2 * arch/sh/boards/dreamcast/irq.c
4 * Holly IRQ support for the Sega Dreamcast.
6 * Copyright (c) 2001, 2002 M. R. Brown <mrbrown@0xd6.org>
8 * This file is part of the LinuxDC project (www.linuxdc.org)
9 * Released under the terms of the GNU GPL v2.0
12 #include <linux/irq.h>
16 #include <asm/dreamcast/sysasic.h>
18 /* Dreamcast System ASIC Hardware Events -
20 The Dreamcast's System ASIC (a.k.a. Holly) is responsible for receiving
21 hardware events from system peripherals and triggering an SH7750 IRQ.
22 Hardware events can trigger IRQs 13, 11, or 9 depending on which bits are
23 set in the Event Mask Registers (EMRs). When a hardware event is
24 triggered, it's corresponding bit in the Event Status Registers (ESRs)
25 is set, and that bit should be rewritten to the ESR to acknowledge that
28 There are three 32-bit ESRs located at 0xa05f8900 - 0xa05f6908. Event
29 types can be found in include/asm-sh/dc_sysasic.h. There are three groups
30 of EMRs that parallel the ESRs. Each EMR group corresponds to an IRQ, so
31 0xa05f6910 - 0xa05f6918 triggers IRQ 13, 0xa05f6920 - 0xa05f6928 triggers
32 IRQ 11, and 0xa05f6930 - 0xa05f6938 triggers IRQ 9.
34 In the kernel, these events are mapped to virtual IRQs so that drivers can
35 respond to them as they would a normal interrupt. In order to keep this
36 mapping simple, the events are mapped as:
38 6900/6910 - Events 0-31, IRQ 13
39 6904/6924 - Events 32-63, IRQ 11
40 6908/6938 - Events 64-95, IRQ 9
44 #define ESR_BASE 0x005f6900 /* Base event status register */
45 #define EMR_BASE 0x005f6910 /* Base event mask register */
47 /* Helps us determine the EMR group that this event belongs to: 0 = 0x6910,
48 1 = 0x6920, 2 = 0x6930; also determine the event offset */
49 #define LEVEL(event) (((event) - HW_EVENT_IRQ_BASE) / 32)
51 /* Return the hardware event's bit positon within the EMR/ESR */
52 #define EVENT_BIT(event) (((event) - HW_EVENT_IRQ_BASE) & 31)
54 /* For each of these *_irq routines, the IRQ passed in is the virtual IRQ
55 (logically mapped to the corresponding bit for the hardware event). */
57 /* Disable the hardware event by masking its bit in its EMR */
58 static inline void disable_systemasic_irq(unsigned int irq)
61 __u32 emr = EMR_BASE + (LEVEL(irq) << 4) + (LEVEL(irq) << 2);
64 local_irq_save(flags);
66 mask &= ~(1 << EVENT_BIT(irq));
68 local_irq_restore(flags);
71 /* Enable the hardware event by setting its bit in its EMR */
72 static inline void enable_systemasic_irq(unsigned int irq)
75 __u32 emr = EMR_BASE + (LEVEL(irq) << 4) + (LEVEL(irq) << 2);
78 local_irq_save(flags);
80 mask |= (1 << EVENT_BIT(irq));
82 local_irq_restore(flags);
85 /* Acknowledge a hardware event by writing its bit back to its ESR */
86 static void ack_systemasic_irq(unsigned int irq)
88 __u32 esr = ESR_BASE + (LEVEL(irq) << 2);
89 disable_systemasic_irq(irq);
90 outl((1 << EVENT_BIT(irq)), esr);
93 /* After a IRQ has been ack'd and responded to, it needs to be renabled */
94 static void end_systemasic_irq(unsigned int irq)
96 if (!(irq_desc[irq].status & (IRQ_DISABLED|IRQ_INPROGRESS)))
97 enable_systemasic_irq(irq);
100 static unsigned int startup_systemasic_irq(unsigned int irq)
102 enable_systemasic_irq(irq);
107 static void shutdown_systemasic_irq(unsigned int irq)
109 disable_systemasic_irq(irq);
112 struct hw_interrupt_type systemasic_int = {
113 .typename = "System ASIC",
114 .startup = startup_systemasic_irq,
115 .shutdown = shutdown_systemasic_irq,
116 .enable = enable_systemasic_irq,
117 .disable = disable_systemasic_irq,
118 .ack = ack_systemasic_irq,
119 .end = end_systemasic_irq,
123 * Map the hardware event indicated by the processor IRQ to a virtual IRQ.
125 int systemasic_irq_demux(int irq)
127 __u32 emr, esr, status, level;
143 emr = EMR_BASE + (level << 4) + (level << 2);
144 esr = ESR_BASE + (level << 2);
146 /* Mask the ESR to filter any spurious, unwanted interrtupts */
150 /* Now scan and find the first set bit as the event to map */
151 for (bit = 1, j = 0; j < 32; bit <<= 1, j++) {
153 irq = HW_EVENT_IRQ_BASE + j + (level << 5);