rt-thread-official/bsp/ls1cdev/drivers/net/synopGMAC.c

973 lines
31 KiB
C

/*
* Copyright (c) 2006-2018, RT-Thread Development Team
*
* SPDX-License-Identifier: Apache-2.0
*
* Change Logs:
* Date Author Notes
* 2017-08-24 chinesebear first version
*/
#include <rtthread.h>
#include <rtdef.h>
//#include <lwip/pbuf.h>
#include "synopGMAC.h"
#include "mii.c"
#include "synopGMAC_debug.h"
#include <ls1c.h>
#include "ls1c_pin.h"
#define RMII
#define Gmac_base 0xbfe10000
#define Buffer_Size 2048
#define MAX_ADDR_LEN 6
#define NAMESIZE 16
#define LS1B_GMAC0_IRQ 34
#define BUS_SIZE_ALIGN(x) ((x+15)&~15)
#define DEFAULT_MAC_ADDRESS {0x00, 0x55, 0x7B, 0xB5, 0x7D, 0xF7}
u32 regbase = 0xbfe10000;
static u32 GMAC_Power_down;
extern void *plat_alloc_consistent_dmaable_memory(synopGMACdevice *pcidev, u32 size, u32 *addr) ;
extern s32 synopGMAC_check_phy_init(synopGMACPciNetworkAdapter *adapter) ;
extern int init_phy(synopGMACdevice *gmacdev);
dma_addr_t plat_dma_map_single(void *hwdev, void *ptr, u32 size);
void eth_rx_irq(int irqno, void *param);
static char Rx_Buffer[Buffer_Size];
static char Tx_Buffer[Buffer_Size];
struct rt_eth_dev
{
struct eth_device parent;
rt_uint8_t dev_addr[MAX_ADDR_LEN];
char *name;
int iobase;
int state;
int index;
struct rt_timer link_timer;
struct rt_timer rx_poll_timer;
void *priv;
};
static struct rt_eth_dev eth_dev;
static struct rt_semaphore sem_ack, sem_lock;
/**
* This sets up the transmit Descriptor queue in ring or chain mode.
* This function is tightly coupled to the platform and operating system
* Device is interested only after the descriptors are setup. Therefore this function
* is not included in the device driver API. This function should be treated as an
* example code to design the descriptor structures for ring mode or chain mode.
* This function depends on the pcidev structure for allocation consistent dma-able memory in case
* of linux.
* This limitation is due to the fact that linux uses pci structure to allocate a dmable memory
* - Allocates the memory for the descriptors.
* - Initialize the Busy and Next descriptors indices to 0(Indicating first descriptor).
* - Initialize the Busy and Next descriptors to first descriptor address.
* - Initialize the last descriptor with the endof ring in case of ring mode.
* - Initialize the descriptors in chain mode.
* @param[in] pointer to synopGMACdevice.
* @param[in] pointer to pci_device structure.
* @param[in] number of descriptor expected in tx descriptor queue.
* @param[in] whether descriptors to be created in RING mode or CHAIN mode.
* \return 0 upon success. Error code upon failure.
* \note This function fails if allocation fails for required number of descriptors in Ring mode,
* but in chain mode
* function returns -ESYNOPGMACNOMEM in the process of descriptor chain creation. once returned from
* this function
* user should for gmacdev->TxDescCount to see how many descriptors are there in the chain. Should
* continue further
* only if the number of descriptors in the chain meets the requirements
*/
s32 synopGMAC_setup_tx_desc_queue(synopGMACdevice *gmacdev, u32 no_of_desc, u32 desc_mode)
{
s32 i;
DmaDesc *bf1;
DmaDesc *first_desc = NULL;
dma_addr_t dma_addr;
gmacdev->TxDescCount = 0;
first_desc = (DmaDesc *)plat_alloc_consistent_dmaable_memory(gmacdev, sizeof(DmaDesc) * no_of_desc, &dma_addr);
if (first_desc == NULL)
{
rt_kprintf("Error in Tx Descriptors memory allocation\n");
return -ESYNOPGMACNOMEM;
}
DEBUG_MES("tx_first_desc_addr = %p\n", first_desc);
DEBUG_MES("dmaadr = %p\n", dma_addr);
gmacdev->TxDescCount = no_of_desc;
gmacdev->TxDesc = first_desc;
gmacdev->TxDescDma = dma_addr;
for (i = 0; i < gmacdev->TxDescCount; i++)
{
synopGMAC_tx_desc_init_ring(gmacdev->TxDesc + i, i == gmacdev->TxDescCount - 1);
#if SYNOP_TOP_DEBUG
rt_kprintf("\n%02d %08x \n", i, (unsigned int)(gmacdev->TxDesc + i));
rt_kprintf("%08x ", (unsigned int)((gmacdev->TxDesc + i))->status);
rt_kprintf("%08x ", (unsigned int)((gmacdev->TxDesc + i)->length));
rt_kprintf("%08x ", (unsigned int)((gmacdev->TxDesc + i)->buffer1));
rt_kprintf("%08x ", (unsigned int)((gmacdev->TxDesc + i)->buffer2));
rt_kprintf("%08x ", (unsigned int)((gmacdev->TxDesc + i)->data1));
rt_kprintf("%08x ", (unsigned int)((gmacdev->TxDesc + i)->data2));
rt_kprintf("%08x ", (unsigned int)((gmacdev->TxDesc + i)->dummy1));
rt_kprintf("%08x ", (unsigned int)((gmacdev->TxDesc + i)->dummy2));
#endif
}
gmacdev->TxNext = 0;
gmacdev->TxBusy = 0;
gmacdev->TxNextDesc = gmacdev->TxDesc;
gmacdev->TxBusyDesc = gmacdev->TxDesc;
gmacdev->BusyTxDesc = 0;
return -ESYNOPGMACNOERR;
}
/**
* This sets up the receive Descriptor queue in ring or chain mode.
* This function is tightly coupled to the platform and operating system
* Device is interested only after the descriptors are setup. Therefore this function
* is not included in the device driver API. This function should be treated as an
* example code to design the descriptor structures in ring mode or chain mode.
* This function depends on the pcidev structure for allocation of consistent dma-able memory in
* case of linux.
* This limitation is due to the fact that linux uses pci structure to allocate a dmable memory
* - Allocates the memory for the descriptors.
* - Initialize the Busy and Next descriptors indices to 0(Indicating first descriptor).
* - Initialize the Busy and Next descriptors to first descriptor address.
* - Initialize the last descriptor with the endof ring in case of ring mode.
* - Initialize the descriptors in chain mode.
* @param[in] pointer to synopGMACdevice.
* @param[in] pointer to pci_device structure.
* @param[in] number of descriptor expected in rx descriptor queue.
* @param[in] whether descriptors to be created in RING mode or CHAIN mode.
* \return 0 upon success. Error code upon failure.
* \note This function fails if allocation fails for required number of descriptors in Ring mode,
* but in chain mode
* function returns -ESYNOPGMACNOMEM in the process of descriptor chain creation. once returned from
* this function
* user should for gmacdev->RxDescCount to see how many descriptors are there in the chain. Should
* continue further
* only if the number of descriptors in the chain meets the requirements
*/
s32 synopGMAC_setup_rx_desc_queue(synopGMACdevice *gmacdev, u32 no_of_desc, u32 desc_mode)
{
s32 i;
DmaDesc *bf1;
DmaDesc *first_desc = NULL;
dma_addr_t dma_addr;
gmacdev->RxDescCount = 0;
first_desc = (DmaDesc *)plat_alloc_consistent_dmaable_memory(gmacdev, sizeof(DmaDesc) * no_of_desc, &dma_addr);
if (first_desc == NULL)
{
rt_kprintf("Error in Rx Descriptor Memory allocation in Ring mode\n");
return -ESYNOPGMACNOMEM;
}
DEBUG_MES("rx_first_desc_addr = %p\n", first_desc);
DEBUG_MES("dmaadr = %p\n", dma_addr);
gmacdev->RxDescCount = no_of_desc;
gmacdev->RxDesc = (DmaDesc *)first_desc;
gmacdev->RxDescDma = dma_addr;
for (i = 0; i < gmacdev->RxDescCount; i++)
{
synopGMAC_rx_desc_init_ring(gmacdev->RxDesc + i, i == gmacdev->RxDescCount - 1);
}
gmacdev->RxNext = 0;
gmacdev->RxBusy = 0;
gmacdev->RxNextDesc = gmacdev->RxDesc;
gmacdev->RxBusyDesc = gmacdev->RxDesc;
gmacdev->BusyRxDesc = 0;
return -ESYNOPGMACNOERR;
}
void synopGMAC_linux_cable_unplug_function(void *adaptr)
{
s32 data;
synopGMACPciNetworkAdapter *adapter = (synopGMACPciNetworkAdapter *)adaptr;
synopGMACdevice *gmacdev = adapter->synopGMACdev;
struct ethtool_cmd cmd;
//rt_kprintf("%s\n",__FUNCTION__);
if (!mii_link_ok(&adapter->mii))
{
if (gmacdev->LinkState)
rt_kprintf("\r\nNo Link\r\n");
gmacdev->DuplexMode = 0;
gmacdev->Speed = 0;
gmacdev->LoopBackMode = 0;
gmacdev->LinkState = 0;
}
else
{
data = synopGMAC_check_phy_init(adapter);
if (gmacdev->LinkState != data)
{
gmacdev->LinkState = data;
synopGMAC_mac_init(gmacdev);
rt_kprintf("Link is up in %s mode\n", (gmacdev->DuplexMode == FULLDUPLEX) ? "FULL DUPLEX" : "HALF DUPLEX");
if (gmacdev->Speed == SPEED1000)
rt_kprintf("Link is with 1000M Speed \r\n");
if (gmacdev->Speed == SPEED100)
rt_kprintf("Link is with 100M Speed \n");
if (gmacdev->Speed == SPEED10)
rt_kprintf("Link is with 10M Speed \n");
}
}
}
s32 synopGMAC_check_phy_init(synopGMACPciNetworkAdapter *adapter)
{
struct ethtool_cmd cmd;
synopGMACdevice *gmacdev = adapter->synopGMACdev;
if (!mii_link_ok(&adapter->mii))
{
gmacdev->DuplexMode = FULLDUPLEX;
gmacdev->Speed = SPEED100;
return 0;
}
else
{
mii_ethtool_gset(&adapter->mii, &cmd);
gmacdev->DuplexMode = (cmd.duplex == DUPLEX_FULL) ? FULLDUPLEX : HALFDUPLEX ;
if (cmd.speed == SPEED_1000)
gmacdev->Speed = SPEED1000;
else if (cmd.speed == SPEED_100)
gmacdev->Speed = SPEED100;
else
gmacdev->Speed = SPEED10;
}
return gmacdev->Speed | (gmacdev->DuplexMode << 4);
}
static int Mac_change_check(u8 *macaddr0, u8 *macaddr1)
{
int i;
for (i = 0; i < 6; i++)
{
if (macaddr0[i] != macaddr1[i])
return 1;
}
return 0;
}
static rt_err_t eth_init(rt_device_t device)
{
struct eth_device *eth_device = (struct eth_device *)device;
RT_ASSERT(eth_device != RT_NULL);
s32 ijk;
s32 status = 0;
u64 dma_addr;
u32 Mac_changed = 0;
struct pbuf *pbuf;
u8 macaddr[6] = DEFAULT_MAC_ADDRESS;
struct rt_eth_dev *dev = &eth_dev;
struct synopGMACNetworkAdapter *adapter = dev->priv;
synopGMACdevice *gmacdev = (synopGMACdevice *)adapter->synopGMACdev;
synopGMAC_reset(gmacdev);
synopGMAC_attach(gmacdev, (regbase + MACBASE), (regbase + DMABASE), DEFAULT_PHY_BASE, macaddr);
synopGMAC_read_version(gmacdev);
synopGMAC_set_mdc_clk_div(gmacdev, GmiiCsrClk3);
gmacdev->ClockDivMdc = synopGMAC_get_mdc_clk_div(gmacdev);
init_phy(adapter->synopGMACdev);
DEBUG_MES("tx desc_queue\n");
synopGMAC_setup_tx_desc_queue(gmacdev, TRANSMIT_DESC_SIZE, RINGMODE);
synopGMAC_init_tx_desc_base(gmacdev);
DEBUG_MES("rx desc_queue\n");
synopGMAC_setup_rx_desc_queue(gmacdev, RECEIVE_DESC_SIZE, RINGMODE);
synopGMAC_init_rx_desc_base(gmacdev);
DEBUG_MES("DmaRxBaseAddr = %08x\n", synopGMACReadReg(gmacdev->DmaBase, DmaRxBaseAddr));
// u32 dmaRx_Base_addr = synopGMACReadReg(gmacdev->DmaBase,DmaRxBaseAddr);
// rt_kprintf("first_desc_addr = 0x%x\n", dmaRx_Base_addr);
#ifdef ENH_DESC_8W
synopGMAC_dma_bus_mode_init(gmacdev, DmaBurstLength32 | DmaDescriptorSkip2 | DmaDescriptor8Words);
#else
//synopGMAC_dma_bus_mode_init(gmacdev, DmaBurstLength4 | DmaDescriptorSkip1);
synopGMAC_dma_bus_mode_init(gmacdev, DmaBurstLength4 | DmaDescriptorSkip2);
#endif
synopGMAC_dma_control_init(gmacdev, DmaStoreAndForward | DmaTxSecondFrame | DmaRxThreshCtrl128);
status = synopGMAC_check_phy_init(adapter);
synopGMAC_mac_init(gmacdev);
synopGMAC_pause_control(gmacdev);
#ifdef IPC_OFFLOAD
synopGMAC_enable_rx_chksum_offload(gmacdev);
synopGMAC_rx_tcpip_chksum_drop_enable(gmacdev);
#endif
u32 skb;
do
{
skb = (u32)plat_alloc_memory(RX_BUF_SIZE); //should skb aligned here?
if (skb == RT_NULL)
{
rt_kprintf("ERROR in skb buffer allocation\n");
break;
}
dma_addr = plat_dma_map_single(gmacdev, (void *)skb, RX_BUF_SIZE); //获取 skb 的 dma 地址
status = synopGMAC_set_rx_qptr(gmacdev, dma_addr, RX_BUF_SIZE, (u32)skb, 0, 0, 0);
if (status < 0)
{
rt_kprintf("status < 0!!\n");
plat_free_memory((void *)skb);
}
}
while (status >= 0 && (status < (RECEIVE_DESC_SIZE - 1)));
synopGMAC_clear_interrupt(gmacdev);
synopGMAC_disable_mmc_tx_interrupt(gmacdev, 0xFFFFFFFF);
synopGMAC_disable_mmc_rx_interrupt(gmacdev, 0xFFFFFFFF);
synopGMAC_disable_mmc_ipc_rx_interrupt(gmacdev, 0xFFFFFFFF);
// synopGMAC_disable_interrupt_all(gmacdev);
synopGMAC_enable_interrupt(gmacdev, DmaIntEnable);
synopGMAC_enable_dma_rx(gmacdev);
synopGMAC_enable_dma_tx(gmacdev);
plat_delay(DEFAULT_LOOP_VARIABLE);
synopGMAC_check_phy_init(adapter);
synopGMAC_mac_init(gmacdev);
rt_timer_init(&dev->link_timer, "link_timer",
synopGMAC_linux_cable_unplug_function,
(void *)adapter,
RT_TICK_PER_SECOND,
RT_TIMER_FLAG_PERIODIC);
rt_timer_start(&dev->link_timer);
#ifdef RT_USING_GMAC_INT_MODE
/* installl isr */
DEBUG_MES("%s\n", __FUNCTION__);
rt_hw_interrupt_install(LS1C_MAC_IRQ, eth_rx_irq, RT_NULL, "e0_isr");
rt_hw_interrupt_umask(LS1C_MAC_IRQ);
#else
rt_timer_init(&dev->rx_poll_timer, "rx_poll_timer",
eth_rx_irq,
(void *)adapter,
1,
RT_TIMER_FLAG_PERIODIC);
rt_timer_start(&dev->rx_poll_timer);
#endif /*RT_USING_GMAC_INT_MODE*/
rt_kprintf("eth_inited!\n");
return RT_EOK;
}
static rt_err_t eth_open(rt_device_t dev, rt_uint16_t oflag)
{
rt_kprintf("eth_open!!\n");
return RT_EOK;
}
static rt_err_t eth_close(rt_device_t dev)
{
return RT_EOK;
}
static rt_size_t eth_read(rt_device_t dev, rt_off_t pos, void *buffer, rt_size_t size)
{
rt_set_errno(-RT_ENOSYS);
return 0;
}
static rt_size_t eth_write(rt_device_t dev, rt_off_t pos, const void *buffer, rt_size_t size)
{
rt_set_errno(-RT_ENOSYS);
return 0;
}
static rt_err_t eth_control(rt_device_t dev, int cmd, void *args)
{
switch (cmd)
{
case NIOCTL_GADDR:
if (args) rt_memcpy(args, eth_dev.dev_addr, 6);
else return -RT_ERROR;
break;
default :
break;
}
return RT_EOK;
}
rt_err_t rt_eth_tx(rt_device_t device, struct pbuf *p)
{
/* lock eth device */
rt_sem_take(&sem_lock, RT_WAITING_FOREVER);
DEBUG_MES("in %s\n", __FUNCTION__);
s32 status;
u32 pbuf;
u64 dma_addr;
u32 offload_needed = 0;
u32 index;
DmaDesc *dpr;
struct rt_eth_dev *dev = (struct rt_eth_dev *) device;
struct synopGMACNetworkAdapter *adapter;
synopGMACdevice *gmacdev;
adapter = (struct synopGMACNetworkAdapter *) dev->priv;
if (adapter == NULL)
return -1;
gmacdev = (synopGMACdevice *) adapter->synopGMACdev;
if (gmacdev == NULL)
return -1;
if (!synopGMAC_is_desc_owned_by_dma(gmacdev->TxNextDesc))
{
pbuf = (u32)plat_alloc_memory(p->tot_len);
//pbuf = (u32)pbuf_alloc(PBUF_LINK, p->len, PBUF_RAM);
if (pbuf == 0)
{
rt_kprintf("===error in alloc bf1\n");
return -1;
}
DEBUG_MES("p->len = %d\n", p->len);
pbuf_copy_partial(p, (void *)pbuf, p->tot_len, 0);
dma_addr = plat_dma_map_single(gmacdev, (void *)pbuf, p->tot_len);
status = synopGMAC_set_tx_qptr(gmacdev, dma_addr, p->tot_len, pbuf, 0, 0, 0, offload_needed, &index, dpr);
if (status < 0)
{
rt_kprintf("%s No More Free Tx Descriptors\n", __FUNCTION__);
plat_free_memory((void *)pbuf);
return -16;
}
}
synopGMAC_resume_dma_tx(gmacdev);
s32 desc_index;
u32 data1, data2;
u32 dma_addr1, dma_addr2;
u32 length1, length2;
#ifdef ENH_DESC_8W
u32 ext_status;
u16 time_stamp_higher;
u32 time_stamp_high;
u32 time_stamp_low;
#endif
do
{
#ifdef ENH_DESC_8W
desc_index = synopGMAC_get_tx_qptr(gmacdev, &status, &dma_addr1, &length1, &data1, &dma_addr2, &length2, &data2, &ext_status, &time_stamp_high, &time_stamp_low);
synopGMAC_TS_read_timestamp_higher_val(gmacdev, &time_stamp_higher);
#else
desc_index = synopGMAC_get_tx_qptr(gmacdev, &status, &dma_addr1, &length1, &data1, &dma_addr2, &length2, &data2);
#endif
if (desc_index >= 0 && data1 != 0)
{
#ifdef IPC_OFFLOAD
if (synopGMAC_is_tx_ipv4header_checksum_error(gmacdev, status))
{
rt_kprintf("Harware Failed to Insert IPV4 Header Checksum\n");
}
if (synopGMAC_is_tx_payload_checksum_error(gmacdev, status))
{
rt_kprintf("Harware Failed to Insert Payload Checksum\n");
}
#endif
plat_free_memory((void *)(data1)); //sw: data1 = buffer1
if (synopGMAC_is_desc_valid(status))
{
adapter->synopGMACNetStats.tx_bytes += length1;
adapter->synopGMACNetStats.tx_packets++;
}
else
{
adapter->synopGMACNetStats.tx_errors++;
adapter->synopGMACNetStats.tx_aborted_errors += synopGMAC_is_tx_aborted(status);
adapter->synopGMACNetStats.tx_carrier_errors += synopGMAC_is_tx_carrier_error(status);
}
}
adapter->synopGMACNetStats.collisions += synopGMAC_get_tx_collision_count(status);
}
while (desc_index >= 0);
/* unlock eth device */
rt_sem_release(&sem_lock);
// rt_kprintf("output %d bytes\n", p->len);
u32 test_data;
test_data = synopGMACReadReg(gmacdev->DmaBase, DmaStatus);
return RT_EOK;
}
struct pbuf *rt_eth_rx(rt_device_t device)
{
DEBUG_MES("%s : \n", __FUNCTION__);
struct rt_eth_dev *dev = &eth_dev;
struct synopGMACNetworkAdapter *adapter;
synopGMACdevice *gmacdev;
// struct PmonInet * pinetdev;
s32 desc_index;
int i;
char *ptr;
u32 bf1;
u32 data1;
u32 data2;
u32 len;
u32 status;
u32 dma_addr1;
u32 dma_addr2;
struct pbuf *pbuf = RT_NULL;
rt_sem_take(&sem_lock, RT_WAITING_FOREVER);
adapter = (struct synopGMACNetworkAdapter *) dev->priv;
if (adapter == NULL)
{
rt_kprintf("%S : Unknown Device !!\n", __FUNCTION__);
return NULL;
}
gmacdev = (synopGMACdevice *) adapter->synopGMACdev;
if (gmacdev == NULL)
{
rt_kprintf("%s : GMAC device structure is missing\n", __FUNCTION__);
return NULL;
}
/*Handle the Receive Descriptors*/
// do{
desc_index = synopGMAC_get_rx_qptr(gmacdev, &status, &dma_addr1, NULL, &data1, &dma_addr2, NULL, &data2);
if (desc_index >= 0 && data1 != 0)
{
DEBUG_MES("Received Data at Rx Descriptor %d for skb 0x%08x whose status is %08x\n", desc_index, dma_addr1, status);
if (synopGMAC_is_rx_desc_valid(status) || SYNOP_PHY_LOOPBACK)
{
pbuf = pbuf_alloc(PBUF_LINK, MAX_ETHERNET_PAYLOAD, PBUF_RAM);
if (pbuf == 0) rt_kprintf("===error in pbuf_alloc\n");
dma_addr1 = plat_dma_map_single(gmacdev, (void *)data1, RX_BUF_SIZE);
len = synopGMAC_get_rx_desc_frame_length(status); //Not interested in Ethernet CRC bytes
rt_memcpy(pbuf->payload, (char *)data1, len);
DEBUG_MES("==get pkg len: %d\n", len);
}
else
{
rt_kprintf("s: %08x\n", status);
adapter->synopGMACNetStats.rx_errors++;
adapter->synopGMACNetStats.collisions += synopGMAC_is_rx_frame_collision(status);
adapter->synopGMACNetStats.rx_crc_errors += synopGMAC_is_rx_crc(status);
adapter->synopGMACNetStats.rx_frame_errors += synopGMAC_is_frame_dribbling_errors(status);
adapter->synopGMACNetStats.rx_length_errors += synopGMAC_is_rx_frame_length_errors(status);
}
desc_index = synopGMAC_set_rx_qptr(gmacdev, dma_addr1, RX_BUF_SIZE, (u32)data1, 0, 0, 0);
if (desc_index < 0)
{
#if SYNOP_RX_DEBUG
rt_kprintf("Cannot set Rx Descriptor for data1 %08x\n", (u32)data1);
#endif
plat_free_memory((void *)data1);
}
}
// }while(desc_index >= 0);
rt_sem_release(&sem_lock);
DEBUG_MES("%s : before return \n", __FUNCTION__);
return pbuf;
}
static int rtl88e1111_config_init(synopGMACdevice *gmacdev)
{
int retval, err;
u16 data;
DEBUG_MES("in %s\n", __FUNCTION__);
synopGMAC_read_phy_reg(gmacdev->MacBase, gmacdev->PhyBase, 0x14, &data);
data = data | 0x82;
err = synopGMAC_write_phy_reg(gmacdev->MacBase, gmacdev->PhyBase, 0x14, data);
synopGMAC_read_phy_reg(gmacdev->MacBase, gmacdev->PhyBase, 0x00, &data);
data = data | 0x8000;
err = synopGMAC_write_phy_reg(gmacdev->MacBase, gmacdev->PhyBase, 0x00, data);
#if SYNOP_PHY_LOOPBACK
synopGMAC_read_phy_reg(gmacdev->MacBase, gmacdev->PhyBase, 0x14, &data);
data = data | 0x70;
data = data & 0xffdf;
err = synopGMAC_write_phy_reg(gmacdev->MacBase, gmacdev->PhyBase, 0x14, data);
data = 0x8000;
err = synopGMAC_write_phy_reg(gmacdev->MacBase, gmacdev->PhyBase, 0x00, data);
data = 0x5140;
err = synopGMAC_write_phy_reg(gmacdev->MacBase, gmacdev->PhyBase, 0x00, data);
#endif
if (err < 0)
return err;
return 0;
}
int init_phy(synopGMACdevice *gmacdev)
{
u16 data;
synopGMAC_read_phy_reg(gmacdev->MacBase, gmacdev->PhyBase, 2, &data);
/*set 88e1111 clock phase delay*/
if (data == 0x141)
rtl88e1111_config_init(gmacdev);
#if defined (RMII)
else if (data == 0x8201)
{
//RTL8201
data = 0x400; // set RMII mode
synopGMAC_write_phy_reg(gmacdev->MacBase, gmacdev->PhyBase, 0x19, data);
synopGMAC_read_phy_reg(gmacdev->MacBase, gmacdev->PhyBase, 0x19, &data);
TR("phy reg25 is %0x \n", data);
data = 0x3100; //set 100M speed
synopGMAC_write_phy_reg(gmacdev->MacBase, gmacdev->PhyBase, 0x0, data);
}
else if (data == 0x0180 || data == 0x0181)
{
//DM9161
synopGMAC_read_phy_reg(gmacdev->MacBase, gmacdev->PhyBase, 0x10, &data);
data |= (1 << 8); //set RMII mode
synopGMAC_write_phy_reg(gmacdev->MacBase, gmacdev->PhyBase, 0x10, data); //set RMII mode
synopGMAC_read_phy_reg(gmacdev->MacBase, gmacdev->PhyBase, 0x10, &data);
TR("phy reg16 is 0x%0x \n", data);
// synopGMAC_read_phy_reg(gmacdev->MacBase,gmacdev->PhyBase,0x0,&data);
// data &= ~(1<<10);
data = 0x3100; //set auto-
//data = 0x0100; //set 10M speed
synopGMAC_write_phy_reg(gmacdev->MacBase, gmacdev->PhyBase, 0x0, data);
}
#endif
return 0;
}
u32 synopGMAC_wakeup_filter_config3[] =
{
0x00000000,
0x000000FF,
0x00000000,
0x00000000,
0x00000100,
0x00003200,
0x7eED0000,
0x00000000
};
static void synopGMAC_linux_powerdown_mac(synopGMACdevice *gmacdev)
{
rt_kprintf("Put the GMAC to power down mode..\n");
GMAC_Power_down = 1;
synopGMAC_disable_dma_tx(gmacdev);
plat_delay(10000);
synopGMAC_tx_disable(gmacdev);
synopGMAC_rx_disable(gmacdev);
plat_delay(10000);
synopGMAC_disable_dma_rx(gmacdev);
synopGMAC_magic_packet_enable(gmacdev);
synopGMAC_write_wakeup_frame_register(gmacdev, synopGMAC_wakeup_filter_config3);
synopGMAC_wakeup_frame_enable(gmacdev);
synopGMAC_rx_enable(gmacdev);
synopGMAC_pmt_int_enable(gmacdev);
synopGMAC_power_down_enable(gmacdev);
return;
}
static void synopGMAC_linux_powerup_mac(synopGMACdevice *gmacdev)
{
GMAC_Power_down = 0;
if (synopGMAC_is_magic_packet_received(gmacdev))
rt_kprintf("GMAC wokeup due to Magic Pkt Received\n");
if (synopGMAC_is_wakeup_frame_received(gmacdev))
rt_kprintf("GMAC wokeup due to Wakeup Frame Received\n");
synopGMAC_pmt_int_disable(gmacdev);
synopGMAC_rx_enable(gmacdev);
synopGMAC_enable_dma_rx(gmacdev);
synopGMAC_tx_enable(gmacdev);
synopGMAC_enable_dma_tx(gmacdev);
return;
}
static int mdio_read(synopGMACPciNetworkAdapter *adapter, int addr, int reg)
{
synopGMACdevice *gmacdev;
u16 data;
gmacdev = adapter->synopGMACdev;
synopGMAC_read_phy_reg(gmacdev->MacBase, addr, reg, &data);
return data;
}
static void mdio_write(synopGMACPciNetworkAdapter *adapter, int addr, int reg, int data)
{
synopGMACdevice *gmacdev;
gmacdev = adapter->synopGMACdev;
synopGMAC_write_phy_reg(gmacdev->MacBase, addr, reg, data);
}
void eth_rx_irq(int irqno, void *param)
{
struct rt_eth_dev *dev = &eth_dev;
struct synopGMACNetworkAdapter *adapter = dev->priv;
//DEBUG_MES("in irq!!\n");
#ifdef RT_USING_GMAC_INT_MODE
int i ;
for (i = 0; i < 7200; i++)
;
#endif /*RT_USING_GMAC_INT_MODE*/
synopGMACdevice *gmacdev = (synopGMACdevice *)adapter->synopGMACdev;
u32 interrupt, dma_status_reg;
s32 status;
u32 dma_addr;
//rt_kprintf("irq i = %d\n", i++);
dma_status_reg = synopGMACReadReg(gmacdev->DmaBase, DmaStatus);
if (dma_status_reg == 0)
{
rt_kprintf("dma_status ==0 \n");
return;
}
//rt_kprintf("dma_status_reg is 0x%x\n", dma_status_reg);
u32 gmacstatus;
synopGMAC_disable_interrupt_all(gmacdev);
gmacstatus = synopGMACReadReg(gmacdev->MacBase, GmacStatus);
if (dma_status_reg & GmacPmtIntr)
{
rt_kprintf("%s:: Interrupt due to PMT module\n", __FUNCTION__);
//synopGMAC_linux_powerup_mac(gmacdev);
}
if (dma_status_reg & GmacMmcIntr)
{
rt_kprintf("%s:: Interrupt due to MMC module\n", __FUNCTION__);
DEBUG_MES("%s:: synopGMAC_rx_int_status = %08x\n", __FUNCTION__, synopGMAC_read_mmc_rx_int_status(gmacdev));
DEBUG_MES("%s:: synopGMAC_tx_int_status = %08x\n", __FUNCTION__, synopGMAC_read_mmc_tx_int_status(gmacdev));
}
if (dma_status_reg & GmacLineIntfIntr)
{
rt_kprintf("%s:: Interrupt due to GMAC LINE module\n", __FUNCTION__);
}
interrupt = synopGMAC_get_interrupt_type(gmacdev);
//rt_kprintf("%s:Interrupts to be handled: 0x%08x\n",__FUNCTION__,interrupt);
if (interrupt & synopGMACDmaError)
{
u8 mac_addr0[6];
rt_kprintf("%s::Fatal Bus Error Inetrrupt Seen\n", __FUNCTION__);
memcpy(mac_addr0, dev->dev_addr, 6);
synopGMAC_disable_dma_tx(gmacdev);
synopGMAC_disable_dma_rx(gmacdev);
synopGMAC_take_desc_ownership_tx(gmacdev);
synopGMAC_take_desc_ownership_rx(gmacdev);
synopGMAC_init_tx_rx_desc_queue(gmacdev);
synopGMAC_reset(gmacdev);
synopGMAC_set_mac_addr(gmacdev, GmacAddr0High, GmacAddr0Low, mac_addr0);
synopGMAC_dma_bus_mode_init(gmacdev, DmaFixedBurstEnable | DmaBurstLength8 | DmaDescriptorSkip2);
synopGMAC_dma_control_init(gmacdev, DmaStoreAndForward);
synopGMAC_init_rx_desc_base(gmacdev);
synopGMAC_init_tx_desc_base(gmacdev);
synopGMAC_mac_init(gmacdev);
synopGMAC_enable_dma_rx(gmacdev);
synopGMAC_enable_dma_tx(gmacdev);
}
if (interrupt & synopGMACDmaRxNormal)
{
//DEBUG_MES("%s:: Rx Normal \n", __FUNCTION__);
//synop_handle_received_data(netdev);
eth_device_ready(&eth_dev.parent);
}
if (interrupt & synopGMACDmaRxAbnormal)
{
//rt_kprintf("%s::Abnormal Rx Interrupt Seen\n",__FUNCTION__);
if (GMAC_Power_down == 0)
{
adapter->synopGMACNetStats.rx_over_errors++;
synopGMACWriteReg(gmacdev->DmaBase, DmaStatus, 0x80);
synopGMAC_resume_dma_rx(gmacdev);
}
}
if (interrupt & synopGMACDmaRxStopped)
{
rt_kprintf("%s::Receiver stopped seeing Rx interrupts\n", __FUNCTION__); //Receiver gone in to stopped state
}
if (interrupt & synopGMACDmaTxNormal)
{
DEBUG_MES("%s::Finished Normal Transmission \n", __FUNCTION__);
// synop_handle_transmit_over(netdev);
}
if (interrupt & synopGMACDmaTxAbnormal)
{
rt_kprintf("%s::Abnormal Tx Interrupt Seen\n", __FUNCTION__);
}
if (interrupt & synopGMACDmaTxStopped)
{
TR("%s::Transmitter stopped sending the packets\n", __FUNCTION__);
if (GMAC_Power_down == 0) // If Mac is not in powerdown
{
synopGMAC_disable_dma_tx(gmacdev);
synopGMAC_take_desc_ownership_tx(gmacdev);
synopGMAC_enable_dma_tx(gmacdev);
// netif_wake_queue(netdev);
TR("%s::Transmission Resumed\n", __FUNCTION__);
}
}
/* Enable the interrrupt before returning from ISR*/
synopGMAC_enable_interrupt(gmacdev, DmaIntEnable);
return;
}
int rt_hw_eth_init(void)
{
u64 base_addr = Gmac_base;
struct synopGMACNetworkAdapter *synopGMACadapter;
static u8 mac_addr0[6] = DEFAULT_MAC_ADDRESS;
int index;
rt_sem_init(&sem_ack, "tx_ack", 1, RT_IPC_FLAG_FIFO);
rt_sem_init(&sem_lock, "eth_lock", 1, RT_IPC_FLAG_FIFO);
for (index = 21; index <= 30; index++)
{
pin_set_purpose(index, PIN_PURPOSE_OTHER);
pin_set_remap(index, PIN_REMAP_DEFAULT);
}
pin_set_purpose(35, PIN_PURPOSE_OTHER);
pin_set_remap(35, PIN_REMAP_DEFAULT);
*((volatile unsigned int *)0xbfd00424) &= ~(7 << 28);
*((volatile unsigned int *)0xbfd00424) |= (1 << 30); //wl rmii
memset(&eth_dev, 0, sizeof(eth_dev));
synopGMACadapter = (struct synopGMACNetworkAdapter *)plat_alloc_memory(sizeof(struct synopGMACNetworkAdapter));
if (!synopGMACadapter)
{
rt_kprintf("Error in Memory Allocataion, Founction : %s \n", __FUNCTION__);
}
memset((char *)synopGMACadapter, 0, sizeof(struct synopGMACNetworkAdapter));
synopGMACadapter->synopGMACdev = NULL;
synopGMACadapter->synopGMACdev = (synopGMACdevice *) plat_alloc_memory(sizeof(synopGMACdevice));
if (!synopGMACadapter->synopGMACdev)
{
rt_kprintf("Error in Memory Allocataion, Founction : %s \n", __FUNCTION__);
}
memset((char *)synopGMACadapter->synopGMACdev, 0, sizeof(synopGMACdevice));
/*
* Attach the device to MAC struct This will configure all the required base addresses
* such as Mac base, configuration base, phy base address(out of 32 possible phys)
* */
synopGMAC_attach(synopGMACadapter->synopGMACdev, (regbase + MACBASE), regbase + DMABASE, DEFAULT_PHY_BASE, mac_addr0);
init_phy(synopGMACadapter->synopGMACdev);
synopGMAC_reset(synopGMACadapter->synopGMACdev);
/* MII setup */
synopGMACadapter->mii.phy_id_mask = 0x1F;
synopGMACadapter->mii.reg_num_mask = 0x1F;
synopGMACadapter->mii.dev = synopGMACadapter;
synopGMACadapter->mii.mdio_read = mdio_read;
synopGMACadapter->mii.mdio_write = mdio_write;
synopGMACadapter->mii.phy_id = synopGMACadapter->synopGMACdev->PhyBase;
synopGMACadapter->mii.supports_gmii = mii_check_gmii_support(&synopGMACadapter->mii);
eth_dev.iobase = base_addr;
eth_dev.name = "e0";
eth_dev.priv = synopGMACadapter;
eth_dev.dev_addr[0] = mac_addr0[0];
eth_dev.dev_addr[1] = mac_addr0[1];
eth_dev.dev_addr[2] = mac_addr0[2];
eth_dev.dev_addr[3] = mac_addr0[3];
eth_dev.dev_addr[4] = mac_addr0[4];
eth_dev.dev_addr[5] = mac_addr0[5];
eth_dev.parent.parent.type = RT_Device_Class_NetIf;
eth_dev.parent.parent.init = eth_init;
eth_dev.parent.parent.open = eth_open;
eth_dev.parent.parent.close = eth_close;
eth_dev.parent.parent.read = eth_read;
eth_dev.parent.parent.write = eth_write;
eth_dev.parent.parent.control = eth_control;
eth_dev.parent.parent.user_data = RT_NULL;
eth_dev.parent.eth_tx = rt_eth_tx;
eth_dev.parent.eth_rx = rt_eth_rx;
eth_device_init(&(eth_dev.parent), "e0");
return 0;
}
INIT_DEVICE_EXPORT(rt_hw_eth_init);