arm-spe-pkt-decoder.h - cachepc-linux - Fork of AMDESE/linux with modifications for CachePC side-channel attack

	cachepc-linux Fork of AMDESE/linux with modifications for CachePC side-channel attack
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arm-spe-pkt-decoder.h (4604B)
      1/* SPDX-License-Identifier: GPL-2.0 */
      2/*
      3 * Arm Statistical Profiling Extensions (SPE) support
      4 * Copyright (c) 2017-2018, Arm Ltd.
      5 */
      6
      7#ifndef INCLUDE__ARM_SPE_PKT_DECODER_H__
      8#define INCLUDE__ARM_SPE_PKT_DECODER_H__
      9
     10#include <stddef.h>
     11#include <stdint.h>
     12
     13#define ARM_SPE_PKT_DESC_MAX		256
     14
     15#define ARM_SPE_NEED_MORE_BYTES		-1
     16#define ARM_SPE_BAD_PACKET		-2
     17
     18#define ARM_SPE_PKT_MAX_SZ		16
     19
     20enum arm_spe_pkt_type {
     21	ARM_SPE_BAD,
     22	ARM_SPE_PAD,
     23	ARM_SPE_END,
     24	ARM_SPE_TIMESTAMP,
     25	ARM_SPE_ADDRESS,
     26	ARM_SPE_COUNTER,
     27	ARM_SPE_CONTEXT,
     28	ARM_SPE_OP_TYPE,
     29	ARM_SPE_EVENTS,
     30	ARM_SPE_DATA_SOURCE,
     31};
     32
     33struct arm_spe_pkt {
     34	enum arm_spe_pkt_type	type;
     35	unsigned char		index;
     36	uint64_t		payload;
     37};
     38
     39/* Short header (HEADER0) and extended header (HEADER1) */
     40#define SPE_HEADER0_PAD				0x0
     41#define SPE_HEADER0_END				0x1
     42#define SPE_HEADER0_TIMESTAMP			0x71
     43/* Mask for event & data source */
     44#define SPE_HEADER0_MASK1			(GENMASK_ULL(7, 6) | GENMASK_ULL(3, 0))
     45#define SPE_HEADER0_EVENTS			0x42
     46#define SPE_HEADER0_SOURCE			0x43
     47/* Mask for context & operation */
     48#define SPE_HEADER0_MASK2			GENMASK_ULL(7, 2)
     49#define SPE_HEADER0_CONTEXT			0x64
     50#define SPE_HEADER0_OP_TYPE			0x48
     51/* Mask for extended format */
     52#define SPE_HEADER0_EXTENDED			0x20
     53/* Mask for address & counter */
     54#define SPE_HEADER0_MASK3			GENMASK_ULL(7, 3)
     55#define SPE_HEADER0_ADDRESS			0xb0
     56#define SPE_HEADER0_COUNTER			0x98
     57#define SPE_HEADER1_ALIGNMENT			0x0
     58
     59#define SPE_HDR_SHORT_INDEX(h)			((h) & GENMASK_ULL(2, 0))
     60#define SPE_HDR_EXTENDED_INDEX(h0, h1)		(((h0) & GENMASK_ULL(1, 0)) << 3 | \
     61						 SPE_HDR_SHORT_INDEX(h1))
     62
     63/* Address packet header */
     64#define SPE_ADDR_PKT_HDR_INDEX_INS		0x0
     65#define SPE_ADDR_PKT_HDR_INDEX_BRANCH		0x1
     66#define SPE_ADDR_PKT_HDR_INDEX_DATA_VIRT	0x2
     67#define SPE_ADDR_PKT_HDR_INDEX_DATA_PHYS	0x3
     68
     69/* Address packet payload */
     70#define SPE_ADDR_PKT_ADDR_BYTE7_SHIFT		56
     71#define SPE_ADDR_PKT_ADDR_GET_BYTES_0_6(v)	((v) & GENMASK_ULL(55, 0))
     72#define SPE_ADDR_PKT_ADDR_GET_BYTE_6(v)		(((v) & GENMASK_ULL(55, 48)) >> 48)
     73
     74#define SPE_ADDR_PKT_GET_NS(v)			(((v) & BIT_ULL(63)) >> 63)
     75#define SPE_ADDR_PKT_GET_EL(v)			(((v) & GENMASK_ULL(62, 61)) >> 61)
     76#define SPE_ADDR_PKT_GET_CH(v)			(((v) & BIT_ULL(62)) >> 62)
     77#define SPE_ADDR_PKT_GET_PAT(v)			(((v) & GENMASK_ULL(59, 56)) >> 56)
     78
     79#define SPE_ADDR_PKT_EL0			0
     80#define SPE_ADDR_PKT_EL1			1
     81#define SPE_ADDR_PKT_EL2			2
     82#define SPE_ADDR_PKT_EL3			3
     83
     84/* Context packet header */
     85#define SPE_CTX_PKT_HDR_INDEX(h)		((h) & GENMASK_ULL(1, 0))
     86
     87/* Counter packet header */
     88#define SPE_CNT_PKT_HDR_INDEX_TOTAL_LAT		0x0
     89#define SPE_CNT_PKT_HDR_INDEX_ISSUE_LAT		0x1
     90#define SPE_CNT_PKT_HDR_INDEX_TRANS_LAT		0x2
     91
     92/* Event packet payload */
     93enum arm_spe_events {
     94	EV_EXCEPTION_GEN	= 0,
     95	EV_RETIRED		= 1,
     96	EV_L1D_ACCESS		= 2,
     97	EV_L1D_REFILL		= 3,
     98	EV_TLB_ACCESS		= 4,
     99	EV_TLB_WALK		= 5,
    100	EV_NOT_TAKEN		= 6,
    101	EV_MISPRED		= 7,
    102	EV_LLC_ACCESS		= 8,
    103	EV_LLC_MISS		= 9,
    104	EV_REMOTE_ACCESS	= 10,
    105	EV_ALIGNMENT		= 11,
    106	EV_PARTIAL_PREDICATE	= 17,
    107	EV_EMPTY_PREDICATE	= 18,
    108};
    109
    110/* Operation packet header */
    111#define SPE_OP_PKT_HDR_CLASS(h)			((h) & GENMASK_ULL(1, 0))
    112#define SPE_OP_PKT_HDR_CLASS_OTHER		0x0
    113#define SPE_OP_PKT_HDR_CLASS_LD_ST_ATOMIC	0x1
    114#define SPE_OP_PKT_HDR_CLASS_BR_ERET		0x2
    115
    116#define SPE_OP_PKT_IS_OTHER_SVE_OP(v)		(((v) & (BIT(7) | BIT(3) | BIT(0))) == 0x8)
    117
    118#define SPE_OP_PKT_COND				BIT(0)
    119
    120#define SPE_OP_PKT_LDST_SUBCLASS_GET(v)		((v) & GENMASK_ULL(7, 1))
    121#define SPE_OP_PKT_LDST_SUBCLASS_GP_REG		0x0
    122#define SPE_OP_PKT_LDST_SUBCLASS_SIMD_FP	0x4
    123#define SPE_OP_PKT_LDST_SUBCLASS_UNSPEC_REG	0x10
    124#define SPE_OP_PKT_LDST_SUBCLASS_NV_SYSREG	0x30
    125
    126#define SPE_OP_PKT_IS_LDST_ATOMIC(v)		(((v) & (GENMASK_ULL(7, 5) | BIT(1))) == 0x2)
    127
    128#define SPE_OP_PKT_AR				BIT(4)
    129#define SPE_OP_PKT_EXCL				BIT(3)
    130#define SPE_OP_PKT_AT				BIT(2)
    131#define SPE_OP_PKT_ST				BIT(0)
    132
    133#define SPE_OP_PKT_IS_LDST_SVE(v)		(((v) & (BIT(3) | BIT(1))) == 0x8)
    134
    135#define SPE_OP_PKT_SVE_SG			BIT(7)
    136/*
    137 * SVE effective vector length (EVL) is stored in byte 0 bits [6:4];
    138 * the length is rounded up to a power of two and use 32 as one step,
    139 * so EVL calculation is:
    140 *
    141 *   32 * (2 ^ bits [6:4]) = 32 << (bits [6:4])
    142 */
    143#define SPE_OP_PKG_SVE_EVL(v)			(32 << (((v) & GENMASK_ULL(6, 4)) >> 4))
    144#define SPE_OP_PKT_SVE_PRED			BIT(2)
    145#define SPE_OP_PKT_SVE_FP			BIT(1)
    146
    147#define SPE_OP_PKT_IS_INDIRECT_BRANCH(v)	(((v) & GENMASK_ULL(7, 1)) == 0x2)
    148
    149const char *arm_spe_pkt_name(enum arm_spe_pkt_type);
    150
    151int arm_spe_get_packet(const unsigned char *buf, size_t len,
    152		       struct arm_spe_pkt *packet);
    153
    154int arm_spe_pkt_desc(const struct arm_spe_pkt *packet, char *buf, size_t len);
    155#endif