/*- * Copyright (c) 2016 Stanislav Galabov. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * * THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * * $FreeBSD$ */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include static int mtkswitch_reg_read(device_t dev, int reg) { struct mtkswitch_softc *sc = device_get_softc(dev); uint32_t val; MTKSWITCH_LOCK_ASSERT(sc, MA_OWNED); val = MTKSWITCH_READ(sc, MTKSWITCH_REG32(reg)); if (MTKSWITCH_IS_HI16(reg)) return (MTKSWITCH_HI16(val)); return (MTKSWITCH_LO16(val)); } static int mtkswitch_reg_write(device_t dev, int reg, int val) { struct mtkswitch_softc *sc = device_get_softc(dev); uint32_t tmp; MTKSWITCH_LOCK_ASSERT(sc, MA_OWNED); tmp = MTKSWITCH_READ(sc, MTKSWITCH_REG32(reg)); if (MTKSWITCH_IS_HI16(reg)) { tmp &= MTKSWITCH_LO16_MSK; tmp |= MTKSWITCH_TO_HI16(val); } else { tmp &= MTKSWITCH_HI16_MSK; tmp |= MTKSWITCH_TO_LO16(val); } MTKSWITCH_WRITE(sc, MTKSWITCH_REG32(reg), tmp); return (0); } static int mtkswitch_phy_read(device_t dev, int phy, int reg) { struct mtkswitch_softc *sc = device_get_softc(dev); int val; MTKSWITCH_LOCK_ASSERT(sc, MA_NOTOWNED); MTKSWITCH_LOCK(sc); while (MTKSWITCH_READ(sc, MTKSWITCH_PCR0) & PCR0_ACTIVE); MTKSWITCH_WRITE(sc, MTKSWITCH_PCR0, PCR0_READ | PCR0_REG(reg) | PCR0_PHY(phy)); while (MTKSWITCH_READ(sc, MTKSWITCH_PCR0) & PCR0_ACTIVE); val = (MTKSWITCH_READ(sc, MTKSWITCH_PCR1) >> PCR1_DATA_OFF) & PCR1_DATA_MASK; MTKSWITCH_UNLOCK(sc); return (val); } static int mtkswitch_phy_write(device_t dev, int phy, int reg, int val) { struct mtkswitch_softc *sc = device_get_softc(dev); MTKSWITCH_LOCK_ASSERT(sc, MA_NOTOWNED); MTKSWITCH_LOCK(sc); while (MTKSWITCH_READ(sc, MTKSWITCH_PCR0) & PCR0_ACTIVE); MTKSWITCH_WRITE(sc, MTKSWITCH_PCR0, PCR0_WRITE | PCR0_REG(reg) | PCR0_PHY(phy) | PCR0_DATA(val)); while (MTKSWITCH_READ(sc, MTKSWITCH_PCR0) & PCR0_ACTIVE); MTKSWITCH_UNLOCK(sc); return (0); } static int mtkswitch_reset(struct mtkswitch_softc *sc) { MTKSWITCH_LOCK_ASSERT(sc, MA_NOTOWNED); MTKSWITCH_LOCK(sc); MTKSWITCH_WRITE(sc, MTKSWITCH_STRT, STRT_RESET); while (MTKSWITCH_READ(sc, MTKSWITCH_STRT) != 0); MTKSWITCH_UNLOCK(sc); return (0); } static int mtkswitch_hw_setup(struct mtkswitch_softc *sc) { /* * TODO: parse the device tree and see if we need to configure * ports, etc. differently. For now we fallback to defaults. */ /* Called early and hence unlocked */ /* Set ports 0-4 to auto negotiation */ MTKSWITCH_WRITE(sc, MTKSWITCH_FPA, FPA_ALL_AUTO); return (0); } static int mtkswitch_hw_global_setup(struct mtkswitch_softc *sc) { /* Called early and hence unlocked */ return (0); } static void mtkswitch_port_init(struct mtkswitch_softc *sc, int port) { /* Called early and hence unlocked */ /* Do nothing - ports are set to auto negotiation in hw_setup */ } static uint32_t mtkswitch_get_port_status(struct mtkswitch_softc *sc, int port) { uint32_t val, res; MTKSWITCH_LOCK_ASSERT(sc, MA_OWNED); res = 0; val = MTKSWITCH_READ(sc, MTKSWITCH_POA); if (val & POA_PRT_LINK(port)) res |= MTKSWITCH_LINK_UP; if (val & POA_PRT_DPX(port)) res |= MTKSWITCH_DUPLEX; if (MTKSWITCH_PORT_IS_100M(port)) { if (val & POA_FE_SPEED(port)) res |= MTKSWITCH_SPEED_100; if (val & POA_FE_XFC(port)) res |= (MTKSWITCH_TXFLOW | MTKSWITCH_RXFLOW); } else { switch (POA_GE_SPEED(val, port)) { case POA_GE_SPEED_10: res |= MTKSWITCH_SPEED_10; break; case POA_GE_SPEED_100: res |= MTKSWITCH_SPEED_100; break; case POA_GE_SPEED_1000: res |= MTKSWITCH_SPEED_1000; break; } val = POA_GE_XFC(val, port); if (val & POA_GE_XFC_TX_MSK) res |= MTKSWITCH_TXFLOW; if (val & POA_GE_XFC_RX_MSK) res |= MTKSWITCH_RXFLOW; } return (res); } static int mtkswitch_atu_flush(struct mtkswitch_softc *sc) { return (0); } static int mtkswitch_port_vlan_setup(struct mtkswitch_softc *sc, etherswitch_port_t *p) { uint32_t val; int err, invert = 0; MTKSWITCH_LOCK_ASSERT(sc, MA_NOTOWNED); MTKSWITCH_LOCK(sc); /* Set the PVID. */ if (p->es_pvid != 0) { err = sc->hal.mtkswitch_vlan_set_pvid(sc, p->es_port, p->es_pvid); if (err != 0) { MTKSWITCH_UNLOCK(sc); return (err); } } /* Mutually exclusive */ if (p->es_flags & ETHERSWITCH_PORT_ADDTAG && p->es_flags & ETHERSWITCH_PORT_STRIPTAG) { invert = 1; } val = MTKSWITCH_READ(sc, MTKSWITCH_SGC2); if (p->es_flags & ETHERSWITCH_PORT_DOUBLE_TAG) val |= SGC2_DOUBLE_TAG_PORT(p->es_port); else val &= ~SGC2_DOUBLE_TAG_PORT(p->es_port); MTKSWITCH_WRITE(sc, MTKSWITCH_SGC2, val); val = MTKSWITCH_READ(sc, MTKSWITCH_POC2); if (invert) { if (val & POC2_UNTAG_PORT(p->es_port)) val &= ~POC2_UNTAG_PORT(p->es_port); else val |= POC2_UNTAG_PORT(p->es_port); } else if (p->es_flags & ETHERSWITCH_PORT_STRIPTAG) val |= POC2_UNTAG_PORT(p->es_port); else val &= ~POC2_UNTAG_PORT(p->es_port); MTKSWITCH_WRITE(sc, MTKSWITCH_POC2, val); MTKSWITCH_UNLOCK(sc); return (0); } static int mtkswitch_port_vlan_get(struct mtkswitch_softc *sc, etherswitch_port_t *p) { uint32_t val; MTKSWITCH_LOCK_ASSERT(sc, MA_NOTOWNED); MTKSWITCH_LOCK(sc); /* Retrieve the PVID */ sc->hal.mtkswitch_vlan_get_pvid(sc, p->es_port, &p->es_pvid); /* Port flags */ p->es_flags = 0; val = MTKSWITCH_READ(sc, MTKSWITCH_SGC2); if (val & SGC2_DOUBLE_TAG_PORT(p->es_port)) p->es_flags |= ETHERSWITCH_PORT_DOUBLE_TAG; val = MTKSWITCH_READ(sc, MTKSWITCH_POC2); if (val & POC2_UNTAG_PORT(p->es_port)) p->es_flags |= ETHERSWITCH_PORT_STRIPTAG; else p->es_flags |= ETHERSWITCH_PORT_ADDTAG; MTKSWITCH_UNLOCK(sc); return (0); } static void mtkswitch_vlan_init_hw(struct mtkswitch_softc *sc) { uint32_t val, vid; int i; MTKSWITCH_LOCK_ASSERT(sc, MA_NOTOWNED); MTKSWITCH_LOCK(sc); /* Reset everything to defaults first */ for (i = 0; i < sc->info.es_nvlangroups; i++) { /* Remove all VLAN members and untag info, if any */ if (i % 4 == 0) { MTKSWITCH_WRITE(sc, MTKSWITCH_VMSC(i), 0); if (sc->sc_switchtype != MTK_SWITCH_RT3050) MTKSWITCH_WRITE(sc, MTKSWITCH_VUB(i), 0); } /* Reset to default VIDs */ val = MTKSWITCH_READ(sc, MTKSWITCH_VLANI(i)); val &= ~(VLANI_MASK << VLANI_OFF(i)); val |= ((i + 1) << VLANI_OFF(i)); MTKSWITCH_WRITE(sc, MTKSWITCH_VLANI(i), val); } /* Now, add all ports as untagged members to VLAN1 */ vid = 0; val = MTKSWITCH_READ(sc, MTKSWITCH_VMSC(vid)); val &= ~(VMSC_MASK << VMSC_OFF(vid)); val |= (((1<numports)-1) << VMSC_OFF(vid)); MTKSWITCH_WRITE(sc, MTKSWITCH_VMSC(vid), val); if (sc->sc_switchtype != MTK_SWITCH_RT3050) { val = MTKSWITCH_READ(sc, MTKSWITCH_VUB(vid)); val &= ~(VUB_MASK << VUB_OFF(vid)); val |= (((1<numports)-1) << VUB_OFF(vid)); MTKSWITCH_WRITE(sc, MTKSWITCH_VUB(vid), val); } val = MTKSWITCH_READ(sc, MTKSWITCH_POC2); if (sc->sc_switchtype != MTK_SWITCH_RT3050) val |= POC2_UNTAG_VLAN; val |= ((1<numports)-1); MTKSWITCH_WRITE(sc, MTKSWITCH_POC2, val); /* only the first vlangroup is valid */ sc->valid_vlans = (1<<0); /* Set all port PVIDs to 1 */ vid = 1; for (i = 0; i < sc->info.es_nports; i++) { val = MTKSWITCH_READ(sc, MTKSWITCH_PVID(i)); val &= ~(PVID_MASK << PVID_OFF(i)); val |= (vid << PVID_OFF(i)); MTKSWITCH_WRITE(sc, MTKSWITCH_PVID(i), val); } MTKSWITCH_UNLOCK(sc); } static int mtkswitch_vlan_getvgroup(struct mtkswitch_softc *sc, etherswitch_vlangroup_t *v) { uint32_t val; MTKSWITCH_LOCK_ASSERT(sc, MA_NOTOWNED); if ((sc->vlan_mode != ETHERSWITCH_VLAN_DOT1Q) || (v->es_vlangroup > sc->info.es_nvlangroups)) return (EINVAL); /* Reset the member ports. */ v->es_untagged_ports = 0; v->es_member_ports = 0; /* Not supported */ v->es_fid = 0; /* Vlan ID */ v->es_vid = 0; if ((sc->valid_vlans & (1<es_vlangroup)) == 0) return (0); MTKSWITCH_LOCK(sc); v->es_vid = (MTKSWITCH_READ(sc, MTKSWITCH_VLANI(v->es_vlangroup)) >> VLANI_OFF(v->es_vlangroup)) & VLANI_MASK; v->es_vid |= ETHERSWITCH_VID_VALID; /* Member ports */ v->es_member_ports = v->es_untagged_ports = (MTKSWITCH_READ(sc, MTKSWITCH_VMSC(v->es_vlangroup)) >> VMSC_OFF(v->es_vlangroup)) & VMSC_MASK; val = MTKSWITCH_READ(sc, MTKSWITCH_POC2); if ((val & POC2_UNTAG_VLAN) && sc->sc_switchtype != MTK_SWITCH_RT3050) { val = (MTKSWITCH_READ(sc, MTKSWITCH_VUB(v->es_vlangroup)) >> VUB_OFF(v->es_vlangroup)) & VUB_MASK; } else { val &= VUB_MASK; } v->es_untagged_ports &= val; MTKSWITCH_UNLOCK(sc); return (0); } static int mtkswitch_vlan_setvgroup(struct mtkswitch_softc *sc, etherswitch_vlangroup_t *v) { uint32_t val, tmp; if ((sc->vlan_mode != ETHERSWITCH_VLAN_DOT1Q) || (v->es_vlangroup > sc->info.es_nvlangroups)) return (EINVAL); MTKSWITCH_LOCK_ASSERT(sc, MA_NOTOWNED); MTKSWITCH_LOCK(sc); /* First, see if we can accommodate the request at all */ val = MTKSWITCH_READ(sc, MTKSWITCH_POC2); if (sc->sc_switchtype == MTK_SWITCH_RT3050 || (val & POC2_UNTAG_VLAN) == 0) { /* * There are 2 things we can't support in per-port untagging * mode: * 1. Adding a port as an untagged member if the port is not * set up to do untagging. * 2. Adding a port as a tagged member if the port is set up * to do untagging. */ val &= VUB_MASK; /* get all untagged members from the member list */ tmp = v->es_untagged_ports & v->es_member_ports; /* fail if untagged members are not a subset of all members */ if (tmp != v->es_untagged_ports) { /* Cannot accommodate request */ MTKSWITCH_UNLOCK(sc); return (ENOTSUP); } /* fail if any untagged member is set up to do tagging */ if ((tmp & val) != tmp) { /* Cannot accommodate request */ MTKSWITCH_UNLOCK(sc); return (ENOTSUP); } /* now, get the list of all tagged members */ tmp = v->es_member_ports & ~tmp; /* fail if any tagged member is set up to do untagging */ if ((tmp & val) != 0) { /* Cannot accommodate request */ MTKSWITCH_UNLOCK(sc); return (ENOTSUP); } } else { /* Prefer per-Vlan untag and set its members */ val = MTKSWITCH_READ(sc, MTKSWITCH_VUB(v->es_vlangroup)); val &= ~(VUB_MASK << VUB_OFF(v->es_vlangroup)); val |= (((v->es_untagged_ports) & VUB_MASK) << VUB_OFF(v->es_vlangroup)); MTKSWITCH_WRITE(sc, MTKSWITCH_VUB(v->es_vlangroup), val); } /* Set VID */ val = MTKSWITCH_READ(sc, MTKSWITCH_VLANI(v->es_vlangroup)); val &= ~(VLANI_MASK << VLANI_OFF(v->es_vlangroup)); val |= (v->es_vid & VLANI_MASK) << VLANI_OFF(v->es_vlangroup); MTKSWITCH_WRITE(sc, MTKSWITCH_VLANI(v->es_vlangroup), val); /* Set members */ val = MTKSWITCH_READ(sc, MTKSWITCH_VMSC(v->es_vlangroup)); val &= ~(VMSC_MASK << VMSC_OFF(v->es_vlangroup)); val |= (v->es_member_ports << VMSC_OFF(v->es_vlangroup)); MTKSWITCH_WRITE(sc, MTKSWITCH_VMSC(v->es_vlangroup), val); sc->valid_vlans |= (1<es_vlangroup); MTKSWITCH_UNLOCK(sc); return (0); } static int mtkswitch_vlan_get_pvid(struct mtkswitch_softc *sc, int port, int *pvid) { MTKSWITCH_LOCK_ASSERT(sc, MA_OWNED); *pvid = (MTKSWITCH_READ(sc, MTKSWITCH_PVID(port)) >> PVID_OFF(port)) & PVID_MASK; return (0); } static int mtkswitch_vlan_set_pvid(struct mtkswitch_softc *sc, int port, int pvid) { uint32_t val; MTKSWITCH_LOCK_ASSERT(sc, MA_OWNED); val = MTKSWITCH_READ(sc, MTKSWITCH_PVID(port)); val &= ~(PVID_MASK << PVID_OFF(port)); val |= (pvid & PVID_MASK) << PVID_OFF(port); MTKSWITCH_WRITE(sc, MTKSWITCH_PVID(port), val); return (0); } extern void mtk_attach_switch_rt3050(struct mtkswitch_softc *sc) { sc->portmap = 0x7f; sc->phymap = 0x1f; sc->info.es_nports = 7; sc->info.es_vlan_caps = ETHERSWITCH_VLAN_DOT1Q; sc->info.es_nvlangroups = 16; sprintf(sc->info.es_name, "Ralink ESW"); sc->hal.mtkswitch_reset = mtkswitch_reset; sc->hal.mtkswitch_hw_setup = mtkswitch_hw_setup; sc->hal.mtkswitch_hw_global_setup = mtkswitch_hw_global_setup; sc->hal.mtkswitch_port_init = mtkswitch_port_init; sc->hal.mtkswitch_get_port_status = mtkswitch_get_port_status; sc->hal.mtkswitch_atu_flush = mtkswitch_atu_flush; sc->hal.mtkswitch_port_vlan_setup = mtkswitch_port_vlan_setup; sc->hal.mtkswitch_port_vlan_get = mtkswitch_port_vlan_get; sc->hal.mtkswitch_vlan_init_hw = mtkswitch_vlan_init_hw; sc->hal.mtkswitch_vlan_getvgroup = mtkswitch_vlan_getvgroup; sc->hal.mtkswitch_vlan_setvgroup = mtkswitch_vlan_setvgroup; sc->hal.mtkswitch_vlan_get_pvid = mtkswitch_vlan_get_pvid; sc->hal.mtkswitch_vlan_set_pvid = mtkswitch_vlan_set_pvid; sc->hal.mtkswitch_phy_read = mtkswitch_phy_read; sc->hal.mtkswitch_phy_write = mtkswitch_phy_write; sc->hal.mtkswitch_reg_read = mtkswitch_reg_read; sc->hal.mtkswitch_reg_write = mtkswitch_reg_write; }