net: wireless: bcmdhd: Initial version based on 5.90.195.23
Change-Id: I91012d9adf1d9506cc0f832a683bd88684111b71
Signed-off-by: Dmitry Shmidt <dimitrysh@google.com>
diff --git a/drivers/net/wireless/bcmdhd/sbutils.c b/drivers/net/wireless/bcmdhd/sbutils.c
new file mode 100644
index 0000000..02d1bc0
--- /dev/null
+++ b/drivers/net/wireless/bcmdhd/sbutils.c
@@ -0,0 +1,992 @@
+/*
+ * Misc utility routines for accessing chip-specific features
+ * of the SiliconBackplane-based Broadcom chips.
+ *
+ * Copyright (C) 1999-2011, Broadcom Corporation
+ *
+ * Unless you and Broadcom execute a separate written software license
+ * agreement governing use of this software, this software is licensed to you
+ * under the terms of the GNU General Public License version 2 (the "GPL"),
+ * available at http://www.broadcom.com/licenses/GPLv2.php, with the
+ * following added to such license:
+ *
+ * As a special exception, the copyright holders of this software give you
+ * permission to link this software with independent modules, and to copy and
+ * distribute the resulting executable under terms of your choice, provided that
+ * you also meet, for each linked independent module, the terms and conditions of
+ * the license of that module. An independent module is a module which is not
+ * derived from this software. The special exception does not apply to any
+ * modifications of the software.
+ *
+ * Notwithstanding the above, under no circumstances may you combine this
+ * software in any way with any other Broadcom software provided under a license
+ * other than the GPL, without Broadcom's express prior written consent.
+ *
+ * $Id: sbutils.c,v 1.687.2.1 2010-11-29 20:21:56 Exp $
+ */
+
+#include <typedefs.h>
+#include <bcmdefs.h>
+#include <osl.h>
+#include <bcmutils.h>
+#include <siutils.h>
+#include <bcmdevs.h>
+#include <hndsoc.h>
+#include <sbchipc.h>
+#include <pcicfg.h>
+#include <sbpcmcia.h>
+
+#include "siutils_priv.h"
+
+
+/* local prototypes */
+static uint _sb_coreidx(si_info_t *sii, uint32 sba);
+static uint _sb_scan(si_info_t *sii, uint32 sba, void *regs, uint bus, uint32 sbba,
+ uint ncores);
+static uint32 _sb_coresba(si_info_t *sii);
+static void *_sb_setcoreidx(si_info_t *sii, uint coreidx);
+
+#define SET_SBREG(sii, r, mask, val) \
+ W_SBREG((sii), (r), ((R_SBREG((sii), (r)) & ~(mask)) | (val)))
+#define REGS2SB(va) (sbconfig_t*) ((int8*)(va) + SBCONFIGOFF)
+
+/* sonicsrev */
+#define SONICS_2_2 (SBIDL_RV_2_2 >> SBIDL_RV_SHIFT)
+#define SONICS_2_3 (SBIDL_RV_2_3 >> SBIDL_RV_SHIFT)
+
+#define R_SBREG(sii, sbr) sb_read_sbreg((sii), (sbr))
+#define W_SBREG(sii, sbr, v) sb_write_sbreg((sii), (sbr), (v))
+#define AND_SBREG(sii, sbr, v) W_SBREG((sii), (sbr), (R_SBREG((sii), (sbr)) & (v)))
+#define OR_SBREG(sii, sbr, v) W_SBREG((sii), (sbr), (R_SBREG((sii), (sbr)) | (v)))
+
+static uint32
+sb_read_sbreg(si_info_t *sii, volatile uint32 *sbr)
+{
+ uint8 tmp;
+ uint32 val, intr_val = 0;
+
+
+ /*
+ * compact flash only has 11 bits address, while we needs 12 bits address.
+ * MEM_SEG will be OR'd with other 11 bits address in hardware,
+ * so we program MEM_SEG with 12th bit when necessary(access sb regsiters).
+ * For normal PCMCIA bus(CFTable_regwinsz > 2k), do nothing special
+ */
+ if (PCMCIA(sii)) {
+ INTR_OFF(sii, intr_val);
+ tmp = 1;
+ OSL_PCMCIA_WRITE_ATTR(sii->osh, MEM_SEG, &tmp, 1);
+ sbr = (volatile uint32 *)((uintptr)sbr & ~(1 << 11)); /* mask out bit 11 */
+ }
+
+ val = R_REG(sii->osh, sbr);
+
+ if (PCMCIA(sii)) {
+ tmp = 0;
+ OSL_PCMCIA_WRITE_ATTR(sii->osh, MEM_SEG, &tmp, 1);
+ INTR_RESTORE(sii, intr_val);
+ }
+
+ return (val);
+}
+
+static void
+sb_write_sbreg(si_info_t *sii, volatile uint32 *sbr, uint32 v)
+{
+ uint8 tmp;
+ volatile uint32 dummy;
+ uint32 intr_val = 0;
+
+
+ /*
+ * compact flash only has 11 bits address, while we needs 12 bits address.
+ * MEM_SEG will be OR'd with other 11 bits address in hardware,
+ * so we program MEM_SEG with 12th bit when necessary(access sb regsiters).
+ * For normal PCMCIA bus(CFTable_regwinsz > 2k), do nothing special
+ */
+ if (PCMCIA(sii)) {
+ INTR_OFF(sii, intr_val);
+ tmp = 1;
+ OSL_PCMCIA_WRITE_ATTR(sii->osh, MEM_SEG, &tmp, 1);
+ sbr = (volatile uint32 *)((uintptr)sbr & ~(1 << 11)); /* mask out bit 11 */
+ }
+
+ if (BUSTYPE(sii->pub.bustype) == PCMCIA_BUS) {
+ dummy = R_REG(sii->osh, sbr);
+ W_REG(sii->osh, (volatile uint16 *)sbr, (uint16)(v & 0xffff));
+ dummy = R_REG(sii->osh, sbr);
+ W_REG(sii->osh, ((volatile uint16 *)sbr + 1), (uint16)((v >> 16) & 0xffff));
+ } else
+ W_REG(sii->osh, sbr, v);
+
+ if (PCMCIA(sii)) {
+ tmp = 0;
+ OSL_PCMCIA_WRITE_ATTR(sii->osh, MEM_SEG, &tmp, 1);
+ INTR_RESTORE(sii, intr_val);
+ }
+}
+
+uint
+sb_coreid(si_t *sih)
+{
+ si_info_t *sii;
+ sbconfig_t *sb;
+
+ sii = SI_INFO(sih);
+ sb = REGS2SB(sii->curmap);
+
+ return ((R_SBREG(sii, &sb->sbidhigh) & SBIDH_CC_MASK) >> SBIDH_CC_SHIFT);
+}
+
+uint
+sb_intflag(si_t *sih)
+{
+ si_info_t *sii;
+ void *corereg;
+ sbconfig_t *sb;
+ uint origidx, intflag, intr_val = 0;
+
+ sii = SI_INFO(sih);
+
+ INTR_OFF(sii, intr_val);
+ origidx = si_coreidx(sih);
+ corereg = si_setcore(sih, CC_CORE_ID, 0);
+ ASSERT(corereg != NULL);
+ sb = REGS2SB(corereg);
+ intflag = R_SBREG(sii, &sb->sbflagst);
+ sb_setcoreidx(sih, origidx);
+ INTR_RESTORE(sii, intr_val);
+
+ return intflag;
+}
+
+uint
+sb_flag(si_t *sih)
+{
+ si_info_t *sii;
+ sbconfig_t *sb;
+
+ sii = SI_INFO(sih);
+ sb = REGS2SB(sii->curmap);
+
+ return R_SBREG(sii, &sb->sbtpsflag) & SBTPS_NUM0_MASK;
+}
+
+void
+sb_setint(si_t *sih, int siflag)
+{
+ si_info_t *sii;
+ sbconfig_t *sb;
+ uint32 vec;
+
+ sii = SI_INFO(sih);
+ sb = REGS2SB(sii->curmap);
+
+ if (siflag == -1)
+ vec = 0;
+ else
+ vec = 1 << siflag;
+ W_SBREG(sii, &sb->sbintvec, vec);
+}
+
+/* return core index of the core with address 'sba' */
+static uint
+_sb_coreidx(si_info_t *sii, uint32 sba)
+{
+ uint i;
+
+ for (i = 0; i < sii->numcores; i ++)
+ if (sba == sii->coresba[i])
+ return i;
+ return BADIDX;
+}
+
+/* return core address of the current core */
+static uint32
+_sb_coresba(si_info_t *sii)
+{
+ uint32 sbaddr;
+
+
+ switch (BUSTYPE(sii->pub.bustype)) {
+ case SI_BUS: {
+ sbconfig_t *sb = REGS2SB(sii->curmap);
+ sbaddr = sb_base(R_SBREG(sii, &sb->sbadmatch0));
+ break;
+ }
+
+ case PCI_BUS:
+ sbaddr = OSL_PCI_READ_CONFIG(sii->osh, PCI_BAR0_WIN, sizeof(uint32));
+ break;
+
+ case PCMCIA_BUS: {
+ uint8 tmp = 0;
+ OSL_PCMCIA_READ_ATTR(sii->osh, PCMCIA_ADDR0, &tmp, 1);
+ sbaddr = (uint32)tmp << 12;
+ OSL_PCMCIA_READ_ATTR(sii->osh, PCMCIA_ADDR1, &tmp, 1);
+ sbaddr |= (uint32)tmp << 16;
+ OSL_PCMCIA_READ_ATTR(sii->osh, PCMCIA_ADDR2, &tmp, 1);
+ sbaddr |= (uint32)tmp << 24;
+ break;
+ }
+
+ case SPI_BUS:
+ case SDIO_BUS:
+ sbaddr = (uint32)(uintptr)sii->curmap;
+ break;
+
+
+ default:
+ sbaddr = BADCOREADDR;
+ break;
+ }
+
+ return sbaddr;
+}
+
+uint
+sb_corevendor(si_t *sih)
+{
+ si_info_t *sii;
+ sbconfig_t *sb;
+
+ sii = SI_INFO(sih);
+ sb = REGS2SB(sii->curmap);
+
+ return ((R_SBREG(sii, &sb->sbidhigh) & SBIDH_VC_MASK) >> SBIDH_VC_SHIFT);
+}
+
+uint
+sb_corerev(si_t *sih)
+{
+ si_info_t *sii;
+ sbconfig_t *sb;
+ uint sbidh;
+
+ sii = SI_INFO(sih);
+ sb = REGS2SB(sii->curmap);
+ sbidh = R_SBREG(sii, &sb->sbidhigh);
+
+ return (SBCOREREV(sbidh));
+}
+
+/* set core-specific control flags */
+void
+sb_core_cflags_wo(si_t *sih, uint32 mask, uint32 val)
+{
+ si_info_t *sii;
+ sbconfig_t *sb;
+ uint32 w;
+
+ sii = SI_INFO(sih);
+ sb = REGS2SB(sii->curmap);
+
+ ASSERT((val & ~mask) == 0);
+
+ /* mask and set */
+ w = (R_SBREG(sii, &sb->sbtmstatelow) & ~(mask << SBTML_SICF_SHIFT)) |
+ (val << SBTML_SICF_SHIFT);
+ W_SBREG(sii, &sb->sbtmstatelow, w);
+}
+
+/* set/clear core-specific control flags */
+uint32
+sb_core_cflags(si_t *sih, uint32 mask, uint32 val)
+{
+ si_info_t *sii;
+ sbconfig_t *sb;
+ uint32 w;
+
+ sii = SI_INFO(sih);
+ sb = REGS2SB(sii->curmap);
+
+ ASSERT((val & ~mask) == 0);
+
+ /* mask and set */
+ if (mask || val) {
+ w = (R_SBREG(sii, &sb->sbtmstatelow) & ~(mask << SBTML_SICF_SHIFT)) |
+ (val << SBTML_SICF_SHIFT);
+ W_SBREG(sii, &sb->sbtmstatelow, w);
+ }
+
+ /* return the new value
+ * for write operation, the following readback ensures the completion of write opration.
+ */
+ return (R_SBREG(sii, &sb->sbtmstatelow) >> SBTML_SICF_SHIFT);
+}
+
+/* set/clear core-specific status flags */
+uint32
+sb_core_sflags(si_t *sih, uint32 mask, uint32 val)
+{
+ si_info_t *sii;
+ sbconfig_t *sb;
+ uint32 w;
+
+ sii = SI_INFO(sih);
+ sb = REGS2SB(sii->curmap);
+
+ ASSERT((val & ~mask) == 0);
+ ASSERT((mask & ~SISF_CORE_BITS) == 0);
+
+ /* mask and set */
+ if (mask || val) {
+ w = (R_SBREG(sii, &sb->sbtmstatehigh) & ~(mask << SBTMH_SISF_SHIFT)) |
+ (val << SBTMH_SISF_SHIFT);
+ W_SBREG(sii, &sb->sbtmstatehigh, w);
+ }
+
+ /* return the new value */
+ return (R_SBREG(sii, &sb->sbtmstatehigh) >> SBTMH_SISF_SHIFT);
+}
+
+bool
+sb_iscoreup(si_t *sih)
+{
+ si_info_t *sii;
+ sbconfig_t *sb;
+
+ sii = SI_INFO(sih);
+ sb = REGS2SB(sii->curmap);
+
+ return ((R_SBREG(sii, &sb->sbtmstatelow) &
+ (SBTML_RESET | SBTML_REJ_MASK | (SICF_CLOCK_EN << SBTML_SICF_SHIFT))) ==
+ (SICF_CLOCK_EN << SBTML_SICF_SHIFT));
+}
+
+/*
+ * Switch to 'coreidx', issue a single arbitrary 32bit register mask&set operation,
+ * switch back to the original core, and return the new value.
+ *
+ * When using the silicon backplane, no fidleing with interrupts or core switches are needed.
+ *
+ * Also, when using pci/pcie, we can optimize away the core switching for pci registers
+ * and (on newer pci cores) chipcommon registers.
+ */
+uint
+sb_corereg(si_t *sih, uint coreidx, uint regoff, uint mask, uint val)
+{
+ uint origidx = 0;
+ uint32 *r = NULL;
+ uint w;
+ uint intr_val = 0;
+ bool fast = FALSE;
+ si_info_t *sii;
+
+ sii = SI_INFO(sih);
+
+ ASSERT(GOODIDX(coreidx));
+ ASSERT(regoff < SI_CORE_SIZE);
+ ASSERT((val & ~mask) == 0);
+
+ if (coreidx >= SI_MAXCORES)
+ return 0;
+
+ if (BUSTYPE(sii->pub.bustype) == SI_BUS) {
+ /* If internal bus, we can always get at everything */
+ fast = TRUE;
+ /* map if does not exist */
+ if (!sii->regs[coreidx]) {
+ sii->regs[coreidx] = REG_MAP(sii->coresba[coreidx],
+ SI_CORE_SIZE);
+ ASSERT(GOODREGS(sii->regs[coreidx]));
+ }
+ r = (uint32 *)((uchar *)sii->regs[coreidx] + regoff);
+ } else if (BUSTYPE(sii->pub.bustype) == PCI_BUS) {
+ /* If pci/pcie, we can get at pci/pcie regs and on newer cores to chipc */
+
+ if ((sii->coreid[coreidx] == CC_CORE_ID) && SI_FAST(sii)) {
+ /* Chipc registers are mapped at 12KB */
+
+ fast = TRUE;
+ r = (uint32 *)((char *)sii->curmap + PCI_16KB0_CCREGS_OFFSET + regoff);
+ } else if (sii->pub.buscoreidx == coreidx) {
+ /* pci registers are at either in the last 2KB of an 8KB window
+ * or, in pcie and pci rev 13 at 8KB
+ */
+ fast = TRUE;
+ if (SI_FAST(sii))
+ r = (uint32 *)((char *)sii->curmap +
+ PCI_16KB0_PCIREGS_OFFSET + regoff);
+ else
+ r = (uint32 *)((char *)sii->curmap +
+ ((regoff >= SBCONFIGOFF) ?
+ PCI_BAR0_PCISBR_OFFSET : PCI_BAR0_PCIREGS_OFFSET) +
+ regoff);
+ }
+ }
+
+ if (!fast) {
+ INTR_OFF(sii, intr_val);
+
+ /* save current core index */
+ origidx = si_coreidx(&sii->pub);
+
+ /* switch core */
+ r = (uint32*) ((uchar*)sb_setcoreidx(&sii->pub, coreidx) + regoff);
+ }
+ ASSERT(r != NULL);
+
+ /* mask and set */
+ if (mask || val) {
+ if (regoff >= SBCONFIGOFF) {
+ w = (R_SBREG(sii, r) & ~mask) | val;
+ W_SBREG(sii, r, w);
+ } else {
+ w = (R_REG(sii->osh, r) & ~mask) | val;
+ W_REG(sii->osh, r, w);
+ }
+ }
+
+ /* readback */
+ if (regoff >= SBCONFIGOFF)
+ w = R_SBREG(sii, r);
+ else {
+ if ((CHIPID(sii->pub.chip) == BCM5354_CHIP_ID) &&
+ (coreidx == SI_CC_IDX) &&
+ (regoff == OFFSETOF(chipcregs_t, watchdog))) {
+ w = val;
+ } else
+ w = R_REG(sii->osh, r);
+ }
+
+ if (!fast) {
+ /* restore core index */
+ if (origidx != coreidx)
+ sb_setcoreidx(&sii->pub, origidx);
+
+ INTR_RESTORE(sii, intr_val);
+ }
+
+ return (w);
+}
+
+/* Scan the enumeration space to find all cores starting from the given
+ * bus 'sbba'. Append coreid and other info to the lists in 'si'. 'sba'
+ * is the default core address at chip POR time and 'regs' is the virtual
+ * address that the default core is mapped at. 'ncores' is the number of
+ * cores expected on bus 'sbba'. It returns the total number of cores
+ * starting from bus 'sbba', inclusive.
+ */
+#define SB_MAXBUSES 2
+static uint
+_sb_scan(si_info_t *sii, uint32 sba, void *regs, uint bus, uint32 sbba, uint numcores)
+{
+ uint next;
+ uint ncc = 0;
+ uint i;
+
+ if (bus >= SB_MAXBUSES) {
+ SI_ERROR(("_sb_scan: bus 0x%08x at level %d is too deep to scan\n", sbba, bus));
+ return 0;
+ }
+ SI_MSG(("_sb_scan: scan bus 0x%08x assume %u cores\n", sbba, numcores));
+
+ /* Scan all cores on the bus starting from core 0.
+ * Core addresses must be contiguous on each bus.
+ */
+ for (i = 0, next = sii->numcores; i < numcores && next < SB_BUS_MAXCORES; i++, next++) {
+ sii->coresba[next] = sbba + (i * SI_CORE_SIZE);
+
+ /* keep and reuse the initial register mapping */
+ if ((BUSTYPE(sii->pub.bustype) == SI_BUS) && (sii->coresba[next] == sba)) {
+ SI_VMSG(("_sb_scan: reuse mapped regs %p for core %u\n", regs, next));
+ sii->regs[next] = regs;
+ }
+
+ /* change core to 'next' and read its coreid */
+ sii->curmap = _sb_setcoreidx(sii, next);
+ sii->curidx = next;
+
+ sii->coreid[next] = sb_coreid(&sii->pub);
+
+ /* core specific processing... */
+ /* chipc provides # cores */
+ if (sii->coreid[next] == CC_CORE_ID) {
+ chipcregs_t *cc = (chipcregs_t *)sii->curmap;
+ uint32 ccrev = sb_corerev(&sii->pub);
+
+ /* determine numcores - this is the total # cores in the chip */
+ if (((ccrev == 4) || (ccrev >= 6)))
+ numcores = (R_REG(sii->osh, &cc->chipid) & CID_CC_MASK) >>
+ CID_CC_SHIFT;
+ else {
+ /* Older chips */
+ uint chip = CHIPID(sii->pub.chip);
+
+ if (chip == BCM4306_CHIP_ID) /* < 4306c0 */
+ numcores = 6;
+ else if (chip == BCM4704_CHIP_ID)
+ numcores = 9;
+ else if (chip == BCM5365_CHIP_ID)
+ numcores = 7;
+ else {
+ SI_ERROR(("sb_chip2numcores: unsupported chip 0x%x\n",
+ chip));
+ ASSERT(0);
+ numcores = 1;
+ }
+ }
+ SI_VMSG(("_sb_scan: there are %u cores in the chip %s\n", numcores,
+ sii->pub.issim ? "QT" : ""));
+ }
+ /* scan bridged SB(s) and add results to the end of the list */
+ else if (sii->coreid[next] == OCP_CORE_ID) {
+ sbconfig_t *sb = REGS2SB(sii->curmap);
+ uint32 nsbba = R_SBREG(sii, &sb->sbadmatch1);
+ uint nsbcc;
+
+ sii->numcores = next + 1;
+
+ if ((nsbba & 0xfff00000) != SI_ENUM_BASE)
+ continue;
+ nsbba &= 0xfffff000;
+ if (_sb_coreidx(sii, nsbba) != BADIDX)
+ continue;
+
+ nsbcc = (R_SBREG(sii, &sb->sbtmstatehigh) & 0x000f0000) >> 16;
+ nsbcc = _sb_scan(sii, sba, regs, bus + 1, nsbba, nsbcc);
+ if (sbba == SI_ENUM_BASE)
+ numcores -= nsbcc;
+ ncc += nsbcc;
+ }
+ }
+
+ SI_MSG(("_sb_scan: found %u cores on bus 0x%08x\n", i, sbba));
+
+ sii->numcores = i + ncc;
+ return sii->numcores;
+}
+
+/* scan the sb enumerated space to identify all cores */
+void
+sb_scan(si_t *sih, void *regs, uint devid)
+{
+ si_info_t *sii;
+ uint32 origsba;
+ sbconfig_t *sb;
+
+ sii = SI_INFO(sih);
+ sb = REGS2SB(sii->curmap);
+
+ sii->pub.socirev = (R_SBREG(sii, &sb->sbidlow) & SBIDL_RV_MASK) >> SBIDL_RV_SHIFT;
+
+ /* Save the current core info and validate it later till we know
+ * for sure what is good and what is bad.
+ */
+ origsba = _sb_coresba(sii);
+
+ /* scan all SB(s) starting from SI_ENUM_BASE */
+ sii->numcores = _sb_scan(sii, origsba, regs, 0, SI_ENUM_BASE, 1);
+}
+
+/*
+ * This function changes logical "focus" to the indicated core;
+ * must be called with interrupts off.
+ * Moreover, callers should keep interrupts off during switching out of and back to d11 core
+ */
+void *
+sb_setcoreidx(si_t *sih, uint coreidx)
+{
+ si_info_t *sii;
+
+ sii = SI_INFO(sih);
+
+ if (coreidx >= sii->numcores)
+ return (NULL);
+
+ /*
+ * If the user has provided an interrupt mask enabled function,
+ * then assert interrupts are disabled before switching the core.
+ */
+ ASSERT((sii->intrsenabled_fn == NULL) || !(*(sii)->intrsenabled_fn)((sii)->intr_arg));
+
+ sii->curmap = _sb_setcoreidx(sii, coreidx);
+ sii->curidx = coreidx;
+
+ return (sii->curmap);
+}
+
+/* This function changes the logical "focus" to the indicated core.
+ * Return the current core's virtual address.
+ */
+static void *
+_sb_setcoreidx(si_info_t *sii, uint coreidx)
+{
+ uint32 sbaddr = sii->coresba[coreidx];
+ void *regs;
+
+ switch (BUSTYPE(sii->pub.bustype)) {
+ case SI_BUS:
+ /* map new one */
+ if (!sii->regs[coreidx]) {
+ sii->regs[coreidx] = REG_MAP(sbaddr, SI_CORE_SIZE);
+ ASSERT(GOODREGS(sii->regs[coreidx]));
+ }
+ regs = sii->regs[coreidx];
+ break;
+
+ case PCI_BUS:
+ /* point bar0 window */
+ OSL_PCI_WRITE_CONFIG(sii->osh, PCI_BAR0_WIN, 4, sbaddr);
+ regs = sii->curmap;
+ break;
+
+ case PCMCIA_BUS: {
+ uint8 tmp = (sbaddr >> 12) & 0x0f;
+ OSL_PCMCIA_WRITE_ATTR(sii->osh, PCMCIA_ADDR0, &tmp, 1);
+ tmp = (sbaddr >> 16) & 0xff;
+ OSL_PCMCIA_WRITE_ATTR(sii->osh, PCMCIA_ADDR1, &tmp, 1);
+ tmp = (sbaddr >> 24) & 0xff;
+ OSL_PCMCIA_WRITE_ATTR(sii->osh, PCMCIA_ADDR2, &tmp, 1);
+ regs = sii->curmap;
+ break;
+ }
+ case SPI_BUS:
+ case SDIO_BUS:
+ /* map new one */
+ if (!sii->regs[coreidx]) {
+ sii->regs[coreidx] = (void *)(uintptr)sbaddr;
+ ASSERT(GOODREGS(sii->regs[coreidx]));
+ }
+ regs = sii->regs[coreidx];
+ break;
+
+
+ default:
+ ASSERT(0);
+ regs = NULL;
+ break;
+ }
+
+ return regs;
+}
+
+/* Return the address of sbadmatch0/1/2/3 register */
+static volatile uint32 *
+sb_admatch(si_info_t *sii, uint asidx)
+{
+ sbconfig_t *sb;
+ volatile uint32 *addrm;
+
+ sb = REGS2SB(sii->curmap);
+
+ switch (asidx) {
+ case 0:
+ addrm = &sb->sbadmatch0;
+ break;
+
+ case 1:
+ addrm = &sb->sbadmatch1;
+ break;
+
+ case 2:
+ addrm = &sb->sbadmatch2;
+ break;
+
+ case 3:
+ addrm = &sb->sbadmatch3;
+ break;
+
+ default:
+ SI_ERROR(("%s: Address space index (%d) out of range\n", __FUNCTION__, asidx));
+ return 0;
+ }
+
+ return (addrm);
+}
+
+/* Return the number of address spaces in current core */
+int
+sb_numaddrspaces(si_t *sih)
+{
+ si_info_t *sii;
+ sbconfig_t *sb;
+
+ sii = SI_INFO(sih);
+ sb = REGS2SB(sii->curmap);
+
+ /* + 1 because of enumeration space */
+ return ((R_SBREG(sii, &sb->sbidlow) & SBIDL_AR_MASK) >> SBIDL_AR_SHIFT) + 1;
+}
+
+/* Return the address of the nth address space in the current core */
+uint32
+sb_addrspace(si_t *sih, uint asidx)
+{
+ si_info_t *sii;
+
+ sii = SI_INFO(sih);
+
+ return (sb_base(R_SBREG(sii, sb_admatch(sii, asidx))));
+}
+
+/* Return the size of the nth address space in the current core */
+uint32
+sb_addrspacesize(si_t *sih, uint asidx)
+{
+ si_info_t *sii;
+
+ sii = SI_INFO(sih);
+
+ return (sb_size(R_SBREG(sii, sb_admatch(sii, asidx))));
+}
+
+
+/* do buffered registers update */
+void
+sb_commit(si_t *sih)
+{
+ si_info_t *sii;
+ uint origidx;
+ uint intr_val = 0;
+
+ sii = SI_INFO(sih);
+
+ origidx = sii->curidx;
+ ASSERT(GOODIDX(origidx));
+
+ INTR_OFF(sii, intr_val);
+
+ /* switch over to chipcommon core if there is one, else use pci */
+ if (sii->pub.ccrev != NOREV) {
+ chipcregs_t *ccregs = (chipcregs_t *)si_setcore(sih, CC_CORE_ID, 0);
+ ASSERT(ccregs != NULL);
+
+ /* do the buffer registers update */
+ W_REG(sii->osh, &ccregs->broadcastaddress, SB_COMMIT);
+ W_REG(sii->osh, &ccregs->broadcastdata, 0x0);
+ } else
+ ASSERT(0);
+
+ /* restore core index */
+ sb_setcoreidx(sih, origidx);
+ INTR_RESTORE(sii, intr_val);
+}
+
+void
+sb_core_disable(si_t *sih, uint32 bits)
+{
+ si_info_t *sii;
+ volatile uint32 dummy;
+ sbconfig_t *sb;
+
+ sii = SI_INFO(sih);
+
+ ASSERT(GOODREGS(sii->curmap));
+ sb = REGS2SB(sii->curmap);
+
+ /* if core is already in reset, just return */
+ if (R_SBREG(sii, &sb->sbtmstatelow) & SBTML_RESET)
+ return;
+
+ /* if clocks are not enabled, put into reset and return */
+ if ((R_SBREG(sii, &sb->sbtmstatelow) & (SICF_CLOCK_EN << SBTML_SICF_SHIFT)) == 0)
+ goto disable;
+
+ /* set target reject and spin until busy is clear (preserve core-specific bits) */
+ OR_SBREG(sii, &sb->sbtmstatelow, SBTML_REJ);
+ dummy = R_SBREG(sii, &sb->sbtmstatelow);
+ OSL_DELAY(1);
+ SPINWAIT((R_SBREG(sii, &sb->sbtmstatehigh) & SBTMH_BUSY), 100000);
+ if (R_SBREG(sii, &sb->sbtmstatehigh) & SBTMH_BUSY)
+ SI_ERROR(("%s: target state still busy\n", __FUNCTION__));
+
+ if (R_SBREG(sii, &sb->sbidlow) & SBIDL_INIT) {
+ OR_SBREG(sii, &sb->sbimstate, SBIM_RJ);
+ dummy = R_SBREG(sii, &sb->sbimstate);
+ OSL_DELAY(1);
+ SPINWAIT((R_SBREG(sii, &sb->sbimstate) & SBIM_BY), 100000);
+ }
+
+ /* set reset and reject while enabling the clocks */
+ W_SBREG(sii, &sb->sbtmstatelow,
+ (((bits | SICF_FGC | SICF_CLOCK_EN) << SBTML_SICF_SHIFT) |
+ SBTML_REJ | SBTML_RESET));
+ dummy = R_SBREG(sii, &sb->sbtmstatelow);
+ OSL_DELAY(10);
+
+ /* don't forget to clear the initiator reject bit */
+ if (R_SBREG(sii, &sb->sbidlow) & SBIDL_INIT)
+ AND_SBREG(sii, &sb->sbimstate, ~SBIM_RJ);
+
+disable:
+ /* leave reset and reject asserted */
+ W_SBREG(sii, &sb->sbtmstatelow, ((bits << SBTML_SICF_SHIFT) | SBTML_REJ | SBTML_RESET));
+ OSL_DELAY(1);
+}
+
+/* reset and re-enable a core
+ * inputs:
+ * bits - core specific bits that are set during and after reset sequence
+ * resetbits - core specific bits that are set only during reset sequence
+ */
+void
+sb_core_reset(si_t *sih, uint32 bits, uint32 resetbits)
+{
+ si_info_t *sii;
+ sbconfig_t *sb;
+ volatile uint32 dummy;
+
+ sii = SI_INFO(sih);
+ ASSERT(GOODREGS(sii->curmap));
+ sb = REGS2SB(sii->curmap);
+
+ /*
+ * Must do the disable sequence first to work for arbitrary current core state.
+ */
+ sb_core_disable(sih, (bits | resetbits));
+
+ /*
+ * Now do the initialization sequence.
+ */
+
+ /* set reset while enabling the clock and forcing them on throughout the core */
+ W_SBREG(sii, &sb->sbtmstatelow,
+ (((bits | resetbits | SICF_FGC | SICF_CLOCK_EN) << SBTML_SICF_SHIFT) |
+ SBTML_RESET));
+ dummy = R_SBREG(sii, &sb->sbtmstatelow);
+ OSL_DELAY(1);
+
+ if (R_SBREG(sii, &sb->sbtmstatehigh) & SBTMH_SERR) {
+ W_SBREG(sii, &sb->sbtmstatehigh, 0);
+ }
+ if ((dummy = R_SBREG(sii, &sb->sbimstate)) & (SBIM_IBE | SBIM_TO)) {
+ AND_SBREG(sii, &sb->sbimstate, ~(SBIM_IBE | SBIM_TO));
+ }
+
+ /* clear reset and allow it to propagate throughout the core */
+ W_SBREG(sii, &sb->sbtmstatelow,
+ ((bits | resetbits | SICF_FGC | SICF_CLOCK_EN) << SBTML_SICF_SHIFT));
+ dummy = R_SBREG(sii, &sb->sbtmstatelow);
+ OSL_DELAY(1);
+
+ /* leave clock enabled */
+ W_SBREG(sii, &sb->sbtmstatelow, ((bits | SICF_CLOCK_EN) << SBTML_SICF_SHIFT));
+ dummy = R_SBREG(sii, &sb->sbtmstatelow);
+ OSL_DELAY(1);
+}
+
+/*
+ * Set the initiator timeout for the "master core".
+ * The master core is defined to be the core in control
+ * of the chip and so it issues accesses to non-memory
+ * locations (Because of dma *any* core can access memeory).
+ *
+ * The routine uses the bus to decide who is the master:
+ * SI_BUS => mips
+ * JTAG_BUS => chipc
+ * PCI_BUS => pci or pcie
+ * PCMCIA_BUS => pcmcia
+ * SDIO_BUS => pcmcia
+ *
+ * This routine exists so callers can disable initiator
+ * timeouts so accesses to very slow devices like otp
+ * won't cause an abort. The routine allows arbitrary
+ * settings of the service and request timeouts, though.
+ *
+ * Returns the timeout state before changing it or -1
+ * on error.
+ */
+
+#define TO_MASK (SBIMCL_RTO_MASK | SBIMCL_STO_MASK)
+
+uint32
+sb_set_initiator_to(si_t *sih, uint32 to, uint idx)
+{
+ si_info_t *sii;
+ uint origidx;
+ uint intr_val = 0;
+ uint32 tmp, ret = 0xffffffff;
+ sbconfig_t *sb;
+
+ sii = SI_INFO(sih);
+
+ if ((to & ~TO_MASK) != 0)
+ return ret;
+
+ /* Figure out the master core */
+ if (idx == BADIDX) {
+ switch (BUSTYPE(sii->pub.bustype)) {
+ case PCI_BUS:
+ idx = sii->pub.buscoreidx;
+ break;
+ case JTAG_BUS:
+ idx = SI_CC_IDX;
+ break;
+ case PCMCIA_BUS:
+ case SDIO_BUS:
+ idx = si_findcoreidx(sih, PCMCIA_CORE_ID, 0);
+ break;
+ case SI_BUS:
+ idx = si_findcoreidx(sih, MIPS33_CORE_ID, 0);
+ break;
+ default:
+ ASSERT(0);
+ }
+ if (idx == BADIDX)
+ return ret;
+ }
+
+ INTR_OFF(sii, intr_val);
+ origidx = si_coreidx(sih);
+
+ sb = REGS2SB(sb_setcoreidx(sih, idx));
+
+ tmp = R_SBREG(sii, &sb->sbimconfiglow);
+ ret = tmp & TO_MASK;
+ W_SBREG(sii, &sb->sbimconfiglow, (tmp & ~TO_MASK) | to);
+
+ sb_commit(sih);
+ sb_setcoreidx(sih, origidx);
+ INTR_RESTORE(sii, intr_val);
+ return ret;
+}
+
+uint32
+sb_base(uint32 admatch)
+{
+ uint32 base;
+ uint type;
+
+ type = admatch & SBAM_TYPE_MASK;
+ ASSERT(type < 3);
+
+ base = 0;
+
+ if (type == 0) {
+ base = admatch & SBAM_BASE0_MASK;
+ } else if (type == 1) {
+ ASSERT(!(admatch & SBAM_ADNEG)); /* neg not supported */
+ base = admatch & SBAM_BASE1_MASK;
+ } else if (type == 2) {
+ ASSERT(!(admatch & SBAM_ADNEG)); /* neg not supported */
+ base = admatch & SBAM_BASE2_MASK;
+ }
+
+ return (base);
+}
+
+uint32
+sb_size(uint32 admatch)
+{
+ uint32 size;
+ uint type;
+
+ type = admatch & SBAM_TYPE_MASK;
+ ASSERT(type < 3);
+
+ size = 0;
+
+ if (type == 0) {
+ size = 1 << (((admatch & SBAM_ADINT0_MASK) >> SBAM_ADINT0_SHIFT) + 1);
+ } else if (type == 1) {
+ ASSERT(!(admatch & SBAM_ADNEG)); /* neg not supported */
+ size = 1 << (((admatch & SBAM_ADINT1_MASK) >> SBAM_ADINT1_SHIFT) + 1);
+ } else if (type == 2) {
+ ASSERT(!(admatch & SBAM_ADNEG)); /* neg not supported */
+ size = 1 << (((admatch & SBAM_ADINT2_MASK) >> SBAM_ADINT2_SHIFT) + 1);
+ }
+
+ return (size);
+}