/* * Shared interrupt handling code for IPR and INTC2 types of IRQs. * * Copyright (C) 2007 Magnus Damm * * Based on intc2.c and ipr.c * * Copyright (C) 1999 Niibe Yutaka & Takeshi Yaegashi * Copyright (C) 2000 Kazumoto Kojima * Copyright (C) 2001 David J. Mckay (david.mckay@st.com) * Copyright (C) 2003 Takashi Kusuda * Copyright (C) 2005, 2006 Paul Mundt * * 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. */ #include #include #include #include #include #define _INTC_MK(fn, idx, bit, value) \ ((fn) << 24 | ((value) << 16) | ((idx) << 8) | (bit)) #define _INTC_FN(h) (h >> 24) #define _INTC_VALUE(h) ((h >> 16) & 0xff) #define _INTC_IDX(h) ((h >> 8) & 0xff) #define _INTC_BIT(h) (h & 0xff) #define _INTC_PTR(desc, member, data) \ (desc->member + _INTC_IDX(data)) static inline struct intc_desc *get_intc_desc(unsigned int irq) { struct irq_chip *chip = get_irq_chip(irq); return (void *)((char *)chip - offsetof(struct intc_desc, chip)); } static inline unsigned int set_field(unsigned int value, unsigned int field_value, unsigned int width, unsigned int shift) { value &= ~(((1 << width) - 1) << shift); value |= field_value << shift; return value; } static inline unsigned int set_prio_field(struct intc_desc *desc, unsigned int value, unsigned int priority, unsigned int data) { unsigned int width = _INTC_PTR(desc, prio_regs, data)->field_width; return set_field(value, priority, width, _INTC_BIT(data)); } static void disable_prio_16(struct intc_desc *desc, unsigned int data) { unsigned long addr = _INTC_PTR(desc, prio_regs, data)->reg; ctrl_outw(set_prio_field(desc, ctrl_inw(addr), 0, data), addr); } static void enable_prio_16(struct intc_desc *desc, unsigned int data) { unsigned long addr = _INTC_PTR(desc, prio_regs, data)->reg; unsigned int prio = _INTC_VALUE(data); ctrl_outw(set_prio_field(desc, ctrl_inw(addr), prio, data), addr); } static void disable_prio_32(struct intc_desc *desc, unsigned int data) { unsigned long addr = _INTC_PTR(desc, prio_regs, data)->reg; ctrl_outl(set_prio_field(desc, ctrl_inl(addr), 0, data), addr); } static void enable_prio_32(struct intc_desc *desc, unsigned int data) { unsigned long addr = _INTC_PTR(desc, prio_regs, data)->reg; unsigned int prio = _INTC_VALUE(data); ctrl_outl(set_prio_field(desc, ctrl_inl(addr), prio, data), addr); } static void write_set_reg_8(struct intc_desc *desc, unsigned int data) { ctrl_outb(1 << _INTC_BIT(data), _INTC_PTR(desc, mask_regs, data)->set_reg); } static void write_clr_reg_8(struct intc_desc *desc, unsigned int data) { ctrl_outb(1 << _INTC_BIT(data), _INTC_PTR(desc, mask_regs, data)->clr_reg); } static void write_set_reg_32(struct intc_desc *desc, unsigned int data) { ctrl_outl(1 << _INTC_BIT(data), _INTC_PTR(desc, mask_regs, data)->set_reg); } static void write_clr_reg_32(struct intc_desc *desc, unsigned int data) { ctrl_outl(1 << _INTC_BIT(data), _INTC_PTR(desc, mask_regs, data)->clr_reg); } static void or_set_reg_16(struct intc_desc *desc, unsigned int data) { unsigned long addr = _INTC_PTR(desc, mask_regs, data)->set_reg; ctrl_outw(ctrl_inw(addr) | 1 << _INTC_BIT(data), addr); } static void and_set_reg_16(struct intc_desc *desc, unsigned int data) { unsigned long addr = _INTC_PTR(desc, mask_regs, data)->set_reg; ctrl_outw(ctrl_inw(addr) & ~(1 << _INTC_BIT(data)), addr); } static void or_set_reg_32(struct intc_desc *desc, unsigned int data) { unsigned long addr = _INTC_PTR(desc, mask_regs, data)->set_reg; ctrl_outl(ctrl_inl(addr) | 1 << _INTC_BIT(data), addr); } static void and_set_reg_32(struct intc_desc *desc, unsigned int data) { unsigned long addr = _INTC_PTR(desc, mask_regs, data)->set_reg; ctrl_outl(ctrl_inl(addr) & ~(1 << _INTC_BIT(data)), addr); } enum { REG_FN_ERROR=0, REG_FN_DUAL_8, REG_FN_DUAL_32, REG_FN_ENA_16, REG_FN_ENA_32, REG_FN_PRIO_16, REG_FN_PRIO_32 }; static struct { void (*enable)(struct intc_desc *, unsigned int); void (*disable)(struct intc_desc *, unsigned int); } intc_reg_fns[] = { [REG_FN_DUAL_8] = { write_clr_reg_8, write_set_reg_8 }, [REG_FN_DUAL_32] = { write_clr_reg_32, write_set_reg_32 }, [REG_FN_ENA_16] = { or_set_reg_16, and_set_reg_16 }, [REG_FN_ENA_32] = { or_set_reg_32, and_set_reg_32 }, [REG_FN_PRIO_16] = { enable_prio_16, disable_prio_16 }, [REG_FN_PRIO_32] = { enable_prio_32, disable_prio_32 }, }; static void intc_enable(unsigned int irq) { struct intc_desc *desc = get_intc_desc(irq); unsigned int data = (unsigned int) get_irq_chip_data(irq); intc_reg_fns[_INTC_FN(data)].enable(desc, data); } static void intc_disable(unsigned int irq) { struct intc_desc *desc = get_intc_desc(irq); unsigned int data = (unsigned int) get_irq_chip_data(irq); intc_reg_fns[_INTC_FN(data)].disable(desc, data); } static void set_sense_16(struct intc_desc *desc, unsigned int data) { unsigned long addr = _INTC_PTR(desc, sense_regs, data)->reg; unsigned int width = _INTC_PTR(desc, sense_regs, data)->field_width; unsigned int bit = _INTC_BIT(data); unsigned int value = _INTC_VALUE(data); ctrl_outw(set_field(ctrl_inw(addr), value, width, bit), addr); } static void set_sense_32(struct intc_desc *desc, unsigned int data) { unsigned long addr = _INTC_PTR(desc, sense_regs, data)->reg; unsigned int width = _INTC_PTR(desc, sense_regs, data)->field_width; unsigned int bit = _INTC_BIT(data); unsigned int value = _INTC_VALUE(data); ctrl_outl(set_field(ctrl_inl(addr), value, width, bit), addr); } #define VALID(x) (x | 0x80) static unsigned char intc_irq_sense_table[IRQ_TYPE_SENSE_MASK + 1] = { [IRQ_TYPE_EDGE_FALLING] = VALID(0), [IRQ_TYPE_EDGE_RISING] = VALID(1), [IRQ_TYPE_LEVEL_LOW] = VALID(2), [IRQ_TYPE_LEVEL_HIGH] = VALID(3), }; static int intc_set_sense(unsigned int irq, unsigned int type) { struct intc_desc *desc = get_intc_desc(irq); unsigned char value = intc_irq_sense_table[type & IRQ_TYPE_SENSE_MASK]; unsigned int i, j, data, bit; intc_enum enum_id = 0; for (i = 0; i < desc->nr_vectors; i++) { struct intc_vect *vect = desc->vectors + i; if (evt2irq(vect->vect) != irq) continue; enum_id = vect->enum_id; break; } if (!enum_id || !value) return -EINVAL; value ^= VALID(0); for (i = 0; i < desc->nr_sense_regs; i++) { struct intc_sense_reg *sr = desc->sense_regs + i; for (j = 0; j < ARRAY_SIZE(sr->enum_ids); j++) { if (sr->enum_ids[j] != enum_id) continue; bit = sr->reg_width - ((j + 1) * sr->field_width); data = _INTC_MK(0, i, bit, value); switch(sr->reg_width) { case 16: set_sense_16(desc, data); break; case 32: set_sense_32(desc, data); break; } return 0; } } return -EINVAL; } static unsigned int __init intc_find_dual_handler(unsigned int width) { switch (width) { case 8: return REG_FN_DUAL_8; case 32: return REG_FN_DUAL_32; } BUG(); return REG_FN_ERROR; } static unsigned int __init intc_find_prio_handler(unsigned int width) { switch (width) { case 16: return REG_FN_PRIO_16; case 32: return REG_FN_PRIO_32; } BUG(); return REG_FN_ERROR; } static unsigned int __init intc_find_ena_handler(unsigned int width) { switch (width) { case 16: return REG_FN_ENA_16; case 32: return REG_FN_ENA_32; } BUG(); return REG_FN_ERROR; } static intc_enum __init intc_grp_id(struct intc_desc *desc, intc_enum enum_id) { struct intc_group *g = desc->groups; unsigned int i, j; for (i = 0; g && enum_id && i < desc->nr_groups; i++) { g = desc->groups + i; for (j = 0; g->enum_ids[j]; j++) { if (g->enum_ids[j] != enum_id) continue; return g->enum_id; } } return 0; } static unsigned int __init intc_prio_value(struct intc_desc *desc, intc_enum enum_id, int do_grps) { struct intc_prio *p = desc->priorities; unsigned int i; for (i = 0; p && enum_id && i < desc->nr_priorities; i++) { p = desc->priorities + i; if (p->enum_id != enum_id) continue; return p->priority; } if (do_grps) return intc_prio_value(desc, intc_grp_id(desc, enum_id), 0); /* default to the lowest priority possible if no priority is set * - this needs to be at least 2 for 5-bit priorities on 7780 */ return 2; } static unsigned int __init intc_mask_data(struct intc_desc *desc, intc_enum enum_id, int do_grps) { struct intc_mask_reg *mr = desc->mask_regs; unsigned int i, j, fn; for (i = 0; mr && enum_id && i < desc->nr_mask_regs; i++) { mr = desc->mask_regs + i; for (j = 0; j < ARRAY_SIZE(mr->enum_ids); j++) { if (mr->enum_ids[j] != enum_id) continue; switch (mr->clr_reg) { case 1: /* 1 = enabled interrupt - "enable" register */ fn = intc_find_ena_handler(mr->reg_width); break; default: fn = intc_find_dual_handler(mr->reg_width); } if (fn == REG_FN_ERROR) return 0; return _INTC_MK(fn, i, (mr->reg_width - 1) - j, 0); } } if (do_grps) return intc_mask_data(desc, intc_grp_id(desc, enum_id), 0); return 0; } static unsigned int __init intc_prio_data(struct intc_desc *desc, intc_enum enum_id, int do_grps) { struct intc_prio_reg *pr = desc->prio_regs; unsigned int i, j, fn, bit, prio; for (i = 0; pr && enum_id && i < desc->nr_prio_regs; i++) { pr = desc->prio_regs + i; for (j = 0; j < ARRAY_SIZE(pr->enum_ids); j++) { if (pr->enum_ids[j] != enum_id) continue; fn = intc_find_prio_handler(pr->reg_width); if (fn == REG_FN_ERROR) return 0; prio = intc_prio_value(desc, enum_id, 1); bit = pr->reg_width - ((j + 1) * pr->field_width); BUG_ON(bit < 0); return _INTC_MK(fn, i, bit, prio); } } if (do_grps) return intc_prio_data(desc, intc_grp_id(desc, enum_id), 0); return 0; } static void __init intc_register_irq(struct intc_desc *desc, intc_enum enum_id, unsigned int irq) { unsigned int data[2], primary; /* Prefer single interrupt source bitmap over other combinations: * 1. bitmap, single interrupt source * 2. priority, single interrupt source * 3. bitmap, multiple interrupt sources (groups) * 4. priority, multiple interrupt sources (groups) */ data[0] = intc_mask_data(desc, enum_id, 0); data[1] = intc_prio_data(desc, enum_id, 0); primary = 0; if (!data[0] && data[1]) primary = 1; data[0] = data[0] ? data[0] : intc_mask_data(desc, enum_id, 1); data[1] = data[1] ? data[1] : intc_prio_data(desc, enum_id, 1); if (!data[primary]) primary ^= 1; BUG_ON(!data[primary]); /* must have primary masking method */ disable_irq_nosync(irq); set_irq_chip_and_handler_name(irq, &desc->chip, handle_level_irq, "level"); set_irq_chip_data(irq, (void *)data[primary]); /* enable secondary masking method if present */ if (data[!primary]) intc_reg_fns[_INTC_FN(data[!primary])].enable(desc, data[!primary]); /* irq should be disabled by default */ desc->chip.mask(irq); } void __init register_intc_controller(struct intc_desc *desc) { unsigned int i; desc->chip.mask = intc_disable; desc->chip.unmask = intc_enable; desc->chip.mask_ack = intc_disable; desc->chip.set_type = intc_set_sense; for (i = 0; i < desc->nr_vectors; i++) { struct intc_vect *vect = desc->vectors + i; intc_register_irq(desc, vect->enum_id, evt2irq(vect->vect)); } }