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1152 lines
46 KiB
Plaintext
1152 lines
46 KiB
Plaintext
;
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; File: TimeMgr.a
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;
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; Contains: The Macintosh OS Time Manager
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;
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; Written by: Gary G. Davidian
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;
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; Copyright: © 1988-1993 by Apple Computer, Inc., all rights reserved.
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;
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; Change History (most recent first):
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;
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; <SM5> 11/9/93 KW added some eieioSTP macros. Only expands for CygnusX1 ROM
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; <SM4> 11/12/92 PN Get rid of ≥ 020 conditionals for ROM builds
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; <3> 9/10/92 AEK Roll in new _microseconds and PrimeTime fix from Quicktime
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; code for _microseconds was already there, so just remove old one
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; <2> 3/27/92 JSM Merge in Philip’s change: Export Labels for Patch roll-in.
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; <1> • Pre-SuperMario comments follow •
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; <9> 2/12/92 JSM Moved this file to TimeMgr folder, keeping all the old
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; revisions.
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; <8> 11/16/91 DTY Checked in Wayne Meretzky’s new version of __MicroSeconds,
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; conditionalized for TheFuture.
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; <7> 9/9/91 JSM Cleanup header.
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; <6> 9/22/90 dba Break some routines into separate PROCs so they can be cut back
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; in the linked patch version. Also change conditionals so the the
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; linked patch version of the Time Mgr. is universal (does not
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; assume 68020 or existence of the Power Mgr. chip). This file is
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; now used as the source both of the Time Mgr. in ROM and of the
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; Time Mgr. patches.
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; <5> 9/19/90 BG Removed <3>. 040s are behaving more reliably now.
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; <4> 7/25/90 GGD Added support for the _MicroSeconds trap which returns a 64 bit
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; Microsecond counter which is usefull for timestamping and
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; timing. Deleted some Eclipse NOPs which would not be assembled
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; for 68040s
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; <3> 6/20/90 CCH Added some NOPs for flaky 68040's.
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; <2> 1/12/90 CCH Added include of “HardwarePrivateEqu.a”.
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; <1.4> 11/13/89 MSH Pmgr equates now in record format.
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; <1.3> 2/23/89 GGD Stored the underflow retry adjustment constant in RAM to allow
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; better patching flexability. On systems with PowerManagers,
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; switch into fast mode in FreezeTime, and restore mode in
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; ThawTime, to reduce drift in the time critical section, and to
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; prevent a potential loop in the underflow path.
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; <1.2> 1/30/89 GGD Added new features for BigBang and the new ROMs. This includes
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; support for extended time manager tasks, and improves accuracy
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; and reduces drift even more.
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; <1.1> 11/10/88 CCH Fixed Header.
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; <1.0> 11/9/88 CCH Adding to EASE.
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; <1.4> 10/16/88 GGD Changed resolution to 20µs with range of 1 day. Improved long
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; term accuracy, and added initialization code to do runtime
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; timings to make it processor speed independent. Coded around the
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; bug in Rockwell VIA timers. Removed machine specific
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; conditionals in favor of the "Cpu" equate. Improved conversion
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; constants for better accuracy. Went back to having state in the
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; system heap.
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; <•1.3> 9/23/88 CCH Got rid of inc.sum.d and empty nFiles
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; <1.2> 8/16/88 GGD Added InitTimeMgr initialization routine. Changed usage of
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; TimeVars, is now head of active list, no state in SysHeap.
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; <1.1> 8/5/88 GGD Completely re-written. Lots of bug fixes and new features.
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; 7/26/88 GGD Completely re-wrote the Time Manager, replacing all of the code
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; and comments from the old version. This version fixes numerous
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; bugs, and adds several new features.
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; <1.0> 2/10/88 BBM Adding file for the first time into EASE…
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;
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TITLE 'Time Manager - Macintosh Time Manager'
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;_______________________________________________________________________
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;
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; Macintosh Time Manager.
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;
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; Written by Gary G. Davidian, July 26, 1988.
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;
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;_______________________________________________________________________
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print off
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load 'StandardEqu.d'
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include 'HardwarePrivateEqu.a'
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print on,nomdir
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if forROM then
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use68020Opcodes: equ 1
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machine MC68020
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else
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use68020Opcodes: equ 0
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machine MC68020 ; some 020 opcodes in stuff that is run-time determined
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endif
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; globals in system heap (same RECORD in TimeMgrPatch.a; move it to an equate file if you like)
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TimeMgrPrivate record 0,increment ; time manager private storage
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ActivePtr ds.l 1 ; pointer to soonest active request
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TimerAdjust ds.b 1 ; number of VIA ticks used loading timer
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TimerLowSave ds.b 1 ; low byte of VIA timer from last FreezeTime <4>
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RetryAdjust ds.w 1 ; number of via ticks for underflow retry
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CurrentTime ds.l 1 ; number of virtual ticks since boot
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BackLog ds.l 1 ; number of virtual ticks of ready tasks
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**** NOTE: The ordering of the following 4 fields must not change (FreezeTime Depends on it) <4>
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HighUSecs ds.l 1 ; high 32 bits of microsecond count <4>
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LowUSecs ds.l 1 ; low 32 bits of microsecond count <4>
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FractUSecs ds.w 1 ; 16 bit fractional microsecond count <4>
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CurTimeThresh ds.w 1 ; CurrentTime threshold for updating µsec count <4>
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**** end of order dependent fields <4>
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PrivateSize equ *-TimeMgrPrivate ; size of this record
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endr
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USecsInc equ $FFF2E035 ; 65522.8758µsec (16.16 fixed point) <4>
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ThreshInc equ 3208 ; = 3208 internal ticks <4>
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eject
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;_______________________________________________________________________
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;
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; The time manager maintains a linked list of tasks that are waiting for
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; their timer to run out. The list is ordered by expiration time, with
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; ActivePtr pointing to the task with the earliest timeout. The tmCount
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; field of the each task on the list contains the number of virtual ticks
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; a task must wait after the task in front of it expires. For the task
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; at the head of the list, this is the time to wait after the VIA timer
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; expires.
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; The TimerAdjust variable is used to account for the number of VIA ticks
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; that go by while we are trying to load a new timer value. This is
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; computed at runtime, so that it is processor speed independent.
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;
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;_______________________________________________________________________
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;_______________________________________________________________________
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;
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; User visible changes since Inside Macintosh Vol. 4 was published.
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;
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; 1) tmCount field is a LONGINT, not an INTEGER (documentation error).
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;
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; 2) RmvTime, and PrimeTime now correctly return a result code (noErr)
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; in register D0. Numerous other bugs that were not as visible have
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; also been fixed.
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;
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; 3) Time can be represented in microseconds as well as milliseconds.
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; Negative values represent negated microseconds. (Although microseconds
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; can be specified, the actual resolution of the time manager is
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; currently closer to 20 microseconds).
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;
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; 4) The high order bit of qType is now a flag to indicate that the
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; task timer is active. Set by PrimeTime, cleared when time expires
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; or RmvTime is called. Initialized cleared by InsTime.
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;
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; 5) tmAddr may be set to zero to indicate that no completion routine
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; should be called. (The flag mentioned above may be used to determine
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; if the time has expired).
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;
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; 6) The completion routine is now passed a pointer (in register A1) to
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; the TMTask record associated with it. This makes it more usable
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; under Multi-Finder.
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;
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; 7) When RmvTime is called on an active task, the tmCount field will
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; be returned with the amount of remaining time that had not been
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; used (in negative microseconds, or positive milliseconds). If
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; the task had already expired, tmCount will contain zero. This
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; allows the Time Manager to be used to compute elapsed times, which
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; is useful for performance measurments.
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;
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; 8) In order to provide better resolution than 1 millisecond, the maximum
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; delay time was reduced from about 24 days, to currently about 1 day.
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; Larger delay times may still be specified to PrimeTime, but they will
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; be converted to the largest possible time instead.
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;
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; 9) Support for Extended Time Manager Tasks has been added, _InsXTime is
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; used to install them. The new field tmWakeUp is used by the TimeMgr
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; to remember when a _PrimeTime is supposed to expire. When _PrimeTime
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; is called, if tmWakeUp is non-zero, then the new wakeup time will be
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; relative to the old tmWakeUp, instead of relative to the current time.
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; This allows for drift free fixed frequency timing tasks, which is needed
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; by the Sound Manager.
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;
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;_______________________________________________________________________
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TITLE 'Time Manager - Equates'
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TaskActiveBit equ 7 ; high bit of QType word is active flag
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ExtendedTmTaskBit equ 6 ; indicates an extended TmTask record
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T2IntBit equ 5 ; VIER/VIFR bit num for VIA Timer 2
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;_______________________________________________________________________
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;
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; Representations of time in the Time Manager.
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;
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; Time is represented externally in two ways, both are stored in a longword,
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; if the value is positive, it represents milliseconds, and if it is
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; negative, it represents negated microseconds. This representation is used
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; as the delay time input to PrimeTime, and as the unused remaining time
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; output by RmvTime.
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;
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; The VIA1 Timer2 is the 16 bit hardware timer used by the time manager.
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; On all current machines, it decrements at a rate of 783360 Hz, and
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; generates an interrupt, and keeps counting, when it counts through zero.
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; This provides resolution of 1.276 µsec, and a range of 83.660 msec.
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;
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; Internally the time manager represents time as a virtual unsigned 36 bit
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; VIA timer, which gives a range of about 1 day. However, since we only
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; have 32 bits to store time in, we drop the low 4 bits of the timer,
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; which reduces the resolution by a factor of 16 to 20.425 µsec.
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;
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; Converting between the external and internal forms of time is done by
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; multiplying by the proper fixed point constants, and shifting the binary
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; point of the 64 bit result to get just the integer portion of the result.
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; The computation of the 32 bit conversion constants requires 64 bit
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; intermediate results, and unfortunatly the assembler only provides 32
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; bit expression evaluation, so the proper constants were computed with
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; a 64 bit hex caculator, and hard coded here (yuck!). These are not
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; "Magic Numbers", the formula for computing them is provided, so that
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; they may be re-computed if any of the parameters ever change.
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;
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;_______________________________________________________________________
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TicksPerSec equ 783360 ; VIA Timer clock rate
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TickScale equ 4 ; Internal time is VIA ticks >> TickScale
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MsToIntFractBits equ 26 ; number of fraction bits in 64 bit result
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*MsToInternal equ ((TicksPerSec<<(MsToIntFractBits-TickScale))\
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+999)/1000
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MsToInternal equ $C3D70A3E ; msec to internal time multiplier
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UsToIntFractBits equ 32 ; number of fraction bits in 64 bit result
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*UsToInternal equ ((TicksPerSec<<(UsToIntFractBits-TickScale))\
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+999999)/1000000
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UsToInternal equ $0C88A47F ; µsec to internal time multiplier
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IntToMsFractBits equ 32 ; number of fraction bits in 64 bit result
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*InternalToMs equ ((1000<<(IntToMsFractBits+TickScale))\
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+TicksPerSec-1)/TicksPerSec
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InternalToMs equ $053A8FE6 ; internal time to msec multiplier
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IntToUsFractBits equ 27 ; number of fraction bits in 64 bit result
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*InternalToUs equ ((1000000<<(IntToUsFractBits+TickScale))\
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+TicksPerSec-1)/TicksPerSec
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InternalToUs equ $A36610BC ; internal time to µsec multiplier
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macro ; Macro for interfacing with the MultAndMerge routine.
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Convert &Multiplier,&FractionBits
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bsr.s MultAndMerge ; input/output is D0
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dc.l &Multiplier ; conversion multiplier
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if &eval(&FractionBits)=32 then
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dc.l 0 ; merge mask (low 32 bits all fraction)
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else
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dc.l -1<<&FractionBits ; merge mask (some low bits not fraction)
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rol.l #32-&FractionBits,d0 ; position result after merge
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endif
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endm
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TITLE 'Time Manager - Remove Time Manager Task'
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TimeMgr proc export
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export __InsTime ; Install Time Manager Task
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export __RmvTime ; Remove Time Manager Task
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export __PrimeTime ; Initiate Time Manager Task Delay
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import FreezeTime ; Stop timer
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entry ThawTime ; Start timer (used by InitTimeMgr)
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entry Timer2Int ; Interrupt handler (vector set up by InitTimeMgr)
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with TimeMgrPrivate
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;_______________________________________________________________________
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;
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; Routine: RmvTime
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; Inputs: A0 - pointer to Time Manager Task to remove
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; Outputs: D0 - error code (noErr)
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; Destroys: none
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; Calls: FreezeTime, ThawTime, MultAndMerge
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; Called by: OsTrap dispatcher
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;
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; Function: Removes the specified Time Manager Task from the control
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; of the Time Manager. If PrimeTime had been previously
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; called for this task, and the time has not expired yet,
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; the amount of unused time will be returned in the tmCount
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; field. The unused time will be represented in negated
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; microseconds, if it is not too large to fit within 32 bits
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; otherwise it will be represented in positive milliseconds.
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; Additionally, the TaskActiveBit of the QType field will
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; be cleared to indicate that the timer task is no longer
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; active.
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;
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;_______________________________________________________________________
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export AfterFreezeTimeInRmvTime
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__RmvTime ; a0-a2/d1-d2 saved by dispatcher
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move.l d3,-(sp) ; save d3 also
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jsr FreezeTime ; setup to manipulate time queue
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AfterFreezeTimeInRmvTime
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moveq.l #0,d2 ; D2 : total time remaining
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lea ActivePtr-Qlink(a2),a1 ; A1 : previous := head
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@SearchLoop move.l QLink(a1),d0 ; D0 : next := previous.QLink
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beq.s @NotActive ; if end, not an active task
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exg.l a1,d0 ; A1 : previous := next (save old previous)
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move.l tmCount(a1),d1 ; get delay between previous and next
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add.l d1,d2 ; add to total time remaining
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cmpa.l a0,a1 ; is this the one to remove?
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bne.s @SearchLoop ; loop until it is found
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movea.l d0,a1 ; A1 : old previous
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move.l QLink(a0),d0 ; get successor to removee
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move.l d0,QLink(a1) ; previous points to successor
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beq.s @Removed ; if no successor, don't adjust time
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movea.l d0,a1 ; get pointer to successor
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add.l d1,tmCount(a1) ; pass removees time to successor
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@Removed move.l d2,d0 ; setup total time remaining in D0
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@NotActive ; at this point D0 is total time remaining
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sub.l BackLog(a2),d0 ; don't count the backlog
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bhs.s @GotRemaining ; if still time remaining
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moveq.l #0,d0 ; otherwise, all backlog, return zero time
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@GotRemaining
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bsr.w ThawTime ; done manipulating time queue
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movea.l d0,a1 ; save a copy of internal time
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convert InternalToUs,IntToUsFractBits ; convert internal to µsec
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neg.l d0 ; µsecs are passed negated
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bmi.s @ConvertDone ; if it fits we're done
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move.l a1,d0 ; restore copy of internal time
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convert InternalToMs,IntToMsFractBits ; convert internal to msec
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@ConvertDone
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move.l d0,tmCount(a0) ; return unused delay time
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move.l (sp)+,d3 ; restore saved d3
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moveq.l #0,d1 ; clear all of the flags
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; (fall in) bra.s __InsTime ; mark task inactive, return with success
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TITLE 'Time Manager - Install Time Manager Task'
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;_______________________________________________________________________
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;
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; Routine: InsTime
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; Inputs: A0 - pointer to Time Manager Task to install
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; Outputs: D0 - error code (noErr)
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; Destroys: none
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; Calls: none
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; Called by: OsTrap dispatcher, RmvTime (falls into)
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;
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; Function: Initializes the fields of a Time Manager Task, to indicate
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; that it is inactive.
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;
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; NOTE: This routine is documented in Inside Machintosh Vol 4., and
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; was used by the old Time Manager to install the task on the
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; Time Manager queue. In this version of the Time Manager, the
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; queue only contains active tasks, so installation is done by
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; _PrimeTime now.
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;
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;_______________________________________________________________________
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__InsTime ; a0-a2/d1-d2 saved by dispatcher
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moveq.l #$1F,d0 ; mask to clear flag bits in QType
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and.b QType(a0),d0 ; clear the flags
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andi.w #$0600,d1 ; isolate 2 flag bits from trap word
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lsr.w #4,d1 ; position the 3 flag bits (high bit zeroed)
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or.b d1,d0 ; merge into QType high byte
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move.b d0,QType(a0) ; save flags, mark the task initially inactive
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moveq.l #noErr,d0 ; return success
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rts ; all done
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TITLE 'Time Manager - Multiply 32 by 32'
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;_______________________________________________________________________
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;
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; Routine: MultAndMerge
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; Inputs: D0 - 32 bit multiplier
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; (return PC) - 32 bit multiplicand
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; (return PC+4) - 32 bit merge mask
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; Outputs: D0 - upper 32 bits of 64 bit product, merged with selected
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; bits of lower 32 bits of 64 bit product as specified by
|
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; merge mask.
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; Destroys: A2, D1, D2, D3
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; Calls: none
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; Called by: PrimeTime, RmvTime
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;
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; Function: Performs a 32 by 32 bit multiply producing a 64 bit result.
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; Same function as the 68020 MULU.L D0,D0:D1 instruction.
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; The 64 bit product is then merged into a 32 bit result, by
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; using a merge mask which has bits set corresponding to which
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; bits in the low 32 bits of the product are to be merged into
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; the corresponding bit positions of the high 32 bits of the
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; product. If the bits specified in the merge mask an non-zero
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; in the high 32 bits of the product, then a result of all ones
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; will be returned to indicate overflow.
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; This routine is used to perform fixed point multiplication,
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; where the position of the implied binary point may vary.
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;
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; Note: D0 = A B, D1 := C D. Product is derived as follows.
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; B*D
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; + B*C
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; + A*D
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; + A*C
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;
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;_______________________________________________________________________
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macro
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mulud0d168000
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; result in d0, d1
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; trashes d2, d3
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move.l d4,-(sp) ; preserve d4
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move.l d1,d2 ; D2 := C D
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move.l d1,d3 ; D3 := C D
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mulu.w d0,d1 ; D1 := B*D
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swap d1 ;
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swap d3 ; D3 := D C
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mulu.w d0,d3 ; D3 := B*C
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swap d0 ; D0 := B A
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ext.l d0 ; D0 := A (sign extended)
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move.w d0,d4 ; D4 := A
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beq.s @ShortMul ; if A is zero, skip next 2 mults
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mulu.w d2,d4 ; D4 := A*D
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swap d2 ; D2 := D C
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mulu.w d2,d0 ; D0 := A*C
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add.l d4,d3 ; D3 := A*D + B*C
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clr.w d4 ;
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addx.w d4,d4 ; D4 := carry from A*D + B*C
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@ShortMul add.w d3,d1 ; add middle product to low product
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swap d1 ; D1 := low 32 bits of product
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move.w d4,d3 ; D3 := copy saved carry
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swap d3 ; D3 := high 17 bits of A*D + B*C
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addx.l d3,d0 ; D0 := high 32 bits of product
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move.l (sp)+,d4 ; restore d4
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endm
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export MultAndMerge
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MultAndMerge
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movea.l (sp)+,a2 ; pop return address
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move.l (a2)+,d1 ; get multiplicand
|
||
|
||
if forROM then
|
||
mulu.l d0,d0:d1 ; d0:d1 := d0*d1
|
||
else
|
||
|
||
tst.b CPUFlag ; are we on a machine with long multiply?
|
||
bz.s @noLongMultiply
|
||
mulu.l d0,d0:d1 ; d0:d1 := d0*d1
|
||
bra.s @didMultiply
|
||
@noLongMultiply
|
||
mulud0d168000 ; d0:d1 := d0*d1 (trash d2, d3)
|
||
@didMultiply
|
||
|
||
endif
|
||
|
||
move.l (a2)+,d2 ; get merge mask
|
||
beq.s @Done ; if zero, result in d0 is correct
|
||
and.l d2,d1 ; get the non-fraction bits from d1
|
||
add.l d0,d2 ; corresponding bits in d0 should be zero
|
||
subx.l d2,d2 ; d2 = -1 if d0 overflowed, else zero
|
||
or.l d2,d0 ; return d0 = -1 if overflow
|
||
or.l d1,d0 ; merge bits from d1 into d0
|
||
@Done jmp (a2) ; return to code after constant list
|
||
TITLE 'Time Manager - Prime Time Manager Task'
|
||
|
||
;_______________________________________________________________________
|
||
;
|
||
; Routine: PrimeTime
|
||
; Inputs: A0 - pointer to Time Manager Task to schedule
|
||
; D0 - [long] if >= 0, Delay Time in positive milliseconds
|
||
; if < 0, Delay Time in negated microseconds
|
||
; Outputs: D0 - error code (noErr)
|
||
; Destroys: none
|
||
; Calls: FreezeTime, ThawTime, MultAndMerge
|
||
; Called by: OsTrap dispatcher
|
||
;
|
||
; Function: Schedules a Time Manager Task to run after the specified
|
||
; Delay Time expires. The Delay Time may be specified in
|
||
; milliseconds, in which case, it must be a positive number,
|
||
; or it can be specified in microseconds, in which case, it
|
||
; must be negated first.
|
||
; Additionally, the TaskActiveBit of the QType field will
|
||
; be set to indicate that the timer task is currently active,
|
||
; and will be cleared when the specified time has expired.
|
||
;
|
||
; NOTE: The Time Manager does not support delay times as long as the
|
||
; maximum number of milliseconds that can be passed to this call.
|
||
; If delay time specified is too large, then the maximum delay
|
||
; time supported will be used instead.
|
||
;
|
||
;_______________________________________________________________________
|
||
export AfterFreezeTimeInPrimeTime
|
||
; a0-a2/d1-d2 saved by dispatcher
|
||
__PrimeTime move.l d3,-(sp) ; save d3 also
|
||
|
||
;_______________________________________________________________________
|
||
;
|
||
; start of code from Quicktime patch
|
||
; attempts to keep backlog from becoming very large
|
||
;
|
||
|
||
btst.b #ExtendedTmTaskBit, qType(a0)
|
||
beq.s @notExtended
|
||
lea 3+tmReserved(a0), a1
|
||
tst.l tmWakeUp(a0)
|
||
beq.s @startNew
|
||
tst.l d0
|
||
beq.s @checkCount
|
||
@startNew:
|
||
clr.b (a1)
|
||
bra.s @notExtended
|
||
@checkCount:
|
||
addq.b #1, (a1)
|
||
bpl.s @notExtended
|
||
bclr.b #ExtendedTmTaskBit, qType(a0)
|
||
@notExtended:
|
||
|
||
;
|
||
; end of code from Quicktime patch
|
||
;
|
||
;_______________________________________________________________________
|
||
|
||
tst.l d0 ; see if +msec or -µsec
|
||
bpl.s @msec ; µsec are negated, msec pos
|
||
|
||
@usec neg.l d0 ; get positive number of µsecs
|
||
convert UsToInternal,UsToIntFractBits ; convert µsec to internal
|
||
bra.s @ConvertDone ; join common code
|
||
|
||
@msec convert MsToInternal,MsToIntFractBits ; convert msec to internal
|
||
@ConvertDone
|
||
jsr FreezeTime ; setup to manipulate time queue
|
||
AfterFreezeTimeInPrimeTime
|
||
bset.b #TaskActiveBit,QType(a0); mark the task as active
|
||
bne.s @AlreadyActive ; if already on the queue don't touch it
|
||
|
||
btst.b #ExtendedTmTaskBit,QType(a0) ; check for extended tmTask
|
||
beq.s @AddToActive ; of standard tmTask, nothing special to do
|
||
|
||
move.l CurrentTime(a2),d2 ; get current time
|
||
move.l tmWakeUp(a0),d1 ; get wake time from last _PrimeTime
|
||
beq.s @SetNewWakeTime ; if not set, delay relative to CurrentTime
|
||
sub.l d2,d1 ; d1 := time since/till last wakeup
|
||
bpl.s @WakeInFuture ; if time till, just add to it
|
||
add.l d1,d0 ; subtract time since from desired delay
|
||
bcs.s @SetNewWakeTime ; if time still positive, use it
|
||
|
||
add.l d0,d2 ; new wakeup := old + delay
|
||
bne.s @WakeupInPast ; zero is special wakeup value, don't allow it
|
||
moveq.l #1,d2 ; use one instead of zero
|
||
@WakeupInPast
|
||
move.l d2,tmWakeUp(a0) ; update wakeup.
|
||
move.l d0,d1 ; remember negated delay
|
||
sub.l d0,BackLog(a2) ; remember how late we are
|
||
moveq.l #0,d0 ; for negative delay, use zero
|
||
lea ActivePtr-Qlink(a2),a1 ; A1 : previous := head
|
||
move.l QLink(a1),d2 ; D2 : next := previous.QLink
|
||
beq.s @Insert ; if empty, make it the head
|
||
exg.l a1,d2 ; A1 : previous := next (save old previous)
|
||
sub.l d1,tmCount(a1) ; add backlog of new task to old first task
|
||
exg.l a1,d2 ; restore prior previous and next ptrs
|
||
bra.s @Insert ; add it to the active list
|
||
|
||
@WakeInFuture
|
||
add.l d1,d0 ; add time till desired delay
|
||
@SetNewWakeTime
|
||
add.l d0,d2 ; new wakeup := old + delay
|
||
bne.s @StoreWakeup ; zero is special wakeup value, don't allow it
|
||
moveq.l #1,d2 ; use one instead of zero
|
||
@StoreWakeup
|
||
move.l d2,tmWakeUp(a0) ; update wakeup.
|
||
|
||
@AddToActive
|
||
add.l BackLog(a2),d0 ; run it after all pending tasks
|
||
lea ActivePtr-Qlink(a2),a1 ; A1 : previous := head
|
||
@SearchLoop move.l QLink(a1),d2 ; D2 : next := previous.QLink
|
||
beq.s @Insert ; if end, insert after previous
|
||
exg.l a1,d2 ; A1 : previous := next (save old previous)
|
||
move.l tmCount(a1),d1 ; get delay between previous and next
|
||
sub.l d1,d0 ; subtract from our delay time
|
||
bhs.s @SearchLoop ; loop until our delay between prev and next
|
||
|
||
add.l d1,d0 ; d0 := delay between previous and new
|
||
sub.l d0,d1 ; d1 := delay between new and next
|
||
move.l d1,tmCount(a1) ; adjust next task delay time
|
||
exg.l a1,d2 ; restore prior previous and next ptrs
|
||
|
||
@Insert move.l d2,QLink(a0) ; new task followed by next task
|
||
move.l d0,tmCount(a0) ; setup new task delay time
|
||
move.l a0,QLink(a1) ; previous task followed by new task
|
||
|
||
@AlreadyActive
|
||
bsr.s ThawTime ; done manipulating time queue
|
||
move.l (sp)+,d3 ; restore saved d3
|
||
moveq.l #noErr,d0 ; return success
|
||
rts ; all done
|
||
TITLE 'Time Manager - Timer 2 Interrupt Handler'
|
||
|
||
;_______________________________________________________________________
|
||
;
|
||
; Routine: Timer2Int
|
||
; Inputs: none
|
||
; Outputs: none
|
||
; Destroys: A0, A1, A2, A3, D0, D1, D2, D3
|
||
; Calls: FreezeTime, ThawTime, tmAddr service routine.
|
||
; Called by: VIA 1 system interrupt handler
|
||
;
|
||
; Function: Services the timer interrupt, and calls the service routine
|
||
; if task at the head of the list has expired, or continues
|
||
; it running if more time remaining. If nothing on timer
|
||
; list, just disables the timer.
|
||
;
|
||
; NOTE: The TaskActiveBit in the QType field will be cleared when the
|
||
; task timer expires so that applications can poll the timer for
|
||
; completion. If the tmAddr field is zero, the service routine
|
||
; will not be called. When the service routine is called, A0 points
|
||
; to the service routine itself, and A1 points to the expired
|
||
; Time Manager task.
|
||
;
|
||
;_______________________________________________________________________
|
||
|
||
export AfterFreezeTimeInTimer2Int
|
||
Timer2Int ; a0-a3/d0-d3 saved by IntHand
|
||
jsr FreezeTime ; stop the timer, adjust time remaining <4>
|
||
AfterFreezeTimeInTimer2Int
|
||
move.l ActivePtr(a2),d0 ; get pointer to first active timer task
|
||
beq.s ThawTime ; if nothing in queue, just exit
|
||
|
||
movea.l d0,a0 ; A0 := pointer to timer task
|
||
tst.l tmCount(a0) ; see if timer expired
|
||
bne.s ThawTime ; if not, let it continue running
|
||
|
||
move.l QLink(a0),ActivePtr(a2) ; remove it from the active list
|
||
bclr.b #TaskActiveBit,QType(a0); mark the task as completed
|
||
bsr.s ThawTime ; start next timer running
|
||
|
||
move.l tmAddr(a0),d0 ; get service routine address
|
||
beq.s @NoHandler ; if no service routine, just exit
|
||
movea.l a0,a1 ; A1 := pointer to queue element
|
||
movea.l d0,a0 ; A0 := address of service routine
|
||
jmp (a0) ; return through the service routine
|
||
@NoHandler rts ; all done
|
||
TITLE 'Time Manager - Thaw Time'
|
||
|
||
;_______________________________________________________________________
|
||
;
|
||
; Routine: ThawTime
|
||
; Inputs: A2 - ptr to TimeMgrPrivate
|
||
; D3.hi - saved SR (interrupt priority)
|
||
; D3.lo - value read from the low byte of the VIA timer masked
|
||
; to virtual ticks.
|
||
; Outputs: none
|
||
; Destroys: D1, D2, A1, A2
|
||
; Calls: none
|
||
; Called by: RmvTime, PrimeTime, Timer2Int
|
||
;
|
||
; Function: Starts timer, based upon head of timer list, adjusts
|
||
; time remaining for head of list. Restores interrupt
|
||
; priority level.
|
||
;
|
||
;_______________________________________________________________________
|
||
|
||
ThawTime move.l #$0000FFFF>>TickScale,d2; max range (internal form) of VIA timer
|
||
add.b TimerAdjust(a2),d3 ; add in the timer loading overhead
|
||
move.l ActivePtr(a2),d1 ; check pointer to first active timer task
|
||
beq.s @StartTimer ; if no tasks, just start timer with max
|
||
|
||
movea.l d1,a1 ; point to head of active list
|
||
move.l tmCount(a1),d1 ; get time remaining for head
|
||
sub.l BackLog(a2),d1 ; remove as much backlog as possible
|
||
bhs.s @NoBacklog ; if tmCount >= BackLog
|
||
neg.l d1 ; BackLog - tmCount
|
||
move.l d1,BackLog(a2) ; update backlog
|
||
moveq.l #0,d1 ; run immediatly
|
||
bra.s @FindMax ; update timer
|
||
@NoBackLog clr.l BackLog(a2) ; no backlog remaining
|
||
@FindMax cmp.l d2,d1 ; check remaining time against max
|
||
bhs.s @UseMax ; if remaining >= max, use the max instead
|
||
move.l d1,d2 ; otherwise, use time remaining
|
||
@UseMax sub.l d2,d1 ; remaining := remaining - timer value
|
||
move.l d1,tmCount(a1) ; update time remaining
|
||
|
||
@StartTimer movea.l VIA,a1 ; get base address of VIA1
|
||
lea vT2C(a1),a1 ; point to low byte of counter for speed
|
||
move.w d3,d1 ; save copy of adjusted original low byte
|
||
@Retry add.l d2,CurrentTime(a2) ; update current time
|
||
lsl.w #TickScale,d2 ; convert internal form to VIA form
|
||
lea vT2CH-vT2C(a1),a2 ; point to high byte for speed
|
||
|
||
; *** Begining of time critical section
|
||
eieioSTP
|
||
sub.b vT2C-vT2C(a1),d3 ; see how many ticks of overhead used
|
||
eieioSTP
|
||
sub.w d3,d2 ; subtract out overhead ticks
|
||
bls.s @Underflow ; if less than 1 tick, fix it up
|
||
|
||
; VIAs from Rockwell (which we have been shipping for several years) and possibly
|
||
; other vendors have a bug. If you load the counter high byte in the same clock
|
||
; as the old counter value is counting through zero, when the new counter value
|
||
; counts through zero the VIA will not generate an interrupt. To work around this
|
||
; "feature", we first load a dummy non-zero value into the high byte of the counter,
|
||
; and then load the value we really wanted. This should allow enough time to
|
||
; guarantee that it will not be counting through zero at the time we load the real
|
||
; counter value. This fixes the "AppleShare server hang problem".
|
||
|
||
eieioSTP
|
||
move.b d1,vT2CH-vT2CH(a2) ; *** ROCKWELL VIA FIX, DON'T REMOVE ***
|
||
eieioSTP
|
||
move.b d2,vT2C-vT2C(a1) ; setup timer low byte latch
|
||
eieioSTP
|
||
if use68020Opcodes then ; 68020 shifting is fast
|
||
lsr.w #8,d2 ; get high byte of time
|
||
eieioSTP
|
||
move.b d2,vT2CH-vT2CH(a2) ; load high byte of timer, start timer
|
||
eieioSTP
|
||
else ; 68000 shifting is slower than memory
|
||
move.w d2,-(sp) ; get high byte of time
|
||
eieioSTP
|
||
move.b (sp)+,vT2CH-vT2CH(a2) ; load high byte of timer, start timer
|
||
eieioSTP
|
||
endif
|
||
; *** End of time critical section
|
||
|
||
if forROM then
|
||
if hasPowerMgr then
|
||
movea.l PMgrBase,a2 ; PMgr gobals.
|
||
cmpi.b #1,PMgrRec.saveSpeedo(a2) ; see if we need to be idle
|
||
bne.s @RemainFast ; if not, remain running at fast speed.
|
||
tst.w Clock1M ; return processor to idle.
|
||
@RemainFast
|
||
endif
|
||
endif
|
||
|
||
swap d3 ; get saved sr from high word
|
||
move.w d3,sr ; restore interrupt priority level
|
||
rts ; all done
|
||
|
||
@Underflow add.w d2,d3 ; recompute original delay value
|
||
sub.b d3,d1 ; adjust initial timer low byte
|
||
neg.w d2 ; make excess time positive
|
||
movea.l TimeVars,a2 ; point to TimeMgrPrivate
|
||
add.w RetryAdjust(a2),d2 ; round up before conversion, add in some extra time
|
||
lsr.w #TickScale,d2 ; convert it to virtual ticks
|
||
add.l d2,BackLog(a2) ; remember how negative we are for next freeze
|
||
move.w d1,d3 ; restore initial timer low byte
|
||
bra.s @Retry ; now go reload the timer
|
||
endproc
|
||
TITLE 'Time Manager - Read 64 bit MicroSecond counter'
|
||
;_______________________________________________________________________ <4>
|
||
;
|
||
; Routine: MicroSeconds
|
||
; Inputs: none
|
||
; Outputs: A0/D0 - 64 bit counter (A0=High, D0=Low)
|
||
; Destroys: none
|
||
; Calls: none
|
||
; Called by: OsTrap dispatcher
|
||
;
|
||
; Function: Returns the value of the 64 bit microsecond counter, which
|
||
; is useful for timestamping.
|
||
;
|
||
;_______________________________________________________________________
|
||
|
||
__MicroSeconds: proc export ; a0-a2/d1-d2 saved by dispatcher
|
||
|
||
with TimeMgrPrivate
|
||
|
||
movem.l d3-d5,-(sp) ; save some others as well
|
||
movea.l VIA,a1 ; get base address of VIA1
|
||
movea.l TimeVars,a0 ; point to TimeMgrPrivate
|
||
moveq.l #0,d1 ; d1 := 0
|
||
|
||
move.w sr,-(sp)
|
||
ori.w #$0700,sr ; disable interrupts
|
||
|
||
; First we'll read the VIA timer. This is complicated by three
|
||
; bits of trivia. First, if an interrupt is pending then reading
|
||
; lower eight bits would clear that interrupt so we'll avoid that by
|
||
; not reading the actual value in the low eight bits but just using
|
||
; zero instead. In fact, because the interrupt may become pending
|
||
; between reading the upper and lower bytes we won't read the
|
||
; lower byte if the upper byte is a zero even if no interrupt is yet
|
||
; pending. The second problem is that between reading the upper
|
||
; byte and the lower byte, the lower byte could decrement from 00
|
||
; to FF which would mean the upper byte value is wrong. So we'll
|
||
; re-read the upper byte after reading the lower byte and if they're
|
||
; not equal we'll retry the entire read operation. Finally, in
|
||
; the case where the interrupt is pending we must adjust the value
|
||
; to take into account the implied latency.
|
||
;
|
||
; When we're done we'll have a 32-bit signed value in d1 which can
|
||
; be combined with CurrentTime to yield the actual time. Also,
|
||
; we'll have the low eight bits from the VIA in d0.
|
||
|
||
eieioSTP
|
||
move.b vT2CH(a1),d1 ; d1 := MSBs of timer
|
||
eieioSTP
|
||
btst.b #T2IntBit,vIFR(a1) ; is the interrupt pending?
|
||
eieioSTP
|
||
beq.s no_overflow
|
||
|
||
overflow: moveq.l #-1,d1 ; force upper bits to ones
|
||
move.b d1,d0 ; generate fake LSBs
|
||
eieioSTP
|
||
move.b vT2CH(a1),d1 ; re-read timer in case of roll-over
|
||
eieioSTP
|
||
rol.w #8,d1 ; position MSBs; LSBs become 1's
|
||
bra.s done_reading_via
|
||
|
||
no_overflow:tst.b d1
|
||
retry: beq.s dont_read_lsbs ; don't clear the interrupt
|
||
eieioSTP
|
||
move.b vT2C(a1),d0 ; d0 := LSBs of timer
|
||
eieioSTP
|
||
move.b vT2CH(a1),d2 ; d2 := MSBs of timer
|
||
eieioSTP
|
||
cmp.b d2,d1 ; did the MSBs roll?
|
||
beq.s have_both_halves
|
||
move.b d2,d1
|
||
bra.s retry
|
||
|
||
dont_read_lsbs:
|
||
moveq.l #0,d0 ; pretend they're zeros
|
||
|
||
have_both_halves:
|
||
lsl.w #8,d1 ; slide the MSBs into position
|
||
move.b d0,d1 ; insert LSBs
|
||
|
||
done_reading_via:
|
||
|
||
; So now we have a 32-bit signed value in d1 which indicates
|
||
; where time really is with respect to the value in CurrentTime.
|
||
; In d0 we have the LSBits of the via timer. Now we convert
|
||
; these values into microseconds. This is pretty contorted
|
||
; because the unit of VIA ticks is not a rational number.
|
||
|
||
moveq.l #(1<<TickScale)-1,d2 ; d2 := virtual tick rounding factor
|
||
add.l d2,d1 ; round to virtual ticks
|
||
asr.l #TickScale,d1 ; convert to virtual ticks by discading LSBs
|
||
move.l CurrentTime(a0),d2 ; d2 := time of next interrupt
|
||
sub.l d1,d2 ; correct with value in VIA
|
||
|
||
lea HighUSecs(a0),a1 ; form pointer for speed
|
||
move.l (a1)+,d3 ; d3.l := High 32 bits of uSeconds
|
||
move.w (a1)+,d4 ; d4.w := Next 16 bits of uSeconds
|
||
move.l (a1)+,d5 ; d5.l := 16 LSBs of uSec and 16 bit fraction
|
||
swap d0 ; put VIA LSBs in d0.hi
|
||
move.w (a1)+,d0 ; d0.w := threshold
|
||
|
||
move.w (sp)+,sr ; now we can enable interrupts
|
||
|
||
; Recall that MicroSeconds are maintained internally as an 80 bit
|
||
; number with 64 bits of mantissa and 16 bits of fraction.
|
||
;
|
||
; The first part of the conversion is to do a huge division by
|
||
; repeated subtraction. We look at the CurrentTime and the
|
||
; Threshold and increment the Threshold by a value X until it
|
||
; is greater than the CurrentTime. Each time we add X to the
|
||
; Threshold we add Y to the 80 bit microsecond counter. X and Y
|
||
; have been carefully chosen so that X is as close to 2^12 as
|
||
; possible and is such that X * Via_Tick_Units is exactly
|
||
; representable in a 32.16 fixed point value.
|
||
|
||
check_threshold:
|
||
cmp.w d0,d2 ; compare CurrentTime to Threshold
|
||
bmi.s threshold_ok
|
||
addi.w #ThreshInc,d0 ; update threshold
|
||
addi.l #USecsInc,d5 ; update Microseconds
|
||
bcc.s check_threshold
|
||
addq.w #1,d4 ; propagate carry
|
||
bcc.s check_threshold
|
||
addq.l #1,d3 ; propagate carry
|
||
bra.s check_threshold
|
||
|
||
threshold_ok:
|
||
swap d4
|
||
swap d5
|
||
move.w d5,d4 ; d3:d4 := 64 bit microseconds count, nearly
|
||
swap d5 ; d5 := 16 bit fractional part
|
||
|
||
; At this point:
|
||
; D0.Hi => lower 8 bits of the upper word are the low VIA byte
|
||
; D0.Lo => Updated Threshold
|
||
; D2 => Updated CurrentTime
|
||
; D3.L => 32 high order bits of microseconds counter
|
||
; D4.L => 32 low order bits of microseconds counter
|
||
; D5.W => 16 bits of microseconds fraction
|
||
|
||
|
||
adjust_for_residual:
|
||
|
||
; Now we need to use the remaining part of Threshold and the four
|
||
; LSBs of the VIA timer to provide further accuracy.
|
||
|
||
move.l d0,d1 ; d1.hi := VIA LSBs
|
||
swap d1 ; d1.lo := VIA LSBs
|
||
neg.b d1 ; convert it to be additional time
|
||
ror.l #TickScale,d1 ; move it into high byte for insertion
|
||
|
||
sub.w d0,d2 ; CurrentTime := CurrentTime - CurTimeThresh
|
||
addi.w #ThreshInc,d2 ; compute additional time
|
||
move.w d2,d1 ; combine with VIA MSBs
|
||
rol.l #TickScale,d1 ; convert to un-scaled VIA time
|
||
mulu.w #InternalToUs>>16,d1 ; convert to microseconds
|
||
if 32-IntToUsFractBits-TickScale <> 1 then
|
||
lsl.l #32-IntToUsFractBits-TickScale,d1 ; align to form 16.16 fixed point result
|
||
else
|
||
add.l d1,d1 ; align to form 16.16 fixed point result
|
||
endif
|
||
add.w d5,d1 ; add in FractUSecs, set ccr.x to carry out
|
||
clr.w d1 ; clear out fraction bits
|
||
swap d1 ; get additional µsecs
|
||
addx.l d1,d4 ; add additional time to LowUSecs
|
||
subx.l d1,d1 ; -1 if ccr.x = 1, 0 if ccr.x = 0
|
||
sub.l d1,d3 ; propagate carry into HighUSecs
|
||
|
||
movea.l d3,a0 ; put result in result registers
|
||
move.l d4,d0
|
||
movem.l (sp)+,d3-d5 ; restore saved registers
|
||
rts ; all done <4>
|
||
|
||
endproc
|
||
|
||
TITLE 'Time Manager - Freeze Time'
|
||
|
||
;_______________________________________________________________________
|
||
;
|
||
; Routine: FreezeTime
|
||
; Inputs: none
|
||
; Outputs: A2 - ptr to TimeMgrPrivate
|
||
; D3.hi - saved SR (interrupt priority)
|
||
; D3.lo - value read from the low byte of the VIA timer masked
|
||
; to virtual ticks.
|
||
; Destroys: D1, D2, A1
|
||
; Calls: none
|
||
; Called by: RmvTime, PrimeTime, Timer2Int
|
||
;
|
||
; Function: Saves current interrupt priority level, disables all interrupts.
|
||
; Reads the VIA timer 2, adjusts tmCount field of all active
|
||
; Time Manager Tasks to reflect actual time remaining.
|
||
;
|
||
;_______________________________________________________________________
|
||
|
||
FreezeTime proc export
|
||
|
||
with TimeMgrPrivate
|
||
|
||
move.w sr,d3 ; save interrupt priority level
|
||
swap d3 ; sr -> high word, zero -> low word
|
||
move.w #$0100-(1<<TickScale),d3; setup virtual tick mask
|
||
movea.l VIA,a1 ; get base address of VIA1
|
||
lea vT2CH(a1),a1 ; point to timer high byte for speed
|
||
movea.l TimeVars,a2 ; point to TimeMgrPrivate
|
||
ori.w #$0700,sr ; disable all interrupts
|
||
if forROM then
|
||
if hasPowerMgr then
|
||
eieioSTP
|
||
tst.w Clock16M ; force processor out of idle.
|
||
eieioSTP
|
||
endif
|
||
else
|
||
|
||
; NOP this out on machines without Power Mgr. chips
|
||
|
||
export PoundThreeNOPsHereIfNoPowerMgr
|
||
PoundThreeNOPsHereIfNoPowerMgr:
|
||
eieioSTP
|
||
tst.w Clock16M ; force processor out of idle.
|
||
eieioSTP
|
||
|
||
endif
|
||
|
||
; The VIA Timer is constantly decrementing, and after the high byte is read, but
|
||
; before the low byte is read, the low byte may decrement from 00 -> FF, which
|
||
; would mean that the high is off by one, which would be an error of 256 ticks.
|
||
; By reading the high byte twice, we can detect and correct this situation.
|
||
; We also correct for the case where the high byte counted from 00 -> FF, in which
|
||
; case the interrupt pending bit may have been incorrect at the time we read it.
|
||
|
||
eieioSTP
|
||
move.b vT2CH-vT2CH(a1),d2 ; get high byte of counter
|
||
eieioSTP
|
||
moveq.l #1<<T2IntBit,d1 ; setup mask to check int pending
|
||
eieioSTP
|
||
and.b vIFR-vT2CH(a1),d1 ; get interrupt pending bit
|
||
eieioSTP
|
||
neg.l d1 ; d1.hi := -1 if int pending, else 0
|
||
if use68020Opcodes then ; 68020 shifting is fast
|
||
move.b d2,d1 ; insert timer high byte
|
||
lsl.w #8,d1 ; position it in the right place
|
||
else ; 68000 shifting is slower than memory
|
||
move.b d2,-(sp) ; insert timer high byte
|
||
move.w (sp)+,d1 ; position it in the right place
|
||
endif
|
||
eieioSTP
|
||
move.b vT2C-vT2CH(a1),d1 ; insert timer low byte
|
||
eieioSTP
|
||
sub.b vT2CH-vT2CH(a1),d2 ; see if high byte changed
|
||
eieioSTP
|
||
beq.s @TimeOK ; if not, time is correct
|
||
|
||
subx.l d2,d2 ; d2 := -1 if counted through zero
|
||
or.l d2,d1 ; update sign bits
|
||
if use68020Opcodes then ; 68020 shifting is fast
|
||
eieioSTP
|
||
move.b vT2CH-vT2CH(a1),d1 ; re-read timer high byte
|
||
eieioSTP
|
||
lsl.w #8,d1 ; position it in the right place
|
||
else ; 68000 shifting is slower than memory
|
||
eieioSTP
|
||
move.b vT2CH-vT2CH(a1),-(sp) ; re-read timer high byte
|
||
eieioSTP
|
||
move.w (sp)+,d1 ; position it in the right place
|
||
endif
|
||
eieioSTP
|
||
move.b vT2C-vT2CH(a1),d1 ; insert timer low byte
|
||
eieioSTP
|
||
@TimeOK
|
||
eieioSTP
|
||
move.b d1,TimerLowSave(a2) ; save low byte of VIA timer <4>
|
||
moveq.l #(1<<TickScale)-1,d2 ; prepare to round to virtual ticks
|
||
add.l d2,d1 ; if virtual tick not complete, don't count it
|
||
and.b d1,d3 ; save VIA timer truncated to virtual ticks
|
||
asr.l #TickScale,d1 ; convert ticks to internal time form
|
||
sub.l d1,CurrentTime(a2) ; update current time
|
||
|
||
move.w CurrentTime+2(a2),d2 ; get low word of current time <4>
|
||
@chkThresh lea CurTimeThresh(a2),a1 ; point to CurTimeThresh <4>
|
||
cmp.w (a1),d2 ; see if next threshold has been reached <4>
|
||
bmi.s @threshOK ; if not reached yet, don't need to increment <4>
|
||
addi.w #ThreshInc,(a1) ; update the next threshold <4>
|
||
addi.l #USecsInc,-(a1) ; update microsecond counter (low word, and fract) <4>
|
||
bcc.s @chkThresh ; if no carry to prop, see if thresh adjusted <4>
|
||
addq.w #1,-(a1) ; propagate the carry <4>
|
||
bcc.s @chkThresh ; if no carry to prop, see if thresh adjusted <4>
|
||
addq.l #1,-(a1) ; propagate the carry <4>
|
||
bra.s @chkThresh ; see if threshold adjusted <4>
|
||
@threshOK ; <4>
|
||
move.l ActivePtr(a2),d2 ; get pointer to first active timer task
|
||
beq.s @UpdateBacklog ; if no active tasks, no backlog (d2=0)
|
||
|
||
movea.l d2,a1 ; setup pointer to task at head
|
||
moveq.l #0,d2 ; assume new backlog will be zero
|
||
sub.l BackLog(a2),d1 ; adjust the timer, account for backlog
|
||
bpl.s @Early ; extra time, no backlog of any kind
|
||
|
||
add.l tmCount(a1),d1 ; tmCount := tmCount - backlog
|
||
bcs.s @UpdateHead ; if no remaining backlog, use remaining count
|
||
sub.l d1,d2 ; setup remaining backlog
|
||
moveq.l #0,d1 ; no remaining time
|
||
@UpdateHead move.l d1,tmCount(a1) ; setup new time remaining
|
||
@UpdateBacklog
|
||
move.l d2,BackLog(a2) ; update backlog time, if any
|
||
rts ; all done
|
||
|
||
@Early add.l tmCount(a1),d1 ; add excess time to time remaining
|
||
bra.s @UpdateHead ; update the time remaining counter
|
||
endproc
|
||
TITLE 'Time Manager - Initialize Time Manager'
|
||
|
||
;_______________________________________________________________________
|
||
;
|
||
; Routine: InitTimeMgr
|
||
; Inputs: none
|
||
; Outputs: none
|
||
; Destroys: none
|
||
; Calls: none
|
||
; Called by: StartInit
|
||
;
|
||
; Function: Allocates and initializes the Time Manager's global data
|
||
; structures at system boot time. Sets up VIA 1 Timer2
|
||
; interrupt handler. Computes the timer adjustment value
|
||
; at runtime, since it is processor speed dependent.
|
||
;
|
||
;_______________________________________________________________________
|
||
|
||
InitTimeMgr proc export
|
||
|
||
import Timer2Int
|
||
import ThawTime
|
||
with TimeMgrPrivate
|
||
|
||
@SavedRegs reg a0-a4/d0-d5 ; registers to preserve
|
||
movem.l @SavedRegs,-(sp) ; save the registers
|
||
|
||
moveq.l #PrivateSize,d0 ; size to allocate
|
||
_NewPtr ,SYS,CLEAR ; allocate and clear the structure
|
||
move.l a0,TimeVars ; setup pointer to private storage
|
||
movea.l a0,a2 ; setup for ThawTime
|
||
|
||
if forROM then
|
||
move.w #(1<<(TickScale-1))\ ; round up before conversion
|
||
+(1<<TickScale),RetryAdjust(a2) ; add in some extra time
|
||
else
|
||
moveq #(1<<(TickScale-1))\ ; round up before conversion
|
||
+(2<<TickScale),d0 ; add in some extra time (value for 68000)
|
||
tst.b CPUFlag ; what processor do we have?
|
||
bz.s @gotRetryAdjust ; 68000, use value computed above
|
||
moveq #(1<<(TickScale-1))\ ; round up before conversion
|
||
+(1<<TickScale),d0 ; add in some extra time (value for 68020)
|
||
@gotRetryAdjust
|
||
move.w d0,RetryAdjust(a2) ; store the computed value
|
||
endif
|
||
|
||
lea Timer2Int,a1 ; get interrupt handler address
|
||
move.l a1,Lvl1DT+(T2IntBit*4) ; put into interrupt table
|
||
|
||
move.w sr,-(sp) ; save interrupt level
|
||
ori.w #$0700,sr ; disable interrupts
|
||
|
||
movea.l Via,a4 ; get VIA pointer
|
||
lea vT2C(a4),a1 ; point to low byte of timer 2 for speed
|
||
lea vT1C(a4),a3 ; point to low byte of timer 1 for speed
|
||
lea vACR(a4),a4 ; point to AUX control reg for speed
|
||
|
||
moveq.l #-$80+(1<<T2IntBit),d1 ; enable timer 2 interrupts
|
||
eieioSTP
|
||
move.b d1,vIER-vT2C(a1) ; initialize the interrupt enable bit
|
||
eieioSTP
|
||
|
||
moveq.l #~(1<<5),d5 ; mask to set timer 2 into timed interrupt mode
|
||
eieioSTP
|
||
and.b vACR-vACR(a4),d5 ; save old AUX control reg
|
||
eieioSTP
|
||
moveq.l #%00111111,d0 ; force timer 1 into one-shot mode
|
||
and.b d5,d0 ; clear the bits
|
||
eieioSTP
|
||
move.b d0,vACR-vACR(a4) ; setup temporary AUX control reg
|
||
eieioSTP
|
||
moveq.l #0,d3 ; setup timer low byte value
|
||
move.w sr,d3 ; get sr
|
||
swap d3 ; sr in high word
|
||
|
||
eieioSTP
|
||
move.b d1,vT1CH-vT1C(a3) ; load and start timer 1
|
||
eieioSTP
|
||
move.b d1,vT2CH-vT2C(a1) ; load and start timer 2
|
||
eieioSTP
|
||
move.b vT2C-vT2C(a1),d0 ; get timer 2 low byte
|
||
eieioSTP
|
||
sub.b vT1C-vT1C(a3),d0 ; get initial timer skew
|
||
eieioSTP
|
||
jsr ThawTime ; run the critical section, start timer
|
||
eieioSTP
|
||
move.b vT2C-vT2C(a1),d1 ; get timer 2 low byte
|
||
eieioSTP
|
||
sub.b vT1C-vT1C(a3),d1 ; get final timer skew
|
||
eieioSTP
|
||
|
||
sub.b d0,d1 ; don't count initial skew
|
||
subi.w #(($FFFF>>TickScale)<<TickScale),d1 ; subtract out loaded timer value
|
||
move.b d1,TimerAdjust(a0) ; setup the fudge factor
|
||
|
||
eieioSTP
|
||
move.b d5,vACR-vACR(a4) ; restore AUX control reg
|
||
eieioSTP
|
||
st vT2CH-vT2C(a1) ; load and start timer 2
|
||
eieioSTP
|
||
move.w (sp)+,sr ; restore interrupt level
|
||
movem.l (sp)+,@SavedRegs ; restore the registers
|
||
rts ; Time Manager is initialized
|
||
endproc
|
||
end
|
||
|