/*
- * Copyright (c) 2003 Apple Computer, Inc. All rights reserved.
+ * Copyright (c) 2003-2005 Apple Computer, Inc. All rights reserved.
*
- * @APPLE_LICENSE_HEADER_START@
+ * @APPLE_OSREFERENCE_LICENSE_HEADER_START@
*
- * The contents of this file constitute Original Code as defined in and
- * are subject to the Apple Public Source License Version 1.1 (the
- * "License"). You may not use this file except in compliance with the
- * License. Please obtain a copy of the License at
- * http://www.apple.com/publicsource and read it before using this file.
+ * This file contains Original Code and/or Modifications of Original Code
+ * as defined in and that are subject to the Apple Public Source License
+ * Version 2.0 (the 'License'). You may not use this file except in
+ * compliance with the License. The rights granted to you under the License
+ * may not be used to create, or enable the creation or redistribution of,
+ * unlawful or unlicensed copies of an Apple operating system, or to
+ * circumvent, violate, or enable the circumvention or violation of, any
+ * terms of an Apple operating system software license agreement.
*
- * This Original Code and all software distributed under the License are
- * distributed on an "AS IS" basis, WITHOUT WARRANTY OF ANY KIND, EITHER
+ * Please obtain a copy of the License at
+ * http://www.opensource.apple.com/apsl/ and read it before using this file.
+ *
+ * The Original Code and all software distributed under the License are
+ * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
* EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
* INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
- * FITNESS FOR A PARTICULAR PURPOSE OR NON-INFRINGEMENT. Please see the
- * License for the specific language governing rights and limitations
- * under the License.
+ * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
+ * Please see the License for the specific language governing rights and
+ * limitations under the License.
*
- * @APPLE_LICENSE_HEADER_END@
+ * @APPLE_OSREFERENCE_LICENSE_HEADER_END@
*/
-#define ASSEMBLER
#include <sys/appleapiopts.h>
#include <ppc/asm.h> // EXT, LEXT
#include <machine/cpu_capabilities.h>
#include <machine/commpage.h>
-#define USEC_PER_SEC 1000000
-
-
/* The red zone is used to move data between GPRs and FPRs: */
#define rzTicks -8 // elapsed ticks since timestamp (double)
// in user mode, usually without having to make a system call. We do not deal with
// the timezone. The kernel maintains the following values in the comm page:
//
-// _COMM_PAGE_TIMESTAMP = a BSD-style pair of uint_32's for seconds and microseconds
+// _COMM_PAGE_TIMESTAMP = 64 bit seconds timestamp
//
// _COMM_PAGE_TIMEBASE = the timebase at which the timestamp was valid
//
0:
lwz r5,_COMM_PAGE_TIMEBASE+0(0) // r5,r6 = TBR at timestamp
lwz r6,_COMM_PAGE_TIMEBASE+4(0)
- lwz r7,_COMM_PAGE_TIMESTAMP+0(0) // r7 = timestamp seconds
- lwz r8,_COMM_PAGE_TIMESTAMP+4(0) // r8 = timestamp microseconds
+ lwz r8,_COMM_PAGE_TIMESTAMP+4(0) // r8 = timestamp 32 bit seconds
lfd f1,_COMM_PAGE_SEC_PER_TICK(0)
1:
mftbu r10 // r10,r11 = current timebase
lwz r0,_COMM_PAGE_TIMEBASE+0(0) // then load data a 2nd time
lwz r12,_COMM_PAGE_TIMEBASE+4(0)
- lwz r2,_COMM_PAGE_TIMESTAMP+0(0)
lwz r9,_COMM_PAGE_TIMESTAMP+4(0)
cmplw cr6,r5,r0 // did we read a consistent set?
cmplw cr7,r6,r12
beq- 3f // timestamp is disabled so return bad status
- cmplw cr1,r2,r7
cmplw cr5,r9,r8
crand cr0_eq,cr6_eq,cr7_eq
- crand cr1_eq,cr1_eq,cr5_eq
- crand cr0_eq,cr0_eq,cr1_eq
+ crand cr0_eq,cr0_eq,cr5_eq
bne- 0b // loop until we have a consistent set of data
subfc r11,r6,r11 // compute ticks since timestamp
lwz r9,_COMM_PAGE_2_TO_52(0) // get exponent for (2**52)
subfe r10,r5,r10 // complete 64-bit subtract
- lfd f2,_COMM_PAGE_2_TO_52(0) // f3 <- (2**52)
+ lfd f2,_COMM_PAGE_2_TO_52(0) // f2 <- (2**52)
srwi. r0,r10,2 // if more than 2**34 ticks have elapsed...
stw r11,rzTicks+4(r1) // store elapsed ticks into red zone
or r10,r10,r9 // convert long-long in (r10,r11) into double
bne- 3f // ...call kernel to reprime timestamp
stw r10,rzTicks(r1) // complete double
- lis r12,hi16(USEC_PER_SEC)
- ori r12,r12,lo16(USEC_PER_SEC)
-
+
+ mffs f7
+ mtfsfi 7,1
lfd f3,rzTicks(r1) // get elapsed ticks since timestamp + 2**52
fsub f4,f3,f2 // subtract 2**52 and normalize
fmul f5,f4,f1 // f5 <- elapsed seconds since timestamp
fmul f6,f6,f3 // f6 <- fractional elapsed useconds
fctiwz f6,f6 // convert useconds to integer
stfd f6,rzUSeconds(r1) // store useconds into red zone
+ mtfsf 0xff,f7
lwz r5,rzSeconds+4(r1) // r5 <- seconds since timestamp
- lwz r6,rzUSeconds+4(r1) // r6 <- useconds since timestamp
- add r7,r7,r5 // add elapsed seconds to timestamp seconds
- add r8,r8,r6 // ditto useconds
+ lwz r7,rzUSeconds+4(r1) // r7 <- useconds since timestamp
+ add r6,r8,r5 // add elapsed seconds to timestamp seconds
- cmplw r8,r12 // r8 >= USEC_PER_SEC ?
- blt 2f // no
- addi r7,r7,1 // add 1 to secs
- sub r8,r8,r12 // subtract USEC_PER_SEC from usecs
-2:
- stw r7,0(r3) // store secs//usecs into user's timeval
- stw r8,4(r3)
+ stw r6,0(r3) // store secs//usecs into user's timeval
+ stw r7,4(r3)
li r3,0 // return success
blr
3: // too long since last timestamp or this code is disabled
// ***************************************
//
// This routine is called in 32-bit mode on 64-bit processors. A timeval is a struct of
-// a long seconds and int useconds, so it's size depends on mode.
+// a long seconds and int useconds, so its size depends on mode.
gettimeofday_g5_32: // int gettimeofday(timeval *tp);
0:
ld r6,_COMM_PAGE_TIMEBASE(0) // r6 = TBR at timestamp
- ld r8,_COMM_PAGE_TIMESTAMP(0) // r8 = timestamp (seconds,useconds)
+ ld r8,_COMM_PAGE_TIMESTAMP(0) // r8 = timestamp (seconds)
lfd f1,_COMM_PAGE_SEC_PER_TICK(0)
mftb r10 // r10 = get current timebase
lwsync // create a barrier if MP (patched to NOP if UP)
std r11,rzTicks(r1) // put ticks in redzone where we can "lfd" it
bne-- 3f // timestamp too old, so reprime
+ mffs f7
+ mtfsfi 7,1
lfd f3,rzTicks(r1) // get elapsed ticks since timestamp (fixed pt)
fcfid f4,f3 // float the tick count
fmul f5,f4,f1 // f5 <- elapsed seconds since timestamp
fmul f6,f6,f3 // f6 <- fractional elapsed useconds
fctidz f6,f6 // convert useconds to fixed pt integer
stfd f6,rzUSeconds(r1) // store useconds into red zone
+ mtfsf 0xff,f7
- lis r12,hi16(USEC_PER_SEC) // r12 <- 10**6
- srdi r7,r8,32 // extract seconds from doubleword timestamp
lwz r5,rzSeconds+4(r1) // r5 <- seconds since timestamp
- ori r12,r12,lo16(USEC_PER_SEC)
- lwz r6,rzUSeconds+4(r1) // r6 <- useconds since timestamp
- add r7,r7,r5 // add elapsed seconds to timestamp seconds
- add r8,r8,r6 // ditto useconds
+ lwz r7,rzUSeconds+4(r1) // r7 <- useconds since timestamp
+ add r6,r8,r5 // add elapsed seconds to timestamp seconds
- cmplw r8,r12 // r8 >= USEC_PER_SEC ?
- blt 2f // no
- addi r7,r7,1 // add 1 to secs
- sub r8,r8,r12 // subtract USEC_PER_SEC from usecs
-2:
- stw r7,0(r3) // store secs//usecs into user's timeval
- stw r8,4(r3)
+ stw r6,0(r3) // store secs//usecs into user's timeval
+ stw r7,4(r3)
li r3,0 // return success
blr
3: // too long since last timestamp or this code is disabled
// ***************************************
//
// This routine is called in 64-bit mode on 64-bit processors. A timeval is a struct of
-// a long seconds and int useconds, so it's size depends on mode.
+// a long seconds and int useconds, so its size depends on mode.
gettimeofday_g5_64: // int gettimeofday(timeval *tp);
0:
ld r6,_COMM_PAGE_TIMEBASE(0) // r6 = TBR at timestamp
- ld r8,_COMM_PAGE_TIMESTAMP(0) // r8 = timestamp (seconds,useconds)
+ ld r8,_COMM_PAGE_TIMESTAMP(0) // r8 = timestamp (seconds)
lfd f1,_COMM_PAGE_SEC_PER_TICK(0)
mftb r10 // r10 = get current timebase
lwsync // create a barrier if MP (patched to NOP if UP)
std r11,rzTicks(r1) // put ticks in redzone where we can "lfd" it
bne-- 3f // timestamp too old, so reprime
+ mffs f7
+ mtfsfi 7,1
lfd f3,rzTicks(r1) // get elapsed ticks since timestamp (fixed pt)
fcfid f4,f3 // float the tick count
fmul f5,f4,f1 // f5 <- elapsed seconds since timestamp
fmul f6,f6,f3 // f6 <- fractional elapsed useconds
fctidz f6,f6 // convert useconds to fixed pt integer
stfd f6,rzUSeconds(r1) // store useconds into red zone
+ mtfsf 0xff,f7
- lis r12,hi16(USEC_PER_SEC) // r12 <- 10**6
- srdi r7,r8,32 // extract seconds from doubleword timestamp
lwz r5,rzSeconds+4(r1) // r5 <- seconds since timestamp
- ori r12,r12,lo16(USEC_PER_SEC)
- lwz r6,rzUSeconds+4(r1) // r6 <- useconds since timestamp
- add r7,r7,r5 // add elapsed seconds to timestamp seconds
- add r8,r8,r6 // ditto useconds
+ lwz r7,rzUSeconds+4(r1) // r7 <- useconds since timestamp
+ add r6,r8,r5 // add elapsed seconds to timestamp seconds
- cmplw r8,r12 // r8 >= USEC_PER_SEC ?
- blt 2f // no
- addi r7,r7,1 // add 1 to secs
- sub r8,r8,r12 // subtract USEC_PER_SEC from usecs
-2:
- std r7,0(r3) // store secs//usecs into user's timeval
- stw r8,8(r3)
+ std r6,0(r3) // store secs//usecs into user's timeval
+ stw r7,8(r3)
li r3,0 // return success
blr
3: // too long since last timestamp or this code is disabled