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/*- * Copyright (c) 2006 Sam Leffler, Errno Consulting * 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, * without modification. * 2. Redistributions in binary form must reproduce at minimum a disclaimer * similar to the "NO WARRANTY" disclaimer below ("Disclaimer") and any * redistribution must be conditioned upon including a substantially * similar Disclaimer requirement for further binary redistribution. * * NO WARRANTY * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS * ``AS IS'' AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT * LIMITED TO, THE IMPLIED WARRANTIES OF NONINFRINGEMENT, MERCHANTIBILITY * AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL * THE COPYRIGHT HOLDERS OR CONTRIBUTORS BE LIABLE FOR 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 DAMAGES. */ /*- * Copyright (c) 2001-2005, Intel Corporation. * 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. * 3. Neither the name of the Intel Corporation nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS 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 COPYRIGHT OWNER 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. */ #include <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/sys/arm/xscale/ixp425/ixp425_qmgr.c 215034 2010-11-09 10:59:09Z brucec $"); /* * Intel XScale Queue Manager support. * * Each IXP4XXX device has a hardware block that implements a priority * queue manager that is shared between the XScale cpu and the backend * devices (such as the NPE). Queues are accessed by reading/writing * special memory locations. The queue contents are mapped into a shared * SRAM region with entries managed in a circular buffer. The XScale * processor can receive interrupts based on queue contents (a condition * code determines when interrupts should be delivered). * * The code here basically replaces the qmgr class in the Intel Access * Library (IAL). */ #include <sys/param.h> #include <sys/systm.h> #include <sys/kernel.h> #include <sys/module.h> #include <sys/time.h> #include <sys/bus.h> #include <sys/resource.h> #include <sys/rman.h> #include <sys/sysctl.h> #include <machine/bus.h> #include <machine/cpu.h> #include <machine/cpufunc.h> #include <machine/resource.h> #include <machine/intr.h> #include <arm/xscale/ixp425/ixp425reg.h> #include <arm/xscale/ixp425/ixp425var.h> #include <arm/xscale/ixp425/ixp425_qmgr.h> /* * State per AQM hw queue. * This structure holds q configuration and dispatch state. */ struct qmgrInfo { int qSizeInWords; /* queue size in words */ uint32_t qOflowStatBitMask; /* overflow status mask */ int qWriteCount; /* queue write count */ bus_size_t qAccRegAddr; /* access register */ bus_size_t qUOStatRegAddr; /* status register */ bus_size_t qConfigRegAddr; /* config register */ int qSizeInEntries; /* queue size in entries */ uint32_t qUflowStatBitMask; /* underflow status mask */ int qReadCount; /* queue read count */ /* XXX union */ uint32_t qStatRegAddr; uint32_t qStatBitsOffset; uint32_t qStat0BitMask; uint32_t qStat1BitMask; uint32_t intRegCheckMask; /* interrupt reg check mask */ void (*cb)(int, void *); /* callback function */ void *cbarg; /* callback argument */ int priority; /* dispatch priority */ #if 0 /* NB: needed only for A0 parts */ u_int statusWordOffset; /* status word offset */ uint32_t statusMask; /* status mask */ uint32_t statusCheckValue; /* status check value */ #endif }; struct ixpqmgr_softc { device_t sc_dev; bus_space_tag_t sc_iot; bus_space_handle_t sc_ioh; struct resource *sc_irq1; /* IRQ resource */ void *sc_ih1; /* interrupt handler */ int sc_rid1; /* resource id for irq */ struct resource *sc_irq2; void *sc_ih2; int sc_rid2; struct qmgrInfo qinfo[IX_QMGR_MAX_NUM_QUEUES]; /* * This array contains a list of queue identifiers ordered by * priority. The table is split logically between queue * identifiers 0-31 and 32-63. To optimize lookups bit masks * are kept for the first-32 and last-32 q's. When the * table needs to be rebuilt mark rebuildTable and it'll * happen after the next interrupt. */ int priorityTable[IX_QMGR_MAX_NUM_QUEUES]; uint32_t lowPriorityTableFirstHalfMask; uint32_t uppPriorityTableFirstHalfMask; int rebuildTable; /* rebuild priorityTable */ uint32_t aqmFreeSramAddress; /* SRAM free space */ }; static int qmgr_debug = 0; SYSCTL_INT(_debug, OID_AUTO, qmgr, CTLFLAG_RW, &qmgr_debug, 0, "IXP4XX Q-Manager debug msgs"); TUNABLE_INT("debug.qmgr", &qmgr_debug); #define DPRINTF(dev, fmt, ...) do { \ if (qmgr_debug) printf(fmt, __VA_ARGS__); \ } while (0) #define DPRINTFn(n, dev, fmt, ...) do { \ if (qmgr_debug >= n) printf(fmt, __VA_ARGS__); \ } while (0) static struct ixpqmgr_softc *ixpqmgr_sc = NULL; static void ixpqmgr_rebuild(struct ixpqmgr_softc *); static void ixpqmgr_intr(void *); static void aqm_int_enable(struct ixpqmgr_softc *sc, int qId); static void aqm_int_disable(struct ixpqmgr_softc *sc, int qId); static void aqm_qcfg(struct ixpqmgr_softc *sc, int qId, u_int ne, u_int nf); static void aqm_srcsel_write(struct ixpqmgr_softc *sc, int qId, int sourceId); static void aqm_reset(struct ixpqmgr_softc *sc); static void dummyCallback(int qId, void *arg) { /* XXX complain */ } static uint32_t aqm_reg_read(struct ixpqmgr_softc *sc, bus_size_t off) { DPRINTFn(9, sc->sc_dev, "%s(0x%x)\n", __func__, (int)off); return bus_space_read_4(sc->sc_iot, sc->sc_ioh, off); } static void aqm_reg_write(struct ixpqmgr_softc *sc, bus_size_t off, uint32_t val) { DPRINTFn(9, sc->sc_dev, "%s(0x%x, 0x%x)\n", __func__, (int)off, val); bus_space_write_4(sc->sc_iot, sc->sc_ioh, off, val); } static int ixpqmgr_probe(device_t dev) { device_set_desc(dev, "IXP4XX Q-Manager"); return 0; } static int ixpqmgr_attach(device_t dev) { struct ixpqmgr_softc *sc = device_get_softc(dev); struct ixp425_softc *sa = device_get_softc(device_get_parent(dev)); int i, err; ixpqmgr_sc = sc; sc->sc_dev = dev; sc->sc_iot = sa->sc_iot; if (bus_space_map(sc->sc_iot, IXP425_QMGR_HWBASE, IXP425_QMGR_SIZE, 0, &sc->sc_ioh)) panic("%s: Cannot map registers", device_get_name(dev)); /* NB: we only use the lower 32 q's */ /* Set up QMGR interrupts */ sc->sc_rid1 = 0; sc->sc_irq1 = bus_alloc_resource(dev, SYS_RES_IRQ, &sc->sc_rid1, IXP425_INT_QUE1_32, IXP425_INT_QUE1_32, 1, RF_ACTIVE); sc->sc_rid2 = 1; sc->sc_irq2 = bus_alloc_resource(dev, SYS_RES_IRQ, &sc->sc_rid2, IXP425_INT_QUE33_64, IXP425_INT_QUE33_64, 1, RF_ACTIVE); if (sc->sc_irq1 == NULL || sc->sc_irq2 == NULL) panic("Unable to allocate the qmgr irqs.\n"); err = bus_setup_intr(dev, sc->sc_irq1, INTR_TYPE_NET | INTR_MPSAFE, NULL, ixpqmgr_intr, NULL, &sc->sc_ih1); if (err) { device_printf(dev, "failed to set up qmgr irq=%d\n", IXP425_INT_QUE1_32); return (ENXIO); } err = bus_setup_intr(dev, sc->sc_irq2, INTR_TYPE_NET | INTR_MPSAFE, NULL, ixpqmgr_intr, NULL, &sc->sc_ih2); if (err) { device_printf(dev, "failed to set up qmgr irq=%d\n", IXP425_INT_QUE33_64); return (ENXIO); } /* NB: softc is pre-zero'd */ for (i = 0; i < IX_QMGR_MAX_NUM_QUEUES; i++) { struct qmgrInfo *qi = &sc->qinfo[i]; qi->cb = dummyCallback; qi->priority = IX_QMGR_Q_PRIORITY_0; /* default priority */ /* * There are two interrupt registers, 32 bits each. One * for the lower queues(0-31) and one for the upper * queues(32-63). Therefore need to mod by 32 i.e the * min upper queue identifier. */ qi->intRegCheckMask = (1<<(i%(IX_QMGR_MIN_QUEUPP_QID))); /* * Register addresses and bit masks are calculated and * stored here to optimize QRead, QWrite and QStatusGet * functions. */ /* AQM Queue access reg addresses, per queue */ qi->qAccRegAddr = IX_QMGR_Q_ACCESS_ADDR_GET(i); qi->qAccRegAddr = IX_QMGR_Q_ACCESS_ADDR_GET(i); qi->qConfigRegAddr = IX_QMGR_Q_CONFIG_ADDR_GET(i); /* AQM Queue lower-group (0-31), only */ if (i < IX_QMGR_MIN_QUEUPP_QID) { /* AQM Q underflow/overflow status reg address, per queue */ qi->qUOStatRegAddr = IX_QMGR_QUEUOSTAT0_OFFSET + ((i / IX_QMGR_QUEUOSTAT_NUM_QUE_PER_WORD) * sizeof(uint32_t)); /* AQM Q underflow status bit masks for status reg per queue */ qi->qUflowStatBitMask = (IX_QMGR_UNDERFLOW_BIT_OFFSET + 1) << ((i & (IX_QMGR_QUEUOSTAT_NUM_QUE_PER_WORD - 1)) * (32 / IX_QMGR_QUEUOSTAT_NUM_QUE_PER_WORD)); /* AQM Q overflow status bit masks for status reg, per queue */ qi->qOflowStatBitMask = (IX_QMGR_OVERFLOW_BIT_OFFSET + 1) << ((i & (IX_QMGR_QUEUOSTAT_NUM_QUE_PER_WORD - 1)) * (32 / IX_QMGR_QUEUOSTAT_NUM_QUE_PER_WORD)); /* AQM Q lower-group (0-31) status reg addresses, per queue */ qi->qStatRegAddr = IX_QMGR_QUELOWSTAT0_OFFSET + ((i / IX_QMGR_QUELOWSTAT_NUM_QUE_PER_WORD) * sizeof(uint32_t)); /* AQM Q lower-group (0-31) status register bit offset */ qi->qStatBitsOffset = (i & (IX_QMGR_QUELOWSTAT_NUM_QUE_PER_WORD - 1)) * (32 / IX_QMGR_QUELOWSTAT_NUM_QUE_PER_WORD); } else { /* AQM Q upper-group (32-63), only */ qi->qUOStatRegAddr = 0; /* XXX */ /* AQM Q upper-group (32-63) Nearly Empty status reg bitmasks */ qi->qStat0BitMask = (1 << (i - IX_QMGR_MIN_QUEUPP_QID)); /* AQM Q upper-group (32-63) Full status register bitmasks */ qi->qStat1BitMask = (1 << (i - IX_QMGR_MIN_QUEUPP_QID)); } } sc->aqmFreeSramAddress = 0x100; /* Q buffer space starts at 0x2100 */ ixpqmgr_rebuild(sc); /* build initial priority table */ aqm_reset(sc); /* reset h/w */ return (0); } static int ixpqmgr_detach(device_t dev) { struct ixpqmgr_softc *sc = device_get_softc(dev); aqm_reset(sc); /* disable interrupts */ bus_teardown_intr(dev, sc->sc_irq1, sc->sc_ih1); bus_teardown_intr(dev, sc->sc_irq2, sc->sc_ih2); bus_release_resource(dev, SYS_RES_IRQ, sc->sc_rid1, sc->sc_irq1); bus_release_resource(dev, SYS_RES_IRQ, sc->sc_rid2, sc->sc_irq2); bus_space_unmap(sc->sc_iot, sc->sc_ioh, IXP425_QMGR_SIZE); return (0); } int ixpqmgr_qconfig(int qId, int qEntries, int ne, int nf, int srcSel, qconfig_hand_t *cb, void *cbarg) { struct ixpqmgr_softc *sc = ixpqmgr_sc; struct qmgrInfo *qi = &sc->qinfo[qId]; DPRINTF(sc->sc_dev, "%s(%u, %u, %u, %u, %u, %p, %p)\n", __func__, qId, qEntries, ne, nf, srcSel, cb, cbarg); /* NB: entry size is always 1 */ qi->qSizeInWords = qEntries; qi->qReadCount = 0; qi->qWriteCount = 0; qi->qSizeInEntries = qEntries; /* XXX kept for code clarity */ if (cb == NULL) { /* Reset to dummy callback */ qi->cb = dummyCallback; qi->cbarg = 0; } else { qi->cb = cb; qi->cbarg = cbarg; } /* Write the config register; NB must be AFTER qinfo setup */ aqm_qcfg(sc, qId, ne, nf); /* * Account for space just allocated to queue. */ sc->aqmFreeSramAddress += (qi->qSizeInWords * sizeof(uint32_t)); /* Set the interrupt source if this queue is in the range 0-31 */ if (qId < IX_QMGR_MIN_QUEUPP_QID) aqm_srcsel_write(sc, qId, srcSel); if (cb != NULL) /* Enable the interrupt */ aqm_int_enable(sc, qId); sc->rebuildTable = TRUE; return 0; /* XXX */ } int ixpqmgr_qwrite(int qId, uint32_t entry) { struct ixpqmgr_softc *sc = ixpqmgr_sc; struct qmgrInfo *qi = &sc->qinfo[qId]; DPRINTFn(3, sc->sc_dev, "%s(%u, 0x%x) writeCount %u size %u\n", __func__, qId, entry, qi->qWriteCount, qi->qSizeInEntries); /* write the entry */ aqm_reg_write(sc, qi->qAccRegAddr, entry); /* NB: overflow is available for lower queues only */ if (qId < IX_QMGR_MIN_QUEUPP_QID) { int qSize = qi->qSizeInEntries; /* * Increment the current number of entries in the queue * and check for overflow . */ if (qi->qWriteCount++ == qSize) { /* check for overflow */ uint32_t status = aqm_reg_read(sc, qi->qUOStatRegAddr); int qPtrs; /* * Read the status twice because the status may * not be immediately ready after the write operation */ if ((status & qi->qOflowStatBitMask) || ((status = aqm_reg_read(sc, qi->qUOStatRegAddr)) & qi->qOflowStatBitMask)) { /* * The queue is full, clear the overflow status bit if set. */ aqm_reg_write(sc, qi->qUOStatRegAddr, status & ~qi->qOflowStatBitMask); qi->qWriteCount = qSize; DPRINTFn(5, sc->sc_dev, "%s(%u, 0x%x) Q full, overflow status cleared\n", __func__, qId, entry); return ENOSPC; } /* * No overflow occured : someone is draining the queue * and the current counter needs to be * updated from the current number of entries in the queue */ /* calculate number of words in q */ qPtrs = aqm_reg_read(sc, qi->qConfigRegAddr); DPRINTFn(2, sc->sc_dev, "%s(%u, 0x%x) Q full, no overflow status, qConfig 0x%x\n", __func__, qId, entry, qPtrs); qPtrs = (qPtrs - (qPtrs >> 7)) & 0x7f; if (qPtrs == 0) { /* * The queue may be full at the time of the * snapshot. Next access will check * the overflow status again. */ qi->qWriteCount = qSize; } else { /* convert the number of words to a number of entries */ qi->qWriteCount = qPtrs & (qSize - 1); } } } return 0; } int ixpqmgr_qread(int qId, uint32_t *entry) { struct ixpqmgr_softc *sc = ixpqmgr_sc; struct qmgrInfo *qi = &sc->qinfo[qId]; bus_size_t off = qi->qAccRegAddr; *entry = aqm_reg_read(sc, off); /* * Reset the current read count : next access to the read function * will force a underflow status check. */ qi->qReadCount = 0; /* Check if underflow occurred on the read */ if (*entry == 0 && qId < IX_QMGR_MIN_QUEUPP_QID) { /* get the queue status */ uint32_t status = aqm_reg_read(sc, qi->qUOStatRegAddr); if (status & qi->qUflowStatBitMask) { /* clear underflow status */ aqm_reg_write(sc, qi->qUOStatRegAddr, status &~ qi->qUflowStatBitMask); return ENOSPC; } } return 0; } int ixpqmgr_qreadm(int qId, uint32_t n, uint32_t *p) { struct ixpqmgr_softc *sc = ixpqmgr_sc; struct qmgrInfo *qi = &sc->qinfo[qId]; uint32_t entry; bus_size_t off = qi->qAccRegAddr; entry = aqm_reg_read(sc, off); while (--n) { if (entry == 0) { /* if we read a NULL entry, stop. We have underflowed */ break; } *p++ = entry; /* store */ entry = aqm_reg_read(sc, off); } *p = entry; /* * Reset the current read count : next access to the read function * will force a underflow status check. */ qi->qReadCount = 0; /* Check if underflow occurred on the read */ if (entry == 0 && qId < IX_QMGR_MIN_QUEUPP_QID) { /* get the queue status */ uint32_t status = aqm_reg_read(sc, qi->qUOStatRegAddr); if (status & qi->qUflowStatBitMask) { /* clear underflow status */ aqm_reg_write(sc, qi->qUOStatRegAddr, status &~ qi->qUflowStatBitMask); return ENOSPC; } } return 0; } uint32_t ixpqmgr_getqstatus(int qId) { #define QLOWSTATMASK \ ((1 << (32 / IX_QMGR_QUELOWSTAT_NUM_QUE_PER_WORD)) - 1) struct ixpqmgr_softc *sc = ixpqmgr_sc; const struct qmgrInfo *qi = &sc->qinfo[qId]; uint32_t status; if (qId < IX_QMGR_MIN_QUEUPP_QID) { /* read the status of a queue in the range 0-31 */ status = aqm_reg_read(sc, qi->qStatRegAddr); /* mask out the status bits relevant only to this queue */ status = (status >> qi->qStatBitsOffset) & QLOWSTATMASK; } else { /* read status of a queue in the range 32-63 */ status = 0; if (aqm_reg_read(sc, IX_QMGR_QUEUPPSTAT0_OFFSET)&qi->qStat0BitMask) status |= IX_QMGR_Q_STATUS_NE_BIT_MASK; /* nearly empty */ if (aqm_reg_read(sc, IX_QMGR_QUEUPPSTAT1_OFFSET)&qi->qStat1BitMask) status |= IX_QMGR_Q_STATUS_F_BIT_MASK; /* full */ } return status; #undef QLOWSTATMASK } uint32_t ixpqmgr_getqconfig(int qId) { struct ixpqmgr_softc *sc = ixpqmgr_sc; return aqm_reg_read(sc, IX_QMGR_Q_CONFIG_ADDR_GET(qId)); } void ixpqmgr_dump(void) { struct ixpqmgr_softc *sc = ixpqmgr_sc; int i, a; /* status registers */ printf("0x%04x: %08x %08x %08x %08x\n" , 0x400 , aqm_reg_read(sc, 0x400) , aqm_reg_read(sc, 0x400+4) , aqm_reg_read(sc, 0x400+8) , aqm_reg_read(sc, 0x400+12) ); printf("0x%04x: %08x %08x %08x %08x\n" , 0x410 , aqm_reg_read(sc, 0x410) , aqm_reg_read(sc, 0x410+4) , aqm_reg_read(sc, 0x410+8) , aqm_reg_read(sc, 0x410+12) ); printf("0x%04x: %08x %08x %08x %08x\n" , 0x420 , aqm_reg_read(sc, 0x420) , aqm_reg_read(sc, 0x420+4) , aqm_reg_read(sc, 0x420+8) , aqm_reg_read(sc, 0x420+12) ); printf("0x%04x: %08x %08x %08x %08x\n" , 0x430 , aqm_reg_read(sc, 0x430) , aqm_reg_read(sc, 0x430+4) , aqm_reg_read(sc, 0x430+8) , aqm_reg_read(sc, 0x430+12) ); /* q configuration registers */ for (a = 0x2000; a < 0x20ff; a += 32) printf("0x%04x: %08x %08x %08x %08x %08x %08x %08x %08x\n" , a , aqm_reg_read(sc, a) , aqm_reg_read(sc, a+4) , aqm_reg_read(sc, a+8) , aqm_reg_read(sc, a+12) , aqm_reg_read(sc, a+16) , aqm_reg_read(sc, a+20) , aqm_reg_read(sc, a+24) , aqm_reg_read(sc, a+28) ); /* allocated SRAM */ for (i = 0x100; i < sc->aqmFreeSramAddress; i += 32) { a = 0x2000 + i; printf("0x%04x: %08x %08x %08x %08x %08x %08x %08x %08x\n" , a , aqm_reg_read(sc, a) , aqm_reg_read(sc, a+4) , aqm_reg_read(sc, a+8) , aqm_reg_read(sc, a+12) , aqm_reg_read(sc, a+16) , aqm_reg_read(sc, a+20) , aqm_reg_read(sc, a+24) , aqm_reg_read(sc, a+28) ); } for (i = 0; i < 16; i++) { printf("Q[%2d] config 0x%08x status 0x%02x " "Q[%2d] config 0x%08x status 0x%02x\n" , i, ixpqmgr_getqconfig(i), ixpqmgr_getqstatus(i) , i+16, ixpqmgr_getqconfig(i+16), ixpqmgr_getqstatus(i+16) ); } } void ixpqmgr_notify_enable(int qId, int srcSel) { struct ixpqmgr_softc *sc = ixpqmgr_sc; #if 0 /* Calculate the checkMask and checkValue for this q */ aqm_calc_statuscheck(sc, qId, srcSel); #endif /* Set the interrupt source if this queue is in the range 0-31 */ if (qId < IX_QMGR_MIN_QUEUPP_QID) aqm_srcsel_write(sc, qId, srcSel); /* Enable the interrupt */ aqm_int_enable(sc, qId); } void ixpqmgr_notify_disable(int qId) { struct ixpqmgr_softc *sc = ixpqmgr_sc; aqm_int_disable(sc, qId); } /* * Rebuild the priority table used by the dispatcher. */ static void ixpqmgr_rebuild(struct ixpqmgr_softc *sc) { int q, pri; int lowQuePriorityTableIndex, uppQuePriorityTableIndex; struct qmgrInfo *qi; sc->lowPriorityTableFirstHalfMask = 0; sc->uppPriorityTableFirstHalfMask = 0; lowQuePriorityTableIndex = 0; uppQuePriorityTableIndex = 32; for (pri = 0; pri < IX_QMGR_NUM_PRIORITY_LEVELS; pri++) { /* low priority q's */ for (q = 0; q < IX_QMGR_MIN_QUEUPP_QID; q++) { qi = &sc->qinfo[q]; if (qi->priority == pri) { /* * Build the priority table bitmask which match the * queues of the first half of the priority table. */ if (lowQuePriorityTableIndex < 16) { sc->lowPriorityTableFirstHalfMask |= qi->intRegCheckMask; } sc->priorityTable[lowQuePriorityTableIndex++] = q; } } /* high priority q's */ for (; q < IX_QMGR_MAX_NUM_QUEUES; q++) { qi = &sc->qinfo[q]; if (qi->priority == pri) { /* * Build the priority table bitmask which match the * queues of the first half of the priority table . */ if (uppQuePriorityTableIndex < 48) { sc->uppPriorityTableFirstHalfMask |= qi->intRegCheckMask; } sc->priorityTable[uppQuePriorityTableIndex++] = q; } } } sc->rebuildTable = FALSE; } /* * Count the number of leading zero bits in a word, * and return the same value than the CLZ instruction. * Note this is similar to the standard ffs function but * it counts zero's from the MSB instead of the LSB. * * word (in) return value (out) * 0x80000000 0 * 0x40000000 1 * ,,, ,,, * 0x00000002 30 * 0x00000001 31 * 0x00000000 32 * * The C version of this function is used as a replacement * for system not providing the equivalent of the CLZ * assembly language instruction. * * Note that this version is big-endian */ static unsigned int _lzcount(uint32_t word) { unsigned int lzcount = 0; if (word == 0) return 32; while ((word & 0x80000000) == 0) { word <<= 1; lzcount++; } return lzcount; } static void ixpqmgr_intr(void *arg) { struct ixpqmgr_softc *sc = ixpqmgr_sc; uint32_t intRegVal; /* Interrupt reg val */ struct qmgrInfo *qi; int priorityTableIndex; /* Priority table index */ int qIndex; /* Current queue being processed */ /* Read the interrupt register */ intRegVal = aqm_reg_read(sc, IX_QMGR_QINTREG0_OFFSET); /* Write back to clear interrupt */ aqm_reg_write(sc, IX_QMGR_QINTREG0_OFFSET, intRegVal); DPRINTFn(5, sc->sc_dev, "%s: ISR0 0x%x ISR1 0x%x\n", __func__, intRegVal, aqm_reg_read(sc, IX_QMGR_QINTREG1_OFFSET)); /* No queue has interrupt register set */ if (intRegVal != 0) { /* get the first queue Id from the interrupt register value */ qIndex = (32 - 1) - _lzcount(intRegVal); DPRINTFn(2, sc->sc_dev, "%s: ISR0 0x%x qIndex %u\n", __func__, intRegVal, qIndex); /* * Optimize for single callback case. */ qi = &sc->qinfo[qIndex]; if (intRegVal == qi->intRegCheckMask) { /* * Only 1 queue event triggered a notification. * Call the callback function for this queue */ qi->cb(qIndex, qi->cbarg); } else { /* * The event is triggered by more than 1 queue, * the queue search will start from the beginning * or the middle of the priority table. * * The search will end when all the bits of the interrupt * register are cleared. There is no need to maintain * a separate value and test it at each iteration. */ if (intRegVal & sc->lowPriorityTableFirstHalfMask) { priorityTableIndex = 0; } else { priorityTableIndex = 16; } /* * Iterate over the priority table until all the bits * of the interrupt register are cleared. */ do { qIndex = sc->priorityTable[priorityTableIndex++]; qi = &sc->qinfo[qIndex]; /* If this queue caused this interrupt to be raised */ if (intRegVal & qi->intRegCheckMask) { /* Call the callback function for this queue */ qi->cb(qIndex, qi->cbarg); /* Clear the interrupt register bit */ intRegVal &= ~qi->intRegCheckMask; } } while (intRegVal); } } /* Rebuild the priority table if needed */ if (sc->rebuildTable) ixpqmgr_rebuild(sc); } #if 0 /* * Generate the parameters used to check if a Q's status matches * the specified source select. We calculate which status word * to check (statusWordOffset), the value to check the status * against (statusCheckValue) and the mask (statusMask) to mask * out all but the bits to check in the status word. */ static void aqm_calc_statuscheck(int qId, IxQMgrSourceId srcSel) { struct qmgrInfo *qi = &qinfo[qId]; uint32_t shiftVal; if (qId < IX_QMGR_MIN_QUEUPP_QID) { switch (srcSel) { case IX_QMGR_Q_SOURCE_ID_E: qi->statusCheckValue = IX_QMGR_Q_STATUS_E_BIT_MASK; qi->statusMask = IX_QMGR_Q_STATUS_E_BIT_MASK; break; case IX_QMGR_Q_SOURCE_ID_NE: qi->statusCheckValue = IX_QMGR_Q_STATUS_NE_BIT_MASK; qi->statusMask = IX_QMGR_Q_STATUS_NE_BIT_MASK; break; case IX_QMGR_Q_SOURCE_ID_NF: qi->statusCheckValue = IX_QMGR_Q_STATUS_NF_BIT_MASK; qi->statusMask = IX_QMGR_Q_STATUS_NF_BIT_MASK; break; case IX_QMGR_Q_SOURCE_ID_F: qi->statusCheckValue = IX_QMGR_Q_STATUS_F_BIT_MASK; qi->statusMask = IX_QMGR_Q_STATUS_F_BIT_MASK; break; case IX_QMGR_Q_SOURCE_ID_NOT_E: qi->statusCheckValue = 0; qi->statusMask = IX_QMGR_Q_STATUS_E_BIT_MASK; break; case IX_QMGR_Q_SOURCE_ID_NOT_NE: qi->statusCheckValue = 0; qi->statusMask = IX_QMGR_Q_STATUS_NE_BIT_MASK; break; case IX_QMGR_Q_SOURCE_ID_NOT_NF: qi->statusCheckValue = 0; qi->statusMask = IX_QMGR_Q_STATUS_NF_BIT_MASK; break; case IX_QMGR_Q_SOURCE_ID_NOT_F: qi->statusCheckValue = 0; qi->statusMask = IX_QMGR_Q_STATUS_F_BIT_MASK; break; default: /* Should never hit */ IX_OSAL_ASSERT(0); break; } /* One nibble of status per queue so need to shift the * check value and mask out to the correct position. */ shiftVal = (qId % IX_QMGR_QUELOWSTAT_NUM_QUE_PER_WORD) * IX_QMGR_QUELOWSTAT_BITS_PER_Q; /* Calculate the which status word to check from the qId, * 8 Qs status per word */ qi->statusWordOffset = qId / IX_QMGR_QUELOWSTAT_NUM_QUE_PER_WORD; qi->statusCheckValue <<= shiftVal; qi->statusMask <<= shiftVal; } else { /* One status word */ qi->statusWordOffset = 0; /* Single bits per queue and int source bit hardwired NE, * Qs start at 32. */ qi->statusMask = 1 << (qId - IX_QMGR_MIN_QUEUPP_QID); qi->statusCheckValue = qi->statusMask; } } #endif static void aqm_int_enable(struct ixpqmgr_softc *sc, int qId) { bus_size_t reg; uint32_t v; if (qId < IX_QMGR_MIN_QUEUPP_QID) reg = IX_QMGR_QUEIEREG0_OFFSET; else reg = IX_QMGR_QUEIEREG1_OFFSET; v = aqm_reg_read(sc, reg); aqm_reg_write(sc, reg, v | (1 << (qId % IX_QMGR_MIN_QUEUPP_QID))); DPRINTF(sc->sc_dev, "%s(%u) 0x%lx: 0x%x => 0x%x\n", __func__, qId, reg, v, aqm_reg_read(sc, reg)); } static void aqm_int_disable(struct ixpqmgr_softc *sc, int qId) { bus_size_t reg; uint32_t v; if (qId < IX_QMGR_MIN_QUEUPP_QID) reg = IX_QMGR_QUEIEREG0_OFFSET; else reg = IX_QMGR_QUEIEREG1_OFFSET; v = aqm_reg_read(sc, reg); aqm_reg_write(sc, reg, v &~ (1 << (qId % IX_QMGR_MIN_QUEUPP_QID))); DPRINTF(sc->sc_dev, "%s(%u) 0x%lx: 0x%x => 0x%x\n", __func__, qId, reg, v, aqm_reg_read(sc, reg)); } static unsigned log2(unsigned n) { unsigned count; /* * N.B. this function will return 0 if supplied 0. */ for (count = 0; n/2; count++) n /= 2; return count; } static __inline unsigned toAqmEntrySize(int entrySize) { /* entrySize 1("00"),2("01"),4("10") */ return log2(entrySize); } static __inline unsigned toAqmBufferSize(unsigned bufferSizeInWords) { /* bufferSize 16("00"),32("01),64("10"),128("11") */ return log2(bufferSizeInWords / IX_QMGR_MIN_BUFFER_SIZE); } static __inline unsigned toAqmWatermark(int watermark) { /* * Watermarks 0("000"),1("001"),2("010"),4("011"), * 8("100"),16("101"),32("110"),64("111") */ return log2(2 * watermark); } static void aqm_qcfg(struct ixpqmgr_softc *sc, int qId, u_int ne, u_int nf) { const struct qmgrInfo *qi = &sc->qinfo[qId]; uint32_t qCfg; uint32_t baseAddress; /* Build config register */ qCfg = ((toAqmEntrySize(1) & IX_QMGR_ENTRY_SIZE_MASK) << IX_QMGR_Q_CONFIG_ESIZE_OFFSET) | ((toAqmBufferSize(qi->qSizeInWords) & IX_QMGR_SIZE_MASK) << IX_QMGR_Q_CONFIG_BSIZE_OFFSET); /* baseAddress, calculated relative to start address */ baseAddress = sc->aqmFreeSramAddress; /* base address must be word-aligned */ KASSERT((baseAddress % IX_QMGR_BASE_ADDR_16_WORD_ALIGN) == 0, ("address not word-aligned")); /* Now convert to a 16 word pointer as required by QUECONFIG register */ baseAddress >>= IX_QMGR_BASE_ADDR_16_WORD_SHIFT; qCfg |= baseAddress << IX_QMGR_Q_CONFIG_BADDR_OFFSET; /* set watermarks */ qCfg |= (toAqmWatermark(ne) << IX_QMGR_Q_CONFIG_NE_OFFSET) | (toAqmWatermark(nf) << IX_QMGR_Q_CONFIG_NF_OFFSET); DPRINTF(sc->sc_dev, "%s(%u, %u, %u) 0x%x => 0x%x @ 0x%x\n", __func__, qId, ne, nf, aqm_reg_read(sc, IX_QMGR_Q_CONFIG_ADDR_GET(qId)), qCfg, IX_QMGR_Q_CONFIG_ADDR_GET(qId)); aqm_reg_write(sc, IX_QMGR_Q_CONFIG_ADDR_GET(qId), qCfg); } static void aqm_srcsel_write(struct ixpqmgr_softc *sc, int qId, int sourceId) { bus_size_t off; uint32_t v; /* * Calculate the register offset; multiple queues split across registers */ off = IX_QMGR_INT0SRCSELREG0_OFFSET + ((qId / IX_QMGR_INTSRC_NUM_QUE_PER_WORD) * sizeof(uint32_t)); v = aqm_reg_read(sc, off); if (off == IX_QMGR_INT0SRCSELREG0_OFFSET && qId == 0) { /* Queue 0 at INT0SRCSELREG should not corrupt the value bit-3 */ v |= 0x7; } else { const uint32_t bpq = 32 / IX_QMGR_INTSRC_NUM_QUE_PER_WORD; uint32_t mask; int qshift; qshift = (qId & (IX_QMGR_INTSRC_NUM_QUE_PER_WORD-1)) * bpq; mask = ((1 << bpq) - 1) << qshift; /* q's status mask */ /* merge sourceId */ v = (v &~ mask) | ((sourceId << qshift) & mask); } DPRINTF(sc->sc_dev, "%s(%u, %u) 0x%x => 0x%x @ 0x%lx\n", __func__, qId, sourceId, aqm_reg_read(sc, off), v, off); aqm_reg_write(sc, off, v); } /* * Reset AQM registers to default values. */ static void aqm_reset(struct ixpqmgr_softc *sc) { int i; /* Reset queues 0..31 status registers 0..3 */ aqm_reg_write(sc, IX_QMGR_QUELOWSTAT0_OFFSET, IX_QMGR_QUELOWSTAT_RESET_VALUE); aqm_reg_write(sc, IX_QMGR_QUELOWSTAT1_OFFSET, IX_QMGR_QUELOWSTAT_RESET_VALUE); aqm_reg_write(sc, IX_QMGR_QUELOWSTAT2_OFFSET, IX_QMGR_QUELOWSTAT_RESET_VALUE); aqm_reg_write(sc, IX_QMGR_QUELOWSTAT3_OFFSET, IX_QMGR_QUELOWSTAT_RESET_VALUE); /* Reset underflow/overflow status registers 0..1 */ aqm_reg_write(sc, IX_QMGR_QUEUOSTAT0_OFFSET, IX_QMGR_QUEUOSTAT_RESET_VALUE); aqm_reg_write(sc, IX_QMGR_QUEUOSTAT1_OFFSET, IX_QMGR_QUEUOSTAT_RESET_VALUE); /* Reset queues 32..63 nearly empty status registers */ aqm_reg_write(sc, IX_QMGR_QUEUPPSTAT0_OFFSET, IX_QMGR_QUEUPPSTAT0_RESET_VALUE); /* Reset queues 32..63 full status registers */ aqm_reg_write(sc, IX_QMGR_QUEUPPSTAT1_OFFSET, IX_QMGR_QUEUPPSTAT1_RESET_VALUE); /* Reset int0 status flag source select registers 0..3 */ aqm_reg_write(sc, IX_QMGR_INT0SRCSELREG0_OFFSET, IX_QMGR_INT0SRCSELREG_RESET_VALUE); aqm_reg_write(sc, IX_QMGR_INT0SRCSELREG1_OFFSET, IX_QMGR_INT0SRCSELREG_RESET_VALUE); aqm_reg_write(sc, IX_QMGR_INT0SRCSELREG2_OFFSET, IX_QMGR_INT0SRCSELREG_RESET_VALUE); aqm_reg_write(sc, IX_QMGR_INT0SRCSELREG3_OFFSET, IX_QMGR_INT0SRCSELREG_RESET_VALUE); /* Reset queue interrupt enable register 0..1 */ aqm_reg_write(sc, IX_QMGR_QUEIEREG0_OFFSET, IX_QMGR_QUEIEREG_RESET_VALUE); aqm_reg_write(sc, IX_QMGR_QUEIEREG1_OFFSET, IX_QMGR_QUEIEREG_RESET_VALUE); /* Reset queue interrupt register 0..1 */ aqm_reg_write(sc, IX_QMGR_QINTREG0_OFFSET, IX_QMGR_QINTREG_RESET_VALUE); aqm_reg_write(sc, IX_QMGR_QINTREG1_OFFSET, IX_QMGR_QINTREG_RESET_VALUE); /* Reset queue configuration words 0..63 */ for (i = 0; i < IX_QMGR_MAX_NUM_QUEUES; i++) aqm_reg_write(sc, sc->qinfo[i].qConfigRegAddr, IX_QMGR_QUECONFIG_RESET_VALUE); /* XXX zero SRAM to simplify debugging */ for (i = IX_QMGR_QUEBUFFER_SPACE_OFFSET; i < IX_QMGR_AQM_SRAM_SIZE_IN_BYTES; i += sizeof(uint32_t)) aqm_reg_write(sc, i, 0); } static device_method_t ixpqmgr_methods[] = { DEVMETHOD(device_probe, ixpqmgr_probe), DEVMETHOD(device_attach, ixpqmgr_attach), DEVMETHOD(device_detach, ixpqmgr_detach), { 0, 0 } }; static driver_t ixpqmgr_driver = { "ixpqmgr", ixpqmgr_methods, sizeof(struct ixpqmgr_softc), }; static devclass_t ixpqmgr_devclass; DRIVER_MODULE(ixpqmgr, ixp, ixpqmgr_driver, ixpqmgr_devclass, 0, 0);