linux-stable/include/uapi/linux/idxd.h
Dave Jiang f25b463883 dmaengine: idxd: add IAX configuration support in the IDXD driver
Add support to allow configuration of Intel Analytics Accelerator (IAX) in
addition to the Intel Data Streaming Accelerator (DSA). The IAX hardware
has the same configuration interface as DSA. The main difference
is the type of operations it performs. We can support the DSA and
IAX devices on the same driver with some tweaks.

IAX has a 64B completion record that needs to be 64B aligned, as opposed to
a 32B completion record that is 32B aligned for DSA. IAX also does not
support token management.

Signed-off-by: Dave Jiang <dave.jiang@intel.com>
Link: https://lore.kernel.org/r/160564555488.1834439.4261958859935360473.stgit@djiang5-desk3.ch.intel.com
Signed-off-by: Vinod Koul <vkoul@kernel.org>
2020-12-11 19:45:53 +05:30

305 lines
6.7 KiB
C

/* SPDX-License-Identifier: GPL-2.0 WITH Linux-syscall-note */
/* Copyright(c) 2019 Intel Corporation. All rights rsvd. */
#ifndef _USR_IDXD_H_
#define _USR_IDXD_H_
#ifdef __KERNEL__
#include <linux/types.h>
#else
#include <stdint.h>
#endif
/* Descriptor flags */
#define IDXD_OP_FLAG_FENCE 0x0001
#define IDXD_OP_FLAG_BOF 0x0002
#define IDXD_OP_FLAG_CRAV 0x0004
#define IDXD_OP_FLAG_RCR 0x0008
#define IDXD_OP_FLAG_RCI 0x0010
#define IDXD_OP_FLAG_CRSTS 0x0020
#define IDXD_OP_FLAG_CR 0x0080
#define IDXD_OP_FLAG_CC 0x0100
#define IDXD_OP_FLAG_ADDR1_TCS 0x0200
#define IDXD_OP_FLAG_ADDR2_TCS 0x0400
#define IDXD_OP_FLAG_ADDR3_TCS 0x0800
#define IDXD_OP_FLAG_CR_TCS 0x1000
#define IDXD_OP_FLAG_STORD 0x2000
#define IDXD_OP_FLAG_DRDBK 0x4000
#define IDXD_OP_FLAG_DSTS 0x8000
/* IAX */
#define IDXD_OP_FLAG_RD_SRC2_AECS 0x010000
/* Opcode */
enum dsa_opcode {
DSA_OPCODE_NOOP = 0,
DSA_OPCODE_BATCH,
DSA_OPCODE_DRAIN,
DSA_OPCODE_MEMMOVE,
DSA_OPCODE_MEMFILL,
DSA_OPCODE_COMPARE,
DSA_OPCODE_COMPVAL,
DSA_OPCODE_CR_DELTA,
DSA_OPCODE_AP_DELTA,
DSA_OPCODE_DUALCAST,
DSA_OPCODE_CRCGEN = 0x10,
DSA_OPCODE_COPY_CRC,
DSA_OPCODE_DIF_CHECK,
DSA_OPCODE_DIF_INS,
DSA_OPCODE_DIF_STRP,
DSA_OPCODE_DIF_UPDT,
DSA_OPCODE_CFLUSH = 0x20,
};
enum iax_opcode {
IAX_OPCODE_NOOP = 0,
IAX_OPCODE_DRAIN = 2,
IAX_OPCODE_MEMMOVE,
IAX_OPCODE_DECOMPRESS = 0x42,
IAX_OPCODE_COMPRESS,
};
/* Completion record status */
enum dsa_completion_status {
DSA_COMP_NONE = 0,
DSA_COMP_SUCCESS,
DSA_COMP_SUCCESS_PRED,
DSA_COMP_PAGE_FAULT_NOBOF,
DSA_COMP_PAGE_FAULT_IR,
DSA_COMP_BATCH_FAIL,
DSA_COMP_BATCH_PAGE_FAULT,
DSA_COMP_DR_OFFSET_NOINC,
DSA_COMP_DR_OFFSET_ERANGE,
DSA_COMP_DIF_ERR,
DSA_COMP_BAD_OPCODE = 0x10,
DSA_COMP_INVALID_FLAGS,
DSA_COMP_NOZERO_RESERVE,
DSA_COMP_XFER_ERANGE,
DSA_COMP_DESC_CNT_ERANGE,
DSA_COMP_DR_ERANGE,
DSA_COMP_OVERLAP_BUFFERS,
DSA_COMP_DCAST_ERR,
DSA_COMP_DESCLIST_ALIGN,
DSA_COMP_INT_HANDLE_INVAL,
DSA_COMP_CRA_XLAT,
DSA_COMP_CRA_ALIGN,
DSA_COMP_ADDR_ALIGN,
DSA_COMP_PRIV_BAD,
DSA_COMP_TRAFFIC_CLASS_CONF,
DSA_COMP_PFAULT_RDBA,
DSA_COMP_HW_ERR1,
DSA_COMP_HW_ERR_DRB,
DSA_COMP_TRANSLATION_FAIL,
};
enum iax_completion_status {
IAX_COMP_NONE = 0,
IAX_COMP_SUCCESS,
IAX_COMP_PAGE_FAULT_IR = 0x04,
IAX_COMP_OUTBUF_OVERFLOW,
IAX_COMP_BAD_OPCODE = 0x10,
IAX_COMP_INVALID_FLAGS,
IAX_COMP_NOZERO_RESERVE,
IAX_COMP_INVALID_SIZE,
IAX_COMP_OVERLAP_BUFFERS = 0x16,
IAX_COMP_INT_HANDLE_INVAL = 0x19,
IAX_COMP_CRA_XLAT,
IAX_COMP_CRA_ALIGN,
IAX_COMP_ADDR_ALIGN,
IAX_COMP_PRIV_BAD,
IAX_COMP_TRAFFIC_CLASS_CONF,
IAX_COMP_PFAULT_RDBA,
IAX_COMP_HW_ERR1,
IAX_COMP_HW_ERR_DRB,
IAX_COMP_TRANSLATION_FAIL,
IAX_COMP_PRS_TIMEOUT,
IAX_COMP_WATCHDOG,
IAX_COMP_INVALID_COMP_FLAG = 0x30,
IAX_COMP_INVALID_FILTER_FLAG,
IAX_COMP_INVALID_NUM_ELEMS = 0x33,
};
#define DSA_COMP_STATUS_MASK 0x7f
#define DSA_COMP_STATUS_WRITE 0x80
struct dsa_hw_desc {
uint32_t pasid:20;
uint32_t rsvd:11;
uint32_t priv:1;
uint32_t flags:24;
uint32_t opcode:8;
uint64_t completion_addr;
union {
uint64_t src_addr;
uint64_t rdback_addr;
uint64_t pattern;
uint64_t desc_list_addr;
};
union {
uint64_t dst_addr;
uint64_t rdback_addr2;
uint64_t src2_addr;
uint64_t comp_pattern;
};
union {
uint32_t xfer_size;
uint32_t desc_count;
};
uint16_t int_handle;
uint16_t rsvd1;
union {
uint8_t expected_res;
/* create delta record */
struct {
uint64_t delta_addr;
uint32_t max_delta_size;
uint32_t delt_rsvd;
uint8_t expected_res_mask;
};
uint32_t delta_rec_size;
uint64_t dest2;
/* CRC */
struct {
uint32_t crc_seed;
uint32_t crc_rsvd;
uint64_t seed_addr;
};
/* DIF check or strip */
struct {
uint8_t src_dif_flags;
uint8_t dif_chk_res;
uint8_t dif_chk_flags;
uint8_t dif_chk_res2[5];
uint32_t chk_ref_tag_seed;
uint16_t chk_app_tag_mask;
uint16_t chk_app_tag_seed;
};
/* DIF insert */
struct {
uint8_t dif_ins_res;
uint8_t dest_dif_flag;
uint8_t dif_ins_flags;
uint8_t dif_ins_res2[13];
uint32_t ins_ref_tag_seed;
uint16_t ins_app_tag_mask;
uint16_t ins_app_tag_seed;
};
/* DIF update */
struct {
uint8_t src_upd_flags;
uint8_t upd_dest_flags;
uint8_t dif_upd_flags;
uint8_t dif_upd_res[5];
uint32_t src_ref_tag_seed;
uint16_t src_app_tag_mask;
uint16_t src_app_tag_seed;
uint32_t dest_ref_tag_seed;
uint16_t dest_app_tag_mask;
uint16_t dest_app_tag_seed;
};
uint8_t op_specific[24];
};
} __attribute__((packed));
struct iax_hw_desc {
uint32_t pasid:20;
uint32_t rsvd:11;
uint32_t priv:1;
uint32_t flags:24;
uint32_t opcode:8;
uint64_t completion_addr;
uint64_t src1_addr;
uint64_t dst_addr;
uint32_t src1_size;
uint16_t int_handle;
union {
uint16_t compr_flags;
uint16_t decompr_flags;
};
uint64_t src2_addr;
uint32_t max_dst_size;
uint32_t src2_size;
uint32_t filter_flags;
uint32_t num_inputs;
} __attribute__((packed));
struct dsa_raw_desc {
uint64_t field[8];
} __attribute__((packed));
/*
* The status field will be modified by hardware, therefore it should be
* volatile and prevent the compiler from optimize the read.
*/
struct dsa_completion_record {
volatile uint8_t status;
union {
uint8_t result;
uint8_t dif_status;
};
uint16_t rsvd;
uint32_t bytes_completed;
uint64_t fault_addr;
union {
/* common record */
struct {
uint32_t invalid_flags:24;
uint32_t rsvd2:8;
};
uint16_t delta_rec_size;
uint16_t crc_val;
/* DIF check & strip */
struct {
uint32_t dif_chk_ref_tag;
uint16_t dif_chk_app_tag_mask;
uint16_t dif_chk_app_tag;
};
/* DIF insert */
struct {
uint64_t dif_ins_res;
uint32_t dif_ins_ref_tag;
uint16_t dif_ins_app_tag_mask;
uint16_t dif_ins_app_tag;
};
/* DIF update */
struct {
uint32_t dif_upd_src_ref_tag;
uint16_t dif_upd_src_app_tag_mask;
uint16_t dif_upd_src_app_tag;
uint32_t dif_upd_dest_ref_tag;
uint16_t dif_upd_dest_app_tag_mask;
uint16_t dif_upd_dest_app_tag;
};
uint8_t op_specific[16];
};
} __attribute__((packed));
struct dsa_raw_completion_record {
uint64_t field[4];
} __attribute__((packed));
struct iax_completion_record {
volatile uint8_t status;
uint8_t error_code;
uint16_t rsvd;
uint32_t bytes_completed;
uint64_t fault_addr;
uint32_t invalid_flags;
uint32_t rsvd2;
uint32_t output_size;
uint8_t output_bits;
uint8_t rsvd3;
uint16_t rsvd4;
uint64_t rsvd5[4];
} __attribute__((packed));
struct iax_raw_completion_record {
uint64_t field[8];
} __attribute__((packed));
#endif