drivers/crypto/cavium/cpt/cpt_hw_types.h - arm/linux - Git at Google

 /*
  * Copyright (C) 2016 Cavium, Inc.
  *
  * This program is free software; you can redistribute it and/or modify it
  * under the terms of version 2 of the GNU General Public License
  * as published by the Free Software Foundation.
  */

 #ifndef __CPT_HW_TYPES_H
 #define __CPT_HW_TYPES_H

 #include "cpt_common.h"

 /**
  * Enumeration cpt_comp_e
  *
  * CPT Completion Enumeration
  * Enumerates the values of CPT_RES_S[COMPCODE].
  */
 enum cpt_comp_e {
 	CPT_COMP_E_NOTDONE = 0x00,
 	CPT_COMP_E_GOOD = 0x01,
 	CPT_COMP_E_FAULT = 0x02,
 	CPT_COMP_E_SWERR = 0x03,
 	CPT_COMP_E_LAST_ENTRY = 0xFF
 };

 /**
  * Structure cpt_inst_s
  *
  * CPT Instruction Structure
  * This structure specifies the instruction layout. Instructions are
  * stored in memory as little-endian unless CPT()_PF_Q()_CTL[INST_BE] is set.
  * cpt_inst_s_s
  * Word 0
  * doneint:1 Done interrupt.
  *	0 = No interrupts related to this instruction.
  *	1 = When the instruction completes, CPT()_VQ()_DONE[DONE] will be
  *	incremented,and based on the rules described there an interrupt may
  *	occur.
  * Word 1
  * res_addr [127: 64] Result IOVA.
  *	If nonzero, specifies where to write CPT_RES_S.
  *	If zero, no result structure will be written.
  *	Address must be 16-byte aligned.
  *	Bits <63:49> are ignored by hardware; software should use a
  *	sign-extended bit <48> for forward compatibility.
  * Word 2
  *  grp:10 [171:162] If [WQ_PTR] is nonzero, the SSO guest-group to use when
  *	CPT submits work SSO.
  *	For the SSO to not discard the add-work request, FPA_PF_MAP() must map
  *	[GRP] and CPT()_PF_Q()_GMCTL[GMID] as valid.
  *  tt:2 [161:160] If [WQ_PTR] is nonzero, the SSO tag type to use when CPT
  *	submits work to SSO
  *  tag:32 [159:128] If [WQ_PTR] is nonzero, the SSO tag to use when CPT
  *	submits work to SSO.
  * Word 3
  *  wq_ptr [255:192] If [WQ_PTR] is nonzero, it is a pointer to a
  *	work-queue entry that CPT submits work to SSO after all context,
  *	output data, and result write operations are visible to other
  *	CNXXXX units and the cores. Bits <2:0> must be zero.
  *	Bits <63:49> are ignored by hardware; software should
  *	use a sign-extended bit <48> for forward compatibility.
  *	Internal:
  *	Bits <63:49>, <2:0> are ignored by hardware, treated as always 0x0.
  * Word 4
  *  ei0; [319:256] Engine instruction word 0. Passed to the AE/SE.
  * Word 5
  *  ei1; [383:320] Engine instruction word 1. Passed to the AE/SE.
  * Word 6
  *  ei2; [447:384] Engine instruction word 1. Passed to the AE/SE.
  * Word 7
  *  ei3; [511:448] Engine instruction word 1. Passed to the AE/SE.
  *
  */
 union cpt_inst_s {
 	u64 u[8];
 	struct cpt_inst_s_s {
 #if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
 		u64 reserved_17_63:47;
 		u64 doneint:1;
 		u64 reserved_0_1:16;
 #else /* Word 0 - Little Endian */
 		u64 reserved_0_15:16;
 		u64 doneint:1;
 		u64 reserved_17_63:47;
 #endif /* Word 0 - End */
 		u64 res_addr;
 #if defined(__BIG_ENDIAN_BITFIELD) /* Word 2 - Big Endian */
 		u64 reserved_172_19:20;
 		u64 grp:10;
 		u64 tt:2;
 		u64 tag:32;
 #else /* Word 2 - Little Endian */
 		u64 tag:32;
 		u64 tt:2;
 		u64 grp:10;
 		u64 reserved_172_191:20;
 #endif /* Word 2 - End */
 		u64 wq_ptr;
 		u64 ei0;
 		u64 ei1;
 		u64 ei2;
 		u64 ei3;
 	} s;
 };

 /**
  * Structure cpt_res_s
  *
  * CPT Result Structure
  * The CPT coprocessor writes the result structure after it completes a
  * CPT_INST_S instruction. The result structure is exactly 16 bytes, and
  * each instruction completion produces exactly one result structure.
  *
  * This structure is stored in memory as little-endian unless
  * CPT()_PF_Q()_CTL[INST_BE] is set.
  * cpt_res_s_s
  * Word 0
  *  doneint:1 [16:16] Done interrupt. This bit is copied from the
  *	corresponding instruction's CPT_INST_S[DONEINT].
  *  compcode:8 [7:0] Indicates completion/error status of the CPT coprocessor
  *	for the	associated instruction, as enumerated by CPT_COMP_E.
  *	Core software may write the memory location containing [COMPCODE] to
  *	0x0 before ringing the doorbell, and then poll for completion by
  *	checking for a nonzero value.
  *	Once the core observes a nonzero [COMPCODE] value in this case,the CPT
  *	coprocessor will have also completed L2/DRAM write operations.
  * Word 1
  *  reserved
  *
  */
 union cpt_res_s {
 	u64 u[2];
 	struct cpt_res_s_s {
 #if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
 		u64 reserved_17_63:47;
 		u64 doneint:1;
 		u64 reserved_8_15:8;
 		u64 compcode:8;
 #else /* Word 0 - Little Endian */
 		u64 compcode:8;
 		u64 reserved_8_15:8;
 		u64 doneint:1;
 		u64 reserved_17_63:47;
 #endif /* Word 0 - End */
 		u64 reserved_64_127;
 	} s;
 };

 /**
  * Register (NCB) cpt#_pf_bist_status
  *
  * CPT PF Control Bist Status Register
  * This register has the BIST status of memories. Each bit is the BIST result
  * of an individual memory (per bit, 0 = pass and 1 = fail).
  * cptx_pf_bist_status_s
  * Word0
  *  bstatus [29:0](RO/H) BIST status. One bit per memory, enumerated by
  *	CPT_RAMS_E.
  */
 union cptx_pf_bist_status {
 	u64 u;
 	struct cptx_pf_bist_status_s {
 #if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
 		u64 reserved_30_63:34;
 		u64 bstatus:30;
 #else /* Word 0 - Little Endian */
 		u64 bstatus:30;
 		u64 reserved_30_63:34;
 #endif /* Word 0 - End */
 	} s;
 };

 /**
  * Register (NCB) cpt#_pf_constants
  *
  * CPT PF Constants Register
  * This register contains implementation-related parameters of CPT in CNXXXX.
  * cptx_pf_constants_s
  * Word 0
  *  reserved_40_63:24 [63:40] Reserved.
  *  epcis:8 [39:32](RO) Number of EPCI busses.
  *  grps:8 [31:24](RO) Number of engine groups implemented.
  *  ae:8 [23:16](RO/H) Number of AEs. In CNXXXX, for CPT0 returns 0x0,
  *	for CPT1 returns 0x18, or less if there are fuse-disables.
  *  se:8 [15:8](RO/H) Number of SEs. In CNXXXX, for CPT0 returns 0x30,
  *	or less if there are fuse-disables, for CPT1 returns 0x0.
  *  vq:8 [7:0](RO) Number of VQs.
  */
 union cptx_pf_constants {
 	u64 u;
 	struct cptx_pf_constants_s {
 #if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
 		u64 reserved_40_63:24;
 		u64 epcis:8;
 		u64 grps:8;
 		u64 ae:8;
 		u64 se:8;
 		u64 vq:8;
 #else /* Word 0 - Little Endian */
 		u64 vq:8;
 		u64 se:8;
 		u64 ae:8;
 		u64 grps:8;
 		u64 epcis:8;
 		u64 reserved_40_63:24;
 #endif /* Word 0 - End */
 	} s;
 };

 /**
  * Register (NCB) cpt#_pf_exe_bist_status
  *
  * CPT PF Engine Bist Status Register
  * This register has the BIST status of each engine.  Each bit is the
  * BIST result of an individual engine (per bit, 0 = pass and 1 = fail).
  * cptx_pf_exe_bist_status_s
  * Word0
  *  reserved_48_63:16 [63:48] reserved
  *  bstatus:48 [47:0](RO/H) BIST status. One bit per engine.
  *
  */
 union cptx_pf_exe_bist_status {
 	u64 u;
 	struct cptx_pf_exe_bist_status_s {
 #if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
 		u64 reserved_48_63:16;
 		u64 bstatus:48;
 #else /* Word 0 - Little Endian */
 		u64 bstatus:48;
 		u64 reserved_48_63:16;
 #endif /* Word 0 - End */
 	} s;
 };

 /**
  * Register (NCB) cpt#_pf_q#_ctl
  *
  * CPT Queue Control Register
  * This register configures queues. This register should be changed only
  * when quiescent (see CPT()_VQ()_INPROG[INFLIGHT]).
  * cptx_pf_qx_ctl_s
  * Word0
  *  reserved_60_63:4 [63:60] reserved.
  *  aura:12; [59:48](R/W) Guest-aura for returning this queue's
  *	instruction-chunk buffers to FPA. Only used when [INST_FREE] is set.
  *	For the FPA to not discard the request, FPA_PF_MAP() must map
  *	[AURA] and CPT()_PF_Q()_GMCTL[GMID] as valid.
  *  reserved_45_47:3 [47:45] reserved.
  *  size:13 [44:32](R/W) Command-buffer size, in number of 64-bit words per
  *	command buffer segment. Must be 8*n + 1, where n is the number of
  *	instructions per buffer segment.
  *  reserved_11_31:21 [31:11] Reserved.
  *  cont_err:1 [10:10](R/W) Continue on error.
  *	0 = When CPT()_VQ()_MISC_INT[NWRP], CPT()_VQ()_MISC_INT[IRDE] or
  *	CPT()_VQ()_MISC_INT[DOVF] are set by hardware or software via
  *	CPT()_VQ()_MISC_INT_W1S, then CPT()_VQ()_CTL[ENA] is cleared.  Due to
  *	pipelining, additional instructions may have been processed between the
  *	instruction causing the error and the next instruction in the disabled
  *	queue (the instruction at CPT()_VQ()_SADDR).
  *	1 = Ignore errors and continue processing instructions.
  *	For diagnostic use only.
  *  inst_free:1 [9:9](R/W) Instruction FPA free. When set, when CPT reaches the
  *	end of an instruction chunk, that chunk will be freed to the FPA.
  *  inst_be:1 [8:8](R/W) Instruction big-endian control. When set, instructions,
  *	instruction next chunk pointers, and result structures are stored in
  *	big-endian format in memory.
  *  iqb_ldwb:1 [7:7](R/W) Instruction load don't write back.
  *	0 = The hardware issues NCB transient load (LDT) towards the cache,
  *	which if the line hits and is is dirty will cause the line to be
  *	written back before being replaced.
  *	1 = The hardware issues NCB LDWB read-and-invalidate command towards
  *	the cache when fetching the last word of instructions; as a result the
  *	line will not be written back when replaced.  This improves
  *	performance, but software must not read the instructions after they are
  *	posted to the hardware.	Reads that do not consume the last word of a
  *	cache line always use LDI.
  *  reserved_4_6:3 [6:4] Reserved.
  *  grp:3; [3:1](R/W) Engine group.
  *  pri:1; [0:0](R/W) Queue priority.
  *	1 = This queue has higher priority. Round-robin between higher
  *	priority queues.
  *	0 = This queue has lower priority. Round-robin between lower
  *	priority queues.
  */
 union cptx_pf_qx_ctl {
 	u64 u;
 	struct cptx_pf_qx_ctl_s {
 #if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
 		u64 reserved_60_63:4;
 		u64 aura:12;
 		u64 reserved_45_47:3;
 		u64 size:13;
 		u64 reserved_11_31:21;
 		u64 cont_err:1;
 		u64 inst_free:1;
 		u64 inst_be:1;
 		u64 iqb_ldwb:1;
 		u64 reserved_4_6:3;
 		u64 grp:3;
 		u64 pri:1;
 #else /* Word 0 - Little Endian */
 		u64 pri:1;
 		u64 grp:3;
 		u64 reserved_4_6:3;
 		u64 iqb_ldwb:1;
 		u64 inst_be:1;
 		u64 inst_free:1;
 		u64 cont_err:1;
 		u64 reserved_11_31:21;
 		u64 size:13;
 		u64 reserved_45_47:3;
 		u64 aura:12;
 		u64 reserved_60_63:4;
 #endif /* Word 0 - End */
 	} s;
 };

 /**
  * Register (NCB) cpt#_vq#_saddr
  *
  * CPT Queue Starting Buffer Address Registers
  * These registers set the instruction buffer starting address.
  * cptx_vqx_saddr_s
  * Word0
  *  reserved_49_63:15 [63:49] Reserved.
  *  ptr:43 [48:6](R/W/H) Instruction buffer IOVA <48:6> (64-byte aligned).
  *	When written, it is the initial buffer starting address; when read,
  *	it is the next read pointer to be requested from L2C. The PTR field
  *	is overwritten with the next pointer each time that the command buffer
  *	segment is exhausted. New commands will then be read from the newly
  *	specified command buffer pointer.
  *  reserved_0_5:6 [5:0] Reserved.
  *
  */
 union cptx_vqx_saddr {
 	u64 u;
 	struct cptx_vqx_saddr_s {
 #if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
 		u64 reserved_49_63:15;
 		u64 ptr:43;
 		u64 reserved_0_5:6;
 #else /* Word 0 - Little Endian */
 		u64 reserved_0_5:6;
 		u64 ptr:43;
 		u64 reserved_49_63:15;
 #endif /* Word 0 - End */
 	} s;
 };

 /**
  * Register (NCB) cpt#_vq#_misc_ena_w1s
  *
  * CPT Queue Misc Interrupt Enable Set Register
  * This register sets interrupt enable bits.
  * cptx_vqx_misc_ena_w1s_s
  * Word0
  * reserved_5_63:59 [63:5] Reserved.
  * swerr:1 [4:4](R/W1S/H) Reads or sets enable for
  *	CPT(0..1)_VQ(0..63)_MISC_INT[SWERR].
  * nwrp:1 [3:3](R/W1S/H) Reads or sets enable for
  *	CPT(0..1)_VQ(0..63)_MISC_INT[NWRP].
  * irde:1 [2:2](R/W1S/H) Reads or sets enable for
  *	CPT(0..1)_VQ(0..63)_MISC_INT[IRDE].
  * dovf:1 [1:1](R/W1S/H) Reads or sets enable for
  *	CPT(0..1)_VQ(0..63)_MISC_INT[DOVF].
  * mbox:1 [0:0](R/W1S/H) Reads or sets enable for
  *	CPT(0..1)_VQ(0..63)_MISC_INT[MBOX].
  *
  */
 union cptx_vqx_misc_ena_w1s {
 	u64 u;
 	struct cptx_vqx_misc_ena_w1s_s {
 #if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
 		u64 reserved_5_63:59;
 		u64 swerr:1;
 		u64 nwrp:1;
 		u64 irde:1;
 		u64 dovf:1;
 		u64 mbox:1;
 #else /* Word 0 - Little Endian */
 		u64 mbox:1;
 		u64 dovf:1;
 		u64 irde:1;
 		u64 nwrp:1;
 		u64 swerr:1;
 		u64 reserved_5_63:59;
 #endif /* Word 0 - End */
 	} s;
 };

 /**
  * Register (NCB) cpt#_vq#_doorbell
  *
  * CPT Queue Doorbell Registers
  * Doorbells for the CPT instruction queues.
  * cptx_vqx_doorbell_s
  * Word0
  *  reserved_20_63:44 [63:20] Reserved.
  *  dbell_cnt:20 [19:0](R/W/H) Number of instruction queue 64-bit words to add
  *	to the CPT instruction doorbell count. Readback value is the the
  *	current number of pending doorbell requests. If counter overflows
  *	CPT()_VQ()_MISC_INT[DBELL_DOVF] is set. To reset the count back to
  *	zero, write one to clear CPT()_VQ()_MISC_INT_ENA_W1C[DBELL_DOVF],
  *	then write a value of 2^20 minus the read [DBELL_CNT], then write one
  *	to CPT()_VQ()_MISC_INT_W1C[DBELL_DOVF] and
  *	CPT()_VQ()_MISC_INT_ENA_W1S[DBELL_DOVF]. Must be a multiple of 8.
  *	All CPT instructions are 8 words and require a doorbell count of
  *	multiple of 8.
  */
 union cptx_vqx_doorbell {
 	u64 u;
 	struct cptx_vqx_doorbell_s {
 #if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
 		u64 reserved_20_63:44;
 		u64 dbell_cnt:20;
 #else /* Word 0 - Little Endian */
 		u64 dbell_cnt:20;
 		u64 reserved_20_63:44;
 #endif /* Word 0 - End */
 	} s;
 };

 /**
  * Register (NCB) cpt#_vq#_inprog
  *
  * CPT Queue In Progress Count Registers
  * These registers contain the per-queue instruction in flight registers.
  * cptx_vqx_inprog_s
  * Word0
  *  reserved_8_63:56 [63:8] Reserved.
  *  inflight:8 [7:0](RO/H) Inflight count. Counts the number of instructions
  *	for the VF for which CPT is fetching, executing or responding to
  *	instructions. However this does not include any interrupts that are
  *	awaiting software handling (CPT()_VQ()_DONE[DONE] != 0x0).
  *	A queue may not be reconfigured until:
  *	1. CPT()_VQ()_CTL[ENA] is cleared by software.
  *	2. [INFLIGHT] is polled until equals to zero.
  */
 union cptx_vqx_inprog {
 	u64 u;
 	struct cptx_vqx_inprog_s {
 #if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
 		u64 reserved_8_63:56;
 		u64 inflight:8;
 #else /* Word 0 - Little Endian */
 		u64 inflight:8;
 		u64 reserved_8_63:56;
 #endif /* Word 0 - End */
 	} s;
 };

 /**
  * Register (NCB) cpt#_vq#_misc_int
  *
  * CPT Queue Misc Interrupt Register
  * These registers contain the per-queue miscellaneous interrupts.
  * cptx_vqx_misc_int_s
  * Word 0
  *  reserved_5_63:59 [63:5] Reserved.
  *  swerr:1 [4:4](R/W1C/H) Software error from engines.
  *  nwrp:1  [3:3](R/W1C/H) NCB result write response error.
  *  irde:1  [2:2](R/W1C/H) Instruction NCB read response error.
  *  dovf:1 [1:1](R/W1C/H) Doorbell overflow.
  *  mbox:1 [0:0](R/W1C/H) PF to VF mailbox interrupt. Set when
  *	CPT()_VF()_PF_MBOX(0) is written.
  *
  */
 union cptx_vqx_misc_int {
 	u64 u;
 	struct cptx_vqx_misc_int_s {
 #if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
 		u64 reserved_5_63:59;
 		u64 swerr:1;
 		u64 nwrp:1;
 		u64 irde:1;
 		u64 dovf:1;
 		u64 mbox:1;
 #else /* Word 0 - Little Endian */
 		u64 mbox:1;
 		u64 dovf:1;
 		u64 irde:1;
 		u64 nwrp:1;
 		u64 swerr:1;
 		u64 reserved_5_63:59;
 #endif /* Word 0 - End */
 	} s;
 };

 /**
  * Register (NCB) cpt#_vq#_done_ack
  *
  * CPT Queue Done Count Ack Registers
  * This register is written by software to acknowledge interrupts.
  * cptx_vqx_done_ack_s
  * Word0
  *  reserved_20_63:44 [63:20] Reserved.
  *  done_ack:20 [19:0](R/W/H) Number of decrements to CPT()_VQ()_DONE[DONE].
  *	Reads CPT()_VQ()_DONE[DONE]. Written by software to acknowledge
  *	interrupts. If CPT()_VQ()_DONE[DONE] is still nonzero the interrupt
  *	will be re-sent if the conditions described in CPT()_VQ()_DONE[DONE]
  *	are satisfied.
  *
  */
 union cptx_vqx_done_ack {
 	u64 u;
 	struct cptx_vqx_done_ack_s {
 #if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
 		u64 reserved_20_63:44;
 		u64 done_ack:20;
 #else /* Word 0 - Little Endian */
 		u64 done_ack:20;
 		u64 reserved_20_63:44;
 #endif /* Word 0 - End */
 	} s;
 };

 /**
  * Register (NCB) cpt#_vq#_done
  *
  * CPT Queue Done Count Registers
  * These registers contain the per-queue instruction done count.
  * cptx_vqx_done_s
  * Word0
  *  reserved_20_63:44 [63:20] Reserved.
  *  done:20 [19:0](R/W/H) Done count. When CPT_INST_S[DONEINT] set and that
  *	instruction completes, CPT()_VQ()_DONE[DONE] is incremented when the
  *	instruction finishes. Write to this field are for diagnostic use only;
  *	instead software writes CPT()_VQ()_DONE_ACK with the number of
  *	decrements for this field.
  *	Interrupts are sent as follows:
  *	* When CPT()_VQ()_DONE[DONE] = 0, then no results are pending, the
  *	interrupt coalescing timer is held to zero, and an interrupt is not
  *	sent.
  *	* When CPT()_VQ()_DONE[DONE] != 0, then the interrupt coalescing timer
  *	counts. If the counter is >= CPT()_VQ()_DONE_WAIT[TIME_WAIT]*1024, or
  *	CPT()_VQ()_DONE[DONE] >= CPT()_VQ()_DONE_WAIT[NUM_WAIT], i.e. enough
  *	time has passed or enough results have arrived, then the interrupt is
  *	sent.
  *	* When CPT()_VQ()_DONE_ACK is written (or CPT()_VQ()_DONE is written
  *	but this is not typical), the interrupt coalescing timer restarts.
  *	Note after decrementing this interrupt equation is recomputed,
  *	for example if CPT()_VQ()_DONE[DONE] >= CPT()_VQ()_DONE_WAIT[NUM_WAIT]
  *	and because the timer is zero, the interrupt will be resent immediately.
  *	(This covers the race case between software acknowledging an interrupt
  *	and a result returning.)
  *	* When CPT()_VQ()_DONE_ENA_W1S[DONE] = 0, interrupts are not sent,
  *	but the counting described above still occurs.
  *	Since CPT instructions complete out-of-order, if software is using
  *	completion interrupts the suggested scheme is to request a DONEINT on
  *	each request, and when an interrupt arrives perform a "greedy" scan for
  *	completions; even if a later command is acknowledged first this will
  *	not result in missing a completion.
  *	Software is responsible for making sure [DONE] does not overflow;
  *	for example by insuring there are not more than 2^20-1 instructions in
  *	flight that may request interrupts.
  *
  */
 union cptx_vqx_done {
 	u64 u;
 	struct cptx_vqx_done_s {
 #if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
 		u64 reserved_20_63:44;
 		u64 done:20;
 #else /* Word 0 - Little Endian */
 		u64 done:20;
 		u64 reserved_20_63:44;
 #endif /* Word 0 - End */
 	} s;
 };

 /**
  * Register (NCB) cpt#_vq#_done_wait
  *
  * CPT Queue Done Interrupt Coalescing Wait Registers
  * Specifies the per queue interrupt coalescing settings.
  * cptx_vqx_done_wait_s
  * Word0
  *  reserved_48_63:16 [63:48] Reserved.
  *  time_wait:16; [47:32](R/W) Time hold-off. When CPT()_VQ()_DONE[DONE] = 0
  *	or CPT()_VQ()_DONE_ACK is written a timer is cleared. When the timer
  *	reaches [TIME_WAIT]*1024 then interrupt coalescing ends.
  *	see CPT()_VQ()_DONE[DONE]. If 0x0, time coalescing is disabled.
  *  reserved_20_31:12 [31:20] Reserved.
  *  num_wait:20 [19:0](R/W) Number of messages hold-off.
  *	When CPT()_VQ()_DONE[DONE] >= [NUM_WAIT] then interrupt coalescing ends
  *	see CPT()_VQ()_DONE[DONE]. If 0x0, same behavior as 0x1.
  *
  */
 union cptx_vqx_done_wait {
 	u64 u;
 	struct cptx_vqx_done_wait_s {
 #if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
 		u64 reserved_48_63:16;
 		u64 time_wait:16;
 		u64 reserved_20_31:12;
 		u64 num_wait:20;
 #else /* Word 0 - Little Endian */
 		u64 num_wait:20;
 		u64 reserved_20_31:12;
 		u64 time_wait:16;
 		u64 reserved_48_63:16;
 #endif /* Word 0 - End */
 	} s;
 };

 /**
  * Register (NCB) cpt#_vq#_done_ena_w1s
  *
  * CPT Queue Done Interrupt Enable Set Registers
  * Write 1 to these registers will enable the DONEINT interrupt for the queue.
  * cptx_vqx_done_ena_w1s_s
  * Word0
  *  reserved_1_63:63 [63:1] Reserved.
  *  done:1 [0:0](R/W1S/H) Write 1 will enable DONEINT for this queue.
  *	Write 0 has no effect. Read will return the enable bit.
  */
 union cptx_vqx_done_ena_w1s {
 	u64 u;
 	struct cptx_vqx_done_ena_w1s_s {
 #if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
 		u64 reserved_1_63:63;
 		u64 done:1;
 #else /* Word 0 - Little Endian */
 		u64 done:1;
 		u64 reserved_1_63:63;
 #endif /* Word 0 - End */
 	} s;
 };

 /**
  * Register (NCB) cpt#_vq#_ctl
  *
  * CPT VF Queue Control Registers
  * This register configures queues. This register should be changed (other than
  * clearing [ENA]) only when quiescent (see CPT()_VQ()_INPROG[INFLIGHT]).
  * cptx_vqx_ctl_s
  * Word0
  *  reserved_1_63:63 [63:1] Reserved.
  *  ena:1 [0:0](R/W/H) Enables the logical instruction queue.
  *	See also CPT()_PF_Q()_CTL[CONT_ERR] and	CPT()_VQ()_INPROG[INFLIGHT].
  *	1 = Queue is enabled.
  *	0 = Queue is disabled.
  */
 union cptx_vqx_ctl {
 	u64 u;
 	struct cptx_vqx_ctl_s {
 #if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
 		u64 reserved_1_63:63;
 		u64 ena:1;
 #else /* Word 0 - Little Endian */
 		u64 ena:1;
 		u64 reserved_1_63:63;
 #endif /* Word 0 - End */
 	} s;
 };
 #endif /*__CPT_HW_TYPES_H*/
	/*
	* Copyright (C) 2016 Cavium, Inc.
	*
	* This program is free software; you can redistribute it and/or modify it
	* under the terms of version 2 of the GNU General Public License
	* as published by the Free Software Foundation.
	*/

	#ifndef __CPT_HW_TYPES_H
	#define __CPT_HW_TYPES_H

	#include "cpt_common.h"

	/**
	* Enumeration cpt_comp_e
	*
	* CPT Completion Enumeration
	* Enumerates the values of CPT_RES_S[COMPCODE].
	*/
	enum cpt_comp_e {
	CPT_COMP_E_NOTDONE = 0x00,
	CPT_COMP_E_GOOD = 0x01,
	CPT_COMP_E_FAULT = 0x02,
	CPT_COMP_E_SWERR = 0x03,
	CPT_COMP_E_LAST_ENTRY = 0xFF
	};

	/**
	* Structure cpt_inst_s
	*
	* CPT Instruction Structure
	* This structure specifies the instruction layout. Instructions are
	* stored in memory as little-endian unless CPT()_PF_Q()_CTL[INST_BE] is set.
	* cpt_inst_s_s
	* Word 0
	* doneint:1 Done interrupt.
	* 0 = No interrupts related to this instruction.
	* 1 = When the instruction completes, CPT()_VQ()_DONE[DONE] will be
	* incremented,and based on the rules described there an interrupt may
	* occur.
	* Word 1
	* res_addr [127: 64] Result IOVA.
	* If nonzero, specifies where to write CPT_RES_S.
	* If zero, no result structure will be written.
	* Address must be 16-byte aligned.
	* Bits <63:49> are ignored by hardware; software should use a
	* sign-extended bit <48> for forward compatibility.
	* Word 2
	* grp:10 [171:162] If [WQ_PTR] is nonzero, the SSO guest-group to use when
	* CPT submits work SSO.
	* For the SSO to not discard the add-work request, FPA_PF_MAP() must map
	* [GRP] and CPT()_PF_Q()_GMCTL[GMID] as valid.
	* tt:2 [161:160] If [WQ_PTR] is nonzero, the SSO tag type to use when CPT
	* submits work to SSO
	* tag:32 [159:128] If [WQ_PTR] is nonzero, the SSO tag to use when CPT
	* submits work to SSO.
	* Word 3
	* wq_ptr [255:192] If [WQ_PTR] is nonzero, it is a pointer to a
	* work-queue entry that CPT submits work to SSO after all context,
	* output data, and result write operations are visible to other
	* CNXXXX units and the cores. Bits <2:0> must be zero.
	* Bits <63:49> are ignored by hardware; software should
	* use a sign-extended bit <48> for forward compatibility.
	* Internal:
	* Bits <63:49>, <2:0> are ignored by hardware, treated as always 0x0.
	* Word 4
	* ei0; [319:256] Engine instruction word 0. Passed to the AE/SE.
	* Word 5
	* ei1; [383:320] Engine instruction word 1. Passed to the AE/SE.
	* Word 6
	* ei2; [447:384] Engine instruction word 1. Passed to the AE/SE.
	* Word 7
	* ei3; [511:448] Engine instruction word 1. Passed to the AE/SE.
	*
	*/
	union cpt_inst_s {
	u64 u[8];
	struct cpt_inst_s_s {
	#if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
	u64 reserved_17_63:47;
	u64 doneint:1;
	u64 reserved_0_1:16;
	#else /* Word 0 - Little Endian */
	u64 reserved_0_15:16;
	u64 doneint:1;
	u64 reserved_17_63:47;
	#endif /* Word 0 - End */
	u64 res_addr;
	#if defined(__BIG_ENDIAN_BITFIELD) /* Word 2 - Big Endian */
	u64 reserved_172_19:20;
	u64 grp:10;
	u64 tt:2;
	u64 tag:32;
	#else /* Word 2 - Little Endian */
	u64 tag:32;
	u64 tt:2;
	u64 grp:10;
	u64 reserved_172_191:20;
	#endif /* Word 2 - End */
	u64 wq_ptr;
	u64 ei0;
	u64 ei1;
	u64 ei2;
	u64 ei3;
	} s;
	};

	/**
	* Structure cpt_res_s
	*
	* CPT Result Structure
	* The CPT coprocessor writes the result structure after it completes a
	* CPT_INST_S instruction. The result structure is exactly 16 bytes, and
	* each instruction completion produces exactly one result structure.
	*
	* This structure is stored in memory as little-endian unless
	* CPT()_PF_Q()_CTL[INST_BE] is set.
	* cpt_res_s_s
	* Word 0
	* doneint:1 [16:16] Done interrupt. This bit is copied from the
	* corresponding instruction's CPT_INST_S[DONEINT].
	* compcode:8 [7:0] Indicates completion/error status of the CPT coprocessor
	* for the associated instruction, as enumerated by CPT_COMP_E.
	* Core software may write the memory location containing [COMPCODE] to
	* 0x0 before ringing the doorbell, and then poll for completion by
	* checking for a nonzero value.
	* Once the core observes a nonzero [COMPCODE] value in this case,the CPT
	* coprocessor will have also completed L2/DRAM write operations.
	* Word 1
	* reserved
	*
	*/
	union cpt_res_s {
	u64 u[2];
	struct cpt_res_s_s {
	#if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
	u64 reserved_17_63:47;
	u64 doneint:1;
	u64 reserved_8_15:8;
	u64 compcode:8;
	#else /* Word 0 - Little Endian */
	u64 compcode:8;
	u64 reserved_8_15:8;
	u64 doneint:1;
	u64 reserved_17_63:47;
	#endif /* Word 0 - End */
	u64 reserved_64_127;
	} s;
	};

	/**
	* Register (NCB) cpt#_pf_bist_status
	*
	* CPT PF Control Bist Status Register
	* This register has the BIST status of memories. Each bit is the BIST result
	* of an individual memory (per bit, 0 = pass and 1 = fail).
	* cptx_pf_bist_status_s
	* Word0
	* bstatus [29:0](RO/H) BIST status. One bit per memory, enumerated by
	* CPT_RAMS_E.
	*/
	union cptx_pf_bist_status {
	u64 u;
	struct cptx_pf_bist_status_s {
	#if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
	u64 reserved_30_63:34;
	u64 bstatus:30;
	#else /* Word 0 - Little Endian */
	u64 bstatus:30;
	u64 reserved_30_63:34;
	#endif /* Word 0 - End */
	} s;
	};

	/**
	* Register (NCB) cpt#_pf_constants
	*
	* CPT PF Constants Register
	* This register contains implementation-related parameters of CPT in CNXXXX.
	* cptx_pf_constants_s
	* Word 0
	* reserved_40_63:24 [63:40] Reserved.
	* epcis:8 [39:32](RO) Number of EPCI busses.
	* grps:8 [31:24](RO) Number of engine groups implemented.
	* ae:8 [23:16](RO/H) Number of AEs. In CNXXXX, for CPT0 returns 0x0,
	* for CPT1 returns 0x18, or less if there are fuse-disables.
	* se:8 [15:8](RO/H) Number of SEs. In CNXXXX, for CPT0 returns 0x30,
	* or less if there are fuse-disables, for CPT1 returns 0x0.
	* vq:8 [7:0](RO) Number of VQs.
	*/
	union cptx_pf_constants {
	u64 u;
	struct cptx_pf_constants_s {
	#if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
	u64 reserved_40_63:24;
	u64 epcis:8;
	u64 grps:8;
	u64 ae:8;
	u64 se:8;
	u64 vq:8;
	#else /* Word 0 - Little Endian */
	u64 vq:8;
	u64 se:8;
	u64 ae:8;
	u64 grps:8;
	u64 epcis:8;
	u64 reserved_40_63:24;
	#endif /* Word 0 - End */
	} s;
	};

	/**
	* Register (NCB) cpt#_pf_exe_bist_status
	*
	* CPT PF Engine Bist Status Register
	* This register has the BIST status of each engine. Each bit is the
	* BIST result of an individual engine (per bit, 0 = pass and 1 = fail).
	* cptx_pf_exe_bist_status_s
	* Word0
	* reserved_48_63:16 [63:48] reserved
	* bstatus:48 [47:0](RO/H) BIST status. One bit per engine.
	*
	*/
	union cptx_pf_exe_bist_status {
	u64 u;
	struct cptx_pf_exe_bist_status_s {
	#if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
	u64 reserved_48_63:16;
	u64 bstatus:48;
	#else /* Word 0 - Little Endian */
	u64 bstatus:48;
	u64 reserved_48_63:16;
	#endif /* Word 0 - End */
	} s;
	};

	/**
	* Register (NCB) cpt#_pf_q#_ctl
	*
	* CPT Queue Control Register
	* This register configures queues. This register should be changed only
	* when quiescent (see CPT()_VQ()_INPROG[INFLIGHT]).
	* cptx_pf_qx_ctl_s
	* Word0
	* reserved_60_63:4 [63:60] reserved.
	* aura:12; [59:48](R/W) Guest-aura for returning this queue's
	* instruction-chunk buffers to FPA. Only used when [INST_FREE] is set.
	* For the FPA to not discard the request, FPA_PF_MAP() must map
	* [AURA] and CPT()_PF_Q()_GMCTL[GMID] as valid.
	* reserved_45_47:3 [47:45] reserved.
	* size:13 [44:32](R/W) Command-buffer size, in number of 64-bit words per
	* command buffer segment. Must be 8*n + 1, where n is the number of
	* instructions per buffer segment.
	* reserved_11_31:21 [31:11] Reserved.
	* cont_err:1 [10:10](R/W) Continue on error.
	* 0 = When CPT()_VQ()_MISC_INT[NWRP], CPT()_VQ()_MISC_INT[IRDE] or
	* CPT()_VQ()_MISC_INT[DOVF] are set by hardware or software via
	* CPT()_VQ()_MISC_INT_W1S, then CPT()_VQ()_CTL[ENA] is cleared. Due to
	* pipelining, additional instructions may have been processed between the
	* instruction causing the error and the next instruction in the disabled
	* queue (the instruction at CPT()_VQ()_SADDR).
	* 1 = Ignore errors and continue processing instructions.
	* For diagnostic use only.
	* inst_free:1 [9:9](R/W) Instruction FPA free. When set, when CPT reaches the
	* end of an instruction chunk, that chunk will be freed to the FPA.
	* inst_be:1 [8:8](R/W) Instruction big-endian control. When set, instructions,
	* instruction next chunk pointers, and result structures are stored in
	* big-endian format in memory.
	* iqb_ldwb:1 [7:7](R/W) Instruction load don't write back.
	* 0 = The hardware issues NCB transient load (LDT) towards the cache,
	* which if the line hits and is is dirty will cause the line to be
	* written back before being replaced.
	* 1 = The hardware issues NCB LDWB read-and-invalidate command towards
	* the cache when fetching the last word of instructions; as a result the
	* line will not be written back when replaced. This improves
	* performance, but software must not read the instructions after they are
	* posted to the hardware. Reads that do not consume the last word of a
	* cache line always use LDI.
	* reserved_4_6:3 [6:4] Reserved.
	* grp:3; [3:1](R/W) Engine group.
	* pri:1; [0:0](R/W) Queue priority.
	* 1 = This queue has higher priority. Round-robin between higher
	* priority queues.
	* 0 = This queue has lower priority. Round-robin between lower
	* priority queues.
	*/
	union cptx_pf_qx_ctl {
	u64 u;
	struct cptx_pf_qx_ctl_s {
	#if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
	u64 reserved_60_63:4;
	u64 aura:12;
	u64 reserved_45_47:3;
	u64 size:13;
	u64 reserved_11_31:21;
	u64 cont_err:1;
	u64 inst_free:1;
	u64 inst_be:1;
	u64 iqb_ldwb:1;
	u64 reserved_4_6:3;
	u64 grp:3;
	u64 pri:1;
	#else /* Word 0 - Little Endian */
	u64 pri:1;
	u64 grp:3;
	u64 reserved_4_6:3;
	u64 iqb_ldwb:1;
	u64 inst_be:1;
	u64 inst_free:1;
	u64 cont_err:1;
	u64 reserved_11_31:21;
	u64 size:13;
	u64 reserved_45_47:3;
	u64 aura:12;
	u64 reserved_60_63:4;
	#endif /* Word 0 - End */
	} s;
	};

	/**
	* Register (NCB) cpt#_vq#_saddr
	*
	* CPT Queue Starting Buffer Address Registers
	* These registers set the instruction buffer starting address.
	* cptx_vqx_saddr_s
	* Word0
	* reserved_49_63:15 [63:49] Reserved.
	* ptr:43 [48:6](R/W/H) Instruction buffer IOVA <48:6> (64-byte aligned).
	* When written, it is the initial buffer starting address; when read,
	* it is the next read pointer to be requested from L2C. The PTR field
	* is overwritten with the next pointer each time that the command buffer
	* segment is exhausted. New commands will then be read from the newly
	* specified command buffer pointer.
	* reserved_0_5:6 [5:0] Reserved.
	*
	*/
	union cptx_vqx_saddr {
	u64 u;
	struct cptx_vqx_saddr_s {
	#if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
	u64 reserved_49_63:15;
	u64 ptr:43;
	u64 reserved_0_5:6;
	#else /* Word 0 - Little Endian */
	u64 reserved_0_5:6;
	u64 ptr:43;
	u64 reserved_49_63:15;
	#endif /* Word 0 - End */
	} s;
	};

	/**
	* Register (NCB) cpt#_vq#_misc_ena_w1s
	*
	* CPT Queue Misc Interrupt Enable Set Register
	* This register sets interrupt enable bits.
	* cptx_vqx_misc_ena_w1s_s
	* Word0
	* reserved_5_63:59 [63:5] Reserved.
	* swerr:1 [4:4](R/W1S/H) Reads or sets enable for
	* CPT(0..1)_VQ(0..63)_MISC_INT[SWERR].
	* nwrp:1 [3:3](R/W1S/H) Reads or sets enable for
	* CPT(0..1)_VQ(0..63)_MISC_INT[NWRP].
	* irde:1 [2:2](R/W1S/H) Reads or sets enable for
	* CPT(0..1)_VQ(0..63)_MISC_INT[IRDE].
	* dovf:1 [1:1](R/W1S/H) Reads or sets enable for
	* CPT(0..1)_VQ(0..63)_MISC_INT[DOVF].
	* mbox:1 [0:0](R/W1S/H) Reads or sets enable for
	* CPT(0..1)_VQ(0..63)_MISC_INT[MBOX].
	*
	*/
	union cptx_vqx_misc_ena_w1s {
	u64 u;
	struct cptx_vqx_misc_ena_w1s_s {
	#if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
	u64 reserved_5_63:59;
	u64 swerr:1;
	u64 nwrp:1;
	u64 irde:1;
	u64 dovf:1;
	u64 mbox:1;
	#else /* Word 0 - Little Endian */
	u64 mbox:1;
	u64 dovf:1;
	u64 irde:1;
	u64 nwrp:1;
	u64 swerr:1;
	u64 reserved_5_63:59;
	#endif /* Word 0 - End */
	} s;
	};

	/**
	* Register (NCB) cpt#_vq#_doorbell
	*
	* CPT Queue Doorbell Registers
	* Doorbells for the CPT instruction queues.
	* cptx_vqx_doorbell_s
	* Word0
	* reserved_20_63:44 [63:20] Reserved.
	* dbell_cnt:20 [19:0](R/W/H) Number of instruction queue 64-bit words to add
	* to the CPT instruction doorbell count. Readback value is the the
	* current number of pending doorbell requests. If counter overflows
	* CPT()_VQ()_MISC_INT[DBELL_DOVF] is set. To reset the count back to
	* zero, write one to clear CPT()_VQ()_MISC_INT_ENA_W1C[DBELL_DOVF],
	* then write a value of 2^20 minus the read [DBELL_CNT], then write one
	* to CPT()_VQ()_MISC_INT_W1C[DBELL_DOVF] and
	* CPT()_VQ()_MISC_INT_ENA_W1S[DBELL_DOVF]. Must be a multiple of 8.
	* All CPT instructions are 8 words and require a doorbell count of
	* multiple of 8.
	*/
	union cptx_vqx_doorbell {
	u64 u;
	struct cptx_vqx_doorbell_s {
	#if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
	u64 reserved_20_63:44;
	u64 dbell_cnt:20;
	#else /* Word 0 - Little Endian */
	u64 dbell_cnt:20;
	u64 reserved_20_63:44;
	#endif /* Word 0 - End */
	} s;
	};

	/**
	* Register (NCB) cpt#_vq#_inprog
	*
	* CPT Queue In Progress Count Registers
	* These registers contain the per-queue instruction in flight registers.
	* cptx_vqx_inprog_s
	* Word0
	* reserved_8_63:56 [63:8] Reserved.
	* inflight:8 [7:0](RO/H) Inflight count. Counts the number of instructions
	* for the VF for which CPT is fetching, executing or responding to
	* instructions. However this does not include any interrupts that are
	* awaiting software handling (CPT()_VQ()_DONE[DONE] != 0x0).
	* A queue may not be reconfigured until:
	* 1. CPT()_VQ()_CTL[ENA] is cleared by software.
	* 2. [INFLIGHT] is polled until equals to zero.
	*/
	union cptx_vqx_inprog {
	u64 u;
	struct cptx_vqx_inprog_s {
	#if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
	u64 reserved_8_63:56;
	u64 inflight:8;
	#else /* Word 0 - Little Endian */
	u64 inflight:8;
	u64 reserved_8_63:56;
	#endif /* Word 0 - End */
	} s;
	};

	/**
	* Register (NCB) cpt#_vq#_misc_int
	*
	* CPT Queue Misc Interrupt Register
	* These registers contain the per-queue miscellaneous interrupts.
	* cptx_vqx_misc_int_s
	* Word 0
	* reserved_5_63:59 [63:5] Reserved.
	* swerr:1 [4:4](R/W1C/H) Software error from engines.
	* nwrp:1 [3:3](R/W1C/H) NCB result write response error.
	* irde:1 [2:2](R/W1C/H) Instruction NCB read response error.
	* dovf:1 [1:1](R/W1C/H) Doorbell overflow.
	* mbox:1 [0:0](R/W1C/H) PF to VF mailbox interrupt. Set when
	* CPT()_VF()_PF_MBOX(0) is written.
	*
	*/
	union cptx_vqx_misc_int {
	u64 u;
	struct cptx_vqx_misc_int_s {
	#if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
	u64 reserved_5_63:59;
	u64 swerr:1;
	u64 nwrp:1;
	u64 irde:1;
	u64 dovf:1;
	u64 mbox:1;
	#else /* Word 0 - Little Endian */
	u64 mbox:1;
	u64 dovf:1;
	u64 irde:1;
	u64 nwrp:1;
	u64 swerr:1;
	u64 reserved_5_63:59;
	#endif /* Word 0 - End */
	} s;
	};

	/**
	* Register (NCB) cpt#_vq#_done_ack
	*
	* CPT Queue Done Count Ack Registers
	* This register is written by software to acknowledge interrupts.
	* cptx_vqx_done_ack_s
	* Word0
	* reserved_20_63:44 [63:20] Reserved.
	* done_ack:20 [19:0](R/W/H) Number of decrements to CPT()_VQ()_DONE[DONE].
	* Reads CPT()_VQ()_DONE[DONE]. Written by software to acknowledge
	* interrupts. If CPT()_VQ()_DONE[DONE] is still nonzero the interrupt
	* will be re-sent if the conditions described in CPT()_VQ()_DONE[DONE]
	* are satisfied.
	*
	*/
	union cptx_vqx_done_ack {
	u64 u;
	struct cptx_vqx_done_ack_s {
	#if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
	u64 reserved_20_63:44;
	u64 done_ack:20;
	#else /* Word 0 - Little Endian */
	u64 done_ack:20;
	u64 reserved_20_63:44;
	#endif /* Word 0 - End */
	} s;
	};

	/**
	* Register (NCB) cpt#_vq#_done
	*
	* CPT Queue Done Count Registers
	* These registers contain the per-queue instruction done count.
	* cptx_vqx_done_s
	* Word0
	* reserved_20_63:44 [63:20] Reserved.
	* done:20 [19:0](R/W/H) Done count. When CPT_INST_S[DONEINT] set and that
	* instruction completes, CPT()_VQ()_DONE[DONE] is incremented when the
	* instruction finishes. Write to this field are for diagnostic use only;
	* instead software writes CPT()_VQ()_DONE_ACK with the number of
	* decrements for this field.
	* Interrupts are sent as follows:
	* * When CPT()_VQ()_DONE[DONE] = 0, then no results are pending, the
	* interrupt coalescing timer is held to zero, and an interrupt is not
	* sent.
	* * When CPT()_VQ()_DONE[DONE] != 0, then the interrupt coalescing timer
	* counts. If the counter is >= CPT()_VQ()_DONE_WAIT[TIME_WAIT]*1024, or
	* CPT()_VQ()_DONE[DONE] >= CPT()_VQ()_DONE_WAIT[NUM_WAIT], i.e. enough
	* time has passed or enough results have arrived, then the interrupt is
	* sent.
	* * When CPT()_VQ()_DONE_ACK is written (or CPT()_VQ()_DONE is written
	* but this is not typical), the interrupt coalescing timer restarts.
	* Note after decrementing this interrupt equation is recomputed,
	* for example if CPT()_VQ()_DONE[DONE] >= CPT()_VQ()_DONE_WAIT[NUM_WAIT]
	* and because the timer is zero, the interrupt will be resent immediately.
	* (This covers the race case between software acknowledging an interrupt
	* and a result returning.)
	* * When CPT()_VQ()_DONE_ENA_W1S[DONE] = 0, interrupts are not sent,
	* but the counting described above still occurs.
	* Since CPT instructions complete out-of-order, if software is using
	* completion interrupts the suggested scheme is to request a DONEINT on
	* each request, and when an interrupt arrives perform a "greedy" scan for
	* completions; even if a later command is acknowledged first this will
	* not result in missing a completion.
	* Software is responsible for making sure [DONE] does not overflow;
	* for example by insuring there are not more than 2^20-1 instructions in
	* flight that may request interrupts.
	*
	*/
	union cptx_vqx_done {
	u64 u;
	struct cptx_vqx_done_s {
	#if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
	u64 reserved_20_63:44;
	u64 done:20;
	#else /* Word 0 - Little Endian */
	u64 done:20;
	u64 reserved_20_63:44;
	#endif /* Word 0 - End */
	} s;
	};

	/**
	* Register (NCB) cpt#_vq#_done_wait
	*
	* CPT Queue Done Interrupt Coalescing Wait Registers
	* Specifies the per queue interrupt coalescing settings.
	* cptx_vqx_done_wait_s
	* Word0
	* reserved_48_63:16 [63:48] Reserved.
	* time_wait:16; [47:32](R/W) Time hold-off. When CPT()_VQ()_DONE[DONE] = 0
	* or CPT()_VQ()_DONE_ACK is written a timer is cleared. When the timer
	* reaches [TIME_WAIT]*1024 then interrupt coalescing ends.
	* see CPT()_VQ()_DONE[DONE]. If 0x0, time coalescing is disabled.
	* reserved_20_31:12 [31:20] Reserved.
	* num_wait:20 [19:0](R/W) Number of messages hold-off.
	* When CPT()_VQ()_DONE[DONE] >= [NUM_WAIT] then interrupt coalescing ends
	* see CPT()_VQ()_DONE[DONE]. If 0x0, same behavior as 0x1.
	*
	*/
	union cptx_vqx_done_wait {
	u64 u;
	struct cptx_vqx_done_wait_s {
	#if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
	u64 reserved_48_63:16;
	u64 time_wait:16;
	u64 reserved_20_31:12;
	u64 num_wait:20;
	#else /* Word 0 - Little Endian */
	u64 num_wait:20;
	u64 reserved_20_31:12;
	u64 time_wait:16;
	u64 reserved_48_63:16;
	#endif /* Word 0 - End */
	} s;
	};

	/**
	* Register (NCB) cpt#_vq#_done_ena_w1s
	*
	* CPT Queue Done Interrupt Enable Set Registers
	* Write 1 to these registers will enable the DONEINT interrupt for the queue.
	* cptx_vqx_done_ena_w1s_s
	* Word0
	* reserved_1_63:63 [63:1] Reserved.
	* done:1 [0:0](R/W1S/H) Write 1 will enable DONEINT for this queue.
	* Write 0 has no effect. Read will return the enable bit.
	*/
	union cptx_vqx_done_ena_w1s {
	u64 u;
	struct cptx_vqx_done_ena_w1s_s {
	#if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
	u64 reserved_1_63:63;
	u64 done:1;
	#else /* Word 0 - Little Endian */
	u64 done:1;
	u64 reserved_1_63:63;
	#endif /* Word 0 - End */
	} s;
	};

	/**
	* Register (NCB) cpt#_vq#_ctl
	*
	* CPT VF Queue Control Registers
	* This register configures queues. This register should be changed (other than
	* clearing [ENA]) only when quiescent (see CPT()_VQ()_INPROG[INFLIGHT]).
	* cptx_vqx_ctl_s
	* Word0
	* reserved_1_63:63 [63:1] Reserved.
	* ena:1 [0:0](R/W/H) Enables the logical instruction queue.
	* See also CPT()_PF_Q()_CTL[CONT_ERR] and CPT()_VQ()_INPROG[INFLIGHT].
	* 1 = Queue is enabled.
	* 0 = Queue is disabled.
	*/
	union cptx_vqx_ctl {
	u64 u;
	struct cptx_vqx_ctl_s {
	#if defined(__BIG_ENDIAN_BITFIELD) /* Word 0 - Big Endian */
	u64 reserved_1_63:63;
	u64 ena:1;
	#else /* Word 0 - Little Endian */
	u64 ena:1;
	u64 reserved_1_63:63;
	#endif /* Word 0 - End */
	} s;
	};
	#endif /__CPT_HW_TYPES_H/