;* ======================================================================== *; ;* These routines are placed into the public domain by their author. All *; ;* copyright rights are hereby relinquished on the routines and data in *; ;* this file. -- Joseph Zbiciak, 2008 *; ;* ======================================================================== *; ;; ======================================================================== ;; ;; DIST_FAST Approximate the distance between two points to 4% error. ;; ;; DIST_FAST.1 Alternate entry point ;; ;; ;; ;; AUTHOR ;; ;; Joseph Zbiciak ;; ;; ;; ;; REVISION HISTORY ;; ;; 22-Apr-2002 Initial Revision ;; ;; ;; ;; INPUTS for DIST_FAST ;; ;; R0 Coordinate x0 ;; ;; R1 Coordinate y0 ;; ;; R2 Coordinate x1 ;; ;; R3 Coordinate y1 ;; ;; R5 Return address ;; ;; ;; ;; INPUTS for DIST_FAST.1 ;; ;; R2 Absolute value of delta-X (eg. abs(x0 - x1)) ;; ;; R3 Absolute value of delta-Y (eg. abs(y0 - y1)) ;; ;; R5 Return address ;; ;; ;; ;; OUTPUTS ;; ;; R0 Unchanged ;; ;; R1 Trashed ;; ;; R2 Trashed ;; ;; R3 Approximate Euclidean distance from (x0, y0) to (x1, y1). ;; ;; ;; ;; NOTES ;; ;; This returns a value which is approximately sqrt(dx**2 + dy**2), ;; ;; within 4%. This should be sufficient for most applications. ;; ;; ;; ;; The code accepts unsigned 16-bit values for the incoming ;; ;; coordinates, and should correctly calculate abs(x0 - x1) ;; ;; and abs(y0 - y1) for the full 16-bit range. ;; ;; ;; ;; The output should have the same dynamic range as the inputs. ;; ;; Thus, if the inputs are in an 8-bit range, so will be the ;; ;; output. If the inputs are in a 16-bit range, so is the output. ;; ;; ;; ;; Although the arguments list R0 and R2 as the X coordinates ;; ;; and R1 and R3 as the Y coordinates, these assignments may be ;; ;; swapped. (eg. R1 and R3 are X coordinates, R0 and R2 are Y ;; ;; coordinates.) Euclidean distance doesn't change when you rotate ;; ;; the page 90 degrees or flip it over. :-) ;; ;; ;; ;; SOURCE ;; ;; Graphics Gems IV (see C code below) ;; ;; ;; ;; C code from the article ;; ;; "Fast Linear Approximations of Euclidean Distance in ;; ;; Higher Dimensions" by Yoshikazu Ohashi, yoshi@cognex.com ;; ;; in "Graphics Gems IV", Academic Press, 1994 ;; ;; ;; ;; /* 2-D Euclidean distance approximation */ ;; ;; /* c1 = 123/128, c2 = 51/128 and max(e) = 4.0% */ ;; ;; int veclen2 (int ix, int iy) ;; ;; { ;; ;; int t; ;; ;; ;; ;; ix= (ix<0 ? -ix : ix); /* absolute values */ ;; ;; iy= (iy<0 ? -iy : iy); ;; ;; ;; ;; if(ix>1); ;; ;; ;; ;; /* return (123 * ix + 51 * iy) / 128; */ ;; ;; return (ix - (ix>>5) - (ix>>7) + (t>>2) + (t>>6)); ;; ;; } ;; ;; ;; ;; CODESIZE ;; ;; 28 words ;; ;; ;; ;; CYCLES ;; ;; 150 to 178 cycles for DIST_FAST. ;; ;; 124 to 140 cycles for DIST_FAST.1. ;; ;; ;; ;; ======================================================================== ;; DIST_FAST PROC SUBR R0, R2 ; 6 ADCR PC ; 7 Skip negr if R2 was greater than R0 NEGR R2 ; 6 ;---- ; 13 best case ; 19 worst case SUBR R1, R3 ; 6 ADCR PC ; 7 Skip negr if R3 was greater than R1 NEGR R3 ; 6 ;---- ; 26 best case ; 38 worst case @@1: CMPR R2, R3 ; 6 Put larger value in R3 BC @@no_swap ; 9/7 XORR R2, R3 ; 6 \ XORR R3, R2 ; 6 |-- Swap R2 and R3 if necessary. XORR R2, R3 ; 6 / ;---- ; 41 best case ; 69 worst case @@no_swap: MOVR R2, R1 ; 6 SLR R1, 1 ; 6 ADDR R1, R2 ; 6 t = iy + (iy >> 1) MOVR R3, R1 ; 6 SLR R1, 2 ; 8 SLR R1, 2 ; 8 SLR R1, 1 ; 6 R1 = ix >> 5 SUBR R1, R3 ; 6 R3 = ix - (ix>>5) SLR R1, 2 ; 8 R1 = ix >> 7 SUBR R1, R3 ; 6 R3 = ix - (ix>>5) - (ix>>7) SLR R2, 2 ; 8 R2 = t >> 2 ADDR R2, R3 ; 6 R3 = ix - (ix>>5) - (ix>>7) + (t>>2) SLR R2, 2 ; 8 SLR R2, 2 ; 8 R2 = t >> 6 ADDR R2, R3 ; 6 R3 = ix - (ix>>5) - (ix>>7) + (t>>2) + (t>>6) ;---- ; 143 best case ; 171 worst case JR R5 ; 7 ;---- ; 150 best case ; 178 worst case ENDP ;; ======================================================================== ;; ;; End of File: dist_fast.asm ;; ;; ======================================================================== ;;