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freebsd-dev/sys/ia64/include/intr.h

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This is the first snapshot of the FreeBSD/ia64 kernel. This kernel will not work on any real hardware (or fully work on any simulator). Much more needs to happen before this is actually functional but its nice to see the FreeBSD copyright message appear in the ia64 simulator.
2000-09-29 13:46:07 +00:00
/*-
Some code churn: o Eliminate IA64_PHYS_TO_RR6 and change all places where the macro is used by calling either bus_space_map() or pmap_mapdev(). o Implement bus_space_map() in terms of pmap_mapdev() and implement bus_space_unmap() in terms of pmap_unmapdev(). o Have ia64_pib hold the uncached virtual address of the processor interrupt block throughout the kernel's life and access the elements of the PIB through this structure pointer. This is a non-functional change with the exception of using ia64_ld1() and ia64_st8() to write to the PIB. We were still using assignments, for which the compiler generates semaphore reads -- which cause undefined behaviour for uncacheable memory. Note also that the memory barriers in ipi_send() are critical for proper functioning. With all the mapping of uncached memory done by pmap_mapdev(), we can keep track of the translations and wire them in the CPU. This then eliminates the need to reserve a whole region for uncached I/O and it eliminates translation traps for device I/O accesses.
2010-02-14 16:56:24 +00:00
* Copyright (c) 2007-2010 Marcel Moolenaar
This is the first snapshot of the FreeBSD/ia64 kernel. This kernel will not work on any real hardware (or fully work on any simulator). Much more needs to happen before this is actually functional but its nice to see the FreeBSD copyright message appear in the ia64 simulator.
2000-09-29 13:46:07 +00:00
* Copyright (c) 1998 Doug Rabson
* All rights reserved.
*
* 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.
*
* 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.
*
* $FreeBSD$
*/
#ifndef _MACHINE_INTR_H_
Some code churn: o Eliminate IA64_PHYS_TO_RR6 and change all places where the macro is used by calling either bus_space_map() or pmap_mapdev(). o Implement bus_space_map() in terms of pmap_mapdev() and implement bus_space_unmap() in terms of pmap_unmapdev(). o Have ia64_pib hold the uncached virtual address of the processor interrupt block throughout the kernel's life and access the elements of the PIB through this structure pointer. This is a non-functional change with the exception of using ia64_ld1() and ia64_st8() to write to the PIB. We were still using assignments, for which the compiler generates semaphore reads -- which cause undefined behaviour for uncacheable memory. Note also that the memory barriers in ipi_send() are critical for proper functioning. With all the mapping of uncached memory done by pmap_mapdev(), we can keep track of the translations and wire them in the CPU. This then eliminates the need to reserve a whole region for uncached I/O and it eliminates translation traps for device I/O accesses.
2010-02-14 16:56:24 +00:00
#define _MACHINE_INTR_H_
This is the first snapshot of the FreeBSD/ia64 kernel. This kernel will not work on any real hardware (or fully work on any simulator). Much more needs to happen before this is actually functional but its nice to see the FreeBSD copyright message appear in the ia64 simulator.
2000-09-29 13:46:07 +00:00
Revamp the interrupt code based on the previous commit: o Introduce XIV, eXternal Interrupt Vector, to differentiate from the interrupts vectors that are offsets in the IVT (Interrupt Vector Table). There's a vector for external interrupts, which are based on the XIVs. o Keep track of allocated and reserved XIVs so that we can assign XIVs without hardcoding anything. When XIVs are allocated, an interrupt handler and a class is specified for the XIV. Classes are: 1. architecture-defined: XIV 15 is returned when no external interrupt are pending, 2. platform-defined: SAL reports which XIV is used to wakeup an AP (typically 0xFF, but it's 0x12 for the Altix 350). 3. inter-processor interrupts: allocated for SMP support and non-redirectable. 4. device interrupts (i.e. IRQs): allocated when devices are discovered and are redirectable. o Rewrite the central interrupt handler to call the per-XIV interrupt handler and rename it to ia64_handle_intr(). Move the per-XIV handler implementation to the file where we have the XIV allocation/reservation. Clock interrupt handling is moved to clock.c. IPI handling is moved to mp_machdep.c. o Drop support for the Intel 8259A because it was broken. When XIV 0 is received, the CPU should initiate an INTA cycle to obtain the interrupt vector of the 8259-based interrupt. In these cases the interrupt controller we should be talking to WRT to masking on signalling EOI is the 8259 and not the I/O SAPIC. This requires adriver for the Intel 8259A which isn't available for ia64. Thus stop pretending to support ExtINTs and instead panic() so that if we come across hardware that has an Intel 8259A, so have something real to work with. o With XIVs for IPIs dynamically allocatedi and also based on priority, define the IPI_* symbols as variables rather than constants. The variable holds the XIV allocated for the IPI. o IPI_STOP_HARD delivers a NMI if possible. Otherwise the XIV assigned to IPI_STOP is delivered.
2010-03-17 00:37:15 +00:00
#define IA64_NXIVS 256 /* External Interrupt Vectors */
#define IA64_MIN_XIV 16
#define IA64_MAX_HWPRIO 14
Implement interrupt to CPU binding. Assign interrupts to CPUs in a round-robin fashion, starting with the highest priority interrupt on the highest-numbered CPU and cycling downwards.
2010-03-27 05:40:50 +00:00
struct pcpu;
Interrupt related cleanups: o Assign vectors based on priority, because vectors have implied priority in hardware. o Use unordered memory accesses to the I/O sapic and use the acceptance form of the mf instruction. o Remove the sapicreg.h and sapicvar.h headers. All definitions in sapicreg.h are private to sapic.c and all definitions in sapicvar.h are either private or interface functions. Move the interface functions to intr.h. o Hide the definition of struct sapic.
2010-02-27 18:55:43 +00:00
struct sapic;
Revamp the interrupt code based on the previous commit: o Introduce XIV, eXternal Interrupt Vector, to differentiate from the interrupts vectors that are offsets in the IVT (Interrupt Vector Table). There's a vector for external interrupts, which are based on the XIVs. o Keep track of allocated and reserved XIVs so that we can assign XIVs without hardcoding anything. When XIVs are allocated, an interrupt handler and a class is specified for the XIV. Classes are: 1. architecture-defined: XIV 15 is returned when no external interrupt are pending, 2. platform-defined: SAL reports which XIV is used to wakeup an AP (typically 0xFF, but it's 0x12 for the Altix 350). 3. inter-processor interrupts: allocated for SMP support and non-redirectable. 4. device interrupts (i.e. IRQs): allocated when devices are discovered and are redirectable. o Rewrite the central interrupt handler to call the per-XIV interrupt handler and rename it to ia64_handle_intr(). Move the per-XIV handler implementation to the file where we have the XIV allocation/reservation. Clock interrupt handling is moved to clock.c. IPI handling is moved to mp_machdep.c. o Drop support for the Intel 8259A because it was broken. When XIV 0 is received, the CPU should initiate an INTA cycle to obtain the interrupt vector of the 8259-based interrupt. In these cases the interrupt controller we should be talking to WRT to masking on signalling EOI is the 8259 and not the I/O SAPIC. This requires adriver for the Intel 8259A which isn't available for ia64. Thus stop pretending to support ExtINTs and instead panic() so that if we come across hardware that has an Intel 8259A, so have something real to work with. o With XIVs for IPIs dynamically allocatedi and also based on priority, define the IPI_* symbols as variables rather than constants. The variable holds the XIV allocated for the IPI. o IPI_STOP_HARD delivers a NMI if possible. Otherwise the XIV assigned to IPI_STOP is delivered.
2010-03-17 00:37:15 +00:00
struct thread;
struct trapframe;
Interrupt related cleanups: o Assign vectors based on priority, because vectors have implied priority in hardware. o Use unordered memory accesses to the I/O sapic and use the acceptance form of the mf instruction. o Remove the sapicreg.h and sapicvar.h headers. All definitions in sapicreg.h are private to sapic.c and all definitions in sapicvar.h are either private or interface functions. Move the interface functions to intr.h. o Hide the definition of struct sapic.
2010-02-27 18:55:43 +00:00
Wire up most of the interrupt handling infrastructure. Not sure it works right yet but its enough for the ATA probe to work. The SCSI probes which follow are broken though.
2001-10-05 10:30:09 +00:00
/*
* Layout of the Processor Interrupt Block.
*/
Some code churn: o Eliminate IA64_PHYS_TO_RR6 and change all places where the macro is used by calling either bus_space_map() or pmap_mapdev(). o Implement bus_space_map() in terms of pmap_mapdev() and implement bus_space_unmap() in terms of pmap_unmapdev(). o Have ia64_pib hold the uncached virtual address of the processor interrupt block throughout the kernel's life and access the elements of the PIB through this structure pointer. This is a non-functional change with the exception of using ia64_ld1() and ia64_st8() to write to the PIB. We were still using assignments, for which the compiler generates semaphore reads -- which cause undefined behaviour for uncacheable memory. Note also that the memory barriers in ipi_send() are critical for proper functioning. With all the mapping of uncached memory done by pmap_mapdev(), we can keep track of the translations and wire them in the CPU. This then eliminates the need to reserve a whole region for uncached I/O and it eliminates translation traps for device I/O accesses.
2010-02-14 16:56:24 +00:00
struct ia64_pib
Wire up most of the interrupt handling infrastructure. Not sure it works right yet but its enough for the ATA probe to work. The SCSI probes which follow are broken though.
2001-10-05 10:30:09 +00:00
{
Some code churn: o Eliminate IA64_PHYS_TO_RR6 and change all places where the macro is used by calling either bus_space_map() or pmap_mapdev(). o Implement bus_space_map() in terms of pmap_mapdev() and implement bus_space_unmap() in terms of pmap_unmapdev(). o Have ia64_pib hold the uncached virtual address of the processor interrupt block throughout the kernel's life and access the elements of the PIB through this structure pointer. This is a non-functional change with the exception of using ia64_ld1() and ia64_st8() to write to the PIB. We were still using assignments, for which the compiler generates semaphore reads -- which cause undefined behaviour for uncacheable memory. Note also that the memory barriers in ipi_send() are critical for proper functioning. With all the mapping of uncached memory done by pmap_mapdev(), we can keep track of the translations and wire them in the CPU. This then eliminates the need to reserve a whole region for uncached I/O and it eliminates translation traps for device I/O accesses.
2010-02-14 16:56:24 +00:00
uint64_t ib_ipi[65536][2]; /* 64K-way IPIs (1MB area). */
uint8_t _rsvd1[0xe0000];
uint8_t ib_inta; /* Generate INTA cycle. */
uint8_t _rsvd2[7];
uint8_t ib_xtp; /* External Task Priority. */
uint8_t _rsvd3[7];
uint8_t _rsvd4[0x1fff0];
Wire up most of the interrupt handling infrastructure. Not sure it works right yet but its enough for the ATA probe to work. The SCSI probes which follow are broken though.
2001-10-05 10:30:09 +00:00
};
Revamp the interrupt code based on the previous commit: o Introduce XIV, eXternal Interrupt Vector, to differentiate from the interrupts vectors that are offsets in the IVT (Interrupt Vector Table). There's a vector for external interrupts, which are based on the XIVs. o Keep track of allocated and reserved XIVs so that we can assign XIVs without hardcoding anything. When XIVs are allocated, an interrupt handler and a class is specified for the XIV. Classes are: 1. architecture-defined: XIV 15 is returned when no external interrupt are pending, 2. platform-defined: SAL reports which XIV is used to wakeup an AP (typically 0xFF, but it's 0x12 for the Altix 350). 3. inter-processor interrupts: allocated for SMP support and non-redirectable. 4. device interrupts (i.e. IRQs): allocated when devices are discovered and are redirectable. o Rewrite the central interrupt handler to call the per-XIV interrupt handler and rename it to ia64_handle_intr(). Move the per-XIV handler implementation to the file where we have the XIV allocation/reservation. Clock interrupt handling is moved to clock.c. IPI handling is moved to mp_machdep.c. o Drop support for the Intel 8259A because it was broken. When XIV 0 is received, the CPU should initiate an INTA cycle to obtain the interrupt vector of the 8259-based interrupt. In these cases the interrupt controller we should be talking to WRT to masking on signalling EOI is the 8259 and not the I/O SAPIC. This requires adriver for the Intel 8259A which isn't available for ia64. Thus stop pretending to support ExtINTs and instead panic() so that if we come across hardware that has an Intel 8259A, so have something real to work with. o With XIVs for IPIs dynamically allocatedi and also based on priority, define the IPI_* symbols as variables rather than constants. The variable holds the XIV allocated for the IPI. o IPI_STOP_HARD delivers a NMI if possible. Otherwise the XIV assigned to IPI_STOP is delivered.
2010-03-17 00:37:15 +00:00
enum ia64_xiv_use {
IA64_XIV_FREE,
IA64_XIV_ARCH, /* Architecturally defined. */
IA64_XIV_PLAT, /* Platform defined. */
IA64_XIV_IPI, /* Used for IPIs. */
IA64_XIV_IRQ /* Used for external interrupts. */
};
typedef u_int (ia64_ihtype)(struct thread *, u_int, struct trapframe *);
Some code churn: o Eliminate IA64_PHYS_TO_RR6 and change all places where the macro is used by calling either bus_space_map() or pmap_mapdev(). o Implement bus_space_map() in terms of pmap_mapdev() and implement bus_space_unmap() in terms of pmap_unmapdev(). o Have ia64_pib hold the uncached virtual address of the processor interrupt block throughout the kernel's life and access the elements of the PIB through this structure pointer. This is a non-functional change with the exception of using ia64_ld1() and ia64_st8() to write to the PIB. We were still using assignments, for which the compiler generates semaphore reads -- which cause undefined behaviour for uncacheable memory. Note also that the memory barriers in ipi_send() are critical for proper functioning. With all the mapping of uncached memory done by pmap_mapdev(), we can keep track of the translations and wire them in the CPU. This then eliminates the need to reserve a whole region for uncached I/O and it eliminates translation traps for device I/O accesses.
2010-02-14 16:56:24 +00:00
extern struct ia64_pib *ia64_pib;
Wire up most of the interrupt handling infrastructure. Not sure it works right yet but its enough for the ATA probe to work. The SCSI probes which follow are broken though.
2001-10-05 10:30:09 +00:00
Implement interrupt to CPU binding. Assign interrupts to CPUs in a round-robin fashion, starting with the highest priority interrupt on the highest-numbered CPU and cycling downwards.
2010-03-27 05:40:50 +00:00
void ia64_bind_intr(void);
Revamp the interrupt code based on the previous commit: o Introduce XIV, eXternal Interrupt Vector, to differentiate from the interrupts vectors that are offsets in the IVT (Interrupt Vector Table). There's a vector for external interrupts, which are based on the XIVs. o Keep track of allocated and reserved XIVs so that we can assign XIVs without hardcoding anything. When XIVs are allocated, an interrupt handler and a class is specified for the XIV. Classes are: 1. architecture-defined: XIV 15 is returned when no external interrupt are pending, 2. platform-defined: SAL reports which XIV is used to wakeup an AP (typically 0xFF, but it's 0x12 for the Altix 350). 3. inter-processor interrupts: allocated for SMP support and non-redirectable. 4. device interrupts (i.e. IRQs): allocated when devices are discovered and are redirectable. o Rewrite the central interrupt handler to call the per-XIV interrupt handler and rename it to ia64_handle_intr(). Move the per-XIV handler implementation to the file where we have the XIV allocation/reservation. Clock interrupt handling is moved to clock.c. IPI handling is moved to mp_machdep.c. o Drop support for the Intel 8259A because it was broken. When XIV 0 is received, the CPU should initiate an INTA cycle to obtain the interrupt vector of the 8259-based interrupt. In these cases the interrupt controller we should be talking to WRT to masking on signalling EOI is the 8259 and not the I/O SAPIC. This requires adriver for the Intel 8259A which isn't available for ia64. Thus stop pretending to support ExtINTs and instead panic() so that if we come across hardware that has an Intel 8259A, so have something real to work with. o With XIVs for IPIs dynamically allocatedi and also based on priority, define the IPI_* symbols as variables rather than constants. The variable holds the XIV allocated for the IPI. o IPI_STOP_HARD delivers a NMI if possible. Otherwise the XIV assigned to IPI_STOP is delivered.
2010-03-17 00:37:15 +00:00
void ia64_handle_intr(struct trapframe *);
Interrupt related cleanups: o Assign vectors based on priority, because vectors have implied priority in hardware. o Use unordered memory accesses to the I/O sapic and use the acceptance form of the mf instruction. o Remove the sapicreg.h and sapicvar.h headers. All definitions in sapicreg.h are private to sapic.c and all definitions in sapicvar.h are either private or interface functions. Move the interface functions to intr.h. o Hide the definition of struct sapic.
2010-02-27 18:55:43 +00:00
int ia64_setup_intr(const char *, int, driver_filter_t, driver_intr_t,
void *, enum intr_type, void **);
int ia64_teardown_intr(void *);
Revamp the interrupt code based on the previous commit: o Introduce XIV, eXternal Interrupt Vector, to differentiate from the interrupts vectors that are offsets in the IVT (Interrupt Vector Table). There's a vector for external interrupts, which are based on the XIVs. o Keep track of allocated and reserved XIVs so that we can assign XIVs without hardcoding anything. When XIVs are allocated, an interrupt handler and a class is specified for the XIV. Classes are: 1. architecture-defined: XIV 15 is returned when no external interrupt are pending, 2. platform-defined: SAL reports which XIV is used to wakeup an AP (typically 0xFF, but it's 0x12 for the Altix 350). 3. inter-processor interrupts: allocated for SMP support and non-redirectable. 4. device interrupts (i.e. IRQs): allocated when devices are discovered and are redirectable. o Rewrite the central interrupt handler to call the per-XIV interrupt handler and rename it to ia64_handle_intr(). Move the per-XIV handler implementation to the file where we have the XIV allocation/reservation. Clock interrupt handling is moved to clock.c. IPI handling is moved to mp_machdep.c. o Drop support for the Intel 8259A because it was broken. When XIV 0 is received, the CPU should initiate an INTA cycle to obtain the interrupt vector of the 8259-based interrupt. In these cases the interrupt controller we should be talking to WRT to masking on signalling EOI is the 8259 and not the I/O SAPIC. This requires adriver for the Intel 8259A which isn't available for ia64. Thus stop pretending to support ExtINTs and instead panic() so that if we come across hardware that has an Intel 8259A, so have something real to work with. o With XIVs for IPIs dynamically allocatedi and also based on priority, define the IPI_* symbols as variables rather than constants. The variable holds the XIV allocated for the IPI. o IPI_STOP_HARD delivers a NMI if possible. Otherwise the XIV assigned to IPI_STOP is delivered.
2010-03-17 00:37:15 +00:00
void ia64_xiv_init(void);
u_int ia64_xiv_alloc(u_int, enum ia64_xiv_use, ia64_ihtype);
int ia64_xiv_free(u_int, enum ia64_xiv_use);
int ia64_xiv_reserve(u_int, enum ia64_xiv_use, ia64_ihtype);
Implement interrupt to CPU binding. Assign interrupts to CPUs in a round-robin fashion, starting with the highest priority interrupt on the highest-numbered CPU and cycling downwards.
2010-03-27 05:40:50 +00:00
int sapic_bind_intr(u_int, struct pcpu *);
Interrupt related cleanups: o Assign vectors based on priority, because vectors have implied priority in hardware. o Use unordered memory accesses to the I/O sapic and use the acceptance form of the mf instruction. o Remove the sapicreg.h and sapicvar.h headers. All definitions in sapicreg.h are private to sapic.c and all definitions in sapicvar.h are either private or interface functions. Move the interface functions to intr.h. o Hide the definition of struct sapic.
2010-02-27 18:55:43 +00:00
int sapic_config_intr(u_int, enum intr_trigger, enum intr_polarity);
struct sapic *sapic_create(u_int, u_int, uint64_t);
int sapic_enable(struct sapic *, u_int, u_int);
void sapic_eoi(struct sapic *, u_int);
struct sapic *sapic_lookup(u_int, u_int *);
void sapic_mask(struct sapic *, u_int);
void sapic_unmask(struct sapic *, u_int);
#ifdef DDB
void sapic_print(struct sapic *, u_int);
#endif
This is the first snapshot of the FreeBSD/ia64 kernel. This kernel will not work on any real hardware (or fully work on any simulator). Much more needs to happen before this is actually functional but its nice to see the FreeBSD copyright message appear in the ia64 simulator.
2000-09-29 13:46:07 +00:00
#endif /* !_MACHINE_INTR_H_ */
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