/**
* @file
*
* @ingroup Virtex4MMU
*
* @brief Implementation of routines to manipulate the PPC 405 mmu.
*
* Since this is a real-time OS we want to stay away from
* software TLB replacement.
*/
/*
* Authorship
* ----------
* This software was created by
* Till Straumann <strauman@slac.stanford.edu>, 2005-2007,
* Stanford Linear Accelerator Center, Stanford University.
* and was transcribed for the PPC 405 by
* R. Claus <claus@slac.stanford.edu>, 2012,
* Stanford Linear Accelerator Center, Stanford University,
*
* Acknowledgement of sponsorship
* ------------------------------
* This software was produced by
* the Stanford Linear Accelerator Center, Stanford University,
* under Contract DE-AC03-76SFO0515 with the Department of Energy.
*
* Government disclaimer of liability
* ----------------------------------
* Neither the United States nor the United States Department of Energy,
* nor any of their employees, makes any warranty, express or implied, or
* assumes any legal liability or responsibility for the accuracy,
* completeness, or usefulness of any data, apparatus, product, or process
* disclosed, or represents that its use would not infringe privately owned
* rights.
*
* Stanford disclaimer of liability
* --------------------------------
* Stanford University makes no representations or warranties, express or
* implied, nor assumes any liability for the use of this software.
*
* Stanford disclaimer of copyright
* --------------------------------
* Stanford University, owner of the copyright, hereby disclaims its
* copyright and all other rights in this software. Hence, anyone may
* freely use it for any purpose without restriction.
*
* Maintenance of notices
* ----------------------
* In the interest of clarity regarding the origin and status of this
* SLAC software, this and all the preceding Stanford University notices
* are to remain affixed to any copy or derivative of this software made
* or distributed by the recipient and are to be affixed to any copy of
* software made or distributed by the recipient that contains a copy or
* derivative of this software.
*
* ------------------ SLAC Software Notices, Set 4 OTT.002a, 2004 FEB 03
*/
/* 405 MSR definitions; note that there are *substantial* differences
* compared to classic powerpc; in particular, IS/DS are *different*
* from IR/DR.
*
* Also: To disable/enable all external interrupts, CE and EE must both be
* controlled.
*/
#include <rtems.h>
#include <rtems/bspIo.h>
#include <rtems/powerpc/powerpc.h>
#include <inttypes.h>
#include <stdio.h>
#include <bsp/mmu.h>
#ifdef DEBUG
#define STATIC
#else
#define STATIC static
#endif
bsp_tlb_entry_t* bsp_mmu_cache = 0;
/* Since it is likely that these routines are used during
* early initialization when stdio is not available yet
* we provide a helper that resorts to 'printk()'
*/
static void
myprintf(FILE *f, char *fmt, ...)
{
va_list ap;
va_start(ap, fmt);
if (!f || !_impure_ptr->__sdidinit) {
/* Might be called at an early stage when stdio is not yet initialized. */
vprintk(fmt,ap);
} else {
vfprintf(f,fmt,ap);
}
va_end(ap);
}
void
bsp_mmu_dump_cache(FILE *f)
{
bsp_tlb_idx_t idx;
if ( !bsp_mmu_cache ) {
myprintf(stderr,"MMU TLB cache not initialized\n");
return;
}
for ( idx=0; idx<NTLBS; idx++ ) {
bsp_tlb_entry_t *tlb = bsp_mmu_cache + idx;
if ( !tlb->hi.v )
continue;
myprintf(f, "#%2i: EA 0x%08x .. 0x%08x, TID 0x%03x, EU0 0x%01x\n",
idx,
tlb->hi.epn << 10,
(tlb->hi.epn << 10) + (1024<<(2*tlb->hi.size))-1,
tlb->id.tid,
tlb->hi.att);
myprintf(f, " PA 0x%08"PRIx32" .. 0x%08"PRIx32", PERM 0x%03x, WIMG 0x%02x\n",
tlb->lo.rpn << 10,
(tlb->lo.rpn << 10) + (1024<<(2*tlb->hi.size))-1,
tlb->lo.perm,
tlb->lo.wimg);
}
}
static void
fetch(bsp_tlb_idx_t key, bsp_tlb_entry_t* tlb)
{
register uint32_t tmp;
__asm__ volatile ("mfpid %[tmp] \n\t"
"stw %[tmp],0(%[tlb]) \n\t"
"tlbrehi %[tmp],%[key] \n\t"
"stw %[tmp],4(%[tlb]) \n\t"
"tlbrelo %[tmp],%[key] \n\t"
"stw %[tmp],8(%[tlb]) \n\t"
"sync \n\t"
: [tmp]"=&r"(tmp)
: [key]"r"(key),
[tlb]"b"(tlb)
);
}
static void
store(bsp_tlb_idx_t key, bsp_tlb_entry_t* tlb)
{
register uint32_t tmp;
__asm__ volatile ("lwz %[tmp],0(%[tlb]) \n\t"
"mtpid %[tmp] \n\t"
"lwz %[tmp],4(%[tlb]) \n\t"
"tlbwehi %[tmp],%[key] \n\t"
"lwz %[tmp],8(%[tlb]) \n\t"
"tlbwelo %[tmp],%[key] \n\t"
: [tmp]"=&r"(tmp)
: [tlb]"b"(tlb),
[key]"r"(key)
);
}
static void
commit(void)
{
__asm__ volatile("isync \n\t");
}
/*
* Read a TLB entry from the hardware and store the current settings in the
* bsp_mmu_cache[] structure.
*
* The routine can perform this operation quietly or
* print information to a file.
*
* 'idx': which TLB entry to access.
* 'quiet': perform operation silently (no info printed)
* if nonzero.
* 'f': open FILE where to print information. May be
* NULL in which case 'stdout' is used.
*
* RETURNS:
* 0: success; TLB entry is VALID
* +1: success but TLB entry is INVALID
* < 0: error (-1: invalid argument)
* (-2: driver not initialized)
*/
int
bsp_mmu_update(bsp_tlb_idx_t key, bool quiet, FILE *f)
{
rtems_interrupt_level lvl;
bsp_tlb_entry_t* tlb;
bsp_tlb_idx_t idx;
idx = key;
if ( idx < 0 || idx > NTLBS-1 )
return -1;
if (!bsp_mmu_cache)
return -2;
tlb = bsp_mmu_cache + idx;
rtems_interrupt_disable(lvl);
fetch(idx, tlb);
rtems_interrupt_enable(lvl);
if ( tlb->hi.v ) {
if ( !quiet ) {
/*
"TLB Entry # 0 spans EA range 0x00000000 - 0x00000000
"Mapping: VA [TID 0x00 / EPN 0x00000] -> RPN 0x00000"
"Size: TSIZE 0x0 (4^sz KB = 000000 KB = 0x00000000 B)
"Attributes: PERM 0x00 (ex/wr/zsel) WIMG 0x00 EU0 0x0"
*/
myprintf(f,
"TLB Entry # %2d spans EA range 0x%08x - 0x%08x\n",
idx,
(tlb->hi.epn << 10),
(tlb->hi.epn << 10) + (1024<<(2*tlb->hi.size)) - 1
);
myprintf(f,
"Mapping: VA [TID 0x%02x / EPN 0x%05x] -> RPN 0x%05"PRIx32"\n",
tlb->id.tid, tlb->hi.epn, tlb->lo.rpn
);
myprintf(f,
"Size: TSIZE 0x%x (4^sz KB = %6d KB = 0x%08x B)\n",
tlb->hi.size, (1<<(2*tlb->hi.size)), (1024<<(2*tlb->hi.size))
);
myprintf(f,
"Attributes: PERM 0x%02x (ex/wr/zsel) WIMG 0x%02x EU0 0x%01x\n",
tlb->lo.perm, tlb->lo.wimg, tlb->hi.att
);
}
} else {
if ( !quiet ) {
myprintf(f,
"TLB Entry # %2d <OFF> (size 0x%x = 0x%xb)\n",
idx, tlb->hi.size, (1024<<(2*tlb->hi.size))
);
}
return 1;
}
return 0;
}
/* Initialize cache. Should be done only once although this is not enforced.
*
* RETURNS: zero on success, nonzero on error; in this case the driver will
* refuse to change TLB entries (other than disabling them).
*/
int
bsp_mmu_initialize()
{
static bsp_tlb_entry_t mmu_cache[NTLBS];
bsp_tlb_entry_t* tlb = mmu_cache; /* Should malloc if it's not too early */
rtems_interrupt_level lvl;
bsp_tlb_idx_t idx;
rtems_interrupt_disable(lvl);
for (idx=0; idx<NTLBS; tlb++, idx++)
{
fetch(idx, tlb);
}
rtems_interrupt_enable(lvl);
bsp_mmu_cache = mmu_cache;
return 0;
}
/* Find first free TLB entry by examining all entries' valid bit. The first
* entry without the valid bit set is returned.
*
* RETURNS: A free TLB entry number. -1 if no entry can be found.
*/
bsp_tlb_idx_t
bsp_mmu_find_first_free()
{
bsp_tlb_idx_t idx;
bsp_tlb_entry_t entry;
for (idx=0; idx<NTLBS; idx++) {
register uint32_t tmp;
__asm__ volatile ("tlbrehi %[tmp],%[idx] \n\t"
"stw %[tmp],4(%[tlb]) \n\t" /* entry.hi */
"sync \n\t"
: [tmp]"=&r"(tmp)
: [idx]"r"(idx),
[tlb]"b"(&entry)
: "memory"
);
if (!(entry.hi.v))
break;
}
return (idx < NTLBS) ? idx : -1;
}
/*
* Write TLB entry (can also be used to disable an entry).
*
* The routine checks against the cached data in
* bsp_mmu_cache[] to prevent the user from generating
* overlapping entries.
*
* 'idx': TLB entry # to manipulate
* 'ea': Effective address (must be page aligned)
* 'pa': Physical address (must be page aligned)
* 'sz': Page size selector; page size is
* 1024 * 2^(2*sz) bytes.
* 'sz' may also be one of the following:
* - page size in bytes ( >= 1024 ); the selector
* value is then computed by this routine.
* However, 'sz' must be a valid page size
* or -1 will be returned.
* - a value < 0 to invalidate/disable the
* TLB entry.
* 'flgs': Page's little-endian & user-defined flags, permissions and attributes
* 'tid': Translation ID
*
* RETURNS: 0 on success, nonzero on error:
*
* >0: requested mapping would overlap with
* existing mapping in other entry. Return
* value gives conflicting entry + 1; i.e.,
* if a value of 4 is returned then the request
* conflicts with existing mapping in entry 3.
* -1: invalid argument
* -3: driver not initialized (or initialization failed).
* <0: other error
*/
bsp_tlb_idx_t
bsp_mmu_write(bsp_tlb_idx_t idx, uint32_t ea, uint32_t pa, uint sz,
uint32_t flgs, uint32_t tid)
{
bsp_tlb_entry_t tlb;
uint32_t msk;
bsp_tlb_idx_t lkup;
rtems_interrupt_level lvl;
if ( sz >= 1024 ) {
/* Assume they literally specify a size */
msk = sz;
sz = 0;
while ( msk != (1024u<<(2*sz)) ) {
if ( ++sz > 7 ) {
return -1;
}
}
/* OK, acceptable */
}
msk = sz > 0 ? (1024u<<(2*sz)) - 1 : 0;
if ( !bsp_mmu_cache && sz > 0 ) {
myprintf(stderr,"MMU driver not initialized; refusing to enable any entry\n");
return -3;
}
if ( (ea & msk) || (pa & msk) ) {
myprintf(stderr,"Misaligned EA (%08x) or PA (%08x) (mask is %08x)\n", ea, pa, msk);
return -1;
}
if ( idx < 0 || idx > NTLBS-1 )
return -1;
if ( sz > 7 ) {
myprintf(stderr,"Invalid size %u = %08x = %u KB\n", sz, 1024u<<(2*sz), (1024u<<(2*sz))/1024);
return -1;
}
if ( sz >=0 ) {
lkup = bsp_mmu_match(ea, sz, tid);
if ( lkup < -1 ) {
/* some error */
return lkup;
}
if ( (lkup >= 0) && (lkup != idx) && (bsp_mmu_cache[lkup].hi.v != 0) ) {
myprintf(stderr,"TLB #%i overlaps with requested mapping\n", lkup);
bsp_mmu_update( lkup, false, stderr);
return lkup+1;
}
}
/* OK to proceed */
tlb.id.tid = tid;
tlb.hi.v = sz >= 0;
tlb.hi.size = sz;
tlb.hi.epn = (ea & (0xfffffc00 << (sz + sz))) >> 10;
tlb.lo.rpn = (pa & (0xfffffc00 << (sz + sz))) >> 10;
tlb.hi.att = (flgs & MMU_M_ATTR) >> MMU_V_ATTR;
tlb.lo.perm = (flgs & MMU_M_PERM) >> MMU_V_PERM;
tlb.lo.wimg = (flgs & MMU_M_PROP) >> MMU_V_PROP;
rtems_interrupt_disable(lvl);
store(idx, &tlb);
commit();
rtems_interrupt_enable(lvl);
/* update cache */
bsp_mmu_update(idx, true, 0);
return 0;
}
/*
* Check if a ea/sz/tid mapping overlaps with an existing entry.
*
* 'ea': The Effective Address to match against
* 'sz': The 'logarithmic' size selector; the page size
* is 1024*2^(2*sz).
* 'tid': The TID to match against
*
* RETURNS:
* >= 0: index of the TLB entry that already provides a mapping
* which overlaps within the ea range.
* -1: SUCCESS (no conflicting entry found)
* <=-2: ERROR (invalid input)
*/
bsp_tlb_idx_t
bsp_mmu_match(uint32_t ea, int sz, uint32_t tid)
{
bsp_tlb_idx_t idx;
uint32_t m,a;
bsp_tlb_entry_t* tlb;
if ( sz < 0 || sz > 7 )
return -4;
sz = (1024<<(2*sz));
if ( !bsp_mmu_cache ) {
/* cache not initialized */
return -3;
}
if ( ea & (sz-1) ) {
/* misaligned ea */
return -2;
}
for ( idx=0, tlb=bsp_mmu_cache; idx<NTLBS; idx++, tlb++ ) {
if ( ! tlb->hi.v )
continue;
if ( tlb->id.tid && tlb->id.tid != tid )
continue;
/* TID matches a valid entry */
m = (1024<<(2*tlb->hi.size)) - 1;
/* calculate starting address of this entry */
a = tlb->hi.epn << 10;
if ( ea <= a + m && ea + sz -1 >= a ) {
/* overlap */
return idx;
}
}
return -1;
}
/* Find TLB index that maps 'ea/tid' combination
*
* 'ea': Effective address to match against
* 'tid': The TID to match against
*
* RETURNS: index 'key' which indicates whether
* the mapping was found.
*
* On error (no mapping) -1 is returned.
*/
bsp_tlb_idx_t
bsp_mmu_find(uint32_t ea, uint32_t tid)
{
rtems_interrupt_level lvl;
register uint32_t pid;
register bsp_tlb_idx_t idx;
register int failure;
rtems_interrupt_disable(lvl);
__asm__ volatile ("mfpid %[pid] \n\t" /* Save PID */
"mtpid %[tid] \n\t"
"tlbsx. %[idx],0,%[ea] \n\t" /* Failure changes the index reg randomly. */
"mfcr %[failure] \n\t"
"mtpid %[pid] \n\t" /* Restore PID */
: [pid]"=r"(pid),
[idx]"=&r"(idx),
[failure]"=&r"(failure)
: [tid]"r"(tid),
[ea]"r"(ea)
: "cc"
);
rtems_interrupt_enable(lvl);
return (failure & 0x20000000) ? idx : -1;
}
/* Mark TLB entry as invalid ('disabled').
*
* 'key': TLB entry (index).
*
* RETURNS: zero on success, nonzero on error (TLB unchanged).
*
* NOTE: If a TLB entry is disabled the associated
* entry in bsp_mmu_cache[] is also
* marked as disabled.
*/
int
bsp_mmu_invalidate(bsp_tlb_idx_t key)
{
bsp_tlb_idx_t k0;
rtems_interrupt_level lvl;
bsp_tlb_entry_t tlb;
uint32_t msr;
/* Minimal guard against bad key */
if ( key < 0 || key > NTLBS-1 )
return -1;
_CPU_MSR_GET(msr);
/* While address translation is enabled... */
if (msr & (PPC_MSR_IR | PPC_MSR_DR))
{
/* Must not invalidate page 0 which holds vectors, text etc... */
k0 = bsp_mmu_find(0, 0);
if ( -1 == k0 ) {
myprintf(stderr,"No mapping for address 0 found\n");
return -2;
}
/* NOTE: we assume PID is ignored */
if ( k0 == key ) {
myprintf(stderr,"Cannot invalidate page holding address 0 (always needed)\n");
return -3;
}
}
rtems_interrupt_disable(lvl);
fetch(key, &tlb);
/* Invalidate old entries */
tlb.hi.v = 0;
store(key, &tlb);
commit();
/* update cache */
bsp_mmu_cache[ key ].hi.v = tlb.hi.v;
rtems_interrupt_enable(lvl);
return 0;
}