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1.1 ! root 1: /* ! 2: * Copyright (c) 1980 Regents of the University of California. ! 3: * All rights reserved. ! 4: * ! 5: * Redistribution and use in source and binary forms are permitted ! 6: * provided that: (1) source distributions retain this entire copyright ! 7: * notice and comment, and (2) distributions including binaries display ! 8: * the following acknowledgement: ``This product includes software ! 9: * developed by the University of California, Berkeley and its contributors'' ! 10: * in the documentation or other materials provided with the distribution ! 11: * and in all advertising materials mentioning features or use of this ! 12: * software. Neither the name of the University nor the names of its ! 13: * contributors may be used to endorse or promote products derived ! 14: * from this software without specific prior written permission. ! 15: * THIS SOFTWARE IS PROVIDED ``AS IS'' AND WITHOUT ANY EXPRESS OR ! 16: * IMPLIED WARRANTIES, INCLUDING, WITHOUT LIMITATION, THE IMPLIED ! 17: * WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE. ! 18: */ ! 19: ! 20: #if defined(LIBC_SCCS) && !defined(lint) ! 21: .asciz "@(#)atof.s 5.6 (Berkeley) 6/1/90" ! 22: #endif /* LIBC_SCCS and not lint */ ! 23: ! 24: #include "DEFS.h" ! 25: ! 26: /* ! 27: * atof: convert ascii to floating ! 28: * ! 29: * C usage: ! 30: * ! 31: * double atof (s) ! 32: * char *s; ! 33: * ! 34: * Register usage: ! 35: * ! 36: * r0-1: value being developed ! 37: * r2: first section: pointer to the next character ! 38: * second section: binary exponent ! 39: * r3: flags ! 40: * r4: first section: the current character ! 41: * second section: scratch ! 42: * r5: the decimal exponent ! 43: * r6-7: scratch ! 44: */ ! 45: .set msign,0 # mantissa has negative sign ! 46: .set esign,1 # exponent has negative sign ! 47: .set decpt,2 # decimal point encountered ! 48: ! 49: ENTRY(atof, R6|R7) ! 50: /* ! 51: * Initialization ! 52: */ ! 53: clrl r3 # All flags start out false ! 54: movl 4(ap),r2 # Address the first character ! 55: clrl r5 # Clear starting exponent ! 56: /* ! 57: * Skip leading white space ! 58: */ ! 59: sk0: movzbl (r2)+,r4 # Fetch the next (first) character ! 60: cmpb $' ,r4 # Is it blank? ! 61: jeql sk0 # ...yes ! 62: cmpb r4,$8 # 8 is lowest of white-space group ! 63: jlss sk1 # Jump if char too low to be white space ! 64: cmpb r4,$13 # 13 is highest of white-space group ! 65: jleq sk0 # Jump if character is white space ! 66: sk1: ! 67: /* ! 68: * Check for a sign ! 69: */ ! 70: cmpb $'+,r4 # Positive sign? ! 71: jeql cs1 # ... yes ! 72: cmpb $'-,r4 # Negative sign? ! 73: jneq cs2 # ... no ! 74: bisb2 $1<msign,r3 # Indicate a negative mantissa ! 75: cs1: movzbl (r2)+,r4 # Skip the character ! 76: cs2: ! 77: /* ! 78: * Accumulate digits, keeping track of the exponent ! 79: */ ! 80: clrq r0 # Clear the accumulator ! 81: ad0: cmpb r4,$'0 # Do we have a digit? ! 82: jlss ad4 # ... no, too small ! 83: cmpb r4,$'9 ! 84: jgtr ad4 # ... no, too large ! 85: /* ! 86: * We got a digit. Accumulate it ! 87: */ ! 88: cmpl r1,$214748364 # Would this digit cause overflow? ! 89: jgeq ad1 # ... yes ! 90: /* ! 91: * Multiply (r0,r1) by 10. This is done by developing ! 92: * (r0,r1)*2 in (r6,r7), shifting (r0,r1) left three bits, ! 93: * and adding the two quadwords. ! 94: */ ! 95: ashq $1,r0,r6 # (r6,r7)=(r0,r1)*2 ! 96: ashq $3,r0,r0 # (r0,r1)=(r0,r1)*8 ! 97: addl2 r6,r0 # Add low halves ! 98: adwc r7,r1 # Add high halves ! 99: /* ! 100: * Add in the digit ! 101: */ ! 102: subl2 $'0,r4 # Get the digit value ! 103: addl2 r4,r0 # Add it into the accumulator ! 104: adwc $0,r1 # Possible carry into high half ! 105: jbr ad2 # Join common code ! 106: /* ! 107: * Here when the digit won't fit in the accumulator ! 108: */ ! 109: ad1: incl r5 # Ignore the digit, bump exponent ! 110: /* ! 111: * If we have seen a decimal point, decrease the exponent by 1 ! 112: */ ! 113: ad2: jbc $decpt,r3,ad3 # Jump if decimal point not seen ! 114: decl r5 # Decrease exponent ! 115: ad3: ! 116: /* ! 117: * Fetch the next character, back for more ! 118: */ ! 119: movzbl (r2)+,r4 # Fetch ! 120: jbr ad0 # Try again ! 121: /* ! 122: * Not a digit. Could it be a decimal point? ! 123: */ ! 124: ad4: cmpb r4,$'. # If it's not a decimal point, either it's ! 125: jneq ad5 # the end of the number or the start of ! 126: # the exponent. ! 127: jbcs $decpt,r3,ad3 # If it IS a decimal point, we record that ! 128: # we've seen one, and keep collecting ! 129: # digits if it is the first one. ! 130: /* ! 131: * Check for an exponent ! 132: */ ! 133: ad5: clrl r6 # Initialize the exponent accumulator ! 134: ! 135: cmpb r4,$'e # We allow both lower case e ! 136: jeql ex1 # ... and ... ! 137: cmpb r4,$'E # upper-case E ! 138: jneq ex7 ! 139: /* ! 140: * Does the exponent have a sign? ! 141: */ ! 142: ex1: movzbl (r2)+,r4 # Get next character ! 143: cmpb r4,$'+ # Positive sign? ! 144: jeql ex2 # ... yes ... ! 145: cmpb r4,$'- # Negative sign? ! 146: jneq ex3 # ... no ... ! 147: bisb2 $1<esign,r3 # Indicate exponent is negative ! 148: ex2: movzbl (r2)+,r4 # Grab the next character ! 149: /* ! 150: * Accumulate exponent digits in r6 ! 151: */ ! 152: ex3: cmpb r4,$'0 # A digit is within the range ! 153: jlss ex4 # '0' through ! 154: cmpb r4,$'9 # '9', ! 155: jgtr ex4 # inclusive. ! 156: cmpl r6,$214748364 # Exponent outrageously large already? ! 157: jgeq ex2 # ... yes ! 158: moval (r6)[r6],r6 # r6 *= 5 ! 159: movaw -'0(r4)[r6],r6 # r6 = r6 * 2 + r4 - '0' ! 160: jbr ex2 # Go 'round again ! 161: ex4: ! 162: /* ! 163: * Now get the final exponent and force it within a reasonable ! 164: * range so our scaling loops don't take forever for values ! 165: * that will ultimately cause overflow or underflow anyway. ! 166: * A tight check on over/underflow will be done by ldexp. ! 167: */ ! 168: jbc $esign,r3,ex5 # Jump if exponent not negative ! 169: mnegl r6,r6 # If sign, negate exponent ! 170: ex5: addl2 r6,r5 # Add given exponent to calculated exponent ! 171: cmpl r5,$-100 # Absurdly small? ! 172: jgtr ex6 # ... no ! 173: movl $-100,r5 # ... yes, force within limit ! 174: ex6: cmpl r5,$100 # Absurdly large? ! 175: jlss ex7 # ... no ! 176: movl $100,r5 # ... yes, force within bounds ! 177: ex7: ! 178: /* ! 179: * Our number has now been reduced to a mantissa and an exponent. ! 180: * The mantissa is a 63-bit positive binary integer in r0,r1, ! 181: * and the exponent is a signed power of 10 in r5. The msign ! 182: * bit in r3 will be on if the mantissa should ultimately be ! 183: * considered negative. ! 184: * ! 185: * We now have to convert it to a standard format floating point ! 186: * number. This will be done by accumulating a binary exponent ! 187: * in r2, as we progressively get r5 closer to zero. ! 188: * ! 189: * Don't bother scaling if the mantissa is zero ! 190: */ ! 191: movq r0,r0 # Mantissa zero? ! 192: jeql exit # ... yes ! 193: ! 194: clrl r2 # Initialize binary exponent ! 195: tstl r5 # Which way to scale? ! 196: jleq sd0 # Scale down if decimal exponent <= 0 ! 197: /* ! 198: * Scale up by "multiplying" r0,r1 by 10 as many times as necessary, ! 199: * as follows: ! 200: * ! 201: * Step 1: Shift r0,r1 right as necessary to ensure that no ! 202: * overflow can occur when multiplying. ! 203: */ ! 204: su0: cmpl r1,$429496729 # Compare high word to (2**31)/5 ! 205: jlss su1 # Jump out if guaranteed safe ! 206: ashq $-1,r0,r0 # Else shift right one bit ! 207: incl r2 # bump exponent to compensate ! 208: jbr su0 # and go back to test again. ! 209: /* ! 210: * Step 2: Multiply r0,r1 by 5, by appropriate shifting and ! 211: * double-precision addition ! 212: */ ! 213: su1: ashq $2,r0,r6 # (r6,r7) := (r0,r1) * 4 ! 214: addl2 r6,r0 # Add low-order halves ! 215: adwc r7,r1 # and high-order halves ! 216: /* ! 217: * Step 3: Increment the binary exponent to take care of the final ! 218: * factor of 2, and go back if we still need to scale more. ! 219: */ ! 220: incl r2 # Increment the exponent ! 221: sobgtr r5,su0 # and back for more (maybe) ! 222: ! 223: jbr cm0 # Merge to build final value ! 224: ! 225: /* ! 226: * Scale down. We must "divide" r0,r1 by 10 as many times ! 227: * as needed, as follows: ! 228: * ! 229: * Step 0: Right now, the condition codes reflect the state ! 230: * of r5. If it's zero, we are done. ! 231: */ ! 232: sd0: jeql cm0 # If finished, build final number ! 233: /* ! 234: * Step 1: Shift r0,r1 left until the high-order bit (not counting ! 235: * the sign bit) is nonzero, so that the division will preserve ! 236: * as much precision as possible. ! 237: */ ! 238: tstl r1 # Is the entire high-order half zero? ! 239: jneq sd2 # ...no, go shift one bit at a time ! 240: ashq $30,r0,r0 # ...yes, shift left 30, ! 241: subl2 $30,r2 # decrement the exponent to compensate, ! 242: # and now it's known to be safe to shift ! 243: # at least once more. ! 244: sd1: ashq $1,r0,r0 # Shift (r0,r1) left one, and ! 245: decl r2 # decrement the exponent to compensate ! 246: sd2: jbc $30,r1,sd1 # If the high-order bit is off, go shift ! 247: /* ! 248: * Step 2: Divide the high-order part of (r0,r1) by 5, ! 249: * giving a quotient in r1 and a remainder in r7. ! 250: */ ! 251: sd3: movl r1,r6 # Copy the high-order part ! 252: clrl r7 # Zero-extend to 64 bits ! 253: ediv $5,r6,r1,r7 # Divide (cannot overflow) ! 254: /* ! 255: * Step 3: Divide the low-order part of (r0,r1) by 5, ! 256: * using the remainder from step 2 for rounding. ! 257: * Note that the result of this computation is unsigned, ! 258: * so we have to allow for the fact that an ordinary division ! 259: * by 5 could overflow. We make allowance by dividing by 10, ! 260: * multiplying the quotient by 2, and using the remainder ! 261: * to adjust the modified quotient. ! 262: */ ! 263: addl3 $2,r0,r6 # Dividend is low part of (r0,r1) plus ! 264: adwc $0,r7 # 2 for rounding plus ! 265: # (2**32) * previous remainder ! 266: ediv $10,r6,r0,r6 # r0 := quotient, r6 := remainder. ! 267: addl2 r0,r0 # Make r0 result of dividing by 5 ! 268: cmpl r6,$5 # If remainder is 5 or greater, ! 269: jlss sd4 # increment the adjustted quotient. ! 270: incl r0 ! 271: /* ! 272: * Step 4: Increment the decimal exponent, decrement the binary ! 273: * exponent (to make the division by 5 into a division by 10), ! 274: * and back for another iteration. ! 275: */ ! 276: sd4: decl r2 # Binary exponent ! 277: aoblss $0,r5,sd2 ! 278: /* ! 279: * We now have the following: ! 280: * ! 281: * r0: low-order half of a 64-bit integer ! 282: * r1: high-order half of the same 64-bit integer ! 283: * r2: a binary exponent ! 284: * ! 285: * Our final result is the integer represented by (r0,r1) ! 286: * multiplied by 2 to the power contained in r2. ! 287: * We will transform (r0,r1) into a floating-point value, ! 288: * set the sign appropriately, and let ldexp do the ! 289: * rest of the work. ! 290: * ! 291: * Step 1: if the high-order bit (excluding the sign) of ! 292: * the high-order half (r1) is 1, then we have 63 bits of ! 293: * fraction, too many to convert easily. However, we also ! 294: * know we won't need them all, so we will just throw the ! 295: * low-order bit away (and adjust the exponent appropriately). ! 296: */ ! 297: cm0: jbc $30,r1,cm1 # jump if no adjustment needed ! 298: ashq $-1,r0,r0 # lose the low-order bit ! 299: incl r2 # increase the exponent to compensate ! 300: /* ! 301: * Step 2: split the 62-bit number in (r0,r1) into two ! 302: * 31-bit positive quantities ! 303: */ ! 304: cm1: ashq $1,r0,r0 # put the high-order bits in r1 ! 305: # and a 0 in the bottom of r0 ! 306: rotl $-1,r0,r0 # right-justify the bits in r0 ! 307: # moving the 0 from the ashq ! 308: # into the sign bit. ! 309: /* ! 310: * Step 3: convert both halves to floating point ! 311: */ ! 312: cvtld r0,r6 # low-order part in r6-r7 ! 313: cvtld r1,r0 # high-order part in r0-r1 ! 314: /* ! 315: * Step 4: multiply the high order part by 2**31 and combine them ! 316: */ ! 317: muld2 two31,r0 # multiply ! 318: addd2 r6,r0 # combine ! 319: /* ! 320: * Step 5: if appropriate, negate the floating value ! 321: */ ! 322: jbc $msign,r3,cm2 # Jump if mantissa not signed ! 323: mnegd r0,r0 # If negative, make it so ! 324: /* ! 325: * Step 6: call ldexp to complete the job ! 326: */ ! 327: cm2: pushl r2 # Put exponent in parameter list ! 328: movd r0,-(sp) # and also mantissa ! 329: calls $3,_ldexp # go combine them ! 330: ! 331: exit: ! 332: ret ! 333: ! 334: .align 2 ! 335: two31: .word 0x5000 # 2 ** 31 ! 336: .word 0 # (=2147483648) ! 337: .word 0 # in floating-point ! 338: .word 0 # (so atof doesn't have to convert it)
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