/* * Copyright (c) 2010 Broadcom Corporation * * Permission to use, copy, modify, and/or distribute this software for any * purpose with or without fee is hereby granted, provided that the above * copyright notice and this permission notice appear in all copies. * * THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES * WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF * MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY * SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES * WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION * OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN * CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE. */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #define SROM_OFFSET(sih) ((sih->ccrev > 31) ? \ (((sih->cccaps & CC_CAP_SROM) == 0) ? NULL : \ ((u8 *)curmap + PCI_16KB0_CCREGS_OFFSET + CC_SROM_OTP)) : \ ((u8 *)curmap + PCI_BAR0_SPROM_OFFSET)) #if defined(BCMDBG) #define WRITE_ENABLE_DELAY 500 /* 500 ms after write enable/disable toggle */ #define WRITE_WORD_DELAY 20 /* 20 ms between each word write */ #endif typedef struct varbuf { char *base; /* pointer to buffer base */ char *buf; /* pointer to current position */ unsigned int size; /* current (residual) size in bytes */ } varbuf_t; extern char *_vars; extern uint _varsz; static int initvars_srom_si(si_t *sih, void *curmap, char **vars, uint *count); static void _initvars_srom_pci(u8 sromrev, u16 *srom, uint off, varbuf_t *b); static int initvars_srom_pci(si_t *sih, void *curmap, char **vars, uint *count); static int initvars_flash_si(si_t *sih, char **vars, uint *count); static int sprom_read_pci(si_t *sih, u16 *sprom, uint wordoff, u16 *buf, uint nwords, bool check_crc); #if defined(BCMNVRAMR) static int otp_read_pci(si_t *sih, u16 *buf, uint bufsz); #endif static u16 srom_cc_cmd(si_t *sih, void *ccregs, u32 cmd, uint wordoff, u16 data); static int initvars_table(char *start, char *end, char **vars, uint *count); static int initvars_flash(si_t *sih, char **vp, uint len); /* Initialization of varbuf structure */ static void varbuf_init(varbuf_t *b, char *buf, uint size) { b->size = size; b->base = b->buf = buf; } /* append a null terminated var=value string */ static int varbuf_append(varbuf_t *b, const char *fmt, ...) { va_list ap; int r; size_t len; char *s; if (b->size < 2) return 0; va_start(ap, fmt); r = vsnprintf(b->buf, b->size, fmt, ap); va_end(ap); /* C99 snprintf behavior returns r >= size on overflow, * others return -1 on overflow. * All return -1 on format error. * We need to leave room for 2 null terminations, one for the current var * string, and one for final null of the var table. So check that the * strlen written, r, leaves room for 2 chars. */ if ((r == -1) || (r > (int)(b->size - 2))) { b->size = 0; return 0; } /* Remove any earlier occurrence of the same variable */ s = strchr(b->buf, '='); if (s != NULL) { len = (size_t) (s - b->buf); for (s = b->base; s < b->buf;) { if ((memcmp(s, b->buf, len) == 0) && s[len] == '=') { len = strlen(s) + 1; memmove(s, (s + len), ((b->buf + r + 1) - (s + len))); b->buf -= len; b->size += (unsigned int)len; break; } while (*s++) ; } } /* skip over this string's null termination */ r++; b->size -= r; b->buf += r; return r; } /* * Initialize local vars from the right source for this platform. * Return 0 on success, nonzero on error. */ int srom_var_init(si_t *sih, uint bustype, void *curmap, char **vars, uint *count) { uint len; len = 0; if (vars == NULL || count == NULL) return 0; *vars = NULL; *count = 0; switch (bustype) { case SI_BUS: case JTAG_BUS: return initvars_srom_si(sih, curmap, vars, count); case PCI_BUS: if (curmap == NULL) return -1; return initvars_srom_pci(sih, curmap, vars, count); default: break; } return -1; } /* In chips with chipcommon rev 32 and later, the srom is in chipcommon, * not in the bus cores. */ static u16 srom_cc_cmd(si_t *sih, void *ccregs, u32 cmd, uint wordoff, u16 data) { chipcregs_t *cc = (chipcregs_t *) ccregs; uint wait_cnt = 1000; if ((cmd == SRC_OP_READ) || (cmd == SRC_OP_WRITE)) { W_REG(&cc->sromaddress, wordoff * 2); if (cmd == SRC_OP_WRITE) W_REG(&cc->sromdata, data); } W_REG(&cc->sromcontrol, SRC_START | cmd); while (wait_cnt--) { if ((R_REG(&cc->sromcontrol) & SRC_BUSY) == 0) break; } if (!wait_cnt) { return 0xffff; } if (cmd == SRC_OP_READ) return (u16) R_REG(&cc->sromdata); else return 0xffff; } static inline void ltoh16_buf(u16 *buf, unsigned int size) { for (size /= 2; size; size--) *(buf + size) = le16_to_cpu(*(buf + size)); } static inline void htol16_buf(u16 *buf, unsigned int size) { for (size /= 2; size; size--) *(buf + size) = cpu_to_le16(*(buf + size)); } /* * Read in and validate sprom. * Return 0 on success, nonzero on error. */ static int sprom_read_pci(si_t *sih, u16 *sprom, uint wordoff, u16 *buf, uint nwords, bool check_crc) { int err = 0; uint i; void *ccregs = NULL; /* read the sprom */ for (i = 0; i < nwords; i++) { if (sih->ccrev > 31 && ISSIM_ENAB(sih)) { /* use indirect since direct is too slow on QT */ if ((sih->cccaps & CC_CAP_SROM) == 0) return 1; ccregs = (void *)((u8 *) sprom - CC_SROM_OTP); buf[i] = srom_cc_cmd(sih, ccregs, SRC_OP_READ, wordoff + i, 0); } else { if (ISSIM_ENAB(sih)) buf[i] = R_REG(&sprom[wordoff + i]); buf[i] = R_REG(&sprom[wordoff + i]); } } /* bypass crc checking for simulation to allow srom hack */ if (ISSIM_ENAB(sih)) return err; if (check_crc) { if (buf[0] == 0xffff) { /* The hardware thinks that an srom that starts with 0xffff * is blank, regardless of the rest of the content, so declare * it bad. */ return 1; } /* fixup the endianness so crc8 will pass */ htol16_buf(buf, nwords * 2); if (bcm_crc8((u8 *) buf, nwords * 2, CRC8_INIT_VALUE) != CRC8_GOOD_VALUE) { /* DBG only pci always read srom4 first, then srom8/9 */ err = 1; } /* now correct the endianness of the byte array */ ltoh16_buf(buf, nwords * 2); } return err; } #if defined(BCMNVRAMR) static int otp_read_pci(si_t *sih, u16 *buf, uint bufsz) { u8 *otp; uint sz = OTP_SZ_MAX / 2; /* size in words */ int err = 0; otp = kzalloc(OTP_SZ_MAX, GFP_ATOMIC); if (otp == NULL) { return -EBADE; } err = otp_read_region(sih, OTP_HW_RGN, (u16 *) otp, &sz); memcpy(buf, otp, bufsz); kfree(otp); /* Check CRC */ if (buf[0] == 0xffff) { /* The hardware thinks that an srom that starts with 0xffff * is blank, regardless of the rest of the content, so declare * it bad. */ return 1; } /* fixup the endianness so crc8 will pass */ htol16_buf(buf, bufsz); if (bcm_crc8((u8 *) buf, SROM4_WORDS * 2, CRC8_INIT_VALUE) != CRC8_GOOD_VALUE) { err = 1; } /* now correct the endianness of the byte array */ ltoh16_buf(buf, bufsz); return err; } #endif /* defined(BCMNVRAMR) */ /* * Create variable table from memory. * Return 0 on success, nonzero on error. */ static int initvars_table(char *start, char *end, char **vars, uint *count) { int c = (int)(end - start); /* do it only when there is more than just the null string */ if (c > 1) { char *vp = kmalloc(c, GFP_ATOMIC); if (!vp) return -ENOMEM; memcpy(vp, start, c); *vars = vp; *count = c; } else { *vars = NULL; *count = 0; } return 0; } /* * Find variables with from flash. 'base' points to the beginning * of the table upon enter and to the end of the table upon exit when success. * Return 0 on success, nonzero on error. */ static int initvars_flash(si_t *sih, char **base, uint len) { char *vp = *base; char *flash; int err; char *s; uint l, dl, copy_len; char devpath[SI_DEVPATH_BUFSZ]; /* allocate memory and read in flash */ flash = kmalloc(NVRAM_SPACE, GFP_ATOMIC); if (!flash) return -ENOMEM; err = nvram_getall(flash, NVRAM_SPACE); if (err) goto exit; ai_devpath(sih, devpath, sizeof(devpath)); /* grab vars with the prefix in name */ dl = strlen(devpath); for (s = flash; s && *s; s += l + 1) { l = strlen(s); /* skip non-matching variable */ if (strncmp(s, devpath, dl)) continue; /* is there enough room to copy? */ copy_len = l - dl + 1; if (len < copy_len) { err = -EOVERFLOW; goto exit; } /* no prefix, just the name=value */ strncpy(vp, &s[dl], copy_len); vp += copy_len; len -= copy_len; } /* add null string as terminator */ if (len < 1) { err = -EOVERFLOW; goto exit; } *vp++ = '\0'; *base = vp; exit: kfree(flash); return err; } /* * Initialize nonvolatile variable table from flash. * Return 0 on success, nonzero on error. */ static int initvars_flash_si(si_t *sih, char **vars, uint *count) { char *vp, *base; int err; base = vp = kmalloc(MAXSZ_NVRAM_VARS, GFP_ATOMIC); if (!vp) return -ENOMEM; err = initvars_flash(sih, &vp, MAXSZ_NVRAM_VARS); if (err == 0) err = initvars_table(base, vp, vars, count); kfree(base); return err; } /* Parse SROM and create name=value pairs. 'srom' points to * the SROM word array. 'off' specifies the offset of the * first word 'srom' points to, which should be either 0 or * SROM3_SWRG_OFF (full SROM or software region). */ static uint mask_shift(u16 mask) { uint i; for (i = 0; i < (sizeof(mask) << 3); i++) { if (mask & (1 << i)) return i; } return 0; } static uint mask_width(u16 mask) { int i; for (i = (sizeof(mask) << 3) - 1; i >= 0; i--) { if (mask & (1 << i)) return (uint) (i - mask_shift(mask) + 1); } return 0; } static void _initvars_srom_pci(u8 sromrev, u16 *srom, uint off, varbuf_t *b) { u16 w; u32 val; const sromvar_t *srv; uint width; uint flags; u32 sr = (1 << sromrev); varbuf_append(b, "sromrev=%d", sromrev); for (srv = pci_sromvars; srv->name != NULL; srv++) { const char *name; if ((srv->revmask & sr) == 0) continue; if (srv->off < off) continue; flags = srv->flags; name = srv->name; /* This entry is for mfgc only. Don't generate param for it, */ if (flags & SRFL_NOVAR) continue; if (flags & SRFL_ETHADDR) { u8 ea[ETH_ALEN]; ea[0] = (srom[srv->off - off] >> 8) & 0xff; ea[1] = srom[srv->off - off] & 0xff; ea[2] = (srom[srv->off + 1 - off] >> 8) & 0xff; ea[3] = srom[srv->off + 1 - off] & 0xff; ea[4] = (srom[srv->off + 2 - off] >> 8) & 0xff; ea[5] = srom[srv->off + 2 - off] & 0xff; varbuf_append(b, "%s=%pM", name, ea); } else { w = srom[srv->off - off]; val = (w & srv->mask) >> mask_shift(srv->mask); width = mask_width(srv->mask); while (srv->flags & SRFL_MORE) { srv++; if (srv->off == 0 || srv->off < off) continue; w = srom[srv->off - off]; val += ((w & srv->mask) >> mask_shift(srv-> mask)) << width; width += mask_width(srv->mask); } if ((flags & SRFL_NOFFS) && ((int)val == (1 << width) - 1)) continue; if (flags & SRFL_CCODE) { if (val == 0) varbuf_append(b, "ccode="); else varbuf_append(b, "ccode=%c%c", (val >> 8), (val & 0xff)); } /* LED Powersave duty cycle has to be scaled: *(oncount >> 24) (offcount >> 8) */ else if (flags & SRFL_LEDDC) { u32 w32 = (((val >> 8) & 0xff) << 24) | /* oncount */ (((val & 0xff)) << 8); /* offcount */ varbuf_append(b, "leddc=%d", w32); } else if (flags & SRFL_PRHEX) varbuf_append(b, "%s=0x%x", name, val); else if ((flags & SRFL_PRSIGN) && (val & (1 << (width - 1)))) varbuf_append(b, "%s=%d", name, (int)(val | (~0 << width))); else varbuf_append(b, "%s=%u", name, val); } } if (sromrev >= 4) { /* Do per-path variables */ uint p, pb, psz; if (sromrev >= 8) { pb = SROM8_PATH0; psz = SROM8_PATH1 - SROM8_PATH0; } else { pb = SROM4_PATH0; psz = SROM4_PATH1 - SROM4_PATH0; } for (p = 0; p < MAX_PATH_SROM; p++) { for (srv = perpath_pci_sromvars; srv->name != NULL; srv++) { if ((srv->revmask & sr) == 0) continue; if (pb + srv->off < off) continue; /* This entry is for mfgc only. Don't generate param for it, */ if (srv->flags & SRFL_NOVAR) continue; w = srom[pb + srv->off - off]; val = (w & srv->mask) >> mask_shift(srv->mask); width = mask_width(srv->mask); /* Cheating: no per-path var is more than 1 word */ if ((srv->flags & SRFL_NOFFS) && ((int)val == (1 << width) - 1)) continue; if (srv->flags & SRFL_PRHEX) varbuf_append(b, "%s%d=0x%x", srv->name, p, val); else varbuf_append(b, "%s%d=%d", srv->name, p, val); } pb += psz; } } } /* * Initialize nonvolatile variable table from sprom. * Return 0 on success, nonzero on error. */ static int initvars_srom_pci(si_t *sih, void *curmap, char **vars, uint *count) { u16 *srom, *sromwindow; u8 sromrev = 0; u32 sr; varbuf_t b; char *vp, *base = NULL; bool flash = false; int err = 0; /* * Apply CRC over SROM content regardless SROM is present or not, * and use variable sromrev's existence in flash to decide * if we should return an error when CRC fails or read SROM variables * from flash. */ srom = kmalloc(SROM_MAX, GFP_ATOMIC); if (!srom) return -2; sromwindow = (u16 *) SROM_OFFSET(sih); if (ai_is_sprom_available(sih)) { err = sprom_read_pci(sih, sromwindow, 0, srom, SROM_WORDS, true); if ((srom[SROM4_SIGN] == SROM4_SIGNATURE) || (((sih->buscoretype == PCIE_CORE_ID) && (sih->buscorerev >= 6)) || ((sih->buscoretype == PCI_CORE_ID) && (sih->buscorerev >= 0xe)))) { /* sromrev >= 4, read more */ err = sprom_read_pci(sih, sromwindow, 0, srom, SROM4_WORDS, true); sromrev = srom[SROM4_CRCREV] & 0xff; } else if (err == 0) { /* srom is good and is rev < 4 */ /* top word of sprom contains version and crc8 */ sromrev = srom[SROM_CRCREV] & 0xff; /* bcm4401 sroms misprogrammed */ if (sromrev == 0x10) sromrev = 1; } } #if defined(BCMNVRAMR) /* Use OTP if SPROM not available */ else { err = otp_read_pci(sih, srom, SROM_MAX); if (err == 0) /* OTP only contain SROM rev8/rev9 for now */ sromrev = srom[SROM4_CRCREV] & 0xff; else err = 1; } #else else err = 1; #endif /* * We want internal/wltest driver to come up with default * sromvars so we can program a blank SPROM/OTP. */ if (err) { char *value; u32 val; val = 0; value = ai_getdevpathvar(sih, "sromrev"); if (value) { sromrev = (u8) simple_strtoul(value, NULL, 0); flash = true; goto varscont; } value = ai_getnvramflvar(sih, "sromrev"); if (value) { err = 0; goto errout; } { err = -1; goto errout; } } varscont: /* Bitmask for the sromrev */ sr = 1 << sromrev; /* srom version check: Current valid versions: 1, 2, 3, 4, 5, 8, 9 */ if ((sr & 0x33e) == 0) { err = -2; goto errout; } base = vp = kmalloc(MAXSZ_NVRAM_VARS, GFP_ATOMIC); if (!vp) { err = -2; goto errout; } /* read variables from flash */ if (flash) { err = initvars_flash(sih, &vp, MAXSZ_NVRAM_VARS); if (err) goto errout; goto varsdone; } varbuf_init(&b, base, MAXSZ_NVRAM_VARS); /* parse SROM into name=value pairs. */ _initvars_srom_pci(sromrev, srom, 0, &b); /* final nullbyte terminator */ vp = b.buf; *vp++ = '\0'; varsdone: err = initvars_table(base, vp, vars, count); errout: if (base) kfree(base); kfree(srom); return err; } static int initvars_srom_si(si_t *sih, void *curmap, char **vars, uint *varsz) { /* Search flash nvram section for srom variables */ return initvars_flash_si(sih, vars, varsz); }