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linux-2.6/arch/x86/include/asm/irq_vectors.h
Sheng Yang 38e20b07ef x86/xen: event channels delivery on HVM. 
Set the callback to receive evtchns from Xen, using the
callback vector delivery mechanism.

The traditional way for receiving event channel notifications from Xen
is via the interrupts from the platform PCI device.
The callback vector is a newer alternative that allow us to receive
notifications on any vcpu and doesn't need any PCI support: we allocate
a vector exclusively to receive events, in the vector handler we don't
need to interact with the vlapic, therefore we avoid a VMEXIT.

Signed-off-by: Stefano Stabellini <stefano.stabellini@eu.citrix.com>
Signed-off-by: Sheng Yang <sheng@linux.intel.com>
Signed-off-by: Jeremy Fitzhardinge <jeremy.fitzhardinge@citrix.com>
2010-07-22 16:45:59 -07:00

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#ifndef _ASM_X86_IRQ_VECTORS_H
#define _ASM_X86_IRQ_VECTORS_H
/*
* Linux IRQ vector layout.
*
* There are 256 IDT entries (per CPU - each entry is 8 bytes) which can
* be defined by Linux. They are used as a jump table by the CPU when a
* given vector is triggered - by a CPU-external, CPU-internal or
* software-triggered event.
*
* Linux sets the kernel code address each entry jumps to early during
* bootup, and never changes them. This is the general layout of the
* IDT entries:
*
* Vectors 0 ... 31 : system traps and exceptions - hardcoded events
* Vectors 32 ... 127 : device interrupts
* Vector 128 : legacy int80 syscall interface
* Vectors 129 ... 237 : device interrupts
* Vectors 238 ... 255 : special interrupts
*
* 64-bit x86 has per CPU IDT tables, 32-bit has one shared IDT table.
*
* This file enumerates the exact layout of them:
*/
#define NMI_VECTOR 0x02
#define MCE_VECTOR 0x12
/*
* IDT vectors usable for external interrupt sources start at 0x20.
* (0x80 is the syscall vector, 0x30-0x3f are for ISA)
*/
#define FIRST_EXTERNAL_VECTOR 0x20
/*
* We start allocating at 0x21 to spread out vectors evenly between
* priority levels. (0x80 is the syscall vector)
*/
#define VECTOR_OFFSET_START 1
/*
* Reserve the lowest usable vector (and hence lowest priority) 0x20 for
* triggering cleanup after irq migration. 0x21-0x2f will still be used
* for device interrupts.
*/
#define IRQ_MOVE_CLEANUP_VECTOR FIRST_EXTERNAL_VECTOR
#define IA32_SYSCALL_VECTOR 0x80
#ifdef CONFIG_X86_32
# define SYSCALL_VECTOR 0x80
#endif
/*
* Vectors 0x30-0x3f are used for ISA interrupts.
* round up to the next 16-vector boundary
*/
#define IRQ0_VECTOR ((FIRST_EXTERNAL_VECTOR + 16) & ~15)
#define IRQ1_VECTOR (IRQ0_VECTOR + 1)
#define IRQ2_VECTOR (IRQ0_VECTOR + 2)
#define IRQ3_VECTOR (IRQ0_VECTOR + 3)
#define IRQ4_VECTOR (IRQ0_VECTOR + 4)
#define IRQ5_VECTOR (IRQ0_VECTOR + 5)
#define IRQ6_VECTOR (IRQ0_VECTOR + 6)
#define IRQ7_VECTOR (IRQ0_VECTOR + 7)
#define IRQ8_VECTOR (IRQ0_VECTOR + 8)
#define IRQ9_VECTOR (IRQ0_VECTOR + 9)
#define IRQ10_VECTOR (IRQ0_VECTOR + 10)
#define IRQ11_VECTOR (IRQ0_VECTOR + 11)
#define IRQ12_VECTOR (IRQ0_VECTOR + 12)
#define IRQ13_VECTOR (IRQ0_VECTOR + 13)
#define IRQ14_VECTOR (IRQ0_VECTOR + 14)
#define IRQ15_VECTOR (IRQ0_VECTOR + 15)
/*
* Special IRQ vectors used by the SMP architecture, 0xf0-0xff
*
* some of the following vectors are 'rare', they are merged
* into a single vector (CALL_FUNCTION_VECTOR) to save vector space.
* TLB, reschedule and local APIC vectors are performance-critical.
*/
#define SPURIOUS_APIC_VECTOR 0xff
/*
* Sanity check
*/
#if ((SPURIOUS_APIC_VECTOR & 0x0F) != 0x0F)
# error SPURIOUS_APIC_VECTOR definition error
#endif
#define ERROR_APIC_VECTOR 0xfe
#define RESCHEDULE_VECTOR 0xfd
#define CALL_FUNCTION_VECTOR 0xfc
#define CALL_FUNCTION_SINGLE_VECTOR 0xfb
#define THERMAL_APIC_VECTOR 0xfa
#define THRESHOLD_APIC_VECTOR 0xf9
#define REBOOT_VECTOR 0xf8
/* f0-f7 used for spreading out TLB flushes: */
#define INVALIDATE_TLB_VECTOR_END 0xf7
#define INVALIDATE_TLB_VECTOR_START 0xf0
#define NUM_INVALIDATE_TLB_VECTORS 8
/*
* Local APIC timer IRQ vector is on a different priority level,
* to work around the 'lost local interrupt if more than 2 IRQ
* sources per level' errata.
*/
#define LOCAL_TIMER_VECTOR 0xef
/*
* Generic system vector for platform specific use
*/
#define X86_PLATFORM_IPI_VECTOR 0xed
/*
* Performance monitoring pending work vector:
*/
#define LOCAL_PENDING_VECTOR 0xec
#define UV_BAU_MESSAGE 0xea
/*
* Self IPI vector for machine checks
*/
#define MCE_SELF_VECTOR 0xeb
/* Xen vector callback to receive events in a HVM domain */
#define XEN_HVM_EVTCHN_CALLBACK 0xe9
#define NR_VECTORS 256
#define FPU_IRQ 13
#define FIRST_VM86_IRQ 3
#define LAST_VM86_IRQ 15
#ifndef __ASSEMBLY__
static inline int invalid_vm86_irq(int irq)
{
return irq < FIRST_VM86_IRQ || irq > LAST_VM86_IRQ;
}
#endif
/*
* Size the maximum number of interrupts.
*
* If the irq_desc[] array has a sparse layout, we can size things
* generously - it scales up linearly with the maximum number of CPUs,
* and the maximum number of IO-APICs, whichever is higher.
*
* In other cases we size more conservatively, to not create too large
* static arrays.
*/
#define NR_IRQS_LEGACY 16
#define IO_APIC_VECTOR_LIMIT ( 32 * MAX_IO_APICS )
#ifdef CONFIG_X86_IO_APIC
# ifdef CONFIG_SPARSE_IRQ
# define CPU_VECTOR_LIMIT (64 * NR_CPUS)
# define NR_IRQS \
(CPU_VECTOR_LIMIT > IO_APIC_VECTOR_LIMIT ? \
(NR_VECTORS + CPU_VECTOR_LIMIT) : \
(NR_VECTORS + IO_APIC_VECTOR_LIMIT))
# else
# define CPU_VECTOR_LIMIT (32 * NR_CPUS)
# define NR_IRQS \
(CPU_VECTOR_LIMIT < IO_APIC_VECTOR_LIMIT ? \
(NR_VECTORS + CPU_VECTOR_LIMIT) : \
(NR_VECTORS + IO_APIC_VECTOR_LIMIT))
# endif
#else /* !CONFIG_X86_IO_APIC: */
# define NR_IRQS NR_IRQS_LEGACY
#endif
#endif /* _ASM_X86_IRQ_VECTORS_H */
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