drivers/net/dc2114x.c

// SPDX-License-Identifier: GPL-2.0+

#include <common.h>
#include <asm/io.h>
#include <env.h>
#include <malloc.h>
#include <net.h>
#include <netdev.h>
#include <pci.h>
#include <linux/bitops.h>
#include <linux/delay.h>

#define SROM_DLEVEL	0

/* PCI Registers. */
#define PCI_CFDA_PSM	0x43

#define CFRV_RN		0x000000f0	/* Revision Number */

#define WAKEUP		0x00		/* Power Saving Wakeup */
#define SLEEP		0x80		/* Power Saving Sleep Mode */

#define DC2114x_BRK	0x0020	/* CFRV break between DC21142 & DC21143 */

/* Ethernet chip registers. */
#define DE4X5_BMR	0x000		/* Bus Mode Register */
#define DE4X5_TPD	0x008		/* Transmit Poll Demand Reg */
#define DE4X5_RRBA	0x018		/* RX Ring Base Address Reg */
#define DE4X5_TRBA	0x020		/* TX Ring Base Address Reg */
#define DE4X5_STS	0x028		/* Status Register */
#define DE4X5_OMR	0x030		/* Operation Mode Register */
#define DE4X5_SICR	0x068		/* SIA Connectivity Register */
#define DE4X5_APROM	0x048		/* Ethernet Address PROM */

/* Register bits. */
#define BMR_SWR		0x00000001	/* Software Reset */
#define STS_TS		0x00700000	/* Transmit Process State */
#define STS_RS		0x000e0000	/* Receive Process State */
#define OMR_ST		0x00002000	/* Start/Stop Transmission Command */
#define OMR_SR		0x00000002	/* Start/Stop Receive */
#define OMR_PS		0x00040000	/* Port Select */
#define OMR_SDP		0x02000000	/* SD Polarity - MUST BE ASSERTED */
#define OMR_PM		0x00000080	/* Pass All Multicast */

/* Descriptor bits. */
#define R_OWN		0x80000000	/* Own Bit */
#define RD_RER		0x02000000	/* Receive End Of Ring */
#define RD_LS		0x00000100	/* Last Descriptor */
#define RD_ES		0x00008000	/* Error Summary */
#define TD_TER		0x02000000	/* Transmit End Of Ring */
#define T_OWN		0x80000000	/* Own Bit */
#define TD_LS		0x40000000	/* Last Segment */
#define TD_FS		0x20000000	/* First Segment */
#define TD_ES		0x00008000	/* Error Summary */
#define TD_SET		0x08000000	/* Setup Packet */

/* The EEPROM commands include the alway-set leading bit. */
#define SROM_WRITE_CMD	5
#define SROM_READ_CMD	6
#define SROM_ERASE_CMD	7

#define SROM_HWADD	0x0014		/* Hardware Address offset in SROM */
#define SROM_RD		0x00004000	/* Read from Boot ROM */
#define EE_DATA_WRITE	0x04		/* EEPROM chip data in. */
#define EE_WRITE_0	0x4801
#define EE_WRITE_1	0x4805
#define EE_DATA_READ	0x08		/* EEPROM chip data out. */
#define SROM_SR		0x00000800	/* Select Serial ROM when set */

#define DT_IN		0x00000004	/* Serial Data In */
#define DT_CLK		0x00000002	/* Serial ROM Clock */
#define DT_CS		0x00000001	/* Serial ROM Chip Select */

#define POLL_DEMAND	1

#if defined(CONFIG_E500)
#define phys_to_bus(a) (a)
#else
#define phys_to_bus(a)	pci_phys_to_mem((pci_dev_t)dev->priv, a)
#endif

#define NUM_RX_DESC PKTBUFSRX
#define NUM_TX_DESC 1			/* Number of TX descriptors   */
#define RX_BUFF_SZ  PKTSIZE_ALIGN

#define TOUT_LOOP   1000000

#define SETUP_FRAME_LEN 192

struct de4x5_desc {
	volatile s32 status;
	u32 des1;
	u32 buf;
	u32 next;
};

struct dc2114x_priv {
	struct eth_device	dev;
	char			*name;
	void __iomem		*iobase;
	u8			*enetaddr;
};

/* RX and TX descriptor ring */
static struct de4x5_desc rx_ring[NUM_RX_DESC] __aligned(32);
static struct de4x5_desc tx_ring[NUM_TX_DESC] __aligned(32);
static int rx_new;	/* RX descriptor ring pointer */
static int tx_new;	/* TX descriptor ring pointer */

static char rx_ring_size;
static char tx_ring_size;

static u32 dc2114x_inl(struct eth_device *dev, u32 addr)
{
	return le32_to_cpu(readl(dev->iobase + addr));
}

static void dc2114x_outl(struct eth_device *dev, u32 command, u32 addr)
{
	writel(cpu_to_le32(command), dev->iobase + addr);
}

static void reset_de4x5(struct eth_device *dev)
{
	u32 i;

	i = dc2114x_inl(dev, DE4X5_BMR);
	mdelay(1);
	dc2114x_outl(dev, i | BMR_SWR, DE4X5_BMR);
	mdelay(1);
	dc2114x_outl(dev, i, DE4X5_BMR);
	mdelay(1);

	for (i = 0; i < 5; i++) {
		dc2114x_inl(dev, DE4X5_BMR);
		mdelay(10);
	}

	mdelay(1);
}

static void start_de4x5(struct eth_device *dev)
{
	u32 omr;

	omr = dc2114x_inl(dev, DE4X5_OMR);
	omr |= OMR_ST | OMR_SR;
	dc2114x_outl(dev, omr, DE4X5_OMR);	/* Enable the TX and/or RX */
}

static void stop_de4x5(struct eth_device *dev)
{
	u32 omr;

	omr = dc2114x_inl(dev, DE4X5_OMR);
	omr &= ~(OMR_ST | OMR_SR);
	dc2114x_outl(dev, omr, DE4X5_OMR);	/* Disable the TX and/or RX */
}

/* SROM Read and write routines. */
static void sendto_srom(struct eth_device *dev, u_int command, u_long addr)
{
	dc2114x_outl(dev, command, addr);
	udelay(1);
}

static int getfrom_srom(struct eth_device *dev, u_long addr)
{
	u32 tmp = dc2114x_inl(dev, addr);

	udelay(1);
	return tmp;
}

/* Note: this routine returns extra data bits for size detection. */
static int do_read_eeprom(struct eth_device *dev, u_long ioaddr, int location,
			  int addr_len)
{
	int read_cmd = location | (SROM_READ_CMD << addr_len);
	unsigned int retval = 0;
	int i;

	sendto_srom(dev, SROM_RD | SROM_SR, ioaddr);
	sendto_srom(dev, SROM_RD | SROM_SR | DT_CS, ioaddr);

	debug_cond(SROM_DLEVEL >= 1, " EEPROM read at %d ", location);

	/* Shift the read command bits out. */
	for (i = 4 + addr_len; i >= 0; i--) {
		short dataval = (read_cmd & (1 << i)) ? EE_DATA_WRITE : 0;

		sendto_srom(dev, SROM_RD | SROM_SR | DT_CS | dataval,
			    ioaddr);
		udelay(10);
		sendto_srom(dev, SROM_RD | SROM_SR | DT_CS | dataval | DT_CLK,
			    ioaddr);
		udelay(10);
		debug_cond(SROM_DLEVEL >= 2, "%X",
			   getfrom_srom(dev, ioaddr) & 15);
		retval = (retval << 1) |
			 !!(getfrom_srom(dev, ioaddr) & EE_DATA_READ);
	}

	sendto_srom(dev, SROM_RD | SROM_SR | DT_CS, ioaddr);

	debug_cond(SROM_DLEVEL >= 2, " :%X:", getfrom_srom(dev, ioaddr) & 15);

	for (i = 16; i > 0; i--) {
		sendto_srom(dev, SROM_RD | SROM_SR | DT_CS | DT_CLK, ioaddr);
		udelay(10);
		debug_cond(SROM_DLEVEL >= 2, "%X",
			   getfrom_srom(dev, ioaddr) & 15);
		retval = (retval << 1) |
			 !!(getfrom_srom(dev, ioaddr) & EE_DATA_READ);
		sendto_srom(dev, SROM_RD | SROM_SR | DT_CS, ioaddr);
		udelay(10);
	}

	/* Terminate the EEPROM access. */
	sendto_srom(dev, SROM_RD | SROM_SR, ioaddr);

	debug_cond(SROM_DLEVEL >= 2, " EEPROM value at %d is %5.5x.\n",
		   location, retval);

	return retval;
}

/*
 * This executes a generic EEPROM command, typically a write or write
 * enable. It returns the data output from the EEPROM, and thus may
 * also be used for reads.
 */
static int do_eeprom_cmd(struct eth_device *dev, u_long ioaddr, int cmd,
			 int cmd_len)
{
	unsigned int retval = 0;

	debug_cond(SROM_DLEVEL >= 1, " EEPROM op 0x%x: ", cmd);

	sendto_srom(dev, SROM_RD | SROM_SR | DT_CS | DT_CLK, ioaddr);

	/* Shift the command bits out. */
	do {
		short dataval = (cmd & BIT(cmd_len)) ? EE_WRITE_1 : EE_WRITE_0;

		sendto_srom(dev, dataval, ioaddr);
		udelay(10);

		debug_cond(SROM_DLEVEL >= 2, "%X",
			   getfrom_srom(dev, ioaddr) & 15);

		sendto_srom(dev, dataval | DT_CLK, ioaddr);
		udelay(10);
		retval = (retval << 1) |
			 !!(getfrom_srom(dev, ioaddr) & EE_DATA_READ);
	} while (--cmd_len >= 0);

	sendto_srom(dev, SROM_RD | SROM_SR | DT_CS, ioaddr);

	/* Terminate the EEPROM access. */
	sendto_srom(dev, SROM_RD | SROM_SR, ioaddr);

	debug_cond(SROM_DLEVEL >= 1, " EEPROM result is 0x%5.5x.\n", retval);

	return retval;
}

static int read_srom(struct eth_device *dev, u_long ioaddr, int index)
{
	int ee_addr_size;

	ee_addr_size = (do_read_eeprom(dev, ioaddr, 0xff, 8) & BIT(18)) ? 8 : 6;

	return do_eeprom_cmd(dev, ioaddr, 0xffff |
			     (((SROM_READ_CMD << ee_addr_size) | index) << 16),
			     3 + ee_addr_size + 16);
}

static void send_setup_frame(struct eth_device *dev, struct bd_info *bis)
{
	char setup_frame[SETUP_FRAME_LEN];
	char *pa = &setup_frame[0];
	int i;

	memset(pa, 0xff, SETUP_FRAME_LEN);

	for (i = 0; i < ETH_ALEN; i++) {
		*(pa + (i & 1)) = dev->enetaddr[i];
		if (i & 0x01)
			pa += 4;
	}

	for (i = 0; tx_ring[tx_new].status & cpu_to_le32(T_OWN); i++) {
		if (i < TOUT_LOOP)
			continue;

		printf("%s: tx error buffer not ready\n", dev->name);
		return;
	}

	tx_ring[tx_new].buf = cpu_to_le32(phys_to_bus((u32)&setup_frame[0]));
	tx_ring[tx_new].des1 = cpu_to_le32(TD_TER | TD_SET | SETUP_FRAME_LEN);
	tx_ring[tx_new].status = cpu_to_le32(T_OWN);

	dc2114x_outl(dev, POLL_DEMAND, DE4X5_TPD);

	for (i = 0; tx_ring[tx_new].status & cpu_to_le32(T_OWN); i++) {
		if (i < TOUT_LOOP)
			continue;

		printf("%s: tx buffer not ready\n", dev->name);
		return;
	}

	if (le32_to_cpu(tx_ring[tx_new].status) != 0x7FFFFFFF) {
		printf("TX error status2 = 0x%08X\n",
		       le32_to_cpu(tx_ring[tx_new].status));
	}

	tx_new = (tx_new + 1) % NUM_TX_DESC;
}

static int dc21x4x_send(struct eth_device *dev, void *packet, int length)
{
	int status = -1;
	int i;

	if (length <= 0) {
		printf("%s: bad packet size: %d\n", dev->name, length);
		goto done;
	}

	for (i = 0; tx_ring[tx_new].status & cpu_to_le32(T_OWN); i++) {
		if (i < TOUT_LOOP)
			continue;

		printf("%s: tx error buffer not ready\n", dev->name);
		goto done;
	}

	tx_ring[tx_new].buf = cpu_to_le32(phys_to_bus((u32)packet));
	tx_ring[tx_new].des1 = cpu_to_le32(TD_TER | TD_LS | TD_FS | length);
	tx_ring[tx_new].status = cpu_to_le32(T_OWN);

	dc2114x_outl(dev, POLL_DEMAND, DE4X5_TPD);

	for (i = 0; tx_ring[tx_new].status & cpu_to_le32(T_OWN); i++) {
		if (i < TOUT_LOOP)
			continue;

		printf(".%s: tx buffer not ready\n", dev->name);
		goto done;
	}

	if (le32_to_cpu(tx_ring[tx_new].status) & TD_ES) {
		tx_ring[tx_new].status = 0x0;
		goto done;
	}

	status = length;

done:
	tx_new = (tx_new + 1) % NUM_TX_DESC;
	return status;
}

static int dc21x4x_recv(struct eth_device *dev)
{
	int length = 0;
	u32 status;

	while (true) {
		status = le32_to_cpu(rx_ring[rx_new].status);

		if (status & R_OWN)
			break;

		if (status & RD_LS) {
			/* Valid frame status. */
			if (status & RD_ES) {
				/* There was an error. */
				printf("RX error status = 0x%08X\n", status);
			} else {
				/* A valid frame received. */
				length = (le32_to_cpu(rx_ring[rx_new].status)
					  >> 16);

				/* Pass the packet up to the protocol layers */
				net_process_received_packet
					(net_rx_packets[rx_new], length - 4);
			}

			/*
			 * Change buffer ownership for this frame,
			 * back to the adapter.
			 */
			rx_ring[rx_new].status = cpu_to_le32(R_OWN);
		}

		/* Update entry information. */
		rx_new = (rx_new + 1) % rx_ring_size;
	}

	return length;
}

static int dc21x4x_init(struct eth_device *dev, struct bd_info *bis)
{
	int i;
	int devbusfn = (int)dev->priv;

	/* Ensure we're not sleeping. */
	pci_write_config_byte(devbusfn, PCI_CFDA_PSM, WAKEUP);

	reset_de4x5(dev);

	if (dc2114x_inl(dev, DE4X5_STS) & (STS_TS | STS_RS)) {
		printf("Error: Cannot reset ethernet controller.\n");
		return -1;
	}

	dc2114x_outl(dev, OMR_SDP | OMR_PS | OMR_PM, DE4X5_OMR);

	for (i = 0; i < NUM_RX_DESC; i++) {
		rx_ring[i].status = cpu_to_le32(R_OWN);
		rx_ring[i].des1 = cpu_to_le32(RX_BUFF_SZ);
		rx_ring[i].buf =
			cpu_to_le32(phys_to_bus((u32)net_rx_packets[i]));
		rx_ring[i].next = 0;
	}

	for (i = 0; i < NUM_TX_DESC; i++) {
		tx_ring[i].status = 0;
		tx_ring[i].des1 = 0;
		tx_ring[i].buf = 0;
		tx_ring[i].next = 0;
	}

	rx_ring_size = NUM_RX_DESC;
	tx_ring_size = NUM_TX_DESC;

	/* Write the end of list marker to the descriptor lists. */
	rx_ring[rx_ring_size - 1].des1 |= cpu_to_le32(RD_RER);
	tx_ring[tx_ring_size - 1].des1 |= cpu_to_le32(TD_TER);

	/* Tell the adapter where the TX/RX rings are located. */
	dc2114x_outl(dev, phys_to_bus((u32)&rx_ring), DE4X5_RRBA);
	dc2114x_outl(dev, phys_to_bus((u32)&tx_ring), DE4X5_TRBA);

	start_de4x5(dev);

	tx_new = 0;
	rx_new = 0;

	send_setup_frame(dev, bis);

	return 0;
}

static void dc21x4x_halt(struct eth_device *dev)
{
	int devbusfn = (int)dev->priv;

	stop_de4x5(dev);
	dc2114x_outl(dev, 0, DE4X5_SICR);

	pci_write_config_byte(devbusfn, PCI_CFDA_PSM, SLEEP);
}

static void read_hw_addr(struct dc2114x_priv *priv)
{
	u_short tmp, *p = (u_short *)(&priv->enetaddr[0]);
	int i, j = 0;

	for (i = 0; i < (ETH_ALEN >> 1); i++) {
		tmp = read_srom(dev, DE4X5_APROM, (SROM_HWADD >> 1) + i);
		*p = le16_to_cpu(tmp);
		j += *p++;
	}

	if (!j || j == 0x2fffd) {
		memset(priv->enetaddr, 0, ETH_ALEN);
		debug("Warning: can't read HW address from SROM.\n");
	}
}

static struct pci_device_id supported[] = {
	{ PCI_DEVICE(PCI_VENDOR_ID_DEC, PCI_DEVICE_ID_DEC_TULIP_FAST) },
	{ PCI_DEVICE(PCI_VENDOR_ID_DEC, PCI_DEVICE_ID_DEC_21142) },
	{ }
};

int dc21x4x_initialize(struct bd_info *bis)
{
	struct dc2114x_priv *priv;
	struct eth_device *dev;
	unsigned short status;
	unsigned char timer;
	unsigned int iobase;
	int card_number = 0;
	pci_dev_t devbusfn;
	int idx = 0;

	while (1) {
		devbusfn = pci_find_devices(supported, idx++);
		if (devbusfn == -1)
			break;

		pci_read_config_word(devbusfn, PCI_COMMAND, &status);
		status |= PCI_COMMAND_MEMORY | PCI_COMMAND_MASTER;
		pci_write_config_word(devbusfn, PCI_COMMAND, status);

		pci_read_config_word(devbusfn, PCI_COMMAND, &status);
		if (!(status & PCI_COMMAND_MEMORY)) {
			printf("Error: Can not enable MEMORY access.\n");
			continue;
		}

		if (!(status & PCI_COMMAND_MASTER)) {
			printf("Error: Can not enable Bus Mastering.\n");
			continue;
		}

		/* Check the latency timer for values >= 0x60. */
		pci_read_config_byte(devbusfn, PCI_LATENCY_TIMER, &timer);

		if (timer < 0x60) {
			pci_write_config_byte(devbusfn, PCI_LATENCY_TIMER,
					      0x60);
		}

		/* read BAR for memory space access */
		pci_read_config_dword(devbusfn, PCI_BASE_ADDRESS_1, &iobase);
		iobase &= PCI_BASE_ADDRESS_MEM_MASK;
		debug("dc21x4x: DEC 21142 PCI Device @0x%x\n", iobase);

		priv = malloc(sizeof(*priv));
		if (!priv) {
			printf("Can not allocalte memory of dc21x4x\n");
			break;
		}
		memset(priv, 0, sizeof(*priv));

		dev = &priv->dev;

		sprintf(dev->name, "dc21x4x#%d", card_number);
		priv->name = dev->name;
		priv->enetaddr = dev->enetaddr;

		dev->iobase = pci_mem_to_phys(devbusfn, iobase);
		dev->priv = (void *)devbusfn;
		dev->init = dc21x4x_init;
		dev->halt = dc21x4x_halt;
		dev->send = dc21x4x_send;
		dev->recv = dc21x4x_recv;

		/* Ensure we're not sleeping. */
		pci_write_config_byte(devbusfn, PCI_CFDA_PSM, WAKEUP);

		udelay(10 * 1000);

		read_hw_addr(priv);

		eth_register(dev);

		card_number++;
	}

	return card_number;
}