/* * arch/powerpc/kernel/mpic.c * * Driver for interrupt controllers following the OpenPIC standard, the * common implementation beeing IBM's MPIC. This driver also can deal * with various broken implementations of this HW. * * Copyright (C) 2004 Benjamin Herrenschmidt, IBM Corp. * Copyright 2010-2011 Freescale Semiconductor, Inc. * * This file is subject to the terms and conditions of the GNU General Public * License. See the file COPYING in the main directory of this archive * for more details. */ #undef DEBUG #undef DEBUG_IPI #undef DEBUG_IRQ #undef DEBUG_LOW #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "mpic.h" #ifdef DEBUG #define DBG(fmt...) printk(fmt) #else #define DBG(fmt...) #endif static struct mpic *mpics; static struct mpic *mpic_primary; static DEFINE_RAW_SPINLOCK(mpic_lock); #ifdef CONFIG_PPC32 /* XXX for now */ #ifdef CONFIG_IRQ_ALL_CPUS #define distribute_irqs (1) #else #define distribute_irqs (0) #endif #endif #ifdef CONFIG_MPIC_WEIRD static u32 mpic_infos[][MPIC_IDX_END] = { [0] = { /* Original OpenPIC compatible MPIC */ MPIC_GREG_BASE, MPIC_GREG_FEATURE_0, MPIC_GREG_GLOBAL_CONF_0, MPIC_GREG_VENDOR_ID, MPIC_GREG_IPI_VECTOR_PRI_0, MPIC_GREG_IPI_STRIDE, MPIC_GREG_SPURIOUS, MPIC_GREG_TIMER_FREQ, MPIC_TIMER_BASE, MPIC_TIMER_STRIDE, MPIC_TIMER_CURRENT_CNT, MPIC_TIMER_BASE_CNT, MPIC_TIMER_VECTOR_PRI, MPIC_TIMER_DESTINATION, MPIC_CPU_BASE, MPIC_CPU_STRIDE, MPIC_CPU_IPI_DISPATCH_0, MPIC_CPU_IPI_DISPATCH_STRIDE, MPIC_CPU_CURRENT_TASK_PRI, MPIC_CPU_WHOAMI, MPIC_CPU_INTACK, MPIC_CPU_EOI, MPIC_CPU_MCACK, MPIC_IRQ_BASE, MPIC_IRQ_STRIDE, MPIC_IRQ_VECTOR_PRI, MPIC_VECPRI_VECTOR_MASK, MPIC_VECPRI_POLARITY_POSITIVE, MPIC_VECPRI_POLARITY_NEGATIVE, MPIC_VECPRI_SENSE_LEVEL, MPIC_VECPRI_SENSE_EDGE, MPIC_VECPRI_POLARITY_MASK, MPIC_VECPRI_SENSE_MASK, MPIC_IRQ_DESTINATION }, [1] = { /* Tsi108/109 PIC */ TSI108_GREG_BASE, TSI108_GREG_FEATURE_0, TSI108_GREG_GLOBAL_CONF_0, TSI108_GREG_VENDOR_ID, TSI108_GREG_IPI_VECTOR_PRI_0, TSI108_GREG_IPI_STRIDE, TSI108_GREG_SPURIOUS, TSI108_GREG_TIMER_FREQ, TSI108_TIMER_BASE, TSI108_TIMER_STRIDE, TSI108_TIMER_CURRENT_CNT, TSI108_TIMER_BASE_CNT, TSI108_TIMER_VECTOR_PRI, TSI108_TIMER_DESTINATION, TSI108_CPU_BASE, TSI108_CPU_STRIDE, TSI108_CPU_IPI_DISPATCH_0, TSI108_CPU_IPI_DISPATCH_STRIDE, TSI108_CPU_CURRENT_TASK_PRI, TSI108_CPU_WHOAMI, TSI108_CPU_INTACK, TSI108_CPU_EOI, TSI108_CPU_MCACK, TSI108_IRQ_BASE, TSI108_IRQ_STRIDE, TSI108_IRQ_VECTOR_PRI, TSI108_VECPRI_VECTOR_MASK, TSI108_VECPRI_POLARITY_POSITIVE, TSI108_VECPRI_POLARITY_NEGATIVE, TSI108_VECPRI_SENSE_LEVEL, TSI108_VECPRI_SENSE_EDGE, TSI108_VECPRI_POLARITY_MASK, TSI108_VECPRI_SENSE_MASK, TSI108_IRQ_DESTINATION }, }; #define MPIC_INFO(name) mpic->hw_set[MPIC_IDX_##name] #else /* CONFIG_MPIC_WEIRD */ #define MPIC_INFO(name) MPIC_##name #endif /* CONFIG_MPIC_WEIRD */ static inline unsigned int mpic_processor_id(struct mpic *mpic) { unsigned int cpu = 0; if (!(mpic->flags & MPIC_SECONDARY)) cpu = hard_smp_processor_id(); return cpu; } /* * Register accessor functions */ static inline u32 _mpic_read(enum mpic_reg_type type, struct mpic_reg_bank *rb, unsigned int reg) { switch(type) { #ifdef CONFIG_PPC_DCR case mpic_access_dcr: return dcr_read(rb->dhost, reg); #endif case mpic_access_mmio_be: return in_be32(rb->base + (reg >> 2)); case mpic_access_mmio_le: default: return in_le32(rb->base + (reg >> 2)); } } static inline void _mpic_write(enum mpic_reg_type type, struct mpic_reg_bank *rb, unsigned int reg, u32 value) { switch(type) { #ifdef CONFIG_PPC_DCR case mpic_access_dcr: dcr_write(rb->dhost, reg, value); break; #endif case mpic_access_mmio_be: out_be32(rb->base + (reg >> 2), value); break; case mpic_access_mmio_le: default: out_le32(rb->base + (reg >> 2), value); break; } } static inline u32 _mpic_ipi_read(struct mpic *mpic, unsigned int ipi) { enum mpic_reg_type type = mpic->reg_type; unsigned int offset = MPIC_INFO(GREG_IPI_VECTOR_PRI_0) + (ipi * MPIC_INFO(GREG_IPI_STRIDE)); if ((mpic->flags & MPIC_BROKEN_IPI) && type == mpic_access_mmio_le) type = mpic_access_mmio_be; return _mpic_read(type, &mpic->gregs, offset); } static inline void _mpic_ipi_write(struct mpic *mpic, unsigned int ipi, u32 value) { unsigned int offset = MPIC_INFO(GREG_IPI_VECTOR_PRI_0) + (ipi * MPIC_INFO(GREG_IPI_STRIDE)); _mpic_write(mpic->reg_type, &mpic->gregs, offset, value); } static inline u32 _mpic_tm_read(struct mpic *mpic, unsigned int tm) { unsigned int offset = MPIC_INFO(TIMER_VECTOR_PRI) + ((tm & 3) * MPIC_INFO(TIMER_STRIDE)); if (tm >= 4) offset += 0x1000 / 4; return _mpic_read(mpic->reg_type, &mpic->tmregs, offset); } static inline void _mpic_tm_write(struct mpic *mpic, unsigned int tm, u32 value) { unsigned int offset = MPIC_INFO(TIMER_VECTOR_PRI) + ((tm & 3) * MPIC_INFO(TIMER_STRIDE)); if (tm >= 4) offset += 0x1000 / 4; _mpic_write(mpic->reg_type, &mpic->tmregs, offset, value); } static inline u32 _mpic_cpu_read(struct mpic *mpic, unsigned int reg) { unsigned int cpu = mpic_processor_id(mpic); return _mpic_read(mpic->reg_type, &mpic->cpuregs[cpu], reg); } static inline void _mpic_cpu_write(struct mpic *mpic, unsigned int reg, u32 value) { unsigned int cpu = mpic_processor_id(mpic); _mpic_write(mpic->reg_type, &mpic->cpuregs[cpu], reg, value); } static inline u32 _mpic_irq_read(struct mpic *mpic, unsigned int src_no, unsigned int reg) { unsigned int isu = src_no >> mpic->isu_shift; unsigned int idx = src_no & mpic->isu_mask; unsigned int val; val = _mpic_read(mpic->reg_type, &mpic->isus[isu], reg + (idx * MPIC_INFO(IRQ_STRIDE))); #ifdef CONFIG_MPIC_BROKEN_REGREAD if (reg == 0) val = (val & (MPIC_VECPRI_MASK | MPIC_VECPRI_ACTIVITY)) | mpic->isu_reg0_shadow[src_no]; #endif return val; } static inline void _mpic_irq_write(struct mpic *mpic, unsigned int src_no, unsigned int reg, u32 value) { unsigned int isu = src_no >> mpic->isu_shift; unsigned int idx = src_no & mpic->isu_mask; _mpic_write(mpic->reg_type, &mpic->isus[isu], reg + (idx * MPIC_INFO(IRQ_STRIDE)), value); #ifdef CONFIG_MPIC_BROKEN_REGREAD if (reg == 0) mpic->isu_reg0_shadow[src_no] = value & ~(MPIC_VECPRI_MASK | MPIC_VECPRI_ACTIVITY); #endif } #define mpic_read(b,r) _mpic_read(mpic->reg_type,&(b),(r)) #define mpic_write(b,r,v) _mpic_write(mpic->reg_type,&(b),(r),(v)) #define mpic_ipi_read(i) _mpic_ipi_read(mpic,(i)) #define mpic_ipi_write(i,v) _mpic_ipi_write(mpic,(i),(v)) #define mpic_tm_read(i) _mpic_tm_read(mpic,(i)) #define mpic_tm_write(i,v) _mpic_tm_write(mpic,(i),(v)) #define mpic_cpu_read(i) _mpic_cpu_read(mpic,(i)) #define mpic_cpu_write(i,v) _mpic_cpu_write(mpic,(i),(v)) #define mpic_irq_read(s,r) _mpic_irq_read(mpic,(s),(r)) #define mpic_irq_write(s,r,v) _mpic_irq_write(mpic,(s),(r),(v)) /* * Low level utility functions */ static void _mpic_map_mmio(struct mpic *mpic, phys_addr_t phys_addr, struct mpic_reg_bank *rb, unsigned int offset, unsigned int size) { rb->base = ioremap(phys_addr + offset, size); BUG_ON(rb->base == NULL); } #ifdef CONFIG_PPC_DCR static void _mpic_map_dcr(struct mpic *mpic, struct mpic_reg_bank *rb, unsigned int offset, unsigned int size) { phys_addr_t phys_addr = dcr_resource_start(mpic->node, 0); rb->dhost = dcr_map(mpic->node, phys_addr + offset, size); BUG_ON(!DCR_MAP_OK(rb->dhost)); } static inline void mpic_map(struct mpic *mpic, phys_addr_t phys_addr, struct mpic_reg_bank *rb, unsigned int offset, unsigned int size) { if (mpic->flags & MPIC_USES_DCR) _mpic_map_dcr(mpic, rb, offset, size); else _mpic_map_mmio(mpic, phys_addr, rb, offset, size); } #else /* CONFIG_PPC_DCR */ #define mpic_map(m,p,b,o,s) _mpic_map_mmio(m,p,b,o,s) #endif /* !CONFIG_PPC_DCR */ /* Check if we have one of those nice broken MPICs with a flipped endian on * reads from IPI registers */ static void __init mpic_test_broken_ipi(struct mpic *mpic) { u32 r; mpic_write(mpic->gregs, MPIC_INFO(GREG_IPI_VECTOR_PRI_0), MPIC_VECPRI_MASK); r = mpic_read(mpic->gregs, MPIC_INFO(GREG_IPI_VECTOR_PRI_0)); if (r == le32_to_cpu(MPIC_VECPRI_MASK)) { printk(KERN_INFO "mpic: Detected reversed IPI registers\n"); mpic->flags |= MPIC_BROKEN_IPI; } } #ifdef CONFIG_MPIC_U3_HT_IRQS /* Test if an interrupt is sourced from HyperTransport (used on broken U3s) * to force the edge setting on the MPIC and do the ack workaround. */ static inline int mpic_is_ht_interrupt(struct mpic *mpic, unsigned int source) { if (source >= 128 || !mpic->fixups) return 0; return mpic->fixups[source].base != NULL; } static inline void mpic_ht_end_irq(struct mpic *mpic, unsigned int source) { struct mpic_irq_fixup *fixup = &mpic->fixups[source]; if (fixup->applebase) { unsigned int soff = (fixup->index >> 3) & ~3; unsigned int mask = 1U << (fixup->index & 0x1f); writel(mask, fixup->applebase + soff); } else { raw_spin_lock(&mpic->fixup_lock); writeb(0x11 + 2 * fixup->index, fixup->base + 2); writel(fixup->data, fixup->base + 4); raw_spin_unlock(&mpic->fixup_lock); } } static void mpic_startup_ht_interrupt(struct mpic *mpic, unsigned int source, bool level) { struct mpic_irq_fixup *fixup = &mpic->fixups[source]; unsigned long flags; u32 tmp; if (fixup->base == NULL) return; DBG("startup_ht_interrupt(0x%x) index: %d\n", source, fixup->index); raw_spin_lock_irqsave(&mpic->fixup_lock, flags); /* Enable and configure */ writeb(0x10 + 2 * fixup->index, fixup->base + 2); tmp = readl(fixup->base + 4); tmp &= ~(0x23U); if (level) tmp |= 0x22; writel(tmp, fixup->base + 4); raw_spin_unlock_irqrestore(&mpic->fixup_lock, flags); #ifdef CONFIG_PM /* use the lowest bit inverted to the actual HW, * set if this fixup was enabled, clear otherwise */ mpic->save_data[source].fixup_data = tmp | 1; #endif } static void mpic_shutdown_ht_interrupt(struct mpic *mpic, unsigned int source) { struct mpic_irq_fixup *fixup = &mpic->fixups[source]; unsigned long flags; u32 tmp; if (fixup->base == NULL) return; DBG("shutdown_ht_interrupt(0x%x)\n", source); /* Disable */ raw_spin_lock_irqsave(&mpic->fixup_lock, flags); writeb(0x10 + 2 * fixup->index, fixup->base + 2); tmp = readl(fixup->base + 4); tmp |= 1; writel(tmp, fixup->base + 4); raw_spin_unlock_irqrestore(&mpic->fixup_lock, flags); #ifdef CONFIG_PM /* use the lowest bit inverted to the actual HW, * set if this fixup was enabled, clear otherwise */ mpic->save_data[source].fixup_data = tmp & ~1; #endif } #ifdef CONFIG_PCI_MSI static void __init mpic_scan_ht_msi(struct mpic *mpic, u8 __iomem *devbase, unsigned int devfn) { u8 __iomem *base; u8 pos, flags; u64 addr = 0; for (pos = readb(devbase + PCI_CAPABILITY_LIST); pos != 0; pos = readb(devbase + pos + PCI_CAP_LIST_NEXT)) { u8 id = readb(devbase + pos + PCI_CAP_LIST_ID); if (id == PCI_CAP_ID_HT) { id = readb(devbase + pos + 3); if ((id & HT_5BIT_CAP_MASK) == HT_CAPTYPE_MSI_MAPPING) break; } } if (pos == 0) return; base = devbase + pos; flags = readb(base + HT_MSI_FLAGS); if (!(flags & HT_MSI_FLAGS_FIXED)) { addr = readl(base + HT_MSI_ADDR_LO) & HT_MSI_ADDR_LO_MASK; addr = addr | ((u64)readl(base + HT_MSI_ADDR_HI) << 32); } printk(KERN_DEBUG "mpic: - HT:%02x.%x %s MSI mapping found @ 0x%llx\n", PCI_SLOT(devfn), PCI_FUNC(devfn), flags & HT_MSI_FLAGS_ENABLE ? "enabled" : "disabled", addr); if (!(flags & HT_MSI_FLAGS_ENABLE)) writeb(flags | HT_MSI_FLAGS_ENABLE, base + HT_MSI_FLAGS); } #else static void __init mpic_scan_ht_msi(struct mpic *mpic, u8 __iomem *devbase, unsigned int devfn) { return; } #endif static void __init mpic_scan_ht_pic(struct mpic *mpic, u8 __iomem *devbase, unsigned int devfn, u32 vdid) { int i, irq, n; u8 __iomem *base; u32 tmp; u8 pos; for (pos = readb(devbase + PCI_CAPABILITY_LIST); pos != 0; pos = readb(devbase + pos + PCI_CAP_LIST_NEXT)) { u8 id = readb(devbase + pos + PCI_CAP_LIST_ID); if (id == PCI_CAP_ID_HT) { id = readb(devbase + pos + 3); if ((id & HT_5BIT_CAP_MASK) == HT_CAPTYPE_IRQ) break; } } if (pos == 0) return; base = devbase + pos; writeb(0x01, base + 2); n = (readl(base + 4) >> 16) & 0xff; printk(KERN_INFO "mpic: - HT:%02x.%x [0x%02x] vendor %04x device %04x" " has %d irqs\n", devfn >> 3, devfn & 0x7, pos, vdid & 0xffff, vdid >> 16, n + 1); for (i = 0; i <= n; i++) { writeb(0x10 + 2 * i, base + 2); tmp = readl(base + 4); irq = (tmp >> 16) & 0xff; DBG("HT PIC index 0x%x, irq 0x%x, tmp: %08x\n", i, irq, tmp); /* mask it , will be unmasked later */ tmp |= 0x1; writel(tmp, base + 4); mpic->fixups[irq].index = i; mpic->fixups[irq].base = base; /* Apple HT PIC has a non-standard way of doing EOIs */ if ((vdid & 0xffff) == 0x106b) mpic->fixups[irq].applebase = devbase + 0x60; else mpic->fixups[irq].applebase = NULL; writeb(0x11 + 2 * i, base + 2); mpic->fixups[irq].data = readl(base + 4) | 0x80000000; } } static void __init mpic_scan_ht_pics(struct mpic *mpic) { unsigned int devfn; u8 __iomem *cfgspace; printk(KERN_INFO "mpic: Setting up HT PICs workarounds for U3/U4\n"); /* Allocate fixups array */ mpic->fixups = kzalloc(128 * sizeof(*mpic->fixups), GFP_KERNEL); BUG_ON(mpic->fixups == NULL); /* Init spinlock */ raw_spin_lock_init(&mpic->fixup_lock); /* Map U3 config space. We assume all IO-APICs are on the primary bus * so we only need to map 64kB. */ cfgspace = ioremap(0xf2000000, 0x10000); BUG_ON(cfgspace == NULL); /* Now we scan all slots. We do a very quick scan, we read the header * type, vendor ID and device ID only, that's plenty enough */ for (devfn = 0; devfn < 0x100; devfn++) { u8 __iomem *devbase = cfgspace + (devfn << 8); u8 hdr_type = readb(devbase + PCI_HEADER_TYPE); u32 l = readl(devbase + PCI_VENDOR_ID); u16 s; DBG("devfn %x, l: %x\n", devfn, l); /* If no device, skip */ if (l == 0xffffffff || l == 0x00000000 || l == 0x0000ffff || l == 0xffff0000) goto next; /* Check if is supports capability lists */ s = readw(devbase + PCI_STATUS); if (!(s & PCI_STATUS_CAP_LIST)) goto next; mpic_scan_ht_pic(mpic, devbase, devfn, l); mpic_scan_ht_msi(mpic, devbase, devfn); next: /* next device, if function 0 */ if (PCI_FUNC(devfn) == 0 && (hdr_type & 0x80) == 0) devfn += 7; } } #else /* CONFIG_MPIC_U3_HT_IRQS */ static inline int mpic_is_ht_interrupt(struct mpic *mpic, unsigned int source) { return 0; } static void __init mpic_scan_ht_pics(struct mpic *mpic) { } #endif /* CONFIG_MPIC_U3_HT_IRQS */ /* Find an mpic associated with a given linux interrupt */ static struct mpic *mpic_find(unsigned int irq) { if (irq < NUM_ISA_INTERRUPTS) return NULL; return irq_get_chip_data(irq); } /* Determine if the linux irq is an IPI */ static unsigned int mpic_is_ipi(struct mpic *mpic, unsigned int src) { return (src >= mpic->ipi_vecs[0] && src <= mpic->ipi_vecs[3]); } /* Determine if the linux irq is a timer */ static unsigned int mpic_is_tm(struct mpic *mpic, unsigned int src) { return (src >= mpic->timer_vecs[0] && src <= mpic->timer_vecs[7]); } /* Convert a cpu mask from logical to physical cpu numbers. */ static inline u32 mpic_physmask(u32 cpumask) { int i; u32 mask = 0; for (i = 0; i < min(32, NR_CPUS); ++i, cpumask >>= 1) mask |= (cpumask & 1) << get_hard_smp_processor_id(i); return mask; } #ifdef CONFIG_SMP /* Get the mpic structure from the IPI number */ static inline struct mpic * mpic_from_ipi(struct irq_data *d) { return irq_data_get_irq_chip_data(d); } #endif /* Get the mpic structure from the irq number */ static inline struct mpic * mpic_from_irq(unsigned int irq) { return irq_get_chip_data(irq); } /* Get the mpic structure from the irq data */ static inline struct mpic * mpic_from_irq_data(struct irq_data *d) { return irq_data_get_irq_chip_data(d); } /* Send an EOI */ static inline void mpic_eoi(struct mpic *mpic) { mpic_cpu_write(MPIC_INFO(CPU_EOI), 0); (void)mpic_cpu_read(MPIC_INFO(CPU_WHOAMI)); } /* * Linux descriptor level callbacks */ void mpic_unmask_irq(struct irq_data *d) { unsigned int loops = 100000; struct mpic *mpic = mpic_from_irq_data(d); unsigned int src = irqd_to_hwirq(d); DBG("%p: %s: enable_irq: %d (src %d)\n", mpic, mpic->name, d->irq, src); mpic_irq_write(src, MPIC_INFO(IRQ_VECTOR_PRI), mpic_irq_read(src, MPIC_INFO(IRQ_VECTOR_PRI)) & ~MPIC_VECPRI_MASK); /* make sure mask gets to controller before we return to user */ do { if (!loops--) { printk(KERN_ERR "%s: timeout on hwirq %u\n", __func__, src); break; } } while(mpic_irq_read(src, MPIC_INFO(IRQ_VECTOR_PRI)) & MPIC_VECPRI_MASK); } void mpic_mask_irq(struct irq_data *d) { unsigned int loops = 100000; struct mpic *mpic = mpic_from_irq_data(d); unsigned int src = irqd_to_hwirq(d); DBG("%s: disable_irq: %d (src %d)\n", mpic->name, d->irq, src); mpic_irq_write(src, MPIC_INFO(IRQ_VECTOR_PRI), mpic_irq_read(src, MPIC_INFO(IRQ_VECTOR_PRI)) | MPIC_VECPRI_MASK); /* make sure mask gets to controller before we return to user */ do { if (!loops--) { printk(KERN_ERR "%s: timeout on hwirq %u\n", __func__, src); break; } } while(!(mpic_irq_read(src, MPIC_INFO(IRQ_VECTOR_PRI)) & MPIC_VECPRI_MASK)); } void mpic_end_irq(struct irq_data *d) { struct mpic *mpic = mpic_from_irq_data(d); #ifdef DEBUG_IRQ DBG("%s: end_irq: %d\n", mpic->name, d->irq); #endif /* We always EOI on end_irq() even for edge interrupts since that * should only lower the priority, the MPIC should have properly * latched another edge interrupt coming in anyway */ mpic_eoi(mpic); } #ifdef CONFIG_MPIC_U3_HT_IRQS static void mpic_unmask_ht_irq(struct irq_data *d) { struct mpic *mpic = mpic_from_irq_data(d); unsigned int src = irqd_to_hwirq(d); mpic_unmask_irq(d); if (irqd_is_level_type(d)) mpic_ht_end_irq(mpic, src); } static unsigned int mpic_startup_ht_irq(struct irq_data *d) { struct mpic *mpic = mpic_from_irq_data(d); unsigned int src = irqd_to_hwirq(d); mpic_unmask_irq(d); mpic_startup_ht_interrupt(mpic, src, irqd_is_level_type(d)); return 0; } static void mpic_shutdown_ht_irq(struct irq_data *d) { struct mpic *mpic = mpic_from_irq_data(d); unsigned int src = irqd_to_hwirq(d); mpic_shutdown_ht_interrupt(mpic, src); mpic_mask_irq(d); } static void mpic_end_ht_irq(struct irq_data *d) { struct mpic *mpic = mpic_from_irq_data(d); unsigned int src = irqd_to_hwirq(d); #ifdef DEBUG_IRQ DBG("%s: end_irq: %d\n", mpic->name, d->irq); #endif /* We always EOI on end_irq() even for edge interrupts since that * should only lower the priority, the MPIC should have properly * latched another edge interrupt coming in anyway */ if (irqd_is_level_type(d)) mpic_ht_end_irq(mpic, src); mpic_eoi(mpic); } #endif /* !CONFIG_MPIC_U3_HT_IRQS */ #ifdef CONFIG_SMP static void mpic_unmask_ipi(struct irq_data *d) { struct mpic *mpic = mpic_from_ipi(d); unsigned int src = virq_to_hw(d->irq) - mpic->ipi_vecs[0]; DBG("%s: enable_ipi: %d (ipi %d)\n", mpic->name, d->irq, src); mpic_ipi_write(src, mpic_ipi_read(src) & ~MPIC_VECPRI_MASK); } static void mpic_mask_ipi(struct irq_data *d) { /* NEVER disable an IPI... that's just plain wrong! */ } static void mpic_end_ipi(struct irq_data *d) { struct mpic *mpic = mpic_from_ipi(d); /* * IPIs are marked IRQ_PER_CPU. This has the side effect of * preventing the IRQ_PENDING/IRQ_INPROGRESS logic from * applying to them. We EOI them late to avoid re-entering. */ mpic_eoi(mpic); } #endif /* CONFIG_SMP */ static void mpic_unmask_tm(struct irq_data *d) { struct mpic *mpic = mpic_from_irq_data(d); unsigned int src = virq_to_hw(d->irq) - mpic->timer_vecs[0]; DBG("%s: enable_tm: %d (tm %d)\n", mpic->name, d->irq, src); mpic_tm_write(src, mpic_tm_read(src) & ~MPIC_VECPRI_MASK); mpic_tm_read(src); } static void mpic_mask_tm(struct irq_data *d) { struct mpic *mpic = mpic_from_irq_data(d); unsigned int src = virq_to_hw(d->irq) - mpic->timer_vecs[0]; mpic_tm_write(src, mpic_tm_read(src) | MPIC_VECPRI_MASK); mpic_tm_read(src); } int mpic_set_affinity(struct irq_data *d, const struct cpumask *cpumask, bool force) { struct mpic *mpic = mpic_from_irq_data(d); unsigned int src = irqd_to_hwirq(d); if (mpic->flags & MPIC_SINGLE_DEST_CPU) { int cpuid = irq_choose_cpu(cpumask); mpic_irq_write(src, MPIC_INFO(IRQ_DESTINATION), 1 << cpuid); } else { u32 mask = cpumask_bits(cpumask)[0]; mask &= cpumask_bits(cpu_online_mask)[0]; mpic_irq_write(src, MPIC_INFO(IRQ_DESTINATION), mpic_physmask(mask)); } return 0; } static unsigned int mpic_type_to_vecpri(struct mpic *mpic, unsigned int type) { /* Now convert sense value */ switch(type & IRQ_TYPE_SENSE_MASK) { case IRQ_TYPE_EDGE_RISING: return MPIC_INFO(VECPRI_SENSE_EDGE) | MPIC_INFO(VECPRI_POLARITY_POSITIVE); case IRQ_TYPE_EDGE_FALLING: case IRQ_TYPE_EDGE_BOTH: return MPIC_INFO(VECPRI_SENSE_EDGE) | MPIC_INFO(VECPRI_POLARITY_NEGATIVE); case IRQ_TYPE_LEVEL_HIGH: return MPIC_INFO(VECPRI_SENSE_LEVEL) | MPIC_INFO(VECPRI_POLARITY_POSITIVE); case IRQ_TYPE_LEVEL_LOW: default: return MPIC_INFO(VECPRI_SENSE_LEVEL) | MPIC_INFO(VECPRI_POLARITY_NEGATIVE); } } int mpic_set_irq_type(struct irq_data *d, unsigned int flow_type) { struct mpic *mpic = mpic_from_irq_data(d); unsigned int src = irqd_to_hwirq(d); unsigned int vecpri, vold, vnew; DBG("mpic: set_irq_type(mpic:@%p,virq:%d,src:0x%x,type:0x%x)\n", mpic, d->irq, src, flow_type); if (src >= mpic->num_sources) return -EINVAL; if (flow_type == IRQ_TYPE_NONE) if (mpic->senses && src < mpic->senses_count) flow_type = mpic->senses[src]; if (flow_type == IRQ_TYPE_NONE) flow_type = IRQ_TYPE_LEVEL_LOW; irqd_set_trigger_type(d, flow_type); if (mpic_is_ht_interrupt(mpic, src)) vecpri = MPIC_VECPRI_POLARITY_POSITIVE | MPIC_VECPRI_SENSE_EDGE; else vecpri = mpic_type_to_vecpri(mpic, flow_type); vold = mpic_irq_read(src, MPIC_INFO(IRQ_VECTOR_PRI)); vnew = vold & ~(MPIC_INFO(VECPRI_POLARITY_MASK) | MPIC_INFO(VECPRI_SENSE_MASK)); vnew |= vecpri; if (vold != vnew) mpic_irq_write(src, MPIC_INFO(IRQ_VECTOR_PRI), vnew); return IRQ_SET_MASK_OK_NOCOPY; } void mpic_set_vector(unsigned int virq, unsigned int vector) { struct mpic *mpic = mpic_from_irq(virq); unsigned int src = virq_to_hw(virq); unsigned int vecpri; DBG("mpic: set_vector(mpic:@%p,virq:%d,src:%d,vector:0x%x)\n", mpic, virq, src, vector); if (src >= mpic->num_sources) return; vecpri = mpic_irq_read(src, MPIC_INFO(IRQ_VECTOR_PRI)); vecpri = vecpri & ~MPIC_INFO(VECPRI_VECTOR_MASK); vecpri |= vector; mpic_irq_write(src, MPIC_INFO(IRQ_VECTOR_PRI), vecpri); } void mpic_set_destination(unsigned int virq, unsigned int cpuid) { struct mpic *mpic = mpic_from_irq(virq); unsigned int src = virq_to_hw(virq); DBG("mpic: set_destination(mpic:@%p,virq:%d,src:%d,cpuid:0x%x)\n", mpic, virq, src, cpuid); if (src >= mpic->num_sources) return; mpic_irq_write(src, MPIC_INFO(IRQ_DESTINATION), 1 << cpuid); } static struct irq_chip mpic_irq_chip = { .irq_mask = mpic_mask_irq, .irq_unmask = mpic_unmask_irq, .irq_eoi = mpic_end_irq, .irq_set_type = mpic_set_irq_type, }; #ifdef CONFIG_SMP static struct irq_chip mpic_ipi_chip = { .irq_mask = mpic_mask_ipi, .irq_unmask = mpic_unmask_ipi, .irq_eoi = mpic_end_ipi, }; #endif /* CONFIG_SMP */ static struct irq_chip mpic_tm_chip = { .irq_mask = mpic_mask_tm, .irq_unmask = mpic_unmask_tm, .irq_eoi = mpic_end_irq, }; #ifdef CONFIG_MPIC_U3_HT_IRQS static struct irq_chip mpic_irq_ht_chip = { .irq_startup = mpic_startup_ht_irq, .irq_shutdown = mpic_shutdown_ht_irq, .irq_mask = mpic_mask_irq, .irq_unmask = mpic_unmask_ht_irq, .irq_eoi = mpic_end_ht_irq, .irq_set_type = mpic_set_irq_type, }; #endif /* CONFIG_MPIC_U3_HT_IRQS */ static int mpic_host_match(struct irq_domain *h, struct device_node *node) { /* Exact match, unless mpic node is NULL */ return h->of_node == NULL || h->of_node == node; } static int mpic_host_map(struct irq_domain *h, unsigned int virq, irq_hw_number_t hw) { struct mpic *mpic = h->host_data; struct irq_chip *chip; DBG("mpic: map virq %d, hwirq 0x%lx\n", virq, hw); if (hw == mpic->spurious_vec) return -EINVAL; if (mpic->protected && test_bit(hw, mpic->protected)) return -EINVAL; #ifdef CONFIG_SMP else if (hw >= mpic->ipi_vecs[0]) { WARN_ON(mpic->flags & MPIC_SECONDARY); DBG("mpic: mapping as IPI\n"); irq_set_chip_data(virq, mpic); irq_set_chip_and_handler(virq, &mpic->hc_ipi, handle_percpu_irq); return 0; } #endif /* CONFIG_SMP */ if (hw >= mpic->timer_vecs[0] && hw <= mpic->timer_vecs[7]) { WARN_ON(mpic->flags & MPIC_SECONDARY); DBG("mpic: mapping as timer\n"); irq_set_chip_data(virq, mpic); irq_set_chip_and_handler(virq, &mpic->hc_tm, handle_fasteoi_irq); return 0; } if (hw >= mpic->num_sources) return -EINVAL; mpic_msi_reserve_hwirq(mpic, hw); /* Default chip */ chip = &mpic->hc_irq; #ifdef CONFIG_MPIC_U3_HT_IRQS /* Check for HT interrupts, override vecpri */ if (mpic_is_ht_interrupt(mpic, hw)) chip = &mpic->hc_ht_irq; #endif /* CONFIG_MPIC_U3_HT_IRQS */ DBG("mpic: mapping to irq chip @%p\n", chip); irq_set_chip_data(virq, mpic); irq_set_chip_and_handler(virq, chip, handle_fasteoi_irq); /* Set default irq type */ irq_set_irq_type(virq, IRQ_TYPE_NONE); /* If the MPIC was reset, then all vectors have already been * initialized. Otherwise, a per source lazy initialization * is done here. */ if (!mpic_is_ipi(mpic, hw) && (mpic->flags & MPIC_NO_RESET)) { mpic_set_vector(virq, hw); mpic_set_destination(virq, mpic_processor_id(mpic)); mpic_irq_set_priority(virq, 8); } return 0; } static int mpic_host_xlate(struct irq_domain *h, struct device_node *ct, const u32 *intspec, unsigned int intsize, irq_hw_number_t *out_hwirq, unsigned int *out_flags) { struct mpic *mpic = h->host_data; static unsigned char map_mpic_senses[4] = { IRQ_TYPE_EDGE_RISING, IRQ_TYPE_LEVEL_LOW, IRQ_TYPE_LEVEL_HIGH, IRQ_TYPE_EDGE_FALLING, }; *out_hwirq = intspec[0]; if (intsize >= 4 && (mpic->flags & MPIC_FSL)) { /* * Freescale MPIC with extended intspec: * First two cells are as usual. Third specifies * an "interrupt type". Fourth is type-specific data. * * See Documentation/devicetree/bindings/powerpc/fsl/mpic.txt */ switch (intspec[2]) { case 0: case 1: /* no EISR/EIMR support for now, treat as shared IRQ */ break; case 2: if (intspec[0] >= ARRAY_SIZE(mpic->ipi_vecs)) return -EINVAL; *out_hwirq = mpic->ipi_vecs[intspec[0]]; break; case 3: if (intspec[0] >= ARRAY_SIZE(mpic->timer_vecs)) return -EINVAL; *out_hwirq = mpic->timer_vecs[intspec[0]]; break; default: pr_debug("%s: unknown irq type %u\n", __func__, intspec[2]); return -EINVAL; } *out_flags = map_mpic_senses[intspec[1] & 3]; } else if (intsize > 1) { u32 mask = 0x3; /* Apple invented a new race of encoding on machines with * an HT APIC. They encode, among others, the index within * the HT APIC. We don't care about it here since thankfully, * it appears that they have the APIC already properly * configured, and thus our current fixup code that reads the * APIC config works fine. However, we still need to mask out * bits in the specifier to make sure we only get bit 0 which * is the level/edge bit (the only sense bit exposed by Apple), * as their bit 1 means something else. */ if (machine_is(powermac)) mask = 0x1; *out_flags = map_mpic_senses[intspec[1] & mask]; } else *out_flags = IRQ_TYPE_NONE; DBG("mpic: xlate (%d cells: 0x%08x 0x%08x) to line 0x%lx sense 0x%x\n", intsize, intspec[0], intspec[1], *out_hwirq, *out_flags); return 0; } /* IRQ handler for a secondary MPIC cascaded from another IRQ controller */ static void mpic_cascade(unsigned int irq, struct irq_desc *desc) { struct irq_chip *chip = irq_desc_get_chip(desc); struct mpic *mpic = irq_desc_get_handler_data(desc); unsigned int virq; BUG_ON(!(mpic->flags & MPIC_SECONDARY)); virq = mpic_get_one_irq(mpic); if (virq) generic_handle_irq(virq); chip->irq_eoi(&desc->irq_data); } static struct irq_domain_ops mpic_host_ops = { .match = mpic_host_match, .map = mpic_host_map, .xlate = mpic_host_xlate, }; /* * Exported functions */ struct mpic * __init mpic_alloc(struct device_node *node, phys_addr_t phys_addr, unsigned int flags, unsigned int isu_size, unsigned int irq_count, const char *name) { int i, psize, intvec_top; struct mpic *mpic; u32 greg_feature; const char *vers; const u32 *psrc; u32 last_irq; /* Default MPIC search parameters */ static const struct of_device_id __initconst mpic_device_id[] = { { .type = "open-pic", }, { .compatible = "open-pic", }, {}, }; /* * If we were not passed a device-tree node, then perform the default * search for standardized a standardized OpenPIC. */ if (node) { node = of_node_get(node); } else { node = of_find_matching_node(NULL, mpic_device_id); if (!node) return NULL; } /* Pick the physical address from the device tree if unspecified */ if (!phys_addr) { /* Check if it is DCR-based */ if (of_get_property(node, "dcr-reg", NULL)) { flags |= MPIC_USES_DCR; } else { struct resource r; if (of_address_to_resource(node, 0, &r)) goto err_of_node_put; phys_addr = r.start; } } /* Read extra device-tree properties into the flags variable */ if (of_get_property(node, "big-endian", NULL)) flags |= MPIC_BIG_ENDIAN; if (of_get_property(node, "pic-no-reset", NULL)) flags |= MPIC_NO_RESET; if (of_get_property(node, "single-cpu-affinity", NULL)) flags |= MPIC_SINGLE_DEST_CPU; if (of_device_is_compatible(node, "fsl,mpic")) flags |= MPIC_FSL; mpic = kzalloc(sizeof(struct mpic), GFP_KERNEL); if (mpic == NULL) goto err_of_node_put; mpic->name = name; mpic->node = node; mpic->paddr = phys_addr; mpic->flags = flags; mpic->hc_irq = mpic_irq_chip; mpic->hc_irq.name = name; if (!(mpic->flags & MPIC_SECONDARY)) mpic->hc_irq.irq_set_affinity = mpic_set_affinity; #ifdef CONFIG_MPIC_U3_HT_IRQS mpic->hc_ht_irq = mpic_irq_ht_chip; mpic->hc_ht_irq.name = name; if (!(mpic->flags & MPIC_SECONDARY)) mpic->hc_ht_irq.irq_set_affinity = mpic_set_affinity; #endif /* CONFIG_MPIC_U3_HT_IRQS */ #ifdef CONFIG_SMP mpic->hc_ipi = mpic_ipi_chip; mpic->hc_ipi.name = name; #endif /* CONFIG_SMP */ mpic->hc_tm = mpic_tm_chip; mpic->hc_tm.name = name; mpic->num_sources = 0; /* so far */ if (mpic->flags & MPIC_LARGE_VECTORS) intvec_top = 2047; else intvec_top = 255; mpic->timer_vecs[0] = intvec_top - 12; mpic->timer_vecs[1] = intvec_top - 11; mpic->timer_vecs[2] = intvec_top - 10; mpic->timer_vecs[3] = intvec_top - 9; mpic->timer_vecs[4] = intvec_top - 8; mpic->timer_vecs[5] = intvec_top - 7; mpic->timer_vecs[6] = intvec_top - 6; mpic->timer_vecs[7] = intvec_top - 5; mpic->ipi_vecs[0] = intvec_top - 4; mpic->ipi_vecs[1] = intvec_top - 3; mpic->ipi_vecs[2] = intvec_top - 2; mpic->ipi_vecs[3] = intvec_top - 1; mpic->spurious_vec = intvec_top; /* Look for protected sources */ psrc = of_get_property(mpic->node, "protected-sources", &psize); if (psrc) { /* Allocate a bitmap with one bit per interrupt */ unsigned int mapsize = BITS_TO_LONGS(intvec_top + 1); mpic->protected = kzalloc(mapsize*sizeof(long), GFP_KERNEL); BUG_ON(mpic->protected == NULL); for (i = 0; i < psize/sizeof(u32); i++) { if (psrc[i] > intvec_top) continue; __set_bit(psrc[i], mpic->protected); } } #ifdef CONFIG_MPIC_WEIRD mpic->hw_set = mpic_infos[MPIC_GET_REGSET(mpic->flags)]; #endif /* default register type */ if (mpic->flags & MPIC_BIG_ENDIAN) mpic->reg_type = mpic_access_mmio_be; else mpic->reg_type = mpic_access_mmio_le; /* * An MPIC with a "dcr-reg" property must be accessed that way, but * only if the kernel includes DCR support. */ #ifdef CONFIG_PPC_DCR if (mpic->flags & MPIC_USES_DCR) mpic->reg_type = mpic_access_dcr; #else BUG_ON(mpic->flags & MPIC_USES_DCR); #endif /* Map the global registers */ mpic_map(mpic, mpic->paddr, &mpic->gregs, MPIC_INFO(GREG_BASE), 0x1000); mpic_map(mpic, mpic->paddr, &mpic->tmregs, MPIC_INFO(TIMER_BASE), 0x1000); /* Reset */ /* When using a device-node, reset requests are only honored if the MPIC * is allowed to reset. */ if (!(mpic->flags & MPIC_NO_RESET)) { printk(KERN_DEBUG "mpic: Resetting\n"); mpic_write(mpic->gregs, MPIC_INFO(GREG_GLOBAL_CONF_0), mpic_read(mpic->gregs, MPIC_INFO(GREG_GLOBAL_CONF_0)) | MPIC_GREG_GCONF_RESET); while( mpic_read(mpic->gregs, MPIC_INFO(GREG_GLOBAL_CONF_0)) & MPIC_GREG_GCONF_RESET) mb(); } /* CoreInt */ if (mpic->flags & MPIC_ENABLE_COREINT) mpic_write(mpic->gregs, MPIC_INFO(GREG_GLOBAL_CONF_0), mpic_read(mpic->gregs, MPIC_INFO(GREG_GLOBAL_CONF_0)) | MPIC_GREG_GCONF_COREINT); if (mpic->flags & MPIC_ENABLE_MCK) mpic_write(mpic->gregs, MPIC_INFO(GREG_GLOBAL_CONF_0), mpic_read(mpic->gregs, MPIC_INFO(GREG_GLOBAL_CONF_0)) | MPIC_GREG_GCONF_MCK); /* * The MPIC driver will crash if there are more cores than we * can initialize, so we may as well catch that problem here. */ BUG_ON(num_possible_cpus() > MPIC_MAX_CPUS); /* Map the per-CPU registers */ for_each_possible_cpu(i) { unsigned int cpu = get_hard_smp_processor_id(i); mpic_map(mpic, mpic->paddr, &mpic->cpuregs[cpu], MPIC_INFO(CPU_BASE) + cpu * MPIC_INFO(CPU_STRIDE), 0x1000); } /* * Read feature register. For non-ISU MPICs, num sources as well. On * ISU MPICs, sources are counted as ISUs are added */ greg_feature = mpic_read(mpic->gregs, MPIC_INFO(GREG_FEATURE_0)); /* * By default, the last source number comes from the MPIC, but the * device-tree and board support code can override it on buggy hw. * If we get passed an isu_size (multi-isu MPIC) then we use that * as a default instead of the value read from the HW. */ last_irq = (greg_feature & MPIC_GREG_FEATURE_LAST_SRC_MASK) >> MPIC_GREG_FEATURE_LAST_SRC_SHIFT; if (isu_size) last_irq = isu_size * MPIC_MAX_ISU - 1; of_property_read_u32(mpic->node, "last-interrupt-source", &last_irq); if (irq_count) last_irq = irq_count - 1; /* Initialize main ISU if none provided */ if (!isu_size) { isu_size = last_irq + 1; mpic->num_sources = isu_size; mpic_map(mpic, mpic->paddr, &mpic->isus[0], MPIC_INFO(IRQ_BASE), MPIC_INFO(IRQ_STRIDE) * isu_size); } mpic->isu_size = isu_size; mpic->isu_shift = 1 + __ilog2(mpic->isu_size - 1); mpic->isu_mask = (1 << mpic->isu_shift) - 1; mpic->irqhost = irq_domain_add_linear(mpic->node, last_irq + 1, &mpic_host_ops, mpic); /* * FIXME: The code leaks the MPIC object and mappings here; this * is very unlikely to fail but it ought to be fixed anyways. */ if (mpic->irqhost == NULL) return NULL; /* Display version */ switch (greg_feature & MPIC_GREG_FEATURE_VERSION_MASK) { case 1: vers = "1.0"; break; case 2: vers = "1.2"; break; case 3: vers = "1.3"; break; default: vers = ""; break; } printk(KERN_INFO "mpic: Setting up MPIC \"%s\" version %s at %llx," " max %d CPUs\n", name, vers, (unsigned long long)mpic->paddr, num_possible_cpus()); printk(KERN_INFO "mpic: ISU size: %d, shift: %d, mask: %x\n", mpic->isu_size, mpic->isu_shift, mpic->isu_mask); mpic->next = mpics; mpics = mpic; if (!(mpic->flags & MPIC_SECONDARY)) { mpic_primary = mpic; irq_set_default_host(mpic->irqhost); } return mpic; err_of_node_put: of_node_put(node); return NULL; } void __init mpic_assign_isu(struct mpic *mpic, unsigned int isu_num, phys_addr_t paddr) { unsigned int isu_first = isu_num * mpic->isu_size; BUG_ON(isu_num >= MPIC_MAX_ISU); mpic_map(mpic, paddr, &mpic->isus[isu_num], 0, MPIC_INFO(IRQ_STRIDE) * mpic->isu_size); if ((isu_first + mpic->isu_size) > mpic->num_sources) mpic->num_sources = isu_first + mpic->isu_size; } void __init mpic_set_default_senses(struct mpic *mpic, u8 *senses, int count) { mpic->senses = senses; mpic->senses_count = count; } void __init mpic_init(struct mpic *mpic) { int i, cpu; BUG_ON(mpic->num_sources == 0); printk(KERN_INFO "mpic: Initializing for %d sources\n", mpic->num_sources); /* Set current processor priority to max */ mpic_cpu_write(MPIC_INFO(CPU_CURRENT_TASK_PRI), 0xf); /* Initialize timers to our reserved vectors and mask them for now */ for (i = 0; i < 4; i++) { mpic_write(mpic->tmregs, i * MPIC_INFO(TIMER_STRIDE) + MPIC_INFO(TIMER_DESTINATION), 1 << hard_smp_processor_id()); mpic_write(mpic->tmregs, i * MPIC_INFO(TIMER_STRIDE) + MPIC_INFO(TIMER_VECTOR_PRI), MPIC_VECPRI_MASK | (9 << MPIC_VECPRI_PRIORITY_SHIFT) | (mpic->timer_vecs[0] + i)); } /* Initialize IPIs to our reserved vectors and mark them disabled for now */ mpic_test_broken_ipi(mpic); for (i = 0; i < 4; i++) { mpic_ipi_write(i, MPIC_VECPRI_MASK | (10 << MPIC_VECPRI_PRIORITY_SHIFT) | (mpic->ipi_vecs[0] + i)); } /* Do the HT PIC fixups on U3 broken mpic */ DBG("MPIC flags: %x\n", mpic->flags); if ((mpic->flags & MPIC_U3_HT_IRQS) && !(mpic->flags & MPIC_SECONDARY)) { mpic_scan_ht_pics(mpic); mpic_u3msi_init(mpic); } mpic_pasemi_msi_init(mpic); cpu = mpic_processor_id(mpic); if (!(mpic->flags & MPIC_NO_RESET)) { for (i = 0; i < mpic->num_sources; i++) { /* start with vector = source number, and masked */ u32 vecpri = MPIC_VECPRI_MASK | i | (8 << MPIC_VECPRI_PRIORITY_SHIFT); /* check if protected */ if (mpic->protected && test_bit(i, mpic->protected)) continue; /* init hw */ mpic_irq_write(i, MPIC_INFO(IRQ_VECTOR_PRI), vecpri); mpic_irq_write(i, MPIC_INFO(IRQ_DESTINATION), 1 << cpu); } } /* Init spurious vector */ mpic_write(mpic->gregs, MPIC_INFO(GREG_SPURIOUS), mpic->spurious_vec); /* Disable 8259 passthrough, if supported */ if (!(mpic->flags & MPIC_NO_PTHROU_DIS)) mpic_write(mpic->gregs, MPIC_INFO(GREG_GLOBAL_CONF_0), mpic_read(mpic->gregs, MPIC_INFO(GREG_GLOBAL_CONF_0)) | MPIC_GREG_GCONF_8259_PTHROU_DIS); if (mpic->flags & MPIC_NO_BIAS) mpic_write(mpic->gregs, MPIC_INFO(GREG_GLOBAL_CONF_0), mpic_read(mpic->gregs, MPIC_INFO(GREG_GLOBAL_CONF_0)) | MPIC_GREG_GCONF_NO_BIAS); /* Set current processor priority to 0 */ mpic_cpu_write(MPIC_INFO(CPU_CURRENT_TASK_PRI), 0); #ifdef CONFIG_PM /* allocate memory to save mpic state */ mpic->save_data = kmalloc(mpic->num_sources * sizeof(*mpic->save_data), GFP_KERNEL); BUG_ON(mpic->save_data == NULL); #endif /* Check if this MPIC is chained from a parent interrupt controller */ if (mpic->flags & MPIC_SECONDARY) { int virq = irq_of_parse_and_map(mpic->node, 0); if (virq != NO_IRQ) { printk(KERN_INFO "%s: hooking up to IRQ %d\n", mpic->node->full_name, virq); irq_set_handler_data(virq, mpic); irq_set_chained_handler(virq, &mpic_cascade); } } } void __init mpic_set_clk_ratio(struct mpic *mpic, u32 clock_ratio) { u32 v; v = mpic_read(mpic->gregs, MPIC_GREG_GLOBAL_CONF_1); v &= ~MPIC_GREG_GLOBAL_CONF_1_CLK_RATIO_MASK; v |= MPIC_GREG_GLOBAL_CONF_1_CLK_RATIO(clock_ratio); mpic_write(mpic->gregs, MPIC_GREG_GLOBAL_CONF_1, v); } void __init mpic_set_serial_int(struct mpic *mpic, int enable) { unsigned long flags; u32 v; raw_spin_lock_irqsave(&mpic_lock, flags); v = mpic_read(mpic->gregs, MPIC_GREG_GLOBAL_CONF_1); if (enable) v |= MPIC_GREG_GLOBAL_CONF_1_SIE; else v &= ~MPIC_GREG_GLOBAL_CONF_1_SIE; mpic_write(mpic->gregs, MPIC_GREG_GLOBAL_CONF_1, v); raw_spin_unlock_irqrestore(&mpic_lock, flags); } void mpic_irq_set_priority(unsigned int irq, unsigned int pri) { struct mpic *mpic = mpic_find(irq); unsigned int src = virq_to_hw(irq); unsigned long flags; u32 reg; if (!mpic) return; raw_spin_lock_irqsave(&mpic_lock, flags); if (mpic_is_ipi(mpic, src)) { reg = mpic_ipi_read(src - mpic->ipi_vecs[0]) & ~MPIC_VECPRI_PRIORITY_MASK; mpic_ipi_write(src - mpic->ipi_vecs[0], reg | (pri << MPIC_VECPRI_PRIORITY_SHIFT)); } else if (mpic_is_tm(mpic, src)) { reg = mpic_tm_read(src - mpic->timer_vecs[0]) & ~MPIC_VECPRI_PRIORITY_MASK; mpic_tm_write(src - mpic->timer_vecs[0], reg | (pri << MPIC_VECPRI_PRIORITY_SHIFT)); } else { reg = mpic_irq_read(src, MPIC_INFO(IRQ_VECTOR_PRI)) & ~MPIC_VECPRI_PRIORITY_MASK; mpic_irq_write(src, MPIC_INFO(IRQ_VECTOR_PRI), reg | (pri << MPIC_VECPRI_PRIORITY_SHIFT)); } raw_spin_unlock_irqrestore(&mpic_lock, flags); } void mpic_setup_this_cpu(void) { #ifdef CONFIG_SMP struct mpic *mpic = mpic_primary; unsigned long flags; u32 msk = 1 << hard_smp_processor_id(); unsigned int i; BUG_ON(mpic == NULL); DBG("%s: setup_this_cpu(%d)\n", mpic->name, hard_smp_processor_id()); raw_spin_lock_irqsave(&mpic_lock, flags); /* let the mpic know we want intrs. default affinity is 0xffffffff * until changed via /proc. That's how it's done on x86. If we want * it differently, then we should make sure we also change the default * values of irq_desc[].affinity in irq.c. */ if (distribute_irqs) { for (i = 0; i < mpic->num_sources ; i++) mpic_irq_write(i, MPIC_INFO(IRQ_DESTINATION), mpic_irq_read(i, MPIC_INFO(IRQ_DESTINATION)) | msk); } /* Set current processor priority to 0 */ mpic_cpu_write(MPIC_INFO(CPU_CURRENT_TASK_PRI), 0); raw_spin_unlock_irqrestore(&mpic_lock, flags); #endif /* CONFIG_SMP */ } int mpic_cpu_get_priority(void) { struct mpic *mpic = mpic_primary; return mpic_cpu_read(MPIC_INFO(CPU_CURRENT_TASK_PRI)); } void mpic_cpu_set_priority(int prio) { struct mpic *mpic = mpic_primary; prio &= MPIC_CPU_TASKPRI_MASK; mpic_cpu_write(MPIC_INFO(CPU_CURRENT_TASK_PRI), prio); } void mpic_teardown_this_cpu(int secondary) { struct mpic *mpic = mpic_primary; unsigned long flags; u32 msk = 1 << hard_smp_processor_id(); unsigned int i; BUG_ON(mpic == NULL); DBG("%s: teardown_this_cpu(%d)\n", mpic->name, hard_smp_processor_id()); raw_spin_lock_irqsave(&mpic_lock, flags); /* let the mpic know we don't want intrs. */ for (i = 0; i < mpic->num_sources ; i++) mpic_irq_write(i, MPIC_INFO(IRQ_DESTINATION), mpic_irq_read(i, MPIC_INFO(IRQ_DESTINATION)) & ~msk); /* Set current processor priority to max */ mpic_cpu_write(MPIC_INFO(CPU_CURRENT_TASK_PRI), 0xf); /* We need to EOI the IPI since not all platforms reset the MPIC * on boot and new interrupts wouldn't get delivered otherwise. */ mpic_eoi(mpic); raw_spin_unlock_irqrestore(&mpic_lock, flags); } static unsigned int _mpic_get_one_irq(struct mpic *mpic, int reg) { u32 src; src = mpic_cpu_read(reg) & MPIC_INFO(VECPRI_VECTOR_MASK); #ifdef DEBUG_LOW DBG("%s: get_one_irq(reg 0x%x): %d\n", mpic->name, reg, src); #endif if (unlikely(src == mpic->spurious_vec)) { if (mpic->flags & MPIC_SPV_EOI) mpic_eoi(mpic); return NO_IRQ; } if (unlikely(mpic->protected && test_bit(src, mpic->protected))) { printk_ratelimited(KERN_WARNING "%s: Got protected source %d !\n", mpic->name, (int)src); mpic_eoi(mpic); return NO_IRQ; } return irq_linear_revmap(mpic->irqhost, src); } unsigned int mpic_get_one_irq(struct mpic *mpic) { return _mpic_get_one_irq(mpic, MPIC_INFO(CPU_INTACK)); } unsigned int mpic_get_irq(void) { struct mpic *mpic = mpic_primary; BUG_ON(mpic == NULL); return mpic_get_one_irq(mpic); } unsigned int mpic_get_coreint_irq(void) { #ifdef CONFIG_BOOKE struct mpic *mpic = mpic_primary; u32 src; BUG_ON(mpic == NULL); src = mfspr(SPRN_EPR); if (unlikely(src == mpic->spurious_vec)) { if (mpic->flags & MPIC_SPV_EOI) mpic_eoi(mpic); return NO_IRQ; } if (unlikely(mpic->protected && test_bit(src, mpic->protected))) { printk_ratelimited(KERN_WARNING "%s: Got protected source %d !\n", mpic->name, (int)src); return NO_IRQ; } return irq_linear_revmap(mpic->irqhost, src); #else return NO_IRQ; #endif } unsigned int mpic_get_mcirq(void) { struct mpic *mpic = mpic_primary; BUG_ON(mpic == NULL); return _mpic_get_one_irq(mpic, MPIC_INFO(CPU_MCACK)); } #ifdef CONFIG_SMP void mpic_request_ipis(void) { struct mpic *mpic = mpic_primary; int i; BUG_ON(mpic == NULL); printk(KERN_INFO "mpic: requesting IPIs...\n"); for (i = 0; i < 4; i++) { unsigned int vipi = irq_create_mapping(mpic->irqhost, mpic->ipi_vecs[0] + i); if (vipi == NO_IRQ) { printk(KERN_ERR "Failed to map %s\n", smp_ipi_name[i]); continue; } smp_request_message_ipi(vipi, i); } } void smp_mpic_message_pass(int cpu, int msg) { struct mpic *mpic = mpic_primary; u32 physmask; BUG_ON(mpic == NULL); /* make sure we're sending something that translates to an IPI */ if ((unsigned int)msg > 3) { printk("SMP %d: smp_message_pass: unknown msg %d\n", smp_processor_id(), msg); return; } #ifdef DEBUG_IPI DBG("%s: send_ipi(ipi_no: %d)\n", mpic->name, msg); #endif physmask = 1 << get_hard_smp_processor_id(cpu); mpic_cpu_write(MPIC_INFO(CPU_IPI_DISPATCH_0) + msg * MPIC_INFO(CPU_IPI_DISPATCH_STRIDE), physmask); } int __init smp_mpic_probe(void) { int nr_cpus; DBG("smp_mpic_probe()...\n"); nr_cpus = cpumask_weight(cpu_possible_mask); DBG("nr_cpus: %d\n", nr_cpus); if (nr_cpus > 1) mpic_request_ipis(); return nr_cpus; } void __devinit smp_mpic_setup_cpu(int cpu) { mpic_setup_this_cpu(); } void mpic_reset_core(int cpu) { struct mpic *mpic = mpic_primary; u32 pir; int cpuid = get_hard_smp_processor_id(cpu); int i; /* Set target bit for core reset */ pir = mpic_read(mpic->gregs, MPIC_INFO(GREG_PROCESSOR_INIT)); pir |= (1 << cpuid); mpic_write(mpic->gregs, MPIC_INFO(GREG_PROCESSOR_INIT), pir); mpic_read(mpic->gregs, MPIC_INFO(GREG_PROCESSOR_INIT)); /* Restore target bit after reset complete */ pir &= ~(1 << cpuid); mpic_write(mpic->gregs, MPIC_INFO(GREG_PROCESSOR_INIT), pir); mpic_read(mpic->gregs, MPIC_INFO(GREG_PROCESSOR_INIT)); /* Perform 15 EOI on each reset core to clear pending interrupts. * This is required for FSL CoreNet based devices */ if (mpic->flags & MPIC_FSL) { for (i = 0; i < 15; i++) { _mpic_write(mpic->reg_type, &mpic->cpuregs[cpuid], MPIC_CPU_EOI, 0); } } } #endif /* CONFIG_SMP */ #ifdef CONFIG_PM static void mpic_suspend_one(struct mpic *mpic) { int i; for (i = 0; i < mpic->num_sources; i++) { mpic->save_data[i].vecprio = mpic_irq_read(i, MPIC_INFO(IRQ_VECTOR_PRI)); mpic->save_data[i].dest = mpic_irq_read(i, MPIC_INFO(IRQ_DESTINATION)); } } static int mpic_suspend(void) { struct mpic *mpic = mpics; while (mpic) { mpic_suspend_one(mpic); mpic = mpic->next; } return 0; } static void mpic_resume_one(struct mpic *mpic) { int i; for (i = 0; i < mpic->num_sources; i++) { mpic_irq_write(i, MPIC_INFO(IRQ_VECTOR_PRI), mpic->save_data[i].vecprio); mpic_irq_write(i, MPIC_INFO(IRQ_DESTINATION), mpic->save_data[i].dest); #ifdef CONFIG_MPIC_U3_HT_IRQS if (mpic->fixups) { struct mpic_irq_fixup *fixup = &mpic->fixups[i]; if (fixup->base) { /* we use the lowest bit in an inverted meaning */ if ((mpic->save_data[i].fixup_data & 1) == 0) continue; /* Enable and configure */ writeb(0x10 + 2 * fixup->index, fixup->base + 2); writel(mpic->save_data[i].fixup_data & ~1, fixup->base + 4); } } #endif } /* end for loop */ } static void mpic_resume(void) { struct mpic *mpic = mpics; while (mpic) { mpic_resume_one(mpic); mpic = mpic->next; } } static struct syscore_ops mpic_syscore_ops = { .resume = mpic_resume, .suspend = mpic_suspend, }; static int mpic_init_sys(void) { register_syscore_ops(&mpic_syscore_ops); return 0; } device_initcall(mpic_init_sys); #endif