freebsd-nq/sys/contrib/octeon-sdk/cvmx-l2d-defs.h
Juli Mallett dc4ee6ca91 Merge the Cavium Octeon SDK 2.3.0 Simple Executive code and update FreeBSD to
make use of it where possible.

This primarily brings in support for newer hardware, and FreeBSD is not yet
able to support the abundance of IRQs on new hardware and many features in the
Ethernet driver.

Because of the changes to IRQs in the Simple Executive, we have to maintain our
own list of Octeon IRQs now, which probably can be pared-down and be specific
to the CIU interrupt unit soon, and when other interrupt mechanisms are added
they can maintain their own definitions.

Remove unmasking of interrupts from within the UART device now that the
function used is no longer present in the Simple Executive.  The unmasking
seems to have been gratuitous as this is more properly handled by the buses
above the UART device, and seems to work on that basis.
2012-03-11 06:17:49 +00:00

1137 lines
61 KiB
C

/***********************license start***************
* Copyright (c) 2003-2012 Cavium Inc. (support@cavium.com). All rights
* reserved.
*
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are
* met:
*
* * Redistributions of source code must retain the above copyright
* notice, this list of conditions and the following disclaimer.
*
* * Redistributions in binary form must reproduce the above
* copyright notice, this list of conditions and the following
* disclaimer in the documentation and/or other materials provided
* with the distribution.
* * Neither the name of Cavium Inc. nor the names of
* its contributors may be used to endorse or promote products
* derived from this software without specific prior written
* permission.
* This Software, including technical data, may be subject to U.S. export control
* laws, including the U.S. Export Administration Act and its associated
* regulations, and may be subject to export or import regulations in other
* countries.
* TO THE MAXIMUM EXTENT PERMITTED BY LAW, THE SOFTWARE IS PROVIDED "AS IS"
* AND WITH ALL FAULTS AND CAVIUM INC. MAKES NO PROMISES, REPRESENTATIONS OR
* WARRANTIES, EITHER EXPRESS, IMPLIED, STATUTORY, OR OTHERWISE, WITH RESPECT TO
* THE SOFTWARE, INCLUDING ITS CONDITION, ITS CONFORMITY TO ANY REPRESENTATION OR
* DESCRIPTION, OR THE EXISTENCE OF ANY LATENT OR PATENT DEFECTS, AND CAVIUM
* SPECIFICALLY DISCLAIMS ALL IMPLIED (IF ANY) WARRANTIES OF TITLE,
* MERCHANTABILITY, NONINFRINGEMENT, FITNESS FOR A PARTICULAR PURPOSE, LACK OF
* VIRUSES, ACCURACY OR COMPLETENESS, QUIET ENJOYMENT, QUIET POSSESSION OR
* CORRESPONDENCE TO DESCRIPTION. THE ENTIRE RISK ARISING OUT OF USE OR
* PERFORMANCE OF THE SOFTWARE LIES WITH YOU.
***********************license end**************************************/
/**
* cvmx-l2d-defs.h
*
* Configuration and status register (CSR) type definitions for
* Octeon l2d.
*
* This file is auto generated. Do not edit.
*
* <hr>$Revision$<hr>
*
*/
#ifndef __CVMX_L2D_DEFS_H__
#define __CVMX_L2D_DEFS_H__
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_L2D_BST0 CVMX_L2D_BST0_FUNC()
static inline uint64_t CVMX_L2D_BST0_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN3XXX) || OCTEON_IS_MODEL(OCTEON_CN5XXX)))
cvmx_warn("CVMX_L2D_BST0 not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180080000780ull);
}
#else
#define CVMX_L2D_BST0 (CVMX_ADD_IO_SEG(0x0001180080000780ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_L2D_BST1 CVMX_L2D_BST1_FUNC()
static inline uint64_t CVMX_L2D_BST1_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN3XXX) || OCTEON_IS_MODEL(OCTEON_CN5XXX)))
cvmx_warn("CVMX_L2D_BST1 not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180080000788ull);
}
#else
#define CVMX_L2D_BST1 (CVMX_ADD_IO_SEG(0x0001180080000788ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_L2D_BST2 CVMX_L2D_BST2_FUNC()
static inline uint64_t CVMX_L2D_BST2_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN3XXX) || OCTEON_IS_MODEL(OCTEON_CN5XXX)))
cvmx_warn("CVMX_L2D_BST2 not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180080000790ull);
}
#else
#define CVMX_L2D_BST2 (CVMX_ADD_IO_SEG(0x0001180080000790ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_L2D_BST3 CVMX_L2D_BST3_FUNC()
static inline uint64_t CVMX_L2D_BST3_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN3XXX) || OCTEON_IS_MODEL(OCTEON_CN5XXX)))
cvmx_warn("CVMX_L2D_BST3 not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180080000798ull);
}
#else
#define CVMX_L2D_BST3 (CVMX_ADD_IO_SEG(0x0001180080000798ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_L2D_ERR CVMX_L2D_ERR_FUNC()
static inline uint64_t CVMX_L2D_ERR_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN3XXX) || OCTEON_IS_MODEL(OCTEON_CN5XXX)))
cvmx_warn("CVMX_L2D_ERR not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180080000010ull);
}
#else
#define CVMX_L2D_ERR (CVMX_ADD_IO_SEG(0x0001180080000010ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_L2D_FADR CVMX_L2D_FADR_FUNC()
static inline uint64_t CVMX_L2D_FADR_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN3XXX) || OCTEON_IS_MODEL(OCTEON_CN5XXX)))
cvmx_warn("CVMX_L2D_FADR not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180080000018ull);
}
#else
#define CVMX_L2D_FADR (CVMX_ADD_IO_SEG(0x0001180080000018ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_L2D_FSYN0 CVMX_L2D_FSYN0_FUNC()
static inline uint64_t CVMX_L2D_FSYN0_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN3XXX) || OCTEON_IS_MODEL(OCTEON_CN5XXX)))
cvmx_warn("CVMX_L2D_FSYN0 not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180080000020ull);
}
#else
#define CVMX_L2D_FSYN0 (CVMX_ADD_IO_SEG(0x0001180080000020ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_L2D_FSYN1 CVMX_L2D_FSYN1_FUNC()
static inline uint64_t CVMX_L2D_FSYN1_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN3XXX) || OCTEON_IS_MODEL(OCTEON_CN5XXX)))
cvmx_warn("CVMX_L2D_FSYN1 not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180080000028ull);
}
#else
#define CVMX_L2D_FSYN1 (CVMX_ADD_IO_SEG(0x0001180080000028ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_L2D_FUS0 CVMX_L2D_FUS0_FUNC()
static inline uint64_t CVMX_L2D_FUS0_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN3XXX) || OCTEON_IS_MODEL(OCTEON_CN5XXX)))
cvmx_warn("CVMX_L2D_FUS0 not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x00011800800007A0ull);
}
#else
#define CVMX_L2D_FUS0 (CVMX_ADD_IO_SEG(0x00011800800007A0ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_L2D_FUS1 CVMX_L2D_FUS1_FUNC()
static inline uint64_t CVMX_L2D_FUS1_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN3XXX) || OCTEON_IS_MODEL(OCTEON_CN5XXX)))
cvmx_warn("CVMX_L2D_FUS1 not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x00011800800007A8ull);
}
#else
#define CVMX_L2D_FUS1 (CVMX_ADD_IO_SEG(0x00011800800007A8ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_L2D_FUS2 CVMX_L2D_FUS2_FUNC()
static inline uint64_t CVMX_L2D_FUS2_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN3XXX) || OCTEON_IS_MODEL(OCTEON_CN5XXX)))
cvmx_warn("CVMX_L2D_FUS2 not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x00011800800007B0ull);
}
#else
#define CVMX_L2D_FUS2 (CVMX_ADD_IO_SEG(0x00011800800007B0ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_L2D_FUS3 CVMX_L2D_FUS3_FUNC()
static inline uint64_t CVMX_L2D_FUS3_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN3XXX) || OCTEON_IS_MODEL(OCTEON_CN5XXX)))
cvmx_warn("CVMX_L2D_FUS3 not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x00011800800007B8ull);
}
#else
#define CVMX_L2D_FUS3 (CVMX_ADD_IO_SEG(0x00011800800007B8ull))
#endif
/**
* cvmx_l2d_bst0
*
* L2D_BST0 = L2C Data Store QUAD0 BIST Status Register
*
*/
union cvmx_l2d_bst0 {
uint64_t u64;
struct cvmx_l2d_bst0_s {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_35_63 : 29;
uint64_t ftl : 1; /**< L2C Data Store Fatal Defect(across all QUADs)
2 or more columns were detected bad across all
QUADs[0-3]. Please refer to individual quad failures
for bad column = 0x7e to determine which QUAD was in
error. */
uint64_t q0stat : 34; /**< Bist Results for QUAD0
Failure \#1 Status
[16:14] bad bank
[13:7] bad high column
[6:0] bad low column
Failure \#2 Status
[33:31] bad bank
[30:24] bad high column
[23:17] bad low column
NOTES: For bad high/low column reporting:
0x7f: No failure
0x7e: Fatal Defect: 2 or more bad columns
0-0x45: Bad column
NOTE: If there are less than 2 failures then the
bad bank will be 0x7. */
#else
uint64_t q0stat : 34;
uint64_t ftl : 1;
uint64_t reserved_35_63 : 29;
#endif
} s;
struct cvmx_l2d_bst0_s cn30xx;
struct cvmx_l2d_bst0_s cn31xx;
struct cvmx_l2d_bst0_s cn38xx;
struct cvmx_l2d_bst0_s cn38xxp2;
struct cvmx_l2d_bst0_s cn50xx;
struct cvmx_l2d_bst0_s cn52xx;
struct cvmx_l2d_bst0_s cn52xxp1;
struct cvmx_l2d_bst0_s cn56xx;
struct cvmx_l2d_bst0_s cn56xxp1;
struct cvmx_l2d_bst0_s cn58xx;
struct cvmx_l2d_bst0_s cn58xxp1;
};
typedef union cvmx_l2d_bst0 cvmx_l2d_bst0_t;
/**
* cvmx_l2d_bst1
*
* L2D_BST1 = L2C Data Store QUAD1 BIST Status Register
*
*/
union cvmx_l2d_bst1 {
uint64_t u64;
struct cvmx_l2d_bst1_s {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_34_63 : 30;
uint64_t q1stat : 34; /**< Bist Results for QUAD1
Failure \#1 Status
[16:14] bad bank
[13:7] bad high column
[6:0] bad low column
Failure \#2 Status
[33:31] bad bank
[30:24] bad high column
[23:17] bad low column
NOTES: For bad high/low column reporting:
0x7f: No failure
0x7e: Fatal Defect: 2 or more bad columns
0-0x45: Bad column
NOTE: If there are less than 2 failures then the
bad bank will be 0x7. */
#else
uint64_t q1stat : 34;
uint64_t reserved_34_63 : 30;
#endif
} s;
struct cvmx_l2d_bst1_s cn30xx;
struct cvmx_l2d_bst1_s cn31xx;
struct cvmx_l2d_bst1_s cn38xx;
struct cvmx_l2d_bst1_s cn38xxp2;
struct cvmx_l2d_bst1_s cn50xx;
struct cvmx_l2d_bst1_s cn52xx;
struct cvmx_l2d_bst1_s cn52xxp1;
struct cvmx_l2d_bst1_s cn56xx;
struct cvmx_l2d_bst1_s cn56xxp1;
struct cvmx_l2d_bst1_s cn58xx;
struct cvmx_l2d_bst1_s cn58xxp1;
};
typedef union cvmx_l2d_bst1 cvmx_l2d_bst1_t;
/**
* cvmx_l2d_bst2
*
* L2D_BST2 = L2C Data Store QUAD2 BIST Status Register
*
*/
union cvmx_l2d_bst2 {
uint64_t u64;
struct cvmx_l2d_bst2_s {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_34_63 : 30;
uint64_t q2stat : 34; /**< Bist Results for QUAD2
Failure \#1 Status
[16:14] bad bank
[13:7] bad high column
[6:0] bad low column
Failure \#2 Status
[33:31] bad bank
[30:24] bad high column
[23:17] bad low column
NOTES: For bad high/low column reporting:
0x7f: No failure
0x7e: Fatal Defect: 2 or more bad columns
0-0x45: Bad column
NOTE: If there are less than 2 failures then the
bad bank will be 0x7. */
#else
uint64_t q2stat : 34;
uint64_t reserved_34_63 : 30;
#endif
} s;
struct cvmx_l2d_bst2_s cn30xx;
struct cvmx_l2d_bst2_s cn31xx;
struct cvmx_l2d_bst2_s cn38xx;
struct cvmx_l2d_bst2_s cn38xxp2;
struct cvmx_l2d_bst2_s cn50xx;
struct cvmx_l2d_bst2_s cn52xx;
struct cvmx_l2d_bst2_s cn52xxp1;
struct cvmx_l2d_bst2_s cn56xx;
struct cvmx_l2d_bst2_s cn56xxp1;
struct cvmx_l2d_bst2_s cn58xx;
struct cvmx_l2d_bst2_s cn58xxp1;
};
typedef union cvmx_l2d_bst2 cvmx_l2d_bst2_t;
/**
* cvmx_l2d_bst3
*
* L2D_BST3 = L2C Data Store QUAD3 BIST Status Register
*
*/
union cvmx_l2d_bst3 {
uint64_t u64;
struct cvmx_l2d_bst3_s {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_34_63 : 30;
uint64_t q3stat : 34; /**< Bist Results for QUAD3
Failure \#1 Status
[16:14] bad bank
[13:7] bad high column
[6:0] bad low column
Failure \#2 Status
[33:31] bad bank
[30:24] bad high column
[23:17] bad low column
NOTES: For bad high/low column reporting:
0x7f: No failure
0x7e: Fatal Defect: 2 or more bad columns
0-0x45: Bad column
NOTE: If there are less than 2 failures then the
bad bank will be 0x7. */
#else
uint64_t q3stat : 34;
uint64_t reserved_34_63 : 30;
#endif
} s;
struct cvmx_l2d_bst3_s cn30xx;
struct cvmx_l2d_bst3_s cn31xx;
struct cvmx_l2d_bst3_s cn38xx;
struct cvmx_l2d_bst3_s cn38xxp2;
struct cvmx_l2d_bst3_s cn50xx;
struct cvmx_l2d_bst3_s cn52xx;
struct cvmx_l2d_bst3_s cn52xxp1;
struct cvmx_l2d_bst3_s cn56xx;
struct cvmx_l2d_bst3_s cn56xxp1;
struct cvmx_l2d_bst3_s cn58xx;
struct cvmx_l2d_bst3_s cn58xxp1;
};
typedef union cvmx_l2d_bst3 cvmx_l2d_bst3_t;
/**
* cvmx_l2d_err
*
* L2D_ERR = L2 Data Errors
*
* Description: L2 Data ECC SEC/DED Errors and Interrupt Enable
*/
union cvmx_l2d_err {
uint64_t u64;
struct cvmx_l2d_err_s {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_6_63 : 58;
uint64_t bmhclsel : 1; /**< L2 Bit Map Half CacheLine ECC Selector
When L2C_DBG[L2T]=1/L2D_ERR[ECC_ENA]=0, the BMHCLSEL selects
which half cacheline to conditionally latch into
the L2D_FSYN0/L2D_FSYN1 registers when an LDD command
is detected from the diagnostic PP (see L2C_DBG[PPNUM]).
- 0: OW[0-3] ECC (from first 1/2 cacheline) is selected to
be conditionally latched into the L2D_FSYN0/1 CSRs.
- 1: OW[4-7] ECC (from last 1/2 cacheline) is selected to
be conditionally latched into
the L2D_FSYN0/1 CSRs. */
uint64_t ded_err : 1; /**< L2D Double Error detected (DED) */
uint64_t sec_err : 1; /**< L2D Single Error corrected (SEC) */
uint64_t ded_intena : 1; /**< L2 Data ECC Double Error Detect(DED) Interrupt Enable bit
When set, allows interrupts to be reported on double bit
(uncorrectable) errors from the L2 Data Arrays. */
uint64_t sec_intena : 1; /**< L2 Data ECC Single Error Correct(SEC) Interrupt Enable bit
When set, allows interrupts to be reported on single bit
(correctable) errors from the L2 Data Arrays. */
uint64_t ecc_ena : 1; /**< L2 Data ECC Enable
When set, enables 10-bit SEC/DED codeword for 128bit L2
Data Arrays. */
#else
uint64_t ecc_ena : 1;
uint64_t sec_intena : 1;
uint64_t ded_intena : 1;
uint64_t sec_err : 1;
uint64_t ded_err : 1;
uint64_t bmhclsel : 1;
uint64_t reserved_6_63 : 58;
#endif
} s;
struct cvmx_l2d_err_s cn30xx;
struct cvmx_l2d_err_s cn31xx;
struct cvmx_l2d_err_s cn38xx;
struct cvmx_l2d_err_s cn38xxp2;
struct cvmx_l2d_err_s cn50xx;
struct cvmx_l2d_err_s cn52xx;
struct cvmx_l2d_err_s cn52xxp1;
struct cvmx_l2d_err_s cn56xx;
struct cvmx_l2d_err_s cn56xxp1;
struct cvmx_l2d_err_s cn58xx;
struct cvmx_l2d_err_s cn58xxp1;
};
typedef union cvmx_l2d_err cvmx_l2d_err_t;
/**
* cvmx_l2d_fadr
*
* L2D_FADR = L2 Failing Address
*
* Description: L2 Data ECC SEC/DED Failing Address
*
* Notes:
* When L2D_SEC_ERR or L2D_DED_ERR are set, this field contains the failing L2 Data store index.
* (A DED Error will always overwrite a SEC Error SYNDROME and FADR).
*/
union cvmx_l2d_fadr {
uint64_t u64;
struct cvmx_l2d_fadr_s {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_19_63 : 45;
uint64_t fadru : 1; /**< Failing L2 Data Store Upper Index bit(MSB) */
uint64_t fowmsk : 4; /**< Failing OW Mask (which one of 4 OWs contained SEC/DED
error) */
uint64_t fset : 3; /**< Failing SET# */
uint64_t fadr : 11; /**< Failing L2 Data Store Lower Index bits
(NOTE: L2 Data Store Index is for each 1/2 cacheline)
[FADRU, FADR[10:1]]: cacheline index[17:7]
FADR[0]: 1/2 cacheline index
NOTE: FADR[1] is used to select between upper/lower 1MB
physical L2 Data Store banks. */
#else
uint64_t fadr : 11;
uint64_t fset : 3;
uint64_t fowmsk : 4;
uint64_t fadru : 1;
uint64_t reserved_19_63 : 45;
#endif
} s;
struct cvmx_l2d_fadr_cn30xx {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_18_63 : 46;
uint64_t fowmsk : 4; /**< Failing OW Mask (which one of 4 OWs contained SEC/DED
error) */
uint64_t reserved_13_13 : 1;
uint64_t fset : 2; /**< Failing SET# */
uint64_t reserved_9_10 : 2;
uint64_t fadr : 9; /**< Failing L2 Data Store Index(1of512 = 1/2 CL address) */
#else
uint64_t fadr : 9;
uint64_t reserved_9_10 : 2;
uint64_t fset : 2;
uint64_t reserved_13_13 : 1;
uint64_t fowmsk : 4;
uint64_t reserved_18_63 : 46;
#endif
} cn30xx;
struct cvmx_l2d_fadr_cn31xx {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_18_63 : 46;
uint64_t fowmsk : 4; /**< Failing OW Mask (which one of 4 OWs contained SEC/DED
error) */
uint64_t reserved_13_13 : 1;
uint64_t fset : 2; /**< Failing SET# */
uint64_t reserved_10_10 : 1;
uint64_t fadr : 10; /**< Failing L2 Data Store Index
(1 of 1024 = half cacheline indices) */
#else
uint64_t fadr : 10;
uint64_t reserved_10_10 : 1;
uint64_t fset : 2;
uint64_t reserved_13_13 : 1;
uint64_t fowmsk : 4;
uint64_t reserved_18_63 : 46;
#endif
} cn31xx;
struct cvmx_l2d_fadr_cn38xx {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_18_63 : 46;
uint64_t fowmsk : 4; /**< Failing OW Mask (which one of 4 OWs contained SEC/DED
error) */
uint64_t fset : 3; /**< Failing SET# */
uint64_t fadr : 11; /**< Failing L2 Data Store Index (1of2K = 1/2 CL address) */
#else
uint64_t fadr : 11;
uint64_t fset : 3;
uint64_t fowmsk : 4;
uint64_t reserved_18_63 : 46;
#endif
} cn38xx;
struct cvmx_l2d_fadr_cn38xx cn38xxp2;
struct cvmx_l2d_fadr_cn50xx {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_18_63 : 46;
uint64_t fowmsk : 4; /**< Failing OW Mask (which one of 4 OWs contained SEC/DED
error) */
uint64_t fset : 3; /**< Failing SET# */
uint64_t reserved_8_10 : 3;
uint64_t fadr : 8; /**< Failing L2 Data Store Lower Index bits
(NOTE: L2 Data Store Index is for each 1/2 cacheline)
FADR[7:1]: cacheline index[13:7]
FADR[0]: 1/2 cacheline index */
#else
uint64_t fadr : 8;
uint64_t reserved_8_10 : 3;
uint64_t fset : 3;
uint64_t fowmsk : 4;
uint64_t reserved_18_63 : 46;
#endif
} cn50xx;
struct cvmx_l2d_fadr_cn52xx {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_18_63 : 46;
uint64_t fowmsk : 4; /**< Failing OW Mask (which one of 4 OWs contained SEC/DED
error) */
uint64_t fset : 3; /**< Failing SET# */
uint64_t reserved_10_10 : 1;
uint64_t fadr : 10; /**< Failing L2 Data Store Lower Index bits
(NOTE: L2 Data Store Index is for each 1/2 cacheline)
FADR[9:1]: cacheline index[15:7]
FADR[0]: 1/2 cacheline index */
#else
uint64_t fadr : 10;
uint64_t reserved_10_10 : 1;
uint64_t fset : 3;
uint64_t fowmsk : 4;
uint64_t reserved_18_63 : 46;
#endif
} cn52xx;
struct cvmx_l2d_fadr_cn52xx cn52xxp1;
struct cvmx_l2d_fadr_s cn56xx;
struct cvmx_l2d_fadr_s cn56xxp1;
struct cvmx_l2d_fadr_s cn58xx;
struct cvmx_l2d_fadr_s cn58xxp1;
};
typedef union cvmx_l2d_fadr cvmx_l2d_fadr_t;
/**
* cvmx_l2d_fsyn0
*
* L2D_FSYN0 = L2 Failing Syndrome [OW0,4 / OW1,5]
*
* Description: L2 Data ECC SEC/DED Failing Syndrome for lower cache line
*
* Notes:
* When L2D_SEC_ERR or L2D_DED_ERR are set, this field contains the failing L2 Data ECC 10b syndrome.
* (A DED Error will always overwrite a SEC Error SYNDROME and FADR).
*/
union cvmx_l2d_fsyn0 {
uint64_t u64;
struct cvmx_l2d_fsyn0_s {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_20_63 : 44;
uint64_t fsyn_ow1 : 10; /**< Failing L2 Data Store SYNDROME OW[1,5]
When L2D_ERR[ECC_ENA]=1 and either L2D_ERR[SEC_ERR]
or L2D_ERR[DED_ERR] are set, this field represents
the failing OWECC syndrome for the half cacheline
indexed by L2D_FADR[FADR].
NOTE: The L2D_FADR[FOWMSK] further qualifies which
OW lane(1of4) detected the error.
When L2C_DBG[L2T]=1 and L2D_ERR[ECC_ENA]=0, an LDD
command from the diagnostic PP will conditionally latch
the raw OWECC for the selected half cacheline.
(see: L2D_ERR[BMHCLSEL] */
uint64_t fsyn_ow0 : 10; /**< Failing L2 Data Store SYNDROME OW[0,4]
When L2D_ERR[ECC_ENA]=1 and either L2D_ERR[SEC_ERR]
or L2D_ERR[DED_ERR] are set, this field represents
the failing OWECC syndrome for the half cacheline
indexed by L2D_FADR[FADR].
NOTE: The L2D_FADR[FOWMSK] further qualifies which
OW lane(1of4) detected the error.
When L2C_DBG[L2T]=1 and L2D_ERR[ECC_ENA]=0, an LDD
(L1 load-miss) from the diagnostic PP will conditionally
latch the raw OWECC for the selected half cacheline.
(see: L2D_ERR[BMHCLSEL] */
#else
uint64_t fsyn_ow0 : 10;
uint64_t fsyn_ow1 : 10;
uint64_t reserved_20_63 : 44;
#endif
} s;
struct cvmx_l2d_fsyn0_s cn30xx;
struct cvmx_l2d_fsyn0_s cn31xx;
struct cvmx_l2d_fsyn0_s cn38xx;
struct cvmx_l2d_fsyn0_s cn38xxp2;
struct cvmx_l2d_fsyn0_s cn50xx;
struct cvmx_l2d_fsyn0_s cn52xx;
struct cvmx_l2d_fsyn0_s cn52xxp1;
struct cvmx_l2d_fsyn0_s cn56xx;
struct cvmx_l2d_fsyn0_s cn56xxp1;
struct cvmx_l2d_fsyn0_s cn58xx;
struct cvmx_l2d_fsyn0_s cn58xxp1;
};
typedef union cvmx_l2d_fsyn0 cvmx_l2d_fsyn0_t;
/**
* cvmx_l2d_fsyn1
*
* L2D_FSYN1 = L2 Failing Syndrome [OW2,6 / OW3,7]
*
* Description: L2 Data ECC SEC/DED Failing Syndrome for upper cache line
*
* Notes:
* When L2D_SEC_ERR or L2D_DED_ERR are set, this field contains the failing L2 Data ECC 10b syndrome.
* (A DED Error will always overwrite a SEC Error SYNDROME and FADR).
*/
union cvmx_l2d_fsyn1 {
uint64_t u64;
struct cvmx_l2d_fsyn1_s {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_20_63 : 44;
uint64_t fsyn_ow3 : 10; /**< Failing L2 Data Store SYNDROME OW[3,7] */
uint64_t fsyn_ow2 : 10; /**< Failing L2 Data Store SYNDROME OW[2,5] */
#else
uint64_t fsyn_ow2 : 10;
uint64_t fsyn_ow3 : 10;
uint64_t reserved_20_63 : 44;
#endif
} s;
struct cvmx_l2d_fsyn1_s cn30xx;
struct cvmx_l2d_fsyn1_s cn31xx;
struct cvmx_l2d_fsyn1_s cn38xx;
struct cvmx_l2d_fsyn1_s cn38xxp2;
struct cvmx_l2d_fsyn1_s cn50xx;
struct cvmx_l2d_fsyn1_s cn52xx;
struct cvmx_l2d_fsyn1_s cn52xxp1;
struct cvmx_l2d_fsyn1_s cn56xx;
struct cvmx_l2d_fsyn1_s cn56xxp1;
struct cvmx_l2d_fsyn1_s cn58xx;
struct cvmx_l2d_fsyn1_s cn58xxp1;
};
typedef union cvmx_l2d_fsyn1 cvmx_l2d_fsyn1_t;
/**
* cvmx_l2d_fus0
*
* L2D_FUS0 = L2C Data Store QUAD0 Fuse Register
*
*/
union cvmx_l2d_fus0 {
uint64_t u64;
struct cvmx_l2d_fus0_s {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_34_63 : 30;
uint64_t q0fus : 34; /**< Fuse Register for QUAD0
This is purely for debug and not needed in the general
manufacturing flow.
Note that the fuse are complementary (Assigning a
fuse to 1 will read as a zero). This means the case
where no fuses are blown result in these csr's showing
all ones.
Failure \#1 Fuse Mapping
[16:14] bad bank
[13:7] bad high column
[6:0] bad low column
Failure \#2 Fuse Mapping
[33:31] bad bank
[30:24] bad high column
[23:17] bad low column */
#else
uint64_t q0fus : 34;
uint64_t reserved_34_63 : 30;
#endif
} s;
struct cvmx_l2d_fus0_s cn30xx;
struct cvmx_l2d_fus0_s cn31xx;
struct cvmx_l2d_fus0_s cn38xx;
struct cvmx_l2d_fus0_s cn38xxp2;
struct cvmx_l2d_fus0_s cn50xx;
struct cvmx_l2d_fus0_s cn52xx;
struct cvmx_l2d_fus0_s cn52xxp1;
struct cvmx_l2d_fus0_s cn56xx;
struct cvmx_l2d_fus0_s cn56xxp1;
struct cvmx_l2d_fus0_s cn58xx;
struct cvmx_l2d_fus0_s cn58xxp1;
};
typedef union cvmx_l2d_fus0 cvmx_l2d_fus0_t;
/**
* cvmx_l2d_fus1
*
* L2D_FUS1 = L2C Data Store QUAD1 Fuse Register
*
*/
union cvmx_l2d_fus1 {
uint64_t u64;
struct cvmx_l2d_fus1_s {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_34_63 : 30;
uint64_t q1fus : 34; /**< Fuse Register for QUAD1
This is purely for debug and not needed in the general
manufacturing flow.
Note that the fuse are complementary (Assigning a
fuse to 1 will read as a zero). This means the case
where no fuses are blown result in these csr's showing
all ones.
Failure \#1 Fuse Mapping
[16:14] bad bank
[13:7] bad high column
[6:0] bad low column
Failure \#2 Fuse Mapping
[33:31] bad bank
[30:24] bad high column
[23:17] bad low column */
#else
uint64_t q1fus : 34;
uint64_t reserved_34_63 : 30;
#endif
} s;
struct cvmx_l2d_fus1_s cn30xx;
struct cvmx_l2d_fus1_s cn31xx;
struct cvmx_l2d_fus1_s cn38xx;
struct cvmx_l2d_fus1_s cn38xxp2;
struct cvmx_l2d_fus1_s cn50xx;
struct cvmx_l2d_fus1_s cn52xx;
struct cvmx_l2d_fus1_s cn52xxp1;
struct cvmx_l2d_fus1_s cn56xx;
struct cvmx_l2d_fus1_s cn56xxp1;
struct cvmx_l2d_fus1_s cn58xx;
struct cvmx_l2d_fus1_s cn58xxp1;
};
typedef union cvmx_l2d_fus1 cvmx_l2d_fus1_t;
/**
* cvmx_l2d_fus2
*
* L2D_FUS2 = L2C Data Store QUAD2 Fuse Register
*
*/
union cvmx_l2d_fus2 {
uint64_t u64;
struct cvmx_l2d_fus2_s {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_34_63 : 30;
uint64_t q2fus : 34; /**< Fuse Register for QUAD2
This is purely for debug and not needed in the general
manufacturing flow.
Note that the fuse are complementary (Assigning a
fuse to 1 will read as a zero). This means the case
where no fuses are blown result in these csr's showing
all ones.
Failure \#1 Fuse Mapping
[16:14] bad bank
[13:7] bad high column
[6:0] bad low column
Failure \#2 Fuse Mapping
[33:31] bad bank
[30:24] bad high column
[23:17] bad low column */
#else
uint64_t q2fus : 34;
uint64_t reserved_34_63 : 30;
#endif
} s;
struct cvmx_l2d_fus2_s cn30xx;
struct cvmx_l2d_fus2_s cn31xx;
struct cvmx_l2d_fus2_s cn38xx;
struct cvmx_l2d_fus2_s cn38xxp2;
struct cvmx_l2d_fus2_s cn50xx;
struct cvmx_l2d_fus2_s cn52xx;
struct cvmx_l2d_fus2_s cn52xxp1;
struct cvmx_l2d_fus2_s cn56xx;
struct cvmx_l2d_fus2_s cn56xxp1;
struct cvmx_l2d_fus2_s cn58xx;
struct cvmx_l2d_fus2_s cn58xxp1;
};
typedef union cvmx_l2d_fus2 cvmx_l2d_fus2_t;
/**
* cvmx_l2d_fus3
*
* L2D_FUS3 = L2C Data Store QUAD3 Fuse Register
*
*/
union cvmx_l2d_fus3 {
uint64_t u64;
struct cvmx_l2d_fus3_s {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_40_63 : 24;
uint64_t ema_ctl : 3; /**< L2 Data Store EMA Control
These bits are used to 'observe' the EMA[1:0] inputs
for the L2 Data Store RAMs which are controlled by
either FUSES[141:140] or by MIO_FUSE_EMA[EMA] CSR.
From poweron (dc_ok), the EMA_CTL are driven from
FUSE[141:140]. However after the 1st CSR write to the
MIO_FUSE_EMA[EMA] bits, the EMA_CTL will source
from the MIO_FUSE_EMA[EMA] register permanently
(until dc_ok). */
uint64_t reserved_34_36 : 3;
uint64_t q3fus : 34; /**< Fuse Register for QUAD3
This is purely for debug and not needed in the general
manufacturing flow.
Note that the fuses are complementary (Assigning a
fuse to 1 will read as a zero). This means the case
where no fuses are blown result in these csr's showing
all ones.
Failure \#1 Fuse Mapping
[16:14] bad bank
[13:7] bad high column
[6:0] bad low column
Failure \#2 Fuse Mapping
[33:31] bad bank
[30:24] bad high column
[23:17] bad low column */
#else
uint64_t q3fus : 34;
uint64_t reserved_34_36 : 3;
uint64_t ema_ctl : 3;
uint64_t reserved_40_63 : 24;
#endif
} s;
struct cvmx_l2d_fus3_cn30xx {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_35_63 : 29;
uint64_t crip_64k : 1; /**< This is purely for debug and not needed in the general
manufacturing flow.
If the FUSE is not-blown, then this bit should read
as 0. If the FUSE is blown, then this bit should read
as 1. */
uint64_t q3fus : 34; /**< Fuse Register for QUAD3
This is purely for debug and not needed in the general
manufacturing flow.
Note that the fuses are complementary (Assigning a
fuse to 1 will read as a zero). This means the case
where no fuses are blown result in these csr's showing
all ones.
Failure \#1 Fuse Mapping
[16:15] UNUSED
[14] bad bank
[13:7] bad high column
[6:0] bad low column
Failure \#2 Fuse Mapping
[33:32] UNUSED
[31] bad bank
[30:24] bad high column
[23:17] bad low column */
#else
uint64_t q3fus : 34;
uint64_t crip_64k : 1;
uint64_t reserved_35_63 : 29;
#endif
} cn30xx;
struct cvmx_l2d_fus3_cn31xx {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_35_63 : 29;
uint64_t crip_128k : 1; /**< This is purely for debug and not needed in the general
manufacturing flow.
If the FUSE is not-blown, then this bit should read
as 0. If the FUSE is blown, then this bit should read
as 1. */
uint64_t q3fus : 34; /**< Fuse Register for QUAD3
This is purely for debug and not needed in the general
manufacturing flow.
Note that the fuses are complementary (Assigning a
fuse to 1 will read as a zero). This means the case
where no fuses are blown result in these csr's showing
all ones.
Failure \#1 Fuse Mapping
[16:15] UNUSED
[14] bad bank
[13:7] bad high column
[6:0] bad low column
Failure \#2 Fuse Mapping
[33:32] UNUSED
[31] bad bank
[30:24] bad high column
[23:17] bad low column */
#else
uint64_t q3fus : 34;
uint64_t crip_128k : 1;
uint64_t reserved_35_63 : 29;
#endif
} cn31xx;
struct cvmx_l2d_fus3_cn38xx {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_36_63 : 28;
uint64_t crip_256k : 1; /**< This is purely for debug and not needed in the general
manufacturing flow.
If the FUSE is not-blown, then this bit should read
as 0. If the FUSE is blown, then this bit should read
as 1.
*** NOTE: Pass2 Addition */
uint64_t crip_512k : 1; /**< This is purely for debug and not needed in the general
manufacturing flow.
If the FUSE is not-blown, then this bit should read
as 0. If the FUSE is blown, then this bit should read
as 1.
*** NOTE: Pass2 Addition */
uint64_t q3fus : 34; /**< Fuse Register for QUAD3
This is purely for debug and not needed in the general
manufacturing flow.
Note that the fuses are complementary (Assigning a
fuse to 1 will read as a zero). This means the case
where no fuses are blown result in these csr's showing
all ones.
Failure \#1 Fuse Mapping
[16:14] bad bank
[13:7] bad high column
[6:0] bad low column
Failure \#2 Fuse Mapping
[33:31] bad bank
[30:24] bad high column
[23:17] bad low column */
#else
uint64_t q3fus : 34;
uint64_t crip_512k : 1;
uint64_t crip_256k : 1;
uint64_t reserved_36_63 : 28;
#endif
} cn38xx;
struct cvmx_l2d_fus3_cn38xx cn38xxp2;
struct cvmx_l2d_fus3_cn50xx {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_40_63 : 24;
uint64_t ema_ctl : 3; /**< L2 Data Store EMA Control
These bits are used to 'observe' the EMA[2:0] inputs
for the L2 Data Store RAMs which are controlled by
either FUSES[142:140] or by MIO_FUSE_EMA[EMA] CSR.
From poweron (dc_ok), the EMA_CTL are driven from
FUSE[141:140]. However after the 1st CSR write to the
MIO_FUSE_EMA[EMA] bits, the EMA_CTL will source
from the MIO_FUSE_EMA[EMA] register permanently
(until dc_ok). */
uint64_t reserved_36_36 : 1;
uint64_t crip_32k : 1; /**< This is purely for debug and not needed in the general
manufacturing flow.
If the FUSE is not-blown, then this bit should read
as 0. If the FUSE is blown, then this bit should read
as 1. */
uint64_t crip_64k : 1; /**< This is purely for debug and not needed in the general
manufacturing flow.
If the FUSE is not-blown, then this bit should read
as 0. If the FUSE is blown, then this bit should read
as 1. */
uint64_t q3fus : 34; /**< Fuse Register for QUAD3
This is purely for debug and not needed in the general
manufacturing flow.
Note that the fuses are complementary (Assigning a
fuse to 1 will read as a zero). This means the case
where no fuses are blown result in these csr's showing
all ones.
Failure \#1 Fuse Mapping
[16:14] UNUSED (5020 uses single physical bank per quad)
[13:7] bad high column
[6:0] bad low column
Failure \#2 Fuse Mapping
[33:31] UNUSED (5020 uses single physical bank per quad)
[30:24] bad high column
[23:17] bad low column */
#else
uint64_t q3fus : 34;
uint64_t crip_64k : 1;
uint64_t crip_32k : 1;
uint64_t reserved_36_36 : 1;
uint64_t ema_ctl : 3;
uint64_t reserved_40_63 : 24;
#endif
} cn50xx;
struct cvmx_l2d_fus3_cn52xx {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_40_63 : 24;
uint64_t ema_ctl : 3; /**< L2 Data Store EMA Control
These bits are used to 'observe' the EMA[2:0] inputs
for the L2 Data Store RAMs which are controlled by
either FUSES[142:140] or by MIO_FUSE_EMA[EMA] CSR.
From poweron (dc_ok), the EMA_CTL are driven from
FUSE[141:140]. However after the 1st CSR write to the
MIO_FUSE_EMA[EMA] bits, the EMA_CTL will source
from the MIO_FUSE_EMA[EMA] register permanently
(until dc_ok). */
uint64_t reserved_36_36 : 1;
uint64_t crip_128k : 1; /**< This is purely for debug and not needed in the general
manufacturing flow.
If the FUSE is not-blown, then this bit should read
as 0. If the FUSE is blown, then this bit should read
as 1. */
uint64_t crip_256k : 1; /**< This is purely for debug and not needed in the general
manufacturing flow.
If the FUSE is not-blown, then this bit should read
as 0. If the FUSE is blown, then this bit should read
as 1. */
uint64_t q3fus : 34; /**< Fuse Register for QUAD3
This is purely for debug and not needed in the general
manufacturing flow.
Note that the fuses are complementary (Assigning a
fuse to 1 will read as a zero). This means the case
where no fuses are blown result in these csr's showing
all ones.
Failure \#1 Fuse Mapping
[16:14] UNUSED (5020 uses single physical bank per quad)
[13:7] bad high column
[6:0] bad low column
Failure \#2 Fuse Mapping
[33:31] UNUSED (5020 uses single physical bank per quad)
[30:24] bad high column
[23:17] bad low column */
#else
uint64_t q3fus : 34;
uint64_t crip_256k : 1;
uint64_t crip_128k : 1;
uint64_t reserved_36_36 : 1;
uint64_t ema_ctl : 3;
uint64_t reserved_40_63 : 24;
#endif
} cn52xx;
struct cvmx_l2d_fus3_cn52xx cn52xxp1;
struct cvmx_l2d_fus3_cn56xx {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_40_63 : 24;
uint64_t ema_ctl : 3; /**< L2 Data Store EMA Control
These bits are used to 'observe' the EMA[2:0] inputs
for the L2 Data Store RAMs which are controlled by
either FUSES[142:140] or by MIO_FUSE_EMA[EMA] CSR.
From poweron (dc_ok), the EMA_CTL are driven from
FUSE[141:140]. However after the 1st CSR write to the
MIO_FUSE_EMA[EMA] bits, the EMA_CTL will source
from the MIO_FUSE_EMA[EMA] register permanently
(until dc_ok). */
uint64_t reserved_36_36 : 1;
uint64_t crip_512k : 1; /**< This is purely for debug and not needed in the general
manufacturing flow.
If the FUSE is not-blown, then this bit should read
as 0. If the FUSE is blown, then this bit should read
as 1.
*** NOTE: Pass2 Addition */
uint64_t crip_1024k : 1; /**< This is purely for debug and not needed in the general
manufacturing flow.
If the FUSE is not-blown, then this bit should read
as 0. If the FUSE is blown, then this bit should read
as 1.
*** NOTE: Pass2 Addition */
uint64_t q3fus : 34; /**< Fuse Register for QUAD3
This is purely for debug and not needed in the general
manufacturing flow.
Note that the fuses are complementary (Assigning a
fuse to 1 will read as a zero). This means the case
where no fuses are blown result in these csr's showing
all ones.
Failure \#1 Fuse Mapping
[16:14] bad bank
[13:7] bad high column
[6:0] bad low column
Failure \#2 Fuse Mapping
[33:31] bad bank
[30:24] bad high column
[23:17] bad low column */
#else
uint64_t q3fus : 34;
uint64_t crip_1024k : 1;
uint64_t crip_512k : 1;
uint64_t reserved_36_36 : 1;
uint64_t ema_ctl : 3;
uint64_t reserved_40_63 : 24;
#endif
} cn56xx;
struct cvmx_l2d_fus3_cn56xx cn56xxp1;
struct cvmx_l2d_fus3_cn58xx {
#ifdef __BIG_ENDIAN_BITFIELD
uint64_t reserved_39_63 : 25;
uint64_t ema_ctl : 2; /**< L2 Data Store EMA Control
These bits are used to 'observe' the EMA[1:0] inputs
for the L2 Data Store RAMs which are controlled by
either FUSES[141:140] or by MIO_FUSE_EMA[EMA] CSR.
From poweron (dc_ok), the EMA_CTL are driven from
FUSE[141:140]. However after the 1st CSR write to the
MIO_FUSE_EMA[EMA] bits, the EMA_CTL will source
from the MIO_FUSE_EMA[EMA] register permanently
(until dc_ok). */
uint64_t reserved_36_36 : 1;
uint64_t crip_512k : 1; /**< This is purely for debug and not needed in the general
manufacturing flow.
If the FUSE is not-blown, then this bit should read
as 0. If the FUSE is blown, then this bit should read
as 1.
*** NOTE: Pass2 Addition */
uint64_t crip_1024k : 1; /**< This is purely for debug and not needed in the general
manufacturing flow.
If the FUSE is not-blown, then this bit should read
as 0. If the FUSE is blown, then this bit should read
as 1.
*** NOTE: Pass2 Addition */
uint64_t q3fus : 34; /**< Fuse Register for QUAD3
This is purely for debug and not needed in the general
manufacturing flow.
Note that the fuses are complementary (Assigning a
fuse to 1 will read as a zero). This means the case
where no fuses are blown result in these csr's showing
all ones.
Failure \#1 Fuse Mapping
[16:14] bad bank
[13:7] bad high column
[6:0] bad low column
Failure \#2 Fuse Mapping
[33:31] bad bank
[30:24] bad high column
[23:17] bad low column */
#else
uint64_t q3fus : 34;
uint64_t crip_1024k : 1;
uint64_t crip_512k : 1;
uint64_t reserved_36_36 : 1;
uint64_t ema_ctl : 2;
uint64_t reserved_39_63 : 25;
#endif
} cn58xx;
struct cvmx_l2d_fus3_cn58xx cn58xxp1;
};
typedef union cvmx_l2d_fus3 cvmx_l2d_fus3_t;
#endif