include/interrupts.h - skiboot - Git at Google

 // SPDX-License-Identifier: Apache-2.0 OR GPL-2.0-or-later
 /* Copyright 2013-2019 IBM Corp. */

 #ifndef __INTERRUPTS_H
 #define __INTERRUPTS_H

 #include <stdint.h>
 #include <ccan/list/list.h>

 /* Note about interrupt numbers on P8
  * ==================================
  *
  * On P8 the interrupts numbers are just a flat space of 19-bit,
  * there is no BUID or similar.
  *
  * However, various unit tend to require blocks of interrupt that
  * are naturally power-of-two aligned
  *
  * Our P8 Interrupt map consits thus of dividing the chip space
  * into "blocks" of 2048 interrupts. Block 0 is for random chip
  * interrupt sources (NX, PSI, OCC, ...) and keeps sources 0..15
  * clear to avoid conflits with IPIs etc.... Block 1..n are assigned
  * to PHB 0..n respectively. The number of blocks is determined by the
  * number of bits assigned to chips.
  *
  * That gives us an interrupt number made of:
  *  18               n+1 n   11  10                         0
  *  |                  | |    | |                           |
  * +--------------------+------+-----------------------------+
  * |        Chip#       | PHB# |             IVE#            |
  * +--------------------+------+-----------------------------+
  *
  * Where n = 18 - p8_chip_id_bits
  *
  * For P8 we have 6 bits for Chip# as defined by p8_chip_id_bits. We
  * therefore support a max of 2^6 = 64 chips.
  *
  * For P8NVL we have an extra PHB and so we assign 5 bits for Chip#
  * and therefore support a max of 32 chips.
  *
  * Each PHB supports 2K interrupt sources, which is shared by
  * LSI and MSI. With default configuration, MSI would use range
  * [0, 0x7f7] and LSI would use [0x7f8, 0x7ff]. The interrupt
  * source should be combined with IRSN to form final hardware
  * IRQ.
  *
  */

 uint32_t p8_chip_irq_block_base(uint32_t chip, uint32_t block);
 uint32_t p8_chip_irq_phb_base(uint32_t chip, uint32_t phb);
 uint32_t p8_irq_to_chip(uint32_t irq);
 uint32_t p8_irq_to_block(uint32_t irq);
 uint32_t p8_irq_to_phb(uint32_t irq);

 /* Total number of bits in the P8 interrupt space */
 #define P8_IRQ_BITS		19

 /* Number of bits per block */
 #define P8_IVE_BITS		11

 #define P8_IRQ_BLOCK_MISC	0
 #define P8_IRQ_BLOCK_PHB_BASE	1

 /* Assignment of the "MISC" block:
  * -------------------------------
  *
  * PSI interface has 6 interrupt sources:
  *
  * FSP, OCC, FSI, LPC, Local error, Host error
  *
  * and thus needs a block of 8
  */
 #define P8_IRQ_MISC_PSI_BASE		0x10	/* 0x10..0x17 */

 /* These are handled by skiboot */
 #define P8_IRQ_PSI_FSP			0
 #define P8_IRQ_PSI_OCC			1
 #define P8_IRQ_PSI_FSI			2
 #define P8_IRQ_PSI_LPC			3
 #define P8_IRQ_PSI_LOCAL_ERR		4
 #define P8_IRQ_PSI_EXTERNAL		5	/* Used for UART */
 #define P8_IRQ_PSI_IRQ_COUNT		6

 /* TBD: NX, AS, ...
  */

 /* Note about interrupt numbers on P9
  * ==================================
  *
  * P9 uses a completely different interrupt controller, XIVE.
  *
  * It targets objects using a combination of block number and
  * index within a block. However, we try to avoid exposing that
  * split to the OS in order to keep some abstraction in case the
  * way we allocate these change.
  *
  * The lowest level entity in Xive is the ESB (state bits).
  *
  * Those are spread between PHBs, PSI bridge and XIVE itself which
  * provide a large amount of state bits for IPIs and other SW and HW
  * generated interrupts by sources that don't have their own ESB logic
  *
  * Due to that spread, they aren't a good representation of a global
  * interrupt number.
  *
  * Each such source however needs to be targetted at an EAS (IVT)
  * entry in a table which will control targetting information and
  * associate that interrupt with a logical number.
  *
  * Thus that table entry number represents a good "global interrupt
  * number". Additionally, for the host OS, we will keep the logical
  * number equal to the global number.
  *
  * The details of how these are assigned on P9 can be found in
  * hw/xive.c. P9 HW will only use a subset of the definitions and
  * functions in this file (or the corresponding core/interrupts.c).
  */

 struct irq_source;

 /*
  * IRQ sources register themselves here.
  *
  * The "attributes" callback provides various attributes specific to
  * a given interrupt, such as whether it's targetted at OPAL or the
  * OS, or whether it's frequent or infrequent. The latter will be used
  * later to optimize the lookup of the sources array by providing a small
  * cache of the frequent interrupts.
  *
  * The "eoi" callback is used for XIVE interrupts in XICS emulation
  * though we might expose it at some point in XIVE native mode for
  * interrupts that require special EOI operations such as possibly
  * the LPC interrupts on P9 that need a latch cleared in the LPCHC.
  *
  * The "name" callback returns a name for the interrupt in a new
  * malloc()'ed block. The caller will free() it. NULL is acceptable.
  */
 struct irq_source_ops {
 	int64_t (*set_xive)(struct irq_source *is, uint32_t isn,
 			    uint16_t server, uint8_t priority);
 	int64_t (*get_xive)(struct irq_source *is, uint32_t isn,
 			    uint16_t *server, uint8_t *priority);
 	uint64_t (*attributes)(struct irq_source *is, uint32_t isn);
 /* LSB is the target */
 #define IRQ_ATTR_TARGET_OPAL		0x0
 #define IRQ_ATTR_TARGET_LINUX		0x1
 /* For OPAL interrupts, estimate frequency */
 #define IRQ_ATTR_TARGET_RARE		0x0
 #define IRQ_ATTR_TARGET_FREQUENT	0x2
 /* For OPAL interrupts, level vs. edge setting */
 #define IRQ_ATTR_TYPE_LSI		0x0
 #define IRQ_ATTR_TYPE_MSI		0x4
 	void (*interrupt)(struct irq_source *is, uint32_t isn);
 	void (*eoi)(struct irq_source *is, uint32_t isn);
 	char *(*name)(struct irq_source *is, uint32_t isn);
 	bool (*has_opal_interrupts)(struct irq_source *is);
 };

 struct irq_source {
 	uint32_t			start;
 	uint32_t			end;
 	const struct irq_source_ops	*ops;
 	void				*data;
 	struct list_node		link;
 };

 extern void __register_irq_source(struct irq_source *is, bool secondary);
 extern void register_irq_source(const struct irq_source_ops *ops, void *data,
 				uint32_t start, uint32_t count);
 extern void unregister_irq_source(uint32_t start, uint32_t count);
 extern struct irq_source *irq_find_source(uint32_t isn);

 /* Warning: callback is called with internal source lock held
  * so don't call back into any of our irq_ APIs from it
  */
 extern void irq_for_each_source(void (*cb)(struct irq_source *, void *),
 				void *data);

 extern uint32_t get_psi_interrupt(uint32_t chip_id);

 extern struct dt_node *add_ics_node(void);
 extern void add_opal_interrupts(void);
 extern uint32_t get_ics_phandle(void);

 struct cpu_thread;

 extern void reset_cpu_icp(void);
 extern void icp_send_eoi(uint32_t interrupt);
 extern void icp_prep_for_pm(void);
 extern void icp_kick_cpu(struct cpu_thread *cpu);

 extern void init_interrupts(void);

 extern bool irq_source_eoi(uint32_t isn);
 extern bool __irq_source_eoi(struct irq_source *is, uint32_t isn);


 #endif /* __INTERRUPTS_H */
	// SPDX-License-Identifier: Apache-2.0 OR GPL-2.0-or-later
	/* Copyright 2013-2019 IBM Corp. */

	#ifndef __INTERRUPTS_H
	#define __INTERRUPTS_H

	#include <stdint.h>
	#include <ccan/list/list.h>

	/* Note about interrupt numbers on P8
	* ==================================
	*
	* On P8 the interrupts numbers are just a flat space of 19-bit,
	* there is no BUID or similar.
	*
	* However, various unit tend to require blocks of interrupt that
	* are naturally power-of-two aligned
	*
	* Our P8 Interrupt map consits thus of dividing the chip space
	* into "blocks" of 2048 interrupts. Block 0 is for random chip
	* interrupt sources (NX, PSI, OCC, ...) and keeps sources 0..15
	* clear to avoid conflits with IPIs etc.... Block 1..n are assigned
	* to PHB 0..n respectively. The number of blocks is determined by the
	* number of bits assigned to chips.
	*
	* That gives us an interrupt number made of:
	* 18 n+1 n 11 10 0
	* \| \| \| \| \| \|
	* +--------------------+------+-----------------------------+
	* \| Chip# \| PHB# \| IVE# \|
	* +--------------------+------+-----------------------------+
	*
	* Where n = 18 - p8_chip_id_bits
	*
	* For P8 we have 6 bits for Chip# as defined by p8_chip_id_bits. We
	* therefore support a max of 2^6 = 64 chips.
	*
	* For P8NVL we have an extra PHB and so we assign 5 bits for Chip#
	* and therefore support a max of 32 chips.
	*
	* Each PHB supports 2K interrupt sources, which is shared by
	* LSI and MSI. With default configuration, MSI would use range
	* [0, 0x7f7] and LSI would use [0x7f8, 0x7ff]. The interrupt
	* source should be combined with IRSN to form final hardware
	* IRQ.
	*
	*/

	uint32_t p8_chip_irq_block_base(uint32_t chip, uint32_t block);
	uint32_t p8_chip_irq_phb_base(uint32_t chip, uint32_t phb);
	uint32_t p8_irq_to_chip(uint32_t irq);
	uint32_t p8_irq_to_block(uint32_t irq);
	uint32_t p8_irq_to_phb(uint32_t irq);

	/* Total number of bits in the P8 interrupt space */
	#define P8_IRQ_BITS 19

	/* Number of bits per block */
	#define P8_IVE_BITS 11

	#define P8_IRQ_BLOCK_MISC 0
	#define P8_IRQ_BLOCK_PHB_BASE 1

	/* Assignment of the "MISC" block:
	* -------------------------------
	*
	* PSI interface has 6 interrupt sources:
	*
	* FSP, OCC, FSI, LPC, Local error, Host error
	*
	* and thus needs a block of 8
	*/
	#define P8_IRQ_MISC_PSI_BASE 0x10 /* 0x10..0x17 */

	/* These are handled by skiboot */
	#define P8_IRQ_PSI_FSP 0
	#define P8_IRQ_PSI_OCC 1
	#define P8_IRQ_PSI_FSI 2
	#define P8_IRQ_PSI_LPC 3
	#define P8_IRQ_PSI_LOCAL_ERR 4
	#define P8_IRQ_PSI_EXTERNAL 5 /* Used for UART */
	#define P8_IRQ_PSI_IRQ_COUNT 6

	/* TBD: NX, AS, ...
	*/

	/* Note about interrupt numbers on P9
	* ==================================
	*
	* P9 uses a completely different interrupt controller, XIVE.
	*
	* It targets objects using a combination of block number and
	* index within a block. However, we try to avoid exposing that
	* split to the OS in order to keep some abstraction in case the
	* way we allocate these change.
	*
	* The lowest level entity in Xive is the ESB (state bits).
	*
	* Those are spread between PHBs, PSI bridge and XIVE itself which
	* provide a large amount of state bits for IPIs and other SW and HW
	* generated interrupts by sources that don't have their own ESB logic
	*
	* Due to that spread, they aren't a good representation of a global
	* interrupt number.
	*
	* Each such source however needs to be targetted at an EAS (IVT)
	* entry in a table which will control targetting information and
	* associate that interrupt with a logical number.
	*
	* Thus that table entry number represents a good "global interrupt
	* number". Additionally, for the host OS, we will keep the logical
	* number equal to the global number.
	*
	* The details of how these are assigned on P9 can be found in
	* hw/xive.c. P9 HW will only use a subset of the definitions and
	* functions in this file (or the corresponding core/interrupts.c).
	*/

	struct irq_source;

	/*
	* IRQ sources register themselves here.
	*
	* The "attributes" callback provides various attributes specific to
	* a given interrupt, such as whether it's targetted at OPAL or the
	* OS, or whether it's frequent or infrequent. The latter will be used
	* later to optimize the lookup of the sources array by providing a small
	* cache of the frequent interrupts.
	*
	* The "eoi" callback is used for XIVE interrupts in XICS emulation
	* though we might expose it at some point in XIVE native mode for
	* interrupts that require special EOI operations such as possibly
	* the LPC interrupts on P9 that need a latch cleared in the LPCHC.
	*
	* The "name" callback returns a name for the interrupt in a new
	* malloc()'ed block. The caller will free() it. NULL is acceptable.
	*/
	struct irq_source_ops {
	int64_t (set_xive)(struct irq_source is, uint32_t isn,
	uint16_t server, uint8_t priority);
	int64_t (get_xive)(struct irq_source is, uint32_t isn,
	uint16_t server, uint8_t priority);
	uint64_t (attributes)(struct irq_source is, uint32_t isn);
	/* LSB is the target */
	#define IRQ_ATTR_TARGET_OPAL 0x0
	#define IRQ_ATTR_TARGET_LINUX 0x1
	/* For OPAL interrupts, estimate frequency */
	#define IRQ_ATTR_TARGET_RARE 0x0
	#define IRQ_ATTR_TARGET_FREQUENT 0x2
	/* For OPAL interrupts, level vs. edge setting */
	#define IRQ_ATTR_TYPE_LSI 0x0
	#define IRQ_ATTR_TYPE_MSI 0x4
	void (interrupt)(struct irq_source is, uint32_t isn);
	void (eoi)(struct irq_source is, uint32_t isn);
	char (name)(struct irq_source *is, uint32_t isn);
	bool (has_opal_interrupts)(struct irq_source is);
	};

	struct irq_source {
	uint32_t start;
	uint32_t end;
	const struct irq_source_ops *ops;
	void *data;
	struct list_node link;
	};

	extern void __register_irq_source(struct irq_source *is, bool secondary);
	extern void register_irq_source(const struct irq_source_ops ops, void data,
	uint32_t start, uint32_t count);
	extern void unregister_irq_source(uint32_t start, uint32_t count);
	extern struct irq_source *irq_find_source(uint32_t isn);

	/* Warning: callback is called with internal source lock held
	* so don't call back into any of our irq_ APIs from it
	*/
	extern void irq_for_each_source(void (cb)(struct irq_source , void *),
	void *data);

	extern uint32_t get_psi_interrupt(uint32_t chip_id);

	extern struct dt_node *add_ics_node(void);
	extern void add_opal_interrupts(void);
	extern uint32_t get_ics_phandle(void);

	struct cpu_thread;

	extern void reset_cpu_icp(void);
	extern void icp_send_eoi(uint32_t interrupt);
	extern void icp_prep_for_pm(void);
	extern void icp_kick_cpu(struct cpu_thread *cpu);

	extern void init_interrupts(void);

	extern bool irq_source_eoi(uint32_t isn);
	extern bool __irq_source_eoi(struct irq_source *is, uint32_t isn);


	#endif /* __INTERRUPTS_H */