/* $Id$ * * This file is subject to the terms and conditions of the GNU General Public * License. See the file "COPYING" in the main directory of this archive * for more details. * * Copyright (C) 1992 - 1997, 2000 Silicon Graphics, Inc. * Copyright (C) 2000 by Colin Ngam */ #ifndef _ASM_SN_SN1_HUBMD_NEXT_H #define _ASM_SN_SN1_HUBMD_NEXT_H #ifdef BRINGUP /* XXX moved over from SN/SN0/hubmd.h -- each should be checked for SN1 */ /* In fact, most of this stuff is wrong. Some is correct, such as * MD_PAGE_SIZE and MD_PAGE_NUM_SHFT. */ #define MD_PERF_COUNTERS 6 #define MD_PERF_SETS 6 #define MD_SIZE_EMPTY 0 #define MD_SIZE_64MB 1 #define MD_SIZE_128MB 2 #define MD_SIZE_256MB 3 #define MD_SIZE_512MB 4 #define MD_SIZE_1GB 5 #define MD_SIZE_BYTES(size) ((size) == 0 ? 0 : 0x2000000L << (size)) #define MD_SIZE_MBYTES(size) ((size) == 0 ? 0 : 0x20 << (size)) #define MD_NUM_ENABLED(_x) ((_x & 0x1) + ((_x >> 1) & 0x1) + \ ((_x >> 2) & 0x1) + ((_x >> 3) & 0x1)) /* Hardware page size and shift */ #define MD_PAGE_SIZE 16384 /* Page size in bytes */ #define MD_PAGE_NUM_SHFT 14 /* Address to page number shift */ #define MMC_IO_PROT (UINT64_CAST 1 << 45) /* Register offsets from LOCAL_HUB or REMOTE_HUB */ #define MD_PERF_SEL 0x210000 /* Select perf monitor events */ /* MD_MIG_VALUE_THRESH bit definitions */ #define MD_MIG_VALUE_THRES_VALID_MASK (UINT64_CAST 0x1 << 63) #define MD_MIG_VALUE_THRES_VALUE_MASK (UINT64_CAST 0xfffff) /* MD_MIG_CANDIDATE bit definitions */ #define MD_MIG_CANDIDATE_VALID_MASK (UINT64_CAST 0x1 << 63) #define MD_MIG_CANDIDATE_VALID_SHFT 63 #define MD_MIG_CANDIDATE_TYPE_MASK (UINT64_CAST 0x1 << 30) #define MD_MIG_CANDIDATE_TYPE_SHFT 30 #define MD_MIG_CANDIDATE_OVERRUN_MASK (UINT64_CAST 0x1 << 29) #define MD_MIG_CANDIDATE_OVERRUN_SHFT 29 #define MD_MIG_CANDIDATE_NODEID_MASK (UINT64_CAST 0x1ff << 20) #define MD_MIG_CANDIDATE_NODEID_SHFT 20 #define MD_MIG_CANDIDATE_ADDR_MASK (UINT64_CAST 0x3ffff) /* XXX protection and migration are completely revised on SN1. On SN0, the reference count and protection fields were accessed in the same word, but on SN1 they reside at different addresses. The users of these macros will need to be rewritten. Also, the MD page size is 16K on SN1 but 4K on SN0. */ /* Premium SIMM protection entry shifts and masks. */ #define MD_PPROT_SHFT 0 /* Prot. field */ #define MD_PPROT_MASK 0xf #define MD_PPROT_REFCNT_SHFT 5 /* Reference count */ #define MD_PPROT_REFCNT_WIDTH 0x7ffff #define MD_PPROT_REFCNT_MASK (MD_PPROT_REFCNT_WIDTH << 5) #define MD_PPROT_IO_SHFT 8 /* I/O Prot field */ /* Standard SIMM protection entry shifts and masks. */ #define MD_SPROT_SHFT 0 /* Prot. field */ #define MD_SPROT_MASK 0xf #define MD_SPROT_IO_SHFT 8 #define MD_SPROT_REFCNT_SHFT 5 /* Reference count */ #define MD_SPROT_REFCNT_WIDTH 0x7ff #define MD_SPROT_REFCNT_MASK (MD_SPROT_REFCNT_WIDTH << 5) /* Migration modes used in protection entries */ #define MD_PROT_MIGMD_IREL (UINT64_CAST 0x3 << 3) #define MD_PROT_MIGMD_IABS (UINT64_CAST 0x2 << 3) #define MD_PROT_MIGMD_PREL (UINT64_CAST 0x1 << 3) #define MD_PROT_MIGMD_OFF (UINT64_CAST 0x0 << 3) /* * Operations on Memory/Directory DIMM control register */ #define DIRTYPE_PREMIUM 1 #define DIRTYPE_STANDARD 0 /* * Operations on page migration count difference and absolute threshold * registers */ #define MD_MIG_VALUE_THRESH_GET(region) ( \ REMOTE_HUB_L((region), MD_MIG_VALUE_THRESH) & \ MD_MIG_VALUE_THRES_VALUE_MASK) #define MD_MIG_VALUE_THRESH_SET(region, value) ( \ REMOTE_HUB_S((region), MD_MIG_VALUE_THRESH, \ MD_MIG_VALUE_THRES_VALID_MASK | (value))) #define MD_MIG_VALUE_THRESH_ENABLE(region) ( \ REMOTE_HUB_S((region), MD_MIG_VALUE_THRESH, \ REMOTE_HUB_L((region), MD_MIG_VALUE_THRESH) \ | MD_MIG_VALUE_THRES_VALID_MASK)) /* * Operations on page migration candidate register */ #define MD_MIG_CANDIDATE_GET(my_region_id) ( \ REMOTE_HUB_L((my_region_id), MD_MIG_CANDIDATE_CLR)) #define MD_MIG_CANDIDATE_HWPFN(value) ((value) & MD_MIG_CANDIDATE_ADDR_MASK) #define MD_MIG_CANDIDATE_NODEID(value) ( \ ((value) & MD_MIG_CANDIDATE_NODEID_MASK) >> MD_MIG_CANDIDATE_NODEID_SHFT) #define MD_MIG_CANDIDATE_TYPE(value) ( \ ((value) & MD_MIG_CANDIDATE_TYPE_MASK) >> MD_MIG_CANDIDATE_TYPE_SHFT) #define MD_MIG_CANDIDATE_VALID(value) ( \ ((value) & MD_MIG_CANDIDATE_VALID_MASK) >> MD_MIG_CANDIDATE_VALID_SHFT) /* * Macros to retrieve fields in the protection entry */ /* for Premium SIMM */ #define MD_PPROT_REFCNT_GET(value) ( \ ((value) & MD_PPROT_REFCNT_MASK) >> MD_PPROT_REFCNT_SHFT) /* for Standard SIMM */ #define MD_SPROT_REFCNT_GET(value) ( \ ((value) & MD_SPROT_REFCNT_MASK) >> MD_SPROT_REFCNT_SHFT) #if _LANGUAGE_C #ifdef LITTLE_ENDIAN typedef union md_perf_sel { uint64_t perf_sel_reg; struct { uint64_t perf_sel : 3, perf_en : 1, perf_rsvd : 60; } perf_sel_bits; } md_perf_sel_t; #else typedef union md_perf_sel { uint64_t perf_sel_reg; struct { uint64_t perf_rsvd : 60, perf_en : 1, perf_sel : 3; } perf_sel_bits; } md_perf_sel_t; #endif #endif /* _LANGUAGE_C */ #endif /* BRINGUP */ /* Like SN0, SN1 supports a mostly-flat address space with 8 CPU-visible, evenly spaced, contiguous regions, or "software banks". On SN1, software bank n begins at addresses n * 1GB, 0 <= n < 8. Physically (and very unlike SN0), each SN1 node board contains 8 dimm sockets, arranged as 4 "DIMM banks" of 2 dimms each. DIMM size and width (x4/x8) is assigned per dimm bank. Each DIMM bank consists of 2 "physical banks", one on the front sides of the 2 DIMMs and the other on the back sides. Therefore a node has a total of 8 ( = 4 * 2) physical banks. They are collectively referred to as "locational banks", since the locational bank number depends on the physical location of the DIMMs on the board. Dimm bank 0, Phys bank 0a (locational bank 0a) Slot D0 ---------------------------------------------- Dimm bank 0, Phys bank 1a (locational bank 1a) Dimm bank 1, Phys bank 0a (locational bank 2a) Slot D1 ---------------------------------------------- Dimm bank 1, Phys bank 1a (locational bank 3a) Dimm bank 2, Phys bank 0a (locational bank 4a) Slot D2 ---------------------------------------------- Dimm bank 2, Phys bank 1a (locational bank 5a) Dimm bank 3, Phys bank 0a (locational bank 6a) Slot D3 ---------------------------------------------- Dimm bank 3, Phys bank 1a (locational bank 7a) Dimm bank 0, Phys bank 0b (locational bank 0b) Slot D4 ---------------------------------------------- Dimm bank 0, Phys bank 1b (locational bank 1b) Dimm bank 1, Phys bank 0b (locational bank 2b) Slot D5 ---------------------------------------------- Dimm bank 1, Phys bank 1b (locational bank 3b) Dimm bank 2, Phys bank 0b (locational bank 4b) Slot D6 ---------------------------------------------- Dimm bank 2, Phys bank 1b (locational bank 5b) Dimm bank 3, Phys bank 0b (locational bank 6b) Slot D7 ---------------------------------------------- Dimm bank 3, Phys bank 1b (locational bank 7b) Since bank size is assigned per DIMM bank, each pair of locational banks must have the same size. However, they may be enabled/disabled individually. The locational banks map to the software banks via the dimm0_sel field in MD_MEMORY_CONFIG. When the field is 0 (the usual case), the mapping is direct: eg. locational bank 1 (dimm bank 0, physical bank 1, which is the back side of the first DIMM pair) corresponds to software bank 1, at node offset 1GB. More generally, locational bank = software bank XOR dimm0_sel. All the PROM's data structures (promlog variables, klconfig, etc.) track memory by the locational bank number. The kernel usually tracks memory by the software bank number. memsupport.c:slot_psize_compute() performs the mapping. (Note: the terms "locational bank" and "software bank" are not offical in any way, but I've tried to make the PROM use them consistently -- bjj.) */ #define MD_MEM_BANKS 8 #define MD_MEM_DIMM_BANKS 4 #define MD_BANK_SHFT 30 /* log2(1 GB) */ #define MD_BANK_MASK (UINT64_CAST 0x7 << 30) #define MD_BANK_SIZE (UINT64_CAST 1 << MD_BANK_SHFT) /* 1 GB */ #define MD_BANK_OFFSET(_b) (UINT64_CAST (_b) << MD_BANK_SHFT) #define MD_BANK_GET(addr) (((addr) & MD_BANK_MASK) >> MD_BANK_SHFT) #define MD_BANK_TO_DIMM_BANK(_b) (( (_b) >> 1) & 0x3) #define MD_BANK_TO_PHYS_BANK(_b) (( (_b) >> 0) & 0x1) #define MD_DIMM_BANK_GET(addr) MD_BANK_TO_DIMM_BANK(MD_BANK_GET(addr)) #define MD_PHYS_BANK_GET(addr) MD_BANK_TO_PHYS_BANK(MD_BANK_GET(addr)) /* Split an MD pointer (or message source & suppl. fields) into node, device */ #define MD_PTR_NODE_SHFT 3 #define MD_PTR_DEVICE_MASK 0x7 #define MD_PTR_SUBNODE0_MASK 0x1 #define MD_PTR_SUBNODE1_MASK 0x4 /********************************************************************** Backdoor protection and page counter structures **********************************************************************/ /* Protection entries and page counters are interleaved at 4 separate addresses, 0x10 apart. Software must read/write all four. */ #define BD_ITLV_COUNT 4 #define BD_ITLV_STRIDE 0x10 /* Protection entries */ /* (these macros work for standard (_rgn < 32) or premium DIMMs) */ #define MD_PROT_SHFT(_rgn, _io) ((((_rgn) & 0x20) >> 2 | \ ((_rgn) & 0x01) << 2 | \ ((_io) & 0x1) << 1) * 8) #define MD_PROT_MASK(_rgn, _io) (0xff << MD_PROT_SHFT(_rgn, _io)) #define MD_PROT_GET(_val, _rgn, _io) \ (((_val) & MD_PROT_MASK(_rgn, _io)) >> MD_PROT_SHFT(_rgn, _io)) /* Protection field values */ #define MD_PROT_RW (UINT64_CAST 0xff) #define MD_PROT_RO (UINT64_CAST 0x0f) #define MD_PROT_NO (UINT64_CAST 0x00) /********************************************************************** Directory format structures ***********************************************************************/ #ifdef _LANGUAGE_C /* Standard Directory Entries */ #ifdef LITTLE_ENDIAN struct md_sdir_pointer_fmt { /* exclusive, busy shared/excl, wait, poisoned */ bdrkreg_t sdp_format : 2; bdrkreg_t sdp_state : 3; bdrkreg_t sdp_priority : 3; bdrkreg_t sdp_pointer1 : 8; bdrkreg_t sdp_ecc : 6; bdrkreg_t sdp_locprot : 1; bdrkreg_t sdp_reserved : 1; bdrkreg_t sdp_crit_word_off : 3; bdrkreg_t sdp_pointer2 : 5; bdrkreg_t sdp_fill : 32; }; #else struct md_sdir_pointer_fmt { /* exclusive, busy shared/excl, wait, poisoned */ bdrkreg_t sdp_fill : 32; bdrkreg_t sdp_pointer2 : 5; bdrkreg_t sdp_crit_word_off : 3; bdrkreg_t sdp_reserved : 1; bdrkreg_t sdp_locprot : 1; bdrkreg_t sdp_ecc : 6; bdrkreg_t sdp_pointer1 : 8; bdrkreg_t sdp_priority : 3; bdrkreg_t sdp_state : 3; bdrkreg_t sdp_format : 2; }; #endif #ifdef LITTLE_ENDIAN struct md_sdir_fine_fmt { /* shared (fine) */ bdrkreg_t sdf_format : 2; bdrkreg_t sdf_tag1 : 3; bdrkreg_t sdf_tag2 : 3; bdrkreg_t sdf_vector1 : 8; bdrkreg_t sdf_ecc : 6; bdrkreg_t sdf_locprot : 1; bdrkreg_t sdf_tag2valid : 1; bdrkreg_t sdf_vector2 : 8; bdrkreg_t sdf_fill : 32; }; #else struct md_sdir_fine_fmt { /* shared (fine) */ bdrkreg_t sdf_fill : 32; bdrkreg_t sdf_vector2 : 8; bdrkreg_t sdf_tag2valid : 1; bdrkreg_t sdf_locprot : 1; bdrkreg_t sdf_ecc : 6; bdrkreg_t sdf_vector1 : 8; bdrkreg_t sdf_tag2 : 3; bdrkreg_t sdf_tag1 : 3; bdrkreg_t sdf_format : 2; }; #endif #ifdef LITTLE_ENDIAN struct md_sdir_coarse_fmt { /* shared (coarse) */ bdrkreg_t sdc_format : 2; bdrkreg_t sdc_reserved_1 : 6; bdrkreg_t sdc_vector_a : 8; bdrkreg_t sdc_ecc : 6; bdrkreg_t sdc_locprot : 1; bdrkreg_t sdc_reserved : 1; bdrkreg_t sdc_vector_b : 8; bdrkreg_t sdc_fill : 32; }; #else struct md_sdir_coarse_fmt { /* shared (coarse) */ bdrkreg_t sdc_fill : 32; bdrkreg_t sdc_vector_b : 8; bdrkreg_t sdc_reserved : 1; bdrkreg_t sdc_locprot : 1; bdrkreg_t sdc_ecc : 6; bdrkreg_t sdc_vector_a : 8; bdrkreg_t sdc_reserved_1 : 6; bdrkreg_t sdc_format : 2; }; #endif typedef union md_sdir { /* The 32 bits of standard directory, in bits 31:0 */ uint64_t sd_val; struct md_sdir_pointer_fmt sdp_fmt; struct md_sdir_fine_fmt sdf_fmt; struct md_sdir_coarse_fmt sdc_fmt; } md_sdir_t; /* Premium Directory Entries */ #ifdef LITTLE_ENDIAN struct md_pdir_pointer_fmt { /* exclusive, busy shared/excl, wait, poisoned */ bdrkreg_t pdp_format : 2; bdrkreg_t pdp_state : 3; bdrkreg_t pdp_priority : 3; bdrkreg_t pdp_pointer1_a : 8; bdrkreg_t pdp_reserved_4 : 6; bdrkreg_t pdp_pointer1_b : 3; bdrkreg_t pdp_reserved_3 : 7; bdrkreg_t pdp_ecc_a : 6; bdrkreg_t pdp_locprot : 1; bdrkreg_t pdp_reserved_2 : 1; bdrkreg_t pdp_crit_word_off : 3; bdrkreg_t pdp_pointer2_a : 5; bdrkreg_t pdp_ecc_b : 1; bdrkreg_t pdp_reserved_1 : 5; bdrkreg_t pdp_pointer2_b : 3; bdrkreg_t pdp_reserved : 7; }; #else struct md_pdir_pointer_fmt { /* exclusive, busy shared/excl, wait, poisoned */ bdrkreg_t pdp_reserved : 7; bdrkreg_t pdp_pointer2_b : 3; bdrkreg_t pdp_reserved_1 : 5; bdrkreg_t pdp_ecc_b : 1; bdrkreg_t pdp_pointer2_a : 5; bdrkreg_t pdp_crit_word_off : 3; bdrkreg_t pdp_reserved_2 : 1; bdrkreg_t pdp_locprot : 1; bdrkreg_t pdp_ecc_a : 6; bdrkreg_t pdp_reserved_3 : 7; bdrkreg_t pdp_pointer1_b : 3; bdrkreg_t pdp_reserved_4 : 6; bdrkreg_t pdp_pointer1_a : 8; bdrkreg_t pdp_priority : 3; bdrkreg_t pdp_state : 3; bdrkreg_t pdp_format : 2; }; #endif #ifdef LITTLE_ENDIAN struct md_pdir_fine_fmt { /* shared (fine) */ bdrkreg_t pdf_format : 2; bdrkreg_t pdf_tag1_a : 3; bdrkreg_t pdf_tag2_a : 3; bdrkreg_t pdf_vector1_a : 8; bdrkreg_t pdf_reserved_1 : 6; bdrkreg_t pdf_tag1_b : 2; bdrkreg_t pdf_vector1_b : 8; bdrkreg_t pdf_ecc_a : 6; bdrkreg_t pdf_locprot : 1; bdrkreg_t pdf_tag2valid : 1; bdrkreg_t pdf_vector2_a : 8; bdrkreg_t pdf_ecc_b : 1; bdrkreg_t pdf_reserved : 5; bdrkreg_t pdf_tag2_b : 2; bdrkreg_t pdf_vector2_b : 8; }; #else struct md_pdir_fine_fmt { /* shared (fine) */ bdrkreg_t pdf_vector2_b : 8; bdrkreg_t pdf_tag2_b : 2; bdrkreg_t pdf_reserved : 5; bdrkreg_t pdf_ecc_b : 1; bdrkreg_t pdf_vector2_a : 8; bdrkreg_t pdf_tag2valid : 1; bdrkreg_t pdf_locprot : 1; bdrkreg_t pdf_ecc_a : 6; bdrkreg_t pdf_vector1_b : 8; bdrkreg_t pdf_tag1_b : 2; bdrkreg_t pdf_reserved_1 : 6; bdrkreg_t pdf_vector1_a : 8; bdrkreg_t pdf_tag2_a : 3; bdrkreg_t pdf_tag1_a : 3; bdrkreg_t pdf_format : 2; }; #endif #ifdef LITTLE_ENDIAN struct md_pdir_sparse_fmt { /* shared (sparse) */ bdrkreg_t pds_format : 2; bdrkreg_t pds_column_a : 6; bdrkreg_t pds_row_a : 8; bdrkreg_t pds_column_b : 16; bdrkreg_t pds_ecc_a : 6; bdrkreg_t pds_locprot : 1; bdrkreg_t pds_reserved_1 : 1; bdrkreg_t pds_row_b : 8; bdrkreg_t pds_ecc_b : 1; bdrkreg_t pds_column_c : 10; bdrkreg_t pds_reserved : 5; }; #else struct md_pdir_sparse_fmt { /* shared (sparse) */ bdrkreg_t pds_reserved : 5; bdrkreg_t pds_column_c : 10; bdrkreg_t pds_ecc_b : 1; bdrkreg_t pds_row_b : 8; bdrkreg_t pds_reserved_1 : 1; bdrkreg_t pds_locprot : 1; bdrkreg_t pds_ecc_a : 6; bdrkreg_t pds_column_b : 16; bdrkreg_t pds_row_a : 8; bdrkreg_t pds_column_a : 6; bdrkreg_t pds_format : 2; }; #endif typedef union md_pdir { /* The 64 bits of premium directory */ uint64_t pd_val; struct md_pdir_pointer_fmt pdp_fmt; struct md_pdir_fine_fmt pdf_fmt; struct md_pdir_sparse_fmt pds_fmt; } md_pdir_t; #endif /* _LANGUAGE_C */ /********************************************************************** The defines for backdoor directory and backdoor ECC. ***********************************************************************/ /* Directory formats, for each format's "format" field */ #define MD_FORMAT_UNOWNED (UINT64_CAST 0x0) /* 00 */ #define MD_FORMAT_POINTER (UINT64_CAST 0x1) /* 01 */ #define MD_FORMAT_SHFINE (UINT64_CAST 0x2) /* 10 */ #define MD_FORMAT_SHCOARSE (UINT64_CAST 0x3) /* 11 */ /* Shared coarse (standard) and shared sparse (premium) both use fmt 0x3 */ /* * Cacheline state values. * * These are really *software* notions of the "state" of a cacheline; but the * actual values have been carefully chosen to align with some hardware values! * The MD_FMT_ST_TO_STATE macro is used to convert from hardware format/state * pairs in the directory entried into one of these cacheline state values. */ #define MD_DIR_EXCLUSIVE (UINT64_CAST 0x0) /* ptr format, hw-defined */ #define MD_DIR_UNOWNED (UINT64_CAST 0x1) /* format=0 */ #define MD_DIR_SHARED (UINT64_CAST 0x2) /* format=2,3 */ #define MD_DIR_BUSY_SHARED (UINT64_CAST 0x4) /* ptr format, hw-defined */ #define MD_DIR_BUSY_EXCL (UINT64_CAST 0x5) /* ptr format, hw-defined */ #define MD_DIR_WAIT (UINT64_CAST 0x6) /* ptr format, hw-defined */ #define MD_DIR_POISONED (UINT64_CAST 0x7) /* ptr format, hw-defined */ #ifdef _LANGUAGE_C /* Convert format and state fields into a single "cacheline state" value, defined above */ #define MD_FMT_ST_TO_STATE(fmt, state) \ ((fmt) == MD_FORMAT_POINTER ? (state) : \ (fmt) == MD_FORMAT_UNOWNED ? MD_DIR_UNOWNED : \ MD_DIR_SHARED) #define MD_DIR_STATE(x) MD_FMT_ST_TO_STATE(MD_DIR_FORMAT(x), MD_DIR_STVAL(x)) #endif /* _LANGUAGE_C */ /* Directory field shifts and masks */ /* Standard */ #define MD_SDIR_FORMAT_SHFT 0 /* All formats */ #define MD_SDIR_FORMAT_MASK (0x3 << 0) #define MD_SDIR_STATE_SHFT 2 /* Pointer fmt. only */ #define MD_SDIR_STATE_MASK (0x7 << 2) /* Premium */ #define MD_PDIR_FORMAT_SHFT 0 /* All formats */ #define MD_PDIR_FORMAT_MASK (0x3 << 0) #define MD_PDIR_STATE_SHFT 2 /* Pointer fmt. only */ #define MD_PDIR_STATE_MASK (0x7 << 2) /* Generic */ #define MD_FORMAT_SHFT 0 /* All formats */ #define MD_FORMAT_MASK (0x3 << 0) #define MD_STATE_SHFT 2 /* Pointer fmt. only */ #define MD_STATE_MASK (0x7 << 2) /* Special shifts to reconstruct fields from the _a and _b parts */ /* Standard: only shared coarse has split fields */ #define MD_SDC_VECTORB_SHFT 8 /* eg: sdc_vector_a is 8 bits */ /* Premium: pointer, shared fine, shared sparse */ #define MD_PDP_POINTER1A_MASK 0xFF #define MD_PDP_POINTER1B_SHFT 8 #define MD_PDP_POINTER2B_SHFT 5 #define MD_PDP_ECCB_SHFT 6 #define MD_PDF_VECTOR1B_SHFT 8 #define MD_PDF_VECTOR2B_SHFT 8 #define MD_PDF_TAG1B_SHFT 3 #define MD_PDF_TAG2B_SHFT 3 #define MD_PDF_ECC_SHFT 6 #define MD_PDS_ROWB_SHFT 8 #define MD_PDS_COLUMNB_SHFT 6 #define MD_PDS_COLUMNC_SHFT (MD_PDS_COLUMNB_SHFT + 16) #define MD_PDS_ECC_SHFT 6 /* * Directory/protection/counter initialization values, premium and standard */ #define MD_PDIR_INIT 0 #define MD_PDIR_INIT_CNT 0 #define MD_PDIR_INIT_PROT 0 #define MD_SDIR_INIT 0 #define MD_SDIR_INIT_CNT 0 #define MD_SDIR_INIT_PROT 0 #define MD_PDIR_MASK 0xffffffffffffffff #define MD_SDIR_MASK 0xffffffff /* When premium mode is on for probing but standard directory memory is installed, the valid directory bits depend on the phys. bank */ #define MD_PDIR_PROBE_MASK(pb) 0xffffffffffffffff #define MD_SDIR_PROBE_MASK(pb) (0xffff0000ffff << ((pb) ? 16 : 0)) /* * Misc. field extractions and conversions */ /* Convert an MD pointer (or message source, supplemental fields) */ #define MD_PTR_NODE(x) ((x) >> MD_PTR_NODE_SHFT) #define MD_PTR_DEVICE(x) ((x) & MD_PTR_DEVICE_MASK) #define MD_PTR_SLICE(x) (((x) & MD_PTR_SUBNODE0_MASK) | \ ((x) & MD_PTR_SUBNODE1_MASK) >> 1) #define MD_PTR_OWNER_CPU(x) (! ((x) & 2)) #define MD_PTR_OWNER_IO(x) ((x) & 2) /* Extract format and raw state from a directory entry */ #define MD_DIR_FORMAT(x) ((x) >> MD_SDIR_FORMAT_SHFT & \ MD_SDIR_FORMAT_MASK >> MD_SDIR_FORMAT_SHFT) #define MD_DIR_STVAL(x) ((x) >> MD_SDIR_STATE_SHFT & \ MD_SDIR_STATE_MASK >> MD_SDIR_STATE_SHFT) /* Mask & Shift to get HSPEC_ADDR from MD DIR_ERROR register */ #define ERROR_ADDR_SHFT 3 #define ERROR_HSPEC_SHFT 3 #define DIR_ERR_HSPEC_MASK 0x1fffffff8 /* * DIR_ERR* and MEM_ERR* defines are used to avoid ugly * #ifdefs for SN0 and SN1 in memerror.c code. See SN0/hubmd.h * for corresponding SN0 definitions. */ #define md_dir_error_t md_dir_error_u_t #define md_mem_error_t md_mem_error_u_t #define derr_reg md_dir_error_regval #define merr_reg md_mem_error_regval #define DIR_ERR_UCE_VALID dir_err.md_dir_error_fld_s.de_uce_valid #define DIR_ERR_AE_VALID dir_err.md_dir_error_fld_s.de_ae_valid #define DIR_ERR_BAD_SYN dir_err.md_dir_error_fld_s.de_bad_syn #define DIR_ERR_CE_OVERRUN dir_err.md_dir_error_fld_s.de_ce_overrun #define MEM_ERR_ADDRESS mem_err.md_mem_error_fld_s.me_address /* BRINGUP Can the overrun bit be set without the valid bit? */ #define MEM_ERR_CE_OVERRUN (mem_err.md_mem_error_fld_s.me_read_ce >> 1) #define MEM_ERR_BAD_SYN mem_err.md_mem_error_fld_s.me_bad_syn #define MEM_ERR_UCE_VALID (mem_err.md_mem_error_fld_s.me_read_uce & 1) /********************************************************************* We have the shift and masks of various fields defined below. *********************************************************************/ /* MD_REFRESH_CONTROL fields */ #define MRC_ENABLE_SHFT 63 #define MRC_ENABLE_MASK (UINT64_CAST 1 << 63) #define MRC_ENABLE (UINT64_CAST 1 << 63) #define MRC_COUNTER_SHFT 12 #define MRC_COUNTER_MASK (UINT64_CAST 0xfff << 12) #define MRC_CNT_THRESH_MASK 0xfff #define MRC_RESET_DEFAULTS (UINT64_CAST 0x800) /* MD_DIR_CONFIG fields */ #define MDC_DIR_PREMIUM (UINT64_CAST 1 << 0) #define MDC_IGNORE_ECC_SHFT 1 #define MDC_IGNORE_ECC_MASK (UINT64_CAST 1 << 1) /* MD_MEMORY_CONFIG fields */ #define MMC_RP_CONFIG_SHFT 61 #define MMC_RP_CONFIG_MASK (UINT64_CAST 1 << 61) #define MMC_RCD_CONFIG_SHFT 60 #define MMC_RCD_CONFIG_MASK (UINT64_CAST 1 << 60) #define MMC_MB_NEG_EDGE_SHFT 56 #define MMC_MB_NEG_EDGE_MASK (UINT64_CAST 0x7 << 56) #define MMC_SAMPLE_TIME_SHFT 52 #define MMC_SAMPLE_TIME_MASK (UINT64_CAST 0x3 << 52) #define MMC_DELAY_MUX_SEL_SHFT 50 #define MMC_DELAY_MUX_SEL_MASK (UINT64_CAST 0x3 << 50) #define MMC_PHASE_DELAY_SHFT 49 #define MMC_PHASE_DELAY_MASK (UINT64_CAST 1 << 49) #define MMC_DB_NEG_EDGE_SHFT 48 #define MMC_DB_NEG_EDGE_MASK (UINT64_CAST 1 << 48) #define MMC_CPU_PROT_IGNORE_SHFT 47 #define MMC_CPU_PROT_IGNORE_MASK (UINT64_CAST 1 << 47) #define MMC_IO_PROT_IGNORE_SHFT 46 #define MMC_IO_PROT_IGNORE_MASK (UINT64_CAST 1 << 46) #define MMC_IO_PROT_EN_SHFT 45 #define MMC_IO_PROT_EN_MASK (UINT64_CAST 1 << 45) #define MMC_CC_ENABLE_SHFT 44 #define MMC_CC_ENABLE_MASK (UINT64_CAST 1 << 44) #define MMC_DIMM0_SEL_SHFT 32 #define MMC_DIMM0_SEL_MASK (UINT64_CAST 0x3 << 32) #define MMC_DIMM_SIZE_SHFT(_dimm) ((_dimm << 3) + 4) #define MMC_DIMM_SIZE_MASK(_dimm) (UINT64_CAST 0xf << MMC_DIMM_SIZE_SHFT(_dimm)) #define MMC_DIMM_WIDTH_SHFT(_dimm) ((_dimm << 3) + 3) #define MMC_DIMM_WIDTH_MASK(_dimm) (UINT64_CAST 0x1 << MMC_DIMM_WIDTH_SHFT(_dimm)) #define MMC_DIMM_BANKS_SHFT(_dimm) (_dimm << 3) #define MMC_DIMM_BANKS_MASK(_dimm) (UINT64_CAST 0x3 << MMC_DIMM_BANKS_SHFT(_dimm)) #define MMC_BANK_ALL_MASK 0xffffffffLL /* Default values for write-only bits in MD_MEMORY_CONFIG */ #define MMC_DEFAULT_BITS (UINT64_CAST 0x7 << MMC_MB_NEG_EDGE_SHFT) /* MD_MB_ECC_CONFIG fields */ #define MEC_IGNORE_ECC (UINT64_CAST 0x1 << 0) /* MD_BIST_DATA fields */ #define MBD_BIST_WRITE (UINT64_CAST 1 << 7) #define MBD_BIST_CYCLE (UINT64_CAST 1 << 6) #define MBD_BIST_BYTE (UINT64_CAST 1 << 5) #define MBD_BIST_NIBBLE (UINT64_CAST 1 << 4) #define MBD_BIST_DATA_MASK 0xf /* MD_BIST_CTL fields */ #define MBC_DIMM_SHFT 5 #define MBC_DIMM_MASK (UINT64_CAST 0x3 << 5) #define MBC_BANK_SHFT 4 #define MBC_BANK_MASK (UINT64_CAST 0x1 << 4) #define MBC_BIST_RESET (UINT64_CAST 0x1 << 2) #define MBC_BIST_STOP (UINT64_CAST 0x1 << 1) #define MBC_BIST_START (UINT64_CAST 0x1 << 0) #define MBC_GO(dimm, bank) \ (((dimm) << MBC_DIMM_SHFT) & MBC_DIMM_MASK | \ ((bank) << MBC_BANK_SHFT) & MBC_BANK_MASK | \ MBC_BIST_START) /* MD_BIST_STATUS fields */ #define MBS_BIST_DONE (UINT64_CAST 0X1 << 1) #define MBS_BIST_PASSED (UINT64_CAST 0X1 << 0) /* MD_JUNK_BUS_TIMING fields */ #define MJT_SYNERGY_ENABLE_SHFT 40 #define MJT_SYNERGY_ENABLE_MASK (UINT64_CAST 0Xff << MJT_SYNERGY_ENABLE_SHFT) #define MJT_SYNERGY_SETUP_SHFT 32 #define MJT_SYNERGY_SETUP_MASK (UINT64_CAST 0Xff << MJT_SYNERGY_SETUP_SHFT) #define MJT_UART_ENABLE_SHFT 24 #define MJT_UART_ENABLE_MASK (UINT64_CAST 0Xff << MJT_UART_ENABLE_SHFT) #define MJT_UART_SETUP_SHFT 16 #define MJT_UART_SETUP_MASK (UINT64_CAST 0Xff << MJT_UART_SETUP_SHFT) #define MJT_FPROM_ENABLE_SHFT 8 #define MJT_FPROM_ENABLE_MASK (UINT64_CAST 0Xff << MJT_FPROM_ENABLE_SHFT) #define MJT_FPROM_SETUP_SHFT 0 #define MJT_FPROM_SETUP_MASK (UINT64_CAST 0Xff << MJT_FPROM_SETUP_SHFT) #define MEM_ERROR_VALID_CE 1 /* MD_FANDOP_CAC_STAT0, MD_FANDOP_CAC_STAT1 addr field shift */ #define MFC_ADDR_SHFT 6 #endif /* _ASM_SN_SN1_HUBMD_NEXT_H */