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FreeBSD hs32.drive.ne.jp 9.1-RELEASE FreeBSD 9.1-RELEASE #1: Wed Jan 14 12:18:08 JST 2015 root@hs32.drive.ne.jp:/sys/amd64/compile/hs32 amd64 |
Current File : //usr/src/sys/x86/x86/msi.c |
/*- * Copyright (c) 2006 Yahoo!, Inc. * All rights reserved. * Written by: John Baldwin <jhb@FreeBSD.org> * * 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 author nor the names of any co-contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * 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. */ /* * Support for PCI Message Signalled Interrupts (MSI). MSI interrupts on * x86 are basically APIC messages that the northbridge delivers directly * to the local APICs as if they had come from an I/O APIC. */ #include <sys/cdefs.h> __FBSDID("$FreeBSD: release/9.1.0/sys/x86/x86/msi.c 214631 2010-11-01 18:18:46Z jhb $"); #include <sys/param.h> #include <sys/bus.h> #include <sys/kernel.h> #include <sys/lock.h> #include <sys/malloc.h> #include <sys/mutex.h> #include <sys/sx.h> #include <sys/systm.h> #include <x86/apicreg.h> #include <machine/cputypes.h> #include <machine/md_var.h> #include <machine/frame.h> #include <machine/intr_machdep.h> #include <machine/apicvar.h> #include <machine/specialreg.h> #include <dev/pci/pcivar.h> /* Fields in address for Intel MSI messages. */ #define MSI_INTEL_ADDR_DEST 0x000ff000 #define MSI_INTEL_ADDR_RH 0x00000008 # define MSI_INTEL_ADDR_RH_ON 0x00000008 # define MSI_INTEL_ADDR_RH_OFF 0x00000000 #define MSI_INTEL_ADDR_DM 0x00000004 # define MSI_INTEL_ADDR_DM_PHYSICAL 0x00000000 # define MSI_INTEL_ADDR_DM_LOGICAL 0x00000004 /* Fields in data for Intel MSI messages. */ #define MSI_INTEL_DATA_TRGRMOD IOART_TRGRMOD /* Trigger mode. */ # define MSI_INTEL_DATA_TRGREDG IOART_TRGREDG # define MSI_INTEL_DATA_TRGRLVL IOART_TRGRLVL #define MSI_INTEL_DATA_LEVEL 0x00004000 /* Polarity. */ # define MSI_INTEL_DATA_DEASSERT 0x00000000 # define MSI_INTEL_DATA_ASSERT 0x00004000 #define MSI_INTEL_DATA_DELMOD IOART_DELMOD /* Delivery mode. */ # define MSI_INTEL_DATA_DELFIXED IOART_DELFIXED # define MSI_INTEL_DATA_DELLOPRI IOART_DELLOPRI # define MSI_INTEL_DATA_DELSMI IOART_DELSMI # define MSI_INTEL_DATA_DELNMI IOART_DELNMI # define MSI_INTEL_DATA_DELINIT IOART_DELINIT # define MSI_INTEL_DATA_DELEXINT IOART_DELEXINT #define MSI_INTEL_DATA_INTVEC IOART_INTVEC /* Interrupt vector. */ /* * Build Intel MSI message and data values from a source. AMD64 systems * seem to be compatible, so we use the same function for both. */ #define INTEL_ADDR(msi) \ (MSI_INTEL_ADDR_BASE | (msi)->msi_cpu << 12 | \ MSI_INTEL_ADDR_RH_OFF | MSI_INTEL_ADDR_DM_PHYSICAL) #define INTEL_DATA(msi) \ (MSI_INTEL_DATA_TRGREDG | MSI_INTEL_DATA_DELFIXED | (msi)->msi_vector) static MALLOC_DEFINE(M_MSI, "msi", "PCI MSI"); /* * MSI sources are bunched into groups. This is because MSI forces * all of the messages to share the address and data registers and * thus certain properties (such as the local APIC ID target on x86). * Each group has a 'first' source that contains information global to * the group. These fields are marked with (g) below. * * Note that local APIC ID is kind of special. Each message will be * assigned an ID by the system; however, a group will use the ID from * the first message. * * For MSI-X, each message is isolated. */ struct msi_intsrc { struct intsrc msi_intsrc; device_t msi_dev; /* Owning device. (g) */ struct msi_intsrc *msi_first; /* First source in group. */ u_int msi_irq; /* IRQ cookie. */ u_int msi_msix; /* MSI-X message. */ u_int msi_vector:8; /* IDT vector. */ u_int msi_cpu:8; /* Local APIC ID. (g) */ u_int msi_count:8; /* Messages in this group. (g) */ u_int msi_maxcount:8; /* Alignment for this group. (g) */ int *msi_irqs; /* Group's IRQ list. (g) */ }; static void msi_create_source(void); static void msi_enable_source(struct intsrc *isrc); static void msi_disable_source(struct intsrc *isrc, int eoi); static void msi_eoi_source(struct intsrc *isrc); static void msi_enable_intr(struct intsrc *isrc); static void msi_disable_intr(struct intsrc *isrc); static int msi_vector(struct intsrc *isrc); static int msi_source_pending(struct intsrc *isrc); static int msi_config_intr(struct intsrc *isrc, enum intr_trigger trig, enum intr_polarity pol); static int msi_assign_cpu(struct intsrc *isrc, u_int apic_id); struct pic msi_pic = { msi_enable_source, msi_disable_source, msi_eoi_source, msi_enable_intr, msi_disable_intr, msi_vector, msi_source_pending, NULL, NULL, msi_config_intr, msi_assign_cpu }; static int msi_enabled; static int msi_last_irq; static struct mtx msi_lock; static void msi_enable_source(struct intsrc *isrc) { } static void msi_disable_source(struct intsrc *isrc, int eoi) { if (eoi == PIC_EOI) lapic_eoi(); } static void msi_eoi_source(struct intsrc *isrc) { lapic_eoi(); } static void msi_enable_intr(struct intsrc *isrc) { struct msi_intsrc *msi = (struct msi_intsrc *)isrc; apic_enable_vector(msi->msi_cpu, msi->msi_vector); } static void msi_disable_intr(struct intsrc *isrc) { struct msi_intsrc *msi = (struct msi_intsrc *)isrc; apic_disable_vector(msi->msi_cpu, msi->msi_vector); } static int msi_vector(struct intsrc *isrc) { struct msi_intsrc *msi = (struct msi_intsrc *)isrc; return (msi->msi_irq); } static int msi_source_pending(struct intsrc *isrc) { return (0); } static int msi_config_intr(struct intsrc *isrc, enum intr_trigger trig, enum intr_polarity pol) { return (ENODEV); } static int msi_assign_cpu(struct intsrc *isrc, u_int apic_id) { struct msi_intsrc *sib, *msi = (struct msi_intsrc *)isrc; int old_vector; u_int old_id; int i, vector; /* * Only allow CPUs to be assigned to the first message for an * MSI group. */ if (msi->msi_first != msi) return (EINVAL); /* Store information to free existing irq. */ old_vector = msi->msi_vector; old_id = msi->msi_cpu; if (old_id == apic_id) return (0); /* Allocate IDT vectors on this cpu. */ if (msi->msi_count > 1) { KASSERT(msi->msi_msix == 0, ("MSI-X message group")); vector = apic_alloc_vectors(apic_id, msi->msi_irqs, msi->msi_count, msi->msi_maxcount); } else vector = apic_alloc_vector(apic_id, msi->msi_irq); if (vector == 0) return (ENOSPC); msi->msi_cpu = apic_id; msi->msi_vector = vector; if (msi->msi_intsrc.is_handlers > 0) apic_enable_vector(msi->msi_cpu, msi->msi_vector); if (bootverbose) printf("msi: Assigning %s IRQ %d to local APIC %u vector %u\n", msi->msi_msix ? "MSI-X" : "MSI", msi->msi_irq, msi->msi_cpu, msi->msi_vector); for (i = 1; i < msi->msi_count; i++) { sib = (struct msi_intsrc *)intr_lookup_source(msi->msi_irqs[i]); sib->msi_cpu = apic_id; sib->msi_vector = vector + i; if (sib->msi_intsrc.is_handlers > 0) apic_enable_vector(sib->msi_cpu, sib->msi_vector); if (bootverbose) printf( "msi: Assigning MSI IRQ %d to local APIC %u vector %u\n", sib->msi_irq, sib->msi_cpu, sib->msi_vector); } BUS_REMAP_INTR(device_get_parent(msi->msi_dev), msi->msi_dev, msi->msi_irq); /* * Free the old vector after the new one is established. This is done * to prevent races where we could miss an interrupt. */ if (msi->msi_intsrc.is_handlers > 0) apic_disable_vector(old_id, old_vector); apic_free_vector(old_id, old_vector, msi->msi_irq); for (i = 1; i < msi->msi_count; i++) { sib = (struct msi_intsrc *)intr_lookup_source(msi->msi_irqs[i]); if (sib->msi_intsrc.is_handlers > 0) apic_disable_vector(old_id, old_vector + i); apic_free_vector(old_id, old_vector + i, msi->msi_irqs[i]); } return (0); } void msi_init(void) { /* Check if we have a supported CPU. */ switch (cpu_vendor_id) { case CPU_VENDOR_INTEL: case CPU_VENDOR_AMD: break; case CPU_VENDOR_CENTAUR: if (CPUID_TO_FAMILY(cpu_id) == 0x6 && CPUID_TO_MODEL(cpu_id) >= 0xf) break; /* FALLTHROUGH */ default: return; } msi_enabled = 1; intr_register_pic(&msi_pic); mtx_init(&msi_lock, "msi", NULL, MTX_DEF); } static void msi_create_source(void) { struct msi_intsrc *msi; u_int irq; mtx_lock(&msi_lock); if (msi_last_irq >= NUM_MSI_INTS) { mtx_unlock(&msi_lock); return; } irq = msi_last_irq + FIRST_MSI_INT; msi_last_irq++; mtx_unlock(&msi_lock); msi = malloc(sizeof(struct msi_intsrc), M_MSI, M_WAITOK | M_ZERO); msi->msi_intsrc.is_pic = &msi_pic; msi->msi_irq = irq; intr_register_source(&msi->msi_intsrc); nexus_add_irq(irq); } /* * Try to allocate 'count' interrupt sources with contiguous IDT values. */ int msi_alloc(device_t dev, int count, int maxcount, int *irqs) { struct msi_intsrc *msi, *fsrc; u_int cpu; int cnt, i, *mirqs, vector; if (!msi_enabled) return (ENXIO); if (count > 1) mirqs = malloc(count * sizeof(*mirqs), M_MSI, M_WAITOK); else mirqs = NULL; again: mtx_lock(&msi_lock); /* Try to find 'count' free IRQs. */ cnt = 0; for (i = FIRST_MSI_INT; i < FIRST_MSI_INT + NUM_MSI_INTS; i++) { msi = (struct msi_intsrc *)intr_lookup_source(i); /* End of allocated sources, so break. */ if (msi == NULL) break; /* If this is a free one, save its IRQ in the array. */ if (msi->msi_dev == NULL) { irqs[cnt] = i; cnt++; if (cnt == count) break; } } /* Do we need to create some new sources? */ if (cnt < count) { /* If we would exceed the max, give up. */ if (i + (count - cnt) > FIRST_MSI_INT + NUM_MSI_INTS) { mtx_unlock(&msi_lock); free(mirqs, M_MSI); return (ENXIO); } mtx_unlock(&msi_lock); /* We need count - cnt more sources. */ while (cnt < count) { msi_create_source(); cnt++; } goto again; } /* Ok, we now have the IRQs allocated. */ KASSERT(cnt == count, ("count mismatch")); /* Allocate 'count' IDT vectors. */ cpu = intr_next_cpu(); vector = apic_alloc_vectors(cpu, irqs, count, maxcount); if (vector == 0) { mtx_unlock(&msi_lock); free(mirqs, M_MSI); return (ENOSPC); } /* Assign IDT vectors and make these messages owned by 'dev'. */ fsrc = (struct msi_intsrc *)intr_lookup_source(irqs[0]); for (i = 0; i < count; i++) { msi = (struct msi_intsrc *)intr_lookup_source(irqs[i]); msi->msi_cpu = cpu; msi->msi_dev = dev; msi->msi_vector = vector + i; if (bootverbose) printf( "msi: routing MSI IRQ %d to local APIC %u vector %u\n", msi->msi_irq, msi->msi_cpu, msi->msi_vector); msi->msi_first = fsrc; KASSERT(msi->msi_intsrc.is_handlers == 0, ("dead MSI has handlers")); } fsrc->msi_count = count; fsrc->msi_maxcount = maxcount; if (count > 1) bcopy(irqs, mirqs, count * sizeof(*mirqs)); fsrc->msi_irqs = mirqs; mtx_unlock(&msi_lock); return (0); } int msi_release(int *irqs, int count) { struct msi_intsrc *msi, *first; int i; mtx_lock(&msi_lock); first = (struct msi_intsrc *)intr_lookup_source(irqs[0]); if (first == NULL) { mtx_unlock(&msi_lock); return (ENOENT); } /* Make sure this isn't an MSI-X message. */ if (first->msi_msix) { mtx_unlock(&msi_lock); return (EINVAL); } /* Make sure this message is allocated to a group. */ if (first->msi_first == NULL) { mtx_unlock(&msi_lock); return (ENXIO); } /* * Make sure this is the start of a group and that we are releasing * the entire group. */ if (first->msi_first != first || first->msi_count != count) { mtx_unlock(&msi_lock); return (EINVAL); } KASSERT(first->msi_dev != NULL, ("unowned group")); /* Clear all the extra messages in the group. */ for (i = 1; i < count; i++) { msi = (struct msi_intsrc *)intr_lookup_source(irqs[i]); KASSERT(msi->msi_first == first, ("message not in group")); KASSERT(msi->msi_dev == first->msi_dev, ("owner mismatch")); msi->msi_first = NULL; msi->msi_dev = NULL; apic_free_vector(msi->msi_cpu, msi->msi_vector, msi->msi_irq); msi->msi_vector = 0; } /* Clear out the first message. */ first->msi_first = NULL; first->msi_dev = NULL; apic_free_vector(first->msi_cpu, first->msi_vector, first->msi_irq); first->msi_vector = 0; first->msi_count = 0; first->msi_maxcount = 0; free(first->msi_irqs, M_MSI); first->msi_irqs = NULL; mtx_unlock(&msi_lock); return (0); } int msi_map(int irq, uint64_t *addr, uint32_t *data) { struct msi_intsrc *msi; mtx_lock(&msi_lock); msi = (struct msi_intsrc *)intr_lookup_source(irq); if (msi == NULL) { mtx_unlock(&msi_lock); return (ENOENT); } /* Make sure this message is allocated to a device. */ if (msi->msi_dev == NULL) { mtx_unlock(&msi_lock); return (ENXIO); } /* * If this message isn't an MSI-X message, make sure it's part * of a group, and switch to the first message in the * group. */ if (!msi->msi_msix) { if (msi->msi_first == NULL) { mtx_unlock(&msi_lock); return (ENXIO); } msi = msi->msi_first; } *addr = INTEL_ADDR(msi); *data = INTEL_DATA(msi); mtx_unlock(&msi_lock); return (0); } int msix_alloc(device_t dev, int *irq) { struct msi_intsrc *msi; u_int cpu; int i, vector; if (!msi_enabled) return (ENXIO); again: mtx_lock(&msi_lock); /* Find a free IRQ. */ for (i = FIRST_MSI_INT; i < FIRST_MSI_INT + NUM_MSI_INTS; i++) { msi = (struct msi_intsrc *)intr_lookup_source(i); /* End of allocated sources, so break. */ if (msi == NULL) break; /* Stop at the first free source. */ if (msi->msi_dev == NULL) break; } /* Do we need to create a new source? */ if (msi == NULL) { /* If we would exceed the max, give up. */ if (i + 1 > FIRST_MSI_INT + NUM_MSI_INTS) { mtx_unlock(&msi_lock); return (ENXIO); } mtx_unlock(&msi_lock); /* Create a new source. */ msi_create_source(); goto again; } /* Allocate an IDT vector. */ cpu = intr_next_cpu(); vector = apic_alloc_vector(cpu, i); if (vector == 0) { mtx_unlock(&msi_lock); return (ENOSPC); } if (bootverbose) printf("msi: routing MSI-X IRQ %d to local APIC %u vector %u\n", msi->msi_irq, cpu, vector); /* Setup source. */ msi->msi_cpu = cpu; msi->msi_dev = dev; msi->msi_first = msi; msi->msi_vector = vector; msi->msi_msix = 1; msi->msi_count = 1; msi->msi_maxcount = 1; msi->msi_irqs = NULL; KASSERT(msi->msi_intsrc.is_handlers == 0, ("dead MSI-X has handlers")); mtx_unlock(&msi_lock); *irq = i; return (0); } int msix_release(int irq) { struct msi_intsrc *msi; mtx_lock(&msi_lock); msi = (struct msi_intsrc *)intr_lookup_source(irq); if (msi == NULL) { mtx_unlock(&msi_lock); return (ENOENT); } /* Make sure this is an MSI-X message. */ if (!msi->msi_msix) { mtx_unlock(&msi_lock); return (EINVAL); } KASSERT(msi->msi_dev != NULL, ("unowned message")); /* Clear out the message. */ msi->msi_first = NULL; msi->msi_dev = NULL; apic_free_vector(msi->msi_cpu, msi->msi_vector, msi->msi_irq); msi->msi_vector = 0; msi->msi_msix = 0; msi->msi_count = 0; msi->msi_maxcount = 0; mtx_unlock(&msi_lock); return (0); }