445 lines
9.6 KiB
C
445 lines
9.6 KiB
C
/*
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* Copyright (c) 2018-2019 Intel Corporation.
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*
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* SPDX-License-Identifier: Apache-2.0
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*/
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#define DT_DRV_COMPAT intel_e1000
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#define LOG_MODULE_NAME eth_e1000
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#define LOG_LEVEL CONFIG_ETHERNET_LOG_LEVEL
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#include <zephyr/logging/log.h>
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LOG_MODULE_REGISTER(LOG_MODULE_NAME);
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#include <sys/types.h>
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#include <zephyr/kernel.h>
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#include <zephyr/net/ethernet.h>
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#include <ethernet/eth_stats.h>
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#include <zephyr/drivers/pcie/pcie.h>
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#include <zephyr/irq.h>
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#include "eth_e1000_priv.h"
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#if defined(CONFIG_ETH_E1000_PTP_CLOCK)
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#include <zephyr/drivers/ptp_clock.h>
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#define PTP_INST_NODEID(n) DT_INST_CHILD(n, ptp)
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#endif
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#if defined(CONFIG_ETH_E1000_VERBOSE_DEBUG)
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#define hexdump(_buf, _len, fmt, args...) \
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({ \
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const size_t STR_SIZE = 80; \
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char _str[STR_SIZE]; \
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\
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snprintk(_str, STR_SIZE, "%s: " fmt, __func__, ## args); \
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\
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LOG_HEXDUMP_DBG(_buf, _len, _str); \
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})
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#else
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#define hexdump(args...)
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#endif
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static const char *e1000_reg_to_string(enum e1000_reg_t r)
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{
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#define _(_x) case _x: return #_x
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switch (r) {
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_(CTRL);
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_(ICR);
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_(ICS);
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_(IMS);
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_(RCTL);
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_(TCTL);
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_(RDBAL);
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_(RDBAH);
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_(RDLEN);
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_(RDH);
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_(RDT);
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_(TDBAL);
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_(TDBAH);
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_(TDLEN);
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_(TDH);
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_(TDT);
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_(RAL);
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_(RAH);
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}
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#undef _
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LOG_ERR("Unsupported register: 0x%x", r);
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k_oops();
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return NULL;
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}
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static struct net_if *get_iface(struct e1000_dev *ctx)
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{
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return ctx->iface;
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}
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static enum ethernet_hw_caps e1000_caps(const struct device *dev)
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{
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return
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#if defined(CONFIG_NET_VLAN)
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ETHERNET_HW_VLAN |
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#endif
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#if defined(CONFIG_ETH_E1000_PTP_CLOCK)
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ETHERNET_PTP |
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#endif
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ETHERNET_LINK_10BASE_T | ETHERNET_LINK_100BASE_T |
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ETHERNET_LINK_1000BASE_T |
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/* The driver does not really support TXTIME atm but mark
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* it to support it so that we can test the txtime sample.
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*/
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ETHERNET_TXTIME;
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}
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#if defined(CONFIG_ETH_E1000_PTP_CLOCK)
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static const struct device *e1000_get_ptp_clock(const struct device *dev)
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{
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struct e1000_dev *ctx = dev->data;
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return ctx->ptp_clock;
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}
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#endif
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static int e1000_tx(struct e1000_dev *dev, void *buf, size_t len)
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{
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hexdump(buf, len, "%zu byte(s)", len);
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dev->tx.addr = POINTER_TO_INT(buf);
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dev->tx.len = len;
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dev->tx.cmd = TDESC_EOP | TDESC_RS;
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iow32(dev, TDT, 1);
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while (!(dev->tx.sta)) {
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k_yield();
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}
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LOG_DBG("tx.sta: 0x%02hx", dev->tx.sta);
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return (dev->tx.sta & TDESC_STA_DD) ? 0 : -EIO;
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}
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static int e1000_send(const struct device *ddev, struct net_pkt *pkt)
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{
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struct e1000_dev *dev = ddev->data;
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size_t len = net_pkt_get_len(pkt);
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if (net_pkt_read(pkt, dev->txb, len)) {
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return -EIO;
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}
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return e1000_tx(dev, dev->txb, len);
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}
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static struct net_pkt *e1000_rx(struct e1000_dev *dev)
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{
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struct net_pkt *pkt = NULL;
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void *buf;
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ssize_t len;
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LOG_DBG("rx.sta: 0x%02hx", dev->rx.sta);
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if (!(dev->rx.sta & RDESC_STA_DD)) {
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LOG_ERR("RX descriptor not ready");
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goto out;
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}
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buf = INT_TO_POINTER((uint32_t)dev->rx.addr);
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len = dev->rx.len - 4;
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if (len <= 0) {
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LOG_ERR("Invalid RX descriptor length: %hu", dev->rx.len);
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goto out;
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}
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hexdump(buf, len, "%zd byte(s)", len);
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pkt = net_pkt_rx_alloc_with_buffer(dev->iface, len, AF_UNSPEC, 0,
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K_NO_WAIT);
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if (!pkt) {
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LOG_ERR("Out of buffers");
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goto out;
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}
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if (net_pkt_write(pkt, buf, len)) {
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LOG_ERR("Out of memory for received frame");
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net_pkt_unref(pkt);
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pkt = NULL;
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}
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out:
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return pkt;
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}
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static void e1000_isr(const struct device *ddev)
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{
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struct e1000_dev *dev = ddev->data;
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uint32_t icr = ior32(dev, ICR); /* Cleared upon read */
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icr &= ~(ICR_TXDW | ICR_TXQE);
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if (icr & ICR_RXO) {
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struct net_pkt *pkt = e1000_rx(dev);
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icr &= ~ICR_RXO;
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if (pkt) {
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net_recv_data(get_iface(dev), pkt);
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} else {
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eth_stats_update_errors_rx(get_iface(dev));
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}
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}
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if (icr) {
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LOG_ERR("Unhandled interrupt, ICR: 0x%x", icr);
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}
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}
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int e1000_probe(const struct device *ddev)
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{
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/* PCI ID is decoded into REG_SIZE */
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struct e1000_dev *dev = ddev->data;
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uint32_t ral, rah;
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struct pcie_bar mbar;
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if (dev->pcie->bdf == PCIE_BDF_NONE) {
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return -ENODEV;
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}
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pcie_probe_mbar(dev->pcie->bdf, 0, &mbar);
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pcie_set_cmd(dev->pcie->bdf, PCIE_CONF_CMDSTAT_MEM |
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PCIE_CONF_CMDSTAT_MASTER, true);
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device_map(&dev->address, mbar.phys_addr, mbar.size,
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K_MEM_CACHE_NONE);
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/* Setup TX descriptor */
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iow32(dev, TDBAL, (uint32_t)POINTER_TO_UINT(&dev->tx));
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iow32(dev, TDBAH, (uint32_t)((POINTER_TO_UINT(&dev->tx) >> 16) >> 16));
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iow32(dev, TDLEN, 1*16);
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iow32(dev, TDH, 0);
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iow32(dev, TDT, 0);
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iow32(dev, TCTL, TCTL_EN);
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/* Setup RX descriptor */
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dev->rx.addr = POINTER_TO_INT(dev->rxb);
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dev->rx.len = sizeof(dev->rxb);
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iow32(dev, RDBAL, (uint32_t)POINTER_TO_UINT(&dev->rx));
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iow32(dev, RDBAH, (uint32_t)((POINTER_TO_UINT(&dev->rx) >> 16) >> 16));
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iow32(dev, RDLEN, 1*16);
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iow32(dev, RDH, 0);
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iow32(dev, RDT, 1);
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iow32(dev, IMS, IMS_RXO);
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ral = ior32(dev, RAL);
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rah = ior32(dev, RAH);
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memcpy(dev->mac, &ral, 4);
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memcpy(dev->mac + 4, &rah, 2);
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return 0;
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}
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BUILD_ASSERT(DT_INST_IRQN(0) != PCIE_IRQ_DETECT,
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"Dynamic IRQ allocation is not supported");
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static void e1000_iface_init(struct net_if *iface)
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{
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struct e1000_dev *dev = net_if_get_device(iface)->data;
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const struct e1000_config *config = net_if_get_device(iface)->config;
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if (dev->iface == NULL) {
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dev->iface = iface;
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/* Do the phy link up only once */
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config->config_func(dev);
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}
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ethernet_init(iface);
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net_if_set_link_addr(iface, dev->mac, sizeof(dev->mac),
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NET_LINK_ETHERNET);
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LOG_DBG("done");
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}
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static const struct ethernet_api e1000_api = {
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.iface_api.init = e1000_iface_init,
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#if defined(CONFIG_ETH_E1000_PTP_CLOCK)
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.get_ptp_clock = e1000_get_ptp_clock,
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#endif
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.get_capabilities = e1000_caps,
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.send = e1000_send,
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};
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#define E1000_DT_INST_IRQ_FLAGS(inst) \
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COND_CODE_1(DT_INST_IRQ_HAS_CELL(inst, sense), \
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(DT_INST_IRQ(inst, sense)), \
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(DT_INST_IRQ(inst, flags)))
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#define E1000_PCI_INIT(inst) \
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DEVICE_PCIE_INST_DECLARE(inst); \
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\
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static struct e1000_dev dev_##inst = { \
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DEVICE_PCIE_INST_INIT(inst, pcie), \
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}; \
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\
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static void e1000_config_##inst(const struct e1000_dev *dev) \
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{ \
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IRQ_CONNECT(DT_INST_IRQN(inst), \
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DT_INST_IRQ(inst, priority), \
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e1000_isr, DEVICE_DT_INST_GET(inst), \
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E1000_DT_INST_IRQ_FLAGS(inst)); \
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\
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irq_enable(DT_INST_IRQN(inst)); \
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iow32(dev, CTRL, CTRL_SLU); /* Set link up */ \
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iow32(dev, RCTL, RCTL_EN | RCTL_MPE); \
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} \
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\
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static const struct e1000_config config_##inst = { \
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.config_func = e1000_config_##inst, \
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}; \
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\
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ETH_NET_DEVICE_DT_INST_DEFINE(inst, \
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e1000_probe, \
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NULL, \
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&dev_##inst, \
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&config_##inst, \
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CONFIG_ETH_INIT_PRIORITY, \
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&e1000_api, \
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NET_ETH_MTU);
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DT_INST_FOREACH_STATUS_OKAY(E1000_PCI_INIT);
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#if defined(CONFIG_ETH_E1000_PTP_CLOCK)
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struct ptp_context {
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struct e1000_dev *eth_context;
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/* Simulate the clock. This is only for testing.
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* The value is in nanoseconds
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*/
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uint64_t clock_time;
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};
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static int ptp_clock_e1000_set(const struct device *dev,
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struct net_ptp_time *tm)
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{
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struct ptp_context *ptp_context = dev->data;
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/* TODO: Set the clock real value here */
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ptp_context->clock_time = tm->second * NSEC_PER_SEC + tm->nanosecond;
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return 0;
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}
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static int ptp_clock_e1000_get(const struct device *dev,
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struct net_ptp_time *tm)
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{
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struct ptp_context *ptp_context = dev->data;
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/* TODO: Get the clock value */
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tm->second = ptp_context->clock_time / NSEC_PER_SEC;
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tm->nanosecond = ptp_context->clock_time - tm->second * NSEC_PER_SEC;
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return 0;
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}
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static int ptp_clock_e1000_adjust(const struct device *dev, int increment)
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{
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ARG_UNUSED(dev);
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ARG_UNUSED(increment);
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/* TODO: Implement clock adjustment */
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return 0;
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}
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static int ptp_clock_e1000_rate_adjust(const struct device *dev, double ratio)
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{
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const int hw_inc = NSEC_PER_SEC / CONFIG_ETH_E1000_PTP_CLOCK_SRC_HZ;
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struct ptp_context *ptp_context = dev->data;
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struct e1000_dev *context = ptp_context->eth_context;
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int corr;
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int32_t mul;
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float val;
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/* No change needed. */
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if (ratio == 1.0) {
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return 0;
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}
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ratio *= context->clk_ratio;
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/* Limit possible ratio. */
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if ((ratio > 1.0 + 1.0/(2.0 * hw_inc)) ||
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(ratio < 1.0 - 1.0/(2.0 * hw_inc))) {
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return -EINVAL;
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}
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/* Save new ratio. */
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context->clk_ratio = ratio;
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if (ratio < 1.0) {
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corr = hw_inc - 1;
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val = 1.0 / (hw_inc * (1.0 - ratio));
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} else if (ratio > 1.0) {
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corr = hw_inc + 1;
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val = 1.0 / (hw_inc * (ratio - 1.0));
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} else {
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val = 0;
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corr = hw_inc;
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}
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if (val >= INT32_MAX) {
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/* Value is too high.
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* It is not possible to adjust the rate of the clock.
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*/
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mul = 0;
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} else {
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mul = val;
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}
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/* TODO: Adjust the clock here */
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return 0;
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}
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static const struct ptp_clock_driver_api api = {
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.set = ptp_clock_e1000_set,
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.get = ptp_clock_e1000_get,
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.adjust = ptp_clock_e1000_adjust,
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.rate_adjust = ptp_clock_e1000_rate_adjust,
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};
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static int ptp_e1000_init(const struct device *port)
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{
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struct ptp_context *ptp_context = port->data;
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struct e1000_dev *context = ptp_context->eth_context;
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context->ptp_clock = port;
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ptp_context->clock_time = k_ticks_to_ns_floor64(k_uptime_ticks());
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return 0;
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}
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#define E1000_PTP_INIT(inst) \
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static struct ptp_context ptp_e1000_context_##inst = { \
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.eth_context = DEVICE_DT_INST_GET(inst)->data, \
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}; \
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\
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DEVICE_DEFINE(e1000_ptp_clock, PTP_CLOCK_NAME, \
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ptp_e1000_init, NULL, \
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&ptp_e1000_context_##inst, NULL, POST_KERNEL, \
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CONFIG_APPLICATION_INIT_PRIORITY, &api);
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DT_INST_FOREACH_STATUS_OKAY(E1000_PTP_INIT);
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#endif /* CONFIG_ETH_E1000_PTP_CLOCK */
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