freebsd-nq/sys/contrib/octeon-sdk/cvmx-mio-defs.h
Juli Mallett 04b6fa8330 Merge Cavium Octeon SDK 2.0 Simple Executive; this brings some fixes and new
facilities as well as support for the Octeon 2 family of SoCs.

XXX Note that with our antediluvian assembler, we can't support some Octeon 2
    instructions and fall back to using the old ones instead.
2010-11-28 08:18:16 +00:00

6587 lines
276 KiB
C

/***********************license start***************
* Copyright (c) 2003-2010 Cavium Networks (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 Networks 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 NETWORKS MAKES NO PROMISES, REPRESENTATIONS OR
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* PERFORMANCE OF THE SOFTWARE LIES WITH YOU.
***********************license end**************************************/
/**
* cvmx-mio-defs.h
*
* Configuration and status register (CSR) type definitions for
* Octeon mio.
*
* This file is auto generated. Do not edit.
*
* <hr>$Revision$<hr>
*
*/
#ifndef __CVMX_MIO_TYPEDEFS_H__
#define __CVMX_MIO_TYPEDEFS_H__
#define CVMX_MIO_BOOT_BIST_STAT (CVMX_ADD_IO_SEG(0x00011800000000F8ull))
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_BOOT_COMP CVMX_MIO_BOOT_COMP_FUNC()
static inline uint64_t CVMX_MIO_BOOT_COMP_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN50XX) || OCTEON_IS_MODEL(OCTEON_CN52XX) || OCTEON_IS_MODEL(OCTEON_CN56XX) || OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_BOOT_COMP not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x00011800000000B8ull);
}
#else
#define CVMX_MIO_BOOT_COMP (CVMX_ADD_IO_SEG(0x00011800000000B8ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_BOOT_DMA_CFGX(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 2))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_BOOT_DMA_CFGX(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000100ull) + ((offset) & 3) * 8;
}
#else
#define CVMX_MIO_BOOT_DMA_CFGX(offset) (CVMX_ADD_IO_SEG(0x0001180000000100ull) + ((offset) & 3) * 8)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_BOOT_DMA_INTX(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 2))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_BOOT_DMA_INTX(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000138ull) + ((offset) & 3) * 8;
}
#else
#define CVMX_MIO_BOOT_DMA_INTX(offset) (CVMX_ADD_IO_SEG(0x0001180000000138ull) + ((offset) & 3) * 8)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_BOOT_DMA_INT_ENX(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 2))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_BOOT_DMA_INT_ENX(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000150ull) + ((offset) & 3) * 8;
}
#else
#define CVMX_MIO_BOOT_DMA_INT_ENX(offset) (CVMX_ADD_IO_SEG(0x0001180000000150ull) + ((offset) & 3) * 8)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_BOOT_DMA_TIMX(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 2))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_BOOT_DMA_TIMX(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000120ull) + ((offset) & 3) * 8;
}
#else
#define CVMX_MIO_BOOT_DMA_TIMX(offset) (CVMX_ADD_IO_SEG(0x0001180000000120ull) + ((offset) & 3) * 8)
#endif
#define CVMX_MIO_BOOT_ERR (CVMX_ADD_IO_SEG(0x00011800000000A0ull))
#define CVMX_MIO_BOOT_INT (CVMX_ADD_IO_SEG(0x00011800000000A8ull))
#define CVMX_MIO_BOOT_LOC_ADR (CVMX_ADD_IO_SEG(0x0001180000000090ull))
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_BOOT_LOC_CFGX(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_BOOT_LOC_CFGX(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000080ull) + ((offset) & 1) * 8;
}
#else
#define CVMX_MIO_BOOT_LOC_CFGX(offset) (CVMX_ADD_IO_SEG(0x0001180000000080ull) + ((offset) & 1) * 8)
#endif
#define CVMX_MIO_BOOT_LOC_DAT (CVMX_ADD_IO_SEG(0x0001180000000098ull))
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_BOOT_PIN_DEFS CVMX_MIO_BOOT_PIN_DEFS_FUNC()
static inline uint64_t CVMX_MIO_BOOT_PIN_DEFS_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX) || OCTEON_IS_MODEL(OCTEON_CN56XX) || OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_BOOT_PIN_DEFS not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x00011800000000C0ull);
}
#else
#define CVMX_MIO_BOOT_PIN_DEFS (CVMX_ADD_IO_SEG(0x00011800000000C0ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_BOOT_REG_CFGX(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 7))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 7))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 7))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 7))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 7))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 7))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 7))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 7)))))
cvmx_warn("CVMX_MIO_BOOT_REG_CFGX(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000000ull) + ((offset) & 7) * 8;
}
#else
#define CVMX_MIO_BOOT_REG_CFGX(offset) (CVMX_ADD_IO_SEG(0x0001180000000000ull) + ((offset) & 7) * 8)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_BOOT_REG_TIMX(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 7))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 7))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 7))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 7))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 7))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 7))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 7))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 7)))))
cvmx_warn("CVMX_MIO_BOOT_REG_TIMX(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000040ull) + ((offset) & 7) * 8;
}
#else
#define CVMX_MIO_BOOT_REG_TIMX(offset) (CVMX_ADD_IO_SEG(0x0001180000000040ull) + ((offset) & 7) * 8)
#endif
#define CVMX_MIO_BOOT_THR (CVMX_ADD_IO_SEG(0x00011800000000B0ull))
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_FUS_BNK_DATX(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 3))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 3))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 3))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 3))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_FUS_BNK_DATX(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000001520ull) + ((offset) & 3) * 8;
}
#else
#define CVMX_MIO_FUS_BNK_DATX(offset) (CVMX_ADD_IO_SEG(0x0001180000001520ull) + ((offset) & 3) * 8)
#endif
#define CVMX_MIO_FUS_DAT0 (CVMX_ADD_IO_SEG(0x0001180000001400ull))
#define CVMX_MIO_FUS_DAT1 (CVMX_ADD_IO_SEG(0x0001180000001408ull))
#define CVMX_MIO_FUS_DAT2 (CVMX_ADD_IO_SEG(0x0001180000001410ull))
#define CVMX_MIO_FUS_DAT3 (CVMX_ADD_IO_SEG(0x0001180000001418ull))
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_FUS_EMA CVMX_MIO_FUS_EMA_FUNC()
static inline uint64_t CVMX_MIO_FUS_EMA_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN5XXX) || OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_FUS_EMA not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000001550ull);
}
#else
#define CVMX_MIO_FUS_EMA (CVMX_ADD_IO_SEG(0x0001180000001550ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_FUS_PDF CVMX_MIO_FUS_PDF_FUNC()
static inline uint64_t CVMX_MIO_FUS_PDF_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN5XXX) || OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_FUS_PDF not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000001420ull);
}
#else
#define CVMX_MIO_FUS_PDF (CVMX_ADD_IO_SEG(0x0001180000001420ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_FUS_PLL CVMX_MIO_FUS_PLL_FUNC()
static inline uint64_t CVMX_MIO_FUS_PLL_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN5XXX) || OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_FUS_PLL not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000001580ull);
}
#else
#define CVMX_MIO_FUS_PLL (CVMX_ADD_IO_SEG(0x0001180000001580ull))
#endif
#define CVMX_MIO_FUS_PROG (CVMX_ADD_IO_SEG(0x0001180000001510ull))
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_FUS_PROG_TIMES CVMX_MIO_FUS_PROG_TIMES_FUNC()
static inline uint64_t CVMX_MIO_FUS_PROG_TIMES_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN5XXX) || OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_FUS_PROG_TIMES not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000001518ull);
}
#else
#define CVMX_MIO_FUS_PROG_TIMES (CVMX_ADD_IO_SEG(0x0001180000001518ull))
#endif
#define CVMX_MIO_FUS_RCMD (CVMX_ADD_IO_SEG(0x0001180000001500ull))
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_FUS_READ_TIMES CVMX_MIO_FUS_READ_TIMES_FUNC()
static inline uint64_t CVMX_MIO_FUS_READ_TIMES_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_FUS_READ_TIMES not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000001570ull);
}
#else
#define CVMX_MIO_FUS_READ_TIMES (CVMX_ADD_IO_SEG(0x0001180000001570ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_FUS_REPAIR_RES0 CVMX_MIO_FUS_REPAIR_RES0_FUNC()
static inline uint64_t CVMX_MIO_FUS_REPAIR_RES0_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_FUS_REPAIR_RES0 not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000001558ull);
}
#else
#define CVMX_MIO_FUS_REPAIR_RES0 (CVMX_ADD_IO_SEG(0x0001180000001558ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_FUS_REPAIR_RES1 CVMX_MIO_FUS_REPAIR_RES1_FUNC()
static inline uint64_t CVMX_MIO_FUS_REPAIR_RES1_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_FUS_REPAIR_RES1 not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000001560ull);
}
#else
#define CVMX_MIO_FUS_REPAIR_RES1 (CVMX_ADD_IO_SEG(0x0001180000001560ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_FUS_REPAIR_RES2 CVMX_MIO_FUS_REPAIR_RES2_FUNC()
static inline uint64_t CVMX_MIO_FUS_REPAIR_RES2_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_FUS_REPAIR_RES2 not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000001568ull);
}
#else
#define CVMX_MIO_FUS_REPAIR_RES2 (CVMX_ADD_IO_SEG(0x0001180000001568ull))
#endif
#define CVMX_MIO_FUS_SPR_REPAIR_RES (CVMX_ADD_IO_SEG(0x0001180000001548ull))
#define CVMX_MIO_FUS_SPR_REPAIR_SUM (CVMX_ADD_IO_SEG(0x0001180000001540ull))
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_FUS_UNLOCK CVMX_MIO_FUS_UNLOCK_FUNC()
static inline uint64_t CVMX_MIO_FUS_UNLOCK_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN30XX) || OCTEON_IS_MODEL(OCTEON_CN31XX)))
cvmx_warn("CVMX_MIO_FUS_UNLOCK not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000001578ull);
}
#else
#define CVMX_MIO_FUS_UNLOCK (CVMX_ADD_IO_SEG(0x0001180000001578ull))
#endif
#define CVMX_MIO_FUS_WADR (CVMX_ADD_IO_SEG(0x0001180000001508ull))
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_GPIO_COMP CVMX_MIO_GPIO_COMP_FUNC()
static inline uint64_t CVMX_MIO_GPIO_COMP_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_GPIO_COMP not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x00011800000000C8ull);
}
#else
#define CVMX_MIO_GPIO_COMP (CVMX_ADD_IO_SEG(0x00011800000000C8ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_NDF_DMA_CFG CVMX_MIO_NDF_DMA_CFG_FUNC()
static inline uint64_t CVMX_MIO_NDF_DMA_CFG_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX) || OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_NDF_DMA_CFG not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000168ull);
}
#else
#define CVMX_MIO_NDF_DMA_CFG (CVMX_ADD_IO_SEG(0x0001180000000168ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_NDF_DMA_INT CVMX_MIO_NDF_DMA_INT_FUNC()
static inline uint64_t CVMX_MIO_NDF_DMA_INT_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX) || OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_NDF_DMA_INT not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000170ull);
}
#else
#define CVMX_MIO_NDF_DMA_INT (CVMX_ADD_IO_SEG(0x0001180000000170ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_NDF_DMA_INT_EN CVMX_MIO_NDF_DMA_INT_EN_FUNC()
static inline uint64_t CVMX_MIO_NDF_DMA_INT_EN_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX) || OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_NDF_DMA_INT_EN not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000178ull);
}
#else
#define CVMX_MIO_NDF_DMA_INT_EN (CVMX_ADD_IO_SEG(0x0001180000000178ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_PLL_CTL CVMX_MIO_PLL_CTL_FUNC()
static inline uint64_t CVMX_MIO_PLL_CTL_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN30XX) || OCTEON_IS_MODEL(OCTEON_CN31XX)))
cvmx_warn("CVMX_MIO_PLL_CTL not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000001448ull);
}
#else
#define CVMX_MIO_PLL_CTL (CVMX_ADD_IO_SEG(0x0001180000001448ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_PLL_SETTING CVMX_MIO_PLL_SETTING_FUNC()
static inline uint64_t CVMX_MIO_PLL_SETTING_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN30XX) || OCTEON_IS_MODEL(OCTEON_CN31XX)))
cvmx_warn("CVMX_MIO_PLL_SETTING not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000001440ull);
}
#else
#define CVMX_MIO_PLL_SETTING (CVMX_ADD_IO_SEG(0x0001180000001440ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_PTP_CLOCK_CFG CVMX_MIO_PTP_CLOCK_CFG_FUNC()
static inline uint64_t CVMX_MIO_PTP_CLOCK_CFG_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_PTP_CLOCK_CFG not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001070000000F00ull);
}
#else
#define CVMX_MIO_PTP_CLOCK_CFG (CVMX_ADD_IO_SEG(0x0001070000000F00ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_PTP_CLOCK_COMP CVMX_MIO_PTP_CLOCK_COMP_FUNC()
static inline uint64_t CVMX_MIO_PTP_CLOCK_COMP_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_PTP_CLOCK_COMP not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001070000000F18ull);
}
#else
#define CVMX_MIO_PTP_CLOCK_COMP (CVMX_ADD_IO_SEG(0x0001070000000F18ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_PTP_CLOCK_HI CVMX_MIO_PTP_CLOCK_HI_FUNC()
static inline uint64_t CVMX_MIO_PTP_CLOCK_HI_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_PTP_CLOCK_HI not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001070000000F10ull);
}
#else
#define CVMX_MIO_PTP_CLOCK_HI (CVMX_ADD_IO_SEG(0x0001070000000F10ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_PTP_CLOCK_LO CVMX_MIO_PTP_CLOCK_LO_FUNC()
static inline uint64_t CVMX_MIO_PTP_CLOCK_LO_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_PTP_CLOCK_LO not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001070000000F08ull);
}
#else
#define CVMX_MIO_PTP_CLOCK_LO (CVMX_ADD_IO_SEG(0x0001070000000F08ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_PTP_EVT_CNT CVMX_MIO_PTP_EVT_CNT_FUNC()
static inline uint64_t CVMX_MIO_PTP_EVT_CNT_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_PTP_EVT_CNT not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001070000000F28ull);
}
#else
#define CVMX_MIO_PTP_EVT_CNT (CVMX_ADD_IO_SEG(0x0001070000000F28ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_PTP_TIMESTAMP CVMX_MIO_PTP_TIMESTAMP_FUNC()
static inline uint64_t CVMX_MIO_PTP_TIMESTAMP_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_PTP_TIMESTAMP not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001070000000F20ull);
}
#else
#define CVMX_MIO_PTP_TIMESTAMP (CVMX_ADD_IO_SEG(0x0001070000000F20ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_RST_BOOT CVMX_MIO_RST_BOOT_FUNC()
static inline uint64_t CVMX_MIO_RST_BOOT_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_RST_BOOT not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000001600ull);
}
#else
#define CVMX_MIO_RST_BOOT (CVMX_ADD_IO_SEG(0x0001180000001600ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_RST_CFG CVMX_MIO_RST_CFG_FUNC()
static inline uint64_t CVMX_MIO_RST_CFG_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_RST_CFG not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000001610ull);
}
#else
#define CVMX_MIO_RST_CFG (CVMX_ADD_IO_SEG(0x0001180000001610ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_RST_CTLX(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_RST_CTLX(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000001618ull) + ((offset) & 1) * 8;
}
#else
#define CVMX_MIO_RST_CTLX(offset) (CVMX_ADD_IO_SEG(0x0001180000001618ull) + ((offset) & 1) * 8)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_RST_DELAY CVMX_MIO_RST_DELAY_FUNC()
static inline uint64_t CVMX_MIO_RST_DELAY_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_RST_DELAY not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000001608ull);
}
#else
#define CVMX_MIO_RST_DELAY (CVMX_ADD_IO_SEG(0x0001180000001608ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_RST_INT CVMX_MIO_RST_INT_FUNC()
static inline uint64_t CVMX_MIO_RST_INT_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_RST_INT not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000001628ull);
}
#else
#define CVMX_MIO_RST_INT (CVMX_ADD_IO_SEG(0x0001180000001628ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_RST_INT_EN CVMX_MIO_RST_INT_EN_FUNC()
static inline uint64_t CVMX_MIO_RST_INT_EN_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN63XX)))
cvmx_warn("CVMX_MIO_RST_INT_EN not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000001630ull);
}
#else
#define CVMX_MIO_RST_INT_EN (CVMX_ADD_IO_SEG(0x0001180000001630ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_TWSX_INT(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_TWSX_INT(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000001010ull) + ((offset) & 1) * 512;
}
#else
#define CVMX_MIO_TWSX_INT(offset) (CVMX_ADD_IO_SEG(0x0001180000001010ull) + ((offset) & 1) * 512)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_TWSX_SW_TWSI(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_TWSX_SW_TWSI(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000001000ull) + ((offset) & 1) * 512;
}
#else
#define CVMX_MIO_TWSX_SW_TWSI(offset) (CVMX_ADD_IO_SEG(0x0001180000001000ull) + ((offset) & 1) * 512)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_TWSX_SW_TWSI_EXT(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_TWSX_SW_TWSI_EXT(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000001018ull) + ((offset) & 1) * 512;
}
#else
#define CVMX_MIO_TWSX_SW_TWSI_EXT(offset) (CVMX_ADD_IO_SEG(0x0001180000001018ull) + ((offset) & 1) * 512)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_TWSX_TWSI_SW(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset == 0))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_TWSX_TWSI_SW(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000001008ull) + ((offset) & 1) * 512;
}
#else
#define CVMX_MIO_TWSX_TWSI_SW(offset) (CVMX_ADD_IO_SEG(0x0001180000001008ull) + ((offset) & 1) * 512)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_DLH CVMX_MIO_UART2_DLH_FUNC()
static inline uint64_t CVMX_MIO_UART2_DLH_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_DLH not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000488ull);
}
#else
#define CVMX_MIO_UART2_DLH (CVMX_ADD_IO_SEG(0x0001180000000488ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_DLL CVMX_MIO_UART2_DLL_FUNC()
static inline uint64_t CVMX_MIO_UART2_DLL_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_DLL not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000480ull);
}
#else
#define CVMX_MIO_UART2_DLL (CVMX_ADD_IO_SEG(0x0001180000000480ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_FAR CVMX_MIO_UART2_FAR_FUNC()
static inline uint64_t CVMX_MIO_UART2_FAR_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_FAR not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000520ull);
}
#else
#define CVMX_MIO_UART2_FAR (CVMX_ADD_IO_SEG(0x0001180000000520ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_FCR CVMX_MIO_UART2_FCR_FUNC()
static inline uint64_t CVMX_MIO_UART2_FCR_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_FCR not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000450ull);
}
#else
#define CVMX_MIO_UART2_FCR (CVMX_ADD_IO_SEG(0x0001180000000450ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_HTX CVMX_MIO_UART2_HTX_FUNC()
static inline uint64_t CVMX_MIO_UART2_HTX_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_HTX not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000708ull);
}
#else
#define CVMX_MIO_UART2_HTX (CVMX_ADD_IO_SEG(0x0001180000000708ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_IER CVMX_MIO_UART2_IER_FUNC()
static inline uint64_t CVMX_MIO_UART2_IER_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_IER not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000408ull);
}
#else
#define CVMX_MIO_UART2_IER (CVMX_ADD_IO_SEG(0x0001180000000408ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_IIR CVMX_MIO_UART2_IIR_FUNC()
static inline uint64_t CVMX_MIO_UART2_IIR_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_IIR not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000410ull);
}
#else
#define CVMX_MIO_UART2_IIR (CVMX_ADD_IO_SEG(0x0001180000000410ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_LCR CVMX_MIO_UART2_LCR_FUNC()
static inline uint64_t CVMX_MIO_UART2_LCR_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_LCR not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000418ull);
}
#else
#define CVMX_MIO_UART2_LCR (CVMX_ADD_IO_SEG(0x0001180000000418ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_LSR CVMX_MIO_UART2_LSR_FUNC()
static inline uint64_t CVMX_MIO_UART2_LSR_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_LSR not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000428ull);
}
#else
#define CVMX_MIO_UART2_LSR (CVMX_ADD_IO_SEG(0x0001180000000428ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_MCR CVMX_MIO_UART2_MCR_FUNC()
static inline uint64_t CVMX_MIO_UART2_MCR_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_MCR not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000420ull);
}
#else
#define CVMX_MIO_UART2_MCR (CVMX_ADD_IO_SEG(0x0001180000000420ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_MSR CVMX_MIO_UART2_MSR_FUNC()
static inline uint64_t CVMX_MIO_UART2_MSR_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_MSR not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000430ull);
}
#else
#define CVMX_MIO_UART2_MSR (CVMX_ADD_IO_SEG(0x0001180000000430ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_RBR CVMX_MIO_UART2_RBR_FUNC()
static inline uint64_t CVMX_MIO_UART2_RBR_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_RBR not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000400ull);
}
#else
#define CVMX_MIO_UART2_RBR (CVMX_ADD_IO_SEG(0x0001180000000400ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_RFL CVMX_MIO_UART2_RFL_FUNC()
static inline uint64_t CVMX_MIO_UART2_RFL_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_RFL not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000608ull);
}
#else
#define CVMX_MIO_UART2_RFL (CVMX_ADD_IO_SEG(0x0001180000000608ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_RFW CVMX_MIO_UART2_RFW_FUNC()
static inline uint64_t CVMX_MIO_UART2_RFW_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_RFW not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000530ull);
}
#else
#define CVMX_MIO_UART2_RFW (CVMX_ADD_IO_SEG(0x0001180000000530ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_SBCR CVMX_MIO_UART2_SBCR_FUNC()
static inline uint64_t CVMX_MIO_UART2_SBCR_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_SBCR not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000620ull);
}
#else
#define CVMX_MIO_UART2_SBCR (CVMX_ADD_IO_SEG(0x0001180000000620ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_SCR CVMX_MIO_UART2_SCR_FUNC()
static inline uint64_t CVMX_MIO_UART2_SCR_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_SCR not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000438ull);
}
#else
#define CVMX_MIO_UART2_SCR (CVMX_ADD_IO_SEG(0x0001180000000438ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_SFE CVMX_MIO_UART2_SFE_FUNC()
static inline uint64_t CVMX_MIO_UART2_SFE_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_SFE not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000630ull);
}
#else
#define CVMX_MIO_UART2_SFE (CVMX_ADD_IO_SEG(0x0001180000000630ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_SRR CVMX_MIO_UART2_SRR_FUNC()
static inline uint64_t CVMX_MIO_UART2_SRR_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_SRR not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000610ull);
}
#else
#define CVMX_MIO_UART2_SRR (CVMX_ADD_IO_SEG(0x0001180000000610ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_SRT CVMX_MIO_UART2_SRT_FUNC()
static inline uint64_t CVMX_MIO_UART2_SRT_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_SRT not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000638ull);
}
#else
#define CVMX_MIO_UART2_SRT (CVMX_ADD_IO_SEG(0x0001180000000638ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_SRTS CVMX_MIO_UART2_SRTS_FUNC()
static inline uint64_t CVMX_MIO_UART2_SRTS_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_SRTS not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000618ull);
}
#else
#define CVMX_MIO_UART2_SRTS (CVMX_ADD_IO_SEG(0x0001180000000618ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_STT CVMX_MIO_UART2_STT_FUNC()
static inline uint64_t CVMX_MIO_UART2_STT_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_STT not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000700ull);
}
#else
#define CVMX_MIO_UART2_STT (CVMX_ADD_IO_SEG(0x0001180000000700ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_TFL CVMX_MIO_UART2_TFL_FUNC()
static inline uint64_t CVMX_MIO_UART2_TFL_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_TFL not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000600ull);
}
#else
#define CVMX_MIO_UART2_TFL (CVMX_ADD_IO_SEG(0x0001180000000600ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_TFR CVMX_MIO_UART2_TFR_FUNC()
static inline uint64_t CVMX_MIO_UART2_TFR_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_TFR not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000528ull);
}
#else
#define CVMX_MIO_UART2_TFR (CVMX_ADD_IO_SEG(0x0001180000000528ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_THR CVMX_MIO_UART2_THR_FUNC()
static inline uint64_t CVMX_MIO_UART2_THR_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_THR not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000440ull);
}
#else
#define CVMX_MIO_UART2_THR (CVMX_ADD_IO_SEG(0x0001180000000440ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
#define CVMX_MIO_UART2_USR CVMX_MIO_UART2_USR_FUNC()
static inline uint64_t CVMX_MIO_UART2_USR_FUNC(void)
{
if (!(OCTEON_IS_MODEL(OCTEON_CN52XX)))
cvmx_warn("CVMX_MIO_UART2_USR not supported on this chip\n");
return CVMX_ADD_IO_SEG(0x0001180000000538ull);
}
#else
#define CVMX_MIO_UART2_USR (CVMX_ADD_IO_SEG(0x0001180000000538ull))
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_DLH(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_DLH(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000888ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_DLH(offset) (CVMX_ADD_IO_SEG(0x0001180000000888ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_DLL(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_DLL(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000880ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_DLL(offset) (CVMX_ADD_IO_SEG(0x0001180000000880ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_FAR(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_FAR(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000920ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_FAR(offset) (CVMX_ADD_IO_SEG(0x0001180000000920ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_FCR(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_FCR(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000850ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_FCR(offset) (CVMX_ADD_IO_SEG(0x0001180000000850ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_HTX(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_HTX(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000B08ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_HTX(offset) (CVMX_ADD_IO_SEG(0x0001180000000B08ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_IER(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_IER(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000808ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_IER(offset) (CVMX_ADD_IO_SEG(0x0001180000000808ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_IIR(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_IIR(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000810ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_IIR(offset) (CVMX_ADD_IO_SEG(0x0001180000000810ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_LCR(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_LCR(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000818ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_LCR(offset) (CVMX_ADD_IO_SEG(0x0001180000000818ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_LSR(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_LSR(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000828ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_LSR(offset) (CVMX_ADD_IO_SEG(0x0001180000000828ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_MCR(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_MCR(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000820ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_MCR(offset) (CVMX_ADD_IO_SEG(0x0001180000000820ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_MSR(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_MSR(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000830ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_MSR(offset) (CVMX_ADD_IO_SEG(0x0001180000000830ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_RBR(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_RBR(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000800ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_RBR(offset) (CVMX_ADD_IO_SEG(0x0001180000000800ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_RFL(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_RFL(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000A08ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_RFL(offset) (CVMX_ADD_IO_SEG(0x0001180000000A08ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_RFW(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_RFW(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000930ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_RFW(offset) (CVMX_ADD_IO_SEG(0x0001180000000930ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_SBCR(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_SBCR(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000A20ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_SBCR(offset) (CVMX_ADD_IO_SEG(0x0001180000000A20ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_SCR(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_SCR(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000838ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_SCR(offset) (CVMX_ADD_IO_SEG(0x0001180000000838ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_SFE(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_SFE(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000A30ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_SFE(offset) (CVMX_ADD_IO_SEG(0x0001180000000A30ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_SRR(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_SRR(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000A10ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_SRR(offset) (CVMX_ADD_IO_SEG(0x0001180000000A10ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_SRT(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_SRT(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000A38ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_SRT(offset) (CVMX_ADD_IO_SEG(0x0001180000000A38ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_SRTS(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_SRTS(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000A18ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_SRTS(offset) (CVMX_ADD_IO_SEG(0x0001180000000A18ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_STT(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_STT(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000B00ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_STT(offset) (CVMX_ADD_IO_SEG(0x0001180000000B00ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_TFL(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_TFL(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000A00ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_TFL(offset) (CVMX_ADD_IO_SEG(0x0001180000000A00ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_TFR(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_TFR(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000928ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_TFR(offset) (CVMX_ADD_IO_SEG(0x0001180000000928ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_THR(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_THR(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000840ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_THR(offset) (CVMX_ADD_IO_SEG(0x0001180000000840ull) + ((offset) & 1) * 1024)
#endif
#if CVMX_ENABLE_CSR_ADDRESS_CHECKING
static inline uint64_t CVMX_MIO_UARTX_USR(unsigned long offset)
{
if (!(
(OCTEON_IS_MODEL(OCTEON_CN30XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN31XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN38XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN50XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN52XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN56XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN58XX) && ((offset <= 1))) ||
(OCTEON_IS_MODEL(OCTEON_CN63XX) && ((offset <= 1)))))
cvmx_warn("CVMX_MIO_UARTX_USR(%lu) is invalid on this chip\n", offset);
return CVMX_ADD_IO_SEG(0x0001180000000938ull) + ((offset) & 1) * 1024;
}
#else
#define CVMX_MIO_UARTX_USR(offset) (CVMX_ADD_IO_SEG(0x0001180000000938ull) + ((offset) & 1) * 1024)
#endif
/**
* cvmx_mio_boot_bist_stat
*
* MIO_BOOT_BIST_STAT = MIO Boot BIST Status Register
*
* Contains the BIST status for the MIO boot memories. '0' = pass, '1' = fail.
*/
union cvmx_mio_boot_bist_stat
{
uint64_t u64;
struct cvmx_mio_boot_bist_stat_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_0_63 : 64;
#else
uint64_t reserved_0_63 : 64;
#endif
} s;
struct cvmx_mio_boot_bist_stat_cn30xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_4_63 : 60;
uint64_t ncbo_1 : 1; /**< NCB output FIFO 1 BIST status */
uint64_t ncbo_0 : 1; /**< NCB output FIFO 0 BIST status */
uint64_t loc : 1; /**< Local memory BIST status */
uint64_t ncbi : 1; /**< NCB input FIFO BIST status */
#else
uint64_t ncbi : 1;
uint64_t loc : 1;
uint64_t ncbo_0 : 1;
uint64_t ncbo_1 : 1;
uint64_t reserved_4_63 : 60;
#endif
} cn30xx;
struct cvmx_mio_boot_bist_stat_cn30xx cn31xx;
struct cvmx_mio_boot_bist_stat_cn38xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_3_63 : 61;
uint64_t ncbo_0 : 1; /**< NCB output FIFO BIST status */
uint64_t loc : 1; /**< Local memory BIST status */
uint64_t ncbi : 1; /**< NCB input FIFO BIST status */
#else
uint64_t ncbi : 1;
uint64_t loc : 1;
uint64_t ncbo_0 : 1;
uint64_t reserved_3_63 : 61;
#endif
} cn38xx;
struct cvmx_mio_boot_bist_stat_cn38xx cn38xxp2;
struct cvmx_mio_boot_bist_stat_cn50xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_6_63 : 58;
uint64_t pcm_1 : 1; /**< PCM memory 1 BIST status */
uint64_t pcm_0 : 1; /**< PCM memory 0 BIST status */
uint64_t ncbo_1 : 1; /**< NCB output FIFO 1 BIST status */
uint64_t ncbo_0 : 1; /**< NCB output FIFO 0 BIST status */
uint64_t loc : 1; /**< Local memory BIST status */
uint64_t ncbi : 1; /**< NCB input FIFO BIST status */
#else
uint64_t ncbi : 1;
uint64_t loc : 1;
uint64_t ncbo_0 : 1;
uint64_t ncbo_1 : 1;
uint64_t pcm_0 : 1;
uint64_t pcm_1 : 1;
uint64_t reserved_6_63 : 58;
#endif
} cn50xx;
struct cvmx_mio_boot_bist_stat_cn52xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_6_63 : 58;
uint64_t ndf : 2; /**< NAND flash BIST status */
uint64_t ncbo_0 : 1; /**< NCB output FIFO BIST status */
uint64_t dma : 1; /**< DMA memory BIST status */
uint64_t loc : 1; /**< Local memory BIST status */
uint64_t ncbi : 1; /**< NCB input FIFO BIST status */
#else
uint64_t ncbi : 1;
uint64_t loc : 1;
uint64_t dma : 1;
uint64_t ncbo_0 : 1;
uint64_t ndf : 2;
uint64_t reserved_6_63 : 58;
#endif
} cn52xx;
struct cvmx_mio_boot_bist_stat_cn52xxp1
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_4_63 : 60;
uint64_t ncbo_0 : 1; /**< NCB output FIFO BIST status */
uint64_t dma : 1; /**< DMA memory BIST status */
uint64_t loc : 1; /**< Local memory BIST status */
uint64_t ncbi : 1; /**< NCB input FIFO BIST status */
#else
uint64_t ncbi : 1;
uint64_t loc : 1;
uint64_t dma : 1;
uint64_t ncbo_0 : 1;
uint64_t reserved_4_63 : 60;
#endif
} cn52xxp1;
struct cvmx_mio_boot_bist_stat_cn52xxp1 cn56xx;
struct cvmx_mio_boot_bist_stat_cn52xxp1 cn56xxp1;
struct cvmx_mio_boot_bist_stat_cn38xx cn58xx;
struct cvmx_mio_boot_bist_stat_cn38xx cn58xxp1;
struct cvmx_mio_boot_bist_stat_cn63xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_9_63 : 55;
uint64_t stat : 9; /**< BIST status */
#else
uint64_t stat : 9;
uint64_t reserved_9_63 : 55;
#endif
} cn63xx;
struct cvmx_mio_boot_bist_stat_cn63xx cn63xxp1;
};
typedef union cvmx_mio_boot_bist_stat cvmx_mio_boot_bist_stat_t;
/**
* cvmx_mio_boot_comp
*
* MIO_BOOT_COMP = MIO Boot Compensation Register
*
* Reset value is as follows:
*
* no pullups, PCTL=38, NCTL=30 (25 ohm termination)
* pullup on boot_ad[9], PCTL=19, NCTL=15 (50 ohm termination)
* pullup on boot_ad[10], PCTL=15, NCTL=12 (65 ohm termination)
* pullups on boot_ad[10:9], PCTL=15, NCTL=12 (65 ohm termination)
*/
union cvmx_mio_boot_comp
{
uint64_t u64;
struct cvmx_mio_boot_comp_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_0_63 : 64;
#else
uint64_t reserved_0_63 : 64;
#endif
} s;
struct cvmx_mio_boot_comp_cn50xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_10_63 : 54;
uint64_t pctl : 5; /**< Boot bus PCTL */
uint64_t nctl : 5; /**< Boot bus NCTL */
#else
uint64_t nctl : 5;
uint64_t pctl : 5;
uint64_t reserved_10_63 : 54;
#endif
} cn50xx;
struct cvmx_mio_boot_comp_cn50xx cn52xx;
struct cvmx_mio_boot_comp_cn50xx cn52xxp1;
struct cvmx_mio_boot_comp_cn50xx cn56xx;
struct cvmx_mio_boot_comp_cn50xx cn56xxp1;
struct cvmx_mio_boot_comp_cn63xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_12_63 : 52;
uint64_t pctl : 6; /**< Boot bus PCTL */
uint64_t nctl : 6; /**< Boot bus NCTL */
#else
uint64_t nctl : 6;
uint64_t pctl : 6;
uint64_t reserved_12_63 : 52;
#endif
} cn63xx;
struct cvmx_mio_boot_comp_cn63xx cn63xxp1;
};
typedef union cvmx_mio_boot_comp cvmx_mio_boot_comp_t;
/**
* cvmx_mio_boot_dma_cfg#
*
* MIO_BOOT_DMA_CFG = MIO Boot DMA Config Register (1 per engine * 2 engines)
*
* SIZE is specified in number of bus transfers, where one transfer is equal to the following number
* of bytes dependent on MIO_BOOT_DMA_TIMn[WIDTH] and MIO_BOOT_DMA_TIMn[DDR]:
*
* WIDTH DDR Transfer Size (bytes)
* ----------------------------------------
* 0 0 2
* 0 1 4
* 1 0 4
* 1 1 8
*
* Note: ADR must be aligned to the bus width (i.e. 16 bit aligned if WIDTH=0, 32 bit aligned if WIDTH=1).
*/
union cvmx_mio_boot_dma_cfgx
{
uint64_t u64;
struct cvmx_mio_boot_dma_cfgx_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t en : 1; /**< DMA Engine X enable */
uint64_t rw : 1; /**< DMA Engine X R/W bit (0 = read, 1 = write) */
uint64_t clr : 1; /**< DMA Engine X clear EN on device terminated burst */
uint64_t reserved_60_60 : 1;
uint64_t swap32 : 1; /**< DMA Engine X 32 bit swap */
uint64_t swap16 : 1; /**< DMA Engine X 16 bit swap */
uint64_t swap8 : 1; /**< DMA Engine X 8 bit swap */
uint64_t endian : 1; /**< DMA Engine X NCB endian mode (0 = big, 1 = little) */
uint64_t size : 20; /**< DMA Engine X size */
uint64_t adr : 36; /**< DMA Engine X address */
#else
uint64_t adr : 36;
uint64_t size : 20;
uint64_t endian : 1;
uint64_t swap8 : 1;
uint64_t swap16 : 1;
uint64_t swap32 : 1;
uint64_t reserved_60_60 : 1;
uint64_t clr : 1;
uint64_t rw : 1;
uint64_t en : 1;
#endif
} s;
struct cvmx_mio_boot_dma_cfgx_s cn52xx;
struct cvmx_mio_boot_dma_cfgx_s cn52xxp1;
struct cvmx_mio_boot_dma_cfgx_s cn56xx;
struct cvmx_mio_boot_dma_cfgx_s cn56xxp1;
struct cvmx_mio_boot_dma_cfgx_s cn63xx;
struct cvmx_mio_boot_dma_cfgx_s cn63xxp1;
};
typedef union cvmx_mio_boot_dma_cfgx cvmx_mio_boot_dma_cfgx_t;
/**
* cvmx_mio_boot_dma_int#
*
* MIO_BOOT_DMA_INT = MIO Boot DMA Interrupt Register (1 per engine * 2 engines)
*
*/
union cvmx_mio_boot_dma_intx
{
uint64_t u64;
struct cvmx_mio_boot_dma_intx_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_2_63 : 62;
uint64_t dmarq : 1; /**< DMA Engine X DMARQ asserted interrupt */
uint64_t done : 1; /**< DMA Engine X request completion interrupt */
#else
uint64_t done : 1;
uint64_t dmarq : 1;
uint64_t reserved_2_63 : 62;
#endif
} s;
struct cvmx_mio_boot_dma_intx_s cn52xx;
struct cvmx_mio_boot_dma_intx_s cn52xxp1;
struct cvmx_mio_boot_dma_intx_s cn56xx;
struct cvmx_mio_boot_dma_intx_s cn56xxp1;
struct cvmx_mio_boot_dma_intx_s cn63xx;
struct cvmx_mio_boot_dma_intx_s cn63xxp1;
};
typedef union cvmx_mio_boot_dma_intx cvmx_mio_boot_dma_intx_t;
/**
* cvmx_mio_boot_dma_int_en#
*
* MIO_BOOT_DMA_INT_EN = MIO Boot DMA Interrupt Enable Register (1 per engine * 2 engines)
*
*/
union cvmx_mio_boot_dma_int_enx
{
uint64_t u64;
struct cvmx_mio_boot_dma_int_enx_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_2_63 : 62;
uint64_t dmarq : 1; /**< DMA Engine X DMARQ asserted interrupt enable */
uint64_t done : 1; /**< DMA Engine X request completion interrupt enable */
#else
uint64_t done : 1;
uint64_t dmarq : 1;
uint64_t reserved_2_63 : 62;
#endif
} s;
struct cvmx_mio_boot_dma_int_enx_s cn52xx;
struct cvmx_mio_boot_dma_int_enx_s cn52xxp1;
struct cvmx_mio_boot_dma_int_enx_s cn56xx;
struct cvmx_mio_boot_dma_int_enx_s cn56xxp1;
struct cvmx_mio_boot_dma_int_enx_s cn63xx;
struct cvmx_mio_boot_dma_int_enx_s cn63xxp1;
};
typedef union cvmx_mio_boot_dma_int_enx cvmx_mio_boot_dma_int_enx_t;
/**
* cvmx_mio_boot_dma_tim#
*
* MIO_BOOT_DMA_TIM = MIO Boot DMA Timing Register (1 per engine * 2 engines)
*
* DMACK_PI inverts the assertion level of boot_dmack[n]. The default polarity of boot_dmack[1:0] is
* selected on the first de-assertion of reset by the values on boot_ad[12:11], where 0 is active high
* and 1 is active low (see MIO_BOOT_PIN_DEFS for a read-only copy of the default polarity).
* boot_ad[12:11] have internal pulldowns, so place a pullup on boot_ad[n+11] for active low default
* polarity on engine n. To interface with CF cards in True IDE Mode, either a pullup should be placed
* on boot_ad[n+11] OR the corresponding DMACK_PI[n] should be set.
*
* DMARQ_PI inverts the assertion level of boot_dmarq[n]. The default polarity of boot_dmarq[1:0] is
* active high, thus setting the polarity inversion bits changes the polarity to active low. To
* interface with CF cards in True IDE Mode, the corresponding DMARQ_PI[n] should be clear.
*
* TIM_MULT specifies the timing multiplier for an engine. The timing multiplier applies to all timing
* parameters, except for DMARQ and RD_DLY, which simply count eclks. TIM_MULT is encoded as follows:
* 0 = 4x, 1 = 1x, 2 = 2x, 3 = 8x.
*
* RD_DLY specifies the read sample delay in eclk cycles for an engine. For reads, the data bus is
* normally sampled on the same eclk edge that drives boot_oe_n high (and also low in DDR mode).
* This parameter can delay that sampling edge by up to 7 eclks. Note: the number of eclk cycles
* counted by the OE_A and DMACK_H + PAUSE timing parameters must be greater than RD_DLY.
*
* If DDR is set, then WE_N must be less than WE_A.
*/
union cvmx_mio_boot_dma_timx
{
uint64_t u64;
struct cvmx_mio_boot_dma_timx_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t dmack_pi : 1; /**< DMA Engine X DMA ack polarity inversion */
uint64_t dmarq_pi : 1; /**< DMA Engine X DMA request polarity inversion */
uint64_t tim_mult : 2; /**< DMA Engine X timing multiplier */
uint64_t rd_dly : 3; /**< DMA Engine X read sample delay */
uint64_t ddr : 1; /**< DMA Engine X DDR mode */
uint64_t width : 1; /**< DMA Engine X bus width (0 = 16 bits, 1 = 32 bits) */
uint64_t reserved_48_54 : 7;
uint64_t pause : 6; /**< DMA Engine X pause count */
uint64_t dmack_h : 6; /**< DMA Engine X DMA ack hold count */
uint64_t we_n : 6; /**< DMA Engine X write enable negated count */
uint64_t we_a : 6; /**< DMA Engine X write enable asserted count */
uint64_t oe_n : 6; /**< DMA Engine X output enable negated count */
uint64_t oe_a : 6; /**< DMA Engine X output enable asserted count */
uint64_t dmack_s : 6; /**< DMA Engine X DMA ack setup count */
uint64_t dmarq : 6; /**< DMA Engine X DMA request count (must be non-zero) */
#else
uint64_t dmarq : 6;
uint64_t dmack_s : 6;
uint64_t oe_a : 6;
uint64_t oe_n : 6;
uint64_t we_a : 6;
uint64_t we_n : 6;
uint64_t dmack_h : 6;
uint64_t pause : 6;
uint64_t reserved_48_54 : 7;
uint64_t width : 1;
uint64_t ddr : 1;
uint64_t rd_dly : 3;
uint64_t tim_mult : 2;
uint64_t dmarq_pi : 1;
uint64_t dmack_pi : 1;
#endif
} s;
struct cvmx_mio_boot_dma_timx_s cn52xx;
struct cvmx_mio_boot_dma_timx_s cn52xxp1;
struct cvmx_mio_boot_dma_timx_s cn56xx;
struct cvmx_mio_boot_dma_timx_s cn56xxp1;
struct cvmx_mio_boot_dma_timx_s cn63xx;
struct cvmx_mio_boot_dma_timx_s cn63xxp1;
};
typedef union cvmx_mio_boot_dma_timx cvmx_mio_boot_dma_timx_t;
/**
* cvmx_mio_boot_err
*
* MIO_BOOT_ERR = MIO Boot Error Register
*
* Contains the address decode error and wait mode error bits. Address decode error is set when a
* boot bus access does not hit in any of the 8 remote regions or 2 local regions. Wait mode error is
* set when wait mode is enabled and the external wait signal is not de-asserted after 32k eclk cycles.
*/
union cvmx_mio_boot_err
{
uint64_t u64;
struct cvmx_mio_boot_err_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_2_63 : 62;
uint64_t wait_err : 1; /**< Wait mode error */
uint64_t adr_err : 1; /**< Address decode error */
#else
uint64_t adr_err : 1;
uint64_t wait_err : 1;
uint64_t reserved_2_63 : 62;
#endif
} s;
struct cvmx_mio_boot_err_s cn30xx;
struct cvmx_mio_boot_err_s cn31xx;
struct cvmx_mio_boot_err_s cn38xx;
struct cvmx_mio_boot_err_s cn38xxp2;
struct cvmx_mio_boot_err_s cn50xx;
struct cvmx_mio_boot_err_s cn52xx;
struct cvmx_mio_boot_err_s cn52xxp1;
struct cvmx_mio_boot_err_s cn56xx;
struct cvmx_mio_boot_err_s cn56xxp1;
struct cvmx_mio_boot_err_s cn58xx;
struct cvmx_mio_boot_err_s cn58xxp1;
struct cvmx_mio_boot_err_s cn63xx;
struct cvmx_mio_boot_err_s cn63xxp1;
};
typedef union cvmx_mio_boot_err cvmx_mio_boot_err_t;
/**
* cvmx_mio_boot_int
*
* MIO_BOOT_INT = MIO Boot Interrupt Register
*
* Contains the interrupt enable bits for address decode error and wait mode error.
*/
union cvmx_mio_boot_int
{
uint64_t u64;
struct cvmx_mio_boot_int_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_2_63 : 62;
uint64_t wait_int : 1; /**< Wait mode error interrupt enable */
uint64_t adr_int : 1; /**< Address decode error interrupt enable */
#else
uint64_t adr_int : 1;
uint64_t wait_int : 1;
uint64_t reserved_2_63 : 62;
#endif
} s;
struct cvmx_mio_boot_int_s cn30xx;
struct cvmx_mio_boot_int_s cn31xx;
struct cvmx_mio_boot_int_s cn38xx;
struct cvmx_mio_boot_int_s cn38xxp2;
struct cvmx_mio_boot_int_s cn50xx;
struct cvmx_mio_boot_int_s cn52xx;
struct cvmx_mio_boot_int_s cn52xxp1;
struct cvmx_mio_boot_int_s cn56xx;
struct cvmx_mio_boot_int_s cn56xxp1;
struct cvmx_mio_boot_int_s cn58xx;
struct cvmx_mio_boot_int_s cn58xxp1;
struct cvmx_mio_boot_int_s cn63xx;
struct cvmx_mio_boot_int_s cn63xxp1;
};
typedef union cvmx_mio_boot_int cvmx_mio_boot_int_t;
/**
* cvmx_mio_boot_loc_adr
*
* MIO_BOOT_LOC_ADR = MIO Boot Local Memory Address Register
*
* Specifies the address for reading or writing the local memory. This address will post-increment
* following an access to the MIO Boot Local Memory Data Register (MIO_BOOT_LOC_DAT).
*
* Local memory region 0 exists from addresses 0x00 - 0x78.
* Local memory region 1 exists from addresses 0x80 - 0xf8.
*/
union cvmx_mio_boot_loc_adr
{
uint64_t u64;
struct cvmx_mio_boot_loc_adr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t adr : 5; /**< Local memory address */
uint64_t reserved_0_2 : 3;
#else
uint64_t reserved_0_2 : 3;
uint64_t adr : 5;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_boot_loc_adr_s cn30xx;
struct cvmx_mio_boot_loc_adr_s cn31xx;
struct cvmx_mio_boot_loc_adr_s cn38xx;
struct cvmx_mio_boot_loc_adr_s cn38xxp2;
struct cvmx_mio_boot_loc_adr_s cn50xx;
struct cvmx_mio_boot_loc_adr_s cn52xx;
struct cvmx_mio_boot_loc_adr_s cn52xxp1;
struct cvmx_mio_boot_loc_adr_s cn56xx;
struct cvmx_mio_boot_loc_adr_s cn56xxp1;
struct cvmx_mio_boot_loc_adr_s cn58xx;
struct cvmx_mio_boot_loc_adr_s cn58xxp1;
struct cvmx_mio_boot_loc_adr_s cn63xx;
struct cvmx_mio_boot_loc_adr_s cn63xxp1;
};
typedef union cvmx_mio_boot_loc_adr cvmx_mio_boot_loc_adr_t;
/**
* cvmx_mio_boot_loc_cfg#
*
* MIO_BOOT_LOC_CFG = MIO Boot Local Region Config Register (1 per region * 2 regions)
*
* Contains local region enable and local region base address parameters. Each local region is 128
* bytes organized as 16 entries x 8 bytes.
*
* Base address specifies address bits [31:7] of the region.
*/
union cvmx_mio_boot_loc_cfgx
{
uint64_t u64;
struct cvmx_mio_boot_loc_cfgx_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_32_63 : 32;
uint64_t en : 1; /**< Local region X enable */
uint64_t reserved_28_30 : 3;
uint64_t base : 25; /**< Local region X base address */
uint64_t reserved_0_2 : 3;
#else
uint64_t reserved_0_2 : 3;
uint64_t base : 25;
uint64_t reserved_28_30 : 3;
uint64_t en : 1;
uint64_t reserved_32_63 : 32;
#endif
} s;
struct cvmx_mio_boot_loc_cfgx_s cn30xx;
struct cvmx_mio_boot_loc_cfgx_s cn31xx;
struct cvmx_mio_boot_loc_cfgx_s cn38xx;
struct cvmx_mio_boot_loc_cfgx_s cn38xxp2;
struct cvmx_mio_boot_loc_cfgx_s cn50xx;
struct cvmx_mio_boot_loc_cfgx_s cn52xx;
struct cvmx_mio_boot_loc_cfgx_s cn52xxp1;
struct cvmx_mio_boot_loc_cfgx_s cn56xx;
struct cvmx_mio_boot_loc_cfgx_s cn56xxp1;
struct cvmx_mio_boot_loc_cfgx_s cn58xx;
struct cvmx_mio_boot_loc_cfgx_s cn58xxp1;
struct cvmx_mio_boot_loc_cfgx_s cn63xx;
struct cvmx_mio_boot_loc_cfgx_s cn63xxp1;
};
typedef union cvmx_mio_boot_loc_cfgx cvmx_mio_boot_loc_cfgx_t;
/**
* cvmx_mio_boot_loc_dat
*
* MIO_BOOT_LOC_DAT = MIO Boot Local Memory Data Register
*
* This is a pseudo-register that will read/write the local memory at the address specified by the MIO
* Boot Local Address Register (MIO_BOOT_LOC_ADR) when accessed.
*/
union cvmx_mio_boot_loc_dat
{
uint64_t u64;
struct cvmx_mio_boot_loc_dat_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t data : 64; /**< Local memory data */
#else
uint64_t data : 64;
#endif
} s;
struct cvmx_mio_boot_loc_dat_s cn30xx;
struct cvmx_mio_boot_loc_dat_s cn31xx;
struct cvmx_mio_boot_loc_dat_s cn38xx;
struct cvmx_mio_boot_loc_dat_s cn38xxp2;
struct cvmx_mio_boot_loc_dat_s cn50xx;
struct cvmx_mio_boot_loc_dat_s cn52xx;
struct cvmx_mio_boot_loc_dat_s cn52xxp1;
struct cvmx_mio_boot_loc_dat_s cn56xx;
struct cvmx_mio_boot_loc_dat_s cn56xxp1;
struct cvmx_mio_boot_loc_dat_s cn58xx;
struct cvmx_mio_boot_loc_dat_s cn58xxp1;
struct cvmx_mio_boot_loc_dat_s cn63xx;
struct cvmx_mio_boot_loc_dat_s cn63xxp1;
};
typedef union cvmx_mio_boot_loc_dat cvmx_mio_boot_loc_dat_t;
/**
* cvmx_mio_boot_pin_defs
*
* MIO_BOOT_PIN_DEFS = MIO Boot Pin Defaults Register
*
*/
union cvmx_mio_boot_pin_defs
{
uint64_t u64;
struct cvmx_mio_boot_pin_defs_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_16_63 : 48;
uint64_t ale : 1; /**< Region 0 default ALE mode */
uint64_t width : 1; /**< Region 0 default bus width */
uint64_t dmack_p2 : 1; /**< boot_dmack[2] default polarity */
uint64_t dmack_p1 : 1; /**< boot_dmack[1] default polarity */
uint64_t dmack_p0 : 1; /**< boot_dmack[0] default polarity */
uint64_t term : 2; /**< Selects default driver termination */
uint64_t nand : 1; /**< Region 0 is NAND flash */
uint64_t reserved_0_7 : 8;
#else
uint64_t reserved_0_7 : 8;
uint64_t nand : 1;
uint64_t term : 2;
uint64_t dmack_p0 : 1;
uint64_t dmack_p1 : 1;
uint64_t dmack_p2 : 1;
uint64_t width : 1;
uint64_t ale : 1;
uint64_t reserved_16_63 : 48;
#endif
} s;
struct cvmx_mio_boot_pin_defs_cn52xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_16_63 : 48;
uint64_t ale : 1; /**< Region 0 default ALE mode */
uint64_t width : 1; /**< Region 0 default bus width */
uint64_t reserved_13_13 : 1;
uint64_t dmack_p1 : 1; /**< boot_dmack[1] default polarity */
uint64_t dmack_p0 : 1; /**< boot_dmack[0] default polarity */
uint64_t term : 2; /**< Selects default driver termination */
uint64_t nand : 1; /**< Region 0 is NAND flash */
uint64_t reserved_0_7 : 8;
#else
uint64_t reserved_0_7 : 8;
uint64_t nand : 1;
uint64_t term : 2;
uint64_t dmack_p0 : 1;
uint64_t dmack_p1 : 1;
uint64_t reserved_13_13 : 1;
uint64_t width : 1;
uint64_t ale : 1;
uint64_t reserved_16_63 : 48;
#endif
} cn52xx;
struct cvmx_mio_boot_pin_defs_cn56xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_16_63 : 48;
uint64_t ale : 1; /**< Region 0 default ALE mode */
uint64_t width : 1; /**< Region 0 default bus width */
uint64_t dmack_p2 : 1; /**< boot_dmack[2] default polarity */
uint64_t dmack_p1 : 1; /**< boot_dmack[1] default polarity */
uint64_t dmack_p0 : 1; /**< boot_dmack[0] default polarity */
uint64_t term : 2; /**< Selects default driver termination */
uint64_t reserved_0_8 : 9;
#else
uint64_t reserved_0_8 : 9;
uint64_t term : 2;
uint64_t dmack_p0 : 1;
uint64_t dmack_p1 : 1;
uint64_t dmack_p2 : 1;
uint64_t width : 1;
uint64_t ale : 1;
uint64_t reserved_16_63 : 48;
#endif
} cn56xx;
struct cvmx_mio_boot_pin_defs_cn52xx cn63xx;
struct cvmx_mio_boot_pin_defs_cn52xx cn63xxp1;
};
typedef union cvmx_mio_boot_pin_defs cvmx_mio_boot_pin_defs_t;
/**
* cvmx_mio_boot_reg_cfg#
*/
union cvmx_mio_boot_reg_cfgx
{
uint64_t u64;
struct cvmx_mio_boot_reg_cfgx_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_44_63 : 20;
uint64_t dmack : 2; /**< Region X DMACK */
uint64_t tim_mult : 2; /**< Region X timing multiplier */
uint64_t rd_dly : 3; /**< Region X read sample delay */
uint64_t sam : 1; /**< Region X SAM mode */
uint64_t we_ext : 2; /**< Region X write enable count extension */
uint64_t oe_ext : 2; /**< Region X output enable count extension */
uint64_t en : 1; /**< Region X enable */
uint64_t orbit : 1; /**< Region X or bit */
uint64_t ale : 1; /**< Region X ALE mode */
uint64_t width : 1; /**< Region X bus width */
uint64_t size : 12; /**< Region X size */
uint64_t base : 16; /**< Region X base address */
#else
uint64_t base : 16;
uint64_t size : 12;
uint64_t width : 1;
uint64_t ale : 1;
uint64_t orbit : 1;
uint64_t en : 1;
uint64_t oe_ext : 2;
uint64_t we_ext : 2;
uint64_t sam : 1;
uint64_t rd_dly : 3;
uint64_t tim_mult : 2;
uint64_t dmack : 2;
uint64_t reserved_44_63 : 20;
#endif
} s;
struct cvmx_mio_boot_reg_cfgx_cn30xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_37_63 : 27;
uint64_t sam : 1; /**< Region X SAM mode */
uint64_t we_ext : 2; /**< Region X write enable count extension */
uint64_t oe_ext : 2; /**< Region X output enable count extension */
uint64_t en : 1; /**< Region X enable */
uint64_t orbit : 1; /**< Region X or bit */
uint64_t ale : 1; /**< Region X ALE mode */
uint64_t width : 1; /**< Region X bus width */
uint64_t size : 12; /**< Region X size */
uint64_t base : 16; /**< Region X base address */
#else
uint64_t base : 16;
uint64_t size : 12;
uint64_t width : 1;
uint64_t ale : 1;
uint64_t orbit : 1;
uint64_t en : 1;
uint64_t oe_ext : 2;
uint64_t we_ext : 2;
uint64_t sam : 1;
uint64_t reserved_37_63 : 27;
#endif
} cn30xx;
struct cvmx_mio_boot_reg_cfgx_cn30xx cn31xx;
struct cvmx_mio_boot_reg_cfgx_cn38xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_32_63 : 32;
uint64_t en : 1; /**< Region X enable */
uint64_t orbit : 1; /**< Region X or bit */
uint64_t reserved_28_29 : 2;
uint64_t size : 12; /**< Region X size */
uint64_t base : 16; /**< Region X base address */
#else
uint64_t base : 16;
uint64_t size : 12;
uint64_t reserved_28_29 : 2;
uint64_t orbit : 1;
uint64_t en : 1;
uint64_t reserved_32_63 : 32;
#endif
} cn38xx;
struct cvmx_mio_boot_reg_cfgx_cn38xx cn38xxp2;
struct cvmx_mio_boot_reg_cfgx_cn50xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_42_63 : 22;
uint64_t tim_mult : 2; /**< Region X timing multiplier */
uint64_t rd_dly : 3; /**< Region X read sample delay */
uint64_t sam : 1; /**< Region X SAM mode */
uint64_t we_ext : 2; /**< Region X write enable count extension */
uint64_t oe_ext : 2; /**< Region X output enable count extension */
uint64_t en : 1; /**< Region X enable */
uint64_t orbit : 1; /**< Region X or bit */
uint64_t ale : 1; /**< Region X ALE mode */
uint64_t width : 1; /**< Region X bus width */
uint64_t size : 12; /**< Region X size */
uint64_t base : 16; /**< Region X base address */
#else
uint64_t base : 16;
uint64_t size : 12;
uint64_t width : 1;
uint64_t ale : 1;
uint64_t orbit : 1;
uint64_t en : 1;
uint64_t oe_ext : 2;
uint64_t we_ext : 2;
uint64_t sam : 1;
uint64_t rd_dly : 3;
uint64_t tim_mult : 2;
uint64_t reserved_42_63 : 22;
#endif
} cn50xx;
struct cvmx_mio_boot_reg_cfgx_s cn52xx;
struct cvmx_mio_boot_reg_cfgx_s cn52xxp1;
struct cvmx_mio_boot_reg_cfgx_s cn56xx;
struct cvmx_mio_boot_reg_cfgx_s cn56xxp1;
struct cvmx_mio_boot_reg_cfgx_cn30xx cn58xx;
struct cvmx_mio_boot_reg_cfgx_cn30xx cn58xxp1;
struct cvmx_mio_boot_reg_cfgx_s cn63xx;
struct cvmx_mio_boot_reg_cfgx_s cn63xxp1;
};
typedef union cvmx_mio_boot_reg_cfgx cvmx_mio_boot_reg_cfgx_t;
/**
* cvmx_mio_boot_reg_tim#
*/
union cvmx_mio_boot_reg_timx
{
uint64_t u64;
struct cvmx_mio_boot_reg_timx_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t pagem : 1; /**< Region X page mode */
uint64_t waitm : 1; /**< Region X wait mode */
uint64_t pages : 2; /**< Region X page size */
uint64_t ale : 6; /**< Region X ALE count */
uint64_t page : 6; /**< Region X page count */
uint64_t wait : 6; /**< Region X wait count */
uint64_t pause : 6; /**< Region X pause count */
uint64_t wr_hld : 6; /**< Region X write hold count */
uint64_t rd_hld : 6; /**< Region X read hold count */
uint64_t we : 6; /**< Region X write enable count */
uint64_t oe : 6; /**< Region X output enable count */
uint64_t ce : 6; /**< Region X chip enable count */
uint64_t adr : 6; /**< Region X address count */
#else
uint64_t adr : 6;
uint64_t ce : 6;
uint64_t oe : 6;
uint64_t we : 6;
uint64_t rd_hld : 6;
uint64_t wr_hld : 6;
uint64_t pause : 6;
uint64_t wait : 6;
uint64_t page : 6;
uint64_t ale : 6;
uint64_t pages : 2;
uint64_t waitm : 1;
uint64_t pagem : 1;
#endif
} s;
struct cvmx_mio_boot_reg_timx_s cn30xx;
struct cvmx_mio_boot_reg_timx_s cn31xx;
struct cvmx_mio_boot_reg_timx_cn38xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t pagem : 1; /**< Region X page mode */
uint64_t waitm : 1; /**< Region X wait mode */
uint64_t pages : 2; /**< Region X page size (NOT IN PASS 1) */
uint64_t reserved_54_59 : 6;
uint64_t page : 6; /**< Region X page count */
uint64_t wait : 6; /**< Region X wait count */
uint64_t pause : 6; /**< Region X pause count */
uint64_t wr_hld : 6; /**< Region X write hold count */
uint64_t rd_hld : 6; /**< Region X read hold count */
uint64_t we : 6; /**< Region X write enable count */
uint64_t oe : 6; /**< Region X output enable count */
uint64_t ce : 6; /**< Region X chip enable count */
uint64_t adr : 6; /**< Region X address count */
#else
uint64_t adr : 6;
uint64_t ce : 6;
uint64_t oe : 6;
uint64_t we : 6;
uint64_t rd_hld : 6;
uint64_t wr_hld : 6;
uint64_t pause : 6;
uint64_t wait : 6;
uint64_t page : 6;
uint64_t reserved_54_59 : 6;
uint64_t pages : 2;
uint64_t waitm : 1;
uint64_t pagem : 1;
#endif
} cn38xx;
struct cvmx_mio_boot_reg_timx_cn38xx cn38xxp2;
struct cvmx_mio_boot_reg_timx_s cn50xx;
struct cvmx_mio_boot_reg_timx_s cn52xx;
struct cvmx_mio_boot_reg_timx_s cn52xxp1;
struct cvmx_mio_boot_reg_timx_s cn56xx;
struct cvmx_mio_boot_reg_timx_s cn56xxp1;
struct cvmx_mio_boot_reg_timx_s cn58xx;
struct cvmx_mio_boot_reg_timx_s cn58xxp1;
struct cvmx_mio_boot_reg_timx_s cn63xx;
struct cvmx_mio_boot_reg_timx_s cn63xxp1;
};
typedef union cvmx_mio_boot_reg_timx cvmx_mio_boot_reg_timx_t;
/**
* cvmx_mio_boot_thr
*
* MIO_BOOT_THR = MIO Boot Threshold Register
*
* Contains MIO Boot threshold values:
*
* FIF_THR = Assert ncb__busy when the Boot NCB input FIFO reaches this level (not typically for
* customer use).
*
* DMA_THR = When non-DMA accesses are pending, perform a DMA access after this value of non-DMA
* accesses have completed. If set to zero, only perform a DMA access when non-DMA
* accesses are not pending.
*/
union cvmx_mio_boot_thr
{
uint64_t u64;
struct cvmx_mio_boot_thr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_22_63 : 42;
uint64_t dma_thr : 6; /**< DMA threshold */
uint64_t reserved_14_15 : 2;
uint64_t fif_cnt : 6; /**< Current NCB FIFO count */
uint64_t reserved_6_7 : 2;
uint64_t fif_thr : 6; /**< NCB busy threshold */
#else
uint64_t fif_thr : 6;
uint64_t reserved_6_7 : 2;
uint64_t fif_cnt : 6;
uint64_t reserved_14_15 : 2;
uint64_t dma_thr : 6;
uint64_t reserved_22_63 : 42;
#endif
} s;
struct cvmx_mio_boot_thr_cn30xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_14_63 : 50;
uint64_t fif_cnt : 6; /**< Current NCB FIFO count */
uint64_t reserved_6_7 : 2;
uint64_t fif_thr : 6; /**< NCB busy threshold */
#else
uint64_t fif_thr : 6;
uint64_t reserved_6_7 : 2;
uint64_t fif_cnt : 6;
uint64_t reserved_14_63 : 50;
#endif
} cn30xx;
struct cvmx_mio_boot_thr_cn30xx cn31xx;
struct cvmx_mio_boot_thr_cn30xx cn38xx;
struct cvmx_mio_boot_thr_cn30xx cn38xxp2;
struct cvmx_mio_boot_thr_cn30xx cn50xx;
struct cvmx_mio_boot_thr_s cn52xx;
struct cvmx_mio_boot_thr_s cn52xxp1;
struct cvmx_mio_boot_thr_s cn56xx;
struct cvmx_mio_boot_thr_s cn56xxp1;
struct cvmx_mio_boot_thr_cn30xx cn58xx;
struct cvmx_mio_boot_thr_cn30xx cn58xxp1;
struct cvmx_mio_boot_thr_s cn63xx;
struct cvmx_mio_boot_thr_s cn63xxp1;
};
typedef union cvmx_mio_boot_thr cvmx_mio_boot_thr_t;
/**
* cvmx_mio_fus_bnk_dat#
*
* Notes:
* The intial state of MIO_FUS_BNK_DAT* is as if bank6 was just read i.e. DAT* = fus[895:768]
*
*/
union cvmx_mio_fus_bnk_datx
{
uint64_t u64;
struct cvmx_mio_fus_bnk_datx_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t dat : 64; /**< Efuse bank store
For reads, the DAT gets the fus bank last read
For write, the DAT determines which fuses to blow */
#else
uint64_t dat : 64;
#endif
} s;
struct cvmx_mio_fus_bnk_datx_s cn50xx;
struct cvmx_mio_fus_bnk_datx_s cn52xx;
struct cvmx_mio_fus_bnk_datx_s cn52xxp1;
struct cvmx_mio_fus_bnk_datx_s cn56xx;
struct cvmx_mio_fus_bnk_datx_s cn56xxp1;
struct cvmx_mio_fus_bnk_datx_s cn58xx;
struct cvmx_mio_fus_bnk_datx_s cn58xxp1;
struct cvmx_mio_fus_bnk_datx_s cn63xx;
struct cvmx_mio_fus_bnk_datx_s cn63xxp1;
};
typedef union cvmx_mio_fus_bnk_datx cvmx_mio_fus_bnk_datx_t;
/**
* cvmx_mio_fus_dat0
*/
union cvmx_mio_fus_dat0
{
uint64_t u64;
struct cvmx_mio_fus_dat0_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_32_63 : 32;
uint64_t man_info : 32; /**< Fuse information - manufacturing info [31:0] */
#else
uint64_t man_info : 32;
uint64_t reserved_32_63 : 32;
#endif
} s;
struct cvmx_mio_fus_dat0_s cn30xx;
struct cvmx_mio_fus_dat0_s cn31xx;
struct cvmx_mio_fus_dat0_s cn38xx;
struct cvmx_mio_fus_dat0_s cn38xxp2;
struct cvmx_mio_fus_dat0_s cn50xx;
struct cvmx_mio_fus_dat0_s cn52xx;
struct cvmx_mio_fus_dat0_s cn52xxp1;
struct cvmx_mio_fus_dat0_s cn56xx;
struct cvmx_mio_fus_dat0_s cn56xxp1;
struct cvmx_mio_fus_dat0_s cn58xx;
struct cvmx_mio_fus_dat0_s cn58xxp1;
struct cvmx_mio_fus_dat0_s cn63xx;
struct cvmx_mio_fus_dat0_s cn63xxp1;
};
typedef union cvmx_mio_fus_dat0 cvmx_mio_fus_dat0_t;
/**
* cvmx_mio_fus_dat1
*/
union cvmx_mio_fus_dat1
{
uint64_t u64;
struct cvmx_mio_fus_dat1_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_32_63 : 32;
uint64_t man_info : 32; /**< Fuse information - manufacturing info [63:32] */
#else
uint64_t man_info : 32;
uint64_t reserved_32_63 : 32;
#endif
} s;
struct cvmx_mio_fus_dat1_s cn30xx;
struct cvmx_mio_fus_dat1_s cn31xx;
struct cvmx_mio_fus_dat1_s cn38xx;
struct cvmx_mio_fus_dat1_s cn38xxp2;
struct cvmx_mio_fus_dat1_s cn50xx;
struct cvmx_mio_fus_dat1_s cn52xx;
struct cvmx_mio_fus_dat1_s cn52xxp1;
struct cvmx_mio_fus_dat1_s cn56xx;
struct cvmx_mio_fus_dat1_s cn56xxp1;
struct cvmx_mio_fus_dat1_s cn58xx;
struct cvmx_mio_fus_dat1_s cn58xxp1;
struct cvmx_mio_fus_dat1_s cn63xx;
struct cvmx_mio_fus_dat1_s cn63xxp1;
};
typedef union cvmx_mio_fus_dat1 cvmx_mio_fus_dat1_t;
/**
* cvmx_mio_fus_dat2
*
* Notes:
* CHIP_ID is consumed in several places within Octeon.
*
* * Core COP0 ProcessorIdentification[Revision]
* * Core EJTAG DeviceIdentification[Version]
* * PCI_CFG02[RID]
* * JTAG controller
*
* Note: The JTAG controller gets CHIP_ID[3:0] solely from the laser fuses.
* Modification to the efuses will not change what the JTAG controller reports
* for CHIP_ID.
*/
union cvmx_mio_fus_dat2
{
uint64_t u64;
struct cvmx_mio_fus_dat2_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_35_63 : 29;
uint64_t dorm_crypto : 1; /**< Fuse information - Dormant Encryption enable */
uint64_t fus318 : 1; /**< Fuse information - a copy of fuse318 */
uint64_t raid_en : 1; /**< Fuse information - RAID enabled */
uint64_t reserved_30_31 : 2;
uint64_t nokasu : 1; /**< Fuse information - Disable Kasumi */
uint64_t nodfa_cp2 : 1; /**< Fuse information - DFA Disable (CP2) */
uint64_t nomul : 1; /**< Fuse information - VMUL disable */
uint64_t nocrypto : 1; /**< Fuse information - AES/DES/HASH disable */
uint64_t rst_sht : 1; /**< Fuse information - When set, use short reset count */
uint64_t bist_dis : 1; /**< Fuse information - BIST Disable */
uint64_t chip_id : 8; /**< Fuse information - CHIP_ID */
uint64_t reserved_0_15 : 16;
#else
uint64_t reserved_0_15 : 16;
uint64_t chip_id : 8;
uint64_t bist_dis : 1;
uint64_t rst_sht : 1;
uint64_t nocrypto : 1;
uint64_t nomul : 1;
uint64_t nodfa_cp2 : 1;
uint64_t nokasu : 1;
uint64_t reserved_30_31 : 2;
uint64_t raid_en : 1;
uint64_t fus318 : 1;
uint64_t dorm_crypto : 1;
uint64_t reserved_35_63 : 29;
#endif
} s;
struct cvmx_mio_fus_dat2_cn30xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_29_63 : 35;
uint64_t nodfa_cp2 : 1; /**< Fuse information - DFA Disable (CP2) */
uint64_t nomul : 1; /**< Fuse information - VMUL disable */
uint64_t nocrypto : 1; /**< Fuse information - AES/DES/HASH disable */
uint64_t rst_sht : 1; /**< Fuse information - When set, use short reset count */
uint64_t bist_dis : 1; /**< Fuse information - BIST Disable */
uint64_t chip_id : 8; /**< Fuse information - CHIP_ID */
uint64_t pll_off : 4; /**< Fuse information - core pll offset
Used to compute the base offset for the core pll.
the offset will be (PLL_OFF ^ 8)
Note, these fuses can only be set from laser fuse */
uint64_t reserved_1_11 : 11;
uint64_t pp_dis : 1; /**< Fuse information - PP_DISABLES */
#else
uint64_t pp_dis : 1;
uint64_t reserved_1_11 : 11;
uint64_t pll_off : 4;
uint64_t chip_id : 8;
uint64_t bist_dis : 1;
uint64_t rst_sht : 1;
uint64_t nocrypto : 1;
uint64_t nomul : 1;
uint64_t nodfa_cp2 : 1;
uint64_t reserved_29_63 : 35;
#endif
} cn30xx;
struct cvmx_mio_fus_dat2_cn31xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_29_63 : 35;
uint64_t nodfa_cp2 : 1; /**< Fuse information - DFA Disable (CP2) */
uint64_t nomul : 1; /**< Fuse information - VMUL disable */
uint64_t nocrypto : 1; /**< Fuse information - AES/DES/HASH disable */
uint64_t rst_sht : 1; /**< Fuse information - When set, use short reset count */
uint64_t bist_dis : 1; /**< Fuse information - BIST Disable */
uint64_t chip_id : 8; /**< Fuse information - CHIP_ID */
uint64_t pll_off : 4; /**< Fuse information - core pll offset
Used to compute the base offset for the core pll.
the offset will be (PLL_OFF ^ 8)
Note, these fuses can only be set from laser fuse */
uint64_t reserved_2_11 : 10;
uint64_t pp_dis : 2; /**< Fuse information - PP_DISABLES */
#else
uint64_t pp_dis : 2;
uint64_t reserved_2_11 : 10;
uint64_t pll_off : 4;
uint64_t chip_id : 8;
uint64_t bist_dis : 1;
uint64_t rst_sht : 1;
uint64_t nocrypto : 1;
uint64_t nomul : 1;
uint64_t nodfa_cp2 : 1;
uint64_t reserved_29_63 : 35;
#endif
} cn31xx;
struct cvmx_mio_fus_dat2_cn38xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_29_63 : 35;
uint64_t nodfa_cp2 : 1; /**< Fuse information - DFA Disable (CP2)
(PASS2 Only) */
uint64_t nomul : 1; /**< Fuse information - VMUL disable
(PASS2 Only) */
uint64_t nocrypto : 1; /**< Fuse information - AES/DES/HASH disable
(PASS2 Only) */
uint64_t rst_sht : 1; /**< Fuse information - When set, use short reset count */
uint64_t bist_dis : 1; /**< Fuse information - BIST Disable */
uint64_t chip_id : 8; /**< Fuse information - CHIP_ID */
uint64_t pp_dis : 16; /**< Fuse information - PP_DISABLES */
#else
uint64_t pp_dis : 16;
uint64_t chip_id : 8;
uint64_t bist_dis : 1;
uint64_t rst_sht : 1;
uint64_t nocrypto : 1;
uint64_t nomul : 1;
uint64_t nodfa_cp2 : 1;
uint64_t reserved_29_63 : 35;
#endif
} cn38xx;
struct cvmx_mio_fus_dat2_cn38xx cn38xxp2;
struct cvmx_mio_fus_dat2_cn50xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_34_63 : 30;
uint64_t fus318 : 1; /**< Fuse information - a copy of fuse318 */
uint64_t raid_en : 1; /**< Fuse information - RAID enabled
(5020 does not have RAID co-processor) */
uint64_t reserved_30_31 : 2;
uint64_t nokasu : 1; /**< Fuse information - Disable Kasumi */
uint64_t nodfa_cp2 : 1; /**< Fuse information - DFA Disable (CP2)
(5020 does not have DFA co-processor) */
uint64_t nomul : 1; /**< Fuse information - VMUL disable */
uint64_t nocrypto : 1; /**< Fuse information - AES/DES/HASH disable */
uint64_t rst_sht : 1; /**< Fuse information - When set, use short reset count */
uint64_t bist_dis : 1; /**< Fuse information - BIST Disable */
uint64_t chip_id : 8; /**< Fuse information - CHIP_ID */
uint64_t reserved_2_15 : 14;
uint64_t pp_dis : 2; /**< Fuse information - PP_DISABLES */
#else
uint64_t pp_dis : 2;
uint64_t reserved_2_15 : 14;
uint64_t chip_id : 8;
uint64_t bist_dis : 1;
uint64_t rst_sht : 1;
uint64_t nocrypto : 1;
uint64_t nomul : 1;
uint64_t nodfa_cp2 : 1;
uint64_t nokasu : 1;
uint64_t reserved_30_31 : 2;
uint64_t raid_en : 1;
uint64_t fus318 : 1;
uint64_t reserved_34_63 : 30;
#endif
} cn50xx;
struct cvmx_mio_fus_dat2_cn52xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_34_63 : 30;
uint64_t fus318 : 1; /**< Fuse information - a copy of fuse318 */
uint64_t raid_en : 1; /**< Fuse information - RAID enabled */
uint64_t reserved_30_31 : 2;
uint64_t nokasu : 1; /**< Fuse information - Disable Kasumi */
uint64_t nodfa_cp2 : 1; /**< Fuse information - DFA Disable (CP2) */
uint64_t nomul : 1; /**< Fuse information - VMUL disable */
uint64_t nocrypto : 1; /**< Fuse information - AES/DES/HASH disable */
uint64_t rst_sht : 1; /**< Fuse information - When set, use short reset count */
uint64_t bist_dis : 1; /**< Fuse information - BIST Disable */
uint64_t chip_id : 8; /**< Fuse information - CHIP_ID */
uint64_t reserved_4_15 : 12;
uint64_t pp_dis : 4; /**< Fuse information - PP_DISABLES */
#else
uint64_t pp_dis : 4;
uint64_t reserved_4_15 : 12;
uint64_t chip_id : 8;
uint64_t bist_dis : 1;
uint64_t rst_sht : 1;
uint64_t nocrypto : 1;
uint64_t nomul : 1;
uint64_t nodfa_cp2 : 1;
uint64_t nokasu : 1;
uint64_t reserved_30_31 : 2;
uint64_t raid_en : 1;
uint64_t fus318 : 1;
uint64_t reserved_34_63 : 30;
#endif
} cn52xx;
struct cvmx_mio_fus_dat2_cn52xx cn52xxp1;
struct cvmx_mio_fus_dat2_cn56xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_34_63 : 30;
uint64_t fus318 : 1; /**< Fuse information - a copy of fuse318 */
uint64_t raid_en : 1; /**< Fuse information - RAID enabled */
uint64_t reserved_30_31 : 2;
uint64_t nokasu : 1; /**< Fuse information - Disable Kasumi */
uint64_t nodfa_cp2 : 1; /**< Fuse information - DFA Disable (CP2) */
uint64_t nomul : 1; /**< Fuse information - VMUL disable */
uint64_t nocrypto : 1; /**< Fuse information - AES/DES/HASH disable */
uint64_t rst_sht : 1; /**< Fuse information - When set, use short reset count */
uint64_t bist_dis : 1; /**< Fuse information - BIST Disable */
uint64_t chip_id : 8; /**< Fuse information - CHIP_ID */
uint64_t reserved_12_15 : 4;
uint64_t pp_dis : 12; /**< Fuse information - PP_DISABLES */
#else
uint64_t pp_dis : 12;
uint64_t reserved_12_15 : 4;
uint64_t chip_id : 8;
uint64_t bist_dis : 1;
uint64_t rst_sht : 1;
uint64_t nocrypto : 1;
uint64_t nomul : 1;
uint64_t nodfa_cp2 : 1;
uint64_t nokasu : 1;
uint64_t reserved_30_31 : 2;
uint64_t raid_en : 1;
uint64_t fus318 : 1;
uint64_t reserved_34_63 : 30;
#endif
} cn56xx;
struct cvmx_mio_fus_dat2_cn56xx cn56xxp1;
struct cvmx_mio_fus_dat2_cn58xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_30_63 : 34;
uint64_t nokasu : 1; /**< Fuse information - Disable Kasumi */
uint64_t nodfa_cp2 : 1; /**< Fuse information - DFA Disable (CP2) */
uint64_t nomul : 1; /**< Fuse information - VMUL disable */
uint64_t nocrypto : 1; /**< Fuse information - AES/DES/HASH disable */
uint64_t rst_sht : 1; /**< Fuse information - When set, use short reset count */
uint64_t bist_dis : 1; /**< Fuse information - BIST Disable */
uint64_t chip_id : 8; /**< Fuse information - CHIP_ID */
uint64_t pp_dis : 16; /**< Fuse information - PP_DISABLES */
#else
uint64_t pp_dis : 16;
uint64_t chip_id : 8;
uint64_t bist_dis : 1;
uint64_t rst_sht : 1;
uint64_t nocrypto : 1;
uint64_t nomul : 1;
uint64_t nodfa_cp2 : 1;
uint64_t nokasu : 1;
uint64_t reserved_30_63 : 34;
#endif
} cn58xx;
struct cvmx_mio_fus_dat2_cn58xx cn58xxp1;
struct cvmx_mio_fus_dat2_cn63xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_35_63 : 29;
uint64_t dorm_crypto : 1; /**< Fuse information - Dormant Encryption enable */
uint64_t fus318 : 1; /**< Fuse information - a copy of fuse318 */
uint64_t raid_en : 1; /**< Fuse information - RAID enabled */
uint64_t reserved_29_31 : 3;
uint64_t nodfa_cp2 : 1; /**< Fuse information - DFA Disable (CP2) */
uint64_t nomul : 1; /**< Fuse information - VMUL disable */
uint64_t nocrypto : 1; /**< Fuse information - AES/DES/HASH disable */
uint64_t reserved_24_25 : 2;
uint64_t chip_id : 8; /**< Fuse information - CHIP_ID */
uint64_t reserved_6_15 : 10;
uint64_t pp_dis : 6; /**< Fuse information - PP_DISABLES */
#else
uint64_t pp_dis : 6;
uint64_t reserved_6_15 : 10;
uint64_t chip_id : 8;
uint64_t reserved_24_25 : 2;
uint64_t nocrypto : 1;
uint64_t nomul : 1;
uint64_t nodfa_cp2 : 1;
uint64_t reserved_29_31 : 3;
uint64_t raid_en : 1;
uint64_t fus318 : 1;
uint64_t dorm_crypto : 1;
uint64_t reserved_35_63 : 29;
#endif
} cn63xx;
struct cvmx_mio_fus_dat2_cn63xx cn63xxp1;
};
typedef union cvmx_mio_fus_dat2 cvmx_mio_fus_dat2_t;
/**
* cvmx_mio_fus_dat3
*/
union cvmx_mio_fus_dat3
{
uint64_t u64;
struct cvmx_mio_fus_dat3_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_58_63 : 6;
uint64_t pll_ctl : 10; /**< Fuse information - PLL control */
uint64_t dfa_info_dte : 3; /**< Fuse information - DFA information (DTE) */
uint64_t dfa_info_clm : 4; /**< Fuse information - DFA information (Cluster mask) */
uint64_t reserved_40_40 : 1;
uint64_t ema : 2; /**< Fuse information - EMA */
uint64_t efus_lck_rsv : 1; /**< Fuse information - efuse lockdown */
uint64_t efus_lck_man : 1; /**< Fuse information - efuse lockdown */
uint64_t pll_half_dis : 1; /**< Fuse information - RCLK PLL control */
uint64_t l2c_crip : 3; /**< Fuse information - L2C Cripple (1/8, 1/4, 1/2) */
uint64_t pll_div4 : 1; /**< Fuse information - PLL DIV4 mode
(laser fuse only) */
uint64_t reserved_29_30 : 2;
uint64_t bar2_en : 1; /**< Fuse information - BAR2 Present (when blown '1') */
uint64_t efus_lck : 1; /**< Fuse information - efuse lockdown */
uint64_t efus_ign : 1; /**< Fuse information - efuse ignore */
uint64_t nozip : 1; /**< Fuse information - ZIP disable */
uint64_t nodfa_dte : 1; /**< Fuse information - DFA Disable (DTE) */
uint64_t icache : 24; /**< Fuse information - ICACHE Hard Repair Data */
#else
uint64_t icache : 24;
uint64_t nodfa_dte : 1;
uint64_t nozip : 1;
uint64_t efus_ign : 1;
uint64_t efus_lck : 1;
uint64_t bar2_en : 1;
uint64_t reserved_29_30 : 2;
uint64_t pll_div4 : 1;
uint64_t l2c_crip : 3;
uint64_t pll_half_dis : 1;
uint64_t efus_lck_man : 1;
uint64_t efus_lck_rsv : 1;
uint64_t ema : 2;
uint64_t reserved_40_40 : 1;
uint64_t dfa_info_clm : 4;
uint64_t dfa_info_dte : 3;
uint64_t pll_ctl : 10;
uint64_t reserved_58_63 : 6;
#endif
} s;
struct cvmx_mio_fus_dat3_cn30xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_32_63 : 32;
uint64_t pll_div4 : 1; /**< Fuse information - PLL DIV4 mode
(laser fuse only) */
uint64_t reserved_29_30 : 2;
uint64_t bar2_en : 1; /**< Fuse information - BAR2 Enable (when blown '1') */
uint64_t efus_lck : 1; /**< Fuse information - efuse lockdown */
uint64_t efus_ign : 1; /**< Fuse information - efuse ignore
This bit only has side effects when blown in
the laser fuses. It is ignore if only set in
efuse store. */
uint64_t nozip : 1; /**< Fuse information - ZIP disable */
uint64_t nodfa_dte : 1; /**< Fuse information - DFA Disable (DTE) */
uint64_t icache : 24; /**< Fuse information - ICACHE Hard Repair Data */
#else
uint64_t icache : 24;
uint64_t nodfa_dte : 1;
uint64_t nozip : 1;
uint64_t efus_ign : 1;
uint64_t efus_lck : 1;
uint64_t bar2_en : 1;
uint64_t reserved_29_30 : 2;
uint64_t pll_div4 : 1;
uint64_t reserved_32_63 : 32;
#endif
} cn30xx;
struct cvmx_mio_fus_dat3_cn31xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_32_63 : 32;
uint64_t pll_div4 : 1; /**< Fuse information - PLL DIV4 mode
(laser fuse only) */
uint64_t zip_crip : 2; /**< Fuse information - Zip Cripple
(O2P Only) */
uint64_t bar2_en : 1; /**< Fuse information - BAR2 Enable (when blown '1') */
uint64_t efus_lck : 1; /**< Fuse information - efuse lockdown */
uint64_t efus_ign : 1; /**< Fuse information - efuse ignore
This bit only has side effects when blown in
the laser fuses. It is ignore if only set in
efuse store. */
uint64_t nozip : 1; /**< Fuse information - ZIP disable */
uint64_t nodfa_dte : 1; /**< Fuse information - DFA Disable (DTE) */
uint64_t icache : 24; /**< Fuse information - ICACHE Hard Repair Data */
#else
uint64_t icache : 24;
uint64_t nodfa_dte : 1;
uint64_t nozip : 1;
uint64_t efus_ign : 1;
uint64_t efus_lck : 1;
uint64_t bar2_en : 1;
uint64_t zip_crip : 2;
uint64_t pll_div4 : 1;
uint64_t reserved_32_63 : 32;
#endif
} cn31xx;
struct cvmx_mio_fus_dat3_cn38xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_31_63 : 33;
uint64_t zip_crip : 2; /**< Fuse information - Zip Cripple
(PASS3 Only) */
uint64_t bar2_en : 1; /**< Fuse information - BAR2 Enable (when blown '1')
(PASS2 Only) */
uint64_t efus_lck : 1; /**< Fuse information - efuse lockdown
(PASS2 Only) */
uint64_t efus_ign : 1; /**< Fuse information - efuse ignore
This bit only has side effects when blown in
the laser fuses. It is ignore if only set in
efuse store.
(PASS2 Only) */
uint64_t nozip : 1; /**< Fuse information - ZIP disable
(PASS2 Only) */
uint64_t nodfa_dte : 1; /**< Fuse information - DFA Disable (DTE)
(PASS2 Only) */
uint64_t icache : 24; /**< Fuse information - ICACHE Hard Repair Data */
#else
uint64_t icache : 24;
uint64_t nodfa_dte : 1;
uint64_t nozip : 1;
uint64_t efus_ign : 1;
uint64_t efus_lck : 1;
uint64_t bar2_en : 1;
uint64_t zip_crip : 2;
uint64_t reserved_31_63 : 33;
#endif
} cn38xx;
struct cvmx_mio_fus_dat3_cn38xxp2
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_29_63 : 35;
uint64_t bar2_en : 1; /**< Fuse information - BAR2 Enable (when blown '1')
(PASS2 Only) */
uint64_t efus_lck : 1; /**< Fuse information - efuse lockdown
(PASS2 Only) */
uint64_t efus_ign : 1; /**< Fuse information - efuse ignore
This bit only has side effects when blown in
the laser fuses. It is ignore if only set in
efuse store.
(PASS2 Only) */
uint64_t nozip : 1; /**< Fuse information - ZIP disable
(PASS2 Only) */
uint64_t nodfa_dte : 1; /**< Fuse information - DFA Disable (DTE)
(PASS2 Only) */
uint64_t icache : 24; /**< Fuse information - ICACHE Hard Repair Data */
#else
uint64_t icache : 24;
uint64_t nodfa_dte : 1;
uint64_t nozip : 1;
uint64_t efus_ign : 1;
uint64_t efus_lck : 1;
uint64_t bar2_en : 1;
uint64_t reserved_29_63 : 35;
#endif
} cn38xxp2;
struct cvmx_mio_fus_dat3_cn38xx cn50xx;
struct cvmx_mio_fus_dat3_cn38xx cn52xx;
struct cvmx_mio_fus_dat3_cn38xx cn52xxp1;
struct cvmx_mio_fus_dat3_cn38xx cn56xx;
struct cvmx_mio_fus_dat3_cn38xx cn56xxp1;
struct cvmx_mio_fus_dat3_cn38xx cn58xx;
struct cvmx_mio_fus_dat3_cn38xx cn58xxp1;
struct cvmx_mio_fus_dat3_cn63xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_58_63 : 6;
uint64_t pll_ctl : 10; /**< Fuse information - PLL control */
uint64_t dfa_info_dte : 3; /**< Fuse information - DFA information (DTE) */
uint64_t dfa_info_clm : 4; /**< Fuse information - DFA information (Cluster mask) */
uint64_t reserved_40_40 : 1;
uint64_t ema : 2; /**< Fuse information - EMA */
uint64_t efus_lck_rsv : 1; /**< Fuse information - efuse lockdown */
uint64_t efus_lck_man : 1; /**< Fuse information - efuse lockdown */
uint64_t pll_half_dis : 1; /**< Fuse information - RCLK PLL control */
uint64_t l2c_crip : 3; /**< Fuse information - L2C Cripple (1/8, 1/4, 1/2) */
uint64_t reserved_31_31 : 1;
uint64_t zip_info : 2; /**< Fuse information - Zip information */
uint64_t bar2_en : 1; /**< Fuse information - BAR2 Present (when blown '1') */
uint64_t efus_lck : 1; /**< Fuse information - efuse lockdown */
uint64_t efus_ign : 1; /**< Fuse information - efuse ignore */
uint64_t nozip : 1; /**< Fuse information - ZIP disable */
uint64_t nodfa_dte : 1; /**< Fuse information - DFA Disable (DTE) */
uint64_t reserved_0_23 : 24;
#else
uint64_t reserved_0_23 : 24;
uint64_t nodfa_dte : 1;
uint64_t nozip : 1;
uint64_t efus_ign : 1;
uint64_t efus_lck : 1;
uint64_t bar2_en : 1;
uint64_t zip_info : 2;
uint64_t reserved_31_31 : 1;
uint64_t l2c_crip : 3;
uint64_t pll_half_dis : 1;
uint64_t efus_lck_man : 1;
uint64_t efus_lck_rsv : 1;
uint64_t ema : 2;
uint64_t reserved_40_40 : 1;
uint64_t dfa_info_clm : 4;
uint64_t dfa_info_dte : 3;
uint64_t pll_ctl : 10;
uint64_t reserved_58_63 : 6;
#endif
} cn63xx;
struct cvmx_mio_fus_dat3_cn63xx cn63xxp1;
};
typedef union cvmx_mio_fus_dat3 cvmx_mio_fus_dat3_t;
/**
* cvmx_mio_fus_ema
*/
union cvmx_mio_fus_ema
{
uint64_t u64;
struct cvmx_mio_fus_ema_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_7_63 : 57;
uint64_t eff_ema : 3; /**< Reserved */
uint64_t reserved_3_3 : 1;
uint64_t ema : 3; /**< Reserved */
#else
uint64_t ema : 3;
uint64_t reserved_3_3 : 1;
uint64_t eff_ema : 3;
uint64_t reserved_7_63 : 57;
#endif
} s;
struct cvmx_mio_fus_ema_s cn50xx;
struct cvmx_mio_fus_ema_s cn52xx;
struct cvmx_mio_fus_ema_s cn52xxp1;
struct cvmx_mio_fus_ema_s cn56xx;
struct cvmx_mio_fus_ema_s cn56xxp1;
struct cvmx_mio_fus_ema_cn58xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_2_63 : 62;
uint64_t ema : 2; /**< EMA Settings */
#else
uint64_t ema : 2;
uint64_t reserved_2_63 : 62;
#endif
} cn58xx;
struct cvmx_mio_fus_ema_cn58xx cn58xxp1;
struct cvmx_mio_fus_ema_s cn63xx;
struct cvmx_mio_fus_ema_s cn63xxp1;
};
typedef union cvmx_mio_fus_ema cvmx_mio_fus_ema_t;
/**
* cvmx_mio_fus_pdf
*/
union cvmx_mio_fus_pdf
{
uint64_t u64;
struct cvmx_mio_fus_pdf_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t pdf : 64; /**< Fuse information - Product Definition Field */
#else
uint64_t pdf : 64;
#endif
} s;
struct cvmx_mio_fus_pdf_s cn50xx;
struct cvmx_mio_fus_pdf_s cn52xx;
struct cvmx_mio_fus_pdf_s cn52xxp1;
struct cvmx_mio_fus_pdf_s cn56xx;
struct cvmx_mio_fus_pdf_s cn56xxp1;
struct cvmx_mio_fus_pdf_s cn58xx;
struct cvmx_mio_fus_pdf_s cn63xx;
struct cvmx_mio_fus_pdf_s cn63xxp1;
};
typedef union cvmx_mio_fus_pdf cvmx_mio_fus_pdf_t;
/**
* cvmx_mio_fus_pll
*
* Notes:
* The core clkout postscaler should be placed in reset at least 10 ref clocks prior to changing
* the core clkout select. The core clkout postscaler should remain under reset for at least 10
* ref clocks after the core clkout select changes.
*
* The pnr clkout postscaler should be placed in reset at least 10 ref clocks prior to changing
* the pnr clkout select. The pnr clkout postscaler should remain under reset for at least 10
* ref clocks after the pnr clkout select changes.
*/
union cvmx_mio_fus_pll
{
uint64_t u64;
struct cvmx_mio_fus_pll_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t c_cout_rst : 1; /**< Core clkout postscaler reset */
uint64_t c_cout_sel : 2; /**< Core clkout select
(0=RCLK,1=PS output,2=PLL output, 3=GND) | $PR */
uint64_t pnr_cout_rst : 1; /**< PNR clkout postscaler reset */
uint64_t pnr_cout_sel : 2; /**< PNR clkout select
(0=SCLK,1=PS output,2=PLL output, 3=GND) | $PR */
uint64_t rfslip : 1; /**< Reserved */
uint64_t fbslip : 1; /**< Reserved */
#else
uint64_t fbslip : 1;
uint64_t rfslip : 1;
uint64_t pnr_cout_sel : 2;
uint64_t pnr_cout_rst : 1;
uint64_t c_cout_sel : 2;
uint64_t c_cout_rst : 1;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_fus_pll_cn50xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_2_63 : 62;
uint64_t rfslip : 1; /**< PLL reference clock slip */
uint64_t fbslip : 1; /**< PLL feedback clock slip */
#else
uint64_t fbslip : 1;
uint64_t rfslip : 1;
uint64_t reserved_2_63 : 62;
#endif
} cn50xx;
struct cvmx_mio_fus_pll_cn50xx cn52xx;
struct cvmx_mio_fus_pll_cn50xx cn52xxp1;
struct cvmx_mio_fus_pll_cn50xx cn56xx;
struct cvmx_mio_fus_pll_cn50xx cn56xxp1;
struct cvmx_mio_fus_pll_cn50xx cn58xx;
struct cvmx_mio_fus_pll_cn50xx cn58xxp1;
struct cvmx_mio_fus_pll_s cn63xx;
struct cvmx_mio_fus_pll_s cn63xxp1;
};
typedef union cvmx_mio_fus_pll cvmx_mio_fus_pll_t;
/**
* cvmx_mio_fus_prog
*
* DON'T PUT IN HRM*
*
*
* Notes:
* This CSR is not present in the HRM.
*
* To write a bank of fuses, SW must set MIO_FUS_WADR[ADDR] to the bank to be
* programmed and then set each bit within MIO_FUS_BNK_DATX to indicate which
* fuses to blow. Once ADDR, and DAT are setup, SW can write to
* MIO_FUS_PROG[PROG] to start the bank write and poll on PROG. Once PROG is
* clear, the bank write is complete.
*
* A soft blow is still subject to lockdown fuses. After a soft/warm reset, the
* chip will behave as though the fuses were actually blown. A cold reset restores
* the actual fuse valuse.
*/
union cvmx_mio_fus_prog
{
uint64_t u64;
struct cvmx_mio_fus_prog_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_2_63 : 62;
uint64_t soft : 1; /**< When set with PROG, causes only the local storeage
to change. Will not really blow any fuses. HW
will clear when the program operation is complete */
uint64_t prog : 1; /**< Blow the fuse bank
SW will set PROG, and then the HW will clear
when the program operation is complete */
#else
uint64_t prog : 1;
uint64_t soft : 1;
uint64_t reserved_2_63 : 62;
#endif
} s;
struct cvmx_mio_fus_prog_cn30xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_1_63 : 63;
uint64_t prog : 1; /**< Blow the fuse
SW will set PROG, hold it for 10us, then clear it */
#else
uint64_t prog : 1;
uint64_t reserved_1_63 : 63;
#endif
} cn30xx;
struct cvmx_mio_fus_prog_cn30xx cn31xx;
struct cvmx_mio_fus_prog_cn30xx cn38xx;
struct cvmx_mio_fus_prog_cn30xx cn38xxp2;
struct cvmx_mio_fus_prog_cn30xx cn50xx;
struct cvmx_mio_fus_prog_cn30xx cn52xx;
struct cvmx_mio_fus_prog_cn30xx cn52xxp1;
struct cvmx_mio_fus_prog_cn30xx cn56xx;
struct cvmx_mio_fus_prog_cn30xx cn56xxp1;
struct cvmx_mio_fus_prog_cn30xx cn58xx;
struct cvmx_mio_fus_prog_cn30xx cn58xxp1;
struct cvmx_mio_fus_prog_s cn63xx;
struct cvmx_mio_fus_prog_s cn63xxp1;
};
typedef union cvmx_mio_fus_prog cvmx_mio_fus_prog_t;
/**
* cvmx_mio_fus_prog_times
*
* DON'T PUT IN HRM*
*
*
* Notes:
* This CSR is not present in the HRM.
*
* All values must be > 0 for correct electrical operation.
*
* IFB fuses are 0..1791
* L6G fuses are 1792 to 2047
*
* The reset values are for IFB fuses for ref_clk of 100MHZ
*/
union cvmx_mio_fus_prog_times
{
uint64_t u64;
struct cvmx_mio_fus_prog_times_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_35_63 : 29;
uint64_t vgate_pin : 1; /**< efuse vgate pin (L6G) */
uint64_t fsrc_pin : 1; /**< efuse fsource pin (L6G) */
uint64_t prog_pin : 1; /**< efuse program pin (IFB) */
uint64_t reserved_6_31 : 26;
uint64_t setup : 6; /**< efuse timing param
SETUP = (tWRS/refclk period)-1
For IFB: tWRS = 20ns
For L6G: tWRS = 20ns */
#else
uint64_t setup : 6;
uint64_t reserved_6_31 : 26;
uint64_t prog_pin : 1;
uint64_t fsrc_pin : 1;
uint64_t vgate_pin : 1;
uint64_t reserved_35_63 : 29;
#endif
} s;
struct cvmx_mio_fus_prog_times_cn50xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_33_63 : 31;
uint64_t prog_pin : 1; /**< efuse program pin */
uint64_t out : 8; /**< efuse timing param (ref_clks to delay 10ns) */
uint64_t sclk_lo : 4; /**< efuse timing param (ref_clks to delay 5ns) */
uint64_t sclk_hi : 12; /**< efuse timing param (ref_clks to delay 1000ns) */
uint64_t setup : 8; /**< efuse timing param (ref_clks to delay 10ns) */
#else
uint64_t setup : 8;
uint64_t sclk_hi : 12;
uint64_t sclk_lo : 4;
uint64_t out : 8;
uint64_t prog_pin : 1;
uint64_t reserved_33_63 : 31;
#endif
} cn50xx;
struct cvmx_mio_fus_prog_times_cn50xx cn52xx;
struct cvmx_mio_fus_prog_times_cn50xx cn52xxp1;
struct cvmx_mio_fus_prog_times_cn50xx cn56xx;
struct cvmx_mio_fus_prog_times_cn50xx cn56xxp1;
struct cvmx_mio_fus_prog_times_cn50xx cn58xx;
struct cvmx_mio_fus_prog_times_cn50xx cn58xxp1;
struct cvmx_mio_fus_prog_times_cn63xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_35_63 : 29;
uint64_t vgate_pin : 1; /**< efuse vgate pin (L6G) */
uint64_t fsrc_pin : 1; /**< efuse fsource pin (L6G) */
uint64_t prog_pin : 1; /**< efuse program pin (IFB) */
uint64_t out : 7; /**< efuse timing param
OUT = (tOUT/refclk period)-1
For IFB: tOUT = 20ns
For L6G: tOUT = 20ns */
uint64_t sclk_lo : 4; /**< efuse timing param
SCLK_LO=(tSLO/refclk period)-1
For IFB: tSLO = 20ns
For L6G: tSLO = 20ns */
uint64_t sclk_hi : 15; /**< efuse timing param
***NOTE: Pass 1.x reset value is 20000
SCLK_HI=(tSHI/refclk period)-1
For IFB: tSHI = 200us
For L6G: tSHI = 25us */
uint64_t setup : 6; /**< efuse timing param
SETUP = (tWRS/refclk period)-1
For IFB: tWRS = 20ns
For L6G: tWRS = 20ns */
#else
uint64_t setup : 6;
uint64_t sclk_hi : 15;
uint64_t sclk_lo : 4;
uint64_t out : 7;
uint64_t prog_pin : 1;
uint64_t fsrc_pin : 1;
uint64_t vgate_pin : 1;
uint64_t reserved_35_63 : 29;
#endif
} cn63xx;
struct cvmx_mio_fus_prog_times_cn63xx cn63xxp1;
};
typedef union cvmx_mio_fus_prog_times cvmx_mio_fus_prog_times_t;
/**
* cvmx_mio_fus_rcmd
*
* Notes:
* To read an efuse, SW writes MIO_FUS_RCMD[ADDR,PEND] with the byte address of
* the fuse in question, then SW can poll MIO_FUS_RCMD[PEND]. When PEND is
* clear, then MIO_FUS_RCMD[DAT] is valid. In addition, if the efuse read went
* to the efuse banks (eg. ((ADDR/16) not [0,1,7]) || EFUSE) SW can read
* MIO_FUS_BNK_DATX which contains all 128 fuses in the bank associated in
* ADDR.
*/
union cvmx_mio_fus_rcmd
{
uint64_t u64;
struct cvmx_mio_fus_rcmd_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_24_63 : 40;
uint64_t dat : 8; /**< 8bits of fuse data */
uint64_t reserved_13_15 : 3;
uint64_t pend : 1; /**< SW sets this bit on a write to start FUSE read
operation. HW clears when read is complete and
the DAT is valid */
uint64_t reserved_9_11 : 3;
uint64_t efuse : 1; /**< When set, return data from the efuse storage
rather than the local storage */
uint64_t addr : 8; /**< The byte address of the fuse to read */
#else
uint64_t addr : 8;
uint64_t efuse : 1;
uint64_t reserved_9_11 : 3;
uint64_t pend : 1;
uint64_t reserved_13_15 : 3;
uint64_t dat : 8;
uint64_t reserved_24_63 : 40;
#endif
} s;
struct cvmx_mio_fus_rcmd_cn30xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_24_63 : 40;
uint64_t dat : 8; /**< 8bits of fuse data */
uint64_t reserved_13_15 : 3;
uint64_t pend : 1; /**< SW sets this bit on a write to start FUSE read
operation. HW clears when read is complete and
the DAT is valid */
uint64_t reserved_9_11 : 3;
uint64_t efuse : 1; /**< When set, return data from the efuse storage
rather than the local storage for the 320 HW fuses */
uint64_t reserved_7_7 : 1;
uint64_t addr : 7; /**< The byte address of the fuse to read */
#else
uint64_t addr : 7;
uint64_t reserved_7_7 : 1;
uint64_t efuse : 1;
uint64_t reserved_9_11 : 3;
uint64_t pend : 1;
uint64_t reserved_13_15 : 3;
uint64_t dat : 8;
uint64_t reserved_24_63 : 40;
#endif
} cn30xx;
struct cvmx_mio_fus_rcmd_cn30xx cn31xx;
struct cvmx_mio_fus_rcmd_cn30xx cn38xx;
struct cvmx_mio_fus_rcmd_cn30xx cn38xxp2;
struct cvmx_mio_fus_rcmd_cn30xx cn50xx;
struct cvmx_mio_fus_rcmd_s cn52xx;
struct cvmx_mio_fus_rcmd_s cn52xxp1;
struct cvmx_mio_fus_rcmd_s cn56xx;
struct cvmx_mio_fus_rcmd_s cn56xxp1;
struct cvmx_mio_fus_rcmd_cn30xx cn58xx;
struct cvmx_mio_fus_rcmd_cn30xx cn58xxp1;
struct cvmx_mio_fus_rcmd_s cn63xx;
struct cvmx_mio_fus_rcmd_s cn63xxp1;
};
typedef union cvmx_mio_fus_rcmd cvmx_mio_fus_rcmd_t;
/**
* cvmx_mio_fus_read_times
*
* Notes:
* IFB fuses are 0..1791
* L6G fuses are 1792 to 2047
*
* The reset values are for IFB fuses for refclk up to 100MHZ when core PLL is enagaged
* The reset values are for IFB fuses for refclk up to 500MHZ when core PLL is not enagaged
*
* If any of the formulas above result in a value less than zero, the corresponding
* timing parameter should be set to zero.
*
* Prior to issuing a read to the fuse banks (via. MIO_FUS_RCMD), this register
* should be written with the timing parameters which correspond to the fuse bank type (IFB vs L6G)
* that will be read.
*
* This register should not be written while MIO_FUS_RCMD[PEND]=1.
*/
union cvmx_mio_fus_read_times
{
uint64_t u64;
struct cvmx_mio_fus_read_times_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_26_63 : 38;
uint64_t sch : 4; /**< Hold CS for (SCH+1) refclks after FSET desserts
SCH = (tSCH/refclk period)-1
For IFB: tSCH = 160ns
For L6G: tSCH = 10ns */
uint64_t fsh : 4; /**< Hold FSET for (FSH+1) refclks after PRCHG deasserts
FSH = (tFSH/refclk period)-1
For IFB: tFSH = 160ns
For L6G: tFSH = 10ns */
uint64_t prh : 4; /**< Assert PRCHG (PRH+1) refclks after SIGDEV deasserts
PRH = (tPRH/refclk period)-1
For IFB: tPRH = 70ns
For L6G: tPRH = 10ns */
uint64_t sdh : 4; /**< Hold SIGDEV for (SDH+1) refclks after FSET asserts
SDH = (tSDH/refclk period)-1
For IFB: tPRH = 10ns
For L6G: tPRH = 10ns */
uint64_t setup : 10; /**< Assert CS for (SETUP+1) refclks before asserting
SIGDEV, FSET, or PRCHG
SETUP=(tRDS/refclk period)-1
For IFB: tRDS = 10000ns
For L6G: tRDS = max(tSCS,tSDS,tPRS)
where tSCS = 10ns
tSDS = 10ns
tPRS = 10ns */
#else
uint64_t setup : 10;
uint64_t sdh : 4;
uint64_t prh : 4;
uint64_t fsh : 4;
uint64_t sch : 4;
uint64_t reserved_26_63 : 38;
#endif
} s;
struct cvmx_mio_fus_read_times_s cn63xx;
struct cvmx_mio_fus_read_times_s cn63xxp1;
};
typedef union cvmx_mio_fus_read_times cvmx_mio_fus_read_times_t;
/**
* cvmx_mio_fus_repair_res0
*/
union cvmx_mio_fus_repair_res0
{
uint64_t u64;
struct cvmx_mio_fus_repair_res0_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_55_63 : 9;
uint64_t too_many : 1; /**< Too many defects */
uint64_t repair2 : 18; /**< BISR Results */
uint64_t repair1 : 18; /**< BISR Results */
uint64_t repair0 : 18; /**< BISR Results */
#else
uint64_t repair0 : 18;
uint64_t repair1 : 18;
uint64_t repair2 : 18;
uint64_t too_many : 1;
uint64_t reserved_55_63 : 9;
#endif
} s;
struct cvmx_mio_fus_repair_res0_s cn63xx;
struct cvmx_mio_fus_repair_res0_s cn63xxp1;
};
typedef union cvmx_mio_fus_repair_res0 cvmx_mio_fus_repair_res0_t;
/**
* cvmx_mio_fus_repair_res1
*/
union cvmx_mio_fus_repair_res1
{
uint64_t u64;
struct cvmx_mio_fus_repair_res1_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_54_63 : 10;
uint64_t repair5 : 18; /**< BISR Results */
uint64_t repair4 : 18; /**< BISR Results */
uint64_t repair3 : 18; /**< BISR Results */
#else
uint64_t repair3 : 18;
uint64_t repair4 : 18;
uint64_t repair5 : 18;
uint64_t reserved_54_63 : 10;
#endif
} s;
struct cvmx_mio_fus_repair_res1_s cn63xx;
struct cvmx_mio_fus_repair_res1_s cn63xxp1;
};
typedef union cvmx_mio_fus_repair_res1 cvmx_mio_fus_repair_res1_t;
/**
* cvmx_mio_fus_repair_res2
*/
union cvmx_mio_fus_repair_res2
{
uint64_t u64;
struct cvmx_mio_fus_repair_res2_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_18_63 : 46;
uint64_t repair6 : 18; /**< BISR Results */
#else
uint64_t repair6 : 18;
uint64_t reserved_18_63 : 46;
#endif
} s;
struct cvmx_mio_fus_repair_res2_s cn63xx;
struct cvmx_mio_fus_repair_res2_s cn63xxp1;
};
typedef union cvmx_mio_fus_repair_res2 cvmx_mio_fus_repair_res2_t;
/**
* cvmx_mio_fus_spr_repair_res
*
* Notes:
* Pass3 Only
*
*/
union cvmx_mio_fus_spr_repair_res
{
uint64_t u64;
struct cvmx_mio_fus_spr_repair_res_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_42_63 : 22;
uint64_t repair2 : 14; /**< Reserved (see MIO_FUS_REPAIR_RES*) */
uint64_t repair1 : 14; /**< Reserved (see MIO_FUS_REPAIR_RES*) */
uint64_t repair0 : 14; /**< Reserved (see MIO_FUS_REPAIR_RES*) */
#else
uint64_t repair0 : 14;
uint64_t repair1 : 14;
uint64_t repair2 : 14;
uint64_t reserved_42_63 : 22;
#endif
} s;
struct cvmx_mio_fus_spr_repair_res_s cn30xx;
struct cvmx_mio_fus_spr_repair_res_s cn31xx;
struct cvmx_mio_fus_spr_repair_res_s cn38xx;
struct cvmx_mio_fus_spr_repair_res_s cn50xx;
struct cvmx_mio_fus_spr_repair_res_s cn52xx;
struct cvmx_mio_fus_spr_repair_res_s cn52xxp1;
struct cvmx_mio_fus_spr_repair_res_s cn56xx;
struct cvmx_mio_fus_spr_repair_res_s cn56xxp1;
struct cvmx_mio_fus_spr_repair_res_s cn58xx;
struct cvmx_mio_fus_spr_repair_res_s cn58xxp1;
struct cvmx_mio_fus_spr_repair_res_s cn63xx;
struct cvmx_mio_fus_spr_repair_res_s cn63xxp1;
};
typedef union cvmx_mio_fus_spr_repair_res cvmx_mio_fus_spr_repair_res_t;
/**
* cvmx_mio_fus_spr_repair_sum
*
* Notes:
* Pass3 Only
*
*/
union cvmx_mio_fus_spr_repair_sum
{
uint64_t u64;
struct cvmx_mio_fus_spr_repair_sum_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_1_63 : 63;
uint64_t too_many : 1; /**< Reserved (see MIO_FUS_REPAIR_RES*) */
#else
uint64_t too_many : 1;
uint64_t reserved_1_63 : 63;
#endif
} s;
struct cvmx_mio_fus_spr_repair_sum_s cn30xx;
struct cvmx_mio_fus_spr_repair_sum_s cn31xx;
struct cvmx_mio_fus_spr_repair_sum_s cn38xx;
struct cvmx_mio_fus_spr_repair_sum_s cn50xx;
struct cvmx_mio_fus_spr_repair_sum_s cn52xx;
struct cvmx_mio_fus_spr_repair_sum_s cn52xxp1;
struct cvmx_mio_fus_spr_repair_sum_s cn56xx;
struct cvmx_mio_fus_spr_repair_sum_s cn56xxp1;
struct cvmx_mio_fus_spr_repair_sum_s cn58xx;
struct cvmx_mio_fus_spr_repair_sum_s cn58xxp1;
struct cvmx_mio_fus_spr_repair_sum_s cn63xx;
struct cvmx_mio_fus_spr_repair_sum_s cn63xxp1;
};
typedef union cvmx_mio_fus_spr_repair_sum cvmx_mio_fus_spr_repair_sum_t;
/**
* cvmx_mio_fus_unlock
*/
union cvmx_mio_fus_unlock
{
uint64_t u64;
struct cvmx_mio_fus_unlock_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_24_63 : 40;
uint64_t key : 24; /**< When set to the typical value, allows SW to
program the efuses */
#else
uint64_t key : 24;
uint64_t reserved_24_63 : 40;
#endif
} s;
struct cvmx_mio_fus_unlock_s cn30xx;
struct cvmx_mio_fus_unlock_s cn31xx;
};
typedef union cvmx_mio_fus_unlock cvmx_mio_fus_unlock_t;
/**
* cvmx_mio_fus_wadr
*/
union cvmx_mio_fus_wadr
{
uint64_t u64;
struct cvmx_mio_fus_wadr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_10_63 : 54;
uint64_t addr : 10; /**< Which of the banks of 128 fuses to blow */
#else
uint64_t addr : 10;
uint64_t reserved_10_63 : 54;
#endif
} s;
struct cvmx_mio_fus_wadr_s cn30xx;
struct cvmx_mio_fus_wadr_s cn31xx;
struct cvmx_mio_fus_wadr_s cn38xx;
struct cvmx_mio_fus_wadr_s cn38xxp2;
struct cvmx_mio_fus_wadr_cn50xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_2_63 : 62;
uint64_t addr : 2; /**< Which of the four banks of 256 fuses to blow */
#else
uint64_t addr : 2;
uint64_t reserved_2_63 : 62;
#endif
} cn50xx;
struct cvmx_mio_fus_wadr_cn52xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_3_63 : 61;
uint64_t addr : 3; /**< Which of the four banks of 256 fuses to blow */
#else
uint64_t addr : 3;
uint64_t reserved_3_63 : 61;
#endif
} cn52xx;
struct cvmx_mio_fus_wadr_cn52xx cn52xxp1;
struct cvmx_mio_fus_wadr_cn52xx cn56xx;
struct cvmx_mio_fus_wadr_cn52xx cn56xxp1;
struct cvmx_mio_fus_wadr_cn50xx cn58xx;
struct cvmx_mio_fus_wadr_cn50xx cn58xxp1;
struct cvmx_mio_fus_wadr_cn63xx
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_4_63 : 60;
uint64_t addr : 4; /**< Which of the banks of 128 fuses to blow */
#else
uint64_t addr : 4;
uint64_t reserved_4_63 : 60;
#endif
} cn63xx;
struct cvmx_mio_fus_wadr_cn63xx cn63xxp1;
};
typedef union cvmx_mio_fus_wadr cvmx_mio_fus_wadr_t;
/**
* cvmx_mio_gpio_comp
*
* MIO_GPIO_COMP = MIO GPIO Compensation Register
*
*/
union cvmx_mio_gpio_comp
{
uint64_t u64;
struct cvmx_mio_gpio_comp_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_12_63 : 52;
uint64_t pctl : 6; /**< GPIO bus PCTL */
uint64_t nctl : 6; /**< GPIO bus NCTL */
#else
uint64_t nctl : 6;
uint64_t pctl : 6;
uint64_t reserved_12_63 : 52;
#endif
} s;
struct cvmx_mio_gpio_comp_s cn63xx;
struct cvmx_mio_gpio_comp_s cn63xxp1;
};
typedef union cvmx_mio_gpio_comp cvmx_mio_gpio_comp_t;
/**
* cvmx_mio_ndf_dma_cfg
*
* MIO_NDF_DMA_CFG = MIO NAND Flash DMA Config Register
*
* SIZE is specified in number of 64 bit transfers (encoded in -1 notation).
*
* ADR must be 64 bit aligned.
*/
union cvmx_mio_ndf_dma_cfg
{
uint64_t u64;
struct cvmx_mio_ndf_dma_cfg_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t en : 1; /**< DMA Engine enable */
uint64_t rw : 1; /**< DMA Engine R/W bit (0 = read, 1 = write) */
uint64_t clr : 1; /**< DMA Engine clear EN on device terminated burst */
uint64_t reserved_60_60 : 1;
uint64_t swap32 : 1; /**< DMA Engine 32 bit swap */
uint64_t swap16 : 1; /**< DMA Engine 16 bit swap */
uint64_t swap8 : 1; /**< DMA Engine 8 bit swap */
uint64_t endian : 1; /**< DMA Engine NCB endian mode (0 = big, 1 = little) */
uint64_t size : 20; /**< DMA Engine size */
uint64_t adr : 36; /**< DMA Engine address */
#else
uint64_t adr : 36;
uint64_t size : 20;
uint64_t endian : 1;
uint64_t swap8 : 1;
uint64_t swap16 : 1;
uint64_t swap32 : 1;
uint64_t reserved_60_60 : 1;
uint64_t clr : 1;
uint64_t rw : 1;
uint64_t en : 1;
#endif
} s;
struct cvmx_mio_ndf_dma_cfg_s cn52xx;
struct cvmx_mio_ndf_dma_cfg_s cn63xx;
struct cvmx_mio_ndf_dma_cfg_s cn63xxp1;
};
typedef union cvmx_mio_ndf_dma_cfg cvmx_mio_ndf_dma_cfg_t;
/**
* cvmx_mio_ndf_dma_int
*
* MIO_NDF_DMA_INT = MIO NAND Flash DMA Interrupt Register
*
*/
union cvmx_mio_ndf_dma_int
{
uint64_t u64;
struct cvmx_mio_ndf_dma_int_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_1_63 : 63;
uint64_t done : 1; /**< DMA Engine request completion interrupt */
#else
uint64_t done : 1;
uint64_t reserved_1_63 : 63;
#endif
} s;
struct cvmx_mio_ndf_dma_int_s cn52xx;
struct cvmx_mio_ndf_dma_int_s cn63xx;
struct cvmx_mio_ndf_dma_int_s cn63xxp1;
};
typedef union cvmx_mio_ndf_dma_int cvmx_mio_ndf_dma_int_t;
/**
* cvmx_mio_ndf_dma_int_en
*
* MIO_NDF_DMA_INT_EN = MIO NAND Flash DMA Interrupt Enable Register
*
*/
union cvmx_mio_ndf_dma_int_en
{
uint64_t u64;
struct cvmx_mio_ndf_dma_int_en_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_1_63 : 63;
uint64_t done : 1; /**< DMA Engine request completion interrupt enable */
#else
uint64_t done : 1;
uint64_t reserved_1_63 : 63;
#endif
} s;
struct cvmx_mio_ndf_dma_int_en_s cn52xx;
struct cvmx_mio_ndf_dma_int_en_s cn63xx;
struct cvmx_mio_ndf_dma_int_en_s cn63xxp1;
};
typedef union cvmx_mio_ndf_dma_int_en cvmx_mio_ndf_dma_int_en_t;
/**
* cvmx_mio_pll_ctl
*/
union cvmx_mio_pll_ctl
{
uint64_t u64;
struct cvmx_mio_pll_ctl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_5_63 : 59;
uint64_t bw_ctl : 5; /**< Core PLL bandwidth control */
#else
uint64_t bw_ctl : 5;
uint64_t reserved_5_63 : 59;
#endif
} s;
struct cvmx_mio_pll_ctl_s cn30xx;
struct cvmx_mio_pll_ctl_s cn31xx;
};
typedef union cvmx_mio_pll_ctl cvmx_mio_pll_ctl_t;
/**
* cvmx_mio_pll_setting
*/
union cvmx_mio_pll_setting
{
uint64_t u64;
struct cvmx_mio_pll_setting_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_17_63 : 47;
uint64_t setting : 17; /**< Core PLL setting */
#else
uint64_t setting : 17;
uint64_t reserved_17_63 : 47;
#endif
} s;
struct cvmx_mio_pll_setting_s cn30xx;
struct cvmx_mio_pll_setting_s cn31xx;
};
typedef union cvmx_mio_pll_setting cvmx_mio_pll_setting_t;
/**
* cvmx_mio_ptp_clock_cfg
*
* MIO_PTP_CLOCK_CFG = Configuration
*
*/
union cvmx_mio_ptp_clock_cfg
{
uint64_t u64;
struct cvmx_mio_ptp_clock_cfg_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_24_63 : 40;
uint64_t evcnt_in : 6; /**< Source for event counter input
0x00-0x0f : GPIO[EVCNT_IN[3:0]]
0x10 : QLM0_REF_CLK
0x11 : QLM1_REF_CLK
0x12 : QLM2_REF_CLK
0x13-0x3f : Reserved */
uint64_t evcnt_edge : 1; /**< Event counter input edge
0 = falling edge
1 = rising edge */
uint64_t evcnt_en : 1; /**< Enable event counter */
uint64_t tstmp_in : 6; /**< Source for timestamp input
0x00-0x0f : GPIO[TSTMP_IN[3:0]]
0x10 : QLM0_REF_CLK
0x11 : QLM1_REF_CLK
0x12 : QLM2_REF_CLK
0x13-0x3f : Reserved */
uint64_t tstmp_edge : 1; /**< External timestamp input edge
0 = falling edge
1 = rising edge */
uint64_t tstmp_en : 1; /**< Enable external timestamp */
uint64_t ext_clk_in : 6; /**< Source for external clock
0x00-0x0f : GPIO[EXT_CLK_IN[3:0]]
0x10 : QLM0_REF_CLK
0x11 : QLM1_REF_CLK
0x12 : QLM2_REF_CLK
0x13-0x3f : Reserved */
uint64_t ext_clk_en : 1; /**< Use positive edge of external clock */
uint64_t ptp_en : 1; /**< Enable PTP Module */
#else
uint64_t ptp_en : 1;
uint64_t ext_clk_en : 1;
uint64_t ext_clk_in : 6;
uint64_t tstmp_en : 1;
uint64_t tstmp_edge : 1;
uint64_t tstmp_in : 6;
uint64_t evcnt_en : 1;
uint64_t evcnt_edge : 1;
uint64_t evcnt_in : 6;
uint64_t reserved_24_63 : 40;
#endif
} s;
struct cvmx_mio_ptp_clock_cfg_s cn63xx;
struct cvmx_mio_ptp_clock_cfg_s cn63xxp1;
};
typedef union cvmx_mio_ptp_clock_cfg cvmx_mio_ptp_clock_cfg_t;
/**
* cvmx_mio_ptp_clock_comp
*
* MIO_PTP_CLOCK_COMP = Compensator
*
*/
union cvmx_mio_ptp_clock_comp
{
uint64_t u64;
struct cvmx_mio_ptp_clock_comp_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t nanosec : 32; /**< Nanoseconds */
uint64_t frnanosec : 32; /**< Fractions of Nanoseconds */
#else
uint64_t frnanosec : 32;
uint64_t nanosec : 32;
#endif
} s;
struct cvmx_mio_ptp_clock_comp_s cn63xx;
struct cvmx_mio_ptp_clock_comp_s cn63xxp1;
};
typedef union cvmx_mio_ptp_clock_comp cvmx_mio_ptp_clock_comp_t;
/**
* cvmx_mio_ptp_clock_hi
*
* MIO_PTP_CLOCK_HI = Hi bytes of CLOCK
*
* Writes to MIO_PTP_CLOCK_HI also clear MIO_PTP_CLOCK_LO. To update all 96 bits, write MIO_PTP_CLOCK_HI followed
* by MIO_PTP_CLOCK_LO
*/
union cvmx_mio_ptp_clock_hi
{
uint64_t u64;
struct cvmx_mio_ptp_clock_hi_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t nanosec : 64; /**< Nanoseconds */
#else
uint64_t nanosec : 64;
#endif
} s;
struct cvmx_mio_ptp_clock_hi_s cn63xx;
struct cvmx_mio_ptp_clock_hi_s cn63xxp1;
};
typedef union cvmx_mio_ptp_clock_hi cvmx_mio_ptp_clock_hi_t;
/**
* cvmx_mio_ptp_clock_lo
*
* MIO_PTP_CLOCK_LO = Lo bytes of CLOCK
*
*/
union cvmx_mio_ptp_clock_lo
{
uint64_t u64;
struct cvmx_mio_ptp_clock_lo_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_32_63 : 32;
uint64_t frnanosec : 32; /**< Fractions of Nanoseconds */
#else
uint64_t frnanosec : 32;
uint64_t reserved_32_63 : 32;
#endif
} s;
struct cvmx_mio_ptp_clock_lo_s cn63xx;
struct cvmx_mio_ptp_clock_lo_s cn63xxp1;
};
typedef union cvmx_mio_ptp_clock_lo cvmx_mio_ptp_clock_lo_t;
/**
* cvmx_mio_ptp_evt_cnt
*
* MIO_PTP_EVT_CNT = Event Counter
*
* Writes to MIO_PTP_EVT_CNT increment this register by the written data. The register counts down by
* 1 for every MIO_PTP_CLOCK_CFG[EVCNT_EDGE] edge of MIO_PTP_CLOCK_CFG[EVCNT_IN]. When register equals
* 0, an interrupt gets gerated
*/
union cvmx_mio_ptp_evt_cnt
{
uint64_t u64;
struct cvmx_mio_ptp_evt_cnt_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t cntr : 64; /**< Nanoseconds */
#else
uint64_t cntr : 64;
#endif
} s;
struct cvmx_mio_ptp_evt_cnt_s cn63xx;
struct cvmx_mio_ptp_evt_cnt_s cn63xxp1;
};
typedef union cvmx_mio_ptp_evt_cnt cvmx_mio_ptp_evt_cnt_t;
/**
* cvmx_mio_ptp_timestamp
*
* MIO_PTP_TIMESTAMP = Timestamp latched on MIO_PTP_CLOCK_CFG[TSTMP_EDGE] edge of MIO_PTP_CLOCK_CFG[TSTMP_IN]
*
*/
union cvmx_mio_ptp_timestamp
{
uint64_t u64;
struct cvmx_mio_ptp_timestamp_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t nanosec : 64; /**< Nanoseconds */
#else
uint64_t nanosec : 64;
#endif
} s;
struct cvmx_mio_ptp_timestamp_s cn63xx;
struct cvmx_mio_ptp_timestamp_s cn63xxp1;
};
typedef union cvmx_mio_ptp_timestamp cvmx_mio_ptp_timestamp_t;
/**
* cvmx_mio_rst_boot
*/
union cvmx_mio_rst_boot
{
uint64_t u64;
struct cvmx_mio_rst_boot_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_36_63 : 28;
uint64_t c_mul : 6; /**< Core clock multiplier:
C_MUL = (core clk speed) / (ref clock speed)
"ref clock speed" should always be 50MHz.
If PLL_QLM_REF_CLK_EN=0, "ref clock" comes
from PLL_REF_CLK pin.
If PLL_QLM_REF_CLK_EN=1, "ref clock" is
1/2 speed of QLMC_REF_CLK_* pins. */
uint64_t pnr_mul : 6; /**< Coprocessor clock multiplier:
PNR_MUL = (coprocessor clk speed) /
(ref clock speed)
See C_MUL comments about ref clock. */
uint64_t qlm2_spd : 4; /**< QLM2_SPD pins sampled at DCOK assertion */
uint64_t qlm1_spd : 4; /**< QLM1_SPD pins sampled at DCOK assertion */
uint64_t qlm0_spd : 4; /**< QLM0_SPD pins sampled at DCOK assertion */
uint64_t lboot : 10; /**< Last boot cause mask, resets only with dock.
bit9 - Soft reset due to watchdog
bit8 - Soft reset due to CIU_SOFT_RST write
bit7 - Warm reset due to cntl0 link-down or
hot-reset
bit6 - Warm reset due to cntl1 link-down or
hot-reset
bit5 - Cntl1 reset due to PERST1_L pin
bit4 - Cntl0 reset due to PERST0_L pin
bit3 - Warm reset due to PERST1_L pin
bit2 - Warm reset due to PERST0_L pin
bit1 - Warm reset due to CHIP_RESET_L pin
bit0 - Cold reset due to DCOK pin */
uint64_t rboot : 1; /**< Determines whether core 0 remains in reset after
after chip cold/warm/soft reset. */
uint64_t rboot_pin : 1; /**< Read-only access to REMOTE_BOOT pin */
#else
uint64_t rboot_pin : 1;
uint64_t rboot : 1;
uint64_t lboot : 10;
uint64_t qlm0_spd : 4;
uint64_t qlm1_spd : 4;
uint64_t qlm2_spd : 4;
uint64_t pnr_mul : 6;
uint64_t c_mul : 6;
uint64_t reserved_36_63 : 28;
#endif
} s;
struct cvmx_mio_rst_boot_s cn63xx;
struct cvmx_mio_rst_boot_s cn63xxp1;
};
typedef union cvmx_mio_rst_boot cvmx_mio_rst_boot_t;
/**
* cvmx_mio_rst_cfg
*
* Notes:
* Cold reset will always performs a full bist.
*
*/
union cvmx_mio_rst_cfg
{
uint64_t u64;
struct cvmx_mio_rst_cfg_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t bist_delay : 58; /**< Reserved */
uint64_t reserved_3_5 : 3;
uint64_t cntl_clr_bist : 1; /**< Peform clear bist during cntl only reset,
instead of a full bist. A warm/soft reset will
not change this field. */
uint64_t warm_clr_bist : 1; /**< Peform clear bist during warm reset, instead
of a full bist. A warm/soft reset will not
change this field. */
uint64_t soft_clr_bist : 1; /**< Peform clear bist during soft reset, instead
of a full bist. A warm/soft reset will not
change this field. */
#else
uint64_t soft_clr_bist : 1;
uint64_t warm_clr_bist : 1;
uint64_t cntl_clr_bist : 1;
uint64_t reserved_3_5 : 3;
uint64_t bist_delay : 58;
#endif
} s;
struct cvmx_mio_rst_cfg_s cn63xx;
struct cvmx_mio_rst_cfg_cn63xxp1
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t bist_delay : 58; /**< Reserved */
uint64_t reserved_2_5 : 4;
uint64_t warm_clr_bist : 1; /**< Peform clear bist during warm reset, instead
of a full bist. A warm/soft reset will not
change this field. */
uint64_t soft_clr_bist : 1; /**< Peform clear bist during soft reset, instead
of a full bist. A warm/soft reset will not
change this field. */
#else
uint64_t soft_clr_bist : 1;
uint64_t warm_clr_bist : 1;
uint64_t reserved_2_5 : 4;
uint64_t bist_delay : 58;
#endif
} cn63xxp1;
};
typedef union cvmx_mio_rst_cfg cvmx_mio_rst_cfg_t;
/**
* cvmx_mio_rst_ctl#
*/
union cvmx_mio_rst_ctlx
{
uint64_t u64;
struct cvmx_mio_rst_ctlx_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_10_63 : 54;
uint64_t prst_link : 1; /**< Controls whether corresponding controller
link-down or hot-reset causes the assertion of
CIU_SOFT_PRST*[SOFT_PRST]
A warm/soft reset will not change this field.
On cold reset, this field is initialized to 0
follows:
0 = when corresponding strap QLM*_HOST_MODE=1
1 = when corresponding strap QLM*_HOST_MODE=0
***NOTE: Added in pass 2.0 */
uint64_t rst_done : 1; /**< Read-only access to controller reset status
RESET_DONE is always zero (i.e. the controller
is held in reset) when:
- CIU_SOFT_PRST*[SOFT_PRST]=1, or
- RST_RCV==1 and PERST*_L pin is asserted */
uint64_t rst_link : 1; /**< Controls whether corresponding controller
link-down or hot-reset causes a warm chip reset
On cold reset, this field is initialized as
follows:
0 = when corresponding strap QLM*_HOST_MODE=1
1 = when corresponding strap QLM*_HOST_MODE=0
Note that a link-down or hot-reset event can
never cause a warm chip reset when the
controller is in reset (i.e. can never cause a
warm reset when RST_DONE==0). */
uint64_t host_mode : 1; /**< RO access to corresponding strap QLM*_HOST_MODE */
uint64_t prtmode : 2; /**< Port mode
0 = port is EP mode
1 = port is RC mode
2,3 = Reserved
A warm/soft reset will not change this field.
On cold reset, this field is initialized as
follows:
0 = when corresponding strap QLM*_HOST_MODE=0
1 = when corresponding strap QLM*_HOST_MODE=1 */
uint64_t rst_drv : 1; /**< Controls whether corresponding PERST*_L chip pin
is driven by the OCTEON. A warm/soft reset
will not change this field. On cold reset,
this field is initialized as follows:
0 = when corresponding strap QLM*_HOST_MODE=0
1 = when corresponding strap QLM*_HOST_MODE=1
When set, OCTEON drives the corresponding
PERST*_L pin. Otherwise, OCTEON does not drive
the corresponding PERST*_L pin. */
uint64_t rst_rcv : 1; /**< Controls whether corresponding PERST*_L chip pin
is recieved by OCTEON. A warm/soft reset
will not change this field. On cold reset,
this field is initialized as follows:
0 = when corresponding strap QLM*_HOST_MODE=1
1 = when corresponding strap QLM*_HOST_MODE=0
When RST_RCV==1, the PERST*_L value is
received and may be used to reset the
controller and (optionally, based on RST_CHIP)
warm reset the chip.
When RST_RCV==1 (and RST_CHIP=0),
MIO_RST_INT[PERST*] gets set when the PERST*_L
pin asserts. (This interrupt can alert SW
whenever the external reset pin initiates a
controller reset sequence.)
RST_VAL gives the PERST*_L pin value when
RST_RCV==1.
When RST_RCV==0, the PERST*_L pin value is
ignored. */
uint64_t rst_chip : 1; /**< Controls whether corresponding PERST*_L chip
pin causes a chip warm reset like CHIP_RESET_L.
A warm/soft reset will not change this field.
On cold reset, this field is initialized to 0.
RST_CHIP is not used when RST_RCV==0.
When RST_RCV==0, RST_CHIP is ignored.
When RST_RCV==1, RST_CHIP==1, and PERST*_L
asserts, a chip warm reset will be generated. */
uint64_t rst_val : 1; /**< Read-only access to corresponding PERST*_L pin
Unpredictable when RST_RCV==0. Reads as 1 when
RST_RCV==1 and the PERST*_L pin is asserted.
Reads as 0 when RST_RCV==1 and the PERST*_L
pin is not asserted. */
#else
uint64_t rst_val : 1;
uint64_t rst_chip : 1;
uint64_t rst_rcv : 1;
uint64_t rst_drv : 1;
uint64_t prtmode : 2;
uint64_t host_mode : 1;
uint64_t rst_link : 1;
uint64_t rst_done : 1;
uint64_t prst_link : 1;
uint64_t reserved_10_63 : 54;
#endif
} s;
struct cvmx_mio_rst_ctlx_s cn63xx;
struct cvmx_mio_rst_ctlx_cn63xxp1
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_9_63 : 55;
uint64_t rst_done : 1; /**< Read-only access to controller reset status
RESET_DONE is always zero (i.e. the controller
is held in reset) when:
- CIU_SOFT_PRST*[SOFT_PRST]=1, or
- RST_RCV==1 and PERST*_L pin is asserted */
uint64_t rst_link : 1; /**< Controls whether corresponding controller
link-down or hot-reset causes a warm chip reset
On cold reset, this field is initialized as
follows:
0 = when corresponding strap QLM*_HOST_MODE=1
1 = when corresponding strap QLM*_HOST_MODE=0
Note that a link-down or hot-reset event can
never cause a warm chip reset when the
controller is in reset (i.e. can never cause a
warm reset when RST_DONE==0). */
uint64_t host_mode : 1; /**< RO access to corresponding strap QLM*_HOST_MODE */
uint64_t prtmode : 2; /**< Port mode
0 = port is EP mode
1 = port is RC mode
2,3 = Reserved
A warm/soft reset will not change this field.
On cold reset, this field is initialized as
follows:
0 = when corresponding strap QLM*_HOST_MODE=0
1 = when corresponding strap QLM*_HOST_MODE=1 */
uint64_t rst_drv : 1; /**< Controls whether corresponding PERST*_L chip pin
is driven by the OCTEON. A warm/soft reset
will not change this field. On cold reset,
this field is initialized as follows:
0 = when corresponding strap QLM*_HOST_MODE=0
1 = when corresponding strap QLM*_HOST_MODE=1
When set, OCTEON drives the corresponding
PERST*_L pin. Otherwise, OCTEON does not drive
the corresponding PERST*_L pin. */
uint64_t rst_rcv : 1; /**< Controls whether corresponding PERST*_L chip pin
is recieved by OCTEON. A warm/soft reset
will not change this field. On cold reset,
this field is initialized as follows:
0 = when corresponding strap QLM*_HOST_MODE=1
1 = when corresponding strap QLM*_HOST_MODE=0
When RST_RCV==1, the PERST*_L value is
received and may be used to reset the
controller and (optionally, based on RST_CHIP)
warm reset the chip.
When RST_RCV==1 (and RST_CHIP=0),
MIO_RST_INT[PERST*] gets set when the PERST*_L
pin asserts. (This interrupt can alert SW
whenever the external reset pin initiates a
controller reset sequence.)
RST_VAL gives the PERST*_L pin value when
RST_RCV==1.
When RST_RCV==0, the PERST*_L pin value is
ignored. */
uint64_t rst_chip : 1; /**< Controls whether corresponding PERST*_L chip
pin causes a chip warm reset like CHIP_RESET_L.
A warm/soft reset will not change this field.
On cold reset, this field is initialized to 0.
RST_CHIP is not used when RST_RCV==0.
When RST_RCV==0, RST_CHIP is ignored.
When RST_RCV==1, RST_CHIP==1, and PERST*_L
asserts, a chip warm reset will be generated. */
uint64_t rst_val : 1; /**< Read-only access to corresponding PERST*_L pin
Unpredictable when RST_RCV==0. Reads as 1 when
RST_RCV==1 and the PERST*_L pin is asserted.
Reads as 0 when RST_RCV==1 and the PERST*_L
pin is not asserted. */
#else
uint64_t rst_val : 1;
uint64_t rst_chip : 1;
uint64_t rst_rcv : 1;
uint64_t rst_drv : 1;
uint64_t prtmode : 2;
uint64_t host_mode : 1;
uint64_t rst_link : 1;
uint64_t rst_done : 1;
uint64_t reserved_9_63 : 55;
#endif
} cn63xxp1;
};
typedef union cvmx_mio_rst_ctlx cvmx_mio_rst_ctlx_t;
/**
* cvmx_mio_rst_delay
*/
union cvmx_mio_rst_delay
{
uint64_t u64;
struct cvmx_mio_rst_delay_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_32_63 : 32;
uint64_t soft_rst_dly : 16; /**< A soft reset immediately causes an early soft
reset notification. However, the assertion of
soft reset will be delayed this many sclks.
A warm/soft reset will not change this field.
NOTE: This must be at least 500 dclks */
uint64_t warm_rst_dly : 16; /**< A warm reset immediately causes an early warm
reset notification. However, the assertion of
warm reset will be delayed this many sclks.
A warm/soft reset will not change this field.
NOTE: This must be at least 500 dclks */
#else
uint64_t warm_rst_dly : 16;
uint64_t soft_rst_dly : 16;
uint64_t reserved_32_63 : 32;
#endif
} s;
struct cvmx_mio_rst_delay_s cn63xx;
struct cvmx_mio_rst_delay_s cn63xxp1;
};
typedef union cvmx_mio_rst_delay cvmx_mio_rst_delay_t;
/**
* cvmx_mio_rst_int
*
* MIO_RST_INT = MIO Reset Interrupt Register
*
*/
union cvmx_mio_rst_int
{
uint64_t u64;
struct cvmx_mio_rst_int_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_10_63 : 54;
uint64_t perst1 : 1; /**< PERST1_L asserted while MIO_RST_CTL1[RST_RCV]=1
and MIO_RST_CTL1[RST_CHIP]=0 */
uint64_t perst0 : 1; /**< PERST0_L asserted while MIO_RST_CTL0[RST_RCV]=1
and MIO_RST_CTL0[RST_CHIP]=0 */
uint64_t reserved_2_7 : 6;
uint64_t rst_link1 : 1; /**< A controller1 link-down/hot-reset occurred while
MIO_RST_CTL1[RST_LINK]=0. Software must assert
then de-assert CIU_SOFT_PRST1[SOFT_PRST] */
uint64_t rst_link0 : 1; /**< A controller0 link-down/hot-reset occurred while
MIO_RST_CTL0[RST_LINK]=0. Software must assert
then de-assert CIU_SOFT_PRST[SOFT_PRST] */
#else
uint64_t rst_link0 : 1;
uint64_t rst_link1 : 1;
uint64_t reserved_2_7 : 6;
uint64_t perst0 : 1;
uint64_t perst1 : 1;
uint64_t reserved_10_63 : 54;
#endif
} s;
struct cvmx_mio_rst_int_s cn63xx;
struct cvmx_mio_rst_int_s cn63xxp1;
};
typedef union cvmx_mio_rst_int cvmx_mio_rst_int_t;
/**
* cvmx_mio_rst_int_en
*
* MIO_RST_INT_EN = MIO Reset Interrupt Enable Register
*
*/
union cvmx_mio_rst_int_en
{
uint64_t u64;
struct cvmx_mio_rst_int_en_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_10_63 : 54;
uint64_t perst1 : 1; /**< Controller1 PERST reset interrupt enable */
uint64_t perst0 : 1; /**< Controller0 PERST reset interrupt enable */
uint64_t reserved_2_7 : 6;
uint64_t rst_link1 : 1; /**< Controller1 link-down/hot reset interrupt enable */
uint64_t rst_link0 : 1; /**< Controller0 link-down/hot reset interrupt enable */
#else
uint64_t rst_link0 : 1;
uint64_t rst_link1 : 1;
uint64_t reserved_2_7 : 6;
uint64_t perst0 : 1;
uint64_t perst1 : 1;
uint64_t reserved_10_63 : 54;
#endif
} s;
struct cvmx_mio_rst_int_en_s cn63xx;
struct cvmx_mio_rst_int_en_s cn63xxp1;
};
typedef union cvmx_mio_rst_int_en cvmx_mio_rst_int_en_t;
/**
* cvmx_mio_tws#_int
*
* MIO_TWSX_INT = TWSX Interrupt Register
*
* This register contains the TWSI interrupt enable mask and the interrupt source bits. Note: the
* interrupt source bit for the TWSI core interrupt (CORE_INT) is read-only, the appropriate sequence
* must be written to the TWSI core to clear this interrupt. The other interrupt source bits are write-
* one-to-clear. TS_INT is set on the update of the MIO_TWS_TWSI_SW register (i.e. when it is written
* by a TWSI device). ST_INT is set whenever the valid bit of the MIO_TWS_SW_TWSI is cleared (see above
* for reasons).
*
* Note: When using the high-level controller, CORE_EN should be clear and CORE_INT should be ignored.
* Conversely, when the high-level controller is disabled, ST_EN / TS_EN should be clear and ST_INT /
* TS_INT should be ignored.
*
* This register also contains a read-only copy of the TWSI bus (SCL and SDA) as well as control bits to
* override the current state of the TWSI bus (SCL_OVR and SDA_OVR). Setting an override bit high will
* result in the open drain driver being activated, thus driving the corresponding signal low.
*/
union cvmx_mio_twsx_int
{
uint64_t u64;
struct cvmx_mio_twsx_int_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_12_63 : 52;
uint64_t scl : 1; /**< SCL */
uint64_t sda : 1; /**< SDA */
uint64_t scl_ovr : 1; /**< SCL override */
uint64_t sda_ovr : 1; /**< SDA override */
uint64_t reserved_7_7 : 1;
uint64_t core_en : 1; /**< TWSI core interrupt enable */
uint64_t ts_en : 1; /**< MIO_TWS_TWSI_SW register update interrupt enable */
uint64_t st_en : 1; /**< MIO_TWS_SW_TWSI register update interrupt enable */
uint64_t reserved_3_3 : 1;
uint64_t core_int : 1; /**< TWSI core interrupt */
uint64_t ts_int : 1; /**< MIO_TWS_TWSI_SW register update interrupt */
uint64_t st_int : 1; /**< MIO_TWS_SW_TWSI register update interrupt */
#else
uint64_t st_int : 1;
uint64_t ts_int : 1;
uint64_t core_int : 1;
uint64_t reserved_3_3 : 1;
uint64_t st_en : 1;
uint64_t ts_en : 1;
uint64_t core_en : 1;
uint64_t reserved_7_7 : 1;
uint64_t sda_ovr : 1;
uint64_t scl_ovr : 1;
uint64_t sda : 1;
uint64_t scl : 1;
uint64_t reserved_12_63 : 52;
#endif
} s;
struct cvmx_mio_twsx_int_s cn30xx;
struct cvmx_mio_twsx_int_s cn31xx;
struct cvmx_mio_twsx_int_s cn38xx;
struct cvmx_mio_twsx_int_cn38xxp2
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_7_63 : 57;
uint64_t core_en : 1; /**< TWSI core interrupt enable */
uint64_t ts_en : 1; /**< MIO_TWS_TWSI_SW register update interrupt enable */
uint64_t st_en : 1; /**< MIO_TWS_SW_TWSI register update interrupt enable */
uint64_t reserved_3_3 : 1;
uint64_t core_int : 1; /**< TWSI core interrupt */
uint64_t ts_int : 1; /**< MIO_TWS_TWSI_SW register update interrupt */
uint64_t st_int : 1; /**< MIO_TWS_SW_TWSI register update interrupt */
#else
uint64_t st_int : 1;
uint64_t ts_int : 1;
uint64_t core_int : 1;
uint64_t reserved_3_3 : 1;
uint64_t st_en : 1;
uint64_t ts_en : 1;
uint64_t core_en : 1;
uint64_t reserved_7_63 : 57;
#endif
} cn38xxp2;
struct cvmx_mio_twsx_int_s cn50xx;
struct cvmx_mio_twsx_int_s cn52xx;
struct cvmx_mio_twsx_int_s cn52xxp1;
struct cvmx_mio_twsx_int_s cn56xx;
struct cvmx_mio_twsx_int_s cn56xxp1;
struct cvmx_mio_twsx_int_s cn58xx;
struct cvmx_mio_twsx_int_s cn58xxp1;
struct cvmx_mio_twsx_int_s cn63xx;
struct cvmx_mio_twsx_int_s cn63xxp1;
};
typedef union cvmx_mio_twsx_int cvmx_mio_twsx_int_t;
/**
* cvmx_mio_tws#_sw_twsi
*
* MIO_TWSX_SW_TWSI = TWSX Software to TWSI Register
*
* This register allows software to
* - initiate TWSI interface master-mode operations with a write and read the result with a read
* - load four bytes for later retrieval (slave mode) with a write and check validity with a read
* - launch a TWSI controller configuration read/write with a write and read the result with a read
*
* This register should be read or written by software, and read by the TWSI device. The TWSI device can
* use either two-byte or five-byte reads to reference this register.
*
* The TWSI device considers this register valid when V==1 and SLONLY==1.
*/
union cvmx_mio_twsx_sw_twsi
{
uint64_t u64;
struct cvmx_mio_twsx_sw_twsi_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t v : 1; /**< Valid bit
- Set on a write (should always be written with
a 1)
- Cleared when a TWSI master mode op completes
- Cleared when a TWSI configuration register
access completes
- Cleared when the TWSI device reads the
register if SLONLY==1 */
uint64_t slonly : 1; /**< Slave Only Mode
- No operation is initiated with a write when
this bit is set - only D field is updated in
this case
- When clear, a write initiates either a TWSI
master-mode operation or a TWSI configuration
register access */
uint64_t eia : 1; /**< Extended Internal Address - send additional
internal address byte (MSB of IA is from IA field
of MIO_TWS_SW_TWSI_EXT) */
uint64_t op : 4; /**< Opcode field - When the register is written with
SLONLY==0, initiate a read or write:
0000 => 7-bit Byte Master Mode TWSI Op
0001 => 7-bit Byte Combined Read Master Mode Op
7-bit Byte Write w/ IA Master Mode Op
0010 => 10-bit Byte Master Mode TWSI Op
0011 => 10-bit Byte Combined Read Master Mode Op
10-bit Byte Write w/ IA Master Mode Op
0100 => TWSI Master Clock Register
0110 => See EOP field
1000 => 7-bit 4-byte Master Mode TWSI Op
1001 => 7-bit 4-byte Comb. Read Master Mode Op
7-bit 4-byte Write w/ IA Master Mode Op
1010 => 10-bit 4-byte Master Mode TWSI Op
1011 => 10-bit 4-byte Comb. Read Master Mode Op
10-bit 4-byte Write w/ IA Master Mode Op */
uint64_t r : 1; /**< Read bit or result
- If set on a write when SLONLY==0, the
operation is a read
- On a read, this bit returns the result
indication for the most recent master mode
operation (1 = success, 0 = fail) */
uint64_t sovr : 1; /**< Size Override - if set, use the SIZE field to
determine Master Mode Op size rather than what
the Opcode field specifies. For operations
greater than 4 bytes, the additional data will be
contained in the D field of MIO_TWS_SW_TWSI_EXT */
uint64_t size : 3; /**< Size in bytes of Master Mode Op if the Size
Override bit is set. Specified in -1 notation
(i.e. 0 = 1 byte, 1 = 2 bytes ... 7 = 8 bytes) */
uint64_t scr : 2; /**< Scratch - unused, but retain state */
uint64_t a : 10; /**< Address field
- the address of the remote device for a master
mode operation
- A<9:7> are only used for 10-bit addressing
Note that when mastering a 7-bit OP, A<6:0> should
not take any of the values 0x78, 0x79, 0x7A nor
0x7B (these 7-bit addresses are reserved to
extend to 10-bit addressing). */
uint64_t ia : 5; /**< Internal Address - Used when launching a master
mode combined read / write with internal address
(lower 3 bits are contained in the EOP_IA field) */
uint64_t eop_ia : 3; /**< Extra opcode (when OP<3:0> == 0110 and SLONLY==0):
000 => TWSI Slave Address Register
001 => TWSI Data Register
010 => TWSI Control Register
011 => TWSI Clock Control Register (when R == 0)
011 => TWSI Status Register (when R == 1)
100 => TWSI Extended Slave Register
111 => TWSI Soft Reset Register
Also the lower 3 bits of Internal Address when
launching a master mode combined read / write
with internal address */
uint64_t d : 32; /**< Data Field
Used on a write when
- initiating a master-mode write (SLONLY==0)
- writing a TWSI config register (SLONLY==0)
- a slave mode write (SLONLY==1)
The read value is updated by
- a write to this register
- master mode completion (contains result or
error code)
- TWSI config register read (contains result) */
#else
uint64_t d : 32;
uint64_t eop_ia : 3;
uint64_t ia : 5;
uint64_t a : 10;
uint64_t scr : 2;
uint64_t size : 3;
uint64_t sovr : 1;
uint64_t r : 1;
uint64_t op : 4;
uint64_t eia : 1;
uint64_t slonly : 1;
uint64_t v : 1;
#endif
} s;
struct cvmx_mio_twsx_sw_twsi_s cn30xx;
struct cvmx_mio_twsx_sw_twsi_s cn31xx;
struct cvmx_mio_twsx_sw_twsi_s cn38xx;
struct cvmx_mio_twsx_sw_twsi_s cn38xxp2;
struct cvmx_mio_twsx_sw_twsi_s cn50xx;
struct cvmx_mio_twsx_sw_twsi_s cn52xx;
struct cvmx_mio_twsx_sw_twsi_s cn52xxp1;
struct cvmx_mio_twsx_sw_twsi_s cn56xx;
struct cvmx_mio_twsx_sw_twsi_s cn56xxp1;
struct cvmx_mio_twsx_sw_twsi_s cn58xx;
struct cvmx_mio_twsx_sw_twsi_s cn58xxp1;
struct cvmx_mio_twsx_sw_twsi_s cn63xx;
struct cvmx_mio_twsx_sw_twsi_s cn63xxp1;
};
typedef union cvmx_mio_twsx_sw_twsi cvmx_mio_twsx_sw_twsi_t;
/**
* cvmx_mio_tws#_sw_twsi_ext
*
* MIO_TWSX_SW_TWSI_EXT = TWSX Software to TWSI Extension Register
*
* This register contains an additional byte of internal address and 4 additional bytes of data to be
* used with TWSI master mode operations. IA will be sent as the first byte of internal address when
* performing master mode combined read / write with internal address operations and the EIA bit of
* MIO_TWS_SW_TWSI is set. D extends the data field of MIO_TWS_SW_TWSI for a total of 8 bytes (SOVR
* must be set to perform operations greater than 4 bytes).
*/
union cvmx_mio_twsx_sw_twsi_ext
{
uint64_t u64;
struct cvmx_mio_twsx_sw_twsi_ext_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_40_63 : 24;
uint64_t ia : 8; /**< Extended Internal Address */
uint64_t d : 32; /**< Extended Data Field */
#else
uint64_t d : 32;
uint64_t ia : 8;
uint64_t reserved_40_63 : 24;
#endif
} s;
struct cvmx_mio_twsx_sw_twsi_ext_s cn30xx;
struct cvmx_mio_twsx_sw_twsi_ext_s cn31xx;
struct cvmx_mio_twsx_sw_twsi_ext_s cn38xx;
struct cvmx_mio_twsx_sw_twsi_ext_s cn38xxp2;
struct cvmx_mio_twsx_sw_twsi_ext_s cn50xx;
struct cvmx_mio_twsx_sw_twsi_ext_s cn52xx;
struct cvmx_mio_twsx_sw_twsi_ext_s cn52xxp1;
struct cvmx_mio_twsx_sw_twsi_ext_s cn56xx;
struct cvmx_mio_twsx_sw_twsi_ext_s cn56xxp1;
struct cvmx_mio_twsx_sw_twsi_ext_s cn58xx;
struct cvmx_mio_twsx_sw_twsi_ext_s cn58xxp1;
struct cvmx_mio_twsx_sw_twsi_ext_s cn63xx;
struct cvmx_mio_twsx_sw_twsi_ext_s cn63xxp1;
};
typedef union cvmx_mio_twsx_sw_twsi_ext cvmx_mio_twsx_sw_twsi_ext_t;
/**
* cvmx_mio_tws#_twsi_sw
*
* MIO_TWSX_TWSI_SW = TWSX TWSI to Software Register
*
* This register allows the TWSI device to transfer data to software and later check that software has
* received the information.
*
* This register should be read or written by the TWSI device, and read by software. The TWSI device can
* use one-byte or four-byte payload writes, and two-byte payload reads.
*
* The TWSI device considers this register valid when V==1.
*/
union cvmx_mio_twsx_twsi_sw
{
uint64_t u64;
struct cvmx_mio_twsx_twsi_sw_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t v : 2; /**< Valid Bits
- Not directly writable
- Set to 1 on any write by the TWSI device
- Cleared on any read by software */
uint64_t reserved_32_61 : 30;
uint64_t d : 32; /**< Data Field - updated on a write by the TWSI device */
#else
uint64_t d : 32;
uint64_t reserved_32_61 : 30;
uint64_t v : 2;
#endif
} s;
struct cvmx_mio_twsx_twsi_sw_s cn30xx;
struct cvmx_mio_twsx_twsi_sw_s cn31xx;
struct cvmx_mio_twsx_twsi_sw_s cn38xx;
struct cvmx_mio_twsx_twsi_sw_s cn38xxp2;
struct cvmx_mio_twsx_twsi_sw_s cn50xx;
struct cvmx_mio_twsx_twsi_sw_s cn52xx;
struct cvmx_mio_twsx_twsi_sw_s cn52xxp1;
struct cvmx_mio_twsx_twsi_sw_s cn56xx;
struct cvmx_mio_twsx_twsi_sw_s cn56xxp1;
struct cvmx_mio_twsx_twsi_sw_s cn58xx;
struct cvmx_mio_twsx_twsi_sw_s cn58xxp1;
struct cvmx_mio_twsx_twsi_sw_s cn63xx;
struct cvmx_mio_twsx_twsi_sw_s cn63xxp1;
};
typedef union cvmx_mio_twsx_twsi_sw cvmx_mio_twsx_twsi_sw_t;
/**
* cvmx_mio_uart#_dlh
*
* MIO_UARTX_DLH = MIO UARTX Divisor Latch High Register
*
* The DLH (Divisor Latch High) register in conjunction with DLL (Divisor Latch Low) register form a
* 16-bit, read/write, Divisor Latch register that contains the baud rate divisor for the UART. It is
* accessed by first setting the DLAB bit (bit 7) in the Line Control Register (LCR). The output baud
* rate is equal to eclk frequency divided by sixteen times the value of the baud rate divisor, as
* follows: baud rate = eclk / (16 * divisor).
*
* Note that the BUSY bit (bit 0) of the UART Status Register (USR) must be clear before writing this
* register. BUSY bit is always clear in PASS3.
*
* Note that with the Divisor Latch Registers (DLL and DLH) set to zero, the baud clock is disabled
* and no serial communications will occur. Also, once the DLL or DLH is set, at least 8 clock cycles
* of eclk should be allowed to pass before transmitting or receiving data.
*
* Note: The address below is an alias to simplify these CSR descriptions. It should be known that the
* IER and DLH registers are the same.
*/
union cvmx_mio_uartx_dlh
{
uint64_t u64;
struct cvmx_mio_uartx_dlh_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t dlh : 8; /**< Divisor Latch High Register */
#else
uint64_t dlh : 8;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uartx_dlh_s cn30xx;
struct cvmx_mio_uartx_dlh_s cn31xx;
struct cvmx_mio_uartx_dlh_s cn38xx;
struct cvmx_mio_uartx_dlh_s cn38xxp2;
struct cvmx_mio_uartx_dlh_s cn50xx;
struct cvmx_mio_uartx_dlh_s cn52xx;
struct cvmx_mio_uartx_dlh_s cn52xxp1;
struct cvmx_mio_uartx_dlh_s cn56xx;
struct cvmx_mio_uartx_dlh_s cn56xxp1;
struct cvmx_mio_uartx_dlh_s cn58xx;
struct cvmx_mio_uartx_dlh_s cn58xxp1;
struct cvmx_mio_uartx_dlh_s cn63xx;
struct cvmx_mio_uartx_dlh_s cn63xxp1;
};
typedef union cvmx_mio_uartx_dlh cvmx_mio_uartx_dlh_t;
typedef cvmx_mio_uartx_dlh_t cvmx_uart_dlh_t;
/**
* cvmx_mio_uart#_dll
*
* MIO_UARTX_DLL = MIO UARTX Divisor Latch Low Register
*
* The DLH (Divisor Latch High) register in conjunction with DLL (Divisor Latch Low) register form a
* 16-bit, read/write, Divisor Latch register that contains the baud rate divisor for the UART. It is
* accessed by first setting the DLAB bit (bit 7) in the Line Control Register (LCR). The output baud
* rate is equal to eclk frequency divided by sixteen times the value of the baud rate divisor, as
* follows: baud rate = eclk / (16 * divisor).
*
* Note that the BUSY bit (bit 0) of the UART Status Register (USR) must be clear before writing this
* register. BUSY bit is always clear in PASS3.
*
* Note that with the Divisor Latch Registers (DLL and DLH) set to zero, the baud clock is disabled
* and no serial communications will occur. Also, once the DLL or DLH is set, at least 8 clock cycles
* of eclk should be allowed to pass before transmitting or receiving data.
*
* Note: The address below is an alias to simplify these CSR descriptions. It should be known that the
* RBR, THR, and DLL registers are the same.
*/
union cvmx_mio_uartx_dll
{
uint64_t u64;
struct cvmx_mio_uartx_dll_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t dll : 8; /**< Divisor Latch Low Register */
#else
uint64_t dll : 8;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uartx_dll_s cn30xx;
struct cvmx_mio_uartx_dll_s cn31xx;
struct cvmx_mio_uartx_dll_s cn38xx;
struct cvmx_mio_uartx_dll_s cn38xxp2;
struct cvmx_mio_uartx_dll_s cn50xx;
struct cvmx_mio_uartx_dll_s cn52xx;
struct cvmx_mio_uartx_dll_s cn52xxp1;
struct cvmx_mio_uartx_dll_s cn56xx;
struct cvmx_mio_uartx_dll_s cn56xxp1;
struct cvmx_mio_uartx_dll_s cn58xx;
struct cvmx_mio_uartx_dll_s cn58xxp1;
struct cvmx_mio_uartx_dll_s cn63xx;
struct cvmx_mio_uartx_dll_s cn63xxp1;
};
typedef union cvmx_mio_uartx_dll cvmx_mio_uartx_dll_t;
typedef cvmx_mio_uartx_dll_t cvmx_uart_dll_t;
/**
* cvmx_mio_uart#_far
*
* MIO_UARTX_FAR = MIO UARTX FIFO Access Register
*
* The FIFO Access Register (FAR) is used to enable a FIFO access mode for testing, so that the receive
* FIFO can be written by software and the transmit FIFO can be read by software when the FIFOs are
* enabled. When FIFOs are not enabled it allows the RBR to be written by software and the THR to be read
* by software. Note, that when the FIFO access mode is enabled/disabled, the control portion of the
* receive FIFO and transmit FIFO is reset and the FIFOs are treated as empty.
*/
union cvmx_mio_uartx_far
{
uint64_t u64;
struct cvmx_mio_uartx_far_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_1_63 : 63;
uint64_t far : 1; /**< FIFO Access Register */
#else
uint64_t far : 1;
uint64_t reserved_1_63 : 63;
#endif
} s;
struct cvmx_mio_uartx_far_s cn30xx;
struct cvmx_mio_uartx_far_s cn31xx;
struct cvmx_mio_uartx_far_s cn38xx;
struct cvmx_mio_uartx_far_s cn38xxp2;
struct cvmx_mio_uartx_far_s cn50xx;
struct cvmx_mio_uartx_far_s cn52xx;
struct cvmx_mio_uartx_far_s cn52xxp1;
struct cvmx_mio_uartx_far_s cn56xx;
struct cvmx_mio_uartx_far_s cn56xxp1;
struct cvmx_mio_uartx_far_s cn58xx;
struct cvmx_mio_uartx_far_s cn58xxp1;
struct cvmx_mio_uartx_far_s cn63xx;
struct cvmx_mio_uartx_far_s cn63xxp1;
};
typedef union cvmx_mio_uartx_far cvmx_mio_uartx_far_t;
typedef cvmx_mio_uartx_far_t cvmx_uart_far_t;
/**
* cvmx_mio_uart#_fcr
*
* MIO_UARTX_FCR = MIO UARTX FIFO Control Register
*
* The FIFO Control Register (FCR) is a write-only register that controls the read and write data FIFO
* operation. When FIFOs and Programmable THRE Interrupt mode are enabled, this register also controls
* the THRE Interrupt empty threshold level.
*
* Setting bit 0 of the FCR enables the transmit and receive FIFOs. Whenever the value of this bit is
* changed both the TX and RX FIFOs will be reset.
*
* Writing a '1' to bit 1 of the FCR resets and flushes data in the receive FIFO. Note that this bit is
* self-clearing and it is not necessary to clear this bit.
*
* Writing a '1' to bit 2 of the FCR resets and flushes data in the transmit FIFO. Note that this bit is
* self-clearing and it is not necessary to clear this bit.
*
* If the FIFOs and Programmable THRE Interrupt mode are enabled, bits 4 and 5 control the empty
* threshold level at which THRE Interrupts are generated when the mode is active. See the following
* table for encodings:
*
* TX Trigger
* ----------
* 00 = empty FIFO
* 01 = 2 chars in FIFO
* 10 = FIFO 1/4 full
* 11 = FIFO 1/2 full
*
* If the FIFO mode is enabled (bit 0 of the FCR is set to '1') bits 6 and 7 are active. Bit 6 and bit 7
* set the trigger level in the receiver FIFO for the Enable Received Data Available Interrupt (ERBFI).
* In auto flow control mode the trigger is used to determine when the rts_n signal will be deasserted.
* See the following table for encodings:
*
* RX Trigger
* ----------
* 00 = 1 char in FIFO
* 01 = FIFO 1/4 full
* 10 = FIFO 1/2 full
* 11 = FIFO 2 chars less than full
*
* Note: The address below is an alias to simplify these CSR descriptions. It should be known that the
* IIR and FCR registers are the same.
*/
union cvmx_mio_uartx_fcr
{
uint64_t u64;
struct cvmx_mio_uartx_fcr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t rxtrig : 2; /**< RX Trigger */
uint64_t txtrig : 2; /**< TX Trigger */
uint64_t reserved_3_3 : 1;
uint64_t txfr : 1; /**< TX FIFO reset */
uint64_t rxfr : 1; /**< RX FIFO reset */
uint64_t en : 1; /**< FIFO enable */
#else
uint64_t en : 1;
uint64_t rxfr : 1;
uint64_t txfr : 1;
uint64_t reserved_3_3 : 1;
uint64_t txtrig : 2;
uint64_t rxtrig : 2;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uartx_fcr_s cn30xx;
struct cvmx_mio_uartx_fcr_s cn31xx;
struct cvmx_mio_uartx_fcr_s cn38xx;
struct cvmx_mio_uartx_fcr_s cn38xxp2;
struct cvmx_mio_uartx_fcr_s cn50xx;
struct cvmx_mio_uartx_fcr_s cn52xx;
struct cvmx_mio_uartx_fcr_s cn52xxp1;
struct cvmx_mio_uartx_fcr_s cn56xx;
struct cvmx_mio_uartx_fcr_s cn56xxp1;
struct cvmx_mio_uartx_fcr_s cn58xx;
struct cvmx_mio_uartx_fcr_s cn58xxp1;
struct cvmx_mio_uartx_fcr_s cn63xx;
struct cvmx_mio_uartx_fcr_s cn63xxp1;
};
typedef union cvmx_mio_uartx_fcr cvmx_mio_uartx_fcr_t;
typedef cvmx_mio_uartx_fcr_t cvmx_uart_fcr_t;
/**
* cvmx_mio_uart#_htx
*
* MIO_UARTX_HTX = MIO UARTX Halt TX Register
*
* The Halt TX Register (HTX) is used to halt transmissions for testing, so that the transmit FIFO can be
* filled by software when FIFOs are enabled. If FIFOs are not enabled, setting the HTX register will
* have no effect.
*/
union cvmx_mio_uartx_htx
{
uint64_t u64;
struct cvmx_mio_uartx_htx_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_1_63 : 63;
uint64_t htx : 1; /**< Halt TX */
#else
uint64_t htx : 1;
uint64_t reserved_1_63 : 63;
#endif
} s;
struct cvmx_mio_uartx_htx_s cn30xx;
struct cvmx_mio_uartx_htx_s cn31xx;
struct cvmx_mio_uartx_htx_s cn38xx;
struct cvmx_mio_uartx_htx_s cn38xxp2;
struct cvmx_mio_uartx_htx_s cn50xx;
struct cvmx_mio_uartx_htx_s cn52xx;
struct cvmx_mio_uartx_htx_s cn52xxp1;
struct cvmx_mio_uartx_htx_s cn56xx;
struct cvmx_mio_uartx_htx_s cn56xxp1;
struct cvmx_mio_uartx_htx_s cn58xx;
struct cvmx_mio_uartx_htx_s cn58xxp1;
struct cvmx_mio_uartx_htx_s cn63xx;
struct cvmx_mio_uartx_htx_s cn63xxp1;
};
typedef union cvmx_mio_uartx_htx cvmx_mio_uartx_htx_t;
typedef cvmx_mio_uartx_htx_t cvmx_uart_htx_t;
/**
* cvmx_mio_uart#_ier
*
* MIO_UARTX_IER = MIO UARTX Interrupt Enable Register
*
* Interrupt Enable Register (IER) is a read/write register that contains four bits that enable
* the generation of interrupts. These four bits are the Enable Received Data Available Interrupt
* (ERBFI), the Enable Transmitter Holding Register Empty Interrupt (ETBEI), the Enable Receiver Line
* Status Interrupt (ELSI), and the Enable Modem Status Interrupt (EDSSI).
*
* The IER also contains an enable bit (PTIME) for the Programmable THRE Interrupt mode.
*
* Note: The Divisor Latch Address Bit (DLAB) of the Line Control Register (LCR) must be clear to access
* this register.
*
* Note: The address below is an alias to simplify these CSR descriptions. It should be known that the
* IER and DLH registers are the same.
*/
union cvmx_mio_uartx_ier
{
uint64_t u64;
struct cvmx_mio_uartx_ier_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t ptime : 1; /**< Programmable THRE Interrupt mode enable */
uint64_t reserved_4_6 : 3;
uint64_t edssi : 1; /**< Enable Modem Status Interrupt */
uint64_t elsi : 1; /**< Enable Receiver Line Status Interrupt */
uint64_t etbei : 1; /**< Enable Transmitter Holding Register Empty Interrupt */
uint64_t erbfi : 1; /**< Enable Received Data Available Interrupt */
#else
uint64_t erbfi : 1;
uint64_t etbei : 1;
uint64_t elsi : 1;
uint64_t edssi : 1;
uint64_t reserved_4_6 : 3;
uint64_t ptime : 1;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uartx_ier_s cn30xx;
struct cvmx_mio_uartx_ier_s cn31xx;
struct cvmx_mio_uartx_ier_s cn38xx;
struct cvmx_mio_uartx_ier_s cn38xxp2;
struct cvmx_mio_uartx_ier_s cn50xx;
struct cvmx_mio_uartx_ier_s cn52xx;
struct cvmx_mio_uartx_ier_s cn52xxp1;
struct cvmx_mio_uartx_ier_s cn56xx;
struct cvmx_mio_uartx_ier_s cn56xxp1;
struct cvmx_mio_uartx_ier_s cn58xx;
struct cvmx_mio_uartx_ier_s cn58xxp1;
struct cvmx_mio_uartx_ier_s cn63xx;
struct cvmx_mio_uartx_ier_s cn63xxp1;
};
typedef union cvmx_mio_uartx_ier cvmx_mio_uartx_ier_t;
typedef cvmx_mio_uartx_ier_t cvmx_uart_ier_t;
/**
* cvmx_mio_uart#_iir
*
* MIO_UARTX_IIR = MIO UARTX Interrupt Identity Register
*
* The Interrupt Identity Register (IIR) is a read-only register that identifies the source of an
* interrupt. The upper two bits of the register are FIFO-enabled bits. These bits are '00' if the FIFOs
* are disabled, and '11' if they are enabled. The lower four bits identify the highest priority pending
* interrupt. The following table defines interrupt source decoding, interrupt priority, and interrupt
* reset control:
*
* Interrupt Priority Interrupt Interrupt Interrupt
* ID Level Type Source Reset By
* ---------------------------------------------------------------------------------------------------------------------------------
* 0001 - None None -
*
* 0110 Highest Receiver Line Overrun, parity, or framing errors or break Reading the Line Status Register
* Status interrupt
*
* 0100 Second Received Data Receiver data available (FIFOs disabled) or Reading the Receiver Buffer Register
* Available RX FIFO trigger level reached (FIFOs (FIFOs disabled) or the FIFO drops below
* enabled) the trigger level (FIFOs enabled)
*
* 1100 Second Character No characters in or out of the RX FIFO Reading the Receiver Buffer Register
* Timeout during the last 4 character times and there
* Indication is at least 1 character in it during this
* time
*
* 0010 Third Transmitter Transmitter Holding Register Empty Reading the Interrupt Identity Register
* Holding (Programmable THRE Mode disabled) or TX (if source of interrupt) or writing into
* Register FIFO at or below threshold (Programmable THR (FIFOs or THRE Mode disabled) or TX
* Empty THRE Mode enabled) FIFO above threshold (FIFOs and THRE
* Mode enabled)
*
* 0000 Fourth Modem Status Clear To Send (CTS) or Data Set Ready (DSR) Reading the Modem Status Register
* Changed or Ring Indicator (RI) or Data Carrier
* Detect (DCD) changed (note: if auto flow
* control mode is enabled, a change in CTS
* will not cause an interrupt)
*
* 0111 Fifth Busy Detect Software has tried to write to the Line Reading the UART Status Register
* Indication Control Register while the BUSY bit of the
* UART Status Register was set
*
* Note: The Busy Detect Indication interrupt has been removed from PASS3 and will never assert.
*
* Note: The address below is an alias to simplify these CSR descriptions. It should be known that the
* IIR and FCR registers are the same.
*/
union cvmx_mio_uartx_iir
{
uint64_t u64;
struct cvmx_mio_uartx_iir_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t fen : 2; /**< FIFO-enabled bits */
uint64_t reserved_4_5 : 2;
cvmx_uart_iid_t iid : 4; /**< Interrupt ID */
#else
cvmx_uart_iid_t iid : 4;
uint64_t reserved_4_5 : 2;
uint64_t fen : 2;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uartx_iir_s cn30xx;
struct cvmx_mio_uartx_iir_s cn31xx;
struct cvmx_mio_uartx_iir_s cn38xx;
struct cvmx_mio_uartx_iir_s cn38xxp2;
struct cvmx_mio_uartx_iir_s cn50xx;
struct cvmx_mio_uartx_iir_s cn52xx;
struct cvmx_mio_uartx_iir_s cn52xxp1;
struct cvmx_mio_uartx_iir_s cn56xx;
struct cvmx_mio_uartx_iir_s cn56xxp1;
struct cvmx_mio_uartx_iir_s cn58xx;
struct cvmx_mio_uartx_iir_s cn58xxp1;
struct cvmx_mio_uartx_iir_s cn63xx;
struct cvmx_mio_uartx_iir_s cn63xxp1;
};
typedef union cvmx_mio_uartx_iir cvmx_mio_uartx_iir_t;
typedef cvmx_mio_uartx_iir_t cvmx_uart_iir_t;
/**
* cvmx_mio_uart#_lcr
*
* MIO_UARTX_LCR = MIO UARTX Line Control Register
*
* The Line Control Register (LCR) controls the format of the data that is transmitted and received by
* the UART.
*
* LCR bits 0 and 1 are the Character Length Select field. This field is used to select the number of
* data bits per character that are transmitted and received. See the following table for encodings:
*
* CLS
* ---
* 00 = 5 bits (bits 0-4 sent)
* 01 = 6 bits (bits 0-5 sent)
* 10 = 7 bits (bits 0-6 sent)
* 11 = 8 bits (all bits sent)
*
* LCR bit 2 controls the number of stop bits transmitted. If bit 2 is a '0', one stop bit is transmitted
* in the serial data. If bit 2 is a '1' and the data bits are set to '00', one and a half stop bits are
* generated. Otherwise, two stop bits are generated and transmitted in the serial data out. Note that
* regardless of the number of stop bits selected the receiver will only check the first stop bit.
*
* LCR bit 3 is the Parity Enable bit. This bit is used to enable and disable parity generation and
* detection in transmitted and received serial character respectively.
*
* LCR bit 4 is the Even Parity Select bit. If parity is enabled, bit 4 selects between even and odd
* parity. If bit 4 is a '1', an even number of ones is transmitted or checked. If bit 4 is a '0', an odd
* number of ones is transmitted or checked.
*
* LCR bit 6 is the Break Control bit. Setting the Break bit sends a break signal by holding the sout
* line low (when not in Loopback mode, as determined by Modem Control Register bit 4). When in Loopback
* mode, the break condition is internally looped back to the receiver.
*
* LCR bit 7 is the Divisor Latch Address bit. Setting this bit enables reading and writing of the
* Divisor Latch register (DLL and DLH) to set the baud rate of the UART. This bit must be cleared after
* initial baud rate setup in order to access other registers.
*
* Note: The LCR is writeable only when the UART is not busy (when the BUSY bit (bit 0) of the UART
* Status Register (USR) is clear). The LCR is always readable. In PASS3, the LCR is always writable
* because the BUSY bit is always clear.
*/
union cvmx_mio_uartx_lcr
{
uint64_t u64;
struct cvmx_mio_uartx_lcr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t dlab : 1; /**< Divisor Latch Address bit */
uint64_t brk : 1; /**< Break Control bit */
uint64_t reserved_5_5 : 1;
uint64_t eps : 1; /**< Even Parity Select bit */
uint64_t pen : 1; /**< Parity Enable bit */
uint64_t stop : 1; /**< Stop Control bit */
cvmx_uart_bits_t cls : 2; /**< Character Length Select */
#else
cvmx_uart_bits_t cls : 2;
uint64_t stop : 1;
uint64_t pen : 1;
uint64_t eps : 1;
uint64_t reserved_5_5 : 1;
uint64_t brk : 1;
uint64_t dlab : 1;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uartx_lcr_s cn30xx;
struct cvmx_mio_uartx_lcr_s cn31xx;
struct cvmx_mio_uartx_lcr_s cn38xx;
struct cvmx_mio_uartx_lcr_s cn38xxp2;
struct cvmx_mio_uartx_lcr_s cn50xx;
struct cvmx_mio_uartx_lcr_s cn52xx;
struct cvmx_mio_uartx_lcr_s cn52xxp1;
struct cvmx_mio_uartx_lcr_s cn56xx;
struct cvmx_mio_uartx_lcr_s cn56xxp1;
struct cvmx_mio_uartx_lcr_s cn58xx;
struct cvmx_mio_uartx_lcr_s cn58xxp1;
struct cvmx_mio_uartx_lcr_s cn63xx;
struct cvmx_mio_uartx_lcr_s cn63xxp1;
};
typedef union cvmx_mio_uartx_lcr cvmx_mio_uartx_lcr_t;
typedef cvmx_mio_uartx_lcr_t cvmx_uart_lcr_t;
/**
* cvmx_mio_uart#_lsr
*
* MIO_UARTX_LSR = MIO UARTX Line Status Register
*
* The Line Status Register (LSR) contains status of the receiver and transmitter data transfers. This
* status can be read by the user at anytime.
*
* LSR bit 0 is the Data Ready (DR) bit. When set, this bit indicates the receiver contains at least one
* character in the RBR or the receiver FIFO. This bit is cleared when the RBR is read in the non-FIFO
* mode, or when the receiver FIFO is empty, in FIFO mode.
*
* LSR bit 1 is the Overrun Error (OE) bit. When set, this bit indicates an overrun error has occurred
* because a new data character was received before the previous data was read. In the non-FIFO mode, the
* OE bit is set when a new character arrives in the receiver before the previous character was read from
* the RBR. When this happens, the data in the RBR is overwritten. In the FIFO mode, an overrun error
* occurs when the FIFO is full and a new character arrives at the receiver. The data in the FIFO is
* retained and the data in the receive shift register is lost.
*
* LSR bit 2 is the Parity Error (PE) bit. This bit is set whenever there is a parity error in the
* receiver if the Parity Enable (PEN) bit in the LCR is set. In the FIFO mode, since the parity error is
* associated with a character received, it is revealed when the character with the parity error arrives
* at the top of the FIFO. It should be noted that the Parity Error (PE) bit will be set if a break
* interrupt has occurred, as indicated by the Break Interrupt (BI) bit.
*
* LSR bit 3 is the Framing Error (FE) bit. This bit is set whenever there is a framing error in the
* receiver. A framing error occurs when the receiver does not detect a valid STOP bit in the received
* data. In the FIFO mode, since the framing error is associated with a character received, it is
* revealed when the character with the framing error is at the top of the FIFO. When a framing error
* occurs the UART will try resynchronize. It does this by assuming that the error was due to the start
* bit of the next character and then continues receiving the other bits (i.e. data and/or parity and
* stop). It should be noted that the Framing Error (FE) bit will be set if a break interrupt has
* occurred, as indicated by the Break Interrupt (BI) bit.
*
* Note: The OE, PE, and FE bits are reset when a read of the LSR is performed.
*
* LSR bit 4 is the Break Interrupt (BI) bit. This bit is set whenever the serial input (sin) is held in
* a 0 state for longer than the sum of start time + data bits + parity + stop bits. A break condition on
* sin causes one and only one character, consisting of all zeros, to be received by the UART. In the
* FIFO mode, the character associated with the break condition is carried through the FIFO and is
* revealed when the character is at the top of the FIFO. Reading the LSR clears the BI bit. In the non-
* FIFO mode, the BI indication occurs immediately and persists until the LSR is read.
*
* LSR bit 5 is the Transmitter Holding Register Empty (THRE) bit. When Programmable THRE Interrupt mode
* is disabled, this bit indicates that the UART can accept a new character for transmission. This bit is
* set whenever data is transferred from the THR (or TX FIFO) to the transmitter shift register and no
* new data has been written to the THR (or TX FIFO). This also causes a THRE Interrupt to occur, if the
* THRE Interrupt is enabled. When FIFOs and Programmable THRE Interrupt mode are enabled, LSR bit 5
* functionality is switched to indicate the transmitter FIFO is full, and no longer controls THRE
* Interrupts, which are then controlled by the FCR[5:4] threshold setting.
*
* LSR bit 6 is the Transmitter Empty (TEMT) bit. In the FIFO mode, this bit is set whenever the
* Transmitter Shift Register and the FIFO are both empty. In the non-FIFO mode, this bit is set whenever
* the Transmitter Holding Register and the Transmitter Shift Register are both empty. This bit is
* typically used to make sure it is safe to change control registers. Changing control registers while
* the transmitter is busy can result in corrupt data being transmitted.
*
* LSR bit 7 is the Error in Receiver FIFO (FERR) bit. This bit is active only when FIFOs are enabled. It
* is set when there is at least one parity error, framing error, or break indication in the FIFO. This
* bit is cleared when the LSR is read and the character with the error is at the top of the receiver
* FIFO and there are no subsequent errors in the FIFO.
*/
union cvmx_mio_uartx_lsr
{
uint64_t u64;
struct cvmx_mio_uartx_lsr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t ferr : 1; /**< Error in Receiver FIFO bit */
uint64_t temt : 1; /**< Transmitter Empty bit */
uint64_t thre : 1; /**< Transmitter Holding Register Empty bit */
uint64_t bi : 1; /**< Break Interrupt bit */
uint64_t fe : 1; /**< Framing Error bit */
uint64_t pe : 1; /**< Parity Error bit */
uint64_t oe : 1; /**< Overrun Error bit */
uint64_t dr : 1; /**< Data Ready bit */
#else
uint64_t dr : 1;
uint64_t oe : 1;
uint64_t pe : 1;
uint64_t fe : 1;
uint64_t bi : 1;
uint64_t thre : 1;
uint64_t temt : 1;
uint64_t ferr : 1;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uartx_lsr_s cn30xx;
struct cvmx_mio_uartx_lsr_s cn31xx;
struct cvmx_mio_uartx_lsr_s cn38xx;
struct cvmx_mio_uartx_lsr_s cn38xxp2;
struct cvmx_mio_uartx_lsr_s cn50xx;
struct cvmx_mio_uartx_lsr_s cn52xx;
struct cvmx_mio_uartx_lsr_s cn52xxp1;
struct cvmx_mio_uartx_lsr_s cn56xx;
struct cvmx_mio_uartx_lsr_s cn56xxp1;
struct cvmx_mio_uartx_lsr_s cn58xx;
struct cvmx_mio_uartx_lsr_s cn58xxp1;
struct cvmx_mio_uartx_lsr_s cn63xx;
struct cvmx_mio_uartx_lsr_s cn63xxp1;
};
typedef union cvmx_mio_uartx_lsr cvmx_mio_uartx_lsr_t;
typedef cvmx_mio_uartx_lsr_t cvmx_uart_lsr_t;
/**
* cvmx_mio_uart#_mcr
*
* MIO_UARTX_MCR = MIO UARTX Modem Control Register
*
* The lower four bits of the Modem Control Register (MCR) directly manipulate the outputs of the UART.
* The DTR (bit 0), RTS (bit 1), OUT1 (bit 2), and OUT2 (bit 3) bits are inverted and then drive the
* corresponding UART outputs, dtr_n, rts_n, out1_n, and out2_n. In loopback mode, these outputs are
* driven inactive high while the values in these locations are internally looped back to the inputs.
*
* Note: When Auto RTS is enabled, the rts_n output is controlled in the same way, but is also gated
* with the receiver FIFO threshold trigger (rts_n is inactive high when above the threshold). The
* rts_n output will be de-asserted whenever RTS (bit 1) is set low.
*
* Note: The UART0 out1_n and out2_n outputs are not present on the pins of the chip, but the UART0 OUT1
* and OUT2 bits still function in Loopback mode. The UART1 dtr_n, out1_n, and out2_n outputs are not
* present on the pins of the chip, but the UART1 DTR, OUT1, and OUT2 bits still function in Loopback
* mode.
*
* MCR bit 4 is the Loopback bit. When set, data on the sout line is held high, while serial data output
* is looped back to the sin line, internally. In this mode all the interrupts are fully functional. This
* feature is used for diagnostic purposes. Also, in loopback mode, the modem control inputs (dsr_n,
* cts_n, ri_n, dcd_n) are disconnected and the four modem control outputs (dtr_n, rts_n, out1_n, out1_n)
* are looped back to the inputs, internally.
*
* MCR bit 5 is the Auto Flow Control Enable (AFCE) bit. When FIFOs are enabled and this bit is set,
* 16750-compatible Auto RTS and Auto CTS serial data flow control features are enabled.
*
* Auto RTS becomes active when the following occurs:
* 1. MCR bit 1 is set
* 2. FIFOs are enabled by setting FIFO Control Register (FCR) bit 0
* 3. MCR bit 5 is set (must be set after FCR bit 0)
*
* When active, the rts_n output is forced inactive-high when the receiver FIFO level reaches the
* threshold set by FCR[7:6]. When rts_n is connected to the cts_n input of another UART device, the
* other UART stops sending serial data until the receiver FIFO has available space.
*
* The selectable receiver FIFO threshold values are: 1, 1/4, 1/2, and 2 less than full. Since one
* additional character may be transmitted to the UART after rts_n has become inactive (due to data
* already having entered the transmitter block in the other UART), setting the threshold to 2 less
* than full allows maximum use of the FIFO with a safety zone of one character.
*
* Once the receiver FIFO becomes completely empty by reading the Receiver Buffer Register (RBR), rts_n
* again becomes active-low, signalling the other UART to continue sending data. It is important to note
* that, even if everything else is set to Enabled and the correct MCR bits are set, if the FIFOs are
* disabled through FCR[0], Auto Flow Control is also disabled. When Auto RTS is disabled or inactive,
* rts_n is controlled solely by MCR[1].
*
* Auto CTS becomes active when the following occurs:
* 1. FIFOs are enabled by setting FIFO Control Register (FCR) bit 0
* 2. MCR bit 5 is set (must be set after FCR bit 0)
*
* When active, the UART transmitter is disabled whenever the cts_n input becomes inactive-high. This
* prevents overflowing the FIFO of the receiving UART.
*
* Note that, if the cts_n input is not inactivated before the middle of the last stop bit, another
* character is transmitted before the transmitter is disabled. While the transmitter is disabled, the
* transmitter FIFO can still be written to, and even overflowed. Therefore, when using this mode, either
* the true FIFO depth (64 characters) must be known to software, or the Programmable THRE Interrupt mode
* must be enabled to access the FIFO full status through the Line Status Register. When using the FIFO
* full status, software can poll this before each write to the Transmitter FIFO.
*
* Note: FIFO full status is also available in the UART Status Register (USR) or the actual level of the
* FIFO may be read through the Transmit FIFO Level (TFL) register.
*
* When the cts_n input becomes active-low again, transmission resumes. It is important to note that,
* even if everything else is set to Enabled, Auto Flow Control is also disabled if the FIFOs are
* disabled through FCR[0]. When Auto CTS is disabled or inactive, the transmitter is unaffected by
* cts_n.
*/
union cvmx_mio_uartx_mcr
{
uint64_t u64;
struct cvmx_mio_uartx_mcr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_6_63 : 58;
uint64_t afce : 1; /**< Auto Flow Control Enable bit */
uint64_t loop : 1; /**< Loopback bit */
uint64_t out2 : 1; /**< OUT2 output bit */
uint64_t out1 : 1; /**< OUT1 output bit */
uint64_t rts : 1; /**< Request To Send output bit */
uint64_t dtr : 1; /**< Data Terminal Ready output bit */
#else
uint64_t dtr : 1;
uint64_t rts : 1;
uint64_t out1 : 1;
uint64_t out2 : 1;
uint64_t loop : 1;
uint64_t afce : 1;
uint64_t reserved_6_63 : 58;
#endif
} s;
struct cvmx_mio_uartx_mcr_s cn30xx;
struct cvmx_mio_uartx_mcr_s cn31xx;
struct cvmx_mio_uartx_mcr_s cn38xx;
struct cvmx_mio_uartx_mcr_s cn38xxp2;
struct cvmx_mio_uartx_mcr_s cn50xx;
struct cvmx_mio_uartx_mcr_s cn52xx;
struct cvmx_mio_uartx_mcr_s cn52xxp1;
struct cvmx_mio_uartx_mcr_s cn56xx;
struct cvmx_mio_uartx_mcr_s cn56xxp1;
struct cvmx_mio_uartx_mcr_s cn58xx;
struct cvmx_mio_uartx_mcr_s cn58xxp1;
struct cvmx_mio_uartx_mcr_s cn63xx;
struct cvmx_mio_uartx_mcr_s cn63xxp1;
};
typedef union cvmx_mio_uartx_mcr cvmx_mio_uartx_mcr_t;
typedef cvmx_mio_uartx_mcr_t cvmx_uart_mcr_t;
/**
* cvmx_mio_uart#_msr
*
* MIO_UARTX_MSR = MIO UARTX Modem Status Register
*
* The Modem Status Register (MSR) contains the current status of the modem control input lines and if
* they changed.
*
* DCTS (bit 0), DDSR (bit 1), and DDCD (bit 3) bits record whether the modem control lines (cts_n,
* dsr_n, and dcd_n) have changed since the last time the user read the MSR. TERI (bit 2) indicates ri_n
* has changed from an active-low, to an inactive-high state since the last time the MSR was read. In
* Loopback mode, DCTS reflects changes on MCR bit 1 (RTS), DDSR reflects changes on MCR bit 0 (DTR), and
* DDCD reflects changes on MCR bit 3 (Out2), while TERI reflects when MCR bit 2 (Out1) has changed state
* from a high to a low.
*
* Note: if the DCTS bit is not set and the cts_n signal is asserted (low) and a reset occurs (software
* or otherwise), then the DCTS bit will get set when the reset is removed if the cts_n signal remains
* asserted.
*
* The CTS, DSR, RI, and DCD Modem Status bits contain information on the current state of the modem
* control lines. CTS (bit 4) is the compliment of cts_n, DSR (bit 5) is the compliment of dsr_n, RI
* (bit 6) is the compliment of ri_n, and DCD (bit 7) is the compliment of dcd_n. In Loopback mode, CTS
* is the same as MCR bit 1 (RTS), DSR is the same as MCR bit 0 (DTR), RI is the same as MCR bit 2
* (Out1), and DCD is the same as MCR bit 3 (Out2).
*
* Note: The UART0 dsr_n and ri_n inputs are internally tied to power and not present on the pins of chip.
* Thus the UART0 DSR and RI bits will be '0' when not in Loopback mode. The UART1 dsr_n, ri_n, and dcd_n
* inputs are internally tied to power and not present on the pins of chip. Thus the UART1 DSR, RI, and
* DCD bits will be '0' when not in Loopback mode.
*/
union cvmx_mio_uartx_msr
{
uint64_t u64;
struct cvmx_mio_uartx_msr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t dcd : 1; /**< Data Carrier Detect input bit */
uint64_t ri : 1; /**< Ring Indicator input bit */
uint64_t dsr : 1; /**< Data Set Ready input bit */
uint64_t cts : 1; /**< Clear To Send input bit */
uint64_t ddcd : 1; /**< Delta Data Carrier Detect bit */
uint64_t teri : 1; /**< Trailing Edge of Ring Indicator bit */
uint64_t ddsr : 1; /**< Delta Data Set Ready bit */
uint64_t dcts : 1; /**< Delta Clear To Send bit */
#else
uint64_t dcts : 1;
uint64_t ddsr : 1;
uint64_t teri : 1;
uint64_t ddcd : 1;
uint64_t cts : 1;
uint64_t dsr : 1;
uint64_t ri : 1;
uint64_t dcd : 1;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uartx_msr_s cn30xx;
struct cvmx_mio_uartx_msr_s cn31xx;
struct cvmx_mio_uartx_msr_s cn38xx;
struct cvmx_mio_uartx_msr_s cn38xxp2;
struct cvmx_mio_uartx_msr_s cn50xx;
struct cvmx_mio_uartx_msr_s cn52xx;
struct cvmx_mio_uartx_msr_s cn52xxp1;
struct cvmx_mio_uartx_msr_s cn56xx;
struct cvmx_mio_uartx_msr_s cn56xxp1;
struct cvmx_mio_uartx_msr_s cn58xx;
struct cvmx_mio_uartx_msr_s cn58xxp1;
struct cvmx_mio_uartx_msr_s cn63xx;
struct cvmx_mio_uartx_msr_s cn63xxp1;
};
typedef union cvmx_mio_uartx_msr cvmx_mio_uartx_msr_t;
typedef cvmx_mio_uartx_msr_t cvmx_uart_msr_t;
/**
* cvmx_mio_uart#_rbr
*
* MIO_UARTX_RBR = MIO UARTX Receive Buffer Register
*
* The Receive Buffer Register (RBR) is a read-only register that contains the data byte received on the
* serial input port (sin). The data in this register is valid only if the Data Ready (DR) bit in the
* Line status Register (LSR) is set. When the FIFOs are programmed OFF, the data in the RBR must be
* read before the next data arrives, otherwise it is overwritten, resulting in an overrun error. When
* the FIFOs are programmed ON, this register accesses the head of the receive FIFO. If the receive FIFO
* is full (64 characters) and this register is not read before the next data character arrives, then the
* data already in the FIFO is preserved, but any incoming data is lost. An overrun error also occurs.
*
* Note: The Divisor Latch Address Bit (DLAB) of the Line Control Register (LCR) must be clear to access
* this register.
*
* Note: The address below is an alias to simplify these CSR descriptions. It should be known that the
* RBR, THR, and DLL registers are the same.
*/
union cvmx_mio_uartx_rbr
{
uint64_t u64;
struct cvmx_mio_uartx_rbr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t rbr : 8; /**< Receive Buffer Register */
#else
uint64_t rbr : 8;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uartx_rbr_s cn30xx;
struct cvmx_mio_uartx_rbr_s cn31xx;
struct cvmx_mio_uartx_rbr_s cn38xx;
struct cvmx_mio_uartx_rbr_s cn38xxp2;
struct cvmx_mio_uartx_rbr_s cn50xx;
struct cvmx_mio_uartx_rbr_s cn52xx;
struct cvmx_mio_uartx_rbr_s cn52xxp1;
struct cvmx_mio_uartx_rbr_s cn56xx;
struct cvmx_mio_uartx_rbr_s cn56xxp1;
struct cvmx_mio_uartx_rbr_s cn58xx;
struct cvmx_mio_uartx_rbr_s cn58xxp1;
struct cvmx_mio_uartx_rbr_s cn63xx;
struct cvmx_mio_uartx_rbr_s cn63xxp1;
};
typedef union cvmx_mio_uartx_rbr cvmx_mio_uartx_rbr_t;
typedef cvmx_mio_uartx_rbr_t cvmx_uart_rbr_t;
/**
* cvmx_mio_uart#_rfl
*
* MIO_UARTX_RFL = MIO UARTX Receive FIFO Level Register
*
* The Receive FIFO Level Register (RFL) indicates the number of data entries in the receive FIFO.
*/
union cvmx_mio_uartx_rfl
{
uint64_t u64;
struct cvmx_mio_uartx_rfl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_7_63 : 57;
uint64_t rfl : 7; /**< Receive FIFO Level Register */
#else
uint64_t rfl : 7;
uint64_t reserved_7_63 : 57;
#endif
} s;
struct cvmx_mio_uartx_rfl_s cn30xx;
struct cvmx_mio_uartx_rfl_s cn31xx;
struct cvmx_mio_uartx_rfl_s cn38xx;
struct cvmx_mio_uartx_rfl_s cn38xxp2;
struct cvmx_mio_uartx_rfl_s cn50xx;
struct cvmx_mio_uartx_rfl_s cn52xx;
struct cvmx_mio_uartx_rfl_s cn52xxp1;
struct cvmx_mio_uartx_rfl_s cn56xx;
struct cvmx_mio_uartx_rfl_s cn56xxp1;
struct cvmx_mio_uartx_rfl_s cn58xx;
struct cvmx_mio_uartx_rfl_s cn58xxp1;
struct cvmx_mio_uartx_rfl_s cn63xx;
struct cvmx_mio_uartx_rfl_s cn63xxp1;
};
typedef union cvmx_mio_uartx_rfl cvmx_mio_uartx_rfl_t;
typedef cvmx_mio_uartx_rfl_t cvmx_uart_rfl_t;
/**
* cvmx_mio_uart#_rfw
*
* MIO_UARTX_RFW = MIO UARTX Receive FIFO Write Register
*
* The Receive FIFO Write Register (RFW) is only valid when FIFO access mode is enabled (FAR bit 0 is
* set). When FIFOs are enabled, this register is used to write data to the receive FIFO. Each
* consecutive write pushes the new data to the next write location in the receive FIFO. When FIFOs are
* not enabled, this register is used to write data to the RBR.
*/
union cvmx_mio_uartx_rfw
{
uint64_t u64;
struct cvmx_mio_uartx_rfw_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_10_63 : 54;
uint64_t rffe : 1; /**< Receive FIFO Framing Error */
uint64_t rfpe : 1; /**< Receive FIFO Parity Error */
uint64_t rfwd : 8; /**< Receive FIFO Write Data */
#else
uint64_t rfwd : 8;
uint64_t rfpe : 1;
uint64_t rffe : 1;
uint64_t reserved_10_63 : 54;
#endif
} s;
struct cvmx_mio_uartx_rfw_s cn30xx;
struct cvmx_mio_uartx_rfw_s cn31xx;
struct cvmx_mio_uartx_rfw_s cn38xx;
struct cvmx_mio_uartx_rfw_s cn38xxp2;
struct cvmx_mio_uartx_rfw_s cn50xx;
struct cvmx_mio_uartx_rfw_s cn52xx;
struct cvmx_mio_uartx_rfw_s cn52xxp1;
struct cvmx_mio_uartx_rfw_s cn56xx;
struct cvmx_mio_uartx_rfw_s cn56xxp1;
struct cvmx_mio_uartx_rfw_s cn58xx;
struct cvmx_mio_uartx_rfw_s cn58xxp1;
struct cvmx_mio_uartx_rfw_s cn63xx;
struct cvmx_mio_uartx_rfw_s cn63xxp1;
};
typedef union cvmx_mio_uartx_rfw cvmx_mio_uartx_rfw_t;
typedef cvmx_mio_uartx_rfw_t cvmx_uart_rfw_t;
/**
* cvmx_mio_uart#_sbcr
*
* MIO_UARTX_SBCR = MIO UARTX Shadow Break Control Register
*
* The Shadow Break Control Register (SBCR) is a shadow register for the BREAK bit (LCR bit 6) that can
* be used to remove the burden of having to perform a read-modify-write on the LCR.
*/
union cvmx_mio_uartx_sbcr
{
uint64_t u64;
struct cvmx_mio_uartx_sbcr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_1_63 : 63;
uint64_t sbcr : 1; /**< Shadow Break Control */
#else
uint64_t sbcr : 1;
uint64_t reserved_1_63 : 63;
#endif
} s;
struct cvmx_mio_uartx_sbcr_s cn30xx;
struct cvmx_mio_uartx_sbcr_s cn31xx;
struct cvmx_mio_uartx_sbcr_s cn38xx;
struct cvmx_mio_uartx_sbcr_s cn38xxp2;
struct cvmx_mio_uartx_sbcr_s cn50xx;
struct cvmx_mio_uartx_sbcr_s cn52xx;
struct cvmx_mio_uartx_sbcr_s cn52xxp1;
struct cvmx_mio_uartx_sbcr_s cn56xx;
struct cvmx_mio_uartx_sbcr_s cn56xxp1;
struct cvmx_mio_uartx_sbcr_s cn58xx;
struct cvmx_mio_uartx_sbcr_s cn58xxp1;
struct cvmx_mio_uartx_sbcr_s cn63xx;
struct cvmx_mio_uartx_sbcr_s cn63xxp1;
};
typedef union cvmx_mio_uartx_sbcr cvmx_mio_uartx_sbcr_t;
typedef cvmx_mio_uartx_sbcr_t cvmx_uart_sbcr_t;
/**
* cvmx_mio_uart#_scr
*
* MIO_UARTX_SCR = MIO UARTX Scratchpad Register
*
* The Scratchpad Register (SCR) is an 8-bit read/write register for programmers to use as a temporary
* storage space.
*/
union cvmx_mio_uartx_scr
{
uint64_t u64;
struct cvmx_mio_uartx_scr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t scr : 8; /**< Scratchpad Register */
#else
uint64_t scr : 8;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uartx_scr_s cn30xx;
struct cvmx_mio_uartx_scr_s cn31xx;
struct cvmx_mio_uartx_scr_s cn38xx;
struct cvmx_mio_uartx_scr_s cn38xxp2;
struct cvmx_mio_uartx_scr_s cn50xx;
struct cvmx_mio_uartx_scr_s cn52xx;
struct cvmx_mio_uartx_scr_s cn52xxp1;
struct cvmx_mio_uartx_scr_s cn56xx;
struct cvmx_mio_uartx_scr_s cn56xxp1;
struct cvmx_mio_uartx_scr_s cn58xx;
struct cvmx_mio_uartx_scr_s cn58xxp1;
struct cvmx_mio_uartx_scr_s cn63xx;
struct cvmx_mio_uartx_scr_s cn63xxp1;
};
typedef union cvmx_mio_uartx_scr cvmx_mio_uartx_scr_t;
typedef cvmx_mio_uartx_scr_t cvmx_uart_scr_t;
/**
* cvmx_mio_uart#_sfe
*
* MIO_UARTX_SFE = MIO UARTX Shadow FIFO Enable Register
*
* The Shadow FIFO Enable Register (SFE) is a shadow register for the FIFO enable bit (FCR bit 0) that
* can be used to remove the burden of having to store the previously written value to the FCR in memory
* and having to mask this value so that only the FIFO enable bit gets updated.
*/
union cvmx_mio_uartx_sfe
{
uint64_t u64;
struct cvmx_mio_uartx_sfe_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_1_63 : 63;
uint64_t sfe : 1; /**< Shadow FIFO Enable */
#else
uint64_t sfe : 1;
uint64_t reserved_1_63 : 63;
#endif
} s;
struct cvmx_mio_uartx_sfe_s cn30xx;
struct cvmx_mio_uartx_sfe_s cn31xx;
struct cvmx_mio_uartx_sfe_s cn38xx;
struct cvmx_mio_uartx_sfe_s cn38xxp2;
struct cvmx_mio_uartx_sfe_s cn50xx;
struct cvmx_mio_uartx_sfe_s cn52xx;
struct cvmx_mio_uartx_sfe_s cn52xxp1;
struct cvmx_mio_uartx_sfe_s cn56xx;
struct cvmx_mio_uartx_sfe_s cn56xxp1;
struct cvmx_mio_uartx_sfe_s cn58xx;
struct cvmx_mio_uartx_sfe_s cn58xxp1;
struct cvmx_mio_uartx_sfe_s cn63xx;
struct cvmx_mio_uartx_sfe_s cn63xxp1;
};
typedef union cvmx_mio_uartx_sfe cvmx_mio_uartx_sfe_t;
typedef cvmx_mio_uartx_sfe_t cvmx_uart_sfe_t;
/**
* cvmx_mio_uart#_srr
*
* MIO_UARTX_SRR = MIO UARTX Software Reset Register
*
* The Software Reset Register (SRR) is a write-only register that resets the UART and/or the receive
* FIFO and/or the transmit FIFO.
*
* Bit 0 of the SRR is the UART Soft Reset (USR) bit. Setting this bit resets the UART.
*
* Bit 1 of the SRR is a shadow copy of the RX FIFO Reset bit (FCR bit 1). This can be used to remove
* the burden on software having to store previously written FCR values (which are pretty static) just
* to reset the receive FIFO.
*
* Bit 2 of the SRR is a shadow copy of the TX FIFO Reset bit (FCR bit 2). This can be used to remove
* the burden on software having to store previously written FCR values (which are pretty static) just
* to reset the transmit FIFO.
*/
union cvmx_mio_uartx_srr
{
uint64_t u64;
struct cvmx_mio_uartx_srr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_3_63 : 61;
uint64_t stfr : 1; /**< Shadow TX FIFO Reset */
uint64_t srfr : 1; /**< Shadow RX FIFO Reset */
uint64_t usr : 1; /**< UART Soft Reset */
#else
uint64_t usr : 1;
uint64_t srfr : 1;
uint64_t stfr : 1;
uint64_t reserved_3_63 : 61;
#endif
} s;
struct cvmx_mio_uartx_srr_s cn30xx;
struct cvmx_mio_uartx_srr_s cn31xx;
struct cvmx_mio_uartx_srr_s cn38xx;
struct cvmx_mio_uartx_srr_s cn38xxp2;
struct cvmx_mio_uartx_srr_s cn50xx;
struct cvmx_mio_uartx_srr_s cn52xx;
struct cvmx_mio_uartx_srr_s cn52xxp1;
struct cvmx_mio_uartx_srr_s cn56xx;
struct cvmx_mio_uartx_srr_s cn56xxp1;
struct cvmx_mio_uartx_srr_s cn58xx;
struct cvmx_mio_uartx_srr_s cn58xxp1;
struct cvmx_mio_uartx_srr_s cn63xx;
struct cvmx_mio_uartx_srr_s cn63xxp1;
};
typedef union cvmx_mio_uartx_srr cvmx_mio_uartx_srr_t;
typedef cvmx_mio_uartx_srr_t cvmx_uart_srr_t;
/**
* cvmx_mio_uart#_srt
*
* MIO_UARTX_SRT = MIO UARTX Shadow RX Trigger Register
*
* The Shadow RX Trigger Register (SRT) is a shadow register for the RX Trigger bits (FCR bits 7:6) that
* can be used to remove the burden of having to store the previously written value to the FCR in memory
* and having to mask this value so that only the RX Trigger bits get updated.
*/
union cvmx_mio_uartx_srt
{
uint64_t u64;
struct cvmx_mio_uartx_srt_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_2_63 : 62;
uint64_t srt : 2; /**< Shadow RX Trigger */
#else
uint64_t srt : 2;
uint64_t reserved_2_63 : 62;
#endif
} s;
struct cvmx_mio_uartx_srt_s cn30xx;
struct cvmx_mio_uartx_srt_s cn31xx;
struct cvmx_mio_uartx_srt_s cn38xx;
struct cvmx_mio_uartx_srt_s cn38xxp2;
struct cvmx_mio_uartx_srt_s cn50xx;
struct cvmx_mio_uartx_srt_s cn52xx;
struct cvmx_mio_uartx_srt_s cn52xxp1;
struct cvmx_mio_uartx_srt_s cn56xx;
struct cvmx_mio_uartx_srt_s cn56xxp1;
struct cvmx_mio_uartx_srt_s cn58xx;
struct cvmx_mio_uartx_srt_s cn58xxp1;
struct cvmx_mio_uartx_srt_s cn63xx;
struct cvmx_mio_uartx_srt_s cn63xxp1;
};
typedef union cvmx_mio_uartx_srt cvmx_mio_uartx_srt_t;
typedef cvmx_mio_uartx_srt_t cvmx_uart_srt_t;
/**
* cvmx_mio_uart#_srts
*
* MIO_UARTX_SRTS = MIO UARTX Shadow Request To Send Register
*
* The Shadow Request To Send Register (SRTS) is a shadow register for the RTS bit (MCR bit 1) that can
* be used to remove the burden of having to perform a read-modify-write on the MCR.
*/
union cvmx_mio_uartx_srts
{
uint64_t u64;
struct cvmx_mio_uartx_srts_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_1_63 : 63;
uint64_t srts : 1; /**< Shadow Request To Send */
#else
uint64_t srts : 1;
uint64_t reserved_1_63 : 63;
#endif
} s;
struct cvmx_mio_uartx_srts_s cn30xx;
struct cvmx_mio_uartx_srts_s cn31xx;
struct cvmx_mio_uartx_srts_s cn38xx;
struct cvmx_mio_uartx_srts_s cn38xxp2;
struct cvmx_mio_uartx_srts_s cn50xx;
struct cvmx_mio_uartx_srts_s cn52xx;
struct cvmx_mio_uartx_srts_s cn52xxp1;
struct cvmx_mio_uartx_srts_s cn56xx;
struct cvmx_mio_uartx_srts_s cn56xxp1;
struct cvmx_mio_uartx_srts_s cn58xx;
struct cvmx_mio_uartx_srts_s cn58xxp1;
struct cvmx_mio_uartx_srts_s cn63xx;
struct cvmx_mio_uartx_srts_s cn63xxp1;
};
typedef union cvmx_mio_uartx_srts cvmx_mio_uartx_srts_t;
typedef cvmx_mio_uartx_srts_t cvmx_uart_srts_t;
/**
* cvmx_mio_uart#_stt
*
* MIO_UARTX_STT = MIO UARTX Shadow TX Trigger Register
*
* The Shadow TX Trigger Register (STT) is a shadow register for the TX Trigger bits (FCR bits 5:4) that
* can be used to remove the burden of having to store the previously written value to the FCR in memory
* and having to mask this value so that only the TX Trigger bits get updated.
*/
union cvmx_mio_uartx_stt
{
uint64_t u64;
struct cvmx_mio_uartx_stt_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_2_63 : 62;
uint64_t stt : 2; /**< Shadow TX Trigger */
#else
uint64_t stt : 2;
uint64_t reserved_2_63 : 62;
#endif
} s;
struct cvmx_mio_uartx_stt_s cn30xx;
struct cvmx_mio_uartx_stt_s cn31xx;
struct cvmx_mio_uartx_stt_s cn38xx;
struct cvmx_mio_uartx_stt_s cn38xxp2;
struct cvmx_mio_uartx_stt_s cn50xx;
struct cvmx_mio_uartx_stt_s cn52xx;
struct cvmx_mio_uartx_stt_s cn52xxp1;
struct cvmx_mio_uartx_stt_s cn56xx;
struct cvmx_mio_uartx_stt_s cn56xxp1;
struct cvmx_mio_uartx_stt_s cn58xx;
struct cvmx_mio_uartx_stt_s cn58xxp1;
struct cvmx_mio_uartx_stt_s cn63xx;
struct cvmx_mio_uartx_stt_s cn63xxp1;
};
typedef union cvmx_mio_uartx_stt cvmx_mio_uartx_stt_t;
typedef cvmx_mio_uartx_stt_t cvmx_uart_stt_t;
/**
* cvmx_mio_uart#_tfl
*
* MIO_UARTX_TFL = MIO UARTX Transmit FIFO Level Register
*
* The Transmit FIFO Level Register (TFL) indicates the number of data entries in the transmit FIFO.
*/
union cvmx_mio_uartx_tfl
{
uint64_t u64;
struct cvmx_mio_uartx_tfl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_7_63 : 57;
uint64_t tfl : 7; /**< Transmit FIFO Level Register */
#else
uint64_t tfl : 7;
uint64_t reserved_7_63 : 57;
#endif
} s;
struct cvmx_mio_uartx_tfl_s cn30xx;
struct cvmx_mio_uartx_tfl_s cn31xx;
struct cvmx_mio_uartx_tfl_s cn38xx;
struct cvmx_mio_uartx_tfl_s cn38xxp2;
struct cvmx_mio_uartx_tfl_s cn50xx;
struct cvmx_mio_uartx_tfl_s cn52xx;
struct cvmx_mio_uartx_tfl_s cn52xxp1;
struct cvmx_mio_uartx_tfl_s cn56xx;
struct cvmx_mio_uartx_tfl_s cn56xxp1;
struct cvmx_mio_uartx_tfl_s cn58xx;
struct cvmx_mio_uartx_tfl_s cn58xxp1;
struct cvmx_mio_uartx_tfl_s cn63xx;
struct cvmx_mio_uartx_tfl_s cn63xxp1;
};
typedef union cvmx_mio_uartx_tfl cvmx_mio_uartx_tfl_t;
typedef cvmx_mio_uartx_tfl_t cvmx_uart_tfl_t;
/**
* cvmx_mio_uart#_tfr
*
* MIO_UARTX_TFR = MIO UARTX Transmit FIFO Read Register
*
* The Transmit FIFO Read Register (TFR) is only valid when FIFO access mode is enabled (FAR bit 0 is
* set). When FIFOs are enabled, reading this register gives the data at the top of the transmit FIFO.
* Each consecutive read pops the transmit FIFO and gives the next data value that is currently at the
* top of the FIFO. When FIFOs are not enabled, reading this register gives the data in the THR.
*/
union cvmx_mio_uartx_tfr
{
uint64_t u64;
struct cvmx_mio_uartx_tfr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t tfr : 8; /**< Transmit FIFO Read Register */
#else
uint64_t tfr : 8;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uartx_tfr_s cn30xx;
struct cvmx_mio_uartx_tfr_s cn31xx;
struct cvmx_mio_uartx_tfr_s cn38xx;
struct cvmx_mio_uartx_tfr_s cn38xxp2;
struct cvmx_mio_uartx_tfr_s cn50xx;
struct cvmx_mio_uartx_tfr_s cn52xx;
struct cvmx_mio_uartx_tfr_s cn52xxp1;
struct cvmx_mio_uartx_tfr_s cn56xx;
struct cvmx_mio_uartx_tfr_s cn56xxp1;
struct cvmx_mio_uartx_tfr_s cn58xx;
struct cvmx_mio_uartx_tfr_s cn58xxp1;
struct cvmx_mio_uartx_tfr_s cn63xx;
struct cvmx_mio_uartx_tfr_s cn63xxp1;
};
typedef union cvmx_mio_uartx_tfr cvmx_mio_uartx_tfr_t;
typedef cvmx_mio_uartx_tfr_t cvmx_uart_tfr_t;
/**
* cvmx_mio_uart#_thr
*
* MIO_UARTX_THR = MIO UARTX Transmit Holding Register
*
* Transmit Holding Register (THR) is a write-only register that contains data to be transmitted on the
* serial output port (sout). Data can be written to the THR any time that the THR Empty (THRE) bit of
* the Line Status Register (LSR) is set.
*
* If FIFOs are not enabled and THRE is set, writing a single character to the THR clears the THRE. Any
* additional writes to the THR before the THRE is set again causes the THR data to be overwritten.
*
* If FIFOs are enabled and THRE is set (and Programmable THRE mode disabled), 64 characters of data may
* be written to the THR before the FIFO is full. Any attempt to write data when the FIFO is full results
* in the write data being lost.
*
* Note: The Divisor Latch Address Bit (DLAB) of the Line Control Register (LCR) must be clear to access
* this register.
*
* Note: The address below is an alias to simplify these CSR descriptions. It should be known that the
* RBR, THR, and DLL registers are the same.
*/
union cvmx_mio_uartx_thr
{
uint64_t u64;
struct cvmx_mio_uartx_thr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t thr : 8; /**< Transmit Holding Register */
#else
uint64_t thr : 8;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uartx_thr_s cn30xx;
struct cvmx_mio_uartx_thr_s cn31xx;
struct cvmx_mio_uartx_thr_s cn38xx;
struct cvmx_mio_uartx_thr_s cn38xxp2;
struct cvmx_mio_uartx_thr_s cn50xx;
struct cvmx_mio_uartx_thr_s cn52xx;
struct cvmx_mio_uartx_thr_s cn52xxp1;
struct cvmx_mio_uartx_thr_s cn56xx;
struct cvmx_mio_uartx_thr_s cn56xxp1;
struct cvmx_mio_uartx_thr_s cn58xx;
struct cvmx_mio_uartx_thr_s cn58xxp1;
struct cvmx_mio_uartx_thr_s cn63xx;
struct cvmx_mio_uartx_thr_s cn63xxp1;
};
typedef union cvmx_mio_uartx_thr cvmx_mio_uartx_thr_t;
typedef cvmx_mio_uartx_thr_t cvmx_uart_thr_t;
/**
* cvmx_mio_uart#_usr
*
* MIO_UARTX_USR = MIO UARTX UART Status Register
*
* The UART Status Register (USR) contains UART status information.
*
* USR bit 0 is the BUSY bit. When set this bit indicates that a serial transfer is in progress, when
* clear it indicates that the UART is idle or inactive.
*
* Note: In PASS3, the BUSY bit will always be clear.
*
* USR bits 1-4 indicate the following FIFO status: TX FIFO Not Full (TFNF), TX FIFO Empty (TFE), RX
* FIFO Not Empty (RFNE), and RX FIFO Full (RFF).
*/
union cvmx_mio_uartx_usr
{
uint64_t u64;
struct cvmx_mio_uartx_usr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_5_63 : 59;
uint64_t rff : 1; /**< RX FIFO Full */
uint64_t rfne : 1; /**< RX FIFO Not Empty */
uint64_t tfe : 1; /**< TX FIFO Empty */
uint64_t tfnf : 1; /**< TX FIFO Not Full */
uint64_t busy : 1; /**< Busy bit (always 0 in PASS3) */
#else
uint64_t busy : 1;
uint64_t tfnf : 1;
uint64_t tfe : 1;
uint64_t rfne : 1;
uint64_t rff : 1;
uint64_t reserved_5_63 : 59;
#endif
} s;
struct cvmx_mio_uartx_usr_s cn30xx;
struct cvmx_mio_uartx_usr_s cn31xx;
struct cvmx_mio_uartx_usr_s cn38xx;
struct cvmx_mio_uartx_usr_s cn38xxp2;
struct cvmx_mio_uartx_usr_s cn50xx;
struct cvmx_mio_uartx_usr_s cn52xx;
struct cvmx_mio_uartx_usr_s cn52xxp1;
struct cvmx_mio_uartx_usr_s cn56xx;
struct cvmx_mio_uartx_usr_s cn56xxp1;
struct cvmx_mio_uartx_usr_s cn58xx;
struct cvmx_mio_uartx_usr_s cn58xxp1;
struct cvmx_mio_uartx_usr_s cn63xx;
struct cvmx_mio_uartx_usr_s cn63xxp1;
};
typedef union cvmx_mio_uartx_usr cvmx_mio_uartx_usr_t;
typedef cvmx_mio_uartx_usr_t cvmx_uart_usr_t;
/**
* cvmx_mio_uart2_dlh
*/
union cvmx_mio_uart2_dlh
{
uint64_t u64;
struct cvmx_mio_uart2_dlh_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t dlh : 8; /**< Divisor Latch High Register */
#else
uint64_t dlh : 8;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uart2_dlh_s cn52xx;
struct cvmx_mio_uart2_dlh_s cn52xxp1;
};
typedef union cvmx_mio_uart2_dlh cvmx_mio_uart2_dlh_t;
/**
* cvmx_mio_uart2_dll
*/
union cvmx_mio_uart2_dll
{
uint64_t u64;
struct cvmx_mio_uart2_dll_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t dll : 8; /**< Divisor Latch Low Register */
#else
uint64_t dll : 8;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uart2_dll_s cn52xx;
struct cvmx_mio_uart2_dll_s cn52xxp1;
};
typedef union cvmx_mio_uart2_dll cvmx_mio_uart2_dll_t;
/**
* cvmx_mio_uart2_far
*/
union cvmx_mio_uart2_far
{
uint64_t u64;
struct cvmx_mio_uart2_far_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_1_63 : 63;
uint64_t far : 1; /**< FIFO Access Register */
#else
uint64_t far : 1;
uint64_t reserved_1_63 : 63;
#endif
} s;
struct cvmx_mio_uart2_far_s cn52xx;
struct cvmx_mio_uart2_far_s cn52xxp1;
};
typedef union cvmx_mio_uart2_far cvmx_mio_uart2_far_t;
/**
* cvmx_mio_uart2_fcr
*/
union cvmx_mio_uart2_fcr
{
uint64_t u64;
struct cvmx_mio_uart2_fcr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t rxtrig : 2; /**< RX Trigger */
uint64_t txtrig : 2; /**< TX Trigger */
uint64_t reserved_3_3 : 1;
uint64_t txfr : 1; /**< TX FIFO reset */
uint64_t rxfr : 1; /**< RX FIFO reset */
uint64_t en : 1; /**< FIFO enable */
#else
uint64_t en : 1;
uint64_t rxfr : 1;
uint64_t txfr : 1;
uint64_t reserved_3_3 : 1;
uint64_t txtrig : 2;
uint64_t rxtrig : 2;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uart2_fcr_s cn52xx;
struct cvmx_mio_uart2_fcr_s cn52xxp1;
};
typedef union cvmx_mio_uart2_fcr cvmx_mio_uart2_fcr_t;
/**
* cvmx_mio_uart2_htx
*/
union cvmx_mio_uart2_htx
{
uint64_t u64;
struct cvmx_mio_uart2_htx_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_1_63 : 63;
uint64_t htx : 1; /**< Halt TX */
#else
uint64_t htx : 1;
uint64_t reserved_1_63 : 63;
#endif
} s;
struct cvmx_mio_uart2_htx_s cn52xx;
struct cvmx_mio_uart2_htx_s cn52xxp1;
};
typedef union cvmx_mio_uart2_htx cvmx_mio_uart2_htx_t;
/**
* cvmx_mio_uart2_ier
*/
union cvmx_mio_uart2_ier
{
uint64_t u64;
struct cvmx_mio_uart2_ier_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t ptime : 1; /**< Programmable THRE Interrupt mode enable */
uint64_t reserved_4_6 : 3;
uint64_t edssi : 1; /**< Enable Modem Status Interrupt */
uint64_t elsi : 1; /**< Enable Receiver Line Status Interrupt */
uint64_t etbei : 1; /**< Enable Transmitter Holding Register Empty Interrupt */
uint64_t erbfi : 1; /**< Enable Received Data Available Interrupt */
#else
uint64_t erbfi : 1;
uint64_t etbei : 1;
uint64_t elsi : 1;
uint64_t edssi : 1;
uint64_t reserved_4_6 : 3;
uint64_t ptime : 1;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uart2_ier_s cn52xx;
struct cvmx_mio_uart2_ier_s cn52xxp1;
};
typedef union cvmx_mio_uart2_ier cvmx_mio_uart2_ier_t;
/**
* cvmx_mio_uart2_iir
*/
union cvmx_mio_uart2_iir
{
uint64_t u64;
struct cvmx_mio_uart2_iir_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t fen : 2; /**< FIFO-enabled bits */
uint64_t reserved_4_5 : 2;
uint64_t iid : 4; /**< Interrupt ID */
#else
uint64_t iid : 4;
uint64_t reserved_4_5 : 2;
uint64_t fen : 2;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uart2_iir_s cn52xx;
struct cvmx_mio_uart2_iir_s cn52xxp1;
};
typedef union cvmx_mio_uart2_iir cvmx_mio_uart2_iir_t;
/**
* cvmx_mio_uart2_lcr
*/
union cvmx_mio_uart2_lcr
{
uint64_t u64;
struct cvmx_mio_uart2_lcr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t dlab : 1; /**< Divisor Latch Address bit */
uint64_t brk : 1; /**< Break Control bit */
uint64_t reserved_5_5 : 1;
uint64_t eps : 1; /**< Even Parity Select bit */
uint64_t pen : 1; /**< Parity Enable bit */
uint64_t stop : 1; /**< Stop Control bit */
uint64_t cls : 2; /**< Character Length Select */
#else
uint64_t cls : 2;
uint64_t stop : 1;
uint64_t pen : 1;
uint64_t eps : 1;
uint64_t reserved_5_5 : 1;
uint64_t brk : 1;
uint64_t dlab : 1;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uart2_lcr_s cn52xx;
struct cvmx_mio_uart2_lcr_s cn52xxp1;
};
typedef union cvmx_mio_uart2_lcr cvmx_mio_uart2_lcr_t;
/**
* cvmx_mio_uart2_lsr
*/
union cvmx_mio_uart2_lsr
{
uint64_t u64;
struct cvmx_mio_uart2_lsr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t ferr : 1; /**< Error in Receiver FIFO bit */
uint64_t temt : 1; /**< Transmitter Empty bit */
uint64_t thre : 1; /**< Transmitter Holding Register Empty bit */
uint64_t bi : 1; /**< Break Interrupt bit */
uint64_t fe : 1; /**< Framing Error bit */
uint64_t pe : 1; /**< Parity Error bit */
uint64_t oe : 1; /**< Overrun Error bit */
uint64_t dr : 1; /**< Data Ready bit */
#else
uint64_t dr : 1;
uint64_t oe : 1;
uint64_t pe : 1;
uint64_t fe : 1;
uint64_t bi : 1;
uint64_t thre : 1;
uint64_t temt : 1;
uint64_t ferr : 1;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uart2_lsr_s cn52xx;
struct cvmx_mio_uart2_lsr_s cn52xxp1;
};
typedef union cvmx_mio_uart2_lsr cvmx_mio_uart2_lsr_t;
/**
* cvmx_mio_uart2_mcr
*/
union cvmx_mio_uart2_mcr
{
uint64_t u64;
struct cvmx_mio_uart2_mcr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_6_63 : 58;
uint64_t afce : 1; /**< Auto Flow Control Enable bit */
uint64_t loop : 1; /**< Loopback bit */
uint64_t out2 : 1; /**< OUT2 output bit */
uint64_t out1 : 1; /**< OUT1 output bit */
uint64_t rts : 1; /**< Request To Send output bit */
uint64_t dtr : 1; /**< Data Terminal Ready output bit */
#else
uint64_t dtr : 1;
uint64_t rts : 1;
uint64_t out1 : 1;
uint64_t out2 : 1;
uint64_t loop : 1;
uint64_t afce : 1;
uint64_t reserved_6_63 : 58;
#endif
} s;
struct cvmx_mio_uart2_mcr_s cn52xx;
struct cvmx_mio_uart2_mcr_s cn52xxp1;
};
typedef union cvmx_mio_uart2_mcr cvmx_mio_uart2_mcr_t;
/**
* cvmx_mio_uart2_msr
*/
union cvmx_mio_uart2_msr
{
uint64_t u64;
struct cvmx_mio_uart2_msr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t dcd : 1; /**< Data Carrier Detect input bit */
uint64_t ri : 1; /**< Ring Indicator input bit */
uint64_t dsr : 1; /**< Data Set Ready input bit */
uint64_t cts : 1; /**< Clear To Send input bit */
uint64_t ddcd : 1; /**< Delta Data Carrier Detect bit */
uint64_t teri : 1; /**< Trailing Edge of Ring Indicator bit */
uint64_t ddsr : 1; /**< Delta Data Set Ready bit */
uint64_t dcts : 1; /**< Delta Clear To Send bit */
#else
uint64_t dcts : 1;
uint64_t ddsr : 1;
uint64_t teri : 1;
uint64_t ddcd : 1;
uint64_t cts : 1;
uint64_t dsr : 1;
uint64_t ri : 1;
uint64_t dcd : 1;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uart2_msr_s cn52xx;
struct cvmx_mio_uart2_msr_s cn52xxp1;
};
typedef union cvmx_mio_uart2_msr cvmx_mio_uart2_msr_t;
/**
* cvmx_mio_uart2_rbr
*/
union cvmx_mio_uart2_rbr
{
uint64_t u64;
struct cvmx_mio_uart2_rbr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t rbr : 8; /**< Receive Buffer Register */
#else
uint64_t rbr : 8;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uart2_rbr_s cn52xx;
struct cvmx_mio_uart2_rbr_s cn52xxp1;
};
typedef union cvmx_mio_uart2_rbr cvmx_mio_uart2_rbr_t;
/**
* cvmx_mio_uart2_rfl
*/
union cvmx_mio_uart2_rfl
{
uint64_t u64;
struct cvmx_mio_uart2_rfl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_7_63 : 57;
uint64_t rfl : 7; /**< Receive FIFO Level Register */
#else
uint64_t rfl : 7;
uint64_t reserved_7_63 : 57;
#endif
} s;
struct cvmx_mio_uart2_rfl_s cn52xx;
struct cvmx_mio_uart2_rfl_s cn52xxp1;
};
typedef union cvmx_mio_uart2_rfl cvmx_mio_uart2_rfl_t;
/**
* cvmx_mio_uart2_rfw
*/
union cvmx_mio_uart2_rfw
{
uint64_t u64;
struct cvmx_mio_uart2_rfw_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_10_63 : 54;
uint64_t rffe : 1; /**< Receive FIFO Framing Error */
uint64_t rfpe : 1; /**< Receive FIFO Parity Error */
uint64_t rfwd : 8; /**< Receive FIFO Write Data */
#else
uint64_t rfwd : 8;
uint64_t rfpe : 1;
uint64_t rffe : 1;
uint64_t reserved_10_63 : 54;
#endif
} s;
struct cvmx_mio_uart2_rfw_s cn52xx;
struct cvmx_mio_uart2_rfw_s cn52xxp1;
};
typedef union cvmx_mio_uart2_rfw cvmx_mio_uart2_rfw_t;
/**
* cvmx_mio_uart2_sbcr
*/
union cvmx_mio_uart2_sbcr
{
uint64_t u64;
struct cvmx_mio_uart2_sbcr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_1_63 : 63;
uint64_t sbcr : 1; /**< Shadow Break Control */
#else
uint64_t sbcr : 1;
uint64_t reserved_1_63 : 63;
#endif
} s;
struct cvmx_mio_uart2_sbcr_s cn52xx;
struct cvmx_mio_uart2_sbcr_s cn52xxp1;
};
typedef union cvmx_mio_uart2_sbcr cvmx_mio_uart2_sbcr_t;
/**
* cvmx_mio_uart2_scr
*/
union cvmx_mio_uart2_scr
{
uint64_t u64;
struct cvmx_mio_uart2_scr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t scr : 8; /**< Scratchpad Register */
#else
uint64_t scr : 8;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uart2_scr_s cn52xx;
struct cvmx_mio_uart2_scr_s cn52xxp1;
};
typedef union cvmx_mio_uart2_scr cvmx_mio_uart2_scr_t;
/**
* cvmx_mio_uart2_sfe
*/
union cvmx_mio_uart2_sfe
{
uint64_t u64;
struct cvmx_mio_uart2_sfe_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_1_63 : 63;
uint64_t sfe : 1; /**< Shadow FIFO Enable */
#else
uint64_t sfe : 1;
uint64_t reserved_1_63 : 63;
#endif
} s;
struct cvmx_mio_uart2_sfe_s cn52xx;
struct cvmx_mio_uart2_sfe_s cn52xxp1;
};
typedef union cvmx_mio_uart2_sfe cvmx_mio_uart2_sfe_t;
/**
* cvmx_mio_uart2_srr
*/
union cvmx_mio_uart2_srr
{
uint64_t u64;
struct cvmx_mio_uart2_srr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_3_63 : 61;
uint64_t stfr : 1; /**< Shadow TX FIFO Reset */
uint64_t srfr : 1; /**< Shadow RX FIFO Reset */
uint64_t usr : 1; /**< UART Soft Reset */
#else
uint64_t usr : 1;
uint64_t srfr : 1;
uint64_t stfr : 1;
uint64_t reserved_3_63 : 61;
#endif
} s;
struct cvmx_mio_uart2_srr_s cn52xx;
struct cvmx_mio_uart2_srr_s cn52xxp1;
};
typedef union cvmx_mio_uart2_srr cvmx_mio_uart2_srr_t;
/**
* cvmx_mio_uart2_srt
*/
union cvmx_mio_uart2_srt
{
uint64_t u64;
struct cvmx_mio_uart2_srt_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_2_63 : 62;
uint64_t srt : 2; /**< Shadow RX Trigger */
#else
uint64_t srt : 2;
uint64_t reserved_2_63 : 62;
#endif
} s;
struct cvmx_mio_uart2_srt_s cn52xx;
struct cvmx_mio_uart2_srt_s cn52xxp1;
};
typedef union cvmx_mio_uart2_srt cvmx_mio_uart2_srt_t;
/**
* cvmx_mio_uart2_srts
*/
union cvmx_mio_uart2_srts
{
uint64_t u64;
struct cvmx_mio_uart2_srts_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_1_63 : 63;
uint64_t srts : 1; /**< Shadow Request To Send */
#else
uint64_t srts : 1;
uint64_t reserved_1_63 : 63;
#endif
} s;
struct cvmx_mio_uart2_srts_s cn52xx;
struct cvmx_mio_uart2_srts_s cn52xxp1;
};
typedef union cvmx_mio_uart2_srts cvmx_mio_uart2_srts_t;
/**
* cvmx_mio_uart2_stt
*/
union cvmx_mio_uart2_stt
{
uint64_t u64;
struct cvmx_mio_uart2_stt_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_2_63 : 62;
uint64_t stt : 2; /**< Shadow TX Trigger */
#else
uint64_t stt : 2;
uint64_t reserved_2_63 : 62;
#endif
} s;
struct cvmx_mio_uart2_stt_s cn52xx;
struct cvmx_mio_uart2_stt_s cn52xxp1;
};
typedef union cvmx_mio_uart2_stt cvmx_mio_uart2_stt_t;
/**
* cvmx_mio_uart2_tfl
*/
union cvmx_mio_uart2_tfl
{
uint64_t u64;
struct cvmx_mio_uart2_tfl_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_7_63 : 57;
uint64_t tfl : 7; /**< Transmit FIFO Level Register */
#else
uint64_t tfl : 7;
uint64_t reserved_7_63 : 57;
#endif
} s;
struct cvmx_mio_uart2_tfl_s cn52xx;
struct cvmx_mio_uart2_tfl_s cn52xxp1;
};
typedef union cvmx_mio_uart2_tfl cvmx_mio_uart2_tfl_t;
/**
* cvmx_mio_uart2_tfr
*/
union cvmx_mio_uart2_tfr
{
uint64_t u64;
struct cvmx_mio_uart2_tfr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t tfr : 8; /**< Transmit FIFO Read Register */
#else
uint64_t tfr : 8;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uart2_tfr_s cn52xx;
struct cvmx_mio_uart2_tfr_s cn52xxp1;
};
typedef union cvmx_mio_uart2_tfr cvmx_mio_uart2_tfr_t;
/**
* cvmx_mio_uart2_thr
*/
union cvmx_mio_uart2_thr
{
uint64_t u64;
struct cvmx_mio_uart2_thr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_8_63 : 56;
uint64_t thr : 8; /**< Transmit Holding Register */
#else
uint64_t thr : 8;
uint64_t reserved_8_63 : 56;
#endif
} s;
struct cvmx_mio_uart2_thr_s cn52xx;
struct cvmx_mio_uart2_thr_s cn52xxp1;
};
typedef union cvmx_mio_uart2_thr cvmx_mio_uart2_thr_t;
/**
* cvmx_mio_uart2_usr
*/
union cvmx_mio_uart2_usr
{
uint64_t u64;
struct cvmx_mio_uart2_usr_s
{
#if __BYTE_ORDER == __BIG_ENDIAN
uint64_t reserved_5_63 : 59;
uint64_t rff : 1; /**< RX FIFO Full */
uint64_t rfne : 1; /**< RX FIFO Not Empty */
uint64_t tfe : 1; /**< TX FIFO Empty */
uint64_t tfnf : 1; /**< TX FIFO Not Full */
uint64_t busy : 1; /**< Busy bit (always 0 in PASS3) */
#else
uint64_t busy : 1;
uint64_t tfnf : 1;
uint64_t tfe : 1;
uint64_t rfne : 1;
uint64_t rff : 1;
uint64_t reserved_5_63 : 59;
#endif
} s;
struct cvmx_mio_uart2_usr_s cn52xx;
struct cvmx_mio_uart2_usr_s cn52xxp1;
};
typedef union cvmx_mio_uart2_usr cvmx_mio_uart2_usr_t;
#endif