{
rcr |= ENET_RCR_DRT_MASK;
tcr &= ~ENET_TCR_FDEN_MASK;
}
else
{
rcr &= ~ENET_RCR_DRT_MASK;
tcr |= ENET_TCR_FDEN_MASK;
}
base->RCR = rcr;
base->TCR = tcr;
}
void ENET_SetMacAddr(ENET_Type *base, uint8_t *macAddr)
{
uint32_t address;
/* Set physical address lower register. */
address = (uint32_t)(((uint32_t)macAddr[0] << 24U) | ((uint32_t)macAddr[1] << 16U) | ((uint32_t)macAddr[2] << 8U) |
(uint32_t)macAddr[3]);
base->PALR = address;
/* Set physical address high register. */
address = (uint32_t)(((uint32_t)macAddr[4] << 8U) | ((uint32_t)macAddr[5]));
base->PAUR = address << ENET_PAUR_PADDR2_SHIFT;
}
void ENET_GetMacAddr(ENET_Type *base, uint8_t *macAddr)
{
assert(macAddr);
uint32_t address;
/* Get from physical address lower register. */
address = base->PALR;
macAddr[0] = 0xFFU & (address >> 24U);
macAddr[1] = 0xFFU & (address >> 16U);
macAddr[2] = 0xFFU & (address >> 8U);
macAddr[3] = 0xFFU & address;
/* Get from physical address high register. */
address = (base->PAUR & ENET_PAUR_PADDR2_MASK) >> ENET_PAUR_PADDR2_SHIFT;
macAddr[4] = 0xFFU & (address >> 8U);
macAddr[5] = 0xFFU & address;
}
void ENET_SetSMI(ENET_Type *base, uint32_t srcClock_Hz, bool isPreambleDisabled)
{
assert(srcClock_Hz);
uint32_t clkCycle = 0;
uint32_t speed = 0;
uint32_t mscr = 0;
/* Calculate the MII speed which controls the frequency of the MDC. */
speed = srcClock_Hz / (2 * ENET_MDC_FREQUENCY);
/* Calculate the hold time on the MDIO output. */
clkCycle = (10 + ENET_NANOSECOND_ONE_SECOND / srcClock_Hz - 1) / (ENET_NANOSECOND_ONE_SECOND / srcClock_Hz) - 1;
/* Build the configuration for MDC/MDIO control. */
mscr = ENET_MSCR_MII_SPEED(speed) | ENET_MSCR_DIS_PRE(isPreambleDisabled) | ENET_MSCR_HOLDTIME(clkCycle);
base->MSCR = mscr;
}
void ENET_StartSMIWrite(ENET_Type *base, uint32_t phyAddr, uint32_t phyReg, enet_mii_write_t operation, uint32_t data)
{
uint32_t mmfr = 0;
/* Build MII write command. */
mmfr = ENET_MMFR_ST(1) | ENET_MMFR_OP(operation) | ENET_MMFR_PA(phyAddr) | ENET_MMFR_RA(phyReg) | ENET_MMFR_TA(2) |
(data & 0xFFFF);
base->MMFR = mmfr;
}
void ENET_StartSMIRead(ENET_Type *base, uint32_t phyAddr, uint32_t phyReg, enet_mii_read_t operation)
{
uint32_t mmfr = 0;
/* Build MII read command. */
mmfr = ENET_MMFR_ST(1) | ENET_MMFR_OP(operation) | ENET_MMFR_PA(phyAddr) | ENET_MMFR_RA(phyReg) | ENET_MMFR_TA(2);
base->MMFR = mmfr;
}
#if defined(FSL_FEATURE_ENET_HAS_EXTEND_MDIO) && FSL_FEATURE_ENET_HAS_EXTEND_MDIO
void ENET_StartExtC45SMIWrite(ENET_Type *base, uint32_t phyAddr, uint32_t phyReg, uint32_t data)
{
uint32_t mmfr = 0;
/* Parse the address from the input register. */
uint16_t devAddr = (phyReg >> ENET_MMFR_TA_SHIFT) & 0x1FU;
uint16_t regAddr = (uint16_t)(phyReg & 0xFFFFU);
/* Address write firstly. */
mmfr = ENET_MMFR_ST(0) | ENET_MMFR_OP(kENET_MiiAddrWrite_C45) | ENET_MMFR_PA(phyAddr) | ENET_MMFR_RA(devAddr) |
ENET_MMFR_TA(2) | ENET_MMFR_DATA(regAddr);
base->MMFR = mmfr;
/* Build MII write command. */
mmfr = ENET_MMFR_ST(0) | ENET_MMFR_OP(kENET_MiiWriteFrame_C45) | ENET_MMFR_PA(phyAddr) | ENET_MMFR_RA(devAddr) |
ENET_MMFR_TA(2) | ENET_MMFR_DATA(data);
base->MMFR = mmfr;
}
void ENET_StartExtC45SMIRead(ENET_Type *base, uint32_t phyAddr, uint32_t phyReg)
{
uint32_t mmfr = 0;
/* Parse the address from the input register. */
uint16_t devAddr = (phyReg >> ENET_MMFR_TA_SHIFT) & 0x1FU;
uint16_t regAddr = (uint16_t)(phyReg & 0xFFFFU);
/* Address write firstly. */
mmfr = ENET_MMFR_ST(0) | ENET_MMFR_OP(kENET_MiiAddrWrite_C45) | ENET_MMFR_PA(phyAddr) | ENET_MMFR_RA(devAddr) |
ENET_MMFR_TA(2) | ENET_MMFR_DATA(regAddr);
base->MMFR = mmfr;
/* Build MII read command. */
mmfr = ENET_MMFR_ST(0) | ENET_MMFR_OP(kENET_MiiReadFrame_C45) | ENET_MMFR_PA(phyAddr) | ENET_MMFR_RA(devAddr) |
ENET_MMFR_TA(2);
base->MMFR = mmfr;
}
#endif /* FSL_FEATURE_ENET_HAS_EXTEND_MDIO */
void ENET_GetRxErrBeforeReadFrame(enet_handle_t *handle, enet_data_error_stats_t *eErrorStatic)
{
assert(handle);
assert(handle->rxBdCurrent);
assert(eErrorStatic);
uint16_t control = 0;
volatile enet_rx_bd_struct_t *curBuffDescrip = handle->rxBdCurrent;
do
{
/* The last buffer descriptor of a frame. */
if (curBuffDescrip->control & ENET_BUFFDESCRIPTOR_RX_LAST_MASK)
{
control = curBuffDescrip->control;
if (control & ENET_BUFFDESCRIPTOR_RX_TRUNC_MASK)
{
/* The receive truncate error. */
eErrorStatic->statsRxTruncateErr++;
}
if (control & ENET_BUFFDESCRIPTOR_RX_OVERRUN_MASK)
{
/* The receive over run error. */
eErrorStatic->statsRxOverRunErr++;
}
if (control & ENET_BUFFDESCRIPTOR_RX_LENVLIOLATE_MASK)
{
/* The receive length violation error. */
eErrorStatic->statsRxLenGreaterErr++;
}
if (control & ENET_BUFFDESCRIPTOR_RX_NOOCTET_MASK)
{
/* The receive alignment error. */
eErrorStatic->statsRxAlignErr++;
}
if (control & ENET_BUFFDESCRIPTOR_RX_CRC_MASK)
{
/* The receive CRC error. */
eErrorStatic->statsRxFcsErr++;
}
#ifdef ENET_ENHANCEDBUFFERDESCRIPTOR_MODE
uint16_t controlExt = curBuffDescrip->controlExtend1;
if (controlExt & ENET_BUFFDESCRIPTOR_RX_MACERR_MASK)
{
/* The MAC error. */
eErrorStatic->statsRxMacErr++;
}
if (controlExt & ENET_BUFFDESCRIPTOR_RX_PHYERR_MASK)
{
/* The PHY error. */
eErrorStatic->statsRxPhyErr++;
}
if (controlExt & ENET_BUFFDESCRIPTOR_RX_COLLISION_MASK)
{
/* The receive collision error. */
eErrorStatic->statsRxCollisionErr++;
}
#endif /* ENET_ENHANCEDBUFFERDESCRIPTOR_MODE */
break;
}
/* Increase the buffer descriptor, if it is the last one, increase to first one of the ring buffer. */
if (curBuffDescrip->control & ENET_BUFFDESCRIPTOR_RX_WRAP_MASK)
{
curBuffDescrip = handle->rxBdBase;
}
else
{
curBuffDescrip++;
}
} while (curBuffDescrip != handle->rxBdCurrent);
}
status_t ENET_GetRxFrameSize(enet_handle_t *handle, uint32_t *length)
{
assert(handle);
assert(handle->rxBdCurrent);
assert(length);
/* Reset the length to zero. */
*length = 0;
uint16_t validLastMask = ENET_BUFFDESCRIPTOR_RX_LAST_MASK | ENET_BUFFDESCRIPTOR_RX_EMPTY_MASK;
volatile enet_rx_bd_struct_t *curBuffDescrip = handle->rxBdCurrent;
/* Check the current buffer descriptor's empty flag. if empty means there is no frame received. */
if (curBuffDescrip->control & ENET_BUFFDESCRIPTOR_RX_EMPTY_MASK)
{
return kStatus_ENET_RxFrameEmpty;
}
do
{
/* Find the last buffer descriptor. */
if ((curBuffDescrip->control & validLastMask) == ENET_BUFFDESCRIPTOR_RX_LAST_MASK)
{
/* The last buffer descriptor in the frame check the status of the received frame. */
if ((curBuffDescrip->control & ENET_BUFFDESCRIPTOR_RX_ERR_MASK)
#ifdef ENET_ENHANCEDBUFFERDESCRIPTOR_MODE
|| (curBuffDescrip->controlExtend1 & ENET_BUFFDESCRIPTOR_RX_EXT_ERR_MASK)
#endif /* ENET_ENHANCEDBUFFERDESCRIPTOR_MODE */
)
{
return kStatus_ENET_RxFrameError;
}
/* FCS is removed by MAC. */
*length = curBuffDescrip->length;
return kStatus_Success;
}
/* Increase the buffer descriptor, if it is the last one, increase to first one of the ring buffer. */
if (curBuffDescrip->control & ENET_BUFFDESCRIPTOR_RX_WRAP_MASK)
{
curBuffDescrip = handle->rxBdBase;
}
else
{
curBuffDescrip++;
}
} while (curBuffDescrip != handle->rxBdCurrent);
/* The frame is on processing - set to empty status to make application to receive it next time. */
return kStatus_ENET_RxFrameEmpty;
}
status_t ENET_ReadFrame(ENET_Type *base, enet_handle_t *handle, uint8_t *data, uint32_t length)
{
assert(handle);
assert(handle->rxBdCurrent);
uint32_t len = 0;
uint32_t offset = 0;
uint16_t control;
bool isLastBuff = false;
volatile enet_rx_bd_struct_t *curBuffDescrip = handle->rxBdCurrent;
status_t result = kStatus_Success;
/* For data-NULL input, only update the buffer descriptor. */
if (!data)
{
do
{
/* Update the control flag. */
control = handle->rxBdCurrent->control;
/* Updates the receive buffer descriptors. */
ENET_UpdateReadBuffers(base, handle);
/* Find the last buffer descriptor for the frame. */
if (control & ENET_BUFFDESCRIPTOR_RX_LAST_MASK)
{
break;
}
} while (handle->rxBdCurrent != curBuffDescrip);
return result;
}
else
{
/* A frame on one buffer or several receive buffers are both considered. */
#ifdef ENET_ENHANCEDBUFFERDESCRIPTOR_MODE
enet_ptp_time_data_t ptpTimestamp;
bool isPtpEventMessage = false;
/* Parse the PTP message according to the header message. */
isPtpEventMessage = ENET_Ptp1588ParseFrame(curBuffDescrip->buffer, &ptpTimestamp, false);
#endif /* ENET_ENHANCEDBUFFERDESCRIPTOR_MODE */
while (!isLastBuff)
{
/* The last buffer descriptor of a frame. */
if (curBuffDescrip->control & ENET_BUFFDESCRIPTOR_RX_LAST_MASK)
{
/* This is a valid frame. */
isLastBuff = true;
if (length == curBuffDescrip->length)
{
/* Copy the frame to user's buffer without FCS. */
len = curBuffDescrip->length - offset;
memcpy(data + offset, curBuffDescrip->buffer, len);
#ifdef ENET_ENHANCEDBUFFERDESCRIPTOR_MODE
/* Store the PTP 1588 timestamp for received PTP event frame. */
if (isPtpEventMessage)
{
/* Set the timestamp to the timestamp ring. */
ptpTimestamp.timeStamp.nanosecond = curBuffDescrip->timestamp;
result = ENET_StoreRxFrameTime(base, handle, &ptpTimestamp);
}
#endif /* ENET_ENHANCEDBUFFERDESCRIPTOR_MODE */
/* Updates the receive buffer descriptors. */
ENET_UpdateReadBuffers(base, handle);
return result;
}
else
{
/* Updates the receive buffer descriptors. */
ENET_UpdateReadBuffers(base, handle);
}
}
else
{
/* Store a frame on several buffer descriptors. */
isLastBuff = false;
/* Length check. */
if (offset >= length)
{
break;
}
memcpy(data + offset, curBuffDescrip->buffer, handle->rxBuffSizeAlign);
offset += handle->rxBuffSizeAlign;
/* Updates the receive buffer descriptors. */
ENET_UpdateReadBuffers(base, handle);
}
/* Get the current buffer descriptor. */
curBuffDescrip = handle->rxBdCurrent;
}
}
return kStatus_ENET_RxFrameFail;
}
static void ENET_UpdateReadBuffers(ENET_Type *base, enet_handle_t *handle)
{
assert(handle);
/* Clears status. */
handle->rxBdCurrent->control &= ENET_BUFFDESCRIPTOR_RX_WRAP_MASK;
/* Sets the receive buffer descriptor with the empty flag. */
handle->rxBdCurrent->control |= ENET_BUFFDESCRIPTOR_RX_EMPTY_MASK;
/* Increase current buffer descriptor to the next one. */
if (handle->rxBdCurrent->control & ENET_BUFFDESCRIPTOR_RX_WRAP_MASK)
{
handle->rxBdCurrent = handle->rxBdBase;
}
else
{
handle->rxBdCurrent++;
}