arch/powerpc/include/asm/xive-regs.h - linux/kernel/git/will/linux - Git at Google

 /* SPDX-License-Identifier: GPL-2.0-or-later */
 /*
  * Copyright 2016,2017 IBM Corporation.
  */
 #ifndef _ASM_POWERPC_XIVE_REGS_H
 #define _ASM_POWERPC_XIVE_REGS_H

 /*
  * "magic" Event State Buffer (ESB) MMIO offsets.
  *
  * Each interrupt source has a 2-bit state machine called ESB
  * which can be controlled by MMIO. It's made of 2 bits, P and
  * Q. P indicates that an interrupt is pending (has been sent
  * to a queue and is waiting for an EOI). Q indicates that the
  * interrupt has been triggered while pending.
  *
  * This acts as a coalescing mechanism in order to guarantee
  * that a given interrupt only occurs at most once in a queue.
  *
  * When doing an EOI, the Q bit will indicate if the interrupt
  * needs to be re-triggered.
  *
  * The following offsets into the ESB MMIO allow to read or
  * manipulate the PQ bits. They must be used with an 8-bytes
  * load instruction. They all return the previous state of the
  * interrupt (atomically).
  *
  * Additionally, some ESB pages support doing an EOI via a
  * store at 0 and some ESBs support doing a trigger via a
  * separate trigger page.
  */
 #define XIVE_ESB_STORE_EOI	0x400 /* Store */
 #define XIVE_ESB_LOAD_EOI	0x000 /* Load */
 #define XIVE_ESB_GET		0x800 /* Load */
 #define XIVE_ESB_SET_PQ_00	0xc00 /* Load */
 #define XIVE_ESB_SET_PQ_01	0xd00 /* Load */
 #define XIVE_ESB_SET_PQ_10	0xe00 /* Load */
 #define XIVE_ESB_SET_PQ_11	0xf00 /* Load */

 #define XIVE_ESB_VAL_P		0x2
 #define XIVE_ESB_VAL_Q		0x1

 /*
  * Thread Management (aka "TM") registers
  */

 /* TM register offsets */
 #define TM_QW0_USER		0x000 /* All rings */
 #define TM_QW1_OS		0x010 /* Ring 0..2 */
 #define TM_QW2_HV_POOL		0x020 /* Ring 0..1 */
 #define TM_QW3_HV_PHYS		0x030 /* Ring 0..1 */

 /* Byte offsets inside a QW             QW0 QW1 QW2 QW3 */
 #define TM_NSR			0x0  /*  +   +   -   +  */
 #define TM_CPPR			0x1  /*  -   +   -   +  */
 #define TM_IPB			0x2  /*  -   +   +   +  */
 #define TM_LSMFB		0x3  /*  -   +   +   +  */
 #define TM_ACK_CNT		0x4  /*  -   +   -   -  */
 #define TM_INC			0x5  /*  -   +   -   +  */
 #define TM_AGE			0x6  /*  -   +   -   +  */
 #define TM_PIPR			0x7  /*  -   +   -   +  */

 #define TM_WORD0		0x0
 #define TM_WORD1		0x4

 /*
  * QW word 2 contains the valid bit at the top and other fields
  * depending on the QW.
  */
 #define TM_WORD2		0x8
 #define   TM_QW0W2_VU		PPC_BIT32(0)
 #define   TM_QW0W2_LOGIC_SERV	PPC_BITMASK32(1,31) // XX 2,31 ?
 #define   TM_QW1W2_VO		PPC_BIT32(0)
 #define   TM_QW1W2_OS_CAM	PPC_BITMASK32(8,31)
 #define   TM_QW2W2_VP		PPC_BIT32(0)
 #define   TM_QW2W2_POOL_CAM	PPC_BITMASK32(8,31)
 #define   TM_QW3W2_VT		PPC_BIT32(0)
 #define   TM_QW3W2_LP		PPC_BIT32(6)
 #define   TM_QW3W2_LE		PPC_BIT32(7)
 #define   TM_QW3W2_T		PPC_BIT32(31)

 /*
  * In addition to normal loads to "peek" and writes (only when invalid)
  * using 4 and 8 bytes accesses, the above registers support these
  * "special" byte operations:
  *
  *   - Byte load from QW0[NSR] - User level NSR (EBB)
  *   - Byte store to QW0[NSR] - User level NSR (EBB)
  *   - Byte load/store to QW1[CPPR] and QW3[CPPR] - CPPR access
  *   - Byte load from QW3[TM_WORD2] - Read VT||00000||LP||LE on thrd 0
  *                                    otherwise VT||0000000
  *   - Byte store to QW3[TM_WORD2] - Set VT bit (and LP/LE if present)
  *
  * Then we have all these "special" CI ops at these offset that trigger
  * all sorts of side effects:
  */
 #define TM_SPC_ACK_EBB		0x800	/* Load8 ack EBB to reg*/
 #define TM_SPC_ACK_OS_REG	0x810	/* Load16 ack OS irq to reg */
 #define TM_SPC_PUSH_USR_CTX	0x808	/* Store32 Push/Validate user context */
 #define TM_SPC_PULL_USR_CTX	0x808	/* Load32 Pull/Invalidate user context */
 #define TM_SPC_SET_OS_PENDING	0x812	/* Store8 Set OS irq pending bit */
 #define TM_SPC_PULL_OS_CTX	0x818	/* Load32/Load64 Pull/Invalidate OS context to reg */
 #define TM_SPC_PULL_POOL_CTX	0x828	/* Load32/Load64 Pull/Invalidate Pool context to reg*/
 #define TM_SPC_ACK_HV_REG	0x830	/* Load16 ack HV irq to reg */
 #define TM_SPC_PULL_USR_CTX_OL	0xc08	/* Store8 Pull/Inval usr ctx to odd line */
 #define TM_SPC_ACK_OS_EL	0xc10	/* Store8 ack OS irq to even line */
 #define TM_SPC_ACK_HV_POOL_EL	0xc20	/* Store8 ack HV evt pool to even line */
 #define TM_SPC_ACK_HV_EL	0xc30	/* Store8 ack HV irq to even line */
 /* XXX more... */

 /* NSR fields for the various QW ack types */
 #define TM_QW0_NSR_EB		PPC_BIT8(0)
 #define TM_QW1_NSR_EO		PPC_BIT8(0)
 #define TM_QW3_NSR_HE		PPC_BITMASK8(0,1)
 #define  TM_QW3_NSR_HE_NONE	0
 #define  TM_QW3_NSR_HE_POOL	1
 #define  TM_QW3_NSR_HE_PHYS	2
 #define  TM_QW3_NSR_HE_LSI	3
 #define TM_QW3_NSR_I		PPC_BIT8(2)
 #define TM_QW3_NSR_GRP_LVL	PPC_BIT8(3,7)

 #endif /* _ASM_POWERPC_XIVE_REGS_H */
	/* SPDX-License-Identifier: GPL-2.0-or-later */
	/*
	* Copyright 2016,2017 IBM Corporation.
	*/
	#ifndef _ASM_POWERPC_XIVE_REGS_H
	#define _ASM_POWERPC_XIVE_REGS_H

	/*
	* "magic" Event State Buffer (ESB) MMIO offsets.
	*
	* Each interrupt source has a 2-bit state machine called ESB
	* which can be controlled by MMIO. It's made of 2 bits, P and
	* Q. P indicates that an interrupt is pending (has been sent
	* to a queue and is waiting for an EOI). Q indicates that the
	* interrupt has been triggered while pending.
	*
	* This acts as a coalescing mechanism in order to guarantee
	* that a given interrupt only occurs at most once in a queue.
	*
	* When doing an EOI, the Q bit will indicate if the interrupt
	* needs to be re-triggered.
	*
	* The following offsets into the ESB MMIO allow to read or
	* manipulate the PQ bits. They must be used with an 8-bytes
	* load instruction. They all return the previous state of the
	* interrupt (atomically).
	*
	* Additionally, some ESB pages support doing an EOI via a
	* store at 0 and some ESBs support doing a trigger via a
	* separate trigger page.
	*/
	#define XIVE_ESB_STORE_EOI 0x400 /* Store */
	#define XIVE_ESB_LOAD_EOI 0x000 /* Load */
	#define XIVE_ESB_GET 0x800 /* Load */
	#define XIVE_ESB_SET_PQ_00 0xc00 /* Load */
	#define XIVE_ESB_SET_PQ_01 0xd00 /* Load */
	#define XIVE_ESB_SET_PQ_10 0xe00 /* Load */
	#define XIVE_ESB_SET_PQ_11 0xf00 /* Load */

	#define XIVE_ESB_VAL_P 0x2
	#define XIVE_ESB_VAL_Q 0x1

	/*
	* Thread Management (aka "TM") registers
	*/

	/* TM register offsets */
	#define TM_QW0_USER 0x000 /* All rings */
	#define TM_QW1_OS 0x010 /* Ring 0..2 */
	#define TM_QW2_HV_POOL 0x020 /* Ring 0..1 */
	#define TM_QW3_HV_PHYS 0x030 /* Ring 0..1 */

	/* Byte offsets inside a QW QW0 QW1 QW2 QW3 */
	#define TM_NSR 0x0 /* + + - + */
	#define TM_CPPR 0x1 /* - + - + */
	#define TM_IPB 0x2 /* - + + + */
	#define TM_LSMFB 0x3 /* - + + + */
	#define TM_ACK_CNT 0x4 /* - + - - */
	#define TM_INC 0x5 /* - + - + */
	#define TM_AGE 0x6 /* - + - + */
	#define TM_PIPR 0x7 /* - + - + */

	#define TM_WORD0 0x0
	#define TM_WORD1 0x4

	/*
	* QW word 2 contains the valid bit at the top and other fields
	* depending on the QW.
	*/
	#define TM_WORD2 0x8
	#define TM_QW0W2_VU PPC_BIT32(0)
	#define TM_QW0W2_LOGIC_SERV PPC_BITMASK32(1,31) // XX 2,31 ?
	#define TM_QW1W2_VO PPC_BIT32(0)
	#define TM_QW1W2_OS_CAM PPC_BITMASK32(8,31)
	#define TM_QW2W2_VP PPC_BIT32(0)
	#define TM_QW2W2_POOL_CAM PPC_BITMASK32(8,31)
	#define TM_QW3W2_VT PPC_BIT32(0)
	#define TM_QW3W2_LP PPC_BIT32(6)
	#define TM_QW3W2_LE PPC_BIT32(7)
	#define TM_QW3W2_T PPC_BIT32(31)

	/*
	* In addition to normal loads to "peek" and writes (only when invalid)
	* using 4 and 8 bytes accesses, the above registers support these
	* "special" byte operations:
	*
	* - Byte load from QW0[NSR] - User level NSR (EBB)
	* - Byte store to QW0[NSR] - User level NSR (EBB)
	* - Byte load/store to QW1[CPPR] and QW3[CPPR] - CPPR access
	* - Byte load from QW3[TM_WORD2] - Read VT\|\|00000\|\|LP\|\|LE on thrd 0
	* otherwise VT\|\|0000000
	* - Byte store to QW3[TM_WORD2] - Set VT bit (and LP/LE if present)
	*
	* Then we have all these "special" CI ops at these offset that trigger
	* all sorts of side effects:
	*/
	#define TM_SPC_ACK_EBB 0x800 /* Load8 ack EBB to reg*/
	#define TM_SPC_ACK_OS_REG 0x810 /* Load16 ack OS irq to reg */
	#define TM_SPC_PUSH_USR_CTX 0x808 /* Store32 Push/Validate user context */
	#define TM_SPC_PULL_USR_CTX 0x808 /* Load32 Pull/Invalidate user context */
	#define TM_SPC_SET_OS_PENDING 0x812 /* Store8 Set OS irq pending bit */
	#define TM_SPC_PULL_OS_CTX 0x818 /* Load32/Load64 Pull/Invalidate OS context to reg */
	#define TM_SPC_PULL_POOL_CTX 0x828 /* Load32/Load64 Pull/Invalidate Pool context to reg*/
	#define TM_SPC_ACK_HV_REG 0x830 /* Load16 ack HV irq to reg */
	#define TM_SPC_PULL_USR_CTX_OL 0xc08 /* Store8 Pull/Inval usr ctx to odd line */
	#define TM_SPC_ACK_OS_EL 0xc10 /* Store8 ack OS irq to even line */
	#define TM_SPC_ACK_HV_POOL_EL 0xc20 /* Store8 ack HV evt pool to even line */
	#define TM_SPC_ACK_HV_EL 0xc30 /* Store8 ack HV irq to even line */
	/* XXX more... */

	/* NSR fields for the various QW ack types */
	#define TM_QW0_NSR_EB PPC_BIT8(0)
	#define TM_QW1_NSR_EO PPC_BIT8(0)
	#define TM_QW3_NSR_HE PPC_BITMASK8(0,1)
	#define TM_QW3_NSR_HE_NONE 0
	#define TM_QW3_NSR_HE_POOL 1
	#define TM_QW3_NSR_HE_PHYS 2
	#define TM_QW3_NSR_HE_LSI 3
	#define TM_QW3_NSR_I PPC_BIT8(2)
	#define TM_QW3_NSR_GRP_LVL PPC_BIT8(3,7)

	#endif /* _ASM_POWERPC_XIVE_REGS_H */