/******************************************************************************* *Copyright (c) 2014 PMC-Sierra, Inc. All rights reserved. * *Redistribution and use in source and binary forms, with or without modification, are permitted provided *that the following conditions are met: *1. Redistributions of source code must retain the above copyright notice, this list of conditions and the *following disclaimer. *2. 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. * *THIS SOFTWARE IS PROVIDED BY THE AUTHOR AND CONTRIBUTORS ``AS IS'' AND ANY EXPRESS OR IMPLIED *WARRANTIES,INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS *FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE AUTHOR OR CONTRIBUTORS BE LIABLE *FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT *NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR *BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT *LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS *SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE * * $FreeBSD$ * ********************************************************************************/ /*******************************************************************************/ /*! \file sa.h * \brief The file defines the constants, data structure, and functions defined by LL API */ /******************************************************************************/ #ifndef __SA_H__ #define __SA_H__ #include #include /* TestBase needed to have the 'Multi-Data fetch disable' feature */ #define SA_CONFIG_MDFD_REGISTRY #define OSSA_OFFSET_OF(STRUCT_TYPE, FEILD) \ (bitptr)&(((STRUCT_TYPE *)0)->FEILD) #if defined(SA_CPU_LITTLE_ENDIAN) #define OSSA_WRITE_LE_16(AGROOT, DMA_ADDR, OFFSET, VALUE16) \ (*((bit16 *)(((bit8 *)DMA_ADDR)+(OFFSET)))) = (bit16)(VALUE16); #define OSSA_WRITE_LE_32(AGROOT, DMA_ADDR, OFFSET, VALUE32) \ (*((bit32 *)(((bit8 *)DMA_ADDR)+(OFFSET)))) = (bit32)(VALUE32); #define OSSA_READ_LE_16(AGROOT, ADDR16, DMA_ADDR, OFFSET) \ (*((bit16 *)ADDR16)) = (*((bit16 *)(((bit8 *)DMA_ADDR)+(OFFSET)))) #define OSSA_READ_LE_32(AGROOT, ADDR32, DMA_ADDR, OFFSET) \ (*((bit32 *)ADDR32)) = (*((bit32 *)(((bit8 *)DMA_ADDR)+(OFFSET)))) #define OSSA_WRITE_BE_16(AGROOT, DMA_ADDR, OFFSET, VALUE16) \ (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)))) = (bit8)((((bit16)VALUE16)>>8)&0xFF); \ (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)+1))) = (bit8)(((bit16)VALUE16)&0xFF); #define OSSA_WRITE_BE_32(AGROOT, DMA_ADDR, OFFSET, VALUE32) \ (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)))) = (bit8)((((bit32)VALUE32)>>24)&0xFF); \ (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)+1))) = (bit8)((((bit32)VALUE32)>>16)&0xFF); \ (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)+2))) = (bit8)((((bit32)VALUE32)>>8)&0xFF); \ (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)+3))) = (bit8)(((bit32)VALUE32)&0xFF); #define OSSA_READ_BE_16(AGROOT, ADDR16, DMA_ADDR, OFFSET) \ (*(bit8 *)(((bit8 *)ADDR16)+1)) = (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)))); \ (*(bit8 *)(((bit8 *)ADDR16))) = (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)+1))); #define OSSA_READ_BE_32(AGROOT, ADDR32, DMA_ADDR, OFFSET) \ (*(bit8 *)(((bit8 *)ADDR32)+3)) = (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)))); \ (*(bit8 *)(((bit8 *)ADDR32)+2)) = (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)+1))); \ (*(bit8 *)(((bit8 *)ADDR32)+1)) = (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)+2))); \ (*(bit8 *)(((bit8 *)ADDR32))) = (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)+3))); #define OSSA_WRITE_BYTE_STRING(AGROOT, DEST_ADDR, SRC_ADDR, LEN) \ si_memcpy(DEST_ADDR, SRC_ADDR, LEN); #elif defined(SA_CPU_BIG_ENDIAN) #define OSSA_WRITE_LE_16(AGROOT, DMA_ADDR, OFFSET, VALUE16) \ (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)+1))) = (bit8)((((bit16)VALUE16)>>8)&0xFF); \ (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)))) = (bit8)(((bit16)VALUE16)&0xFF); #define OSSA_WRITE_LE_32(AGROOT, DMA_ADDR, OFFSET, VALUE32) \ (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)+3))) = (bit8)((((bit32)VALUE32)>>24)&0xFF); \ (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)+2))) = (bit8)((((bit32)VALUE32)>>16)&0xFF); \ (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)+1))) = (bit8)((((bit32)VALUE32)>>8)&0xFF); \ (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)))) = (bit8)(((bit32)VALUE32)&0xFF); #define OSSA_READ_LE_16(AGROOT, ADDR16, DMA_ADDR, OFFSET) \ (*(bit8 *)(((bit8 *)ADDR16)+1)) = (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)))); \ (*(bit8 *)(((bit8 *)ADDR16))) = (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)+1))); #define OSSA_READ_LE_32(AGROOT, ADDR32, DMA_ADDR, OFFSET) \ (*((bit8 *)(((bit8 *)ADDR32)+3))) = (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)))); \ (*((bit8 *)(((bit8 *)ADDR32)+2))) = (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)+1))); \ (*((bit8 *)(((bit8 *)ADDR32)+1))) = (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)+2))); \ (*((bit8 *)(((bit8 *)ADDR32)))) = (*((bit8 *)(((bit8 *)DMA_ADDR)+(OFFSET)+3))); #define OSSA_WRITE_BE_16(AGROOT, DMA_ADDR, OFFSET, VALUE16) \ (*((bit16 *)(((bit8 *)DMA_ADDR)+(OFFSET)))) = (bit16)(VALUE16); #define OSSA_WRITE_BE_32(AGROOT, DMA_ADDR, OFFSET, VALUE32) \ (*((bit32 *)(((bit8 *)DMA_ADDR)+(OFFSET)))) = (bit32)(VALUE32); #define OSSA_READ_BE_16(AGROOT, ADDR16, DMA_ADDR, OFFSET) \ (*((bit16 *)ADDR16)) = (*((bit16 *)(((bit8 *)DMA_ADDR)+(OFFSET)))); #define OSSA_READ_BE_32(AGROOT, ADDR32, DMA_ADDR, OFFSET) \ (*((bit32 *)ADDR32)) = (*((bit32 *)(((bit8 *)DMA_ADDR)+(OFFSET)))); #define OSSA_WRITE_BYTE_STRING(AGROOT, DEST_ADDR, SRC_ADDR, LEN) \ si_memcpy(DEST_ADDR, SRC_ADDR, LEN); #else #error (Host CPU endianess undefined!!) #endif #define AGSA_WRITE_SGL(sglDest, sgLower, sgUpper, len, extReserved) \ OSSA_WRITE_LE_32(agRoot, sglDest, 0, sgLower); \ OSSA_WRITE_LE_32(agRoot, sglDest, 4, sgUpper); \ OSSA_WRITE_LE_32(agRoot, sglDest, 8, len); \ OSSA_WRITE_LE_32(agRoot, sglDest, 12, extReserved); /************************************************************************** * define byte swap macro * **************************************************************************/ /*! \def AGSA_FLIP_2_BYTES(_x) * \brief AGSA_FLIP_2_BYTES macro * * use to flip two bytes */ #define AGSA_FLIP_2_BYTES(_x) ((bit16)(((((bit16)(_x))&0x00FF)<<8)| \ ((((bit16)(_x))&0xFF00)>>8))) /*! \def AGSA_FLIP_4_BYTES(_x) * \brief AGSA_FLIP_4_BYTES macro * * use to flip four bytes */ #define AGSA_FLIP_4_BYTES(_x) ((bit32)(((((bit32)(_x))&0x000000FF)<<24)| \ ((((bit32)(_x))&0x0000FF00)<<8)| \ ((((bit32)(_x))&0x00FF0000)>>8)| \ ((((bit32)(_x))&0xFF000000)>>24))) #if defined(SA_CPU_LITTLE_ENDIAN) /*! \def LEBIT16_TO_BIT16(_x) * \brief LEBIT16_TO_BIT16 macro * * use to convert little endian bit16 to host bit16 */ #ifndef LEBIT16_TO_BIT16 #define LEBIT16_TO_BIT16(_x) (_x) #endif /*! \def BIT16_TO_LEBIT16(_x) * \brief BIT16_TO_LEBIT16 macro * * use to convert host bit16 to little endian bit16 */ #ifndef BIT16_TO_LEBIT16 #define BIT16_TO_LEBIT16(_x) (_x) #endif /*! \def BEBIT16_TO_BIT16(_x) * \brief BEBIT16_TO_BIT16 macro * * use to convert big endian bit16 to host bit16 */ #ifndef BEBIT16_TO_BIT16 #define BEBIT16_TO_BIT16(_x) AGSA_FLIP_2_BYTES(_x) #endif /*! \def BIT16_TO_BEBIT16(_x) * \brief BIT16_TO_BEBIT16 macro * * use to convert host bit16 to big endian bit16 */ #ifndef BIT16_TO_BEBIT16 #define BIT16_TO_BEBIT16(_x) AGSA_FLIP_2_BYTES(_x) #endif /*! \def LEBIT32_TO_BIT32(_x) * \brief LEBIT32_TO_BIT32 macro * * use to convert little endian bit32 to host bit32 */ #ifndef LEBIT32_TO_BIT32 #define LEBIT32_TO_BIT32(_x) (_x) #endif /*! \def BIT32_TO_LEBIT32(_x) * \brief BIT32_TO_LEBIT32 macro * * use to convert host bit32 to little endian bit32 */ #ifndef BIT32_TO_LEBIT32 #define BIT32_TO_LEBIT32(_x) (_x) #endif /*! \def BEBIT32_TO_BIT32(_x) * \brief BEBIT32_TO_BIT32 macro * * use to convert big endian bit32 to host bit32 */ #ifndef BEBIT32_TO_BIT32 #define BEBIT32_TO_BIT32(_x) AGSA_FLIP_4_BYTES(_x) #endif /*! \def BIT32_TO_BEBIT32(_x) * \brief BIT32_TO_BEBIT32 macro * * use to convert host bit32 to big endian bit32 */ #ifndef BIT32_TO_BEBIT32 #define BIT32_TO_BEBIT32(_x) AGSA_FLIP_4_BYTES(_x) #endif /* * bit8 to Byte[x] of bit32 */ #ifndef BIT8_TO_BIT32_B0 #define BIT8_TO_BIT32_B0(_x) ((bit32)(_x)) #endif #ifndef BIT8_TO_BIT32_B1 #define BIT8_TO_BIT32_B1(_x) (((bit32)(_x)) << 8) #endif #ifndef BIT8_TO_BIT32_B2 #define BIT8_TO_BIT32_B2(_x) (((bit32)(_x)) << 16) #endif #ifndef BIT8_TO_BIT32_B3 #define BIT8_TO_BIT32_B3(_x) (((bit32)(_x)) << 24) #endif /* * Byte[x] of bit32 to bit8 */ #ifndef BIT32_B0_TO_BIT8 #define BIT32_B0_TO_BIT8(_x) ((bit8)(((bit32)(_x)) & 0x000000FF)) #endif #ifndef BIT32_B1_TO_BIT8 #define BIT32_B1_TO_BIT8(_x) ((bit8)((((bit32)(_x)) & 0x0000FF00) >> 8)) #endif #ifndef BIT32_B2_TO_BIT8 #define BIT32_B2_TO_BIT8(_x) ((bit8)((((bit32)(_x)) & 0x00FF0000) >> 16)) #endif #ifndef BIT32_B3_TO_BIT8 #define BIT32_B3_TO_BIT8(_x) ((bit8)((((bit32)(_x)) & 0xFF000000) >> 24)) #endif #elif defined(SA_CPU_BIG_ENDIAN) /*! \def LEBIT16_TO_BIT16(_x) * \brief LEBIT16_TO_BIT16 macro * * use to convert little endian bit16 to host bit16 */ #ifndef LEBIT16_TO_BIT16 #define LEBIT16_TO_BIT16(_x) AGSA_FLIP_2_BYTES(_x) #endif /*! \def BIT16_TO_LEBIT16(_x) * \brief BIT16_TO_LEBIT16 macro * * use to convert host bit16 to little endian bit16 */ #ifndef BIT16_TO_LEBIT16 #define BIT16_TO_LEBIT16(_x) AGSA_FLIP_2_BYTES(_x) #endif /*! \def BEBIT16_TO_BIT16(_x) * \brief BEBIT16_TO_BIT16 macro * * use to convert big endian bit16 to host bit16 */ #ifndef BEBIT16_TO_BIT16 #define BEBIT16_TO_BIT16(_x) (_x) #endif /*! \def BIT16_TO_BEBIT16(_x) * \brief BIT16_TO_BEBIT16 macro * * use to convert host bit16 to big endian bit16 */ #ifndef BIT16_TO_BEBIT16 #define BIT16_TO_BEBIT16(_x) (_x) #endif /*! \def LEBIT32_TO_BIT32(_x) * \brief LEBIT32_TO_BIT32 macro * * use to convert little endian bit32 to host bit32 */ #ifndef LEBIT32_TO_BIT32 #define LEBIT32_TO_BIT32(_x) AGSA_FLIP_4_BYTES(_x) #endif /*! \def BIT32_TO_LEBIT32(_x) * \brief BIT32_TO_LEBIT32 macro * * use to convert host bit32 to little endian bit32 */ #ifndef BIT32_TO_LEBIT32 #define BIT32_TO_LEBIT32(_x) AGSA_FLIP_4_BYTES(_x) #endif /*! \def BEBIT32_TO_BIT32(_x) * \brief BEBIT32_TO_BIT32 macro * * use to convert big endian bit32 to host bit32 */ #ifndef BEBIT32_TO_BIT32 #define BEBIT32_TO_BIT32(_x) (_x) #endif /*! \def BIT32_TO_BEBIT32(_x) * \brief BIT32_TO_BEBIT32 macro * * use to convert host bit32 to big endian bit32 */ #ifndef BIT32_TO_BEBIT32 #define BIT32_TO_BEBIT32(_x) (_x) #endif /* * bit8 to Byte[x] of bit32 */ #ifndef BIT8_TO_BIT32_B0 #define BIT8_TO_BIT32_B0(_x) (((bit32)(_x)) << 24) #endif #ifndef BIT8_TO_BIT32_B1 #define BIT8_TO_BIT32_B1(_x) (((bit32)(_x)) << 16) #endif #ifndef BIT8_TO_BIT32_B2 #define BIT8_TO_BIT32_B2(_x) (((bit32)(_x)) << 8) #endif #ifndef BIT8_TO_BIT32_B3 #define BIT8_TO_BIT32_B3(_x) ((bit32)(_x)) #endif /* * Byte[x] of bit32 to bit8 */ #ifndef BIT32_B0_TO_BIT8 #define BIT32_B0_TO_BIT8(_x) ((bit8)((((bit32)(_x)) & 0xFF000000) >> 24)) #endif #ifndef BIT32_B1_TO_BIT8 #define BIT32_B1_TO_BIT8(_x) ((bit8)((((bit32)(_x)) & 0x00FF0000) >> 16)) #endif #ifndef BIT32_B2_TO_BIT8 #define BIT32_B2_TO_BIT8(_x) ((bit8)((((bit32)(_x)) & 0x0000FF00) >> 8)) #endif #ifndef BIT32_B3_TO_BIT8 #define BIT32_B3_TO_BIT8(_x) ((bit8)(((bit32)(_x)) & 0x000000FF)) #endif #else #error No definition of SA_CPU_BIG_ENDIAN or SA_CPU_LITTLE_ENDIAN #endif #if defined(SA_DMA_LITTLE_ENDIAN) /* * ** bit32 to bit32 * */ #ifndef DMA_BIT32_TO_BIT32 #define DMA_BIT32_TO_BIT32(_x) (_x) #endif #ifndef DMA_LEBIT32_TO_BIT32 #define DMA_LEBIT32_TO_BIT32(_x) (_x) #endif #ifndef DMA_BEBIT32_TO_BIT32 #define DMA_BEBIT32_TO_BIT32(_x) AGSA_FLIP_4_BYTES(_x) #endif #ifndef BIT32_TO_DMA_BIT32 #define BIT32_TO_DMA_BIT32(_x) (_x) #endif #ifndef BIT32_TO_DMA_LEBIT32 #define BIT32_TO_DMA_LEBIT32(_x) (_x) #endif #ifndef BIT32_TO_DMA_BEBIT32 #define BIT32_TO_DMA_BEBIT32(_x) AGSA_FLIP_4_BYTES(_x) #endif /* * ** bit16 to bit16 * */ #ifndef DMA_BIT16_TO_BIT16 #define DMA_BIT16_TO_BIT16(_x) (_x) #endif #ifndef DMA_LEBIT16_TO_BIT16 #define DMA_LEBIT16_TO_BIT16(_x) (_x) #endif #ifndef DMA_BEBIT16_TO_BIT16 #define DMA_BEBIT16_TO_BIT16(_x) AGSA_FLIP_2_BYTES(_x) #endif #ifndef BIT16_TO_DMA_BIT16 #define BIT16_TO_DMA_BIT16(_x) (_x) #endif #ifndef BIT16_TO_DMA_LEBIT16 #define BIT16_TO_DMA_LEBIT16(_x) (_x) #endif #ifndef BIT16_TO_DMA_BEBIT16 #define BIT16_TO_DMA_BEBIT16(_x) AGSA_FLIP_2_BYTES(_x) #endif #if defined(SA_CPU_LITTLE_ENDIAN) #ifndef BEBIT32_TO_DMA_BEBIT32 #define BEBIT32_TO_DMA_BEBIT32(_x) (_x) #endif #ifndef LEBIT32_TO_DMA_LEBIT32 #define LEBIT32_TO_DMA_LEBIT32(_x) (_x) #endif #ifndef DMA_LEBIT32_TO_LEBIT32 #define DMA_LEBIT32_TO_LEBIT32(_x) (_x) #endif #ifndef DMA_BEBIT32_TO_BEBIT32 #define DMA_BEBIT32_TO_BEBIT32(_x) (_x) #endif /* * ** bit16 to bit16 * */ #ifndef BEBIT16_TO_DMA_BEBIT16 #define BEBIT16_TO_DMA_BEBIT16(_x) (_x) #endif #ifndef LEBIT16_TO_DMA_LEBIT16 #define LEBIT16_TO_DMA_LEBIT16(_x) (_x) #endif #ifndef DMA_LEBIT16_TO_LEBIT16 #define DMA_LEBIT16_TO_LEBIT16(_x) (_x) #endif #ifndef DMA_BEBIT16_TO_BEBIT16 #define DMA_BEBIT16_TO_BEBIT16(_x) (_x) #endif #else /* defined(SA_CPU_BIG_ENDIAN) */ /* * ** bit32 to bit32 * */ #ifndef BEBIT32_TO_DMA_BEBIT32 #define BEBIT32_TO_DMA_BEBIT32(_x) AGSA_FLIP_4_BYTES(_x) #endif #ifndef LEBIT32_TO_DMA_LEBIT32 #define LEBIT32_TO_DMA_LEBIT32(_x) AGSA_FLIP_4_BYTES(_x) #endif #ifndef DMA_LEBIT32_TO_LEBIT32 #define DMA_LEBIT32_TO_LEBIT32(_x) AGSA_FLIP_4_BYTES(_x) #endif #ifndef DMA_BEBIT32_TO_BEBIT32 #define DMA_BEBIT32_TO_BEBIT32(_x) AGSA_FLIP_4_BYTES(_x) #endif /* * ** bit16 to bit16 * */ #ifndef BEBIT16_TO_DMA_BEBIT16 #define BEBIT16_TO_DMA_BEBIT16(_x) AGSA_FLIP_2_BYTES(_x) #endif #ifndef LEBIT16_TO_DMA_LEBIT16 #define LEBIT16_TO_DMA_LEBIT16(_x) AGSA_FLIP_2_BYTES(_x) #endif #ifndef DMA_LEBIT16_TO_LEBIT16 #define DMA_LEBIT16_TO_LEBIT16(_x) AGSA_FLIP_2_BYTES(_x) #endif #ifndef DMA_BEBIT16_TO_BEBIT16 #define DMA_BEBIT16_TO_BEBIT16(_x) AGSA_FLIP_2_BYTES(_x) #endif #endif /* * bit8 to Byte[x] of bit32 */ #ifndef BIT8_TO_DMA_BIT32_B0 #define BIT8_TO_DMA_BIT32_B0(_x) ((bit32)(_x)) #endif #ifndef BIT8_TO_DMA_BIT32_B1 #define BIT8_TO_DMA_BIT32_B1(_x) (((bit32)(_x)) << 8) #endif #ifndef BIT8_TO_DMA_BIT32_B2 #define BIT8_TO_DMA_BIT32_B2(_x) (((bit32)(_x)) << 16) #endif #ifndef BIT8_TO_DMA_BIT32_B3 #define BIT8_TO_DMA_BIT32_B3(_x) (((bit32)(_x)) << 24) #endif /* * Byte[x] of bit32 to bit8 */ #ifndef DMA_BIT32_B0_TO_BIT8 #define DMA_BIT32_B0_TO_BIT8(_x) ((bit8)(((bit32)(_x)) & 0x000000FF)) #endif #ifndef DMA_BIT32_B1_TO_BIT8 #define DMA_BIT32_B1_TO_BIT8(_x) ((bit8)((((bit32)(_x)) & 0x0000FF00) >> 8)) #endif #ifndef DMA_BIT32_B2_TO_BIT8 #define DMA_BIT32_B2_TO_BIT8(_x) ((bit8)((((bit32)(_x)) & 0x00FF0000) >> 16)) #endif #ifndef DMA_BIT32_B3_TO_BIT8 #define DMA_BIT32_B3_TO_BIT8(_x) ((bit8)((((bit32)(_x)) & 0xFF000000) >> 24)) #endif /*| | | end of DMA access macros for LITTLE ENDIAN | --------------------------------------------------------------------- */ #elif defined(SA_DMA_BIG_ENDIAN) /* DMA big endian */ /*-------------------------------------------------------------------- | DMA buffer access macros for BIG ENDIAN | | | */ /* bit32 to bit32 */ #ifndef DMA_BEBIT32_TO_BIT32 #define DMA_BEBIT32_TO_BIT32(_x) (_x) #endif #ifndef DMA_LEBIT32_TO_BIT32 #define DMA_LEBIT32_TO_BIT32(_x) AGSA_FLIP_4_BYTES(_x) #endif #ifndef BIT32_TO_DMA_BIT32 #define BIT32_TO_DMA_BIT32(_x) (_x) #endif #ifndef BIT32_TO_DMA_LEBIT32 #define BIT32_TO_DMA_LEBIT32(_x) AGSA_FLIP_4_BYTES(_x) #endif #ifndef BIT32_TO_DMA_BEBIT32 #define BIT32_TO_DMA_BEBIT32(_x) (_x) #endif /* bit16 to bit16 */ #ifndef DMA_BEBIT16_TO_BIT16 #define DMA_BEBIT16_TO_BIT16(_x) (_x) #endif #ifndef DMA_LEBIT16_TO_BIT16 #define DMA_LEBIT16_TO_BIT16(_x) AGSA_FLIP_2_BYTES(_x) #endif #ifndef BIT16_TO_DMA_BIT16 #define BIT16_TO_DMA_BIT16(_x) (_x) #endif #ifndef BIT16_TO_DMA_LEBIT16 #define BIT16_TO_DMA_LEBIT16(_x) AGSA_FLIP_2_BYTES(_x) #endif #ifndef BIT16_TO_DMA_BEBIT16 #define BIT16_TO_DMA_BEBIT16(_x) (_x) #endif #if defined(SA_CPU_LITTLE_ENDIAN) /* CPU little endain */ /* bit32 to bit32 */ #ifndef BEBIT32_TO_DMA_BEBIT32 #define BEBIT32_TO_DMA_BEBIT32(_x) AGSA_FLIP_4_BYTES(_x) #endif #ifndef LEBIT32_TO_DMA_LEBIT32 #define LEBIT32_TO_DMA_LEBIT32(_x) AGSA_FLIP_4_BYTES(_x) #endif #ifndef DMA_LEBIT32_TO_LEBIT32 #define DMA_LEBIT32_TO_LEBIT32(_x) AGSA_FLIP_4_BYTES(_x) #endif #ifndef DMA_BEBIT32_TO_BEBIT32 #define DMA_BEBIT32_TO_BEBIT32(_x) AGSA_FLIP_4_BYTES(_x) #endif /* bit16 to bit16 */ #ifndef BEBIT16_TO_DMA_BEBIT16 #define BEBIT16_TO_DMA_BEBIT16(_x) AGSA_FLIP_2_BYTES(_x) #endif #ifndef LEBIT16_TO_DMA_LEBIT16 #define LEBIT16_TO_DMA_LEBIT16(_x) AGSA_FLIP_2_BYTES(_x) #endif #ifndef DMA_LEBIT16_TO_LEBIT16 #define DMA_LEBIT16_TO_LEBIT16(_x) AGSA_FLIP_2_BYTES(_x) #endif #ifndef DMA_BEBIT16_TO_BEBIT16 #define DMA_BEBIT16_TO_BEBIT16(_x) AGSA_FLIP_2_BYTES(_x) #endif #else /* defined(SA_CPU_BIG_ENDIAN) */ /* bit32 to bit32 */ #ifndef BEBIT32_TO_DMA_BEBIT32 #define BEBIT32_TO_DMA_BEBIT32(_x) (_x) #endif #ifndef LEBIT32_TO_DMA_LEBIT32 #define LEBIT32_TO_DMA_LEBIT32(_x) (_x) #endif #ifndef DMA_LEBIT32_TO_LEBIT32 #define DMA_LEBIT32_TO_LEBIT32(_x) (_x) #endif #ifndef DMA_BEBIT32_TO_BEBIT32 #define DMA_BEBIT32_TO_BEBIT32(_x) (_x) #endif /* bit16 to bit16 */ #ifndef BEBIT16_TO_DMA_BEBIT16 #define BEBIT16_TO_DMA_BEBIT16(_x) (_x) #endif #ifndef LEBIT16_TO_DMA_LEBIT16 #define LEBIT16_TO_DMA_LEBIT16(_x) (_x) #endif #ifndef DMA_LEBIT16_TO_LEBIT16 #define DMA_LEBIT16_TO_LEBIT16(_x) (_x) #endif #ifndef DMA_BEBIT16_TO_BEBIT16 #define DMA_BEBIT16_TO_BEBIT16(_x) (_x) #endif #endif /* * bit8 to Byte[x] of bit32 */ #ifndef BIT8_TO_DMA_BIT32_B0 #define BIT8_TO_DMA_BIT32_B0(_x) (((bit32)(_x)) << 24) #endif #ifndef BIT8_TO_DMA_BIT32_B1 #define BIT8_TO_DMA_BIT32_B1(_x) (((bit32)(_x)) << 16) #endif #ifndef BIT8_TO_DMA_BIT32_B2 #define BIT8_TO_DMA_BIT32_B2(_x) (((bit32)(_x)) << 8) #endif #ifndef BIT8_TO_DMA_BIT32_B3 #define BIT8_TO_DMA_BIT32_B3(_x) ((bit32)(_x)) #endif /* * ** Byte[x] of bit32 to bit8 * */ #ifndef DMA_BIT32_B0_TO_BIT8 #define DMA_BIT32_B0_TO_BIT8(_x) ((bit8)((((bit32)(_x)) & 0xFF000000) >> 24)) #endif #ifndef DMA_BIT32_B1_TO_BIT8 #define DMA_BIT32_B1_TO_BIT8(_x) ((bit8)((((bit32)(_x)) & 0x00FF0000) >> 16)) #endif #ifndef DMA_BIT32_B2_TO_BIT8 #define DMA_BIT32_B2_TO_BIT8(_x) ((bit8)((((bit32)(_x)) & 0x0000FF00) >> 8)) #endif #ifndef DMA_BIT32_B3_TO_BIT8 #define DMA_BIT32_B3_TO_BIT8(_x) ((bit8)(((bit32)(_x)) & 0x000000FF)) #endif /*| | | end of DMA access macros for BIG ENDIAN | --------------------------------------------------------------------- */ #else #error No definition of SA_DMA_BIG_ENDIAN or SA_DMA_LITTLE_ENDIAN #endif /* DMA endian */ /* * End of DMA buffer access macros * * * ********************************************************************** */ /************************************************************************************ * * * Constants defined for LL Layer starts * * * ************************************************************************************/ /********************************************************* * sTSDK LL revision and Interface revision, FW version *********************************************************/ #define FW_THIS_VERSION_SPC12G 0x03060005 #define FW_THIS_VERSION_SPC6G 0x02092400 #define FW_THIS_VERSION_SPC 0x01110000 #define STSDK_LL_INTERFACE_VERSION 0x20A #define STSDK_LL_OLD_INTERFACE_VERSION 0x1 /* SPC and SPCv before 02030401 */ #define STSDK_LL_VERSION FW_THIS_VERSION_SPC6G /**< current sTSDK version */ #define MAX_FW_VERSION_SUPPORTED FW_THIS_VERSION_SPC6G /**< FW */ #define MATCHING_V_FW_VERSION FW_THIS_VERSION_SPC6G /**< current V matching FW version */ #define MIN_FW_SPCVE_VERSION_SUPPORTED 0x02000000 /**< 2.00 FW */ #define STSDK_LL_12G_INTERFACE_VERSION 0x302 #define STSDK_LL_12G_VERSION FW_THIS_VERSION_SPC12G /**< current sTSDK version */ #define MAX_FW_12G_VERSION_SUPPORTED FW_THIS_VERSION_SPC12G /**< FW */ #define MATCHING_12G_V_FW_VERSION FW_THIS_VERSION_SPC12G /**< current V matching FW version */ #define MIN_FW_12G_SPCVE_VERSION_SUPPORTED 0x03000000 /**< 3.00 FW */ #define STSDK_LL_SPC_VERSION 0x01100000 /**< current SPC FW version supported */ #define MATCHING_SPC_FW_VERSION FW_THIS_VERSION_SPC /**< current SPC matching FW version */ #define MIN_FW_SPC_VERSION_SUPPORTED 0x01062502 /**< 1.06d FW */ #define STSDK_LL_INTERFACE_VERSION_IGNORE_MASK 0xF00 /************************************************* * constants for API return values *************************************************/ #define AGSA_RC_SUCCESS 0x00 /**< Successful function return value */ #define AGSA_RC_FAILURE 0x01 /**< Failed function return value */ #define AGSA_RC_BUSY 0x02 /**< Busy function return value */ /* current only return from saGetControllerInfo() and saGetControllerStatus() */ #define AGSA_RC_HDA_NO_FW_RUNNING 0x03 /**< HDA mode and no FW running */ #define AGSA_RC_FW_NOT_IN_READY_STATE 0x04 /**< FW not in ready state */ /* current only return from saInitialize() for version checking */ #define AGSA_RC_VERSION_INCOMPATIBLE 0x05 /**< Version mismatch */ #define AGSA_RC_VERSION_UNTESTED 0x06 /**< Version not tested */ #define AGSA_RC_NOT_SUPPORTED 0x07 /**< Operation not supported on the current hardware */ #define AGSA_RC_COMPLETE 0x08 /************************************************* * constants for type field in agsaMem_t *************************************************/ #define AGSA_CACHED_MEM 0x00 /**< CACHED memory type */ #define AGSA_DMA_MEM 0x01 /**< DMA memory type */ #define AGSA_CACHED_DMA_MEM 0x02 /**< CACHED DMA memory type */ #ifdef SA_ENABLE_TRACE_FUNCTIONS #ifdef FAST_IO_TEST #define AGSA_NUM_MEM_CHUNKS (12 + AGSA_MAX_INBOUND_Q + AGSA_MAX_OUTBOUND_Q) /**< max # of memory chunks supported */ #else #define AGSA_NUM_MEM_CHUNKS (11 + AGSA_MAX_INBOUND_Q + AGSA_MAX_OUTBOUND_Q) /**< max # of memory chunks supported */ #endif #else #ifdef FAST_IO_TEST #define AGSA_NUM_MEM_CHUNKS (11 + AGSA_MAX_INBOUND_Q + AGSA_MAX_OUTBOUND_Q) /**< max # of memory chunks supported */ #else #define AGSA_NUM_MEM_CHUNKS (10 + AGSA_MAX_INBOUND_Q + AGSA_MAX_OUTBOUND_Q) /**< max # of memory chunks supported */ #endif #endif /* END SA_ENABLE_TRACE_FUNCTIONS */ /********************************** * default constant for phy count **********************************/ #define AGSA_MAX_VALID_PHYS 16 /* was 8 for SPC */ /**< max # of phys supported by the hardware */ /************************************ * default constant for Esgl entries ************************************/ #define MAX_ESGL_ENTRIES 10 /**< max # of extended SG list entry */ /******************************************* * constant for max inbound/outbound queues *******************************************/ #define AGSA_MAX_INBOUND_Q 64 /**< max # of inbound queue */ #define AGSA_MAX_OUTBOUND_Q 64 /**< max # of outbound queue */ #define AGSA_MAX_BEST_INBOUND_Q 16 /* Max inbound Q number with good IO performance */ /**************************** * Phy Control constants ****************************/ #define AGSA_PHY_LINK_RESET 0x01 #define AGSA_PHY_HARD_RESET 0x02 #define AGSA_PHY_GET_ERROR_COUNTS 0x03 /* SPC only used in original saLocalPhyControl */ #define AGSA_PHY_CLEAR_ERROR_COUNTS 0x04 /* SPC only */ #define AGSA_PHY_GET_BW_COUNTS 0x05 /* SPC only */ #define AGSA_PHY_NOTIFY_ENABLE_SPINUP 0x10 #define AGSA_PHY_BROADCAST_ASYNCH_EVENT 0x12 #define AGSA_PHY_COMINIT_OOB 0x20 #define AGSA_SAS_PHY_ERR_COUNTERS_PAGE 0x01 /* retrieve the SAS PHY error counters */ #define AGSA_SAS_PHY_ERR_COUNTERS_CLR_PAGE 0x02 /* retrieve the SAS PHY error counters After capturing the errors, the hardware error counters are cleared and restarted. */ #define AGSA_SAS_PHY_BW_COUNTERS_PAGE 0x03 /* retrieve the SAS PHY transmit and receive bandwidth counters. */ #define AGSA_SAS_PHY_ANALOG_SETTINGS_PAGE 0x04 /* retrieve the SAS PHY analog settings */ #define AGSA_SAS_PHY_GENERAL_STATUS_PAGE 0x05 /* retrieve the SAS PHY general status for the PHY specified in the phyID parameter */ #define AGSA_PHY_SNW3_PAGE 0x06 #define AGSA_PHY_RATE_CONTROL_PAGE 0x07 /* Used to set several rate control parameters. */ #define AGSA_SAS_PHY_MISC_PAGE 0x08 #define AGSA_SAS_PHY_OPEN_REJECT_RETRY_BACKOFF_THRESHOLD_PAGE 0x08 /* Used to set retry and backoff threshold parameters. */ /***************** * HW Reset *****************/ #define AGSA_CHIP_RESET 0x00 /**< flag to reset hard reset */ #define AGSA_SOFT_RESET 0x01 /**< flag to reset the controller chip */ /*************************************** * Discovery Types ***************************************/ #define AG_SA_DISCOVERY_TYPE_SAS 0x00 /**< flag to discover SAS devices */ #define AG_SA_DISCOVERY_TYPE_SATA 0x01 /**< flag to discover SATA devices */ /*************************************** * Discovery Options ***************************************/ #define AG_SA_DISCOVERY_OPTION_FULL_START 0x00 /**< flag to start full discovery */ #define AG_SA_DISCOVERY_OPTION_INCREMENTAL_START 0x01 /**< flag to start incremental discovery */ #define AG_SA_DISCOVERY_OPTION_ABORT 0x02 /**< flag to abort a discovery */ /**************************************************************** * SSP/SMP/SATA Request type ****************************************************************/ /* bit31-28 - request type bit27-16 - reserved bit15-10 - SATA ATAP bit9-8 - direction bit7 - AUTO bit6 - reserved bit5 - EXT bit4 - MSG bit3-0 - Initiator, target or task mode (1 to 8) */ #define AGSA_REQTYPE_MASK 0xF0000000 /**< request type mask */ #define AGSA_REQ_TYPE_UNKNOWN 0x00000000 /**< unknown request type */ #define AGSA_SSP_REQTYPE 0x80000000 #define AGSA_SMP_REQTYPE 0x40000000 #define AGSA_SATA_REQTYPE 0x20000000 #define AGSA_DIR_MASK 0x00000300 #define AGSA_AUTO_MASK 0x00000080 #define AGSA_SATA_ATAP_MASK 0x0000FC00 #define AGSA_DIR_NONE 0x00000000 #define AGSA_DIR_CONTROLLER_TO_HOST 0x00000100 /**< used to be called AGSA_DIR_READ */ #define AGSA_DIR_HOST_TO_CONTROLLER 0x00000200 /**< used to be called AGSA_DIR_WRITE */ /* bit definition - AUTO mode */ #define AGSA_AUTO_GOOD_RESPONSE 0x00000080 /* request type - not bit difination */ #define AGSA_SSP_INIT 0x00000001 #define AGSA_SSP_TGT_MODE 0x00000003 #define AGSA_SSP_TASK_MGNT 0x00000005 #define AGSA_SSP_TGT_RSP 0x00000006 #define AGSA_SMP_INIT 0x00000007 #define AGSA_SMP_TGT 0x00000008 /* request type for SSP Initiator and extend */ #define AGSA_SSP_INIT_EXT (AGSA_SSP_INIT | AGSA_SSP_EXT_BIT) /* request type for SSP Initiator and indirect */ #define AGSA_SSP_INIT_INDIRECT (AGSA_SSP_INIT | AGSA_SSP_INDIRECT_BIT) /* bit definition */ #define AGSA_MSG 0x00000010 #define AGSA_SSP_EXT_BIT 0x00000020 #define AGSA_SSP_INDIRECT_BIT 0x00000040 #define AGSA_MSG_BIT AGSA_MSG >> 2 /* agsaSSPIniEncryptIOStartCmd_t dirMTlr bits*/ #define AGSA_INDIRECT_CDB_BIT 0x00000008 #define AGSA_SKIP_MASK_BIT 0x00000010 #define AGSA_ENCRYPT_BIT 0x00000020 #define AGSA_DIF_BIT 0x00000040 #define AGSA_DIF_LA_BIT 0x00000080 #define AGSA_DIRECTION_BITS 0x00000300 #define AGSA_SKIP_MASK_OFFSET_BITS 0x0F000000 #define AGSA_SSP_INFO_LENGTH_BITS 0xF0000000 /* agsaSSPTgtIOStartCmd_t INITagAgrDir bits */ #define AGSA_SSP_TGT_BITS_INI_TAG 0xFFFF0000 /* 16 31 */ #define AGSA_SSP_TGT_BITS_ODS 0x00008000 /* 15 */ #define AGSA_SSP_TGT_BITS_DEE_DIF 0x00004000 /* 14 */ #define AGSA_SSP_TGT_BITS_DEE 0x00002000 /* 13 14 */ #define AGSA_SSP_TGT_BITS_R 0x00001000 /* 12 */ #define AGSA_SSP_TGT_BITS_DAD 0x00000600 /* 11 10 */ #define AGSA_SSP_TGT_BITS_DIR 0x00000300 /* 8 9 */ #define AGSA_SSP_TGT_BITS_DIR_IN 0x00000100 /* 8 9 */ #define AGSA_SSP_TGT_BITS_DIR_OUT 0x00000200 /* 8 9 */ #define AGSA_SSP_TGT_BITS_AGR 0x00000080 /* 7 */ #define AGSA_SSP_TGT_BITS_RDF 0x00000040 /* 6 */ #define AGSA_SSP_TGT_BITS_RTE 0x00000030 /* 4 5 */ #define AGSA_SSP_TGT_BITS_AN 0x00000006 /* 2 3 */ /* agsaSSPIniEncryptIOStartCmd_t DIF_flags bit definitions */ #define AGSA_DIF_UPDATE_BITS 0xFC000000 #define AGSA_DIF_VERIFY_BITS 0x03F00000 #define AGSA_DIF_BLOCK_SIZE_BITS 0x000F0000 #define AGSA_DIF_ENABLE_BLOCK_COUNT_BIT 0x00000040 #define AGSA_DIF_CRC_SEED_BIT 0x00000020 #define AGSA_DIF_CRC_INVERT_BIT 0x00000010 #define AGSA_DIF_CRC_VERIFY_BIT 0x00000008 #define AGSA_DIF_OP_BITS 0x00000007 #define AGSA_DIF_OP_INSERT 0x00000000 #define AGSA_DIF_OP_VERIFY_AND_FORWARD 0x00000001 #define AGSA_DIF_OP_VERIFY_AND_DELETE 0x00000002 #define AGSA_DIF_OP_VERIFY_AND_REPLACE 0x00000003 #define AGSA_DIF_OP_RESERVED2 0x00000004 #define AGSA_DIF_OP_VERIFY_UDT_REPLACE_CRC 0x00000005 #define AGSA_DIF_OP_RESERVED3 0x00000006 #define AGSA_DIF_OP_REPLACE_UDT_REPLACE_CRC 0x00000007 /* agsaSSPIniEncryptIOStartCmd_t EncryptFlagsLo bit definitions */ #define AGSA_ENCRYPT_DEK_BITS 0xFFFFFF000 #define AGSA_ENCRYPT_SKIP_DIF_BIT 0x000000010 #define AGSA_ENCRYPT_KEY_TABLE_BITS 0x00000000C #define AGSA_ENCRYPT_KEY_TAG_BIT 0x000000002 /* Cipher mode to be used for this I/O. */ #define AGSA_ENCRYPT_ECB_Mode 0 #define AGSA_ENCRYPT_XTS_Mode 0x6 /* agsaSSPIniEncryptIOStartCmd_t EncryptFlagsHi bit definitions */ #define AGSA_ENCRYPT_KEK_SELECT_BITS 0x0000000E0 #define AGSA_ENCRYPT_SECTOR_SIZE_BITS 0x00000001F /* defined in the sTSDK spec. */ #define AGSA_SSP_INIT_NONDATA (AGSA_SSP_REQTYPE | AGSA_DIR_NONE | AGSA_SSP_INIT) /**< SSP initiator non data request type */ #define AGSA_SSP_INIT_READ (AGSA_SSP_REQTYPE | AGSA_DIR_CONTROLLER_TO_HOST | AGSA_SSP_INIT) /**< SSP initiator read request type */ #define AGSA_SSP_INIT_WRITE (AGSA_SSP_REQTYPE | AGSA_DIR_HOST_TO_CONTROLLER | AGSA_SSP_INIT) /**< SSP initiator write request type */ #define AGSA_SSP_TGT_READ_DATA (AGSA_SSP_REQTYPE | AGSA_DIR_HOST_TO_CONTROLLER | AGSA_SSP_TGT_MODE) /**< SSP target read data request type */ #define AGSA_SSP_TGT_READ (AGSA_SSP_REQTYPE | AGSA_DIR_HOST_TO_CONTROLLER | AGSA_SSP_TGT_MODE) /**< SSP target read data request type */ #define AGSA_SSP_TGT_READ_GOOD_RESP (AGSA_SSP_REQTYPE | AGSA_DIR_HOST_TO_CONTROLLER | AGSA_SSP_TGT_MODE | AGSA_AUTO_GOOD_RESPONSE) /**< SSP target read data with automatic good response request type */ #define AGSA_SSP_TGT_WRITE_DATA (AGSA_SSP_REQTYPE | AGSA_DIR_CONTROLLER_TO_HOST | AGSA_SSP_TGT_MODE) /**< SSP target write data request type */ #define AGSA_SSP_TGT_WRITE (AGSA_SSP_REQTYPE | AGSA_DIR_CONTROLLER_TO_HOST | AGSA_SSP_TGT_MODE) /**< SSP target write data request type */ #define AGSA_SSP_TGT_WRITE_GOOD_RESP (AGSA_SSP_REQTYPE | AGSA_DIR_CONTROLLER_TO_HOST | AGSA_SSP_TGT_MODE | AGSA_AUTO_GOOD_RESPONSE) /**< SSP target write data request type with automatic good response request type*/ #define AGSA_SSP_TASK_MGNT_REQ (AGSA_SSP_REQTYPE | AGSA_SSP_TASK_MGNT) /**< SSP task management request type */ #define AGSA_SSP_TGT_CMD_OR_TASK_RSP (AGSA_SSP_REQTYPE | AGSA_SSP_TGT_RSP) /**< SSP command or task management response request type */ #define AGSA_SMP_INIT_REQ (AGSA_SMP_REQTYPE | AGSA_SMP_INIT) /**< SMP initiator request type */ #define AGSA_SMP_TGT_RESPONSE (AGSA_SMP_REQTYPE | AGSA_SMP_TGT) /**< SMP target response request type */ #define AGSA_SSP_INIT_READ_M (AGSA_SSP_REQTYPE | AGSA_DIR_CONTROLLER_TO_HOST | AGSA_SSP_INIT | AGSA_MSG) #define AGSA_SSP_INIT_WRITE_M (AGSA_SSP_REQTYPE | AGSA_DIR_HOST_TO_CONTROLLER | AGSA_SSP_INIT | AGSA_MSG) #define AGSA_SSP_TASK_MGNT_REQ_M (AGSA_SSP_REQTYPE | AGSA_SSP_TASK_MGNT | AGSA_MSG) #define AGSA_SSP_INIT_READ_EXT (AGSA_SSP_REQTYPE | AGSA_DIR_CONTROLLER_TO_HOST | AGSA_SSP_INIT_EXT) /**< SSP initiator read request Ext type */ #define AGSA_SSP_INIT_WRITE_EXT (AGSA_SSP_REQTYPE | AGSA_DIR_HOST_TO_CONTROLLER | AGSA_SSP_INIT_EXT) /**< SSP initiator write request Ext type */ #define AGSA_SSP_INIT_READ_INDIRECT (AGSA_SSP_REQTYPE | AGSA_DIR_CONTROLLER_TO_HOST | AGSA_SSP_INIT_INDIRECT) /**< SSP initiator read request indirect type */ #define AGSA_SSP_INIT_WRITE_INDIRECT (AGSA_SSP_REQTYPE | AGSA_DIR_HOST_TO_CONTROLLER | AGSA_SSP_INIT_INDIRECT) /**< SSP initiator write request indirect type */ #define AGSA_SSP_INIT_READ_INDIRECT_M (AGSA_SSP_REQTYPE | AGSA_DIR_CONTROLLER_TO_HOST | AGSA_SSP_INIT_INDIRECT | AGSA_MSG) /**< SSP initiator read request indirect type */ #define AGSA_SSP_INIT_WRITE_INDIRECT_M (AGSA_SSP_REQTYPE | AGSA_DIR_HOST_TO_CONTROLLER | AGSA_SSP_INIT_INDIRECT | AGSA_MSG) /**< SSP initiator write request indirect type */ #define AGSA_SSP_INIT_READ_EXT_M (AGSA_SSP_REQTYPE | AGSA_DIR_CONTROLLER_TO_HOST | AGSA_SSP_INIT_EXT | AGSA_MSG) #define AGSA_SSP_INIT_WRITE_EXT_M (AGSA_SSP_REQTYPE | AGSA_DIR_HOST_TO_CONTROLLER | AGSA_SSP_INIT_EXT | AGSA_MSG) #define AGSA_SMP_IOCTL_REQUEST 0xFFFFFFFF #define AGSA_SATA_ATAP_SRST_ASSERT 0x00000400 #define AGSA_SATA_ATAP_SRST_DEASSERT 0x00000800 #define AGSA_SATA_ATAP_EXECDEVDIAG 0x00000C00 #define AGSA_SATA_ATAP_NON_DATA 0x00001000 #define AGSA_SATA_ATAP_PIO 0x00001400 #define AGSA_SATA_ATAP_DMA 0x00001800 #define AGSA_SATA_ATAP_NCQ 0x00001C00 #define AGSA_SATA_ATAP_PKT_DEVRESET 0x00002000 #define AGSA_SATA_ATAP_PKT 0x00002400 #define AGSA_SATA_PROTOCOL_NON_DATA (AGSA_SATA_REQTYPE | AGSA_DIR_NONE | AGSA_SATA_ATAP_NON_DATA) #define AGSA_SATA_PROTOCOL_PIO_READ (AGSA_SATA_REQTYPE | AGSA_DIR_CONTROLLER_TO_HOST | AGSA_SATA_ATAP_PIO) /**< SATA PIO read request type */ #define AGSA_SATA_PROTOCOL_DMA_READ (AGSA_SATA_REQTYPE | AGSA_DIR_CONTROLLER_TO_HOST | AGSA_SATA_ATAP_DMA) /**< SATA DMA read request type */ #define AGSA_SATA_PROTOCOL_FPDMA_READ (AGSA_SATA_REQTYPE | AGSA_DIR_CONTROLLER_TO_HOST | AGSA_SATA_ATAP_NCQ) /**< SATA FDMA read request type */ #define AGSA_SATA_PROTOCOL_PIO_WRITE (AGSA_SATA_REQTYPE | AGSA_DIR_HOST_TO_CONTROLLER | AGSA_SATA_ATAP_PIO) /**< SATA PIO read request type */ #define AGSA_SATA_PROTOCOL_DMA_WRITE (AGSA_SATA_REQTYPE | AGSA_DIR_HOST_TO_CONTROLLER | AGSA_SATA_ATAP_DMA) /**< SATA DMA read request type */ #define AGSA_SATA_PROTOCOL_FPDMA_WRITE (AGSA_SATA_REQTYPE | AGSA_DIR_HOST_TO_CONTROLLER | AGSA_SATA_ATAP_NCQ) /**< SATA FDMA read request type */ #define AGSA_SATA_PROTOCOL_DEV_RESET (AGSA_SATA_REQTYPE | AGSA_DIR_NONE | AGSA_SATA_ATAP_PKT_DEVRESET) /**< SATA device reset request type */ #define AGSA_SATA_PROTOCOL_SRST_ASSERT (AGSA_SATA_REQTYPE | AGSA_DIR_NONE | AGSA_SATA_ATAP_SRST_ASSERT) /**< SATA device reset assert */ #define AGSA_SATA_PROTOCOL_SRST_DEASSERT (AGSA_SATA_REQTYPE | AGSA_DIR_NONE | AGSA_SATA_ATAP_SRST_DEASSERT) /**< SATA device reset deassert */ #define AGSA_SATA_PROTOCOL_D2H_PKT (AGSA_SATA_REQTYPE | AGSA_DIR_CONTROLLER_TO_HOST | AGSA_SATA_ATAP_PKT) #define AGSA_SATA_PROTOCOL_H2D_PKT (AGSA_SATA_REQTYPE | AGSA_DIR_HOST_TO_CONTROLLER | AGSA_SATA_ATAP_PKT) #define AGSA_SATA_PROTOCOL_NON_PKT (AGSA_SATA_REQTYPE | AGSA_DIR_NONE | AGSA_SATA_ATAP_PKT) #define AGSA_SATA_PROTOCOL_NON_DATA_M (AGSA_SATA_REQTYPE | AGSA_DIR_NONE | AGSA_SATA_ATAP_NON_DATA | AGSA_MSG) #define AGSA_SATA_PROTOCOL_PIO_READ_M (AGSA_SATA_REQTYPE | AGSA_DIR_CONTROLLER_TO_HOST | AGSA_SATA_ATAP_PIO | AGSA_MSG) /**< SATA PIO read request type */ #define AGSA_SATA_PROTOCOL_DMA_READ_M (AGSA_SATA_REQTYPE | AGSA_DIR_CONTROLLER_TO_HOST | AGSA_SATA_ATAP_DMA | AGSA_MSG) /**< SATA DMA read request type */ #define AGSA_SATA_PROTOCOL_FPDMA_READ_M (AGSA_SATA_REQTYPE | AGSA_DIR_CONTROLLER_TO_HOST | AGSA_SATA_ATAP_NCQ | AGSA_MSG) /**< SATA FDMA read request type */ #define AGSA_SATA_PROTOCOL_PIO_WRITE_M (AGSA_SATA_REQTYPE | AGSA_DIR_HOST_TO_CONTROLLER | AGSA_SATA_ATAP_PIO | AGSA_MSG) /**< SATA PIO read request type */ #define AGSA_SATA_PROTOCOL_DMA_WRITE_M (AGSA_SATA_REQTYPE | AGSA_DIR_HOST_TO_CONTROLLER | AGSA_SATA_ATAP_DMA | AGSA_MSG) /**< SATA DMA read request type */ #define AGSA_SATA_PROTOCOL_FPDMA_WRITE_M (AGSA_SATA_REQTYPE | AGSA_DIR_HOST_TO_CONTROLLER | AGSA_SATA_ATAP_NCQ | AGSA_MSG) /**< SATA FDMA read request type */ #define AGSA_SATA_PROTOCOL_D2H_PKT_M (AGSA_SATA_REQTYPE | AGSA_DIR_CONTROLLER_TO_HOST | AGSA_SATA_ATAP_PKT | AGSA_MSG) #define AGSA_SATA_PROTOCOL_H2D_PKT_M (AGSA_SATA_REQTYPE | AGSA_DIR_HOST_TO_CONTROLLER | AGSA_SATA_ATAP_PKT | AGSA_MSG) #define AGSA_SATA_PROTOCOL_NON_PKT_M (AGSA_SATA_REQTYPE | AGSA_DIR_NONE | AGSA_SATA_ATAP_PKT | AGSA_MSG) /* TestBase */ #define AGSA_SATA_PROTOCOL_DEV_RESET_M (AGSA_SATA_REQTYPE | AGSA_DIR_NONE | AGSA_SATA_ATAP_PKT_DEVRESET | AGSA_MSG) /**< SATA device reset request type */ #define AGSA_INTERRUPT_HANDLE_ALL_CHANNELS 0xFFFFFFFF /**< flag indicates handles interrupts for all channles */ /**************************************************************************** ** INBOUND Queue related macros ****************************************************************************/ #define AGSA_IBQ_PRIORITY_NORMAL 0x0 #define AGSA_IBQ_PRIORITY_HIGH 0x1 /**************************************************************************** ** Phy properties related macros ****************************************************************************/ /* link rate */ #define AGSA_PHY_MAX_LINK_RATE_MASK 0x0000000F /* bits 0-3 */ #define AGSA_PHY_MAX_LINK_RATE_1_5G 0x00000001 /* 0001b */ #define AGSA_PHY_MAX_LINK_RATE_3_0G 0x00000002 /* 0010b */ #define AGSA_PHY_MAX_LINK_RATE_6_0G 0x00000004 /* 0100b */ #define AGSA_PHY_MAX_LINK_RATE_12_0G 0x00000008 /* 1000b */ /* SAS/SATA mode */ #define AGSA_PHY_MODE_MASK 0x00000030 /* bits 4-5 */ #define AGSA_PHY_MODE_SAS 0x00000010 /* 01b */ #define AGSA_PHY_MODE_SATA 0x00000020 /* 10b */ /* control spin-up hold */ #define AGSA_PHY_SPIN_UP_HOLD_MASK 0x00000040 /* bit6 */ #define AGSA_PHY_SPIN_UP_HOLD_ON 0x00000040 /* 1b */ #define AGSA_PHY_SPIN_UP_HOLD_OFF 0x00000000 /* 0b */ /**************************************************************************** ** Device Info related macros ****************************************************************************/ /* S (SAS/SATA) */ #define AGSA_DEV_INFO_SASSATA_MASK 0x00000010 /* bit 4 */ #define AGSA_DEV_INFO_SASSATA_SAS 0x00000010 /* 1b */ #define AGSA_DEV_INFO_SASSATA_SATA 0x00000000 /* 0b */ /* Rate (link-rate) */ #define AGSA_DEV_INFO_RATE_MASK 0x0000000F /* bits 0-3 */ #define AGSA_DEV_INFO_RATE_1_5G 0x00000008 /* 8h */ #define AGSA_DEV_INFO_RATE_3_0G 0x00000009 /* 9h */ #define AGSA_DEV_INFO_RATE_6_0G 0x0000000A /* Ah */ #define AGSA_DEV_INFO_RATE_12_0G 0x0000000B /* Bh */ /* devType */ #define AGSA_DEV_INFO_DEV_TYPE_MASK 0x000000E0 /* bits 5-7 */ #define AGSA_DEV_INFO_DEV_TYPE_END_DEVICE 0x00000020 /* 001b */ #define AGSA_DEV_INFO_DEV_TYPE_EDGE_EXP_DEVICE 0x00000040 /* 010b */ #define AGSA_DEV_INFO_DEV_TYPE_FANOUT_EXP_DEVICE 0x00000060 /* 011b */ /***************************************************************************** ** SAS TM Function definitions see SAS spec p308 Table 105 (Revision 7) *****************************************************************************/ #define AGSA_ABORT_TASK 0x01 #define AGSA_ABORT_TASK_SET 0x02 #define AGSA_CLEAR_TASK_SET 0x04 #define AGSA_LOGICAL_UNIT_RESET 0x08 #define AGSA_IT_NEXUS_RESET 0x10 #define AGSA_CLEAR_ACA 0x40 #define AGSA_QUERY_TASK 0x80 #define AGSA_QUERY_TASK_SET 0x81 #define AGSA_QUERY_UNIT_ATTENTION 0x82 /***************************************************************************** ** SAS TM Function Response Code see SAS spec p312 Table 111 (Revision 7) *****************************************************************************/ #define AGSA_TASK_MANAGEMENT_FUNCTION_COMPLETE 0x0 #define AGSA_INVALID_FRAME 0x2 #define AGSA_TASK_MANAGEMENT_FUNCTION_NOT_SUPPORTED 0x4 #define AGSA_TASK_MANAGEMENT_FUNCTION_FAILED 0x5 #define AGSA_TASK_MANAGEMENT_FUNCTION_SUCCEEDED 0x8 #define AGSA_INCORRECT_LOGICAL_UNIT_NUMBER 0x9 /* SAS spec 9.2.2.5.3 p356 Table 128 (Revision 9e) */ #define AGSA_OVERLAPPED_TAG_ATTEMPTED 0xA #define AGSA_SATA_BSY_OVERRIDE 0x00080000 #define AGSA_SATA_CLOSE_CLEAR_AFFILIATION 0x00400000 #define AGSA_MAX_SMPPAYLOAD_VIA_SFO 40 #define AGSA_MAX_SSPPAYLOAD_VIA_SFO 36 /* SATA Initiator Request option field defintion */ #define AGSA_RETURN_D2H_FIS_GOOD_COMPLETION 0x000001 #define AGSA_SATA_ENABLE_ENCRYPTION 0x000004 #define AGSA_SATA_ENABLE_DIF 0x000008 #define AGSA_SATA_SKIP_QWORD 0xFFFF00 /* SAS Initiator Request flag definitions */ /* Bits 0,1 use TLR_MASK */ #define AGSA_SAS_ENABLE_ENCRYPTION 0x0004 #define AGSA_SAS_ENABLE_DIF 0x0008 #ifdef SAFLAG_USE_DIF_ENC_IOMB #define AGSA_SAS_USE_DIF_ENC_OPSTART 0x0010 #endif /* SAFLAG_USE_DIF_ENC_IOMB */ #define AGSA_SAS_ENABLE_SKIP_MASK 0x0010 #define AGSA_SAS_SKIP_MASK_OFFSET 0xFFE0 /**************************************************************************** ** SMP Phy control Phy Operation field ****************************************************************************/ #define AGSA_PHY_CONTROL_LINK_RESET_OP 0x1 #define AGSA_PHY_CONTROL_HARD_RESET_OP 0x2 #define AGSA_PHY_CONTROL_DISABLE 0x3 #define AGSA_PHY_CONTROL_CLEAR_ERROR_LOG_OP 0x5 #define AGSA_PHY_CONTROL_CLEAR_AFFILIATION 0x6 #define AGSA_PHY_CONTROL_XMIT_SATA_PS_SIGNAL 0x7 /**************************************************************************** ** SAS Diagnostic Operation code ****************************************************************************/ #define AGSA_SAS_DIAG_START 0x1 #define AGSA_SAS_DIAG_END 0x0 /**************************************************************************** ** Port Control constants ****************************************************************************/ #define AGSA_PORT_SET_SMP_PHY_WIDTH 0x1 #define AGSA_PORT_SET_PORT_RECOVERY_TIME 0x2 #define AGSA_PORT_IO_ABORT 0x3 #define AGSA_PORT_SET_PORT_RESET_TIME 0x4 #define AGSA_PORT_HARD_RESET 0x5 #define AGSA_PORT_CLEAN_UP 0x6 #define AGSA_STOP_PORT_RECOVERY_TIMER 0x7 /* Device State */ #define SA_DS_OPERATIONAL 0x1 #define SA_DS_PORT_IN_RESET 0x2 #define SA_DS_IN_RECOVERY 0x3 #define SA_DS_IN_ERROR 0x4 #define SA_DS_NON_OPERATIONAL 0x7 /************************************************************************************ * * * Constants defined for LL Layer ends * * * ************************************************************************************/ /************************************************************************************ * * * Constants defined for OS Layer starts * * * ************************************************************************************/ /***************************************** * ossaXXX return values ******************************************/ /* common for all ossaXXX CB */ #define OSSA_SUCCESS 0x00 /**< flag indicates successful callback status */ #define OSSA_FAILURE 0x01 /**< flag indicates failed callback status */ /* ossaHwCB() */ #define OSSA_RESET_PENDING 0x03 /**< flag indicates reset pending callback status */ #define OSSA_CHIP_FAILED 0x04 /**< flag indicates chip failed callback status */ #define OSSA_FREEZE_FAILED 0x05 /**< flag indicates freeze failed callback status */ /* ossaLocalPhyControl() */ #define OSSA_PHY_CONTROL_FAILURE 0x03 /**< flag indicates phy Control operation failure */ /* ossaDeviceRegisterCB() */ #define OSSA_FAILURE_OUT_OF_RESOURCE 0x01 /**< flag indicates failed callback status */ #define OSSA_FAILURE_DEVICE_ALREADY_REGISTERED 0x02 /**< flag indicates failed callback status */ #define OSSA_FAILURE_INVALID_PHY_ID 0x03 /**< flag indicates failed callback status */ #define OSSA_FAILURE_PHY_ID_ALREADY_REGISTERED 0x04 /**< flag indicates failed callback status */ #define OSSA_FAILURE_PORT_ID_OUT_OF_RANGE 0x05 /**< flag indicates failed callback status */ #define OSSA_FAILURE_PORT_NOT_VALID_STATE 0x06 /**< flag indicates failed callback status */ #define OSSA_FAILURE_DEVICE_TYPE_NOT_VALID 0x07 /**< flag indicates failed callback status */ #define OSSA_ERR_DEVICE_HANDLE_UNAVAILABLE 0x1020 #define OSSA_ERR_DEVICE_ALREADY_REGISTERED 0x1021 #define OSSA_ERR_DEVICE_TYPE_NOT_VALID 0x1022 #define OSSA_MPI_ERR_DEVICE_ACCEPT_PENDING 0x1027 /**/ #define OSSA_ERR_PORT_INVALID 0x1041 #define OSSA_ERR_PORT_STATE_NOT_VALID 0x1042 #define OSSA_ERR_PORT_SMP_PHY_WIDTH_EXCEED 0x1045 #define OSSA_ERR_PHY_ID_INVALID 0x1061 #define OSSA_ERR_PHY_ID_ALREADY_REGISTERED 0x1062 /* ossaDeregisterDeviceCB() */ #define OSSA_INVALID_HANDLE 0x02 /**< flag indicates failed callback status */ #define OSSA_ERR_DEVICE_HANDLE_INVALID 0x1023 /* MPI_ERR_DEVICE_HANDLE_INVALID The device handle associated with DEVICE_ID does not exist. */ #define OSSA_ERR_DEVICE_BUSY 0x1024 /* MPI_ERR_DEVICE_BUSY Device has outstanding I/Os. */ #define OSSA_RC_ACCEPT 0x00 /**< flag indicates the result of the callback function */ #define OSSA_RC_REJECT 0x01 /**< flag indicates the result of the callback function */ /* ossaSetDeviceStateCB() */ #define OSSA_INVALID_STATE 0x0001 #define OSSA_ERR_DEVICE_NEW_STATE_INVALID 0x1025 #define OSSA_ERR_DEVICE_STATE_CHANGE_NOT_ALLOWED 0x1026 #define OSSA_ERR_DEVICE_STATE_INVALID 0x0049 /* status of ossaSASDiagExecuteCB() */ #define OSSA_DIAG_SUCCESS 0x00 /* Successful SAS diagnostic command. */ #define OSSA_DIAG_INVALID_COMMAND 0x01 /* Invalid SAS diagnostic command. */ #define OSSA_REGISTER_ACCESS_TIMEOUT 0x02 /* Register access has been timed-out. This is applicable only to the SPCv controller. */ #define OSSA_DIAG_FAIL 0x02 /* SAS diagnostic command failed. This is applicable only to the SPC controller. */ #define OSSA_DIAG_NOT_IN_DIAGNOSTIC_MODE 0x03 /* Attempted to execute SAS diagnostic command but PHY is not in diagnostic mode */ #define OSSA_DIAG_INVALID_PHY 0x04 /* Attempted to execute SAS diagnostic command on an invalid/out-of-range PHY. */ #define OSSA_MEMORY_ALLOC_FAILURE 0x05 /* Memory allocation failed in diagnostic. This is applicable only to the SPCv controller. */ /* status of ossaSASDiagStartEndCB() */ #define OSSA_DIAG_SE_SUCCESS 0x00 #define OSSA_DIAG_SE_INVALID_PHY_ID 0x01 #define OSSA_DIAG_PHY_NOT_DISABLED 0x02 #define OSSA_DIAG_OTHER_FAILURE 0x03 /* SPC */ #define OSSA_DIAG_OPCODE_INVALID 0x03 /* status of ossaPortControlCB() */ #define OSSA_PORT_CONTROL_FAILURE 0x03 #define OSSA_MPI_ERR_PORT_IO_RESOURCE_UNAVAILABLE 0x1004 #define OSSA_MPI_ERR_PORT_INVALID 0x1041 /**/ #define OSSA_MPI_ERR_PORT_OP_NOT_IN_USE 0x1043 /**/ #define OSSA_MPI_ERR_PORT_OP_NOT_SUPPORTED 0x1044 /**/ #define OSSA_MPI_ERR_PORT_SMP_WIDTH_EXCEEDED 0x1045 /**/ #define OSSA_MPI_ERR_PORT_NOT_IN_CORRECT_STATE 0x1047 /**/ /*regDumpNum of agsaRegDumpInfo_t */ #define GET_GSM_SM_INFO 0x02 #define GET_IOST_RB_INFO 0x03 /************************************************************************************ * HW Events ************************************************************************************/ #define OSSA_HW_EVENT_RESET_START 0x01 /**< flag indicates reset started event */ #define OSSA_HW_EVENT_RESET_COMPLETE 0x02 /**< flag indicates chip reset completed event */ #define OSSA_HW_EVENT_PHY_STOP_STATUS 0x03 /**< flag indicates phy stop event status */ #define OSSA_HW_EVENT_SAS_PHY_UP 0x04 /**< flag indicates SAS link up event */ #define OSSA_HW_EVENT_SATA_PHY_UP 0x05 /**< flag indicates SATA link up event */ #define OSSA_HW_EVENT_SATA_SPINUP_HOLD 0x06 /**< flag indicates SATA spinup hold event */ #define OSSA_HW_EVENT_PHY_DOWN 0x07 /**< flag indicates link down event */ #define OSSA_HW_EVENT_BROADCAST_CHANGE 0x09 /**< flag indicates broadcast change event */ /* not used spcv 0x0A*/ #define OSSA_HW_EVENT_PHY_ERROR 0x0A /**< flag indicates link error event */ #define OSSA_HW_EVENT_BROADCAST_SES 0x0B /**< flag indicates broadcast change (SES) event */ #define OSSA_HW_EVENT_PHY_ERR_INBOUND_CRC 0x0C #define OSSA_HW_EVENT_HARD_RESET_RECEIVED 0x0D /**< flag indicates hardware reset received event */ /* not used spcv 0x0E*/ #define OSSA_HW_EVENT_MALFUNCTION 0x0E /**< flag indicates unrecoverable Error */ #define OSSA_HW_EVENT_ID_FRAME_TIMEOUT 0x0F /**< flag indicates ID Frame Timeout event */ #define OSSA_HW_EVENT_BROADCAST_EXP 0x10 /**< flag indicates broadcast (EXPANDER) event */ /* not used spcv 0x11*/ #define OSSA_HW_EVENT_PHY_START_STATUS 0x11 /**< flag indicates phy start event status */ #define OSSA_HW_EVENT_PHY_ERR_INVALID_DWORD 0x12 /**< flag indicates Link error invalid DWORD */ #define OSSA_HW_EVENT_PHY_ERR_DISPARITY_ERROR 0x13 /**< flag indicates Phy error disparity */ #define OSSA_HW_EVENT_PHY_ERR_CODE_VIOLATION 0x14 /**< flag indicates Phy error code violation */ #define OSSA_HW_EVENT_PHY_ERR_LOSS_OF_DWORD_SYNCH 0x15 /**< flag indicates Link error loss of DWORD synch */ #define OSSA_HW_EVENT_PHY_ERR_PHY_RESET_FAILED 0x16 /**< flag indicates Link error phy reset failed */ #define OSSA_HW_EVENT_PORT_RECOVERY_TIMER_TMO 0x17 /**< flag indicates Port Recovery timeout */ #define OSSA_HW_EVENT_PORT_RECOVER 0x18 /**< flag indicates Port Recovery */ #define OSSA_HW_EVENT_PORT_RESET_TIMER_TMO 0x19 /**< flag indicates Port Reset Timer out */ #define OSSA_HW_EVENT_PORT_RESET_COMPLETE 0x20 /**< flag indicates Port Reset Complete */ #define OSSA_HW_EVENT_BROADCAST_ASYNCH_EVENT 0x21 /**< flag indicates Broadcast Asynch Event */ #define OSSA_HW_EVENT_IT_NEXUS_LOSS 0x22 /**< Custom: H/W event for IT Nexus Loss */ #define OSSA_HW_EVENT_OPEN_RETRY_BACKOFF_THR_ADJUSTED 0x25 #define OSSA_HW_EVENT_ENCRYPTION 0x83 /**< TSDK internal flag indicating that an encryption event occurred */ #define OSSA_HW_EVENT_MODE 0x84 /**< TSDK internal flag indicating that a controller mode page operation completed */ #define OSSA_HW_EVENT_SECURITY_MODE 0x85 /**< TSDK internal flag indicating that saEncryptSetMode() completed */ /* port state */ #define OSSA_PORT_NOT_ESTABLISHED 0x00 /**< flag indicates port is not established */ #define OSSA_PORT_VALID 0x01 /**< flag indicates port valid */ #define OSSA_PORT_LOSTCOMM 0x02 /**< flag indicates port lost communication */ #define OSSA_PORT_IN_RESET 0x04 /**< flag indicates port in reset state */ #define OSSA_PORT_3RDPARTY_RESET 0x07 /**< flag indicates port in 3rd party reset state */ #define OSSA_PORT_INVALID 0x08 /**< flag indicates port invalid */ /* status for agsaHWEventMode_t */ #define OSSA_CTL_SUCCESS 0x0000 #define OSSA_CTL_INVALID_CONFIG_PAGE 0x1001 #define OSSA_CTL_INVALID_PARAM_IN_CONFIG_PAGE 0x1002 #define OSSA_CTL_INVALID_ENCRYPTION_SECURITY_MODE 0x1003 #define OSSA_CTL_RESOURCE_NOT_AVAILABLE 0x1004 #define OSSA_CTL_CONTROLLER_NOT_IDLE 0x1005 // #define OSSA_CTL_NVM_MEMORY_ACCESS_ERR 0x100B #define OSSA_CTL_OPERATOR_AUTHENTICATION_FAILURE 0x100XX /************************************************************************************ * General Events value ************************************************************************************/ #define OSSA_INBOUND_V_BIT_NOT_SET 0x01 #define OSSA_INBOUND_OPC_NOT_SUPPORTED 0x02 #define OSSA_INBOUND_IOMB_INVALID_OBID 0x03 /************************************************************************************ * FW Flash Update status values ************************************************************************************/ #define OSSA_FLASH_UPDATE_COMPLETE_PENDING_REBOOT 0x00 /**< flag indicates fw flash update completed */ #define OSSA_FLASH_UPDATE_IN_PROGRESS 0x01 /**< flag indicates fw flash update in progress */ #define OSSA_FLASH_UPDATE_HDR_ERR 0x02 /**< flag indicates fw flash header error */ #define OSSA_FLASH_UPDATE_OFFSET_ERR 0x03 /**< flag indicates fw flash offset error */ #define OSSA_FLASH_UPDATE_CRC_ERR 0x04 /**< flag indicates fw flash CRC error */ #define OSSA_FLASH_UPDATE_LENGTH_ERR 0x05 /**< flag indicates fw flash length error */ #define OSSA_FLASH_UPDATE_HW_ERR 0x06 /**< flag indicates fw flash HW error */ #define OSSA_FLASH_UPDATE_HMAC_ERR 0x0E /**< flag indicates fw flash Firmware image HMAC authentication failure.*/ #define OSSA_FLASH_UPDATE_DNLD_NOT_SUPPORTED 0x10 /**< flag indicates fw flash down load not supported */ #define OSSA_FLASH_UPDATE_DISABLED 0x11 /**< flag indicates fw flash Update disabled */ #define OSSA_FLASH_FWDNLD_DEVICE_UNSUPPORT 0x12 /**< flag indicates fw flash Update disabled */ /************************************************************************************ * Discovery status values ************************************************************************************/ #define OSSA_DISCOVER_STARTED 0x00 /**< flag indicates discover started */ #define OSSA_DISCOVER_FOUND_DEVICE 0x01 /**< flag indicates discovery found a new device */ #define OSSA_DISCOVER_REMOVED_DEVICE 0x02 /**< flag indicates discovery found a device removed */ #define OSSA_DISCOVER_COMPLETE 0x03 /**< flag indicates discover completed */ #define OSSA_DISCOVER_ABORT 0x04 /**< flag indicates discover error12 */ #define OSSA_DISCOVER_ABORT_ERROR_1 0x05 /**< flag indicates discover error1 */ #define OSSA_DISCOVER_ABORT_ERROR_2 0x06 /**< flag indicates discover error2 */ #define OSSA_DISCOVER_ABORT_ERROR_3 0x07 /**< flag indicates discover error3 */ #define OSSA_DISCOVER_ABORT_ERROR_4 0x08 /**< flag indicates discover error4 */ #define OSSA_DISCOVER_ABORT_ERROR_5 0x09 /**< flag indicates discover error5 */ #define OSSA_DISCOVER_ABORT_ERROR_6 0x0A /**< flag indicates discover error6 */ #define OSSA_DISCOVER_ABORT_ERROR_7 0x0B /**< flag indicates discover error7 */ #define OSSA_DISCOVER_ABORT_ERROR_8 0x0C /**< flag indicates discover error8 */ #define OSSA_DISCOVER_ABORT_ERROR_9 0x0D /**< flag indicates discover error9 */ /*********************************************************************************** * Log Debug Levels ***********************************************************************************/ #define OSSA_DEBUG_LEVEL_0 0x00 /**< debug level 0 */ #define OSSA_DEBUG_LEVEL_1 0x01 /**< debug level 1 */ #define OSSA_DEBUG_LEVEL_2 0x02 /**< debug level 2 */ #define OSSA_DEBUG_LEVEL_3 0x03 /**< debug level 3 */ #define OSSA_DEBUG_LEVEL_4 0x04 /**< debug level 4 */ #define OSSA_DEBUG_PRINT_INVALID_NUMBER 0xFFFFFFFF /**< the number won't be printed by OS layer */ #define OSSA_FRAME_TYPE_SSP_CMD 0x06 /**< flag indicates received frame is SSP command */ #define OSSA_FRAME_TYPE_SSP_TASK 0x16 /**< flag indicates received frame is SSP task management */ /* Event Source Type of saRegisterEventCallback() */ #define OSSA_EVENT_SOURCE_DEVICE_HANDLE_ADDED 0x00 #define OSSA_EVENT_SOURCE_DEVICE_HANDLE_REMOVED 0x01 /* Status of Get Device Info CB */ #define OSSA_DEV_INFO_INVALID_HANDLE 0x01 #define OSSA_DEV_INFO_NO_EXTENDED_INFO 0x02 #define OSSA_DEV_INFO_SAS_EXTENDED_INFO 0x03 #define OSSA_DEV_INFO_SATA_EXTENDED_INFO 0x04 /* Diagnostic Command Type */ #define AGSA_CMD_TYPE_DIAG_OPRN_PERFORM 0x00 #define AGSA_CMD_TYPE_DIAG_OPRN_STOP 0x01 #define AGSA_CMD_TYPE_DIAG_THRESHOLD_SPECIFY 0x02 #define AGSA_CMD_TYPE_DIAG_RECEIVE_ENABLE 0x03 #define AGSA_CMD_TYPE_DIAG_REPORT_GET 0x04 #define AGSA_CMD_TYPE_DIAG_ERR_CNT_RESET 0x05 /* Command Description for CMD_TYPE DIAG_OPRN_PERFORM, DIAG_OPRN_STOP, THRESHOLD_SPECIFY */ #define AGSA_CMD_DESC_PRBS 0x00 #define AGSA_CMD_DESC_CJTPAT 0x01 #define AGSA_CMD_DESC_USR_PATTERNS 0x02 #define AGSA_CMD_DESC_PRBS_ERR_INSERT 0x08 #define AGSA_CMD_DESC_PRBS_INVERT 0x09 #define AGSA_CMD_DESC_CJTPAT_INVERT 0x0A #define AGSA_CMD_DESC_CODE_VIOL_INSERT 0x0B #define AGSA_CMD_DESC_DISP_ERR_INSERT 0x0C #define AGSA_CMD_DESC_SSPA_PERF_EVENT_1 0x0E #define AGSA_CMD_DESC_LINE_SIDE_ANA_LPBK 0x10 #define AGSA_CMD_DESC_LINE_SIDE_DIG_LPBK 0x11 #define AGSA_CMD_DESC_SYS_SIDE_ANA_LPBK 0x12 /* Command Description for CMD_TYPE DIAG_REPORT_GET and ERR_CNT_RESET */ #define AGSA_CMD_DESC_PRBS_ERR_CNT 0x00 #define AGSA_CMD_DESC_CODE_VIOL_ERR_CNT 0x01 #define AGSA_CMD_DESC_DISP_ERR_CNT 0x02 #define AGSA_CMD_DESC_LOST_DWD_SYNC_CNT 0x05 #define AGSA_CMD_DESC_INVALID_DWD_CNT 0x06 #define AGSA_CMD_DESC_CODE_VIOL_ERR_CNT_THHD 0x09 #define AGSA_CMD_DESC_DISP_ERR_CNT_THHD 0x0A #define AGSA_CMD_DESC_SSPA_PERF_CNT 0x0B #define AGSA_CMD_DESC_PHY_RST_CNT 0x0C #define AGSA_CMD_DESC_SSPA_PERF_1_THRESHOLD 0x0E #define AGSA_CMD_DESC_CODE_VIOL_ERR_THHD 0x19 #define AGSA_CMD_DESC_DISP_ERR_THHD 0x1A #define AGSA_CMD_DESC_RX_LINK_BANDWIDTH 0x1B #define AGSA_CMD_DESC_TX_LINK_BANDWIDTH 0x1C #define AGSA_CMD_DESC_ALL 0x1F /* NVMDevice type */ #define AGSA_NVMD_TWI_DEVICES 0x00 #define AGSA_NVMD_CONFIG_SEEPROM 0x01 #define AGSA_NVMD_VPD_FLASH 0x04 #define AGSA_NVMD_AAP1_REG_FLASH 0x05 #define AGSA_NVMD_IOP_REG_FLASH 0x06 #define AGSA_NVMD_EXPANSION_ROM 0x07 #define AGSA_NVMD_REG_FLASH 0x05 /* GET/SET NVMD Data Response errors */ #define OSSA_NVMD_SUCCESS 0x0000 #define OSSA_NVMD_MODE_ERROR 0x0001 #define OSSA_NVMD_LENGTH_ERROR 0x0002 #define OSSA_NVMD_TWI_ADDRESS_SIZE_ERROR 0x0005 #define OSSA_NVMD_TWI_NACK_ERROR 0x2001 #define OSSA_NVMD_TWI_LOST_ARB_ERROR 0x2002 #define OSSA_NVMD_TWI_TIMEOUT_ERROR 0x2021 #define OSSA_NVMD_TWI_BUS_NACK_ERROR 0x2081 #define OSSA_NVMD_TWI_ARB_FAILED_ERROR 0x2082 #define OSSA_NVMD_TWI_BUS_TIMEOUT_ERROR 0x20FF #define OSSA_NVMD_FLASH_PARTITION_NUM_ERROR 0x9001 #define OSSA_NVMD_FLASH_LENGTH_TOOBIG_ERROR 0x9002 #define OSSA_NVMD_FLASH_PROGRAM_ERROR 0x9003 #define OSSA_NVMD_FLASH_DEVICEID_ERROR 0x9004 #define OSSA_NVMD_FLASH_VENDORID_ERROR 0x9005 #define OSSA_NVMD_FLASH_ERASE_TIMEOUT_ERROR 0x9006 #define OSSA_NVMD_FLASH_ERASE_ERROR 0x9007 #define OSSA_NVMD_FLASH_BUSY_ERROR 0x9008 #define OSSA_NVMD_FLASH_NOT_SUPPORT_DEVICE_ERROR 0x9009 #define OSSA_NVMD_FLASH_CFI_INF_ERROR 0x900A #define OSSA_NVMD_FLASH_MORE_ERASE_BLOCK_ERROR 0x900B #define OSSA_NVMD_FLASH_READ_ONLY_ERROR 0x900C #define OSSA_NVMD_FLASH_MAP_TYPE_ERROR 0x900D #define OSSA_NVMD_FLASH_MAP_DISABLE_ERROR 0x900E /************************************************************ * ossaHwCB Encryption encryptOperation of agsaHWEventEncrypt_t ************************************************************/ #define OSSA_HW_ENCRYPT_KEK_UPDATE 0x0000 #define OSSA_HW_ENCRYPT_KEK_UPDATE_AND_STORE 0x0001 #define OSSA_HW_ENCRYPT_KEK_INVALIDTE 0x0002 #define OSSA_HW_ENCRYPT_DEK_UPDATE 0x0003 #define OSSA_HW_ENCRYPT_DEK_INVALIDTE 0x0004 #define OSSA_HW_ENCRYPT_OPERATOR_MANAGEMENT 0x0005 #define OSSA_HW_ENCRYPT_TEST_EXECUTE 0x0006 #define OSSA_HW_ENCRYPT_SET_OPERATOR 0x0007 #define OSSA_HW_ENCRYPT_GET_OPERATOR 0x0008 /************************************************************ * ossaHwCB Encryption status of agsaHWEventEncrypt_t ************************************************************/ /* KEK and DEK managment status from PM */ #define OSSA_INVALID_ENCRYPTION_SECURITY_MODE 0x1003 #define OSSA_KEK_MGMT_SUBOP_NOT_SUPPORTED_ 0x2000 /*not in PM 101222*/ #define OSSA_DEK_MGMT_SUBOP_NOT_SUPPORTED 0x2000 #define OSSA_MPI_ENC_ERR_ILLEGAL_DEK_PARAM 0x2001 #define OSSA_MPI_ERR_DEK_MANAGEMENT_DEK_UNWRAP_FAIL 0x2002 #define OSSA_MPI_ENC_ERR_ILLEGAL_KEK_PARAM 0x2021 #define OSSA_MPI_ERR_KEK_MANAGEMENT_KEK_UNWRAP_FAIL 0x2022 #define OSSA_MPI_ERR_KEK_MANAGEMENT_NVRAM_OPERATION_FAIL 0x2023 /*encrypt operator management response status */ #define OSSA_OPR_MGMT_OP_NOT_SUPPORTED 0x2060 #define OSSA_MPI_ENC_ERR_OPR_PARAM_ILLEGAL 0x2061 #define OSSA_MPI_ENC_ERR_OPR_ID_NOT_FOUND 0x2062 #define OSSA_MPI_ENC_ERR_OPR_ROLE_NOT_MATCH 0x2063 #define OSSA_MPI_ENC_ERR_OPR_MAX_NUM_EXCEEDED 0x2064 /*encrypt saSetOperator() response status */ #define OSSA_MPI_ENC_ERR_CONTROLLER_NOT_IDLE 0x1005 #define OSSA_MPI_ENC_NVM_MEM_ACCESS_ERR 0x100B /* agsaEncryptSMX | agsaEncryptCipherMode == cipherMode for saEncryptSetMode()*/ /* Make sure all definitions are unique bits */ #define agsaEncryptSMF 0x00000000 #define agsaEncryptSMA 0x00000100 #define agsaEncryptSMB 0x00000200 #define agsaEncryptReturnSMF (1 << 12) #define agsaEncryptAuthorize (1 << 13) /* Bits 16-23: Allowable Cipher Mode(ACM) Bit 16: Enable AES ECB. If set to 1, AES ECB is enable. If set to 0, AES ECB is disabled. Bit 22: Enable AES XTS. If set to 1, AES XTS is enable. If set to 0, AES XTS is disabled. */ #define agsaEncryptAcmMask 0x00ff0000 #define agsaEncryptEnableAES_ECB (1 << 16) #define agsaEncryptEnableAES_XTS (1 << 22) #define agsaEncryptCipherModeECB 0x00000001 #define agsaEncryptCipherModeXTS 0x00000002 #define agsaEncryptStatusNoNVRAM 0x00000001 #define agsaEncryptStatusNVRAMErr 0x00000002 /* Bin Hex Sector Total 00000 :0x0 512B 512 11000 :0x1 520B 520 00010 :0x2 4K 4096 00011 :0x3 4K+64B 4160 00100 :0x4 4K+128B 4224 11000 :0x18 512+8B 520 11001 :0x19 520+8B 528 11010 :0x1A 4K+8B 4104 11011 :0x1B 4K+64B+8B 4168 11100 :0x1C 4K+128B+8B 4232 */ #define agsaEncryptSectorSize512 0 /* define agsaEncryptSectorSize520 1 Not supported */ #define agsaEncryptSectorSize4096 2 #define agsaEncryptSectorSize4160 3 #define agsaEncryptSectorSize4224 4 #define agsaEncryptDIFSectorSize520 (agsaEncryptSectorSize512 | 0x18) #define agsaEncryptDIFSectorSize528 ( 0x19) #define agsaEncryptDIFSectorSize4104 (agsaEncryptSectorSize4096 | 0x18) #define agsaEncryptDIFSectorSize4168 (agsaEncryptSectorSize4160 | 0x18) #define agsaEncryptDIFSectorSize4232 (agsaEncryptSectorSize4224 | 0x18) #define AGSA_ENCRYPT_STORE_NVRAM 1 /************************************************************ * ossaHwCB Mode page event definitions ************************************************************/ #define agsaModePageGet 1 #define agsaModePageSet 2 /************************************************************ * saSgpio() SGPIO Function and Register type ************************************************************/ #define AGSA_READ_SGPIO_REGISTER 0x02 #define AGSA_WRITE_SGPIO_REGISTER 0x82 #define AGSA_SGPIO_CONFIG_REG 0x0 #define AGSA_SGPIO_DRIVE_BY_DRIVE_RECEIVE_REG 0x1 #define AGSA_SGPIO_GENERAL_PURPOSE_RECEIVE_REG 0x2 #define AGSA_SGPIO_DRIVE_BY_DRIVE_TRANSMIT_REG 0x3 #define AGSA_SGPIO_GENERAL_PURPOSE_TRANSMIT_REG 0x4 /************************************************************ * ossaSGpioCB() Function result ************************************************************/ #define OSSA_SGPIO_COMMAND_SUCCESS 0x00 #define OSSA_SGPIO_CMD_ERROR_WRONG_FRAME_TYPE 0x01 #define OSSA_SGPIO_CMD_ERROR_WRONG_REG_TYPE 0x02 #define OSSA_SGPIO_CMD_ERROR_WRONG_REG_INDEX 0x03 #define OSSA_SGPIO_CMD_ERROR_WRONG_REG_COUNT 0x04 #define OSSA_SGPIO_CMD_ERROR_WRONG_FRAME_REG_TYPE 0x05 #define OSSA_SGPIO_CMD_ERROR_WRONG_FUNCTION 0x06 #define OSSA_SGPIO_CMD_ERROR_WRONG_FRAME_TYPE_REG_INDEX 0x19 #define OSSA_SGPIO_CMD_ERROR_WRONG_FRAME_TYPE_REG_CNT 0x81 #define OSSA_SGPIO_CMD_ERROR_WRONG_REG_TYPE_REG_INDEX 0x1A #define OSSA_SGPIO_CMD_ERROR_WRONG_REG_TYPE_REG_COUNT 0x82 #define OSSA_SGPIO_CMD_ERROR_WRONG_REG_INDEX_REG_COUNT 0x83 #define OSSA_SGPIO_CMD_ERROR_WRONG_FRAME_REG_TYPE_REG_INDEX 0x1D #define OSSA_SGPIO_CMD_ERROR_WRONG_ALL_HEADER_PARAMS 0x9D #define OSSA_SGPIO_MAX_READ_DATA_COUNT 0x0D #define OSSA_SGPIO_MAX_WRITE_DATA_COUNT 0x0C /************************************************************ * ossaGetDFEDataCB() status ************************************************************/ #define OSSA_DFE_MPI_IO_SUCCESS 0x0000 #define OSSA_DFE_DATA_OVERFLOW 0x0002 #define OSSA_DFE_MPI_ERR_RESOURCE_UNAVAILABLE 0x1004 #define OSSA_DFE_CHANNEL_DOWN 0x100E #define OSSA_DFE_MEASUREMENT_IN_PROGRESS 0x100F #define OSSA_DFE_CHANNEL_INVALID 0x1010 #define OSSA_DFE_DMA_FAILURE 0x1011 /************************************************************************************ * * * Constants defined for OS Layer ends * * * ************************************************************************************/ /************************************************************************************ * * * Data Structures Defined for LL API start * * * ************************************************************************************/ /** \brief data structure stores OS specific and LL specific context * * The agsaContext_t data structure contains two generic pointers, * also known as handles, which are used to store OS Layer-specific and * LL Layer-specific contexts. Only the handle specific to a layer can * be modified by the layer. The other layer's handle must be returned * unmodified when communicating between the layers. * A layer's handle is typically typecast to an instance of a layer-specific * data structure. The layer can use its handle to point to any data type * that is to be associated with a function call. A handle provides a way * to uniquely identify responses when multiple calls to the same function * are necessary. * */ typedef struct agsaContext_s { void *osData; /**< Pointer-sized value used internally by the OS Layer */ void *sdkData; /**< Pointer-sized value used internally by the LL Layer */ } agsaContext_t; /** \brief hold points to global data strutures used by the LL and OS Layers * * The agsaRoot_t data structure is used to hold pointer-sized values for * internal use by the LL and OS Layers. It is intended that the * sdkData element of the agsaRoot_t data structure be used to * identify an instance of the hardware context. The sdkData * element is set by the LL Layer in the saHwInitialize() * function and returned to the OS Layer in the agsaRoot_t data * structure */ typedef agsaContext_t agsaRoot_t; /** \brief holds the pointers to the device data structure used by the LL and OS Layers * * The agsaDevHandle_t data structure is the device instance handle. * It holds pointer-sized values used internally by each of the LL and * OS Layers. It is intended that the agsaDevHandle_t data * structure be used to identify a specific device instance. A * device instance is uniquely identified by its device handle. */ typedef agsaContext_t agsaDevHandle_t; /** \brief holds the pointers to the port data structure used by the LL and * OS Layers * * The agsaPortContext_t data structure is used to describe an instance of * SAS port or SATA port. It holds pointer-sized values used * internally by each of the LL and OS Layers. * * When connected to other SAS end-devices or expanders, each instance of * agsaPortContext_t represents a SAS local narrow-port or * wide-port. * * When connected to SATA device, each instance of agsaPortContext_t * represents a local SATA port. * */ typedef agsaContext_t agsaPortContext_t; /** \brief data structure pointer to IO request structure * * It is intended that the agsaIORequest_t structure be used to * uniquely identify each I/O Request for either target or * initiator. The OS Layer is responsible for allocating and * managing agsaIORequest_t structures. The LL Layer uses each * structure only between calls to: saSSPStart() and * ossaSSPCompleted(), saSATAStart() and ossaSATACompleted(), * saSMPStart() and ossaSMPCompleted() * */ typedef agsaContext_t agsaIORequest_t; /** \brief handle to access frame * * This data structure is the handle to access frame */ typedef void *agsaFrameHandle_t; /** \brief describe a SAS ReCofiguration structure in the SAS/SATA hardware * * Describe a SAS ReConfiguration in the SAS/SATA hardware * */ typedef struct agsaSASReconfig_s { bit32 flags; /* flag to indicate a change to the default parameter bit31-30:reserved bit29: a change to the default SAS/SATA ports is requested bit28: the OPEN REJECT (RETRY) in command phase is requested bit27: the OPEN REJECT (RETRY) in data phase is requested bit26: REJECT will be mapped into OPEN REJECT bit25: delay for SATA Head-of-Line blocking detection timeout bit24-00:reserved */ bit16 reserved0; /* reserved */ bit8 reserved1; /* reserved */ bit8 maxPorts; /* This field is valid if bit 29 of the flags field is set to 1 */ bit16 openRejectRetriesCmd; /* This field is valid if bit 28 of the flags field is set to 1 */ bit16 openRejectRetriesData; /* This field is valid if bit 27 of the flags field is set to 1.*/ bit16 reserved2; /* reserved */ bit16 sataHolTmo; /* This field is valid if bit 25 of the flags field is set to 1 */ } agsaSASReconfig_t; /** \brief describe a Phy Analog Setup registers for a Controller in the SAS/SATA hardware * * Describe a Phy Analog Setup registers for a controller in the SAS/SATA hardware * */ typedef struct agsaPhyAnalogSetupRegisters_s { bit32 spaRegister0; bit32 spaRegister1; bit32 spaRegister2; bit32 spaRegister3; bit32 spaRegister4; bit32 spaRegister5; bit32 spaRegister6; bit32 spaRegister7; bit32 spaRegister8; bit32 spaRegister9; } agsaPhyAnalogSetupRegisters_t; #define MAX_INDEX 10 /** \brief * */ typedef struct agsaPhyAnalogSetupTable_s { agsaPhyAnalogSetupRegisters_t phyAnalogSetupRegisters[MAX_INDEX]; } agsaPhyAnalogSetupTable_t; /** \brief describe a Phy Analog Setting * * Describe a Phy Analog Setup registers for a controller in the SAS/SATA hardware * */ typedef struct agsaPhyAnalogSettingsPage_s { bit32 Dword0; bit32 Dword1; bit32 Dword2; bit32 Dword3; bit32 Dword4; bit32 Dword5; bit32 Dword6; bit32 Dword7; bit32 Dword8; bit32 Dword9; } agsaPhyAnalogSettingsPage_t; /** \brief describe a Open reject retry backoff threshold page * * Describe a Open reject retry backoff threshold registers in the SAS/SATA hardware * */ typedef struct agsaSASPhyOpenRejectRetryBackOffThresholdPage_s { bit32 Dword0; bit32 Dword1; bit32 Dword2; bit32 Dword3; } agsaSASPhyOpenRejectRetryBackOffThresholdPage_t; /** \brief describe a Phy Rate Control * 4.56 agsaPhyRateControlPage_t * Description * This profile page is used to read or set several rate control * parameters. The page code for this profile page is 0x07. This page can * be READ by issuing saGetPhyProfile(). It can be read anytime and there * is no need to quiesce the I/O to the controller. * Related parameters can be modified by issuing saSetPhyProfile() before * calling saPhyStart() to the PHY. * Note: This page is applicable only to the SPCv controller. * Usage * Initiator and target. */ typedef struct agsaPhyRateControlPage_s { bit32 Dword0; bit32 Dword1; bit32 Dword2; } agsaPhyRateControlPage_t; /** * Dword0 Bits 0-11: ALIGN_RATE(ALNR). Align Insertion rate is 2 in every * ALIGN_RATE+1 DWord. The default value results in the standard compliant * value of 2/256. This rate applies to out of connection, SMP and SSP * connections. The default value is 0x0ff. Other bits are reserved. * Dword1 Bits 0 -11: STP_ALIGN_RATE(STPALNR) Align Insertion rate is 2 in * every ALIGN_RATE+1 DWords. Default value results in standard compliant * value of 2/256. This rate applies to out of STP connections. The default * value is 0x0ff. Other bits are reserved. * Dword2 Bits 0-7: SSP_FRAME_RATE(SSPFRMR) The number of idle DWords * between each SSP frame. 0 means no idle cycles. The default value is * 0x0. Other bits are reserved. **/ /** \brief describe a Register Dump information for a Controller in the SAS/SATA hardware * * Describe a register dump information for a controller in the SAS/SATA hardware * */ typedef struct agsaRegDumpInfo_s { bit8 regDumpSrc; bit8 regDumpNum; bit8 reserved[2]; bit32 regDumpOffset; bit32 directLen; void *directData; bit32 indirectAddrUpper32; bit32 indirectAddrLower32; bit32 indirectLen; } agsaRegDumpInfo_t; /* 7 : SPC GSM register at [MEMBASE-III SHIFT = 0x00_0000] 8 : SPC GSM register at [MEMBASE-III SHIFT = 0x05_0000] 9 : BDMA GSM register at [MEMBASE-III SHIFT = 0x01_0000] 10: PCIe APP GSM register at [MEMBASE-III SHIFT = 0x01_0000] 11: PCIe PHY GSM register at [MEMBASE-III SHIFT = 0x01_0000] 12: PCIe CORE GSM register at [MEMBASE-III SHIFT = 0x01_0000] 13: OSSP GSM register at [MEMBASE-III SHIFT = 0x02_0000] 14: SSPA GSM register at [MEMBASE-III SHIFT = 0x03_0000] 15: SSPA GSM register at [MEMBASE-III SHIFT = 0x04_0000] 16: HSST GSM register at [MEMBASE-III SHIFT = 0x02_0000] 17: LMS_DSS(A) GSM register at [MEMBASE-III SHIFT = 0x03_0000] 18: SSPL_6G GSM register at [MEMBASE-III SHIFT = 0x03_0000] 19: HSST(A) GSM register at [MEMBASE-III SHIFT = 0x03_0000] 20: LMS_DSS(A) GSM register at [MEMBASE-III SHIFT = 0x04_0000] 21: SSPL_6G GSM register at [MEMBASE-III SHIFT = 0x04_0000] 22: HSST(A) GSM register at [MEMBASE-III SHIFT = 0x04_0000] 23: MBIC IOP GSM register at [MEMBASE-III SHIFT = 0x06_0000] 24: MBIC AAP1 GSM register at [MEMBASE-III SHIFT = 0x07_0000] 25: SPBC GSM register at [MEMBASE-III SHIFT = 0x09_0000] 26: GSM GSM register at [MEMBASE-III SHIFT = 0x70_0000] */ #define TYPE_GSM_SPACE 1 #define TYPE_QUEUE 2 #define TYPE_FATAL 3 #define TYPE_NON_FATAL 4 #define TYPE_INBOUND_QUEUE 5 #define TYPE_OUTBOUND_QUEUE 6 #define BAR_SHIFT_GSM_OFFSET 0x400000 #define ONE_MEGABYTE 0x100000 #define SIXTYFOURKBYTE (1024 * 64) #define TYPE_INBOUND 1 #define TYPE_OUTBOUND 2 typedef struct { bit32 DataType; union { struct { bit32 directLen; bit32 directOffset; bit32 readLen; void *directData; }gsmBuf; struct { bit16 queueType; bit16 queueIndex; bit32 directLen; void *directData; }queueBuf; struct { bit32 directLen; bit32 directOffset; bit32 readLen; void *directData; }dataBuf; } BufferType; } agsaForensicData_t; /** \brief describe a NVMData for a Controller in the SAS/SATA hardware * * Describe a NVMData for a controller in the SAS/SATA hardware * */ typedef struct agsaNVMDData_s { bit32 indirectPayload :1; bit32 reserved :7; bit32 TWIDeviceAddress :8; bit32 TWIBusNumber :4; bit32 TWIDevicePageSize :4; bit32 TWIDeviceAddressSize :4; bit32 NVMDevice :4; bit32 directLen :8; bit32 dataOffsetAddress :24; void *directData; bit32 indirectAddrUpper32; bit32 indirectAddrLower32; bit32 indirectLen; bit32 signature; } agsaNVMDData_t; /* status of ossaPCIeDiagExecuteCB() is shared with ossaSASDiagExecuteCB() */ #define OSSA_PCIE_DIAG_SUCCESS 0x0000 #define OSSA_PCIE_DIAG_INVALID_COMMAND 0x0001 #define OSSA_PCIE_DIAG_INTERNAL_FAILURE 0x0002 #define OSSA_PCIE_DIAG_INVALID_CMD_TYPE 0x1006 #define OSSA_PCIE_DIAG_INVALID_CMD_DESC 0x1007 #define OSSA_PCIE_DIAG_INVALID_PCIE_ADDR 0x1008 #define OSSA_PCIE_DIAG_INVALID_BLOCK_SIZE 0x1009 #define OSSA_PCIE_DIAG_LENGTH_NOT_BLOCK_SIZE_ALIGNED 0x100A #define OSSA_PCIE_DIAG_IO_XFR_ERROR_DIF_MISMATCH 0x3000 #define OSSA_PCIE_DIAG_IO_XFR_ERROR_DIF_APPLICATION_TAG_MISMATCH 0x3001 #define OSSA_PCIE_DIAG_IO_XFR_ERROR_DIF_REFERENCE_TAG_MISMATCH 0x3002 #define OSSA_PCIE_DIAG_IO_XFR_ERROR_DIF_CRC_MISMATCH 0x3003 #define OSSA_PCIE_DIAG_MPI_ERR_INVALID_LENGTH 0x0042 #define OSSA_PCIE_DIAG_MPI_ERR_IO_RESOURCE_UNAVAILABLE 0x1004 #define OSSA_PCIE_DIAG_MPI_ERR_CONTROLLER_NOT_IDLE 0x1005 typedef struct agsaPCIeDiagExecute_s { bit32 command; bit32 flags; bit16 initialIOSeed; bit16 reserved; bit32 rdAddrLower; bit32 rdAddrUpper; bit32 wrAddrLower; bit32 wrAddrUpper; bit32 len; bit32 pattern; bit8 udtArray[6]; bit8 udrtArray[6]; } agsaPCIeDiagExecute_t; /** \brief agsaPCIeDiagResponse_t * * status of ossaPCIeDiagExecuteCB() * The agsaPCIeDiagResponse_t structure is a parameter passed to * ossaPCIeDiagExecuteCB() * to contain a PCIe Diagnostic command response. */ typedef struct agsaPCIeDiagResponse_s { bit32 ERR_BLKH; bit32 ERR_BLKL; bit32 DWord8; bit32 DWord9; bit32 DWord10; bit32 DWord11; bit32 DIF_ERR; } agsaPCIeDiagResponse_t; /** \brief describe a fatal error information for a Controller in the SAS/SATA hardware * * Describe a fatal error information for a controller in the SAS/SATA hardware * */ typedef struct agsaFatalErrorInfo_s { bit32 errorInfo0; bit32 errorInfo1; bit32 errorInfo2; bit32 errorInfo3; bit32 regDumpBusBaseNum0; bit32 regDumpOffset0; bit32 regDumpLen0; bit32 regDumpBusBaseNum1; bit32 regDumpOffset1; bit32 regDumpLen1; } agsaFatalErrorInfo_t; /** \brief describe a information for a Event in the SAS/SATA hardware * * Describe a general information for a Event in the SAS/SATA hardware * */ typedef struct agsaEventSource_s { agsaPortContext_t *agPortContext; bit32 event; bit32 param; } agsaEventSource_t; /** \brief describe a information for a Controller in the SAS/SATA hardware * * Describe a general information for a controller in the SAS/SATA hardware * */ typedef struct agsaControllerInfo_s { bit32 signature; /* coherent controller information */ bit32 fwInterfaceRev; /* host and controller interface version */ bit32 hwRevision; /* controller HW Revision number */ bit32 fwRevision; /* controller FW Revision number */ bit32 ilaRevision; /* controller ILA Revision number */ bit32 maxPendingIO; /* maximum number of outstanding I/Os supported */ bit32 maxDevices; /* Maximum Device Supported by controller */ bit32 maxSgElements; /* maximum number of SG elements supported */ bit32 queueSupport; /* maximum number of IQ and OQ supported bit31-19 reserved bit18 interrupt coalescing bit17 reserved bit16 high priority IQ supported bit15-08 maximum number of OQ bit07-00 maximum number of IQ */ bit8 phyCount; /* number of phy available in the controller */ bit8 controllerSetting;/* Controller setting bit07-04 reserved bit03-00 HDA setting */ bit8 PCILinkRate; /* PCI generation 1/2/3 2.5g/5g/8g */ bit8 PCIWidth; /* PCI number of lanes */ bit32 sasSpecsSupport; /* the supported SAS spec. */ bit32 sdkInterfaceRev; /* sdk interface reversion */ bit32 sdkRevision; /* sdk reversion */ } agsaControllerInfo_t; /** \brief describe a status for a Controller in the SAS/SATA hardware * * Describe a general status for a controller in the SAS/SATA hardware * */ typedef struct agsaControllerStatus_s { agsaFatalErrorInfo_t fatalErrorInfo; /* fatal error information */ bit32 interfaceState; /* host and controller interface state bit02-00 state of host and controller bit16-03 reserved bit31-16 detail of error based on error state */ bit32 iqFreezeState0; /* freeze state of 1st set of IQ */ bit32 iqFreezeState1; /* freeze state of 2nd set of IQ */ bit32 tickCount0; /* tick count in second for internal CPU-0 */ bit32 tickCount1; /* tick count in second for internal CPU-1 */ bit32 tickCount2; /* tick count in second for internal CPU-2 */ bit32 phyStatus[8]; /* status of phy 0 to phy 15 */ bit32 recoverableErrorInfo[8]; /* controller specific recoverable error information */ bit32 bootStatus; bit16 bootComponentState[8]; } agsaControllerStatus_t; /** \brief describe a GPIO Event Setup Infomation in the SAS/SATA hardware * * Describe a configuration for a GPIO Event Setup Infomation in the SAS/SATA hardware * */ typedef struct agsaGpioEventSetupInfo_s { bit32 gpioPinMask; bit32 gpioEventLevel; bit32 gpioEventRisingEdge; bit32 gpioEventFallingEdge; } agsaGpioEventSetupInfo_t; /** \brief describe a GPIO Pin Setup Infomation in the SAS/SATA hardware * * Describe a configuration for a GPIO Pin Setup Infomation in the SAS/SATA hardware * */ typedef struct agsaGpioPinSetupInfo_t { bit32 gpioPinMask; bit32 gpioInputEnabled; bit32 gpioTypePart1; bit32 gpioTypePart2; } agsaGpioPinSetupInfo_t; /** \brief describe a serial GPIO operation in the SAS/SATA hardware * * Describe a configuration for a GPIO write Setup Infomation in the SAS/SATA hardware * */ typedef struct agsaGpioWriteSetupInfo_s { bit32 gpioWritemask; bit32 gpioWriteVal; }agsaGpioWriteSetupInfo_t; /** \brief describe a GPIO Read Infomation in the SAS/SATA hardware * * Describe a configuration for a GPIO read Infomation in the SAS/SATA hardware * */ typedef struct agsaGpioReadInfo_s { bit32 gpioReadValue; bit32 gpioInputEnabled; /* GPIOIE */ bit32 gpioEventLevelChangePart1; /* GPIEVCHANGE (pins 11-0) */ bit32 gpioEventLevelChangePart2; /* GPIEVCHANGE (pins 23-20) */ bit32 gpioEventRisingEdgePart1; /* GPIEVRISE (pins 11-0) */ bit32 gpioEventRisingEdgePart2; /* GPIEVRISE (pins 23-20) */ bit32 gpioEventFallingEdgePart1; /* GPIEVALL (pins 11-0) */ bit32 gpioEventFallingEdgePart2; /* GPIEVALL (pins 23-20) */ }agsaGpioReadInfo_t; /** \brief describe a serial GPIO request and response in the SAS/SATA hardware * * Describe the fields required for serial GPIO request and response in the SAS/SATA hardware * */ typedef struct agsaSGpioReqResponse_s { bit8 smpFrameType; /* 0x40 for request, 0x41 for response*/ bit8 function; /* 0x02 for read, 0x82 for write */ bit8 registerType; /* used only in request */ bit8 registerIndex; /* used only in request */ bit8 registerCount; /* used only in request */ bit8 functionResult; /* used only in response */ bit32 readWriteData[OSSA_SGPIO_MAX_READ_DATA_COUNT]; /* write data for request; read data for response */ } agsaSGpioReqResponse_t; /** \brief describe a serial GPIO operation response in the SAS/SATA hardware * * Describe the fields required for serial GPIO operations response in the SAS/SATA hardware * */ typedef struct agsaSGpioCfg0 { bit8 reserved1; bit8 version:4; bit8 reserved2:4; bit8 gpRegisterCount:4; bit8 cfgRegisterCount:3; bit8 gpioEnable:1; bit8 supportedDriveCount; } agsaSGpioCfg0_t; /** \brief SGPIO configuration register 1 * * These fields constitute SGPIO configuration register 1, as defined by SFF-8485 spec * */ typedef struct agsaSGpioCfg1{ bit8 reserved; bit8 blinkGenA:4; bit8 blinkGenB:4; bit8 maxActOn:4; bit8 forceActOff:4; bit8 stretchActOn:4; bit8 stretchActOff:4; } agsaSGpioCfg1_t; /** \brief describe a configuration for a PHY in the SAS/SATA hardware * * Describe a configuration for a PHY in the SAS/SATA hardware * */ typedef struct agsaPhyConfig_s { bit32 phyProperties; /**< b31-b8 reserved */ /**< b16-b19 SSC Disable */ /**< b15-b8 phy analog setup index */ /**< b7 phy analog setup enable */ /**< b6 Control spin up hold */ /**< b5-b4 SAS/SATA mode, bit4 - SAS, bit5 - SATA, 11b - Auto mode */ /**< b3-b0 Max. Link Rate, bit0 - 1.5Gb/s, bit1 - 3.0Gb/s, bit2 - 6.0Gb/s, bit3 - reserved */ } agsaPhyConfig_t; /** \brief Structure is used as a parameter passed in saLocalPhyControlCB() to describe the error counter * * Description * This profile page is used to read or set the SNW-3 PHY capabilities of a * SAS PHY. This page can be read by calling saGetPhyProfile(). It can be * read anytime and there is no need to quiesce he I/O to the controller. * The format of the 32-bit SNW3 is the same as defined in the SAS 2 * specification. * Local SNW3 can be modified by calling saSetPhyProfile() before * saPhyStart() to the PHY. REQUESTED LOGICAL LINK RATE is reserved. * The SPCv will calculate the PARITY field. * Note: This page is applicable only to the SPCv controller. * Usage * Initiator and target. */ typedef struct agsaPhySNW3Page_s { bit32 LSNW3; bit32 RSNW3; } agsaPhySNW3Page_t; /** \brief structure describe error counters of a PHY in the SAS/SATA * * Structure is used as a parameter passed in saLocalPhyControlCB() * to describe the error counter * */ typedef struct agsaPhyErrCounters_s { bit32 invalidDword; /* Number of invalid dwords that have been received outside of phy reset sequences.*/ bit32 runningDisparityError; /* Number of dwords containing running disparity errors that have been received outside of phy reset sequences.*/ bit32 lossOfDwordSynch; /* Number of times the phy has restarted the link reset sequence because it lost dword synchronization.*/ bit32 phyResetProblem; /* Number of times the phy did not obtain dword synchronization during the final SAS speed negotiation window.*/ bit32 elasticityBufferOverflow; /* Number of times the phys receive elasticity buffer has overflowed.*/ bit32 receivedErrorPrimitive; /* Number of times the phy received an ERROR primitive */ bit32 inboundCRCError; /* Number of inbound CRC Error */ bit32 codeViolation; /* Number of code violation */ } agsaPhyErrCounters_t; /** \brief * used in saGetPhyProfile */ typedef struct agsaPhyErrCountersPage_s { bit32 invalidDword; bit32 runningDisparityError; bit32 codeViolation; bit32 lossOfDwordSynch; bit32 phyResetProblem; bit32 inboundCRCError; } agsaPhyErrCountersPage_t; /** \brief structure describes bandwidth counters of a PHY in the SAS/SATA * * Structure is used as a parameter passed in saGetPhyProfile() * to describe the error counter * */ typedef struct agsaPhyBWCountersPage_s { bit32 TXBWCounter; bit32 RXBWCounter; } agsaPhyBWCountersPage_t; /** \brief structure describe hardware configuration * * Structure is used as a parameter passed in saInitialize() to describe the * configuration used during hardware initialization * */ typedef struct agsaHwConfig_s { bit32 phyCount; /**< Number of PHYs that are to be configured and initialized. */ bit32 hwInterruptCoalescingTimer; /**< Host Interrupt CoalescingTimer */ bit32 hwInterruptCoalescingControl; /**< Host Interrupt CoalescingControl */ bit32 intReassertionOption; /**< Interrupt Ressertion Option */ bit32 hwOption; /** PCAD64 on 64 bit addressing */ agsaPhyAnalogSetupTable_t phyAnalogConfig; /**< Phy Analog Setting Table */ } agsaHwConfig_t; /** \brief structure describe software configuration * * Structure is used as a parameter passed in saInitialize() to describe the * configuration used during software initialization * */ typedef struct agsaSwConfig_s { bit32 maxActiveIOs; /**< Maximum active I/O requests supported */ bit32 numDevHandles; /**< Number of SAS/SATA device handles allocated in the pool */ bit32 smpReqTimeout; /**< SMP request time out in millisecond */ bit32 numberOfEventRegClients; /**< Maximum number of OS Layer clients for the event registration defined by saRegisterEventCallback() */ bit32 sizefEventLog1; /**< Size of Event Log 1 */ bit32 sizefEventLog2; /**< Size of Event Log 2 */ bit32 eventLog1Option; /**< Option of Event Log 1 */ bit32 eventLog2Option; /**< Option of Event Log 2 */ bit32 fatalErrorInterruptEnable:1; /**< 0 Fatal Error Iterrupt Enable */ bit32 sgpioSupportEnable:1; /**< 1 SGPIO Support Enable */ bit32 fatalErrorInterruptVector:8; /**< 2-9 Fatal Error Interrupt Vector */ bit32 max_MSI_InterruptVectors:8; /**< 10-18 Maximum MSI Interrupt Vectors */ bit32 max_MSIX_InterruptVectors:8; /**< 18-25 Maximum MSIX Interrupt Vectors */ bit32 legacyInt_X:1; /**< 26 Support Legacy Interrupt */ bit32 hostDirectAccessSupport:1; /**< 27 Support HDA mode */ bit32 hostDirectAccessMode:2; /**< 28-29 HDA mode: 00b - HDA SoftReset, 01b - HDA Normal */ bit32 enableDIF:1; /**< 30 */ bit32 enableEncryption:1; /**< 31 */ #ifdef SA_CONFIG_MDFD_REGISTRY bit32 disableMDF; /*disable MDF*/ #endif bit32 param1; /**< parameter1 */ bit32 param2; /**< parameter2 */ void *param3; /**< parameter3 */ void *param4; /**< paramater4 */ bit32 stallUsec; bit32 FWConfig; bit32 PortRecoveryResetTimer; void *mpiContextTable; /** Pointer to a table that contains agsaMPIContext_t entries. This table is used to fill in MPI table fields. Values in this table are written to MPI table last. Any previous values in MPI table are overwritten by values in this table. */ bit32 mpiContextTablelen; /** Number of agsaMPIContext_t entries in mpiContextTable */ #if defined(SALLSDK_DEBUG) bit32 sallDebugLevel; /**< Low Layer debug level */ #endif #ifdef SA_ENABLE_PCI_TRIGGER bit32 PCI_trigger; #endif /* SA_ENABLE_PCI_TRIGGER */ #ifdef SA_ENABLE_TRACE_FUNCTIONS bit32 TraceDestination; bit32 TraceBufferSize; bit32 TraceMask; #endif /* SA_ENABLE_TRACE_FUNCTIONS */ } agsaSwConfig_t; typedef struct agsaQueueInbound_s { bit32 elementCount:16; /* Maximum number of elements in the queue (queue depth). A value of zero indicates that the host disabled this queue.*/ bit32 elementSize:16; /* Size of each element in the queue in bytes.*/ bit32 priority:2; /* Queue priority: 00: normal priority 01: high priority 10: reserved 11: reserved */ bit32 reserved:30; } agsaQueueInbound_t; typedef struct agsaQueueOutbound_s { bit32 elementCount:16; /* Maximum number of elements in the queue (queue depth). A value of zero indicates that the host disabled this queue.*/ bit32 elementSize:16; /* Size of each element in the queue in bytes.*/ bit32 interruptDelay:16; /* Time, in usec, to delay interrupts to the host. Zero means not to delay based on time. An interrupt is passed to the host when either of the interruptDelay or interruptCount parameters is satisfied. Default value is 0.*/ bit32 interruptCount:16; /* Number of interrupts required before passing to the host. Zero means not to coalesce based on count. */ bit32 interruptVectorIndex:8; /* MSI/MSI-X interrupt vector index. For MSI, when Multiple Messages is enabled, this field is the index to the MSI vectors derived from a single Message Address and multiple Message Data. For MSI-X, this field is the index to the MSI-X Table Structure. */ bit32 interruptEnable:1; /* 0b: No interrupt to host (host polling) 1b: Interrupt enabled */ bit32 reserved:23; } agsaQueueOutbound_t; typedef struct agsaPhyCalibrationTbl_s { bit32 txPortConfig1; /* transmitter per port configuration 1 SAS_SATA G1 */ bit32 txPortConfig2; /* transmitter per port configuration 2 SAS_SATA G1*/ bit32 txPortConfig3; /* transmitter per port configuration 3 SAS_SATA G1*/ bit32 txConfig1; /* transmitter configuration 1 */ bit32 rvPortConfig1; /* reveiver per port configuration 1 SAS_SATA G1G2 */ bit32 rvPortConfig2; /* reveiver per port configuration 2 SAS_SATA G3 */ bit32 rvConfig1; /* reveiver per configuration 1 */ bit32 rvConfig2; /* reveiver per configuration 2 */ bit32 reserved[2]; /* reserved */ } agsaPhyCalibrationTbl_t; typedef struct agsaQueueConfig_s { bit16 numInboundQueues; bit16 numOutboundQueues; bit8 sasHwEventQueue[AGSA_MAX_VALID_PHYS]; bit8 sataNCQErrorEventQueue[AGSA_MAX_VALID_PHYS]; bit8 tgtITNexusEventQueue[AGSA_MAX_VALID_PHYS]; bit8 tgtSSPEventQueue[AGSA_MAX_VALID_PHYS]; bit8 tgtSMPEventQueue[AGSA_MAX_VALID_PHYS]; bit8 iqNormalPriorityProcessingDepth; bit8 iqHighPriorityProcessingDepth; bit8 generalEventQueue; bit8 tgtDeviceRemovedEventQueue; bit32 queueOption; agsaQueueInbound_t inboundQueues[AGSA_MAX_INBOUND_Q]; agsaQueueOutbound_t outboundQueues[AGSA_MAX_OUTBOUND_Q]; } agsaQueueConfig_t; #define OQ_SHARE_PATH_BIT 0x00000001 typedef struct agsaFwImg_s { bit8 *aap1Img; /**< AAP1 Image */ bit32 aap1Len; /**< AAP1 Image Length */ bit8 *ilaImg; /**< ILA Image */ bit32 ilaLen; /**< ILA Image Length */ bit8 *iopImg; /**< IOP Image */ bit32 iopLen; /**< IOP Image Length */ bit8 *istrImg; /**< Init String */ bit32 istrLen; /**< Init String Length */ } agsaFwImg_t; /** \brief generic memory descriptor * * a generic memory descriptor used for describing a memory requirement in a structure * */ typedef struct agsaMem_s { void *virtPtr; /**< Virtual pointer to the memory chunk */ void *osHandle; /**< Handle used for OS to free memory */ bit32 phyAddrUpper; /**< Upper 32 bits of physical address */ bit32 phyAddrLower; /**< Lower 32 bits of physical address */ bit32 totalLength; /**< Total length in bytes allocated */ bit32 numElements; /**< Number of elements */ bit32 singleElementLength; /**< Size in bytes of an element */ bit32 alignment; /**< Alignment in bytes needed. A value of one indicates no specific alignment requirement */ bit32 type; /**< DMA or Cache */ bit32 reserved; /**< reserved */ } agsaMem_t; /** \brief specify the controller Event Log for the SAS/SATA LL Layer * * data structure used in the saGetControllerEventLogInfo() function calls * */ typedef struct agsaControllerEventLog_s { agsaMem_t eventLog1; agsaMem_t eventLog2; bit32 eventLog1Option; bit32 eventLog2Option; } agsaControllerEventLog_t; /* Log Option - bit3-0 */ #define DISABLE_LOGGING 0x0 #define CRITICAL_ERROR 0x1 #define WARNING 0x2 #define NOTICE 0x3 #define INFORMATION 0x4 #define DEBUGGING 0x5 /** \brief specify the SAS Diagnostic Parameters for the SAS/SATA LL Layer * * data structure used in the saGetRequirements() and the saInitialize() function calls * */ typedef struct agsaSASDiagExecute_s { bit32 command; bit32 param0; bit32 param1; bit32 param2; bit32 param3; bit32 param4; bit32 param5; } agsaSASDiagExecute_t; /** \brief for the SAS/SATA LL Layer * * This data structure contains the general status of a SAS Phy. * Section 4.60 */ typedef struct agsaSASPhyGeneralStatusPage_s { bit32 Dword0; bit32 Dword1; } agsaSASPhyGeneralStatusPage_t; /** \brief specify the memory allocation requirement for the SAS/SATA LL Layer * * data structure used in the saGetRequirements() and the saInitialize() function calls * */ typedef struct agsaMemoryRequirement_s { bit32 count; /**< The number of memory chunks used in the agMemory table */ agsaMem_t agMemory[AGSA_NUM_MEM_CHUNKS]; /**< The structure that defines the memory requirement structure */ } agsaMemoryRequirement_t; /** \brief describe a SAS address and PHY Identifier * * This structure is used * */ typedef struct agsaSASAddressID_s { bit8 sasAddressLo[4]; /**< HOST SAS address lower part */ bit8 sasAddressHi[4]; /**< HOST SAS address higher part */ bit8 phyIdentifier; /**< PHY IDENTIFIER of the PHY */ } agsaSASAddressID_t; /** \brief data structure provides some information about a SATA device * * data structure provides some information about a SATA device discovered * following the SATA discovery. * */ typedef struct agsaDeviceInfo_s { bit16 smpTimeout; bit16 it_NexusTimeout; bit16 firstBurstSize; bit8 reserved; /* Not Used */ bit8 devType_S_Rate; /* Bit 6-7: reserved Bit 4-5: Two-bit flag to specify a SSP/SMP, or directly attached SATA or STP device 00: STP device 01: SSP or SMP device 10: Direct SATA device Bit 0-3: Connection Rate field when opening the device. Code Description: 08h: 1.5 Gbps 09h: 3.0 Gbps 0ah: 6.0 Gbps All others Reserved */ bit8 sasAddressHi[4]; bit8 sasAddressLo[4]; bit32 flag; /* flag Bit 0: Retry flag. 1b: enable SAS TLR (Transport Layer Retry). 0b: disable SAS TLR (Transport Layer Retry). When used during device registration, it is recommended that TLR is enabled, i.e. set the bit to 1. Bit 1: Priority setting for AWT (Arbitration Wait Time) for this device. 0b: Default setting (recommended). Actual AWT value TBD. 1b: Increase priority. Actual AWT value TBD. Bit 2-3: Reserved Bit 4-11: Zero-based PHY identifier. This field is used only if bits 4-5 in devType_S_Rate are set to 10b which indicates a directly-attached SATA drive. Bit 12-15: Reserved Bit 16-19 : Maximum Connection Number. This field specifies the maximum number of connections that can be established with the device concurrently. This field is set to the lowest port width along the pathway from the controller to the device. This is applicable only to the SPCv controller. However, for backward compatibility reasons, if this field is set to zero, it is treated as 1 so that the controller can establish at least one connection. Bit 20: Initiator Role This bit indicates whether the device has SSP initiator role capability. This is applicable only to the SPCv controller. 0b : The device has no SSP initiator capability. 1b : The device has SSP initiator capability. Bit 21: ATAPI Device Flag. (Only applies to the SPCv) Flag to indicate ATAPI protocol support 0b : Device does not support ATAPI protocol. 1b : Device supports ATAPI protocol. Bit 22-31: Reserved */ } agsaDeviceInfo_t; #define DEV_INFO_MASK 0xFF #define DEV_INFO_MCN_SHIFT 16 #define DEV_INFO_IR_SHIFT 20 #define RETRY_DEVICE_FLAG (1 << SHIFT0) #define AWT_DEVICE_FLAG (1 << SHIFT1) #define SSP_DEVICE_FLAG (1 << SHIFT20) #define ATAPI_DEVICE_FLAG 0x200000 /* bit21 */ #define XFER_RDY_PRIORTY_DEVICE_FLAG (1 << SHIFT22) #define DEV_LINK_RATE 0x3F #define SA_DEVINFO_GET_SAS_ADDRESSLO(devInfo) \ DMA_BEBIT32_TO_BIT32(*(bit32 *)(devInfo)->sasAddressLo) #define SA_DEVINFO_GET_SAS_ADDRESSHI(devInfo) \ DMA_BEBIT32_TO_BIT32(*(bit32 *)(devInfo)->sasAddressHi) #define SA_DEVINFO_GET_DEVICETTYPE(devInfo) \ (((devInfo)->devType_S_Rate & 0xC0) >> 5) #define SA_DEVINFO_PUT_SAS_ADDRESSLO(devInfo, src32) \ *(bit32 *)((devInfo)->sasAddressLo) = BIT32_TO_DMA_BEBIT32(src32) #define SA_DEVINFO_PUT_SAS_ADDRESSHI(devInfo, src32) \ *(bit32 *)((devInfo)->sasAddressHi) = BIT32_TO_DMA_BEBIT32(src32) /** \brief data structure provides some information about a SATA device * * data structure provides some information about a SATA device discovered * following the SATA discovery. * */ typedef struct agsaSATADeviceInfo_s { agsaDeviceInfo_t commonDevInfo; /**< The general/common part of the SAS/SATA device information */ bit8 connection; /**< How device is connected: 0: Direct attached. 1: Behind Port Multiplier, portMultiplierField is valid. 2: STP, stpPhyIdentifier is valid */ bit8 portMultiplierField; /**< The first 4 bits indicate that the Port Multiplier field is defined by SATA-II. This field is valid only if the connection field above is set to 1 */ bit8 stpPhyIdentifier; /**< PHY ID of the STP PHY. Valid only if connection field is set to 2 (STP). */ bit8 reserved; bit8 signature[8]; /**< The signature of SATA in Task File registers following power up. Only five bytes are defined by ATA. The added three bytes are for alignment purposes */ } agsaSATADeviceInfo_t; /** \brief data structure provides some information about a SAS device * * data structure provides some information about a SAS device discovered * following the SAS discovery * */ typedef struct agsaSASDeviceInfo_s { agsaDeviceInfo_t commonDevInfo; /**< The general/common part of the SAS/SATA device information */ bit8 initiator_ssp_stp_smp; /**< SAS initiator capabilities */ /* b4-7: reserved */ /* b3: SSP initiator port */ /* b2: STP initiator port */ /* b1: SMP initiator port */ /* b0: reserved */ bit8 target_ssp_stp_smp; /**< SAS target capabilities */ /* b4-7: reserved */ /* b3: SSP target port */ /* b2: STP target port */ /* b1: SMP target port */ /* b0: reserved */ bit32 numOfPhys; /**< Number of PHYs in the device */ bit8 phyIdentifier; /**< PHY IDENTIFIER in IDENTIFY address frame as defined by the SAS specification. */ } agsaSASDeviceInfo_t; #define SA_SASDEV_SSP_BIT SA_IDFRM_SSP_BIT /* SSP Initiator port */ #define SA_SASDEV_STP_BIT SA_IDFRM_STP_BIT /* STP Initiator port */ #define SA_SASDEV_SMP_BIT SA_IDFRM_SMP_BIT /* SMP Initiator port */ #define SA_SASDEV_SATA_BIT SA_IDFRM_SATA_BIT /* SATA device, valid in the discovery response only */ #define SA_SASDEV_IS_SSP_INITIATOR(sasDev) \ (((sasDev)->initiator_ssp_stp_smp & SA_SASDEV_SSP_BIT) == SA_SASDEV_SSP_BIT) #define SA_SASDEV_IS_STP_INITIATOR(sasDev) \ (((sasDev)->initiator_ssp_stp_smp & SA_SASDEV_STP_BIT) == SA_SASDEV_STP_BIT) #define SA_SASDEV_IS_SMP_INITIATOR(sasDev) \ (((sasDev)->initiator_ssp_stp_smp & SA_SASDEV_SMP_BIT) == SA_SASDEV_SMP_BIT) #define SA_SASDEV_IS_SSP_TARGET(sasDev) \ (((sasDev)->target_ssp_stp_smp & SA_SASDEV_SSP_BIT) == SA_SASDEV_SSP_BIT) #define SA_SASDEV_IS_STP_TARGET(sasDev) \ (((sasDev)->target_ssp_stp_smp & SA_SASDEV_STP_BIT) == SA_SASDEV_STP_BIT) #define SA_SASDEV_IS_SMP_TARGET(sasDev) \ (((sasDev)->target_ssp_stp_smp & SA_SASDEV_SMP_BIT) == SA_SASDEV_SMP_BIT) #define SA_SASDEV_IS_SATA_DEVICE(sasDev) \ (((sasDev)->target_ssp_stp_smp & SA_SASDEV_SATA_BIT) == SA_SASDEV_SATA_BIT) /** \brief the data structure describe SG list * * the data structure describe SG list * */ typedef struct _SASG_DESCRIPTOR { bit32 sgLower; /**< Lower 32 bits of data area physical address */ bit32 sgUpper; /**< Upper 32 bits of data area physical address */ bit32 len; /**< Total data length in bytes */ } SASG_DESCRIPTOR, * PSASG_DESCRIPTOR; /** \brief data structure used to pass information about the scatter-gather list to the LL Layer * * The ESGL pages are uncached, have a configurable number of SGL * of (min, max) = (1, 10), and are 16-byte aligned. Although * the application can configure the page size, the size must be * incremented in TBD-byte increments. Refer the hardware * documentation for more detail on the format of ESGL * structure. * */ typedef struct agsaSgl_s { bit32 sgLower; /**< Lower 32 bits of data area physical address */ bit32 sgUpper; /**< Upper 32 bits of data area physical address */ bit32 len; /**< Total data length in bytes */ bit32 extReserved; /**< bit31 is for extended sgl list */ } agsaSgl_t; /** \brief data structure is used to pass information about the extended * scatter-gather list (ESGL) to the LL Layer * * The agsaEsgl_t data structure is used to pass information about the * extended scatter-gather list (ESGL) to the LL Layer. * * When ESGL is used, its starting address is specified the first descriptor * entry (i.e. descriptor[0]) in agsaSgl_t structure. * * The ESGL pages are uncached, have a fixed number of SGL of 10, and are * 16-byte aligned. Refer the hardware documentation for more * detail on ESGL. * */ typedef struct agsaEsgl_s { agsaSgl_t descriptor[MAX_ESGL_ENTRIES]; } agsaEsgl_t; /** \brief data structure describes an SSP Command INFORMATION UNIT * * data structure describes an SSP Command INFORMATION UNIT used for SSP command and is part of * the SSP frame. * * Currently, Additional CDB length is supported to 16 bytes * */ #define MAX_CDB_LEN 32 typedef struct agsaSSPCmdInfoUnitExt_s { bit8 lun[8]; bit8 reserved1; bit8 efb_tp_taskAttribute; bit8 reserved2; bit8 additionalCdbLen; bit8 cdb[MAX_CDB_LEN]; } agsaSSPCmdInfoUnitExt_t ; #define DIF_UDT_SIZE 6 /* difAction in agsaDif_t */ #define AGSA_DIF_INSERT 0 #define AGSA_DIF_VERIFY_FORWARD 1 #define AGSA_DIF_VERIFY_DELETE 2 #define AGSA_DIF_VERIFY_REPLACE 3 #define AGSA_DIF_VERIFY_UDT_REPLACE_CRC 5 #define AGSA_DIF_REPLACE_UDT_REPLACE_CRC 7 #define agsaDIFSectorSize512 0 #define agsaDIFSectorSize520 1 #define agsaDIFSectorSize4096 2 #define agsaDIFSectorSize4160 3 typedef struct agsaDif_s { agBOOLEAN enableDIFPerLA; bit32 flags; bit16 initialIOSeed; bit16 reserved; bit32 DIFPerLAAddrLo; bit32 DIFPerLAAddrHi; bit16 DIFPerLARegion0SecCount; bit16 Reserved2; bit8 udtArray[DIF_UDT_SIZE]; bit8 udrtArray[DIF_UDT_SIZE]; } agsaDif_t; /* From LL SDK2 */ #define DIF_FLAG_BITS_ACTION 0x00000007 /* 0-2*/ #define DIF_FLAG_BITS_CRC_VER 0x00000008 /* 3 */ #define DIF_FLAG_BITS_CRC_INV 0x00000010 /* 4 */ #define DIF_FLAG_BITS_CRC_SEED 0x00000020 /* 5 */ #define DIF_FLAG_BITS_UDT_REF_TAG 0x00000040 /* 6 */ #define DIF_FLAG_BITS_UDT_APP_TAG 0x00000080 /* 7 */ #define DIF_FLAG_BITS_UDTR_REF_BLKCOUNT 0x00000100 /* 8 */ #define DIF_FLAG_BITS_UDTR_APP_BLKCOUNT 0x00000200 /* 9 */ #define DIF_FLAG_BITS_CUST_APP_TAG 0x00000C00 /* 10 11*/ #define DIF_FLAG_BITS_EPRC 0x00001000 /* 12 */ #define DIF_FLAG_BITS_Reserved 0x0000E000 /* 13 14 15*/ #define DIF_FLAG_BITS_BLOCKSIZE_MASK 0x00070000 /* 16 17 18 */ #define DIF_FLAG_BITS_BLOCKSIZE_SHIFT 16 #define DIF_FLAG_BITS_BLOCKSIZE_512 0x00000000 /* */ #define DIF_FLAG_BITS_BLOCKSIZE_520 0x00010000 /* 16 */ #define DIF_FLAG_BITS_BLOCKSIZE_4096 0x00020000 /* 17 */ #define DIF_FLAG_BITS_BLOCKSIZE_4160 0x00030000 /* 16 17 */ #define DIF_FLAG_BITS_UDTVMASK 0x03F00000 /* 20 21 22 23 24 25 */ #define DIF_FLAG_BITS_UDTV_SHIFT 20 #define DIF_FLAG_BITS_UDTUPMASK 0xF6000000 /* 26 27 28 29 30 31 */ #define DIF_FLAG_BITS_UDTUPSHIFT 26 typedef struct agsaEncryptDek_s { bit32 dekTable; bit32 dekIndex; } agsaEncryptDek_t; typedef struct agsaEncrypt_s { agsaEncryptDek_t dekInfo; bit32 kekIndex; agBOOLEAN keyTagCheck; agBOOLEAN enableEncryptionPerLA; /* new */ bit32 sectorSizeIndex; bit32 cipherMode; bit32 keyTag_W0; bit32 keyTag_W1; bit32 tweakVal_W0; bit32 tweakVal_W1; bit32 tweakVal_W2; bit32 tweakVal_W3; bit32 EncryptionPerLAAddrLo; /* new */ bit32 EncryptionPerLAAddrHi; /* new */ bit16 EncryptionPerLRegion0SecCount; /* new */ bit16 reserved; } agsaEncrypt_t; /** \brief data structure describes a SAS SSP command request to be sent to the target device * * data structure describes a SAS SSP command request to be sent to the * target device. This structure limits the CDB length in SSP * command up to 16 bytes long. * * This data structure is one instance of the generic request issued to * saSSPStart() and is passed as an agsaSASRequestBody_t . * */ typedef struct agsaSSPInitiatorRequest_s { agsaSgl_t agSgl; /**< This structure is used to define either an ESGL list or a single SGL for the SSP command operation */ bit32 dataLength; /**< Total data length in bytes */ bit16 firstBurstSize; /**< First Burst Size field as defined by SAS specification */ bit16 flag; /**< bit1-0 TLR as SAS specification bit31-2 reserved */ agsaSSPCmdInfoUnit_t sspCmdIU; /**< Structure containing SSP Command INFORMATION UNIT */ agsaDif_t dif; agsaEncrypt_t encrypt; #ifdef SA_TESTBASE_EXTRA /* Added by TestBase */ bit16 bstIndex; #endif /* SA_TESTBASE_EXTRA */ } agsaSSPInitiatorRequest_t; /** \brief data structure describes a SAS SSP command request Ext to be sent to the target device * * data structure describes a SAS SSP command request to be sent to the * target device. This structure support the CDB length in SSP * command more than 16 bytes long. * * This data structure is one instance of the generic request issued to * saSSPStart() and is passed as an agsaSASRequestBody_t . * */ typedef struct agsaSSPInitiatorRequestExt_s { agsaSgl_t agSgl; /**< This structure is used to define either an ESGL list or a single SGL for the SSP command operation */ bit32 dataLength; bit16 firstBurstSize; bit16 flag; agsaSSPCmdInfoUnitExt_t sspCmdIUExt; agsaDif_t dif; agsaEncrypt_t encrypt; } agsaSSPInitiatorRequestExt_t; typedef struct agsaSSPInitiatorRequestIndirect_s { agsaSgl_t agSgl; /**< This structure is used to define either an ESGL list or a single SGL for the SSP command operation */ bit32 dataLength; bit16 firstBurstSize; bit16 flag; bit32 sspInitiatorReqAddrUpper32; /**< The upper 32 bits of the 64-bit physical DMA address of the SSP initiator request buffer */ bit32 sspInitiatorReqAddrLower32; /**< The lower 32 bits of the 64-bit physical DMA address of the SSP initiator request buffer */ bit32 sspInitiatorReqLen; /**< Specifies the length of the SSP initiator request in bytes */ agsaDif_t dif; agsaEncrypt_t encrypt; }agsaSSPInitiatorRequestIndirect_t; /** \brief data structure describes a SAS SSP target read and write request * * The agsaSSPTargetRequest_t data structure describes a SAS SSP target read * and write request to be issued on the port. It includes the * length of the data to be received or sent, an offset into the * data block where the transfer is to start, and a list of * scatter-gather buffers. * * This data structure is one instance of the generic request issued * to saSSPStart() and is passed as an agsaSASRequestBody_t . * */ /** bit definitions for sspOption Bit 0-1: Transport Layer Retry setting for other phase: 00b: No retry 01b: Retry on ACK/NAK timeout 10b: Retry on NAK received 11b: Retry on both ACK/NAK timeout and NAK received Bit 2-3: Transport Layer Retry setting for data phase: 00b: No retry 01b: Retry on ACK/NAK timeout 10b: Retry on NAK received 11b: Retry on both ACK/NAK timeout and NAK received Bit 4: Retry Data Frame. Valid only on write command. Indicates whether Target supports RTL for this particular IO. 1b: enabled 0b: disabled Bit 5: Auto good response on successful read (data transfer from target to initiator) request. 1b: Enabled 0b: Disabled Bits 6-15 : Reserved. */ typedef struct agsaSSPTargetRequest_s { agsaSgl_t agSgl; /**< This structure is used to define either an ESGL list or a single SGL for the target read or write operation */ bit32 dataLength; /**< Specifies the amount of data to be sent in this data phase */ bit32 offset; /**< Specifies the offset into the overall data block where this data phase is to begin */ bit16 agTag; /**< Tag from ossaSSPReqReceived(). */ bit16 sspOption; /**< SSP option for retry */ agsaDif_t dif; } agsaSSPTargetRequest_t; #define SSP_OPTION_BITS 0x3F /**< bit5-AGR, bit4-RDF bit3,2-RTE, bit1,0-AN */ #define SSP_OPTION_ODS 0x8000 /**< bit15-ODS */ #define SSP_OPTION_OTHR_NO_RETRY 0 #define SSP_OPTION_OTHR_RETRY_ON_ACK_NAK_TIMEOUT 1 #define SSP_OPTION_OTHR_RETRY_ON_NAK_RECEIVED 2 #define SSP_OPTION_OTHR_RETRY_ON_BOTH_ACK_NAK_TIMEOUT_AND_NAK_RECEIVED 3 #define SSP_OPTION_DATA_NO_RETRY 0 #define SSP_OPTION_DATA_RETRY_ON_ACK_NAK_TIMEOUT 1 #define SSP_OPTION_DATA_RETRY_ON_NAK_RECEIVED 2 #define SSP_OPTION_DATA_RETRY_ON_BOTH_ACK_NAK_TIMEOUT_AND_NAK_RECEIVED 3 #define SSP_OPTION_RETRY_DATA_FRAME_ENABLED (1 << SHIFT4) #define SSP_OPTION_AUTO_GOOD_RESPONSE (1 << SHIFT5) #define SSP_OPTION_ENCRYPT (1 << SHIFT6) #define SSP_OPTION_DIF (1 << SHIFT7) #define SSP_OPTION_OVERRIDE_DEVICE_STATE (1 << SHIFT15) /** \brief data structure describes a SAS SSP target response to be issued * on the port * * This data structure is one instance of the generic request issued to * saSSPStart() and is passed as an agsaSASRequestBody_t * */ typedef struct agsaSSPTargetResponse_s { bit32 agTag; /**< Tag from ossaSSPReqReceived(). */ void *frameBuf; bit32 respBufLength; /**< Specifies the length of the Response buffer */ bit32 respBufUpper; /**< Upper 32 bit of physical address of OS Layer allocated the Response buffer (agsaSSPResponseInfoUnit_t). Valid only when respBufLength is not zero */ bit32 respBufLower; /**< Lower 32 bit of physical address of OS Layer allocated the Response buffer (agsaSSPResponseInfoUnit_t). Valid only when respBufLength is not zero */ bit32 respOption; /**< Bit 0-1: ACK and NAK retry option: 00b: No retry 01b: Retry on ACK/NAK timeout 10b: Retry on NAK received 11b: Retry on both ACK/NAK timeout and NAK received */ } agsaSSPTargetResponse_t; #define RESP_OPTION_BITS 0x3 /** bit0-1 */ #define RESP_OPTION_ODS 0x8000 /** bit15 */ /** \brief data structure describes a SMP request or response frame to be sent on the SAS port * * The agsaSMPFrame_t data structure describes a SMP request or response * frame to be issued or sent on the SAS port. * * This data structure is one instance of the generic request issued to * saSMPStart() and is passed as an agsaSASRequestBody_t . * */ typedef struct agsaSMPFrame_s { void *outFrameBuf; /**< if payload is less than 32 bytes,A virtual frameBuf can be used. instead of physical address. Set to NULL and use physical address if payload is > 32 bytes */ bit32 outFrameAddrUpper32; /**< The upper 32 bits of the 64-bit physical DMA address of the SMP frame buffer */ bit32 outFrameAddrLower32; /**< The lower 32 bits of the 64-bit physical DMA address of the SMP frame buffer */ bit32 outFrameLen; /**< Specifies the length of the SMP request frame excluding the CRC field in bytes */ bit32 inFrameAddrUpper32; /**< The upper 32 bits of the 64-bit phsical address of DMA address of response SMP Frame buffer */ bit32 inFrameAddrLower32; /**< The lower 32 bits of the 64-bit phsical address of DMA address of response SMP Frame buffer */ bit32 inFrameLen; /**< Specifies the length of the SMP response frame excluding the CRC field in bytes */ bit32 expectedRespLen; /**< Specifies the length of SMP Response */ bit32 flag; /** For the SPCv controller: Bit 0: Indirect Response (IR). This indicates direct or indirect mode for SMP response frame to be received. 0b: Direct mode 1b: Indirect mode Bit 1: Indirect Payload (IP). This indicates direct or indirect mode for SMP request frame to be sent. 0b: Direct mode 1b: Indirect mode Bits 2-31: Reserved For the SPC controller: This is not applicable. */ } agsaSMPFrame_t; #define smpFrameFlagDirectResponse 0 #define smpFrameFlagIndirectResponse 1 #define smpFrameFlagDirectPayload 0 #define smpFrameFlagIndirectPayload 2 /** \brief union data structure specifies a request * * union data structure specifies a request */ typedef union agsaSASRequestBody_u { agsaSSPInitiatorRequest_t sspInitiatorReq; /**< Structure containing the SSP initiator request, Support up to 16 bytes CDB */ agsaSSPInitiatorRequestExt_t sspInitiatorReqExt; /**< Structure containing the SSP initiator request for CDB > 16 bytes */ agsaSSPInitiatorRequestIndirect_t sspInitiatorReqIndirect; /**< Structure containing the SSP indirect initiator request */ agsaSSPTargetRequest_t sspTargetReq; /**< Structure containing the SSP Target request */ agsaSSPScsiTaskMgntReq_t sspTaskMgntReq; /**< Structure containing the SSP SCSI Task Management request */ agsaSSPTargetResponse_t sspTargetResponse; /**< Structure containing the SSP Target response. */ agsaSMPFrame_t smpFrame; /**< Structure containing SMP request or response frame */ }agsaSASRequestBody_t; /** \brief data structure describes an STP or direct connect SATA command * * The agsaSATAInitiatorRequest_t data structure describes an STP or direct * connect SATA command request to be sent to the device and * passed as a parameter to saSATAStart() function. * * This structure is an encapsulation of SATA FIS (Frame Information * Structures), which enables the execution of ATA command * descriptor using SATA transport * */ typedef struct agsaSATAInitiatorRequest_s { agsaSgl_t agSgl; /**< This structure is used to define either an ESGL list or a single SGL for operation that involves DMA transfer */ bit32 dataLength; /**< Total data length in bytes */ bit32 option; /**< Operational option, defined using the bit field. b7-1: reserved b0: AGSA-STP-CLOSE-CLEAR-AFFILIATION */ agsaSATAHostFis_t fis; /**< The FIS request */ agsaDif_t dif; agsaEncrypt_t encrypt; bit8 scsiCDB[16]; #ifdef SA_TESTBASE_EXTRA /* Added by TestBase */ bit16 bstIndex; #endif /* SA_TESTBASE_EXTRA */ } agsaSATAInitiatorRequest_t; /* controller Configuration page */ #define AGSA_SAS_PROTOCOL_TIMER_CONFIG_PAGE 0x04 #define AGSA_INTERRUPT_CONFIGURATION_PAGE 0x05 #define AGSA_IO_GENERAL_CONFIG_PAGE 0x06 #define AGSA_ENCRYPTION_GENERAL_CONFIG_PAGE 0x20 #define AGSA_ENCRYPTION_DEK_CONFIG_PAGE 0x21 #define AGSA_ENCRYPTION_CONTROL_PARM_PAGE 0x22 #define AGSA_ENCRYPTION_HMAC_CONFIG_PAGE 0x23 #ifdef HIALEAH_ENCRYPTION typedef struct agsaEncryptGeneralPage_s { bit32 numberOfKeksPageCode; /* 0x20 */ bit32 KeyCardIdKekIndex; bit32 KeyCardId3_0; bit32 KeyCardId7_4; bit32 KeyCardId11_8; } agsaEncryptGeneralPage_t; #else typedef struct agsaEncryptGeneralPage_s { bit32 pageCode; /* 0x20 */ bit32 numberOfDeks; } agsaEncryptGeneralPage_t; #endif /* HIALEAH_ENCRYPTION */ #define AGSA_ENC_CONFIG_PAGE_KEK_NUMBER 0x0000FF00 #define AGSA_ENC_CONFIG_PAGE_KEK_SHIFT 8 /* sTSDK 4.14 */ typedef struct agsaEncryptDekConfigPage_s { bit32 pageCode; bit32 table0AddrLo; bit32 table0AddrHi; bit32 table0Entries; bit32 table0BFES; bit32 table1AddrLo; bit32 table1AddrHi; bit32 table1Entries; bit32 table1BFES; } agsaEncryptDekConfigPage_t; #define AGSA_ENC_DEK_CONFIG_PAGE_DEK_TABLE_NUMBER 0xF0000000 #define AGSA_ENC_DEK_CONFIG_PAGE_DEK_TABLE_SHIFT SHIFT28 #define AGSA_ENC_DEK_CONFIG_PAGE_DEK_CACHE_WAY 0x0F000000 #define AGSA_ENC_DEK_CONFIG_PAGE_DEK_CACHE_SHIFT SHIFT24 /*sTSDK 4.18 */ /* CCS (Current Crypto Services) and NOPR (Number of Operators) are valid only in GET_CONTROLLER_CONFIG */ /* NAR, CORCAP and USRCAP are valid only when AUT==1 */ typedef struct agsaEncryptControlParamPage_s { bit32 pageCode; /* 0x22 */ bit32 CORCAP; /* Crypto Officer Role Capabilities */ bit32 USRCAP; /* User Role Capabilities */ bit32 CCS; /* Current Crypto Services */ bit32 NOPR; /* Number of Operators */ } agsaEncryptControlParamPage_t; typedef struct agsaEncryptInfo_s { bit32 encryptionCipherMode; bit32 encryptionSecurityMode; bit32 status; bit32 flag; } agsaEncryptInfo_t; #define OperatorAuthenticationEnable_AUT 1 #define ReturnToFactoryMode_ARF 2 /*sTSDK 4.19 */ typedef struct agsaEncryptSelfTestBitMap_s { bit32 AES_Test; bit32 KEY_WRAP_Test; bit32 HMAC_Test; } agsaEncryptSelfTestBitMap_t; typedef struct agsaEncryptSelfTestStatusBitMap_s{ bit32 AES_Status; bit32 KEY_WRAP_Status; bit32 HMAC_Status; } agsaEncryptSelfTestStatusBitMap_t; typedef struct agsaEncryptHMACTestDescriptor_s { bit32 Dword0; bit32 MsgAddrLo; bit32 MsgAddrHi; bit32 MsgLen; bit32 DigestAddrLo; bit32 DigestAddrHi; bit32 KeyAddrLo; bit32 KeyAddrHi; bit32 KeyLen; } agsaEncryptHMACTestDescriptor_t; typedef struct agsaEncryptHMACTestResult_s { bit32 Dword0; bit32 Dword[12]; } agsaEncryptHMACTestResult_t; typedef struct agsaEncryptSHATestDescriptor_s { bit32 Dword0; bit32 MsgAddrLo; bit32 MsgAddrHi; bit32 MsgLen; bit32 DigestAddrLo; bit32 DigestAddrHi; } agsaEncryptSHATestDescriptor_t; typedef struct agsaEncryptSHATestResult_s { bit32 Dword0; bit32 Dword[12]; } agsaEncryptSHATestResult_t; /* types of self test */ #define AGSA_BIST_TEST 0x1 #define AGSA_HMAC_TEST 0x2 #define AGSA_SHA_TEST 0x3 /*sTSDK 4.13 */ typedef struct agsaEncryptDekBlob_s { bit8 dekBlob[80]; } agsaEncryptDekBlob_t; typedef struct agsaEncryptKekBlob_s { bit8 kekBlob[48]; } agsaEncryptKekBlob_t; /*sTSDK 4.45 */ typedef struct agsaEncryptHMACConfigPage_s { bit32 PageCode; bit32 CustomerTag; bit32 KeyAddrLo; bit32 KeyAddrHi; } agsaEncryptHMACConfigPage_t; /*sTSDK 4.38 */ #define AGSA_ID_SIZE 31 typedef struct agsaID_s { bit8 ID[AGSA_ID_SIZE]; }agsaID_t; #define SA_OPR_MGMNT_FLAG_MASK 0x00003000 #define SA_OPR_MGMNT_FLAG_SHIFT 12 /* */ typedef struct agsaSASPhyMiscPage_s { bit32 Dword0; bit32 Dword1; } agsaSASPhyMiscPage_t ; typedef struct agsaHWEventEncrypt_s { bit32 encryptOperation; bit32 status; bit32 eq; /* error qualifier */ bit32 info; void *handle; void *param; } agsaHWEventEncrypt_t; /*sTSDK 4.32 */ typedef struct agsaHWEventMode_s { bit32 modePageOperation; bit32 status; bit32 modePageLen; void *modePage; void *context; } agsaHWEventMode_t; /*sTSDK 4.33 */ typedef struct agsaInterruptConfigPage_s { bit32 pageCode; bit32 vectorMask0; bit32 vectorMask1; bit32 ICTC0; bit32 ICTC1; bit32 ICTC2; bit32 ICTC3; bit32 ICTC4; bit32 ICTC5; bit32 ICTC6; bit32 ICTC7; } agsaInterruptConfigPage_t; typedef struct agsaIoGeneralPage_s { bit32 pageCode; /* 0x06 */ bit32 ActiveMask; bit32 QrntTime; } agsaIoGeneralPage_t; /* \brief data structure defines detail information about Agilent Error * Detection Code (DIF) errors. * * The agsaDifDetails_t data structure defines detail information about * PMC Error Detection Code (DIF) error. Please refer to the latest T10 SBC * and SPC draft/specification for the definition of the Protection * Information. * * This structure is filled by the function saGetDifErrorDetails(). */ typedef struct agsaDifDetails_s { bit32 UpperLBA; bit32 LowerLBA; bit8 sasAddressHi[4]; bit8 sasAddressLo[4]; bit32 ExpectedCRCUDT01; bit32 ExpectedUDT2345; bit32 ActualCRCUDT01; bit32 ActualUDT2345; bit32 DIFErrDevID; bit32 ErrBoffsetEDataLen; void * frame; } agsaDifDetails_t; /** \brief data structure for SAS protocol timer configuration page. * */ typedef struct agsaSASProtocolTimerConfigurationPage_s{ bit32 pageCode; /* 0 */ bit32 MST_MSI; /* 1 */ bit32 STP_SSP_MCT_TMO; /* 2 */ bit32 STP_FRM_TMO; /* 3 */ bit32 STP_IDLE_TMO; /* 4 */ bit32 OPNRJT_RTRY_INTVL; /* 5 */ bit32 Data_Cmd_OPNRJT_RTRY_TMO; /* 6 */ bit32 Data_Cmd_OPNRJT_RTRY_THR; /* 7 */ bit32 MAX_AIP; /* 8 */ } agsaSASProtocolTimerConfigurationPage_t; /** \brief data structure for firmware flash update saFwFlashUpdate(). * * The agsaUpdateFwFlash data structure specifies a request to saFwFlashUpdate() */ typedef struct agsaUpdateFwFlash_s { bit32 currentImageOffset; bit32 currentImageLen; bit32 totalImageLen; agsaSgl_t agSgl; } agsaUpdateFwFlash_t; /** \brief data structure for extended firmware flash update saFwFlashExtUpdate(). * * The agsaFlashExtExecute_s data structure specifies a request to saFwFlashExtUpdate() */ typedef struct agsaFlashExtExecute_s { bit32 command; bit32 partOffset; bit32 dataLen; agsaSgl_t *agSgl; } agsaFlashExtExecute_t; /** \brief data structure for firmware flash update saFwFlashUpdate(). * * The agsaFlashExtResponse_t data structure specifies a request to ossaFlashExtExecuteCB().() */ typedef struct agsaFlashExtResponse_s { bit32 epart_size; bit32 epart_sect_size; } agsaFlashExtResponse_t; /** \brief data structure for set fields in MPI table. * The agsaMPIContext_t data structure is used to set fields in MPI table. * For details of MPI table, refer to PM8001 Tachyon SPC 8x6G Programmers' * Manual PMC-2080222 or PM8008/PM8009/PM8018 Tachyon SPCv/SPCve/SPCv+ Programmers Manual * PMC-2091148/PMC-2102373. sTSDK section 4.39 */ typedef struct agsaMPIContext_s { bit32 MPITableType; bit32 offset; bit32 value; } agsaMPIContext_t; #define AGSA_MPI_MAIN_CONFIGURATION_TABLE 1 #define AGSA_MPI_GENERAL_STATUS_TABLE 2 #define AGSA_MPI_INBOUND_QUEUE_CONFIGURATION_TABLE 3 #define AGSA_MPI_OUTBOUND_QUEUE_CONFIGURATION_TABLE 4 #define AGSA_MPI_SAS_PHY_ANALOG_SETUP_TABLE 5 #define AGSA_MPI_INTERRUPT_VECTOR_TABLE 6 #define AGSA_MPI_PER_SAS_PHY_ATTRIBUTE_TABLE 7 #define AGSA_MPI_OUTBOUND_QUEUE_FAILOVER_TABLE 8 /************************************************************/ /*This flag and datastructure are specific for fw profiling, Now defined as compiler flag*/ //#define SPC_ENABLE_PROFILE #ifdef SPC_ENABLE_PROFILE typedef struct agsaFwProfile_s { bit32 tcid; bit32 processor; bit32 cmd; bit32 len; bit32 codeStartAdd; bit32 codeEndAdd; agsaSgl_t agSgl; } agsaFwProfile_t; #endif /************************************************************/ /** \brief Callback definition for .ossaDeviceRegistration * */ typedef void (*ossaDeviceRegistrationCB_t)( agsaRoot_t *agRoot, agsaContext_t *agContext, bit32 status, agsaDevHandle_t *agDevHandle, bit32 deviceID ); /** \brief Callback definition for * */ typedef void (*ossaDeregisterDeviceHandleCB_t)( agsaRoot_t *agRoot, agsaContext_t *agContext, agsaDevHandle_t *agDevHandle, bit32 status ); /** \brief Callback definition for * */ typedef void (*ossaGenericCB_t)(void); /** \brief Callback definition for abort SMP SSP SATA callback * */ typedef void (*ossaGenericAbortCB_t)( agsaRoot_t *agRoot, agsaIORequest_t *agIORequest, bit32 flag, bit32 status ); typedef void (*ossaLocalPhyControlCB_t)( agsaRoot_t *agRoot, agsaContext_t *agContext, bit32 phyId, bit32 phyOperation, bit32 status, void *parm ); /** \brief Callback definition for * */ typedef void (*ossaSATACompletedCB_t)( agsaRoot_t *agRoot, agsaIORequest_t *agIORequest, bit32 agIOStatus, void *agFirstDword, bit32 agIOInfoLen, void *agParam ); /** \brief Callback definition for * */ typedef void (*ossaSMPCompletedCB_t)( agsaRoot_t *agRoot, agsaIORequest_t *agIORequest, bit32 agIOStatus, bit32 agIOInfoLen, agsaFrameHandle_t agFrameHandle ); /** \brief Callback definition for * */ typedef void (*ossaSSPCompletedCB_t)( agsaRoot_t *agRoot, agsaIORequest_t *agIORequest, bit32 agIOStatus, bit32 agIOInfoLen, void *agParam, bit16 sspTag, bit32 agOtherInfo ); /** \brief Callback definition for * */ typedef void (*ossaSetDeviceInfoCB_t) ( agsaRoot_t *agRoot, agsaContext_t *agContext, agsaDevHandle_t *agDevHandle, bit32 status, bit32 option, bit32 param ); typedef struct agsaOffloadDifDetails_s { bit32 ExpectedCRCUDT01; bit32 ExpectedUDT2345; bit32 ActualCRCUDT01; bit32 ActualUDT2345; bit32 DIFErr; bit32 ErrBoffset; } agsaOffloadDifDetails_t; typedef struct agsaDifEncPayload_s { agsaSgl_t SrcSgl; bit32 SrcDL; agsaSgl_t DstSgl; bit32 DstDL; agsaDif_t dif; agsaEncrypt_t encrypt; } agsaDifEncPayload_t; typedef void (*ossaVhistCaptureCB_t) ( agsaRoot_t *agRoot, agsaContext_t *agContext, bit32 status, bit32 len); typedef void (*ossaDIFEncryptionOffloadStartCB_t) ( agsaRoot_t *agRoot, agsaContext_t *agContext, bit32 status, agsaOffloadDifDetails_t *agsaOffloadDifDetails ); #define SA_RESERVED_REQUEST_COUNT 16 #ifdef SA_FW_TIMER_READS_STATUS #define SA_FW_TIMER_READS_STATUS_INTERVAL 20 #endif /* SA_FW_TIMER_READS_STATUS */ #define SIZE_DW 4 /**< Size in bytes */ #define SIZE_QW 8 /**< Size in bytes */ #define PCIBAR0 0 /**< PCI Base Address 0 */ #define PCIBAR1 1 /**< PCI Base Address 1 */ #define PCIBAR2 2 /**< PCI Base Address 2 */ #define PCIBAR3 3 /**< PCI Base Address 3 */ #define PCIBAR4 4 /**< PCI Base Address 4 */ #define PCIBAR5 5 /**< PCI Base Address 5 */ /** \brief describe an element of SPC-SPCV converter * * This structure is used * */ typedef struct agsaBarOffset_s { bit32 Generic; /* */ bit32 Bar; /* */ bit32 Offset; /* */ bit32 Length; /* */ } agsaBarOffset_t; typedef union agsabit32bit64_U { bit32 S32[2]; bit64 B64; } agsabit32bit64; /* The agsaIOErrorEventStats_t data structure is used as parameter in ossaGetIOErrorStatsCB(),ossaGetIOEventStatsCB(). This data structure contains the number of IO error and event. */ typedef struct agsaIOErrorEventStats_s { bit32 agOSSA_IO_COMPLETED_ERROR_SCSI_STATUS; bit32 agOSSA_IO_ABORTED; bit32 agOSSA_IO_OVERFLOW; bit32 agOSSA_IO_UNDERFLOW; bit32 agOSSA_IO_FAILED; bit32 agOSSA_IO_ABORT_RESET; bit32 agOSSA_IO_NOT_VALID; bit32 agOSSA_IO_NO_DEVICE; bit32 agOSSA_IO_ILLEGAL_PARAMETER; bit32 agOSSA_IO_LINK_FAILURE; bit32 agOSSA_IO_PROG_ERROR; bit32 agOSSA_IO_DIF_IN_ERROR; bit32 agOSSA_IO_DIF_OUT_ERROR; bit32 agOSSA_IO_ERROR_HW_TIMEOUT; bit32 agOSSA_IO_XFER_ERROR_BREAK; bit32 agOSSA_IO_XFER_ERROR_PHY_NOT_READY; bit32 agOSSA_IO_OPEN_CNX_ERROR_PROTOCOL_NOT_SUPPORTED; bit32 agOSSA_IO_OPEN_CNX_ERROR_ZONE_VIOLATION; bit32 agOSSA_IO_OPEN_CNX_ERROR_BREAK; bit32 agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS; bit32 agOSSA_IO_OPEN_CNX_ERROR_BAD_DESTINATION; bit32 agOSSA_IO_OPEN_CNX_ERROR_CONNECTION_RATE_NOT_SUPPORTED; bit32 agOSSA_IO_OPEN_CNX_ERROR_STP_RESOURCES_BUSY; bit32 agOSSA_IO_OPEN_CNX_ERROR_WRONG_DESTINATION; bit32 agOSSA_IO_OPEN_CNX_ERROR_UNKNOWN_ERROR; bit32 agOSSA_IO_XFER_ERROR_NAK_RECEIVED; bit32 agOSSA_IO_XFER_ERROR_ACK_NAK_TIMEOUT; bit32 agOSSA_IO_XFER_ERROR_PEER_ABORTED; bit32 agOSSA_IO_XFER_ERROR_RX_FRAME; bit32 agOSSA_IO_XFER_ERROR_DMA; bit32 agOSSA_IO_XFER_ERROR_CREDIT_TIMEOUT; bit32 agOSSA_IO_XFER_ERROR_SATA_LINK_TIMEOUT; bit32 agOSSA_IO_XFER_ERROR_SATA; bit32 agOSSA_IO_XFER_ERROR_ABORTED_DUE_TO_SRST; bit32 agOSSA_IO_XFER_ERROR_REJECTED_NCQ_MODE; bit32 agOSSA_IO_XFER_ERROR_ABORTED_NCQ_MODE; bit32 agOSSA_IO_XFER_OPEN_RETRY_TIMEOUT; bit32 agOSSA_IO_XFER_SMP_RESP_CONNECTION_ERROR; bit32 agOSSA_IO_XFER_ERROR_UNEXPECTED_PHASE; bit32 agOSSA_IO_XFER_ERROR_XFER_RDY_OVERRUN; bit32 agOSSA_IO_XFER_ERROR_XFER_RDY_NOT_EXPECTED; bit32 agOSSA_IO_XFER_ERROR_CMD_ISSUE_ACK_NAK_TIMEOUT; bit32 agOSSA_IO_XFER_ERROR_CMD_ISSUE_BREAK_BEFORE_ACK_NAK; bit32 agOSSA_IO_XFER_ERROR_CMD_ISSUE_PHY_DOWN_BEFORE_ACK_NAK; bit32 agOSSA_IO_XFER_ERROR_OFFSET_MISMATCH; bit32 agOSSA_IO_XFER_ERROR_XFER_ZERO_DATA_LEN; bit32 agOSSA_IO_XFER_CMD_FRAME_ISSUED; bit32 agOSSA_IO_ERROR_INTERNAL_SMP_RESOURCE; bit32 agOSSA_IO_PORT_IN_RESET; bit32 agOSSA_IO_DS_NON_OPERATIONAL; bit32 agOSSA_IO_DS_IN_RECOVERY; bit32 agOSSA_IO_TM_TAG_NOT_FOUND; bit32 agOSSA_IO_XFER_PIO_SETUP_ERROR; bit32 agOSSA_IO_SSP_EXT_IU_ZERO_LEN_ERROR; bit32 agOSSA_IO_DS_IN_ERROR; bit32 agOSSA_IO_OPEN_CNX_ERROR_HW_RESOURCE_BUSY; bit32 agOSSA_IO_ABORT_IN_PROGRESS; bit32 agOSSA_IO_ABORT_DELAYED; bit32 agOSSA_IO_INVALID_LENGTH; bit32 agOSSA_IO_OPEN_CNX_ERROR_HW_RESOURCE_BUSY_ALT; bit32 agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_RETRY_BACKOFF_THRESHOLD_REACHED; bit32 agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_TMO; bit32 agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_NO_DEST; bit32 agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_OPEN_COLLIDE; bit32 agOSSA_IO_OPEN_CNX_ERROR_IT_NEXUS_LOSS_PATHWAY_BLOCKED; bit32 agOSSA_IO_DS_INVALID; bit32 agOSSA_IO_XFER_READ_COMPL_ERR; bit32 agOSSA_IO_XFER_ERR_LAST_PIO_DATAIN_CRC_ERR; bit32 agOSSA_IO_XFR_ERROR_INTERNAL_CRC_ERROR; bit32 agOSSA_MPI_IO_RQE_BUSY_FULL; bit32 agOSSA_MPI_ERR_IO_RESOURCE_UNAVAILABLE; bit32 agOSSA_MPI_ERR_ATAPI_DEVICE_BUSY; bit32 agOSSA_IO_XFR_ERROR_DEK_KEY_CACHE_MISS; bit32 agOSSA_IO_XFR_ERROR_DEK_KEY_TAG_MISMATCH; bit32 agOSSA_IO_XFR_ERROR_CIPHER_MODE_INVALID; bit32 agOSSA_IO_XFR_ERROR_DEK_IV_MISMATCH; bit32 agOSSA_IO_XFR_ERROR_DEK_RAM_INTERFACE_ERROR; bit32 agOSSA_IO_XFR_ERROR_INTERNAL_RAM; bit32 agOSSA_IO_XFR_ERROR_DIF_MISMATCH; bit32 agOSSA_IO_XFR_ERROR_DIF_APPLICATION_TAG_MISMATCH; bit32 agOSSA_IO_XFR_ERROR_DIF_REFERENCE_TAG_MISMATCH; bit32 agOSSA_IO_XFR_ERROR_DIF_CRC_MISMATCH; bit32 agOSSA_IO_XFR_ERROR_INVALID_SSP_RSP_FRAME; bit32 agOSSA_IO_XFER_ERR_EOB_DATA_OVERRUN; bit32 agOSSA_IO_XFR_ERROR_DEK_INDEX_OUT_OF_BOUNDS; bit32 agOSSA_IO_OPEN_CNX_ERROR_OPEN_PREEMPTED; bit32 agOSSA_IO_XFR_ERROR_DEK_ILLEGAL_TABLE; bit32 agOSSA_IO_XFER_ERROR_DIF_INTERNAL_ERROR; bit32 agOSSA_MPI_ERR_OFFLOAD_DIF_OR_ENC_NOT_ENABLED; bit32 agOSSA_IO_XFER_ERROR_DMA_ACTIVATE_TIMEOUT; bit32 agOSSA_IO_UNKNOWN_ERROR; } agsaIOErrorEventStats_t; /************************************************************************************ * * * Data Structures Defined for LL API ends * * * ************************************************************************************/ #ifdef SALL_API_TEST typedef struct agsaIOCountInfo_s { bit32 numSSPStarted; // saSSPStart() bit32 numSSPAborted; // saSSPAbort() bit32 numSSPAbortedCB; // ossaSSPAbortCB() bit32 numSSPCompleted; // includes success and aborted IOs bit32 numSMPStarted; // saSMPStart() bit32 numSMPAborted; // saSMPAbort() bit32 numSMPAbortedCB; // ossaSMPAbortCB() bit32 numSMPCompleted; // includes success and aborted IOs bit32 numSataStarted; // saSATAStart() bit32 numSataAborted; // saSATAAbort() bit32 numSataAbortedCB; // ossaSATAAbortCB() bit32 numSataCompleted; // includes success and aborted IOs bit32 numEchoSent; // saEchoCommand() bit32 numEchoCB; // ossaEchoCB() bit32 numUNKNWRespIOMB; // unknow Response IOMB received bit32 numOurIntCount; //InterruptHandler() counter bit32 numSpuriousInt; //spurious interrupts // bit32 numSpInts[64]; //spuriours interrupts count for each OBQ (PI=CI) // bit32 numSpInts1[64]; //spuriours interrupts count for each OBQ (PI!=CI) } agsaIOCountInfo_t; /* Total IO Counter */ #define LL_COUNTERS 17 /* Counter Bit Map */ #define COUNTER_SSP_START 0x000001 #define COUNTER_SSP_ABORT 0x000002 #define COUNTER_SSPABORT_CB 0x000004 #define COUNTER_SSP_COMPLETEED 0x000008 #define COUNTER_SMP_START 0x000010 #define COUNTER_SMP_ABORT 0x000020 #define COUNTER_SMPABORT_CB 0x000040 #define COUNTER_SMP_COMPLETEED 0x000080 #define COUNTER_SATA_START 0x000100 #define COUNTER_SATA_ABORT 0x000200 #define COUNTER_SATAABORT_CB 0x000400 #define COUNTER_SATA_COMPLETEED 0x000800 #define COUNTER_ECHO_SENT 0x001000 #define COUNTER_ECHO_CB 0x002000 #define COUNTER_UNKWN_IOMB 0x004000 #define COUNTER_OUR_INT 0x008000 #define COUNTER_SPUR_INT 0x010000 #define ALL_COUNTERS 0xFFFFFF typedef union agsaLLCountInfo_s { agsaIOCountInfo_t IOCounter; bit32 arrayIOCounter[LL_COUNTERS]; } agsaLLCountInfo_t; #endif /* SALL_API_TEST */ #define MAX_IO_DEVICE_ENTRIES 4096 /**< Maximum Device Entries */ #ifdef SA_ENABLE_POISION_TLP #define SA_PTNFE_POISION_TLP 1 /* Enable if one */ #else /* SA_ENABLE_POISION_TLP */ #define SA_PTNFE_POISION_TLP 0 /* Disable if zero default setting */ #endif /* SA_ENABLE_POISION_TLP */ #ifdef SA_DISABLE_MDFD #define SA_MDFD_MULTI_DATA_FETCH 1 /* Disable if one */ #else /* SA_DISABLE_MDFD */ #define SA_MDFD_MULTI_DATA_FETCH 0 /* Enable if zero default setting */ #endif /* SA_DISABLE_MDFD */ #ifdef SA_ENABLE_ARBTE #define SA_ARBTE 1 /* Enable if one */ #else /* SA_ENABLE_ARBTE */ #define SA_ARBTE 0 /* Disable if zero default setting */ #endif /* SA_ENABLE_ARBTE */ #ifdef SA_DISABLE_OB_COAL #define SA_OUTBOUND_COALESCE 0 /* Disable if zero */ #else /* SA_DISABLE_OB_COAL */ #define SA_OUTBOUND_COALESCE 1 /* Enable if one default setting */ #endif /* SA_DISABLE_OB_COAL */ /*********************************************************************************** * * * The OS Layer Functions Declarations start * * * ***********************************************************************************/ #include "saosapi.h" /*********************************************************************************** * * * The OS Layer Functions Declarations end * * * ***********************************************************************************/ /*********************************************************************************** * * * The LL Layer Functions Declarations start * * * ***********************************************************************************/ #ifdef FAST_IO_TEST /* needs to be allocated by the xPrepare() caller, one struct per IO */ typedef struct agsaFastCBBuf_s { void *cb; void *cbArg; void *pSenseData; bit8 *senseLen; /* internal */ void *oneDeviceData; /* tdsaDeviceData_t */ } agsaFastCBBuf_t; typedef struct agsaFastCommand_s { /* in */ void *agRoot; /* modified by TD tiFastPrepare() */ void *devHandle; /* agsaDevHandle_t* */ void *agSgl; /* agsaSgl_t* */ bit32 dataLength; bit32 extDataLength; bit8 additionalCdbLen; bit8 *cdb; bit8 *lun; /* modified by TD tiFastPrepare() */ bit8 taskAttribute; /* TD_xxx */ bit16 flag; /* TLR_MASK */ bit32 agRequestType; bit32 queueNum; agsaFastCBBuf_t *safb; } agsaFastCommand_t; #endif /* Enable test by setting bits in gFPGA_TEST */ #define EnableFPGA_TEST_ICCcontrol 0x01 #define EnableFPGA_TEST_ReadDEV 0x02 #define EnableFPGA_TEST_WriteCALAll 0x04 #define EnableFPGA_TEST_ReconfigSASParams 0x08 #define EnableFPGA_TEST_LocalPhyControl 0x10 #define EnableFPGA_TEST_PortControl 0x20 /* PM8001/PM8008/PM8009/PM8018 sTSDK Low-Level Architecture Specification SDK2 3.3 Encryption Status Definitions Encryption engine generated errors. Table 7 Encryption Engine Generated Errors Error Definition */ /* PM 1.01 section 4.26.12.6 Encryption Errors Table 51 lists initialization errors related to encryption functionality. For information on errors reported for inbound IOMB commands, refer to the corresponding outbound response sections. The error codes listed in Table 51 are reported in the Scratchpad 3 Register. */ #define OSSA_ENCRYPT_ENGINE_FAILURE_MASK 0x00FF0000 /* Encrypt Engine failed the BIST Test */ #define OSSA_ENCRYPT_SEEPROM_NOT_FOUND 0x01 /* SEEPROM is not installed. This condition is reported based on the bootstrap pin setting. */ #define OSSA_ENCRYPT_SEEPROM_IPW_RD_ACCESS_TMO 0x02 /* SEEPROM access timeout detected while reading initialization password or Allowable Cipher Modes. */ #define OSSA_ENCRYPT_SEEPROM_IPW_RD_CRC_ERR 0x03 /* CRC Error detected when reading initialization password or Allowable Cipher Modes. */ #define OSSA_ENCRYPT_SEEPROM_IPW_INVALID 0x04 /* Initialization password read from SEEPROM doesn't match any valid password value. This could also mean SEEPROM is blank. */ #define OSSA_ENCRYPT_SEEPROM_WR_ACCESS_TMO 0x05 /* access timeout detected while writing initialization password or Allowable Cipher Modes. */ #define OSSA_ENCRYPT_FLASH_ACCESS_TMO 0x20 /* Timeout while reading flash memory. */ #define OSSA_ENCRYPT_FLASH_SECTOR_ERASE_TMO 0x21 /* Flash sector erase timeout while writing to flash memory. */ #define OSSA_ENCRYPT_FLASH_SECTOR_ERASE_ERR 0x22 /* Flash sector erase failure while writing to flash memory. */ #define OSSA_ENCRYPT_FLASH_ECC_CHECK_ERR 0x23 /* Flash ECC check failure. */ #define OSSA_ENCRYPT_FLASH_NOT_INSTALLED 0x24 /* Flash memory not installed, this error is only detected in Security Mode B. */ #define OSSA_ENCRYPT_INITIAL_KEK_NOT_FOUND 0x40 /* Initial KEK is not found in the flash memory. This error is only detected in Security Mode B. */ #define OSSA_ENCRYPT_AES_BIST_ERR 0x41 /* Built-In Test Failure */ #define OSSA_ENCRYPT_KWP_BIST_FAILURE 0x42 /* Built-In Test Failed on Key Wrap Engine */ /* 0x01:ENC_ERR_SEEPROM_NOT_INSTALLED */ /* 0x02:ENC_ERR_SEEPROM_IPW_RD_ACCESS_TMO */ /* 0x03:ENC_ERR_SEEPROM_IPW_RD_CRC_ERR */ /* 0x04:ENC_ERR_SEEPROM_IPW_INVALID */ /* 0x05:ENC_ERR_SEEPROM_WR_ACCESS_TMO */ /* 0x20:ENC_ERR_FLASH_ACCESS_TMO */ /* 0x21:ENC_ERR_FLASH_SECTOR_ERASE_TMO */ /* 0x22:ENC_ERR_FLASH_SECTOR_ERASE_FAILURE */ /* 0x23:ENC_ERR_FLASH_ECC_CHECK_FAILURE */ /* 0x24:ENC_ERR_FLASH_NOT_INSTALLED */ /* 0x40:ENC_ERR_INITIAL_KEK_NOT_FOUND */ /* 0x41:ENC_ERR_AES_BIST_FAILURE */ /* 0x42:ENC_ERR_KWP_BIST_FAILURE */ /* This field indicates self test failure in DIF engine bits [27:24]. */ #define OSSA_DIF_ENGINE_FAILURE_MASK 0x0F000000 /* DIF Engine failed the BIST Test */ #define OSSA_DIF_ENGINE_0_BIST_FAILURE 0x1 /* DIF Engine 0 failed the BIST Test */ #define OSSA_DIF_ENGINE_1_BIST_FAILURE 0x2 /* DIF Engine 1 failed the BIST Test */ #define OSSA_DIF_ENGINE_2_BIST_FAILURE 0x4 /* DIF Engine 2 failed the BIST Test */ #define OSSA_DIF_ENGINE_3_BIST_FAILURE 0x8 /* DIF Engine 3 failed the BIST Test */ #define SA_ROLE_CAPABILITIES_CSP 0x001 #define SA_ROLE_CAPABILITIES_OPR 0x002 #define SA_ROLE_CAPABILITIES_SCO 0x004 #define SA_ROLE_CAPABILITIES_STS 0x008 #define SA_ROLE_CAPABILITIES_TST 0x010 #define SA_ROLE_CAPABILITIES_KEK 0x020 #define SA_ROLE_CAPABILITIES_DEK 0x040 #define SA_ROLE_CAPABILITIES_IOS 0x080 #define SA_ROLE_CAPABILITIES_FWU 0x100 #define SA_ROLE_CAPABILITIES_PRM 0x200 #include "saapi.h" /*********************************************************************************** * * * The LL Layer Functions Declarations end * * * ***********************************************************************************/ #endif /*__SA_H__ */