Sep 95 Challenge
| Volume Number: | | 11
|
| Issue Number: | | 9
|
| Column Tag: | | Programmer’s Challenge
|
Programmer’s Challenge 
By Bob Boonstra, Westford, Massachusetts
Note: Source code files accompanying article are located on MacTech CD-ROM or source code disks.
Reversible Scrambling Algorithm
According to tradition, September is Assembly Language Challenge month here at MacTech, and we continue that tradition this month. Your challenge is to do some simple arithmetic - raising a number to a power, and taking the remainder of the result modulo another number. Simple, right? To make things interesting, though, the numbers are going to be a little larger than you are used to dealing with. Hundreds of decimal digits long, in fact. “Why,” you may ask? We’ll get into that in a minute, but there are a couple of hints in the title of this month’s challenge.
The data structure to be used for the large numbers in this Challenge, and the prototype for the code you should write are:
typedef struct BigNum {
short numDig; /* the number of bytes in the BigNum */
unsigned char *dig; /* dig[0] is the most significant byte */
/* dig[numDig-1] is least significant */
} BigNum;
void PowerAndRemainder(
BigNum *msg,
BigNum *exp, /* calculate msg to the exp power, */
BigNum *n, /* take the remainder modulo n */
BigNum *res/* and store the result in res */
);
For example, the value 1048573 (0xFFFFD) would be provided to you in a BigNum b with the values b.numDig=3, b.dig[0] = 0x0F, b.dig[1]=0xFF, and b.dig[2]=0xFD. The first three arguments will be provided as input when PowerAndRemainder is called; you are to generate both elements of the BigNum struct for the res argument. The storage for all of the BigNums in the call to PowerAndRemainder will be allocated by the caller. All BigNums will be positive integers, and none of the BigNums will be larger than 128 bytes in length (i.e., b.numDig will be no larger than 128). There is no restriction on the amount of memory you may use (within reason).
Those of you with some number theory in your background may recognize what a function like this might be used for. If the modulus n is the product of two large primes p and q, one can find values e and d for the exponent with the property that they are inverses of one another, but that neither can be easily derived from the other, provided prime numbers p and q are not divulged. If you calculate PowerAndRemainder(msg,e,n,c), and I then calculate PowerAndRemainder(c,d,n,x), then the result x turns out to be identical to the original value msg if e and d are relatively prime to (p-1)*(q-1). Now what do you suppose such a function might be useful for?
Your solution may use any combination of ANSI C and/or 68K assembly language, along with your choice of either the THINK C or MetroWerks C 68K compilers. I considered making this a PowerPC challenge, but I wasn’t confident that enough people are proficient with PPC assembly just yet - perhaps next September. In the meantime, you can look forward to a native PPC challenge next month.
If you are interested in some sample values to test your code, send me email and I’ll provide some.
Challenge Deadline
Several people wrote to point out that the deadline for submitting Challenge solutions was missing from the Rules box during July and August. Unfortunately, when the rules were revised to accommodate multiple compilers and target instruction sets, the deadline was inadvertently omitted. The Challenge deadline remains the 10th of the month printed on the cover of the magazine. I received several submissions for the Chess challenge after the deadline (and after the article was submitted for publication). Because of the problem with the deadline, I would have awarded points to any fast and correct entries, but all of the late entries had problems with correctness so no additional points were awarded.
Two Months Ago Winner
Of the nine entries to the Sprite Blitz challenge, seven of them worked correctly. Congratulations to Xan Gregg (Durham, NC) for having the fastest solution, some 30% faster than the second place entry, submitted by John Nevard. Despite the variation in run time performance, there were a number of clever and creative solutions among the top entries.
Here are the times and code sizes for the entries that worked correctly. Numbers in parens after a person’s name indicate that person’s cumulative point total for all previous Challenges, not including this one.
Name time (68K)
Xan Gregg (31) 908
John Nevard 1300
Bill Karsh (71) 3363
Jim Bumgardner (4) 3495
Jeremy Vineyard (40) 5789
Norman Basham 10164
Steve Israelson 75846
Like most of the top entries, Xan composed his screen updates offscreen. Xan uses one offscreen GWorld to hold the background and another to prepare the next animation frame. One clever trick is that the offscreen image is large enough to contain all of a sprite that overlaps a window boundary, so that clipping need only be done when updating the window. Drawing is done directly to the screen, taking advantage of alignment conditions guaranteed to hold by the problem statement. Xan does all of his copying to the screen using unrolled loops, avoiding the overhead incurred when using CopyBits or CopyMask for small copies. When reading the code, take note of the switch statement in the COPY4 macro that copies the icon based on the value of the mask, and of the longword copies in the FastCopyChunk routine.
Bill Karsh pointed out in his entry that the relative performance of CopyBits and CopyMask varies between his 68K machine and his PPC 7100, with CopyBits being faster on the former machine and CopyMask being faster on the latter. I didn’t have time to measure native performance on the PowerPC, but there was a 15% difference between the two versions in my 68K tests. Of course, as Xan’s solution shows, avoiding both can have its advantages also.
Does Performance Matter?
I’ve received some email suggesting that the emphasis on performance in this column ought to be replaced by emphases on other things, like code portability, readability, reliability, encapsulation, or object orientation. The argument is that improvements in hardware performance make efficiency less important than it has been in the past. This is certainly a valid point of view, and there is no question that processor improvements have enabled us to sacrifice some machine cycles to achieve objectives other than performance. However, I contend that the performance of several popular personal computer applications demonstrates that software developers are capable of adding enough functionality (or generating poor enough code) to degrade performance to an unacceptable level, despite hardware advances. In my opinion, this will always be so. Certainly the techniques demonstrated in this column should not be used in all software, but they have their place in time-critical areas, and it is worth devoting more attention to efficiency than we typically do. Besides, squeezing instructions out of code is great fun! But if you are interested in seeing a column that focuses on something besides efficiency, drop me a note.
Top 20 Contestants of All Time
Here are the Top 20 Contestants for the Programmer’s Challenges to date. The numbers below include points awarded for this month’s entrants. (Note: ties are listed alphabetically by last name - there are more than 20 people listed this month because of ties.)
1. [Name deleted] 176
2. Karsh, Bill 78
3. Munter, Ernst 70
4. Stenger, Allen 65
5. Larsson, Gustav 60
6. Gregg, Xan 51
7. Riha, Stepan 51
8. Goebel, James 49
9. Nepsund, Ronald 47
10. Cutts, Kevin 46
11. Mallett, Jeff 44
12. Kasparian, Raffi 42
13. Vineyard, Jeremy 42
14. Darrah, Dave 31
15. Landry, Larry 29
16. Elwertowski, Tom 24
17. Lee, Johnny 22
18. Noll, Robert 22
19. Anderson, Troy 20
20. Beith, Gary 20
21. Burgoyne, Nick 20
22. Galway, Will 20
23. Israelson, Steve 20
24. Landweber, Greg 20
25. Pinkerton, Tom 20
There are three ways to earn points: (1) scoring in the top 5 of any Challenge, (2) being the first person to find a bug in a published winning solution or, (3) being the first person to suggest a Challenge that I use. The points you can win are:
1st place 20 points
2nd place 10 points
3rd place 7 points
4th place 4 points
5th place 2 points
finding bug 2 points
suggesting Challenge 2 points
Here is Xan’s winning solution:
Sprite Blitz
Xan Gregg, July 1995
/*
Since “correctness” is considered before speed in judging solutions, this solution makes correctness the
top priority at the cost of speed.
I use two offscreen GWorlds. One has the background, and another has the image to be displayed on the
screen next. The “on deck” image is updated sprite by sprite, then it is copied to the screen for minimum
flicker.
The GWorlds are a little bigger than the screen so I don’t have to worry about sprites that overlap the edges
until copying to the screen.
Memory usage:
2 GWorlds, each 64 pixels wider and taller than window.
1K of pixel data for each sprite.
128 bytes of mask data for each sprite.
16 bytes of info for each sprite.
I set the number of sprites to 400. The problem states a maximum of 200 present at a time, but because
a deleted sprite stays around until the next UpdateScreen() call,
I allow for 400 in case you delete all 200 then add 200 more before calling UpdateScreen(). Paranoid, but
if you’ve got the memory...
Assumptions not stated in the problem:
Enough memory available for above usage.
Window width is a multiple of 4 (confirmed by BB).
Window does not move during play.
*/
#include <QDOffscreen.h>
typedef struct
{
short nextSlot;
short status;
short width;
short height;
Point position;
Point lastPosition;
} SpriteInfo, *SpriteInfoPtr;
typedef struct
{
char pixData[1024];
} SpritePixData, *SpritePixDataPtr;
typedef struct
{
char maskData[128];
} SpriteMaskData, *SpriteMaskDataPtr;
#define kMaxSprites400L
#define kMaxSpriteWidth 32L
#define kMaxSpriteHeight 32L
static CWindowPtrgScreenWindowP;
static GWorldPtr gBackgroundGW;
static PixMapHandlegBackgroundPixMapH;
static GWorldPtr gOnDeckGW;
static PixMapHandlegOnDeckPixMapH;
static shortgLastSpriteSlot;
static shortgFirstSpriteSlot;
static shortgSpriteCount;
static shortgWindowWidth;
static shortgWindowHeight;
static SpriteInfoPtr gSpriteInfo;
static SpritePixDataPtr gSpritePixData;
static SpriteMaskDataPtr gSpriteMaskData;
static long gOnDeckRowBytes;
static PtrgOnDeckBaseAddr;
static long gBkgRowBytes;
static PtrgBkgBaseAddr;
static long gScreenRowBytes;
static PtrgScreenBaseAddr;
static Ptr*gBkgRowAddr;
static Ptr*gOnDeckRowAddr;
static Ptr*gScreenRowAddr;
static shortgDeletionCount;
StartGame
void StartGame(CWindowPtr windowP)
{
Rect r;
PixMapPtrbkgPixMapP;
PixMapPtronDeckPixMapP;
PixMapPtrscreenPixMapP;
gLastSpriteSlot = -1;
gFirstSpriteSlot = -1;
gSpriteCount = 0;
gDeletionCount = 0;
gScreenWindowP = windowP;
r = windowP->portRect;
OffsetRect(&r, -r.left, -r.top);
gWindowWidth = r.right;
gWindowHeight = r.bottom;
InsetRect(&r, -kMaxSpriteWidth, -kMaxSpriteHeight);
NewGWorld(&gBackgroundGW, 0, &r, 0, 0, 0);
gBackgroundPixMapH = GetGWorldPixMap(gBackgroundGW);
LockPixels(gBackgroundPixMapH); /* always locked */
NewGWorld(&gOnDeckGW, 0, &r, 0, 0, 0);
gOnDeckPixMapH = GetGWorldPixMap(gOnDeckGW);
LockPixels(gOnDeckPixMapH);/* always locked */
gSpriteInfo = (SpriteInfoPtr) NewPtrClear
(sizeof(SpriteInfo) * kMaxSprites);
gSpritePixData = (SpritePixDataPtr) NewPtrClear
(sizeof(SpritePixData) * kMaxSprites);
gSpriteMaskData = (SpriteMaskDataPtr) NewPtrClear
(sizeof(SpriteMaskData) * kMaxSprites);
gBkgRowAddr = (Ptr *) NewPtr(sizeof(Ptr) *
(gWindowHeight + kMaxSpriteHeight * 2));
gOnDeckRowAddr = (Ptr *) NewPtr(sizeof(Ptr) *
(gWindowHeight + kMaxSpriteHeight * 2));
gScreenRowAddr = (Ptr *) NewPtr(sizeof(Ptr)
* (long) gWindowHeight);
if (gSpriteInfo == 0 || gSpritePixData == 0
|| gSpriteMaskData == 0 || gScreenRowAddr == 0
|| gBkgRowAddr == 0 || gOnDeckRowAddr == 0
|| gBackgroundGW == 0 || gOnDeckGW == 0)
DebugStr("\p out of memory!");
InsetRect(&r, kMaxSpriteWidth, kMaxSpriteHeight);
OffsetRect(&r, kMaxSpriteWidth, kMaxSpriteHeight);
CopyBits(&((WindowPtr)windowP)->portBits,
&((WindowPtr)gBackgroundGW)->portBits,
&windowP->portRect, &r, srcCopy, NULL);
CopyBits(&((WindowPtr)windowP)->portBits,
&((WindowPtr)gOnDeckGW)->portBits,
&windowP->portRect, &r, srcCopy, NULL);
bkgPixMapP = *gBackgroundPixMapH;
onDeckPixMapP = *gOnDeckPixMapH;
gOnDeckRowBytes = onDeckPixMapP->rowBytes & 0x7fff;
gOnDeckBaseAddr = onDeckPixMapP->baseAddr
+ gOnDeckRowBytes * kMaxSpriteHeight
+ kMaxSpriteWidth;
gBkgRowBytes = bkgPixMapP->rowBytes & 0x7fff;
gBkgBaseAddr = bkgPixMapP->baseAddr
+ gBkgRowBytes * kMaxSpriteHeight
+ kMaxSpriteWidth;
screenPixMapP = *gScreenWindowP->portPixMap;
gScreenRowBytes = screenPixMapP->rowBytes & 0x7fff;
gScreenBaseAddr = screenPixMapP->baseAddr
- screenPixMapP->bounds.left
- screenPixMapP->bounds.top
* gScreenRowBytes;
{ /* initialize rowAddr’s */
long row;
gOnDeckRowAddr += kMaxSpriteHeight;
gBkgRowAddr += kMaxSpriteHeight;
for (row = -kMaxSpriteHeight;
row < gWindowHeight + kMaxSpriteHeight; row++)
{
gBkgRowAddr[row] = gBkgBaseAddr
+ row * gBkgRowBytes;
gOnDeckRowAddr[row] = gOnDeckBaseAddr
+ row * gOnDeckRowBytes;
}
for (row = 0; row < gWindowHeight; row++)
gScreenRowAddr[row] = gScreenBaseAddr
+ row * gScreenRowBytes;
}
}
AddSprite
/* make a copy of CIcon’s pixel and mask data */
short AddSprite(CIconPtr cIconP, Point startPt)
{
short slot;
short i;
short pixWidth;
short maskWidth;
short pixBytes;
short maskBytes;
short bitBytes;
short height;
Ptr pixSrcAddr, pixDstAddr;
long *maskSrcAddr, *maskDstAddr;
slot = gLastSpriteSlot + 1;
if (slot == kMaxSprites)
slot = 0;
while (gSpriteInfo[slot].status != 0)
{
slot++;
if (slot == kMaxSprites)
slot = 0;
}
gSpriteInfo[slot].status = 1;/* occupied */
height = cIconP->iconPMap.bounds.bottom
- cIconP->iconPMap.bounds.top;
pixWidth = cIconP->iconPMap.bounds.right
- cIconP->iconPMap.bounds.left;
maskWidth = (pixWidth + 7) >> 3;
gSpriteInfo[slot].width = pixWidth;
gSpriteInfo[slot].height = height;
pixBytes = cIconP->iconPMap.rowBytes & 0x7fff;
maskBytes = cIconP->iconMask.rowBytes;
bitBytes = cIconP->iconBMap.rowBytes;
pixSrcAddr = ((Ptr) &cIconP->iconMaskData)
+ bitBytes * height
+ maskBytes * height
+ 256 * 8 + 8; /* 8-bit color table */
pixDstAddr = (char *) &gSpritePixData[slot];
maskSrcAddr = (long *) &cIconP->iconMaskData;
maskDstAddr = (long *) &gSpriteMaskData[slot];
pixWidth = pixWidth >> 2;
for (i = 0; i < height; i++)
{
{
register long *q = (long *) pixDstAddr;
register long *p = (long *) pixSrcAddr;
register short j = pixWidth;
while (j > 0)
{
*q++ = *p++;
j--;
}
}
*maskDstAddr++ = *maskSrcAddr;
pixDstAddr += 32;
pixSrcAddr += pixBytes;
maskSrcAddr = (long *) (((Ptr) maskSrcAddr)
+ maskBytes);
}
if (gLastSpriteSlot >= 0)
{
gSpriteInfo[gLastSpriteSlot].nextSlot = slot;
}
else
{
gFirstSpriteSlot = slot;
}
gLastSpriteSlot = slot;
gSpriteInfo[slot].nextSlot = -1;
gSpriteInfo[slot].position = startPt;
gSpriteInfo[slot].lastPosition = startPt;
gSpriteCount ++;
return slot;
}
EraseSprite
/* replace sprite with chunk from the bkg gworld */
static void EraseSprite(SpriteInfoPtr spriteInfoP)
{
short numRows;
short numCols;
register long *p;
register long *q;
short h, v;
register long srcRowBytes;
register long dstRowBytes;
numRows = spriteInfoP->height;
numCols = spriteInfoP->width;
h = spriteInfoP->lastPosition.h;
v = spriteInfoP->lastPosition.v;
if (h + numCols <= 0 || h >= gWindowWidth
|| v + numRows <= 0 || v >= gWindowHeight)
return;/* totally offscreen, so skip it */
p = (long *) (gBkgRowAddr[v] + h);
q = (long *) (gOnDeckRowAddr[v] + h);
srcRowBytes = gBkgRowBytes - numCols;
dstRowBytes = gOnDeckRowBytes - numCols;
if (numCols >= 16)
if (numCols == 32)
{
while (numRows != 0)
{
numRows--;
*q++ = *p++;
*q++ = *p++;
*q++ = *p++;
*q++ = *p++;
*q++ = *p++;
*q++ = *p++;
*q++ = *p++;
*q++ = *p++;
p = (long *) (((Ptr) p) + srcRowBytes);
q = (long *) (((Ptr) q) + dstRowBytes);
}
}
else
{
while (numRows != 0)
{
numRows--;
*q++ = *p++;
*q++ = *p++;
*q++ = *p++;
*q++ = *p++;
p = (long *) (((Ptr) p) + srcRowBytes);
q = (long *) (((Ptr) q) + dstRowBytes);
}
}
else
{
if (numCols < 8)
while (numRows != 0)
{
numRows--;
*q = *p;
p = (long *) (((Ptr) p) + gBkgRowBytes);
q = (long *) (((Ptr) q) + gOnDeckRowBytes);
}
else /* erase 4 pixels, even if its smaller */
while (numRows != 0)
{
numRows--;
*q++ = *p++;
*q++ = *p++;
p = (long *) (((Ptr) p) + srcRowBytes);
q = (long *) (((Ptr) q) + dstRowBytes);
}
}
}
DeleteSprite
/* Don’t actually do the delete, just mark for deletion -- because we still
need to erase it in UpdateScreen()
*/
void DeleteSprite(short spriteID)
{
gSpriteInfo[spriteID].status = -1;/* to be deleted */
gDeletionCount++;
}
RemoveDeletedSprites
/* only called when there is at least one deletion */
static void RemoveDeletedSprites(void)
{
short prevSlot = -1;
short slot = gFirstSpriteSlot;
short count = gDeletionCount;
while (1)
{
if (gSpriteInfo[slot].status < 0)
{/* needs to be removed */
if (prevSlot >= 0)
gSpriteInfo[prevSlot].nextSlot
= gSpriteInfo[slot].nextSlot;
else
gFirstSpriteSlot
= gSpriteInfo[slot].nextSlot;
if (slot == gLastSpriteSlot)
gLastSpriteSlot = prevSlot;
gSpriteInfo[slot].status = 0;/* available */
gSpriteCount--;
count--;
if (count == 0)
break;
}
else
{
prevSlot = slot;
}
slot = gSpriteInfo[slot].nextSlot;
}
gDeletionCount = 0;
}
MoveSprite
void MoveSprite(short spriteID, Point deltaPt)
{
gSpriteInfo[spriteID].position.h += deltaPt.h;
gSpriteInfo[spriteID].position.v += deltaPt.v;
}
EraseOldSprites
static void EraseOldSprites(void)
{
short slot;
SpriteInfoPtr spriteInfoP;
slot = gFirstSpriteSlot;
while (slot >= 0)
{
spriteInfoP = &gSpriteInfo[slot];
EraseSprite(spriteInfoP);
slot = spriteInfoP->nextSlot;
}
}
COPY4
/* copy 4 pixels based on bits of the mask */
#define COPY4(q,p,m) \
switch ((m) & 0x0f)\
{ \
case 0x0: break;\
case 0x1: *(q+3) = *(p+3); break; \
case 0x2: *(q+2) = *(p+2); break; \
case 0x3: *(short*)(q+2) = *(short*)(p+2); break; \
case 0x4: *(q+1) = *(p+1); break; \
case 0x5: *(q+1) = *(p+1); *(q+3) = *(p+3); break; \
case 0x6: *(short*)(q+1) = *(short*)(p+1); break; \
case 0x7: *(q+1) = *(p+1); \
*(short*)(q+2) = *(short*)(p+2); break; \
case 0x8: *(q) = *(p); break;\
case 0x9: *(q) = *(p); *(q+3) = *(p+3); break; \
case 0xA: *(q) = *(p); *(q+2) = *(p+2); break; \
case 0xB: *(q) = *(p); \
*(short*)(q+2) = *(short*)(p+2); break; \
case 0xC: *(short*)(q) = *(short*)(p); break; \
case 0xD: *(short*)(q) = *(short*)(p);\
*(q+3) = *(p+3); break;\
case 0xE: *(short*)(q) = *(short*)(p);\
*(q+2) = *(p+2); break;\
case 0xF: *(long*)(q) = *(long*)(p); break; \
}
COPY8
#define COPY8(q,p,mask) \
COPY4(q, p, mask >> 4) \
COPY4(q+4,p+4, mask)
DrawSprite
static void DrawSprite(short slot)
{
SpriteInfoPtr spriteInfoP;
short numRows;
short numCols;
register Ptr p;
register Ptr q;
Ptr maskP;
short srcRowBytes;
short h, v;
short mask;
short maskMask;
short maskRowBytes;
short numMaskBytes;
short i;
long dstRowBytes;
spriteInfoP = &gSpriteInfo[slot];
h = spriteInfoP->position.h;
v = spriteInfoP->position.v;
numRows = spriteInfoP->height;
numCols = spriteInfoP->width;
p = (char *) &gSpritePixData[slot];
q = gOnDeckRowAddr[v] + h;
maskP = (char *) &gSpriteMaskData[slot];
if (numCols >= 8)
{
numMaskBytes = numCols >> 3;
maskRowBytes = 4 - numMaskBytes;
srcRowBytes = 40 - numCols;
dstRowBytes = gOnDeckRowBytes - numCols + 8;
while (1)
{
i = numMaskBytes;
while (1)
{
mask = *maskP++;
COPY8(q, p, mask)
if (--i == 0)
break;
p += 8;
q += 8;
}
if (--numRows == 0)
break;
maskP += maskRowBytes;
p += srcRowBytes;
q += dstRowBytes;
}
}
else
{
maskMask = 0xf00 >> numCols;
while (1)
{
mask = (*maskP) & maskMask;
COPY8(q, p, mask)
if (--numRows == 0)
break;
maskP += 4;
p += 32;
q += gOnDeckRowBytes;
}
}
}
DrawNewSprites
static void DrawNewSprites(void)
{
register short slot;
SpriteInfoPtr spriteInfoP;
slot = gFirstSpriteSlot;
while (slot >= 0)
{
register short numRows;
register short numCols;
register short h;
register short v;
spriteInfoP = &gSpriteInfo[slot];
if (spriteInfoP->status < 0)
goto nextSlot; /* deleted, so skip it */
numRows = spriteInfoP->height;
numCols = spriteInfoP->width;
h = spriteInfoP->position.h;
v = spriteInfoP->position.v;
if (h + numCols <= 0 || h >= gWindowWidth
|| v + numRows <= 0 || v >= gWindowHeight)
goto nextSlot; /* totally offscreen */
DrawSprite(slot);
nextSlot:
slot = spriteInfoP->nextSlot;
}
}
FastCopyChunk
/* count is a multiple of 4 in the range [4..44] */
static void FastCopyChunk(long *q, long *p,
short count, short rows)
{
register short srcRowBytes;
register short dstRowBytes;
register short rowsLeft = rows;
register short copy8 = count & 8;
register short copy4 = count & 4;
srcRowBytes = gOnDeckRowBytes - count;
dstRowBytes = gScreenRowBytes - count;
if (count & 32)
{
while (rowsLeft > 0)
{
rowsLeft--;
*q++ = *p++;
*q++ = *p++;
*q++ = *p++;
*q++ = *p++;
*q++ = *p++;
*q++ = *p++;
*q++ = *p++;
*q++ = *p++;
if (copy8)
{
*q++ = *p++;
*q++ = *p++;
}
if (copy4)
*q++ = *p++;
p = (long *) (((Ptr) p) + srcRowBytes);
q = (long *) (((Ptr) q) + dstRowBytes);
}
}
else if (count & 16)
{
while (rowsLeft > 0)
{
rowsLeft--;
*q++ = *p++;
*q++ = *p++;
*q++ = *p++;
*q++ = *p++;
if (copy8)
{
*q++ = *p++;
*q++ = *p++;
}
if (copy4)
*q++ = *p++;
p = (long *) (((Ptr) p) + srcRowBytes);
q = (long *) (((Ptr) q) + dstRowBytes);
}
}
else
{
while (rowsLeft > 0)
{
rowsLeft--;
if (copy8)
{
*q++ = *p++;
*q++ = *p++;
}
if (copy4)
*q++ = *p++;
p = (long *) (((Ptr) p) + srcRowBytes);
q = (long *) (((Ptr) q) + dstRowBytes);
}
}
}
DrawNewSpritesToScreen
/* Here we do have to watch out for sprites that overlap the edges of the window. We copy a rectangluar
region that includes the sprites previous and current positions. We know they will be close sionce sprites
move at most 8 pixels per turn.
*/
static void DrawNewSpritesToScreen(void)
{
short slot;
SpriteInfoPtr spriteInfoP;
short numRows;
short numCols;
register long *p;
register long *q;
short hStart, hEnd;
short vStart, vEnd;
slot = gFirstSpriteSlot;
while (slot >= 0)
{
spriteInfoP = &gSpriteInfo[slot];
numRows = spriteInfoP->height;
numCols = spriteInfoP->width;
if (spriteInfoP->position.h
< spriteInfoP->lastPosition.h)
{
hStart = spriteInfoP->position.h;
hEnd = spriteInfoP->lastPosition.h + numCols;
}
else
{
hStart = spriteInfoP->lastPosition.h;
hEnd = spriteInfoP->position.h + numCols;
}
if (hStart < 0)
hStart = 0;
else if (hEnd > gWindowWidth)
hEnd = gWindowWidth;
if (spriteInfoP->position.v
< spriteInfoP->lastPosition.v)
{
vStart = spriteInfoP->position.v;
vEnd = spriteInfoP->lastPosition.v + numRows;
}
else
{
vStart = spriteInfoP->lastPosition.v;
vEnd = spriteInfoP->position.v + numRows;
}
if (vStart < 0)
vStart = 0;
else if (vEnd > gWindowHeight)
vEnd = gWindowHeight;
hStart = hStart & -4; /* make it a mult of 4 */
hEnd = (hEnd + 3) & -4; /* make it a mult of 4 */
p = (long *) (gOnDeckRowAddr[vStart] + hStart);
q = (long *) (gScreenRowAddr[vStart] + hStart);
vEnd -= vStart; /* now it’s a count */
hEnd -= hStart; /* now it’s a count */
if (hEnd >= 0)
FastCopyChunk(q, p, hEnd, vEnd);
spriteInfoP->lastPosition = spriteInfoP->position;
slot = spriteInfoP->nextSlot;
}
}
UpdateScreen
void UpdateScreen(void)
{
EraseOldSprites();
DrawNewSprites();
DrawNewSpritesToScreen();
if (gDeletionCount != 0)
RemoveDeletedSprites();
}
