/* * CDDL HEADER START * * The contents of this file are subject to the terms of the * Common Development and Distribution License (the "License"). * You may not use this file except in compliance with the License. * * You can obtain a copy of the license at usr/src/OPENSOLARIS.LICENSE * or http://www.opensolaris.org/os/licensing. * See the License for the specific language governing permissions * and limitations under the License. * * When distributing Covered Code, include this CDDL HEADER in each * file and include the License file at usr/src/OPENSOLARIS.LICENSE. * If applicable, add the following below this CDDL HEADER, with the * fields enclosed by brackets "[]" replaced with your own identifying * information: Portions Copyright [yyyy] [name of copyright owner] * * CDDL HEADER END * * Copyright 2006 Sun Microsystems, Inc. All rights reserved. * Use is subject to license terms. */ #pragma ident "%Z%%M% %I% %E% SMI" /* * Given a physical address and an optional syndrome, determine the * name of the memory module that contains it. */ #include #include #include #include #include #define MC_SYSADDR_MSB 39 #define MC_SYSADDR_LSB 3 #define CSDIMM1 0x1 #define CSDIMM2 0x2 #define BITS(val, high, low) \ ((val) & (((2ULL << (high)) - 1) & ~((1ULL << (low)) - 1))) /* * iaddr_gen generates a "normalized" DRAM controller input address * from a system address (physical address) if it falls within the * mapped range for this memory controller. Normalisation is * performed by subtracting the node base address from the system address, * allowing from hoisting, and excising any bits being used in node * interleaving. */ static int iaddr_gen(struct mcamd_hdl *hdl, mcamd_node_t *mc, uint64_t pa, uint64_t *iaddrp) { uint64_t orig = pa; uint64_t mcnum, base, lim, dramaddr, ilen, ilsel, top, holesz; if (!mcamd_get_numprops(hdl, mc, MCAMD_PROP_NUM, &mcnum, mc, MCAMD_PROP_BASE_ADDR, &base, mc, MCAMD_PROP_LIM_ADDR, &lim, mc, MCAMD_PROP_ILEN, &ilen, mc, MCAMD_PROP_ILSEL, &ilsel, mc, MCAMD_PROP_DRAMHOLE_SIZE, &holesz, NULL)) { mcamd_dprintf(hdl, MCAMD_DBG_ERR, "iaddr_gen: failed to " "lookup required properties"); return (mcamd_set_errno(hdl, EMCAMD_TREEINVALID)); } /* * A node with no mapped memory (no active chip-selects is usually * mapped with base and lim both zero. We'll cover that case and * any other where the range is 0. */ if (base == lim) return (mcamd_set_errno(hdl, EMCAMD_NOADDR)); if (pa < base || pa > lim) { mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "iaddr_gen: PA 0x%llx not " "in range [0x%llx, 0x%llx] of MC %d\n", pa, base, lim, (int)mcnum); return (mcamd_set_errno(hdl, EMCAMD_NOADDR)); } /* * Rev E and later added the DRAM Hole Address Register for * memory hoisting. In earlier revisions memory hoisting is * achieved by following some algorithm to modify the CS bases etc, * and this pa to unum algorithm will simply see those modified * values. But if the Hole Address Register is being used then * we need to reduce any address at or above 4GB by the size of * the hole. */ if (holesz != 0 && pa >= 0x100000000) { pa -= holesz; mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "iaddr_gen: dram hole " "valid; pa decremented from 0x%llx to 0x%llx for " "a dramhole size of 0x%llx\n", orig, pa, holesz); } dramaddr = BITS(pa, 39, 0) - BITS(base, 39, 24); if (ilen != 0) { int pailsel; if (ilen != 1 && ilen != 3 && ilen != 7) { mcamd_dprintf(hdl, MCAMD_DBG_ERR, "Invalid intlven " "of %d for MC %d\n", (int)ilen, (int)mcnum); return (mcamd_set_errno(hdl, EMCAMD_TREEINVALID)); } if ((pailsel = BITS(pa, 14, 12) >> 12 & ilen) != ilsel) { mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "iaddr_gen: " "PA 0x%llx in a %d-way node interleave indicates " "selection %d, MC %d has ilsel of %d\n", pa, (int)ilen + 1, pailsel, (int)mcnum, (int)ilsel); return (mcamd_set_errno(hdl, EMCAMD_NOADDR)); } if (ilen == 1) top = BITS(dramaddr, 36, 13) >> 1; else if (ilen == 3) top = BITS(dramaddr, 37, 14) >> 2; else if (ilen == 7) top = BITS(dramaddr, 38, 15) >> 3; } else { top = BITS(dramaddr, 35, 12); } *iaddrp = top | BITS(dramaddr, 11, 0); mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "iaddr_gen: PA 0x%llx in range " "[0x%llx, 0x%llx] of MC %d; normalized address for cs compare " "is 0x%llx\n", pa, base, lim, (int)mcnum, *iaddrp); return (0); } /* * cs_match determines whether the given DRAM controller input address * would be responded to by the given chip-select (which may or may not * be interleaved with other chip-selects). Since we include nodes * for spare chip-selects (if any) and those marked TestFail (if any) * we must check chip-select-bank-enable. */ static int cs_match(struct mcamd_hdl *hdl, uint64_t iaddr, mcamd_node_t *cs) { uint64_t csnum, csbase, csmask, csbe; int match = 0; if (!mcamd_get_numprops(hdl, cs, MCAMD_PROP_NUM, &csnum, cs, MCAMD_PROP_BASE_ADDR, &csbase, cs, MCAMD_PROP_MASK, &csmask, cs, MCAMD_PROP_CSBE, &csbe, NULL)) { mcamd_dprintf(hdl, MCAMD_DBG_ERR, "cs_match: failed to lookup " "required properties\n"); return (0); } if (csbe) { match = ((iaddr & ~csmask) == (csbase & ~csmask)); mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "cs_match: iaddr 0x%llx " "does %smatch CS %d (base 0x%llx, mask 0x%llx)\n", iaddr, match ? "" : "not ", (int)csnum, csbase, csmask); } else { mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "cs_match: iaddr 0x%llx " "does not match disabled CS %d\n", iaddr, (int)csnum); } return (match); } /* * Given a chip-select node determine whether it has been substituted * by the online spare chip-select. */ static mcamd_node_t * cs_sparedto(struct mcamd_hdl *hdl, mcamd_node_t *cs, mcamd_node_t *mc) { uint64_t csnum, badcsnum, sparecsnum, tmpcsnum; if (!mcamd_get_numprops(hdl, cs, MCAMD_PROP_NUM, &csnum, mc, MCAMD_PROP_BADCS, &badcsnum, mc, MCAMD_PROP_SPARECS, &sparecsnum, NULL)) { mcamd_dprintf(hdl, MCAMD_DBG_ERR, "cs_sparedto: failed to " "lookup required properties\n"); return (NULL); } if ((badcsnum == MC_INVALNUM && sparecsnum == MC_INVALNUM) || csnum != badcsnum) return (NULL); for (cs = mcamd_cs_next(hdl, mc, NULL); cs != NULL; cs = mcamd_cs_next(hdl, mc, cs)) { if (!mcamd_get_numprop(hdl, cs, MCAMD_PROP_NUM, &tmpcsnum)) { mcamd_dprintf(hdl, MCAMD_DBG_ERR, "cs_sparedto: " "fail to lookup csnum - cannot reroute to spare\n"); return (NULL); } if (tmpcsnum == sparecsnum) break; } if (cs != NULL) { mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "cs_sparedto: cs#%d is " "redirected to active online spare of cs#%d\n", csnum, sparecsnum); } else { mcamd_dprintf(hdl, MCAMD_DBG_ERR, "cs_sparedto: cs#%d is " "redirected but cannot find spare cs# - cannout reroute to " "cs#%d\n", csnum, sparecsnum); } return (cs); } /* * Having determined which node and chip-select an address maps to, * as well as whether it is a dimm1, dimm2 or dimm1/dimm2 pair * involved, fill the unum structure including an optional dimm offset * member. */ static int unum_fill(struct mcamd_hdl *hdl, mcamd_node_t *cs, int which, uint64_t iaddr, mc_unum_t *unump, int incloff) { uint64_t chipnum, csnum, dimm1, dimm2, ranknum; mcamd_node_t *mc, *dimm; int offsetdimm; int i; if ((mc = mcamd_cs_mc(hdl, cs)) == NULL || !mcamd_get_numprops(hdl, mc, MCAMD_PROP_NUM, &chipnum, cs, MCAMD_PROP_NUM, &csnum, cs, MCAMD_PROP_DIMMRANK, &ranknum, NULL)) { mcamd_dprintf(hdl, MCAMD_DBG_ERR, "unum_fill: failed to " "lookup required properties\n"); return (mcamd_set_errno(hdl, EMCAMD_TREEINVALID)); } if ((which & CSDIMM1) && !mcamd_get_numprop(hdl, cs, MCAMD_PROP_CSDIMM1, &dimm1) || (which & CSDIMM2) && !mcamd_get_numprop(hdl, cs, MCAMD_PROP_CSDIMM2, &dimm2)) { mcamd_dprintf(hdl, MCAMD_DBG_ERR, "unum_fill: failed to " "lookup dimm1/dimm2 properties\n"); return (mcamd_set_errno(hdl, EMCAMD_TREEINVALID)); } unump->unum_board = 0; unump->unum_chip = chipnum; unump->unum_mc = 0; unump->unum_cs = csnum; unump->unum_rank = ranknum; for (i = 0; i < MC_UNUM_NDIMM; i++) { unump->unum_dimms[i] = MC_INVALNUM; } switch (which) { case CSDIMM1: unump->unum_dimms[0] = dimm1; offsetdimm = dimm1; break; case CSDIMM2: unump->unum_dimms[0] = dimm2; offsetdimm = dimm2; break; case CSDIMM1 | CSDIMM2: unump->unum_dimms[0] = dimm1; unump->unum_dimms[1] = dimm2; offsetdimm = dimm1; break; } if (!incloff) { unump->unum_offset = MCAMD_RC_INVALID_OFFSET; return (0); } /* * We wish to calculate a dimm offset. In the paired case we will * lookup dimm1 (see offsetdimm above). */ for (dimm = mcamd_dimm_next(hdl, mc, NULL); dimm != NULL; dimm = mcamd_dimm_next(hdl, mc, dimm)) { uint64_t dnum; if (!mcamd_get_numprop(hdl, dimm, MCAMD_PROP_NUM, &dnum)) { mcamd_dprintf(hdl, MCAMD_DBG_ERR, "unum_fill: failed " "to lookup dimm number property\n"); continue; } if (dnum == offsetdimm) break; } if (dimm == NULL) { mcamd_dprintf(hdl, MCAMD_DBG_ERR, "unum_fill: failed to " "find dimm with number %d for offset calculation\n", offsetdimm); unump->unum_offset = MCAMD_RC_INVALID_OFFSET; return (mcamd_set_errno(hdl, EMCAMD_TREEINVALID)); } /* * mc_pa_to_offset sets the offset to an invalid value if * it hits an error. */ (void) mc_pa_to_offset(hdl, mc, cs, iaddr, &unump->unum_offset); return (0); } /* * We have translated a system address to a (node, chip-select), and wish * to determine the associated dimm or dimms. * * A (node, chip-select) pair identifies one (in 64-bit MC mode) or two (in * 128-bit MC mode) DIMMs. In the case of a single dimm it is usually in a * lodimm (channel A) slot, but if mismatched dimm support is present it may * be an updimm (channel B). * * Where just one dimm is associated with the chip-select we are done. * Where there are two dimms associated with the chip-select we can * use the ECC type and/or syndrome to determine which of the pair we * resolve to, if the error is correctable. If the error is uncorrectable * then in 64/8 ECC mode we can still resolve to a single dimm (since ECC * is calculated and checked on each half of the data separately), but * in ChipKill mode we cannot resolve down to a single dimm. */ static int mc_whichdimm(struct mcamd_hdl *hdl, mcamd_node_t *cs, uint64_t pa, uint8_t valid_lo, uint32_t synd, int syndtype) { int lobit, hibit, data, check; uint64_t dimm1, dimm2; uint_t sym, pat; int ndimm; /* * Read the associated dimm instance numbers. The provider must * assure that if there is just one dimm then it is in the first * property, and if there are two then the first must be on * channel A. */ if (!mcamd_get_numprops(hdl, cs, MCAMD_PROP_CSDIMM1, &dimm1, cs, MCAMD_PROP_CSDIMM2, &dimm2, NULL)) { mcamd_dprintf(hdl, MCAMD_DBG_ERR, "mc_whichdimm: failed to " "lookup required properties"); return (mcamd_set_errno(hdl, EMCAMD_TREEINVALID)); } ndimm = (dimm1 != MC_INVALNUM) + (dimm2 != MC_INVALNUM); if (ndimm == 0) { mcamd_dprintf(hdl, MCAMD_DBG_ERR, "mc_whichdimm: found no " "dimms associated with chip-select"); return (mcamd_set_errno(hdl, EMCAMD_TREEINVALID)); } if (ndimm == 1) { mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "mc_whichdimm: just one " "dimm associated with this chip-select"); return (CSDIMM1); } /* * 64/8 ECC is checked separately for the upper and lower * halves, so even an uncorrectable error is contained within * one of the two halves. If we have sufficient address resolution * then we can determine which DIMM. */ if (syndtype == AMD_SYNDTYPE_ECC) { if (valid_lo <= MC_SYSADDR_LSB) { mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "mc_whichdimm: 64/8 " "ECC in 128-bit mode, PA 0x%llx is in %s half\n", pa, pa & 0x8 ? "upper" : "lower"); return (pa & 0x8 ? CSDIMM2 : CSDIMM1); } else { mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "mc_whichdimm: " "64/8 ECC in 128-bit mode, PA 0x%llx with least " "significant valid bit %d cannot be resolved to " "a single DIMM\n", pa, valid_lo); return (mcamd_set_errno(hdl, EMCAMD_INSUFF_RES)); } } /* * ChipKill ECC */ if (mcamd_cksynd_decode(hdl, synd, &sym, &pat)) { /* * A correctable ChipKill syndrome and we can tell * which half the error was in from the symbol number. */ if (mcamd_cksym_decode(hdl, sym, &lobit, &hibit, &data, &check) == 0) return (mcamd_set_errno(hdl, EMCAMD_SYNDINVALID)); if (data && hibit <= 63 || check && hibit <= 7) { mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "mc_whichdimm: " "ChipKill symbol %d (%s %d..%d), so LODIMM\n", sym, data ? "data" : "check", lobit, hibit); return (CSDIMM1); } else { mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "mc_whichdimm: " "ChipKill symbol %d (%s %d..%d), so UPDIMM\n", sym, data ? "data" : "check", lobit, hibit); return (CSDIMM2); } } else { /* * An uncorrectable error while in ChipKill ECC mode - can't * tell which dimm or dimms the errors lie within. */ mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "mc_whichhdimm: " "uncorrectable ChipKill, could be either LODIMM " "or UPDIMM\n"); return (CSDIMM1 | CSDIMM2); } } /* * Brute-force BKDG pa to cs translation, coded to look as much like the * BKDG code as possible. */ static int mc_bkdg_patounum(struct mcamd_hdl *hdl, mcamd_node_t *mc, uint64_t pa, uint8_t valid_lo, uint32_t synd, int syndtype, mc_unum_t *unump) { int which; uint64_t mcnum, rev; mcamd_node_t *cs; /* * Raw registers as per BKDG */ uint32_t HoleEn; uint32_t DramBase, DramLimit; uint32_t CSBase, CSMask; /* * Variables as per BKDG */ int Ilog; uint32_t SystemAddr = (uint32_t)(pa >> 8); uint64_t IntlvEn, IntlvSel; uint32_t HoleOffset; uint32_t InputAddr, Temp; if (!mcamd_get_numprops(hdl, mc, MCAMD_PROP_NUM, &mcnum, mc, MCAMD_PROP_REV, &rev, NULL) || !mcamd_get_cfgregs(hdl, mc, MCAMD_REG_DRAMBASE, &DramBase, mc, MCAMD_REG_DRAMLIMIT, &DramLimit, mc, MCAMD_REG_DRAMHOLE, &HoleEn, NULL)) { mcamd_dprintf(hdl, MCAMD_DBG_ERR, "mc_bkdg_patounm: failed " "to lookup required properties and registers\n"); return (mcamd_set_errno(hdl, EMCAMD_TREEINVALID)); } /* * BKDG line to skip Why * * F1Offset = ... Register already read, * DramBase = Get_PCI() and retrieved above. * DramEn = ... Function only called for enabled nodes. */ IntlvEn = (DramBase & 0x00000700) >> 8; DramBase &= 0xffff0000; /* DramLimit = Get_PCI() Retrieved above */ IntlvSel = (DramLimit & 0x00000700) >> 8; DramLimit |= 0x0000ffff; /* HoleEn = ... Retrieved above */ HoleOffset = (HoleEn & 0x0000ff00) << 8; HoleEn &= 0x00000001; if (!(DramBase <= SystemAddr && SystemAddr <= DramLimit)) { mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "mc_bkdg_patounum: " "SystemAddr 0x%x derived from PA 0x%llx is not in the " "address range [0x%x, 0x%x] of MC %d\n", SystemAddr, pa, DramBase, DramLimit, (int)mcnum); return (mcamd_set_errno(hdl, EMCAMD_NOADDR)); } if (HoleEn && SystemAddr > 0x00ffffff) InputAddr = SystemAddr - HoleOffset; InputAddr = SystemAddr - DramBase; if (IntlvEn) { if (IntlvSel == ((SystemAddr >> 4) & IntlvEn)) { switch (IntlvEn) { case 1: Ilog = 1; break; case 3: Ilog = 2; break; case 7: Ilog = 3; break; default: return (mcamd_set_errno(hdl, EMCAMD_TREEINVALID)); } Temp = (InputAddr >> (4 + Ilog)) << 4; InputAddr = (Temp | (SystemAddr & 0x0000000f)); } else { /* not this node */ mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "mc_bkdg_patounum: " "Node interleaving, MC node %d not selected\n", (int)mcnum); return (mcamd_set_errno(hdl, EMCAMD_NOADDR)); } } if (!MC_REV_MATCH(rev, MC_REVS_FG)) InputAddr <<= 4; for (cs = mcamd_cs_next(hdl, mc, NULL); cs != NULL; cs = mcamd_cs_next(hdl, mc, cs)) { uint64_t csnum, CSEn; if (!mcamd_get_cfgregs(hdl, cs, MCAMD_REG_CSBASE, &CSBase, cs, MCAMD_REG_CSMASK, &CSMask, NULL) || !mcamd_get_numprops(hdl, cs, MCAMD_PROP_NUM, &csnum, cs, MCAMD_PROP_CSBE, &CSEn, NULL)) { mcamd_dprintf(hdl, MCAMD_DBG_ERR, "mc_bkdg_patounm: " "failed to read cs registers\n"); return (mcamd_set_errno(hdl, EMCAMD_TREEINVALID)); } /* * BKDG line to skip Why * * F2Offset = Register already read, * F2MaskOffset (rev F) Register already read * CSBase = Register already read * CSEn = We only keep enabled cs. */ if (MC_REV_MATCH(rev, MC_REVS_FG)) { CSBase &= 0x1ff83fe0; /* CSMask = Get_PCI() Retrieved above */ CSMask = (CSMask | 0x0007c01f) & 0x1fffffff; } else { CSBase &= 0xffe0fe00; /* CSMask = Get_PCI() Retrieved above */ CSMask = (CSMask | 0x001f01ff) & 0x3fffffff; } if (CSEn && (InputAddr & ~CSMask) == (CSBase & ~CSMask)) { mcamd_node_t *sparecs; mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "mc_bkdg_patounum: " "match for chip select %d of MC %d\n", (int)csnum, (int)mcnum); if ((sparecs = cs_sparedto(hdl, cs, mc)) != NULL) cs = sparecs; if ((which = mc_whichdimm(hdl, cs, pa, valid_lo, synd, syndtype)) < 0) return (-1); /* errno is set for us */ /* * The BKDG algorithm drops low-order bits that * are unimportant in deriving chip-select but are * included in row/col/bank mapping, so do not * perform offset calculation in this case. */ if (unum_fill(hdl, cs, which, InputAddr, unump, 0) < 0) return (-1); /* errno is set for us */ return (0); } } mcamd_dprintf(hdl, MCAMD_DBG_ERR, "mc_bkdg_patounum: in range " "for MC %d but no cs responds\n", (int)mcnum); return (mcamd_set_errno(hdl, EMCAMD_NOADDR)); } /* * Called for each memory controller to see if the given address is * mapped to this node (as determined in iaddr_gen) and, if so, which * chip-select on this node responds. */ /*ARGSUSED*/ static int mc_patounum(struct mcamd_hdl *hdl, mcamd_node_t *mc, uint64_t pa, uint8_t valid_lo, uint32_t synd, int syndtype, mc_unum_t *unump) { uint64_t iaddr; mcamd_node_t *cs, *sparecs; int which; #ifdef DEBUG mc_unum_t bkdg_unum; int bkdgres; /* * We perform the translation twice, once using the brute-force * approach of the BKDG and again using a more elegant but more * difficult to review against the BKDG approach. */ mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "BKDG brute-force method begins\n"); bkdgres = mc_bkdg_patounum(hdl, mc, pa, valid_lo, synd, syndtype, &bkdg_unum); mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "BKDG brute-force method ends\n"); #endif if (iaddr_gen(hdl, mc, pa, &iaddr) < 0) return (-1); /* errno is set for us */ for (cs = mcamd_cs_next(hdl, mc, NULL); cs != NULL; cs = mcamd_cs_next(hdl, mc, cs)) { if (cs_match(hdl, iaddr, cs)) break; } if (cs == NULL) return (mcamd_set_errno(hdl, EMCAMD_NOADDR)); /* * If the spare chip-select has been swapped in for the one just * matched then it is really the spare that we are after. Note that * when the swap is done the csbase, csmask and CSBE of the spare * rank do not change - accesses to the bad rank (as nominated in * the Online Spare Control Register) are redirect to the spare. */ if ((sparecs = cs_sparedto(hdl, cs, mc)) != NULL) { cs = sparecs; } if ((which = mc_whichdimm(hdl, cs, pa, valid_lo, synd, syndtype)) < 0) return (-1); /* errno is set for us */ if (unum_fill(hdl, cs, which, iaddr, unump, 1) < 0) return (-1); /* errno is set for us */ #ifdef DEBUG mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "bkdgres=%d res=0\n", bkdgres); /* offset is not checked - see note in BKDG algorithm */ if (bkdgres != 0) { mcamd_dprintf(hdl, MCAMD_DBG_ERR, "BKDG alg failed while " "ours succeeded\n"); } else if (!(unump->unum_board == bkdg_unum.unum_board && unump->unum_chip == bkdg_unum.unum_chip && unump->unum_mc == bkdg_unum.unum_mc && unump->unum_cs == bkdg_unum.unum_cs && unump->unum_dimms[0] == bkdg_unum.unum_dimms[0] && unump->unum_dimms[1] == bkdg_unum.unum_dimms[1])) { mcamd_dprintf(hdl, MCAMD_DBG_ERR, "BKDG: node %d mc %d cs %d dimm(s) %d/%d\n" "Ours: node 5d mc %d cs %d dimm(s) %d/%d\n", bkdg_unum.unum_chip, bkdg_unum.unum_mc, bkdg_unum.unum_cs, bkdg_unum.unum_dimms[0], bkdg_unum.unum_dimms[1], unump->unum_chip, unump->unum_mc, unump->unum_cs, unump->unum_dimms[0], unump->unum_dimms[1]); } #endif /* DEBUG */ mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "Result: chip %d mc %d cs %d " "offset 0x%llx\n", unump->unum_chip, unump->unum_mc, unump->unum_cs, unump->unum_offset); return (0); } int mcamd_patounum(struct mcamd_hdl *hdl, mcamd_node_t *root, uint64_t pa, uint8_t valid_hi, uint8_t valid_lo, uint32_t synd, int syndtype, mc_unum_t *unump) { mcamd_node_t *mc; mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "mcamd_patounum: pa=0x%llx, " "synd=0x%x, syndtype=%d\n", pa, synd, syndtype); if (valid_hi < MC_SYSADDR_MSB) { mcamd_dprintf(hdl, MCAMD_DBG_FLOW, "mcamd_patounum: require " "pa<%d> to be valid\n", MC_SYSADDR_MSB); return (mcamd_set_errno(hdl, EMCAMD_INSUFF_RES)); } if (!mcamd_synd_validate(hdl, synd, syndtype)) return (mcamd_set_errno(hdl, EMCAMD_SYNDINVALID)); for (mc = mcamd_mc_next(hdl, root, NULL); mc != NULL; mc = mcamd_mc_next(hdl, root, mc)) { if (mc_patounum(hdl, mc, pa, valid_lo, synd, syndtype, unump) == 0) return (0); if (mcamd_errno(hdl) != EMCAMD_NOADDR) break; } return (-1); /* errno is set for us */ }