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|
/***********************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
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