sunxi_emac.c revision 1.5
1 1.5 jmcneill /* $NetBSD: sunxi_emac.c,v 1.5 2017/09/07 01:07:04 jmcneill Exp $ */ 2 1.1 jmcneill 3 1.1 jmcneill /*- 4 1.1 jmcneill * Copyright (c) 2016-2017 Jared McNeill <jmcneill (at) invisible.ca> 5 1.1 jmcneill * All rights reserved. 6 1.1 jmcneill * 7 1.1 jmcneill * Redistribution and use in source and binary forms, with or without 8 1.1 jmcneill * modification, are permitted provided that the following conditions 9 1.1 jmcneill * are met: 10 1.1 jmcneill * 1. Redistributions of source code must retain the above copyright 11 1.1 jmcneill * notice, this list of conditions and the following disclaimer. 12 1.1 jmcneill * 2. Redistributions in binary form must reproduce the above copyright 13 1.1 jmcneill * notice, this list of conditions and the following disclaimer in the 14 1.1 jmcneill * documentation and/or other materials provided with the distribution. 15 1.1 jmcneill * 16 1.1 jmcneill * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR 17 1.1 jmcneill * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES 18 1.1 jmcneill * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. 19 1.1 jmcneill * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT, 20 1.1 jmcneill * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, 21 1.1 jmcneill * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; 22 1.1 jmcneill * LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED 23 1.1 jmcneill * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, 24 1.1 jmcneill * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY 25 1.1 jmcneill * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF 26 1.1 jmcneill * SUCH DAMAGE. 27 1.1 jmcneill */ 28 1.1 jmcneill 29 1.1 jmcneill /* 30 1.1 jmcneill * Allwinner Gigabit Ethernet MAC (EMAC) controller 31 1.1 jmcneill */ 32 1.1 jmcneill 33 1.1 jmcneill #include "opt_net_mpsafe.h" 34 1.1 jmcneill 35 1.1 jmcneill #include <sys/cdefs.h> 36 1.5 jmcneill __KERNEL_RCSID(0, "$NetBSD: sunxi_emac.c,v 1.5 2017/09/07 01:07:04 jmcneill Exp $"); 37 1.1 jmcneill 38 1.1 jmcneill #include <sys/param.h> 39 1.1 jmcneill #include <sys/bus.h> 40 1.1 jmcneill #include <sys/device.h> 41 1.1 jmcneill #include <sys/intr.h> 42 1.1 jmcneill #include <sys/systm.h> 43 1.1 jmcneill #include <sys/kernel.h> 44 1.1 jmcneill #include <sys/mutex.h> 45 1.1 jmcneill #include <sys/callout.h> 46 1.1 jmcneill #include <sys/gpio.h> 47 1.1 jmcneill #include <sys/cprng.h> 48 1.1 jmcneill 49 1.1 jmcneill #include <net/if.h> 50 1.1 jmcneill #include <net/if_dl.h> 51 1.1 jmcneill #include <net/if_ether.h> 52 1.1 jmcneill #include <net/if_media.h> 53 1.1 jmcneill #include <net/bpf.h> 54 1.1 jmcneill 55 1.1 jmcneill #include <dev/mii/miivar.h> 56 1.1 jmcneill 57 1.1 jmcneill #include <dev/fdt/fdtvar.h> 58 1.1 jmcneill 59 1.1 jmcneill #include <arm/sunxi/sunxi_emac.h> 60 1.1 jmcneill 61 1.1 jmcneill #ifdef NET_MPSAFE 62 1.1 jmcneill #define EMAC_MPSAFE 1 63 1.1 jmcneill #define CALLOUT_FLAGS CALLOUT_MPSAFE 64 1.1 jmcneill #define FDT_INTR_FLAGS FDT_INTR_MPSAFE 65 1.1 jmcneill #else 66 1.1 jmcneill #define CALLOUT_FLAGS 0 67 1.1 jmcneill #define FDT_INTR_FLAGS 0 68 1.1 jmcneill #endif 69 1.1 jmcneill 70 1.1 jmcneill #define EMAC_IFNAME "emac%d" 71 1.1 jmcneill 72 1.1 jmcneill #define ETHER_ALIGN 2 73 1.1 jmcneill 74 1.1 jmcneill #define EMAC_LOCK(sc) mutex_enter(&(sc)->mtx) 75 1.1 jmcneill #define EMAC_UNLOCK(sc) mutex_exit(&(sc)->mtx) 76 1.1 jmcneill #define EMAC_ASSERT_LOCKED(sc) KASSERT(mutex_owned(&(sc)->mtx)) 77 1.1 jmcneill 78 1.2 jmcneill #define DESC_ALIGN sizeof(struct sunxi_emac_desc) 79 1.1 jmcneill #define TX_DESC_COUNT 1024 80 1.1 jmcneill #define TX_DESC_SIZE (sizeof(struct sunxi_emac_desc) * TX_DESC_COUNT) 81 1.1 jmcneill #define RX_DESC_COUNT 256 82 1.1 jmcneill #define RX_DESC_SIZE (sizeof(struct sunxi_emac_desc) * RX_DESC_COUNT) 83 1.1 jmcneill 84 1.1 jmcneill #define DESC_OFF(n) ((n) * sizeof(struct sunxi_emac_desc)) 85 1.1 jmcneill #define TX_NEXT(n) (((n) + 1) & (TX_DESC_COUNT - 1)) 86 1.1 jmcneill #define TX_SKIP(n, o) (((n) + (o)) & (TX_DESC_COUNT - 1)) 87 1.1 jmcneill #define RX_NEXT(n) (((n) + 1) & (RX_DESC_COUNT - 1)) 88 1.1 jmcneill 89 1.1 jmcneill #define TX_MAX_SEGS 128 90 1.1 jmcneill 91 1.1 jmcneill #define SOFT_RST_RETRY 1000 92 1.1 jmcneill #define MII_BUSY_RETRY 1000 93 1.1 jmcneill #define MDIO_FREQ 2500000 94 1.1 jmcneill 95 1.1 jmcneill #define BURST_LEN_DEFAULT 8 96 1.1 jmcneill #define RX_TX_PRI_DEFAULT 0 97 1.1 jmcneill #define PAUSE_TIME_DEFAULT 0x400 98 1.3 jmcneill #define TX_INTERVAL_DEFAULT 64 99 1.1 jmcneill 100 1.1 jmcneill /* syscon EMAC clock register */ 101 1.1 jmcneill #define EMAC_CLK_EPHY_ADDR (0x1f << 20) /* H3 */ 102 1.1 jmcneill #define EMAC_CLK_EPHY_ADDR_SHIFT 20 103 1.1 jmcneill #define EMAC_CLK_EPHY_LED_POL (1 << 17) /* H3 */ 104 1.1 jmcneill #define EMAC_CLK_EPHY_SHUTDOWN (1 << 16) /* H3 */ 105 1.1 jmcneill #define EMAC_CLK_EPHY_SELECT (1 << 15) /* H3 */ 106 1.1 jmcneill #define EMAC_CLK_RMII_EN (1 << 13) 107 1.1 jmcneill #define EMAC_CLK_ETXDC (0x7 << 10) 108 1.1 jmcneill #define EMAC_CLK_ETXDC_SHIFT 10 109 1.1 jmcneill #define EMAC_CLK_ERXDC (0x1f << 5) 110 1.1 jmcneill #define EMAC_CLK_ERXDC_SHIFT 5 111 1.1 jmcneill #define EMAC_CLK_PIT (0x1 << 2) 112 1.1 jmcneill #define EMAC_CLK_PIT_MII (0 << 2) 113 1.1 jmcneill #define EMAC_CLK_PIT_RGMII (1 << 2) 114 1.1 jmcneill #define EMAC_CLK_SRC (0x3 << 0) 115 1.1 jmcneill #define EMAC_CLK_SRC_MII (0 << 0) 116 1.1 jmcneill #define EMAC_CLK_SRC_EXT_RGMII (1 << 0) 117 1.1 jmcneill #define EMAC_CLK_SRC_RGMII (2 << 0) 118 1.1 jmcneill 119 1.1 jmcneill /* Burst length of RX and TX DMA transfers */ 120 1.1 jmcneill static int sunxi_emac_burst_len = BURST_LEN_DEFAULT; 121 1.1 jmcneill 122 1.1 jmcneill /* RX / TX DMA priority. If 1, RX DMA has priority over TX DMA. */ 123 1.1 jmcneill static int sunxi_emac_rx_tx_pri = RX_TX_PRI_DEFAULT; 124 1.1 jmcneill 125 1.1 jmcneill /* Pause time field in the transmitted control frame */ 126 1.1 jmcneill static int sunxi_emac_pause_time = PAUSE_TIME_DEFAULT; 127 1.1 jmcneill 128 1.1 jmcneill /* Request a TX interrupt every <n> descriptors */ 129 1.1 jmcneill static int sunxi_emac_tx_interval = TX_INTERVAL_DEFAULT; 130 1.1 jmcneill 131 1.1 jmcneill enum sunxi_emac_type { 132 1.1 jmcneill EMAC_A83T = 1, 133 1.1 jmcneill EMAC_H3, 134 1.5 jmcneill EMAC_A64, 135 1.1 jmcneill }; 136 1.1 jmcneill 137 1.1 jmcneill static const struct of_compat_data compat_data[] = { 138 1.1 jmcneill { "allwinner,sun8i-a83t-emac", EMAC_A83T }, 139 1.1 jmcneill { "allwinner,sun8i-h3-emac", EMAC_H3 }, 140 1.5 jmcneill { "allwinner,sun50i-a64-emac", EMAC_A64 }, 141 1.1 jmcneill { NULL } 142 1.1 jmcneill }; 143 1.1 jmcneill 144 1.1 jmcneill struct sunxi_emac_bufmap { 145 1.1 jmcneill bus_dmamap_t map; 146 1.1 jmcneill struct mbuf *mbuf; 147 1.1 jmcneill }; 148 1.1 jmcneill 149 1.1 jmcneill struct sunxi_emac_txring { 150 1.1 jmcneill bus_dma_tag_t desc_tag; 151 1.1 jmcneill bus_dmamap_t desc_map; 152 1.1 jmcneill bus_dma_segment_t desc_dmaseg; 153 1.1 jmcneill struct sunxi_emac_desc *desc_ring; 154 1.1 jmcneill bus_addr_t desc_ring_paddr; 155 1.1 jmcneill bus_dma_tag_t buf_tag; 156 1.1 jmcneill struct sunxi_emac_bufmap buf_map[TX_DESC_COUNT]; 157 1.1 jmcneill u_int cur, next, queued; 158 1.1 jmcneill }; 159 1.1 jmcneill 160 1.1 jmcneill struct sunxi_emac_rxring { 161 1.1 jmcneill bus_dma_tag_t desc_tag; 162 1.1 jmcneill bus_dmamap_t desc_map; 163 1.1 jmcneill bus_dma_segment_t desc_dmaseg; 164 1.1 jmcneill struct sunxi_emac_desc *desc_ring; 165 1.1 jmcneill bus_addr_t desc_ring_paddr; 166 1.1 jmcneill bus_dma_tag_t buf_tag; 167 1.1 jmcneill struct sunxi_emac_bufmap buf_map[RX_DESC_COUNT]; 168 1.1 jmcneill u_int cur; 169 1.1 jmcneill }; 170 1.1 jmcneill 171 1.1 jmcneill enum { 172 1.1 jmcneill _RES_EMAC, 173 1.1 jmcneill _RES_SYSCON, 174 1.1 jmcneill _RES_NITEMS 175 1.1 jmcneill }; 176 1.1 jmcneill 177 1.1 jmcneill struct sunxi_emac_softc { 178 1.1 jmcneill device_t dev; 179 1.1 jmcneill int phandle; 180 1.1 jmcneill enum sunxi_emac_type type; 181 1.1 jmcneill bus_space_tag_t bst; 182 1.1 jmcneill bus_dma_tag_t dmat; 183 1.1 jmcneill 184 1.1 jmcneill bus_space_handle_t bsh[_RES_NITEMS]; 185 1.1 jmcneill struct clk *clk_ahb; 186 1.1 jmcneill struct clk *clk_ephy; 187 1.1 jmcneill struct fdtbus_reset *rst_ahb; 188 1.1 jmcneill struct fdtbus_reset *rst_ephy; 189 1.1 jmcneill struct fdtbus_regulator *reg_phy; 190 1.1 jmcneill struct fdtbus_gpio_pin *pin_reset; 191 1.1 jmcneill 192 1.1 jmcneill kmutex_t mtx; 193 1.1 jmcneill struct ethercom ec; 194 1.1 jmcneill struct mii_data mii; 195 1.1 jmcneill callout_t stat_ch; 196 1.1 jmcneill void *ih; 197 1.1 jmcneill u_int mdc_div_ratio_m; 198 1.1 jmcneill 199 1.1 jmcneill struct sunxi_emac_txring tx; 200 1.1 jmcneill struct sunxi_emac_rxring rx; 201 1.1 jmcneill }; 202 1.1 jmcneill 203 1.1 jmcneill #define RD4(sc, reg) \ 204 1.1 jmcneill bus_space_read_4((sc)->bst, (sc)->bsh[_RES_EMAC], (reg)) 205 1.1 jmcneill #define WR4(sc, reg, val) \ 206 1.1 jmcneill bus_space_write_4((sc)->bst, (sc)->bsh[_RES_EMAC], (reg), (val)) 207 1.1 jmcneill 208 1.1 jmcneill #define SYSCONRD4(sc, reg) \ 209 1.1 jmcneill bus_space_read_4((sc)->bst, (sc)->bsh[_RES_SYSCON], (reg)) 210 1.1 jmcneill #define SYSCONWR4(sc, reg, val) \ 211 1.1 jmcneill bus_space_write_4((sc)->bst, (sc)->bsh[_RES_SYSCON], (reg), (val)) 212 1.1 jmcneill 213 1.1 jmcneill static int 214 1.1 jmcneill sunxi_emac_mii_readreg(device_t dev, int phy, int reg) 215 1.1 jmcneill { 216 1.1 jmcneill struct sunxi_emac_softc *sc = device_private(dev); 217 1.1 jmcneill int retry, val; 218 1.1 jmcneill 219 1.1 jmcneill val = 0; 220 1.1 jmcneill 221 1.1 jmcneill WR4(sc, EMAC_MII_CMD, 222 1.1 jmcneill (sc->mdc_div_ratio_m << MDC_DIV_RATIO_M_SHIFT) | 223 1.1 jmcneill (phy << PHY_ADDR_SHIFT) | 224 1.1 jmcneill (reg << PHY_REG_ADDR_SHIFT) | 225 1.1 jmcneill MII_BUSY); 226 1.1 jmcneill for (retry = MII_BUSY_RETRY; retry > 0; retry--) { 227 1.1 jmcneill if ((RD4(sc, EMAC_MII_CMD) & MII_BUSY) == 0) { 228 1.1 jmcneill val = RD4(sc, EMAC_MII_DATA); 229 1.1 jmcneill break; 230 1.1 jmcneill } 231 1.1 jmcneill delay(10); 232 1.1 jmcneill } 233 1.1 jmcneill 234 1.1 jmcneill if (retry == 0) 235 1.1 jmcneill device_printf(dev, "phy read timeout, phy=%d reg=%d\n", 236 1.1 jmcneill phy, reg); 237 1.1 jmcneill 238 1.1 jmcneill return val; 239 1.1 jmcneill } 240 1.1 jmcneill 241 1.1 jmcneill static void 242 1.1 jmcneill sunxi_emac_mii_writereg(device_t dev, int phy, int reg, int val) 243 1.1 jmcneill { 244 1.1 jmcneill struct sunxi_emac_softc *sc = device_private(dev); 245 1.1 jmcneill int retry; 246 1.1 jmcneill 247 1.1 jmcneill WR4(sc, EMAC_MII_DATA, val); 248 1.1 jmcneill WR4(sc, EMAC_MII_CMD, 249 1.1 jmcneill (sc->mdc_div_ratio_m << MDC_DIV_RATIO_M_SHIFT) | 250 1.1 jmcneill (phy << PHY_ADDR_SHIFT) | 251 1.1 jmcneill (reg << PHY_REG_ADDR_SHIFT) | 252 1.1 jmcneill MII_WR | MII_BUSY); 253 1.1 jmcneill for (retry = MII_BUSY_RETRY; retry > 0; retry--) { 254 1.1 jmcneill if ((RD4(sc, EMAC_MII_CMD) & MII_BUSY) == 0) 255 1.1 jmcneill break; 256 1.1 jmcneill delay(10); 257 1.1 jmcneill } 258 1.1 jmcneill 259 1.1 jmcneill if (retry == 0) 260 1.1 jmcneill device_printf(dev, "phy write timeout, phy=%d reg=%d\n", 261 1.1 jmcneill phy, reg); 262 1.1 jmcneill } 263 1.1 jmcneill 264 1.1 jmcneill static void 265 1.1 jmcneill sunxi_emac_update_link(struct sunxi_emac_softc *sc) 266 1.1 jmcneill { 267 1.1 jmcneill struct mii_data *mii = &sc->mii; 268 1.1 jmcneill uint32_t val; 269 1.1 jmcneill 270 1.1 jmcneill val = RD4(sc, EMAC_BASIC_CTL_0); 271 1.1 jmcneill val &= ~(BASIC_CTL_SPEED | BASIC_CTL_DUPLEX); 272 1.1 jmcneill 273 1.1 jmcneill if (IFM_SUBTYPE(mii->mii_media_active) == IFM_1000_T || 274 1.1 jmcneill IFM_SUBTYPE(mii->mii_media_active) == IFM_1000_SX) 275 1.1 jmcneill val |= BASIC_CTL_SPEED_1000 << BASIC_CTL_SPEED_SHIFT; 276 1.1 jmcneill else if (IFM_SUBTYPE(mii->mii_media_active) == IFM_100_TX) 277 1.1 jmcneill val |= BASIC_CTL_SPEED_100 << BASIC_CTL_SPEED_SHIFT; 278 1.1 jmcneill else 279 1.1 jmcneill val |= BASIC_CTL_SPEED_10 << BASIC_CTL_SPEED_SHIFT; 280 1.1 jmcneill 281 1.1 jmcneill if ((IFM_OPTIONS(mii->mii_media_active) & IFM_FDX) != 0) 282 1.1 jmcneill val |= BASIC_CTL_DUPLEX; 283 1.1 jmcneill 284 1.1 jmcneill WR4(sc, EMAC_BASIC_CTL_0, val); 285 1.1 jmcneill 286 1.1 jmcneill val = RD4(sc, EMAC_RX_CTL_0); 287 1.1 jmcneill val &= ~RX_FLOW_CTL_EN; 288 1.1 jmcneill if ((IFM_OPTIONS(mii->mii_media_active) & IFM_ETH_RXPAUSE) != 0) 289 1.1 jmcneill val |= RX_FLOW_CTL_EN; 290 1.1 jmcneill WR4(sc, EMAC_RX_CTL_0, val); 291 1.1 jmcneill 292 1.1 jmcneill val = RD4(sc, EMAC_TX_FLOW_CTL); 293 1.1 jmcneill val &= ~(PAUSE_TIME|TX_FLOW_CTL_EN); 294 1.1 jmcneill if ((IFM_OPTIONS(mii->mii_media_active) & IFM_ETH_TXPAUSE) != 0) 295 1.1 jmcneill val |= TX_FLOW_CTL_EN; 296 1.1 jmcneill if ((IFM_OPTIONS(mii->mii_media_active) & IFM_FDX) != 0) 297 1.1 jmcneill val |= sunxi_emac_pause_time << PAUSE_TIME_SHIFT; 298 1.1 jmcneill WR4(sc, EMAC_TX_FLOW_CTL, val); 299 1.1 jmcneill } 300 1.1 jmcneill 301 1.1 jmcneill static void 302 1.1 jmcneill sunxi_emac_mii_statchg(struct ifnet *ifp) 303 1.1 jmcneill { 304 1.1 jmcneill struct sunxi_emac_softc * const sc = ifp->if_softc; 305 1.1 jmcneill 306 1.1 jmcneill sunxi_emac_update_link(sc); 307 1.1 jmcneill } 308 1.1 jmcneill 309 1.1 jmcneill static void 310 1.1 jmcneill sunxi_emac_dma_sync(struct sunxi_emac_softc *sc, bus_dma_tag_t dmat, 311 1.1 jmcneill bus_dmamap_t map, int start, int end, int total, int flags) 312 1.1 jmcneill { 313 1.1 jmcneill if (end > start) { 314 1.1 jmcneill bus_dmamap_sync(dmat, map, DESC_OFF(start), 315 1.1 jmcneill DESC_OFF(end) - DESC_OFF(start), flags); 316 1.1 jmcneill } else { 317 1.1 jmcneill bus_dmamap_sync(dmat, map, DESC_OFF(start), 318 1.1 jmcneill DESC_OFF(total) - DESC_OFF(start), flags); 319 1.2 jmcneill if (DESC_OFF(end) - DESC_OFF(0) > 0) 320 1.2 jmcneill bus_dmamap_sync(dmat, map, DESC_OFF(0), 321 1.2 jmcneill DESC_OFF(end) - DESC_OFF(0), flags); 322 1.1 jmcneill } 323 1.1 jmcneill } 324 1.1 jmcneill 325 1.1 jmcneill static void 326 1.1 jmcneill sunxi_emac_setup_txdesc(struct sunxi_emac_softc *sc, int index, int flags, 327 1.1 jmcneill bus_addr_t paddr, u_int len) 328 1.1 jmcneill { 329 1.1 jmcneill uint32_t status, size; 330 1.1 jmcneill 331 1.1 jmcneill if (paddr == 0 || len == 0) { 332 1.1 jmcneill status = 0; 333 1.1 jmcneill size = 0; 334 1.1 jmcneill --sc->tx.queued; 335 1.1 jmcneill } else { 336 1.1 jmcneill status = TX_DESC_CTL; 337 1.1 jmcneill size = flags | len; 338 1.1 jmcneill if ((index & (sunxi_emac_tx_interval - 1)) == 0) 339 1.1 jmcneill size |= TX_INT_CTL; 340 1.1 jmcneill ++sc->tx.queued; 341 1.1 jmcneill } 342 1.1 jmcneill 343 1.1 jmcneill sc->tx.desc_ring[index].addr = htole32((uint32_t)paddr); 344 1.1 jmcneill sc->tx.desc_ring[index].size = htole32(size); 345 1.1 jmcneill sc->tx.desc_ring[index].status = htole32(status); 346 1.1 jmcneill } 347 1.1 jmcneill 348 1.1 jmcneill static int 349 1.1 jmcneill sunxi_emac_setup_txbuf(struct sunxi_emac_softc *sc, int index, struct mbuf *m) 350 1.1 jmcneill { 351 1.1 jmcneill bus_dma_segment_t *segs; 352 1.1 jmcneill int error, nsegs, cur, i, flags; 353 1.1 jmcneill u_int csum_flags; 354 1.1 jmcneill 355 1.1 jmcneill error = bus_dmamap_load_mbuf(sc->tx.buf_tag, 356 1.1 jmcneill sc->tx.buf_map[index].map, m, BUS_DMA_WRITE|BUS_DMA_NOWAIT); 357 1.1 jmcneill if (error == EFBIG) { 358 1.1 jmcneill device_printf(sc->dev, 359 1.1 jmcneill "TX packet needs too many DMA segments, dropping...\n"); 360 1.1 jmcneill m_freem(m); 361 1.1 jmcneill return 0; 362 1.1 jmcneill } 363 1.1 jmcneill if (error != 0) 364 1.1 jmcneill return 0; 365 1.1 jmcneill 366 1.1 jmcneill segs = sc->tx.buf_map[index].map->dm_segs; 367 1.1 jmcneill nsegs = sc->tx.buf_map[index].map->dm_nsegs; 368 1.1 jmcneill 369 1.1 jmcneill flags = TX_FIR_DESC; 370 1.1 jmcneill if ((m->m_pkthdr.csum_flags & M_CSUM_IPv4) != 0) { 371 1.1 jmcneill if ((m->m_pkthdr.csum_flags & (M_CSUM_TCPv4|M_CSUM_UDPv4)) != 0) 372 1.1 jmcneill csum_flags = TX_CHECKSUM_CTL_FULL; 373 1.1 jmcneill else 374 1.1 jmcneill csum_flags = TX_CHECKSUM_CTL_IP; 375 1.1 jmcneill flags |= (csum_flags << TX_CHECKSUM_CTL_SHIFT); 376 1.1 jmcneill } 377 1.1 jmcneill 378 1.1 jmcneill for (cur = index, i = 0; i < nsegs; i++) { 379 1.1 jmcneill sc->tx.buf_map[cur].mbuf = (i == 0 ? m : NULL); 380 1.1 jmcneill if (i == nsegs - 1) 381 1.1 jmcneill flags |= TX_LAST_DESC; 382 1.1 jmcneill 383 1.1 jmcneill sunxi_emac_setup_txdesc(sc, cur, flags, segs[i].ds_addr, 384 1.1 jmcneill segs[i].ds_len); 385 1.1 jmcneill flags &= ~TX_FIR_DESC; 386 1.1 jmcneill cur = TX_NEXT(cur); 387 1.1 jmcneill } 388 1.1 jmcneill 389 1.2 jmcneill bus_dmamap_sync(sc->tx.buf_tag, sc->tx.buf_map[index].map, 390 1.2 jmcneill 0, sc->tx.buf_map[index].map->dm_mapsize, BUS_DMASYNC_PREWRITE); 391 1.2 jmcneill 392 1.1 jmcneill return nsegs; 393 1.1 jmcneill } 394 1.1 jmcneill 395 1.1 jmcneill static void 396 1.1 jmcneill sunxi_emac_setup_rxdesc(struct sunxi_emac_softc *sc, int index, 397 1.1 jmcneill bus_addr_t paddr) 398 1.1 jmcneill { 399 1.1 jmcneill uint32_t status, size; 400 1.1 jmcneill 401 1.1 jmcneill status = RX_DESC_CTL; 402 1.1 jmcneill size = MCLBYTES - 1; 403 1.1 jmcneill 404 1.1 jmcneill sc->rx.desc_ring[index].addr = htole32((uint32_t)paddr); 405 1.1 jmcneill sc->rx.desc_ring[index].size = htole32(size); 406 1.1 jmcneill sc->rx.desc_ring[index].next = 407 1.1 jmcneill htole32(sc->rx.desc_ring_paddr + DESC_OFF(RX_NEXT(index))); 408 1.1 jmcneill sc->rx.desc_ring[index].status = htole32(status); 409 1.1 jmcneill } 410 1.1 jmcneill 411 1.1 jmcneill static int 412 1.1 jmcneill sunxi_emac_setup_rxbuf(struct sunxi_emac_softc *sc, int index, struct mbuf *m) 413 1.1 jmcneill { 414 1.1 jmcneill int error; 415 1.1 jmcneill 416 1.1 jmcneill m_adj(m, ETHER_ALIGN); 417 1.1 jmcneill 418 1.1 jmcneill error = bus_dmamap_load_mbuf(sc->rx.buf_tag, 419 1.1 jmcneill sc->rx.buf_map[index].map, m, BUS_DMA_READ|BUS_DMA_NOWAIT); 420 1.1 jmcneill if (error != 0) 421 1.1 jmcneill return error; 422 1.1 jmcneill 423 1.1 jmcneill bus_dmamap_sync(sc->rx.buf_tag, sc->rx.buf_map[index].map, 424 1.1 jmcneill 0, sc->rx.buf_map[index].map->dm_mapsize, 425 1.1 jmcneill BUS_DMASYNC_PREREAD); 426 1.1 jmcneill 427 1.1 jmcneill sc->rx.buf_map[index].mbuf = m; 428 1.1 jmcneill sunxi_emac_setup_rxdesc(sc, index, 429 1.1 jmcneill sc->rx.buf_map[index].map->dm_segs[0].ds_addr); 430 1.1 jmcneill 431 1.1 jmcneill return 0; 432 1.1 jmcneill } 433 1.1 jmcneill 434 1.1 jmcneill static struct mbuf * 435 1.1 jmcneill sunxi_emac_alloc_mbufcl(struct sunxi_emac_softc *sc) 436 1.1 jmcneill { 437 1.1 jmcneill struct mbuf *m; 438 1.1 jmcneill 439 1.1 jmcneill m = m_getcl(M_NOWAIT, MT_DATA, M_PKTHDR); 440 1.1 jmcneill if (m != NULL) 441 1.1 jmcneill m->m_pkthdr.len = m->m_len = m->m_ext.ext_size; 442 1.1 jmcneill 443 1.1 jmcneill return m; 444 1.1 jmcneill } 445 1.1 jmcneill 446 1.1 jmcneill static void 447 1.1 jmcneill sunxi_emac_start_locked(struct sunxi_emac_softc *sc) 448 1.1 jmcneill { 449 1.1 jmcneill struct ifnet *ifp = &sc->ec.ec_if; 450 1.1 jmcneill struct mbuf *m; 451 1.1 jmcneill uint32_t val; 452 1.1 jmcneill int cnt, nsegs, start; 453 1.1 jmcneill 454 1.1 jmcneill EMAC_ASSERT_LOCKED(sc); 455 1.1 jmcneill 456 1.1 jmcneill if ((ifp->if_flags & (IFF_RUNNING | IFF_OACTIVE)) != IFF_RUNNING) 457 1.1 jmcneill return; 458 1.1 jmcneill 459 1.1 jmcneill for (cnt = 0, start = sc->tx.cur; ; cnt++) { 460 1.1 jmcneill if (sc->tx.queued >= TX_DESC_COUNT - TX_MAX_SEGS) { 461 1.1 jmcneill ifp->if_flags |= IFF_OACTIVE; 462 1.1 jmcneill break; 463 1.1 jmcneill } 464 1.1 jmcneill 465 1.1 jmcneill IFQ_POLL(&ifp->if_snd, m); 466 1.1 jmcneill if (m == NULL) 467 1.1 jmcneill break; 468 1.1 jmcneill 469 1.1 jmcneill nsegs = sunxi_emac_setup_txbuf(sc, sc->tx.cur, m); 470 1.1 jmcneill if (nsegs == 0) { 471 1.1 jmcneill ifp->if_flags |= IFF_OACTIVE; 472 1.1 jmcneill break; 473 1.1 jmcneill } 474 1.1 jmcneill IFQ_DEQUEUE(&ifp->if_snd, m); 475 1.1 jmcneill bpf_mtap(ifp, m); 476 1.1 jmcneill 477 1.1 jmcneill sc->tx.cur = TX_SKIP(sc->tx.cur, nsegs); 478 1.1 jmcneill } 479 1.1 jmcneill 480 1.1 jmcneill if (cnt != 0) { 481 1.1 jmcneill sunxi_emac_dma_sync(sc, sc->tx.desc_tag, sc->tx.desc_map, 482 1.1 jmcneill start, sc->tx.cur, TX_DESC_COUNT, 483 1.1 jmcneill BUS_DMASYNC_PREREAD|BUS_DMASYNC_PREWRITE); 484 1.1 jmcneill 485 1.1 jmcneill /* Start and run TX DMA */ 486 1.1 jmcneill val = RD4(sc, EMAC_TX_CTL_1); 487 1.1 jmcneill WR4(sc, EMAC_TX_CTL_1, val | TX_DMA_START); 488 1.1 jmcneill } 489 1.1 jmcneill } 490 1.1 jmcneill 491 1.1 jmcneill static void 492 1.1 jmcneill sunxi_emac_start(struct ifnet *ifp) 493 1.1 jmcneill { 494 1.1 jmcneill struct sunxi_emac_softc *sc = ifp->if_softc; 495 1.1 jmcneill 496 1.1 jmcneill EMAC_LOCK(sc); 497 1.1 jmcneill sunxi_emac_start_locked(sc); 498 1.1 jmcneill EMAC_UNLOCK(sc); 499 1.1 jmcneill } 500 1.1 jmcneill 501 1.1 jmcneill static void 502 1.1 jmcneill sunxi_emac_tick(void *softc) 503 1.1 jmcneill { 504 1.1 jmcneill struct sunxi_emac_softc *sc = softc; 505 1.1 jmcneill struct mii_data *mii = &sc->mii; 506 1.1 jmcneill #ifndef EMAC_MPSAFE 507 1.1 jmcneill int s = splnet(); 508 1.1 jmcneill #endif 509 1.1 jmcneill 510 1.1 jmcneill EMAC_LOCK(sc); 511 1.1 jmcneill mii_tick(mii); 512 1.1 jmcneill callout_schedule(&sc->stat_ch, hz); 513 1.1 jmcneill EMAC_UNLOCK(sc); 514 1.1 jmcneill 515 1.1 jmcneill #ifndef EMAC_MPSAFE 516 1.1 jmcneill splx(s); 517 1.1 jmcneill #endif 518 1.1 jmcneill } 519 1.1 jmcneill 520 1.1 jmcneill /* Bit Reversal - http://aggregate.org/MAGIC/#Bit%20Reversal */ 521 1.1 jmcneill static uint32_t 522 1.1 jmcneill bitrev32(uint32_t x) 523 1.1 jmcneill { 524 1.1 jmcneill x = (((x & 0xaaaaaaaa) >> 1) | ((x & 0x55555555) << 1)); 525 1.1 jmcneill x = (((x & 0xcccccccc) >> 2) | ((x & 0x33333333) << 2)); 526 1.1 jmcneill x = (((x & 0xf0f0f0f0) >> 4) | ((x & 0x0f0f0f0f) << 4)); 527 1.1 jmcneill x = (((x & 0xff00ff00) >> 8) | ((x & 0x00ff00ff) << 8)); 528 1.1 jmcneill 529 1.1 jmcneill return (x >> 16) | (x << 16); 530 1.1 jmcneill } 531 1.1 jmcneill 532 1.1 jmcneill static void 533 1.1 jmcneill sunxi_emac_setup_rxfilter(struct sunxi_emac_softc *sc) 534 1.1 jmcneill { 535 1.1 jmcneill struct ifnet *ifp = &sc->ec.ec_if; 536 1.1 jmcneill uint32_t val, crc, hashreg, hashbit, hash[2], machi, maclo; 537 1.1 jmcneill struct ether_multi *enm; 538 1.1 jmcneill struct ether_multistep step; 539 1.1 jmcneill const uint8_t *eaddr; 540 1.1 jmcneill 541 1.1 jmcneill EMAC_ASSERT_LOCKED(sc); 542 1.1 jmcneill 543 1.1 jmcneill val = 0; 544 1.1 jmcneill hash[0] = hash[1] = 0; 545 1.1 jmcneill 546 1.1 jmcneill if ((ifp->if_flags & IFF_PROMISC) != 0) 547 1.1 jmcneill val |= DIS_ADDR_FILTER; 548 1.1 jmcneill else if ((ifp->if_flags & IFF_ALLMULTI) != 0) { 549 1.1 jmcneill val |= RX_ALL_MULTICAST; 550 1.1 jmcneill hash[0] = hash[1] = ~0; 551 1.1 jmcneill } else { 552 1.1 jmcneill val |= HASH_MULTICAST; 553 1.1 jmcneill ETHER_FIRST_MULTI(step, &sc->ec, enm); 554 1.1 jmcneill while (enm != NULL) { 555 1.1 jmcneill crc = ether_crc32_le(enm->enm_addrlo, ETHER_ADDR_LEN); 556 1.1 jmcneill crc &= 0x7f; 557 1.1 jmcneill crc = bitrev32(~crc) >> 26; 558 1.1 jmcneill hashreg = (crc >> 5); 559 1.1 jmcneill hashbit = (crc & 0x1f); 560 1.1 jmcneill hash[hashreg] |= (1 << hashbit); 561 1.1 jmcneill ETHER_NEXT_MULTI(step, enm); 562 1.1 jmcneill } 563 1.1 jmcneill } 564 1.1 jmcneill 565 1.1 jmcneill /* Write our unicast address */ 566 1.1 jmcneill eaddr = CLLADDR(ifp->if_sadl); 567 1.1 jmcneill machi = (eaddr[5] << 8) | eaddr[4]; 568 1.1 jmcneill maclo = (eaddr[3] << 24) | (eaddr[2] << 16) | (eaddr[1] << 8) | 569 1.1 jmcneill (eaddr[0] << 0); 570 1.1 jmcneill WR4(sc, EMAC_ADDR_HIGH(0), machi); 571 1.1 jmcneill WR4(sc, EMAC_ADDR_LOW(0), maclo); 572 1.1 jmcneill 573 1.1 jmcneill /* Multicast hash filters */ 574 1.1 jmcneill WR4(sc, EMAC_RX_HASH_0, hash[1]); 575 1.1 jmcneill WR4(sc, EMAC_RX_HASH_1, hash[0]); 576 1.1 jmcneill 577 1.1 jmcneill /* RX frame filter config */ 578 1.1 jmcneill WR4(sc, EMAC_RX_FRM_FLT, val); 579 1.1 jmcneill } 580 1.1 jmcneill 581 1.1 jmcneill static void 582 1.1 jmcneill sunxi_emac_enable_intr(struct sunxi_emac_softc *sc) 583 1.1 jmcneill { 584 1.1 jmcneill /* Enable interrupts */ 585 1.1 jmcneill WR4(sc, EMAC_INT_EN, RX_INT_EN | TX_INT_EN | TX_BUF_UA_INT_EN); 586 1.1 jmcneill } 587 1.1 jmcneill 588 1.1 jmcneill static void 589 1.1 jmcneill sunxi_emac_disable_intr(struct sunxi_emac_softc *sc) 590 1.1 jmcneill { 591 1.1 jmcneill /* Disable interrupts */ 592 1.1 jmcneill WR4(sc, EMAC_INT_EN, 0); 593 1.1 jmcneill } 594 1.1 jmcneill 595 1.1 jmcneill static int 596 1.1 jmcneill sunxi_emac_init_locked(struct sunxi_emac_softc *sc) 597 1.1 jmcneill { 598 1.1 jmcneill struct ifnet *ifp = &sc->ec.ec_if; 599 1.1 jmcneill struct mii_data *mii = &sc->mii; 600 1.1 jmcneill uint32_t val; 601 1.1 jmcneill 602 1.1 jmcneill EMAC_ASSERT_LOCKED(sc); 603 1.1 jmcneill 604 1.1 jmcneill if ((ifp->if_flags & IFF_RUNNING) != 0) 605 1.1 jmcneill return 0; 606 1.1 jmcneill 607 1.1 jmcneill sunxi_emac_setup_rxfilter(sc); 608 1.1 jmcneill 609 1.1 jmcneill /* Configure DMA burst length and priorities */ 610 1.1 jmcneill val = sunxi_emac_burst_len << BASIC_CTL_BURST_LEN_SHIFT; 611 1.1 jmcneill if (sunxi_emac_rx_tx_pri) 612 1.1 jmcneill val |= BASIC_CTL_RX_TX_PRI; 613 1.1 jmcneill WR4(sc, EMAC_BASIC_CTL_1, val); 614 1.1 jmcneill 615 1.1 jmcneill /* Enable interrupts */ 616 1.1 jmcneill sunxi_emac_enable_intr(sc); 617 1.1 jmcneill 618 1.1 jmcneill /* Enable transmit DMA */ 619 1.1 jmcneill val = RD4(sc, EMAC_TX_CTL_1); 620 1.1 jmcneill WR4(sc, EMAC_TX_CTL_1, val | TX_DMA_EN | TX_MD | TX_NEXT_FRAME); 621 1.1 jmcneill 622 1.1 jmcneill /* Enable receive DMA */ 623 1.1 jmcneill val = RD4(sc, EMAC_RX_CTL_1); 624 1.1 jmcneill WR4(sc, EMAC_RX_CTL_1, val | RX_DMA_EN | RX_MD); 625 1.1 jmcneill 626 1.1 jmcneill /* Enable transmitter */ 627 1.1 jmcneill val = RD4(sc, EMAC_TX_CTL_0); 628 1.1 jmcneill WR4(sc, EMAC_TX_CTL_0, val | TX_EN); 629 1.1 jmcneill 630 1.1 jmcneill /* Enable receiver */ 631 1.1 jmcneill val = RD4(sc, EMAC_RX_CTL_0); 632 1.1 jmcneill WR4(sc, EMAC_RX_CTL_0, val | RX_EN | CHECK_CRC); 633 1.1 jmcneill 634 1.1 jmcneill ifp->if_flags |= IFF_RUNNING; 635 1.1 jmcneill ifp->if_flags &= ~IFF_OACTIVE; 636 1.1 jmcneill 637 1.1 jmcneill mii_mediachg(mii); 638 1.1 jmcneill callout_schedule(&sc->stat_ch, hz); 639 1.1 jmcneill 640 1.1 jmcneill return 0; 641 1.1 jmcneill } 642 1.1 jmcneill 643 1.1 jmcneill static int 644 1.1 jmcneill sunxi_emac_init(struct ifnet *ifp) 645 1.1 jmcneill { 646 1.1 jmcneill struct sunxi_emac_softc *sc = ifp->if_softc; 647 1.1 jmcneill int error; 648 1.1 jmcneill 649 1.1 jmcneill EMAC_LOCK(sc); 650 1.1 jmcneill error = sunxi_emac_init_locked(sc); 651 1.1 jmcneill EMAC_UNLOCK(sc); 652 1.1 jmcneill 653 1.1 jmcneill return error; 654 1.1 jmcneill } 655 1.1 jmcneill 656 1.1 jmcneill static void 657 1.1 jmcneill sunxi_emac_stop_locked(struct sunxi_emac_softc *sc, int disable) 658 1.1 jmcneill { 659 1.1 jmcneill struct ifnet *ifp = &sc->ec.ec_if; 660 1.1 jmcneill uint32_t val; 661 1.1 jmcneill 662 1.1 jmcneill EMAC_ASSERT_LOCKED(sc); 663 1.1 jmcneill 664 1.1 jmcneill callout_stop(&sc->stat_ch); 665 1.1 jmcneill 666 1.1 jmcneill mii_down(&sc->mii); 667 1.1 jmcneill 668 1.1 jmcneill /* Stop transmit DMA and flush data in the TX FIFO */ 669 1.1 jmcneill val = RD4(sc, EMAC_TX_CTL_1); 670 1.1 jmcneill val &= ~TX_DMA_EN; 671 1.1 jmcneill val |= FLUSH_TX_FIFO; 672 1.1 jmcneill WR4(sc, EMAC_TX_CTL_1, val); 673 1.1 jmcneill 674 1.1 jmcneill /* Disable transmitter */ 675 1.1 jmcneill val = RD4(sc, EMAC_TX_CTL_0); 676 1.1 jmcneill WR4(sc, EMAC_TX_CTL_0, val & ~TX_EN); 677 1.1 jmcneill 678 1.1 jmcneill /* Disable receiver */ 679 1.1 jmcneill val = RD4(sc, EMAC_RX_CTL_0); 680 1.1 jmcneill WR4(sc, EMAC_RX_CTL_0, val & ~RX_EN); 681 1.1 jmcneill 682 1.1 jmcneill /* Disable interrupts */ 683 1.1 jmcneill sunxi_emac_disable_intr(sc); 684 1.1 jmcneill 685 1.1 jmcneill /* Disable transmit DMA */ 686 1.1 jmcneill val = RD4(sc, EMAC_TX_CTL_1); 687 1.1 jmcneill WR4(sc, EMAC_TX_CTL_1, val & ~TX_DMA_EN); 688 1.1 jmcneill 689 1.1 jmcneill /* Disable receive DMA */ 690 1.1 jmcneill val = RD4(sc, EMAC_RX_CTL_1); 691 1.1 jmcneill WR4(sc, EMAC_RX_CTL_1, val & ~RX_DMA_EN); 692 1.1 jmcneill 693 1.1 jmcneill ifp->if_flags &= ~(IFF_RUNNING | IFF_OACTIVE); 694 1.1 jmcneill } 695 1.1 jmcneill 696 1.1 jmcneill static void 697 1.1 jmcneill sunxi_emac_stop(struct ifnet *ifp, int disable) 698 1.1 jmcneill { 699 1.1 jmcneill struct sunxi_emac_softc * const sc = ifp->if_softc; 700 1.1 jmcneill 701 1.1 jmcneill EMAC_LOCK(sc); 702 1.1 jmcneill sunxi_emac_stop_locked(sc, disable); 703 1.1 jmcneill EMAC_UNLOCK(sc); 704 1.1 jmcneill } 705 1.1 jmcneill 706 1.1 jmcneill static int 707 1.1 jmcneill sunxi_emac_rxintr(struct sunxi_emac_softc *sc) 708 1.1 jmcneill { 709 1.1 jmcneill struct ifnet *ifp = &sc->ec.ec_if; 710 1.4 jmcneill int error, index, len, npkt; 711 1.4 jmcneill struct mbuf *m, *m0; 712 1.1 jmcneill uint32_t status; 713 1.1 jmcneill 714 1.1 jmcneill npkt = 0; 715 1.1 jmcneill 716 1.1 jmcneill for (index = sc->rx.cur; ; index = RX_NEXT(index)) { 717 1.1 jmcneill sunxi_emac_dma_sync(sc, sc->rx.desc_tag, sc->rx.desc_map, 718 1.1 jmcneill index, index + 1, 719 1.1 jmcneill RX_DESC_COUNT, BUS_DMASYNC_POSTREAD|BUS_DMASYNC_POSTWRITE); 720 1.1 jmcneill 721 1.1 jmcneill status = le32toh(sc->rx.desc_ring[index].status); 722 1.1 jmcneill if ((status & RX_DESC_CTL) != 0) 723 1.1 jmcneill break; 724 1.1 jmcneill 725 1.1 jmcneill bus_dmamap_sync(sc->rx.buf_tag, sc->rx.buf_map[index].map, 726 1.1 jmcneill 0, sc->rx.buf_map[index].map->dm_mapsize, 727 1.1 jmcneill BUS_DMASYNC_POSTREAD); 728 1.1 jmcneill bus_dmamap_unload(sc->rx.buf_tag, sc->rx.buf_map[index].map); 729 1.1 jmcneill 730 1.1 jmcneill len = (status & RX_FRM_LEN) >> RX_FRM_LEN_SHIFT; 731 1.1 jmcneill if (len != 0) { 732 1.1 jmcneill m = sc->rx.buf_map[index].mbuf; 733 1.1 jmcneill m_set_rcvif(m, ifp); 734 1.1 jmcneill m->m_flags |= M_HASFCS; 735 1.1 jmcneill m->m_pkthdr.len = len; 736 1.1 jmcneill m->m_len = len; 737 1.4 jmcneill m->m_nextpkt = NULL; 738 1.1 jmcneill 739 1.1 jmcneill if ((ifp->if_capenable & IFCAP_CSUM_IPv4_Rx) != 0 && 740 1.1 jmcneill (status & RX_FRM_TYPE) != 0) { 741 1.1 jmcneill m->m_pkthdr.csum_flags = M_CSUM_IPv4; 742 1.1 jmcneill if ((status & RX_HEADER_ERR) != 0) 743 1.1 jmcneill m->m_pkthdr.csum_flags |= 744 1.1 jmcneill M_CSUM_IPv4_BAD; 745 1.1 jmcneill if ((status & RX_PAYLOAD_ERR) == 0) { 746 1.1 jmcneill m->m_pkthdr.csum_flags |= 747 1.1 jmcneill M_CSUM_DATA; 748 1.1 jmcneill m->m_pkthdr.csum_data = 0xffff; 749 1.1 jmcneill } 750 1.1 jmcneill } 751 1.1 jmcneill 752 1.1 jmcneill ++npkt; 753 1.1 jmcneill 754 1.4 jmcneill if_percpuq_enqueue(ifp->if_percpuq, m); 755 1.1 jmcneill } 756 1.1 jmcneill 757 1.1 jmcneill if ((m0 = sunxi_emac_alloc_mbufcl(sc)) != NULL) { 758 1.1 jmcneill error = sunxi_emac_setup_rxbuf(sc, index, m0); 759 1.1 jmcneill if (error != 0) { 760 1.1 jmcneill /* XXX hole in RX ring */ 761 1.1 jmcneill } 762 1.1 jmcneill } else 763 1.1 jmcneill ifp->if_ierrors++; 764 1.1 jmcneill 765 1.1 jmcneill sunxi_emac_dma_sync(sc, sc->rx.desc_tag, sc->rx.desc_map, 766 1.1 jmcneill index, index + 1, 767 1.2 jmcneill RX_DESC_COUNT, BUS_DMASYNC_PREWRITE|BUS_DMASYNC_PREREAD); 768 1.1 jmcneill } 769 1.1 jmcneill 770 1.2 jmcneill sc->rx.cur = index; 771 1.2 jmcneill 772 1.1 jmcneill return npkt; 773 1.1 jmcneill } 774 1.1 jmcneill 775 1.1 jmcneill static void 776 1.1 jmcneill sunxi_emac_txintr(struct sunxi_emac_softc *sc) 777 1.1 jmcneill { 778 1.1 jmcneill struct ifnet *ifp = &sc->ec.ec_if; 779 1.1 jmcneill struct sunxi_emac_bufmap *bmap; 780 1.1 jmcneill struct sunxi_emac_desc *desc; 781 1.1 jmcneill uint32_t status; 782 1.1 jmcneill int i; 783 1.1 jmcneill 784 1.1 jmcneill EMAC_ASSERT_LOCKED(sc); 785 1.1 jmcneill 786 1.1 jmcneill for (i = sc->tx.next; sc->tx.queued > 0; i = TX_NEXT(i)) { 787 1.1 jmcneill KASSERT(sc->tx.queued > 0 && sc->tx.queued <= TX_DESC_COUNT); 788 1.1 jmcneill sunxi_emac_dma_sync(sc, sc->tx.desc_tag, sc->tx.desc_map, 789 1.1 jmcneill i, i + 1, TX_DESC_COUNT, 790 1.1 jmcneill BUS_DMASYNC_POSTREAD|BUS_DMASYNC_POSTWRITE); 791 1.1 jmcneill desc = &sc->tx.desc_ring[i]; 792 1.1 jmcneill status = le32toh(desc->status); 793 1.1 jmcneill if ((status & TX_DESC_CTL) != 0) 794 1.1 jmcneill break; 795 1.1 jmcneill bmap = &sc->tx.buf_map[i]; 796 1.1 jmcneill if (bmap->mbuf != NULL) { 797 1.1 jmcneill bus_dmamap_sync(sc->tx.buf_tag, bmap->map, 798 1.1 jmcneill 0, bmap->map->dm_mapsize, 799 1.1 jmcneill BUS_DMASYNC_POSTWRITE); 800 1.1 jmcneill bus_dmamap_unload(sc->tx.buf_tag, bmap->map); 801 1.1 jmcneill m_freem(bmap->mbuf); 802 1.1 jmcneill bmap->mbuf = NULL; 803 1.1 jmcneill } 804 1.1 jmcneill 805 1.1 jmcneill sunxi_emac_setup_txdesc(sc, i, 0, 0, 0); 806 1.2 jmcneill sunxi_emac_dma_sync(sc, sc->tx.desc_tag, sc->tx.desc_map, 807 1.2 jmcneill i, i + 1, TX_DESC_COUNT, 808 1.2 jmcneill BUS_DMASYNC_PREREAD|BUS_DMASYNC_PREWRITE); 809 1.1 jmcneill 810 1.1 jmcneill ifp->if_flags &= ~IFF_OACTIVE; 811 1.1 jmcneill ifp->if_opackets++; 812 1.1 jmcneill } 813 1.1 jmcneill 814 1.1 jmcneill sc->tx.next = i; 815 1.1 jmcneill } 816 1.1 jmcneill 817 1.1 jmcneill static int 818 1.1 jmcneill sunxi_emac_intr(void *arg) 819 1.1 jmcneill { 820 1.1 jmcneill struct sunxi_emac_softc *sc = arg; 821 1.1 jmcneill struct ifnet *ifp = &sc->ec.ec_if; 822 1.1 jmcneill uint32_t val; 823 1.1 jmcneill 824 1.1 jmcneill EMAC_LOCK(sc); 825 1.1 jmcneill 826 1.1 jmcneill val = RD4(sc, EMAC_INT_STA); 827 1.1 jmcneill WR4(sc, EMAC_INT_STA, val); 828 1.1 jmcneill 829 1.1 jmcneill if (val & RX_INT) 830 1.1 jmcneill sunxi_emac_rxintr(sc); 831 1.1 jmcneill 832 1.1 jmcneill if (val & (TX_INT|TX_BUF_UA_INT)) { 833 1.1 jmcneill sunxi_emac_txintr(sc); 834 1.1 jmcneill if_schedule_deferred_start(ifp); 835 1.1 jmcneill } 836 1.1 jmcneill 837 1.1 jmcneill EMAC_UNLOCK(sc); 838 1.1 jmcneill 839 1.1 jmcneill return 1; 840 1.1 jmcneill } 841 1.1 jmcneill 842 1.1 jmcneill static int 843 1.1 jmcneill sunxi_emac_ioctl(struct ifnet *ifp, u_long cmd, void *data) 844 1.1 jmcneill { 845 1.1 jmcneill struct sunxi_emac_softc *sc = ifp->if_softc; 846 1.1 jmcneill struct mii_data *mii = &sc->mii; 847 1.1 jmcneill struct ifreq *ifr = data; 848 1.1 jmcneill int error, s; 849 1.1 jmcneill 850 1.1 jmcneill #ifndef EMAC_MPSAFE 851 1.1 jmcneill s = splnet(); 852 1.1 jmcneill #endif 853 1.1 jmcneill 854 1.1 jmcneill switch (cmd) { 855 1.1 jmcneill case SIOCSIFMEDIA: 856 1.1 jmcneill case SIOCGIFMEDIA: 857 1.1 jmcneill #ifdef EMAC_MPSAFE 858 1.1 jmcneill s = splnet(); 859 1.1 jmcneill #endif 860 1.1 jmcneill error = ifmedia_ioctl(ifp, ifr, &mii->mii_media, cmd); 861 1.1 jmcneill #ifdef EMAC_MPSAFE 862 1.1 jmcneill splx(s); 863 1.1 jmcneill #endif 864 1.1 jmcneill break; 865 1.1 jmcneill default: 866 1.1 jmcneill #ifdef EMAC_MPSAFE 867 1.1 jmcneill s = splnet(); 868 1.1 jmcneill #endif 869 1.1 jmcneill error = ether_ioctl(ifp, cmd, data); 870 1.1 jmcneill #ifdef EMAC_MPSAFE 871 1.1 jmcneill splx(s); 872 1.1 jmcneill #endif 873 1.1 jmcneill if (error != ENETRESET) 874 1.1 jmcneill break; 875 1.1 jmcneill 876 1.1 jmcneill error = 0; 877 1.1 jmcneill 878 1.1 jmcneill if (cmd == SIOCSIFCAP) 879 1.1 jmcneill error = (*ifp->if_init)(ifp); 880 1.1 jmcneill else if (cmd != SIOCADDMULTI && cmd != SIOCDELMULTI) 881 1.1 jmcneill ; 882 1.1 jmcneill else if ((ifp->if_flags & IFF_RUNNING) != 0) { 883 1.1 jmcneill EMAC_LOCK(sc); 884 1.1 jmcneill sunxi_emac_setup_rxfilter(sc); 885 1.1 jmcneill EMAC_UNLOCK(sc); 886 1.1 jmcneill } 887 1.1 jmcneill break; 888 1.1 jmcneill } 889 1.1 jmcneill 890 1.1 jmcneill #ifndef EMAC_MPSAFE 891 1.1 jmcneill splx(s); 892 1.1 jmcneill #endif 893 1.1 jmcneill 894 1.1 jmcneill return error; 895 1.1 jmcneill } 896 1.1 jmcneill 897 1.1 jmcneill static int 898 1.1 jmcneill sunxi_emac_setup_phy(struct sunxi_emac_softc *sc) 899 1.1 jmcneill { 900 1.1 jmcneill uint32_t reg, tx_delay, rx_delay; 901 1.1 jmcneill const char *phy_type; 902 1.1 jmcneill 903 1.1 jmcneill phy_type = fdtbus_get_string(sc->phandle, "phy-mode"); 904 1.1 jmcneill if (phy_type == NULL) 905 1.1 jmcneill return 0; 906 1.1 jmcneill 907 1.1 jmcneill aprint_debug_dev(sc->dev, "PHY type: %s\n", phy_type); 908 1.1 jmcneill 909 1.1 jmcneill reg = SYSCONRD4(sc, 0); 910 1.1 jmcneill 911 1.1 jmcneill reg &= ~(EMAC_CLK_PIT | EMAC_CLK_SRC | EMAC_CLK_RMII_EN); 912 1.1 jmcneill if (strcmp(phy_type, "rgmii") == 0) 913 1.1 jmcneill reg |= EMAC_CLK_PIT_RGMII | EMAC_CLK_SRC_RGMII; 914 1.1 jmcneill else if (strcmp(phy_type, "rmii") == 0) 915 1.1 jmcneill reg |= EMAC_CLK_RMII_EN; 916 1.1 jmcneill else 917 1.1 jmcneill reg |= EMAC_CLK_PIT_MII | EMAC_CLK_SRC_MII; 918 1.1 jmcneill 919 1.1 jmcneill if (of_getprop_uint32(sc->phandle, "tx-delay", &tx_delay) == 0) { 920 1.1 jmcneill reg &= ~EMAC_CLK_ETXDC; 921 1.1 jmcneill reg |= (tx_delay << EMAC_CLK_ETXDC_SHIFT); 922 1.1 jmcneill } 923 1.1 jmcneill if (of_getprop_uint32(sc->phandle, "rx-delay", &rx_delay) == 0) { 924 1.1 jmcneill reg &= ~EMAC_CLK_ERXDC; 925 1.1 jmcneill reg |= (rx_delay << EMAC_CLK_ERXDC_SHIFT); 926 1.1 jmcneill } 927 1.1 jmcneill 928 1.1 jmcneill if (sc->type == EMAC_H3) { 929 1.1 jmcneill if (of_hasprop(sc->phandle, "allwinner,use-internal-phy")) { 930 1.1 jmcneill reg |= EMAC_CLK_EPHY_SELECT; 931 1.1 jmcneill reg &= ~EMAC_CLK_EPHY_SHUTDOWN; 932 1.1 jmcneill if (of_hasprop(sc->phandle, 933 1.1 jmcneill "allwinner,leds-active-low")) 934 1.1 jmcneill reg |= EMAC_CLK_EPHY_LED_POL; 935 1.1 jmcneill else 936 1.1 jmcneill reg &= ~EMAC_CLK_EPHY_LED_POL; 937 1.1 jmcneill 938 1.1 jmcneill /* Set internal PHY addr to 1 */ 939 1.1 jmcneill reg &= ~EMAC_CLK_EPHY_ADDR; 940 1.1 jmcneill reg |= (1 << EMAC_CLK_EPHY_ADDR_SHIFT); 941 1.1 jmcneill } else { 942 1.1 jmcneill reg &= ~EMAC_CLK_EPHY_SELECT; 943 1.1 jmcneill } 944 1.1 jmcneill } 945 1.1 jmcneill 946 1.1 jmcneill aprint_debug_dev(sc->dev, "EMAC clock: 0x%08x\n", reg); 947 1.1 jmcneill 948 1.1 jmcneill SYSCONWR4(sc, 0, reg); 949 1.1 jmcneill 950 1.1 jmcneill return 0; 951 1.1 jmcneill } 952 1.1 jmcneill 953 1.1 jmcneill static int 954 1.1 jmcneill sunxi_emac_setup_resources(struct sunxi_emac_softc *sc) 955 1.1 jmcneill { 956 1.1 jmcneill u_int freq; 957 1.1 jmcneill int error, div; 958 1.1 jmcneill 959 1.1 jmcneill /* Configure PHY for MII or RGMII mode */ 960 1.1 jmcneill if (sunxi_emac_setup_phy(sc) != 0) 961 1.1 jmcneill return ENXIO; 962 1.1 jmcneill 963 1.1 jmcneill /* Enable clocks */ 964 1.1 jmcneill error = clk_enable(sc->clk_ahb); 965 1.1 jmcneill if (error != 0) { 966 1.1 jmcneill aprint_error_dev(sc->dev, "cannot enable ahb clock\n"); 967 1.1 jmcneill return error; 968 1.1 jmcneill } 969 1.1 jmcneill 970 1.1 jmcneill if (sc->clk_ephy != NULL) { 971 1.1 jmcneill error = clk_enable(sc->clk_ephy); 972 1.1 jmcneill if (error != 0) { 973 1.1 jmcneill aprint_error_dev(sc->dev, "cannot enable ephy clock\n"); 974 1.1 jmcneill return error; 975 1.1 jmcneill } 976 1.1 jmcneill } 977 1.1 jmcneill 978 1.1 jmcneill /* De-assert reset */ 979 1.1 jmcneill error = fdtbus_reset_deassert(sc->rst_ahb); 980 1.1 jmcneill if (error != 0) { 981 1.1 jmcneill aprint_error_dev(sc->dev, "cannot de-assert ahb reset\n"); 982 1.1 jmcneill return error; 983 1.1 jmcneill } 984 1.1 jmcneill if (sc->rst_ephy != NULL) { 985 1.1 jmcneill error = fdtbus_reset_deassert(sc->rst_ephy); 986 1.1 jmcneill if (error != 0) { 987 1.1 jmcneill aprint_error_dev(sc->dev, 988 1.1 jmcneill "cannot de-assert ephy reset\n"); 989 1.1 jmcneill return error; 990 1.1 jmcneill } 991 1.1 jmcneill } 992 1.1 jmcneill 993 1.1 jmcneill /* Enable PHY regulator if applicable */ 994 1.1 jmcneill if (sc->reg_phy != NULL) { 995 1.1 jmcneill error = fdtbus_regulator_enable(sc->reg_phy); 996 1.1 jmcneill if (error != 0) { 997 1.1 jmcneill aprint_error_dev(sc->dev, 998 1.1 jmcneill "cannot enable PHY regulator\n"); 999 1.1 jmcneill return error; 1000 1.1 jmcneill } 1001 1.1 jmcneill } 1002 1.1 jmcneill 1003 1.1 jmcneill /* Determine MDC clock divide ratio based on AHB clock */ 1004 1.1 jmcneill freq = clk_get_rate(sc->clk_ahb); 1005 1.1 jmcneill if (freq == 0) { 1006 1.1 jmcneill aprint_error_dev(sc->dev, "cannot get AHB clock frequency\n"); 1007 1.1 jmcneill return ENXIO; 1008 1.1 jmcneill } 1009 1.1 jmcneill div = freq / MDIO_FREQ; 1010 1.1 jmcneill if (div <= 16) 1011 1.1 jmcneill sc->mdc_div_ratio_m = MDC_DIV_RATIO_M_16; 1012 1.1 jmcneill else if (div <= 32) 1013 1.1 jmcneill sc->mdc_div_ratio_m = MDC_DIV_RATIO_M_32; 1014 1.1 jmcneill else if (div <= 64) 1015 1.1 jmcneill sc->mdc_div_ratio_m = MDC_DIV_RATIO_M_64; 1016 1.1 jmcneill else if (div <= 128) 1017 1.1 jmcneill sc->mdc_div_ratio_m = MDC_DIV_RATIO_M_128; 1018 1.1 jmcneill else { 1019 1.1 jmcneill aprint_error_dev(sc->dev, 1020 1.1 jmcneill "cannot determine MDC clock divide ratio\n"); 1021 1.1 jmcneill return ENXIO; 1022 1.1 jmcneill } 1023 1.1 jmcneill 1024 1.1 jmcneill aprint_debug_dev(sc->dev, "AHB frequency %u Hz, MDC div: 0x%x\n", 1025 1.1 jmcneill freq, sc->mdc_div_ratio_m); 1026 1.1 jmcneill 1027 1.1 jmcneill return 0; 1028 1.1 jmcneill } 1029 1.1 jmcneill 1030 1.1 jmcneill static void 1031 1.1 jmcneill sunxi_emac_get_eaddr(struct sunxi_emac_softc *sc, uint8_t *eaddr) 1032 1.1 jmcneill { 1033 1.1 jmcneill uint32_t maclo, machi; 1034 1.1 jmcneill #if notyet 1035 1.1 jmcneill u_char rootkey[16]; 1036 1.1 jmcneill #endif 1037 1.1 jmcneill 1038 1.1 jmcneill machi = RD4(sc, EMAC_ADDR_HIGH(0)) & 0xffff; 1039 1.1 jmcneill maclo = RD4(sc, EMAC_ADDR_LOW(0)); 1040 1.1 jmcneill 1041 1.1 jmcneill if (maclo == 0xffffffff && machi == 0xffff) { 1042 1.1 jmcneill #if notyet 1043 1.1 jmcneill /* MAC address in hardware is invalid, create one */ 1044 1.1 jmcneill if (aw_sid_get_rootkey(rootkey) == 0 && 1045 1.1 jmcneill (rootkey[3] | rootkey[12] | rootkey[13] | rootkey[14] | 1046 1.1 jmcneill rootkey[15]) != 0) { 1047 1.1 jmcneill /* MAC address is derived from the root key in SID */ 1048 1.1 jmcneill maclo = (rootkey[13] << 24) | (rootkey[12] << 16) | 1049 1.1 jmcneill (rootkey[3] << 8) | 0x02; 1050 1.1 jmcneill machi = (rootkey[15] << 8) | rootkey[14]; 1051 1.1 jmcneill } else { 1052 1.1 jmcneill #endif 1053 1.1 jmcneill /* Create one */ 1054 1.1 jmcneill maclo = 0x00f2 | (cprng_strong32() & 0xffff0000); 1055 1.1 jmcneill machi = cprng_strong32() & 0xffff; 1056 1.1 jmcneill #if notyet 1057 1.1 jmcneill } 1058 1.1 jmcneill #endif 1059 1.1 jmcneill } 1060 1.1 jmcneill 1061 1.1 jmcneill eaddr[0] = maclo & 0xff; 1062 1.1 jmcneill eaddr[1] = (maclo >> 8) & 0xff; 1063 1.1 jmcneill eaddr[2] = (maclo >> 16) & 0xff; 1064 1.1 jmcneill eaddr[3] = (maclo >> 24) & 0xff; 1065 1.1 jmcneill eaddr[4] = machi & 0xff; 1066 1.1 jmcneill eaddr[5] = (machi >> 8) & 0xff; 1067 1.1 jmcneill } 1068 1.1 jmcneill 1069 1.1 jmcneill #ifdef SUNXI_EMAC_DEBUG 1070 1.1 jmcneill static void 1071 1.1 jmcneill sunxi_emac_dump_regs(struct sunxi_emac_softc *sc) 1072 1.1 jmcneill { 1073 1.1 jmcneill static const struct { 1074 1.1 jmcneill const char *name; 1075 1.1 jmcneill u_int reg; 1076 1.1 jmcneill } regs[] = { 1077 1.1 jmcneill { "BASIC_CTL_0", EMAC_BASIC_CTL_0 }, 1078 1.1 jmcneill { "BASIC_CTL_1", EMAC_BASIC_CTL_1 }, 1079 1.1 jmcneill { "INT_STA", EMAC_INT_STA }, 1080 1.1 jmcneill { "INT_EN", EMAC_INT_EN }, 1081 1.1 jmcneill { "TX_CTL_0", EMAC_TX_CTL_0 }, 1082 1.1 jmcneill { "TX_CTL_1", EMAC_TX_CTL_1 }, 1083 1.1 jmcneill { "TX_FLOW_CTL", EMAC_TX_FLOW_CTL }, 1084 1.1 jmcneill { "TX_DMA_LIST", EMAC_TX_DMA_LIST }, 1085 1.1 jmcneill { "RX_CTL_0", EMAC_RX_CTL_0 }, 1086 1.1 jmcneill { "RX_CTL_1", EMAC_RX_CTL_1 }, 1087 1.1 jmcneill { "RX_DMA_LIST", EMAC_RX_DMA_LIST }, 1088 1.1 jmcneill { "RX_FRM_FLT", EMAC_RX_FRM_FLT }, 1089 1.1 jmcneill { "RX_HASH_0", EMAC_RX_HASH_0 }, 1090 1.1 jmcneill { "RX_HASH_1", EMAC_RX_HASH_1 }, 1091 1.1 jmcneill { "MII_CMD", EMAC_MII_CMD }, 1092 1.1 jmcneill { "ADDR_HIGH0", EMAC_ADDR_HIGH(0) }, 1093 1.1 jmcneill { "ADDR_LOW0", EMAC_ADDR_LOW(0) }, 1094 1.1 jmcneill { "TX_DMA_STA", EMAC_TX_DMA_STA }, 1095 1.1 jmcneill { "TX_DMA_CUR_DESC", EMAC_TX_DMA_CUR_DESC }, 1096 1.1 jmcneill { "TX_DMA_CUR_BUF", EMAC_TX_DMA_CUR_BUF }, 1097 1.1 jmcneill { "RX_DMA_STA", EMAC_RX_DMA_STA }, 1098 1.1 jmcneill { "RX_DMA_CUR_DESC", EMAC_RX_DMA_CUR_DESC }, 1099 1.1 jmcneill { "RX_DMA_CUR_BUF", EMAC_RX_DMA_CUR_BUF }, 1100 1.1 jmcneill { "RGMII_STA", EMAC_RGMII_STA }, 1101 1.1 jmcneill }; 1102 1.1 jmcneill u_int n; 1103 1.1 jmcneill 1104 1.1 jmcneill for (n = 0; n < __arraycount(regs); n++) 1105 1.1 jmcneill device_printf(dev, " %-20s %08x\n", regs[n].name, 1106 1.1 jmcneill RD4(sc, regs[n].reg)); 1107 1.1 jmcneill } 1108 1.1 jmcneill #endif 1109 1.1 jmcneill 1110 1.1 jmcneill static int 1111 1.1 jmcneill sunxi_emac_phy_reset(struct sunxi_emac_softc *sc) 1112 1.1 jmcneill { 1113 1.1 jmcneill uint32_t delay_prop[3]; 1114 1.1 jmcneill int pin_value; 1115 1.1 jmcneill 1116 1.1 jmcneill if (sc->pin_reset == NULL) 1117 1.1 jmcneill return 0; 1118 1.1 jmcneill 1119 1.1 jmcneill if (OF_getprop(sc->phandle, "allwinner,reset-delays-us", delay_prop, 1120 1.1 jmcneill sizeof(delay_prop)) <= 0) 1121 1.1 jmcneill return ENXIO; 1122 1.1 jmcneill 1123 1.1 jmcneill pin_value = of_hasprop(sc->phandle, "allwinner,reset-active-low"); 1124 1.1 jmcneill 1125 1.1 jmcneill fdtbus_gpio_write(sc->pin_reset, pin_value); 1126 1.1 jmcneill delay(htole32(delay_prop[0])); 1127 1.1 jmcneill fdtbus_gpio_write(sc->pin_reset, !pin_value); 1128 1.1 jmcneill delay(htole32(delay_prop[1])); 1129 1.1 jmcneill fdtbus_gpio_write(sc->pin_reset, pin_value); 1130 1.1 jmcneill delay(htole32(delay_prop[2])); 1131 1.1 jmcneill 1132 1.1 jmcneill return 0; 1133 1.1 jmcneill } 1134 1.1 jmcneill 1135 1.1 jmcneill static int 1136 1.1 jmcneill sunxi_emac_reset(struct sunxi_emac_softc *sc) 1137 1.1 jmcneill { 1138 1.1 jmcneill int retry; 1139 1.1 jmcneill 1140 1.1 jmcneill /* Reset PHY if necessary */ 1141 1.1 jmcneill if (sunxi_emac_phy_reset(sc) != 0) { 1142 1.1 jmcneill aprint_error_dev(sc->dev, "failed to reset PHY\n"); 1143 1.1 jmcneill return ENXIO; 1144 1.1 jmcneill } 1145 1.1 jmcneill 1146 1.1 jmcneill /* Soft reset all registers and logic */ 1147 1.1 jmcneill WR4(sc, EMAC_BASIC_CTL_1, BASIC_CTL_SOFT_RST); 1148 1.1 jmcneill 1149 1.1 jmcneill /* Wait for soft reset bit to self-clear */ 1150 1.1 jmcneill for (retry = SOFT_RST_RETRY; retry > 0; retry--) { 1151 1.1 jmcneill if ((RD4(sc, EMAC_BASIC_CTL_1) & BASIC_CTL_SOFT_RST) == 0) 1152 1.1 jmcneill break; 1153 1.1 jmcneill delay(10); 1154 1.1 jmcneill } 1155 1.1 jmcneill if (retry == 0) { 1156 1.1 jmcneill aprint_error_dev(sc->dev, "soft reset timed out\n"); 1157 1.1 jmcneill #ifdef SUNXI_EMAC_DEBUG 1158 1.1 jmcneill sunxi_emac_dump_regs(sc); 1159 1.1 jmcneill #endif 1160 1.1 jmcneill return ETIMEDOUT; 1161 1.1 jmcneill } 1162 1.1 jmcneill 1163 1.1 jmcneill return 0; 1164 1.1 jmcneill } 1165 1.1 jmcneill 1166 1.1 jmcneill static int 1167 1.1 jmcneill sunxi_emac_setup_dma(struct sunxi_emac_softc *sc) 1168 1.1 jmcneill { 1169 1.1 jmcneill struct mbuf *m; 1170 1.1 jmcneill int error, nsegs, i; 1171 1.1 jmcneill 1172 1.1 jmcneill /* Setup TX ring */ 1173 1.1 jmcneill sc->tx.buf_tag = sc->tx.desc_tag = sc->dmat; 1174 1.1 jmcneill error = bus_dmamap_create(sc->dmat, TX_DESC_SIZE, 1, TX_DESC_SIZE, 0, 1175 1.1 jmcneill BUS_DMA_WAITOK, &sc->tx.desc_map); 1176 1.1 jmcneill if (error) 1177 1.1 jmcneill return error; 1178 1.1 jmcneill error = bus_dmamem_alloc(sc->dmat, TX_DESC_SIZE, DESC_ALIGN, 0, 1179 1.1 jmcneill &sc->tx.desc_dmaseg, 1, &nsegs, BUS_DMA_WAITOK); 1180 1.1 jmcneill if (error) 1181 1.1 jmcneill return error; 1182 1.1 jmcneill error = bus_dmamem_map(sc->dmat, &sc->tx.desc_dmaseg, nsegs, 1183 1.1 jmcneill TX_DESC_SIZE, (void *)&sc->tx.desc_ring, 1184 1.2 jmcneill BUS_DMA_WAITOK); 1185 1.1 jmcneill if (error) 1186 1.1 jmcneill return error; 1187 1.1 jmcneill error = bus_dmamap_load(sc->dmat, sc->tx.desc_map, sc->tx.desc_ring, 1188 1.1 jmcneill TX_DESC_SIZE, NULL, BUS_DMA_WAITOK); 1189 1.1 jmcneill if (error) 1190 1.1 jmcneill return error; 1191 1.1 jmcneill sc->tx.desc_ring_paddr = sc->tx.desc_map->dm_segs[0].ds_addr; 1192 1.1 jmcneill 1193 1.1 jmcneill memset(sc->tx.desc_ring, 0, TX_DESC_SIZE); 1194 1.1 jmcneill bus_dmamap_sync(sc->dmat, sc->tx.desc_map, 0, TX_DESC_SIZE, 1195 1.2 jmcneill BUS_DMASYNC_PREREAD|BUS_DMASYNC_PREWRITE); 1196 1.1 jmcneill 1197 1.1 jmcneill for (i = 0; i < TX_DESC_COUNT; i++) 1198 1.1 jmcneill sc->tx.desc_ring[i].next = 1199 1.1 jmcneill htole32(sc->tx.desc_ring_paddr + DESC_OFF(TX_NEXT(i))); 1200 1.1 jmcneill 1201 1.1 jmcneill sc->tx.queued = TX_DESC_COUNT; 1202 1.1 jmcneill for (i = 0; i < TX_DESC_COUNT; i++) { 1203 1.1 jmcneill error = bus_dmamap_create(sc->tx.buf_tag, MCLBYTES, 1204 1.1 jmcneill TX_MAX_SEGS, MCLBYTES, 0, BUS_DMA_WAITOK, 1205 1.1 jmcneill &sc->tx.buf_map[i].map); 1206 1.1 jmcneill if (error != 0) { 1207 1.1 jmcneill device_printf(sc->dev, "cannot create TX buffer map\n"); 1208 1.1 jmcneill return error; 1209 1.1 jmcneill } 1210 1.1 jmcneill sunxi_emac_setup_txdesc(sc, i, 0, 0, 0); 1211 1.1 jmcneill } 1212 1.1 jmcneill 1213 1.1 jmcneill /* Setup RX ring */ 1214 1.1 jmcneill sc->rx.buf_tag = sc->rx.desc_tag = sc->dmat; 1215 1.1 jmcneill error = bus_dmamap_create(sc->dmat, RX_DESC_SIZE, 1, RX_DESC_SIZE, 0, 1216 1.1 jmcneill BUS_DMA_WAITOK, &sc->rx.desc_map); 1217 1.1 jmcneill if (error) 1218 1.1 jmcneill return error; 1219 1.1 jmcneill error = bus_dmamem_alloc(sc->dmat, RX_DESC_SIZE, DESC_ALIGN, 0, 1220 1.1 jmcneill &sc->rx.desc_dmaseg, 1, &nsegs, BUS_DMA_WAITOK); 1221 1.1 jmcneill if (error) 1222 1.1 jmcneill return error; 1223 1.1 jmcneill error = bus_dmamem_map(sc->dmat, &sc->rx.desc_dmaseg, nsegs, 1224 1.1 jmcneill RX_DESC_SIZE, (void *)&sc->rx.desc_ring, 1225 1.2 jmcneill BUS_DMA_WAITOK); 1226 1.1 jmcneill if (error) 1227 1.1 jmcneill return error; 1228 1.1 jmcneill error = bus_dmamap_load(sc->dmat, sc->rx.desc_map, sc->rx.desc_ring, 1229 1.1 jmcneill RX_DESC_SIZE, NULL, BUS_DMA_WAITOK); 1230 1.1 jmcneill if (error) 1231 1.1 jmcneill return error; 1232 1.1 jmcneill sc->rx.desc_ring_paddr = sc->rx.desc_map->dm_segs[0].ds_addr; 1233 1.1 jmcneill 1234 1.1 jmcneill memset(sc->rx.desc_ring, 0, RX_DESC_SIZE); 1235 1.1 jmcneill 1236 1.1 jmcneill for (i = 0; i < RX_DESC_COUNT; i++) { 1237 1.1 jmcneill error = bus_dmamap_create(sc->rx.buf_tag, MCLBYTES, 1238 1.1 jmcneill RX_DESC_COUNT, MCLBYTES, 0, BUS_DMA_WAITOK, 1239 1.1 jmcneill &sc->rx.buf_map[i].map); 1240 1.1 jmcneill if (error != 0) { 1241 1.1 jmcneill device_printf(sc->dev, "cannot create RX buffer map\n"); 1242 1.1 jmcneill return error; 1243 1.1 jmcneill } 1244 1.1 jmcneill if ((m = sunxi_emac_alloc_mbufcl(sc)) == NULL) { 1245 1.1 jmcneill device_printf(sc->dev, "cannot allocate RX mbuf\n"); 1246 1.1 jmcneill return ENOMEM; 1247 1.1 jmcneill } 1248 1.1 jmcneill error = sunxi_emac_setup_rxbuf(sc, i, m); 1249 1.1 jmcneill if (error != 0) { 1250 1.1 jmcneill device_printf(sc->dev, "cannot create RX buffer\n"); 1251 1.1 jmcneill return error; 1252 1.1 jmcneill } 1253 1.1 jmcneill } 1254 1.1 jmcneill bus_dmamap_sync(sc->rx.desc_tag, sc->rx.desc_map, 1255 1.1 jmcneill 0, sc->rx.desc_map->dm_mapsize, 1256 1.2 jmcneill BUS_DMASYNC_PREREAD|BUS_DMASYNC_PREWRITE); 1257 1.1 jmcneill 1258 1.1 jmcneill /* Write transmit and receive descriptor base address registers */ 1259 1.1 jmcneill WR4(sc, EMAC_TX_DMA_LIST, sc->tx.desc_ring_paddr); 1260 1.1 jmcneill WR4(sc, EMAC_RX_DMA_LIST, sc->rx.desc_ring_paddr); 1261 1.1 jmcneill 1262 1.1 jmcneill return 0; 1263 1.1 jmcneill } 1264 1.1 jmcneill 1265 1.1 jmcneill static int 1266 1.1 jmcneill sunxi_emac_get_resources(struct sunxi_emac_softc *sc) 1267 1.1 jmcneill { 1268 1.1 jmcneill const int phandle = sc->phandle; 1269 1.1 jmcneill bus_addr_t addr, size; 1270 1.1 jmcneill u_int n; 1271 1.1 jmcneill 1272 1.1 jmcneill /* Map registers */ 1273 1.1 jmcneill for (n = 0; n < _RES_NITEMS; n++) { 1274 1.1 jmcneill if (fdtbus_get_reg(phandle, n, &addr, &size) != 0) 1275 1.1 jmcneill return ENXIO; 1276 1.1 jmcneill if (bus_space_map(sc->bst, addr, size, 0, &sc->bsh[n]) != 0) 1277 1.1 jmcneill return ENXIO; 1278 1.1 jmcneill } 1279 1.1 jmcneill 1280 1.1 jmcneill /* Get clocks and resets. "ahb" is required, "ephy" is optional. */ 1281 1.1 jmcneill 1282 1.1 jmcneill if ((sc->clk_ahb = fdtbus_clock_get(phandle, "ahb")) == NULL) 1283 1.1 jmcneill return ENXIO; 1284 1.1 jmcneill sc->clk_ephy = fdtbus_clock_get(phandle, "ephy"); 1285 1.1 jmcneill 1286 1.1 jmcneill if ((sc->rst_ahb = fdtbus_reset_get(phandle, "ahb")) == NULL) 1287 1.1 jmcneill return ENXIO; 1288 1.1 jmcneill sc->rst_ahb = fdtbus_reset_get(phandle, "ephy"); 1289 1.1 jmcneill 1290 1.1 jmcneill /* Regulator is optional */ 1291 1.1 jmcneill sc->reg_phy = fdtbus_regulator_acquire(phandle, "phy-supply"); 1292 1.1 jmcneill 1293 1.1 jmcneill /* Reset GPIO is optional */ 1294 1.1 jmcneill sc->pin_reset = fdtbus_gpio_acquire(sc->phandle, 1295 1.1 jmcneill "allwinner,reset-gpio", GPIO_PIN_OUTPUT); 1296 1.1 jmcneill 1297 1.1 jmcneill return 0; 1298 1.1 jmcneill } 1299 1.1 jmcneill 1300 1.1 jmcneill static int 1301 1.1 jmcneill sunxi_emac_match(device_t parent, cfdata_t cf, void *aux) 1302 1.1 jmcneill { 1303 1.1 jmcneill struct fdt_attach_args * const faa = aux; 1304 1.1 jmcneill 1305 1.1 jmcneill return of_match_compat_data(faa->faa_phandle, compat_data); 1306 1.1 jmcneill } 1307 1.1 jmcneill 1308 1.1 jmcneill static void 1309 1.1 jmcneill sunxi_emac_attach(device_t parent, device_t self, void *aux) 1310 1.1 jmcneill { 1311 1.1 jmcneill struct fdt_attach_args * const faa = aux; 1312 1.1 jmcneill struct sunxi_emac_softc * const sc = device_private(self); 1313 1.1 jmcneill const int phandle = faa->faa_phandle; 1314 1.1 jmcneill struct mii_data *mii = &sc->mii; 1315 1.1 jmcneill struct ifnet *ifp = &sc->ec.ec_if; 1316 1.1 jmcneill uint8_t eaddr[ETHER_ADDR_LEN]; 1317 1.1 jmcneill char intrstr[128]; 1318 1.1 jmcneill 1319 1.1 jmcneill sc->dev = self; 1320 1.1 jmcneill sc->phandle = phandle; 1321 1.1 jmcneill sc->bst = faa->faa_bst; 1322 1.1 jmcneill sc->dmat = faa->faa_dmat; 1323 1.1 jmcneill sc->type = of_search_compatible(phandle, compat_data)->data; 1324 1.1 jmcneill 1325 1.1 jmcneill if (sunxi_emac_get_resources(sc) != 0) { 1326 1.1 jmcneill aprint_error(": cannot allocate resources for device\n"); 1327 1.1 jmcneill return; 1328 1.1 jmcneill } 1329 1.1 jmcneill if (!fdtbus_intr_str(phandle, 0, intrstr, sizeof(intrstr))) { 1330 1.1 jmcneill aprint_error(": cannot decode interrupt\n"); 1331 1.1 jmcneill return; 1332 1.1 jmcneill } 1333 1.1 jmcneill 1334 1.1 jmcneill mutex_init(&sc->mtx, MUTEX_DEFAULT, IPL_NET); 1335 1.1 jmcneill callout_init(&sc->stat_ch, CALLOUT_FLAGS); 1336 1.1 jmcneill callout_setfunc(&sc->stat_ch, sunxi_emac_tick, sc); 1337 1.1 jmcneill 1338 1.1 jmcneill aprint_naive("\n"); 1339 1.1 jmcneill aprint_normal(": EMAC\n"); 1340 1.1 jmcneill 1341 1.1 jmcneill /* Setup clocks and regulators */ 1342 1.1 jmcneill if (sunxi_emac_setup_resources(sc) != 0) 1343 1.1 jmcneill return; 1344 1.1 jmcneill 1345 1.1 jmcneill /* Read MAC address before resetting the chip */ 1346 1.1 jmcneill sunxi_emac_get_eaddr(sc, eaddr); 1347 1.1 jmcneill 1348 1.1 jmcneill /* Soft reset EMAC core */ 1349 1.1 jmcneill if (sunxi_emac_reset(sc) != 0) 1350 1.1 jmcneill return; 1351 1.1 jmcneill 1352 1.1 jmcneill /* Setup DMA descriptors */ 1353 1.1 jmcneill if (sunxi_emac_setup_dma(sc) != 0) { 1354 1.1 jmcneill aprint_error_dev(self, "failed to setup DMA descriptors\n"); 1355 1.1 jmcneill return; 1356 1.1 jmcneill } 1357 1.1 jmcneill 1358 1.1 jmcneill /* Install interrupt handler */ 1359 1.1 jmcneill sc->ih = fdtbus_intr_establish(phandle, 0, IPL_NET, 1360 1.1 jmcneill FDT_INTR_FLAGS, sunxi_emac_intr, sc); 1361 1.1 jmcneill if (sc->ih == NULL) { 1362 1.1 jmcneill aprint_error_dev(self, "failed to establish interrupt on %s\n", 1363 1.1 jmcneill intrstr); 1364 1.1 jmcneill return; 1365 1.1 jmcneill } 1366 1.1 jmcneill aprint_normal_dev(self, "interrupting on %s\n", intrstr); 1367 1.1 jmcneill 1368 1.1 jmcneill /* Setup ethernet interface */ 1369 1.1 jmcneill ifp->if_softc = sc; 1370 1.1 jmcneill snprintf(ifp->if_xname, IFNAMSIZ, EMAC_IFNAME, device_unit(self)); 1371 1.1 jmcneill ifp->if_flags = IFF_BROADCAST | IFF_SIMPLEX | IFF_MULTICAST; 1372 1.1 jmcneill #ifdef EMAC_MPSAFE 1373 1.1 jmcneill ifp->if_extflags = IFEF_START_MPSAFE; 1374 1.1 jmcneill #endif 1375 1.1 jmcneill ifp->if_start = sunxi_emac_start; 1376 1.1 jmcneill ifp->if_ioctl = sunxi_emac_ioctl; 1377 1.1 jmcneill ifp->if_init = sunxi_emac_init; 1378 1.1 jmcneill ifp->if_stop = sunxi_emac_stop; 1379 1.1 jmcneill ifp->if_capabilities = IFCAP_CSUM_IPv4_Rx | 1380 1.1 jmcneill IFCAP_CSUM_IPv4_Tx | 1381 1.1 jmcneill IFCAP_CSUM_TCPv4_Rx | 1382 1.1 jmcneill IFCAP_CSUM_TCPv4_Tx | 1383 1.1 jmcneill IFCAP_CSUM_UDPv4_Rx | 1384 1.1 jmcneill IFCAP_CSUM_UDPv4_Tx; 1385 1.1 jmcneill IFQ_SET_MAXLEN(&ifp->if_snd, IFQ_MAXLEN); 1386 1.1 jmcneill IFQ_SET_READY(&ifp->if_snd); 1387 1.1 jmcneill 1388 1.1 jmcneill /* 802.1Q VLAN-sized frames are supported */ 1389 1.1 jmcneill sc->ec.ec_capabilities |= ETHERCAP_VLAN_MTU; 1390 1.1 jmcneill 1391 1.1 jmcneill /* Attach MII driver */ 1392 1.1 jmcneill sc->ec.ec_mii = mii; 1393 1.1 jmcneill ifmedia_init(&mii->mii_media, 0, ether_mediachange, ether_mediastatus); 1394 1.1 jmcneill mii->mii_ifp = ifp; 1395 1.1 jmcneill mii->mii_readreg = sunxi_emac_mii_readreg; 1396 1.1 jmcneill mii->mii_writereg = sunxi_emac_mii_writereg; 1397 1.1 jmcneill mii->mii_statchg = sunxi_emac_mii_statchg; 1398 1.1 jmcneill mii_attach(self, mii, 0xffffffff, MII_PHY_ANY, MII_OFFSET_ANY, 1399 1.1 jmcneill MIIF_DOPAUSE); 1400 1.1 jmcneill 1401 1.1 jmcneill if (LIST_EMPTY(&mii->mii_phys)) { 1402 1.1 jmcneill aprint_error_dev(self, "no PHY found!\n"); 1403 1.1 jmcneill return; 1404 1.1 jmcneill } 1405 1.1 jmcneill ifmedia_set(&mii->mii_media, IFM_ETHER|IFM_AUTO); 1406 1.1 jmcneill 1407 1.1 jmcneill /* Attach interface */ 1408 1.1 jmcneill if_attach(ifp); 1409 1.1 jmcneill if_deferred_start_init(ifp, NULL); 1410 1.1 jmcneill 1411 1.1 jmcneill /* Attach ethernet interface */ 1412 1.1 jmcneill ether_ifattach(ifp, eaddr); 1413 1.1 jmcneill } 1414 1.1 jmcneill 1415 1.1 jmcneill CFATTACH_DECL_NEW(sunxi_emac, sizeof(struct sunxi_emac_softc), 1416 1.1 jmcneill sunxi_emac_match, sunxi_emac_attach, NULL, NULL); 1417
Indexes created Wed Oct 22 13:09:56 GMT 2025