| Volume Number: | 2 | |
| Issue Number: | 1 | |
| Column Tag: | Ask Prof. Mac |
Readers Technical Questions 
By Steve Brecher, Software Supply, MacTutor Contributing Editor
SCSI
Q. It's widely rumored that Apple is going to offer an upgrade that includes a "SCSI port." What's that?
A. At this writing Apple has made no announcements about such an upgrade, but assuming that the rumors are true let's talk about SCSI. This is just a background briefing -- if the Mac does get a SCSI connection, the only programmers who will need to be concerned with its details are those who write device driver and other low-level software to talk to the SCSI devices that attach to the Mac.
SCSI stands for Small Computer Systems Interface and is usually pronounced as "scuzzy." It is a standard 8-bit-wide data bus that is increasingly popular in the industry for connecting peripheral devices to each other and to host computers.
SCSI is an enhancement and standardization of SASI (Shugart Associates Systems Interface), a disk controller interface which was originated by Shugart, the disk drive manufacturer, in the late '70s and widely used. SASI was submitted to ANSI (American National Standards Institute) for official standardization. In the process its name was changed to drop the association with a particular vendor, and protocols were added to enable multiple hosts to coexist on the bus, to allow peripherals to release the bus during their execution of long processes and then reconnect with the host which issued the command, and to add commands oriented to devices other than disks (e.g., tape drives).
The basic purpose of SCSI, like that of other buses (S100, VME, Qbus, Multibus, etc.) is to connect devices whose manufacturers may never have heard of one another so that the devices can send data back and forth in a coordinated way. SCSI specifies both the electrical aspects of the connection and a communication protocol. Up to 8 devices (peripheral controllers and/or computers) can be connected to a SCSI bus.
The bus consists of 8 data lines ("wires"), one data parity line, and 9 control signal lines. (For reasons best known to the hardware folks, a 50-line cable is usually used for SCSI interconnections.) Data transfer is asynchronous -- that means that an explicit control signal handshake protocol is used to coordinate the transfer of each byte (as opposed to synchronous, which means that the communicating devices use a common clock signal to pace data transfers).
The maximum SCSI data transfer rate is more than 1MByte/sec -- thus fast peripherals will have to wait for the Mac rather than vice-versa. The Mac, lacking DMA (Direct Memory Access), cannot transfer more than about 0.5Mbyte/sec into and out of RAM, because each byte transferred (recall that SCSI is an 8-bit-wide data bus) requires at least one CPU instruction and two 68000 bus accessess -- data source and destination -- in addition to the access for the instruction fetch. That's not counting any additional instructions such as for loop control.
A typical SCSI bus system is shown in Figure 1. This is a single-host system -- only one computer -- which allows the computer to drive the peripherals connected to the bus. The illustration shows only two peripherals, but there could be up to 7 (the host is one of the up to 8 devices that can attach to the bus).
The host adapter in the computer interfaces between the SCSI bus and the CPU. CPUs like the 68000 which use memory-mapped I/O would communicate with the host adapter by writing to or reading from fixed addresses -- just as the Mac communicates with its serial and diskette hardware at fixed addresses.
The bus allows any one pair of devices connected to it to be in communication at a given time. One of the devices (usually the computer) is the Initiator and the other (usually a peripheral) is the Target. The Initiator obtains use of the bus, and selects a Target; the Target responds to indicate it is selected, and then the two devices have exclusive use of the bus until they release it The Initiator sends commands to the Target, and the Target executes them. The set of possible commands includes Read (send data to me), Write (take the following data), Format (a disk), Rewind (a tape drive), etc.
SCSI peripheral controllers are fairly intelligent. For example, to read from a disk device, the Initiator (computer) need specify only a logical block address (a relative data block offset) and the number of blocks. The target controller then translates this into a low-level disk location (cylinder, head, sector). Historically, driver software in the computer has been responsible for such translation to low-level terms, because that's all that "dumb" disk controllers were able to understand. In addition to making things simpler for the host computer device driver software, this kind of controller intelligence allows a higher degree of device-independence -- the same way that a high-level programming language allows CPU-independence.
Soft Coding
Q. "ELL" on Delphi notes that Apple often warns against "hard-coding" constants such as screen and memory sizes into programs, but some example programs from Apple seem to include such constants nonetheless.
A. Do as they say, not as they do. Any program that's going to be used more than once (or farther into the future than five minutes) should be defensively programmed to assume that anything about its environment that might change, will change. Even today a program might be run on machines varying in memory size from 128K to 2MB, and varying in screen size from the Mac's screen to the XL's.
Handling an arbitrary screen size can be difficult with respect to multiple windows which contain many elements and which have been designed to look pretty. But that's no excuse for avaoiding simple measures, such as calculating at run time instead of hard-coding the positions of a window which should be centered.
To get the lazy started, I've provided in Figure 2 a couple of routines to vertically and horizontally center a rectangle. The code is trivial, but it illustrates the use of a couple of macros discussed in the next question.
In those cases in which constants must be used, they should be defined mnemonically (e.g., using EQU in assembler or Const in Pascal). That makes them easy to identify and change.
Macros
Q. I haven't seen many macros used in the assembly programs I've looked at. Could you give some examples of macro usage?
A. I have a file of macro definitions that I incorporate into most programs using the MDS Asm Include facility. The file is shown in Figure 3.
The first set of macros compensates for an MDS bug which generates incorrect results for some comparison operators. For example, instead of
If A<B
which doesn't work properly, I use the macro .LT.:
If A .LT. B
(I stole the substance of these comparison macros from the TMON user area source code.)
The second and most elaborate set of macros is used to avoid errors in stack addressing for a routine's arguments, result, and temporaries. Figure 4 shows an example of how this set of macros is used.
The Assume macro is useful for explicitly stating assumptions made by the code (usually relating to the value of an offset which is defined in an Equ file, or to the adjacency of values accessed with autoincrement or autodecrement addressing). For example, the code in Figure 2 contains:
Assume top=0 Add (A0),D0
Coding top(A0) wastes a word if top=0; including the Assume macro in this case makes clear what is going on (as well as protecting the program from undetected error should the offset of "top" ever change).
The various Push and Pop macros reduce the amount of typing required to code pushes and pops of the A7 stack as well as making the program easier to read (at least to my eye).
The BitDefinitions and Bit macros make it easy to define mnemonic values for bit numbers and masks which are used with flag bytes and hardware registers. Coding
BitDefinitions InterruptFlags Bit OneSec Bit VertBlank Bit KbdRdy ;etc.
is the equivalent of coding
OneSecBit Equ 0 OneSecMask Equ 1 VertBlankBit Equ 1 VertBlankMask Equ 2 KbdRdyBit Equ 2 KbdRdyMask Equ 4 ;etc.
spExtra
Q. Bill Bynum of Williamsburg, VA noticed that both Inside Macintosh and the June '85 issue of MacTutor (p. 45) indicate that the spExtra field of a grafPort record is a word, while in the MDS file QuickEqu.Txt, it's shown as a long (Pascal data type "fixed"). There is a corresponding discrepancy in the total size of a grafPort.
A. When in doubt, always go by the Equ files -- they're used by the folks at Apple who write systems software.
SpExtra is 4 bytes long, and a grafPort is 108 bytes long. Theoretically spExtra is of "fixed" data type, i.e., a 32-bit value with an implicit binary point in the middle. This implies that that spaces can be extended by a fractional number of pixels. However, in the current ROM QuickDraw effectively uses only the high-order word of spExtra. That's why the SpaceExtra trap works with an integer argument as it's documented in IM . QuickDraw moves a long argument from the stack to the field in the grafPort. Since the caller pushed only a word argument, the low-order word of the spExtra field in the grafPort will be whatever word happened to be above the caller's word argument on the stack. But since the low-order word doesn't really affect QuickDraw's calculations, all is well.
Figure 2 Source Code IncludeQuickEqu.D IncludeMacros ;see Figure 3 MBarHt Equ 20 ;vertical size of menu bar ; ; procedure VertCenterRect(VAR myRect: rect) ; ; Adjust the top and bottom of the rect so that the rect is ; vertically centered in the desktop area for current ; screen size. ; StackFrame NotLinked Arg myRect,Long ; VertCenterRect: Move.L (A5),A0 ;addr of QuickDraw globals Move screenBits+bounds+bottom(A0),D0 ;vertical size of screen Move.L myRect(SP),A0;addr of caller's rect Move bottom(A0),D1;D1 = bottom of caller's rect Sub D1,D0 ;D0 = old bottom margin Assume top=0 ;(macro) Add (A0),D0 ;+ old top margin, D0 = total ;vertical margin Lsr #1,D0 ;D0 = 1/2 of the vert space ;not used by rect Add #MbarHt/2,D0 ;adjust for menubar, D0 = ;new top of rect Sub (A0),D1 ;D1 = vertical size of rect Move D0,(A0) ;set new top Add D1,D0 ;new bottom = top + size Move D0,bottom(A0);set new bottom Return ;(macro) ; ; procedure HorzCenterRect(VAR myRect: rect) ; ; Adjust the left and right of the rect so that the rect is ; horizontally centered for current screen size. ; StackFrame NotLinked Arg myRect,Long ; HorzCenterRect: Move.L (A5),A0 ;addr of QuickDraw globals Move screenBits+bounds+right(A0),D0 ;D0 = horz size of screen Move.L myRect(SP),A0;addr of caller's rect Move right(A0),D1 ;D1 = right of caller's rect Lea left(A0),A0;point to left coordinate ;of rect Sub D1,D0 ;D0 = old right margin Add (A0),D0 ;+ old left margin, D0 = ;total horz margin Lsr #1,D0 ;D0 = 1/2 of the horz space ;not used by rect Sub (A0),D1 ;D1 = horizontal size of rect Move D0,(A0) ;set new left Add D1,D0 ;new right = left + size Move D0,right-left(A0) ;set new right Return ;(macro)
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Figure 3
; Macros.Asm -- General purpose MDS macros
;
; Macros to work around MDS Asm comparison reversal bug
;
If 1<0 ;if bug is present
Macro .LT. = > |
Macro .LE. = >= |
Macro .GT. = < |
Macro .GE. = <= |
Else ;if bug is not present
Macro .LT. = < |
Macro .LE. = <= |
Macro .GT. = > |
Macro .GE. = >= |
Endif
; Subroutine stack frame definition macros
;
; Usage:
;
;StackFrame Linked ;if A6 link to be used
;<or>
;StackFrame <anything else> ;if no A6 link to be used
;
;Arg ArgN,ArgNLen ;last arg pushed by caller
;...
;Arg Arg1,Arg1Len ;first arg pushed by caller
;Result ResultName,ResultLen
;Local Local1,Local1Len
;...
;Local LocalN,LocalNLen
;
;Routine:
;Link A6,#-LocalsSize ;if StackFrame Linked
;...
;Return
;
; Notes:
;
; StackFrame is required. Each of the other types of
; macro invocations is optional, but if present their
;relative ordering must be as shown.
;
; Arguments (Arg macro invocations) must appear in
; the reverse of the order in which the caller pushes
; the arguments.
;
; ResultLen is ignored, but provided for documentary
; purposes.
Macro StackFrame Type =
If'{Type}' = 'Linked'
..RtnAddr..Set 4
..ArgOffs..Set 8
Else
..RtnAddr..Set 0
..ArgOffs..Set 4
Endif
..ArgsSz.. Set 0
LocalsSize Set 0
|
Macro Arg Name,Len =
{Name} Set ..ArgOffs..
..ArgOffs..Set {Name}+{Len}+({Len}&1)
..ArgsSz.. Set ..ArgOffs..-..RtnAddr..-4
|
Macro ResultName,Len =
{Name} Set ..ArgOffs..
|
Macro Local Name,Len =
{Name} Set 0-LocalsSize-{Len}-({Len}&1)
LocalsSize Set 0-{Name}
|
Macro Return =
If..RtnAddr.. =4
Unlk A6
Endif
If..ArgsSz.. <>0
Move.L (SP)+,A0 ;return addr
If..ArgsSz.. .LE. 8
AddQ #..ArgsSz..,SP
Else
Lea ..ArgsSz..(SP),SP
Endif
Jmp (A0)
Else
Rts
Endif
|
;
; Define standard lengths
;
Byte Equ 1 ;same affect as Word
; use for declarative purpose
Word Equ 2
Long Equ 4
;
; Macros to push and pop stack
;
Macro Pop.B Dest =
If '{Dest}' <> ''
Move.B (SP)+,{Dest}
Else
Tst.B (SP)+ ;pop and set condition codes
;per Boolean
Endif
|
Macro Pop Dest =
If '{Dest}' <> ''
Move.W (SP)+,{Dest}
Else
AddQ #2,SP
Endif
|
Macro Pop.L Dest =
If '{Dest}' <> ''
Move.L (SP)+,{Dest}
Else
AddQ #4,SP
Endif
|
Macro Push.BSrc =
Move.B {Src},-(SP)
|
Macro PushSrc =
Move.W {Src},-(SP)
|
Macro Push.LSrc =
Move.L {Src},-(SP)
|
Macro PushM Regs =
MoveM.W{Regs},-(SP)
|
Macro PushM.L Regs =
MoveM.L{Regs},-(SP)
|
Macro PopMRegs =
MoveM.W(SP)+,{Regs}
|
Macro PopM.LRegs =
MoveM.L(SP)+,{Regs}
|
; Macro to make an assertion about an assumed condition
;
Macro Assume Cond =
If {Cond}
Else
Assumption error -- {Cond}
Endif
|
; Macros to decare bits and masks
; Usage
;BitDefinitions ID ;setup -- ID is documentary only
;Bit Name1 ;Defines Name1bit=0, Name1mask=1
;...
;Bit NameN ;Defines NameNbit=N, NameNmask=1<<N
;
Macro BitDefinitions ID
.BitNbr. Set 0
|
Macro Bit Name =
{Name}bitEqu .BitNbr.
{Name}mask Equ 1<<{Name}bit
.BitNbr. Set {Name}bit+1
|
Figure 4 IncludeSysEqu.D IncludeMacTraps.D IncludeMacros ; ; Function CanGetInfo(vRefNum, DirID: integer; FileNamePtr: Ptr): boolean ; Calls _HGetFileInfo (HFS version) if DirID<>0, ; otherwise _GetFileInfo. ; Returns true if the trap result is noErr. ; ioHFQElSize Equ $6C ;size of HFS parameter block ioDirID Equ $30 ;offset of DirID ; StackFrame Linked Arg FileNamePtr,long Arg DirID,word Arg vRefNum,word Result Flag,byte Local ioPB,ioHFQElSize ; CanGetInfo: Link A6,#-LocalsSize Lea ioPB(A6),A0;addr of parameter block Move.L FileNamePtr(A6),ioFileName(A0) Move vRefNum(A6),ioVRefNum(A0) Clr.B ioFVersNum(A0) ;version number always 0 Clr ioFDirIndex(A0);not an indexed call Move DirID(A6),D0 ;HFS? Bne.S @0;yes _GetFileInfo ;no Bra.S @1 @0 Move D0,ioDirID(A0) _HGetFileInfo @1 Assume noErr=0 Seq Flag(A6) ;set result Return
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