1
  2
  3
  4
  5
  6
  7
  8
  9
 10
 11
 12
 13
 14
 15
 16
 17
 18
 19
 20
 21
 22
 23
 24
 25
 26
 27
 28
 29
 30
 31
 32
 33
 34
 35
 36
 37
 38
 39
 40
 41
 42
 43
 44
 45
 46
 47
 48
 49
 50
 51
 52
 53
 54
 55
 56
 57
 58
 59
 60
 61
 62
 63
 64
 65
 66
 67
 68
 69
 70
 71
 72
 73
 74
 75
 76
 77
 78
 79
 80
 81
 82
 83
 84
 85
 86
 87
 88
 89
 90
 91
 92
 93
 94
 95
 96
 97
 98
 99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
//! Almost direct (but slightly optimized) Rust translation of Figure 3 of "Printing
//! Floating-Point Numbers Quickly and Accurately"[^1].
//!
//! [^1]: Burger, R. G. and Dybvig, R. K. 1996. Printing floating-point numbers
//!   quickly and accurately. SIGPLAN Not. 31, 5 (May. 1996), 108-116.

use crate::cmp::Ordering;
use crate::mem::MaybeUninit;

use crate::num::bignum::Big32x40 as Big;
use crate::num::bignum::Digit32 as Digit;
use crate::num::flt2dec::estimator::estimate_scaling_factor;
use crate::num::flt2dec::{round_up, Decoded, MAX_SIG_DIGITS};

static POW10: [Digit; 10] =
    [1, 10, 100, 1000, 10000, 100000, 1000000, 10000000, 100000000, 1000000000];
static TWOPOW10: [Digit; 10] =
    [2, 20, 200, 2000, 20000, 200000, 2000000, 20000000, 200000000, 2000000000];

// precalculated arrays of `Digit`s for 10^(2^n)
static POW10TO16: [Digit; 2] = [0x6fc10000, 0x2386f2];
static POW10TO32: [Digit; 4] = [0, 0x85acef81, 0x2d6d415b, 0x4ee];
static POW10TO64: [Digit; 7] = [0, 0, 0xbf6a1f01, 0x6e38ed64, 0xdaa797ed, 0xe93ff9f4, 0x184f03];
static POW10TO128: [Digit; 14] = [
    0, 0, 0, 0, 0x2e953e01, 0x3df9909, 0xf1538fd, 0x2374e42f, 0xd3cff5ec, 0xc404dc08, 0xbccdb0da,
    0xa6337f19, 0xe91f2603, 0x24e,
];
static POW10TO256: [Digit; 27] = [
    0, 0, 0, 0, 0, 0, 0, 0, 0x982e7c01, 0xbed3875b, 0xd8d99f72, 0x12152f87, 0x6bde50c6, 0xcf4a6e70,
    0xd595d80f, 0x26b2716e, 0xadc666b0, 0x1d153624, 0x3c42d35a, 0x63ff540e, 0xcc5573c0, 0x65f9ef17,
    0x55bc28f2, 0x80dcc7f7, 0xf46eeddc, 0x5fdcefce, 0x553f7,
];

#[doc(hidden)]
pub fn mul_pow10(x: &mut Big, n: usize) -> &mut Big {
    debug_assert!(n < 512);
    if n & 7 != 0 {
        x.mul_small(POW10[n & 7]);
    }
    if n & 8 != 0 {
        x.mul_small(POW10[8]);
    }
    if n & 16 != 0 {
        x.mul_digits(&POW10TO16);
    }
    if n & 32 != 0 {
        x.mul_digits(&POW10TO32);
    }
    if n & 64 != 0 {
        x.mul_digits(&POW10TO64);
    }
    if n & 128 != 0 {
        x.mul_digits(&POW10TO128);
    }
    if n & 256 != 0 {
        x.mul_digits(&POW10TO256);
    }
    x
}

fn div_2pow10(x: &mut Big, mut n: usize) -> &mut Big {
    let largest = POW10.len() - 1;
    while n > largest {
        x.div_rem_small(POW10[largest]);
        n -= largest;
    }
    x.div_rem_small(TWOPOW10[n]);
    x
}

// only usable when `x < 16 * scale`; `scaleN` should be `scale.mul_small(N)`
fn div_rem_upto_16<'a>(
    x: &'a mut Big,
    scale: &Big,
    scale2: &Big,
    scale4: &Big,
    scale8: &Big,
) -> (u8, &'a mut Big) {
    let mut d = 0;
    if *x >= *scale8 {
        x.sub(scale8);
        d += 8;
    }
    if *x >= *scale4 {
        x.sub(scale4);
        d += 4;
    }
    if *x >= *scale2 {
        x.sub(scale2);
        d += 2;
    }
    if *x >= *scale {
        x.sub(scale);
        d += 1;
    }
    debug_assert!(*x < *scale);
    (d, x)
}

/// The shortest mode implementation for Dragon.
pub fn format_shortest<'a>(
    d: &Decoded,
    buf: &'a mut [MaybeUninit<u8>],
) -> (/*digits*/ &'a [u8], /*exp*/ i16) {
    // the number `v` to format is known to be:
    // - equal to `mant * 2^exp`;
    // - preceded by `(mant - 2 * minus) * 2^exp` in the original type; and
    // - followed by `(mant + 2 * plus) * 2^exp` in the original type.
    //
    // obviously, `minus` and `plus` cannot be zero. (for infinities, we use out-of-range values.)
    // also we assume that at least one digit is generated, i.e., `mant` cannot be zero too.
    //
    // this also means that any number between `low = (mant - minus) * 2^exp` and
    // `high = (mant + plus) * 2^exp` will map to this exact floating point number,
    // with bounds included when the original mantissa was even (i.e., `!mant_was_odd`).

    assert!(d.mant > 0);
    assert!(d.minus > 0);
    assert!(d.plus > 0);
    assert!(d.mant.checked_add(d.plus).is_some());
    assert!(d.mant.checked_sub(d.minus).is_some());
    assert!(buf.len() >= MAX_SIG_DIGITS);

    // `a.cmp(&b) < rounding` is `if d.inclusive {a <= b} else {a < b}`
    let rounding = if d.inclusive { Ordering::Greater } else { Ordering::Equal };

    // estimate `k_0` from original inputs satisfying `10^(k_0-1) < high <= 10^(k_0+1)`.
    // the tight bound `k` satisfying `10^(k-1) < high <= 10^k` is calculated later.
    let mut k = estimate_scaling_factor(d.mant + d.plus, d.exp);

    // convert `{mant, plus, minus} * 2^exp` into the fractional form so that:
    // - `v = mant / scale`
    // - `low = (mant - minus) / scale`
    // - `high = (mant + plus) / scale`
    let mut mant = Big::from_u64(d.mant);
    let mut minus = Big::from_u64(d.minus);
    let mut plus = Big::from_u64(d.plus);
    let mut scale = Big::from_small(1);
    if d.exp < 0 {
        scale.mul_pow2(-d.exp as usize);
    } else {
        mant.mul_pow2(d.exp as usize);
        minus.mul_pow2(d.exp as usize);
        plus.mul_pow2(d.exp as usize);
    }

    // divide `mant` by `10^k`. now `scale / 10 < mant + plus <= scale * 10`.
    if k >= 0 {
        mul_pow10(&mut scale, k as usize);
    } else {
        mul_pow10(&mut mant, -k as usize);
        mul_pow10(&mut minus, -k as usize);
        mul_pow10(&mut plus, -k as usize);
    }

    // fixup when `mant + plus > scale` (or `>=`).
    // we are not actually modifying `scale`, since we can skip the initial multiplication instead.
    // now `scale < mant + plus <= scale * 10` and we are ready to generate digits.
    //
    // note that `d[0]` *can* be zero, when `scale - plus < mant < scale`.
    // in this case rounding-up condition (`up` below) will be triggered immediately.
    if scale.cmp(mant.clone().add(&plus)) < rounding {
        // equivalent to scaling `scale` by 10
        k += 1;
    } else {
        mant.mul_small(10);
        minus.mul_small(10);
        plus.mul_small(10);
    }

    // cache `(2, 4, 8) * scale` for digit generation.
    let mut scale2 = scale.clone();
    scale2.mul_pow2(1);
    let mut scale4 = scale.clone();
    scale4.mul_pow2(2);
    let mut scale8 = scale.clone();
    scale8.mul_pow2(3);

    let mut down;
    let mut up;
    let mut i = 0;
    loop {
        // invariants, where `d[0..n-1]` are digits generated so far:
        // - `v = mant / scale * 10^(k-n-1) + d[0..n-1] * 10^(k-n)`
        // - `v - low = minus / scale * 10^(k-n-1)`
        // - `high - v = plus / scale * 10^(k-n-1)`
        // - `(mant + plus) / scale <= 10` (thus `mant / scale < 10`)
        // where `d[i..j]` is a shorthand for `d[i] * 10^(j-i) + ... + d[j-1] * 10 + d[j]`.

        // generate one digit: `d[n] = floor(mant / scale) < 10`.
        let (d, _) = div_rem_upto_16(&mut mant, &scale, &scale2, &scale4, &scale8);
        debug_assert!(d < 10);
        buf[i] = MaybeUninit::new(b'0' + d);
        i += 1;

        // this is a simplified description of the modified Dragon algorithm.
        // many intermediate derivations and completeness arguments are omitted for convenience.
        //
        // start with modified invariants, as we've updated `n`:
        // - `v = mant / scale * 10^(k-n) + d[0..n-1] * 10^(k-n)`
        // - `v - low = minus / scale * 10^(k-n)`
        // - `high - v = plus / scale * 10^(k-n)`
        //
        // assume that `d[0..n-1]` is the shortest representation between `low` and `high`,
        // i.e., `d[0..n-1]` satisfies both of the following but `d[0..n-2]` doesn't:
        // - `low < d[0..n-1] * 10^(k-n) < high` (bijectivity: digits round to `v`); and
        // - `abs(v / 10^(k-n) - d[0..n-1]) <= 1/2` (the last digit is correct).
        //
        // the second condition simplifies to `2 * mant <= scale`.
        // solving invariants in terms of `mant`, `low` and `high` yields
        // a simpler version of the first condition: `-plus < mant < minus`.
        // since `-plus < 0 <= mant`, we have the correct shortest representation
        // when `mant < minus` and `2 * mant <= scale`.
        // (the former becomes `mant <= minus` when the original mantissa is even.)
        //
        // when the second doesn't hold (`2 * mant > scale`), we need to increase the last digit.
        // this is enough for restoring that condition: we already know that
        // the digit generation guarantees `0 <= v / 10^(k-n) - d[0..n-1] < 1`.
        // in this case, the first condition becomes `-plus < mant - scale < minus`.
        // since `mant < scale` after the generation, we have `scale < mant + plus`.
        // (again, this becomes `scale <= mant + plus` when the original mantissa is even.)
        //
        // in short:
        // - stop and round `down` (keep digits as is) when `mant < minus` (or `<=`).
        // - stop and round `up` (increase the last digit) when `scale < mant + plus` (or `<=`).
        // - keep generating otherwise.
        down = mant.cmp(&minus) < rounding;
        up = scale.cmp(mant.clone().add(&plus)) < rounding;
        if down || up {
            break;
        } // we have the shortest representation, proceed to the rounding

        // restore the invariants.
        // this makes the algorithm always terminating: `minus` and `plus` always increases,
        // but `mant` is clipped modulo `scale` and `scale` is fixed.
        mant.mul_small(10);
        minus.mul_small(10);
        plus.mul_small(10);
    }

    // rounding up happens when
    // i) only the rounding-up condition was triggered, or
    // ii) both conditions were triggered and tie breaking prefers rounding up.
    if up && (!down || *mant.mul_pow2(1) >= scale) {
        // if rounding up changes the length, the exponent should also change.
        // it seems that this condition is very hard to satisfy (possibly impossible),
        // but we are just being safe and consistent here.
        // SAFETY: we initialized that memory above.
        if let Some(c) = round_up(unsafe { MaybeUninit::slice_assume_init_mut(&mut buf[..i]) }) {
            buf[i] = MaybeUninit::new(c);
            i += 1;
            k += 1;
        }
    }

    // SAFETY: we initialized that memory above.
    (unsafe { MaybeUninit::slice_assume_init_ref(&buf[..i]) }, k)
}

/// The exact and fixed mode implementation for Dragon.
pub fn format_exact<'a>(
    d: &Decoded,
    buf: &'a mut [MaybeUninit<u8>],
    limit: i16,
) -> (/*digits*/ &'a [u8], /*exp*/ i16) {
    assert!(d.mant > 0);
    assert!(d.minus > 0);
    assert!(d.plus > 0);
    assert!(d.mant.checked_add(d.plus).is_some());
    assert!(d.mant.checked_sub(d.minus).is_some());

    // estimate `k_0` from original inputs satisfying `10^(k_0-1) < v <= 10^(k_0+1)`.
    let mut k = estimate_scaling_factor(d.mant, d.exp);

    // `v = mant / scale`.
    let mut mant = Big::from_u64(d.mant);
    let mut scale = Big::from_small(1);
    if d.exp < 0 {
        scale.mul_pow2(-d.exp as usize);
    } else {
        mant.mul_pow2(d.exp as usize);
    }

    // divide `mant` by `10^k`. now `scale / 10 < mant <= scale * 10`.
    if k >= 0 {
        mul_pow10(&mut scale, k as usize);
    } else {
        mul_pow10(&mut mant, -k as usize);
    }

    // fixup when `mant + plus >= scale`, where `plus / scale = 10^-buf.len() / 2`.
    // in order to keep the fixed-size bignum, we actually use `mant + floor(plus) >= scale`.
    // we are not actually modifying `scale`, since we can skip the initial multiplication instead.
    // again with the shortest algorithm, `d[0]` can be zero but will be eventually rounded up.
    if *div_2pow10(&mut scale.clone(), buf.len()).add(&mant) >= scale {
        // equivalent to scaling `scale` by 10
        k += 1;
    } else {
        mant.mul_small(10);
    }

    // if we are working with the last-digit limitation, we need to shorten the buffer
    // before the actual rendering in order to avoid double rounding.
    // note that we have to enlarge the buffer again when rounding up happens!
    let mut len = if k < limit {
        // oops, we cannot even produce *one* digit.
        // this is possible when, say, we've got something like 9.5 and it's being rounded to 10.
        // we return an empty buffer, with an exception of the later rounding-up case
        // which occurs when `k == limit` and has to produce exactly one digit.
        0
    } else if ((k as i32 - limit as i32) as usize) < buf.len() {
        (k - limit) as usize
    } else {
        buf.len()
    };

    if len > 0 {
        // cache `(2, 4, 8) * scale` for digit generation.
        // (this can be expensive, so do not calculate them when the buffer is empty.)
        let mut scale2 = scale.clone();
        scale2.mul_pow2(1);
        let mut scale4 = scale.clone();
        scale4.mul_pow2(2);
        let mut scale8 = scale.clone();
        scale8.mul_pow2(3);

        for i in 0..len {
            if mant.is_zero() {
                // following digits are all zeroes, we stop here
                // do *not* try to perform rounding! rather, fill remaining digits.
                for c in &mut buf[i..len] {
                    *c = MaybeUninit::new(b'0');
                }
                // SAFETY: we initialized that memory above.
                return (unsafe { MaybeUninit::slice_assume_init_ref(&buf[..len]) }, k);
            }

            let mut d = 0;
            if mant >= scale8 {
                mant.sub(&scale8);
                d += 8;
            }
            if mant >= scale4 {
                mant.sub(&scale4);
                d += 4;
            }
            if mant >= scale2 {
                mant.sub(&scale2);
                d += 2;
            }
            if mant >= scale {
                mant.sub(&scale);
                d += 1;
            }
            debug_assert!(mant < scale);
            debug_assert!(d < 10);
            buf[i] = MaybeUninit::new(b'0' + d);
            mant.mul_small(10);
        }
    }

    // rounding up if we stop in the middle of digits
    // if the following digits are exactly 5000..., check the prior digit and try to
    // round to even (i.e., avoid rounding up when the prior digit is even).
    let order = mant.cmp(scale.mul_small(5));
    if order == Ordering::Greater
        || (order == Ordering::Equal
            // SAFETY: `buf[len-1]` is initialized.
            && (len == 0 || unsafe { buf[len - 1].assume_init() } & 1 == 1))
    {
        // if rounding up changes the length, the exponent should also change.
        // but we've been requested a fixed number of digits, so do not alter the buffer...
        // SAFETY: we initialized that memory above.
        if let Some(c) = round_up(unsafe { MaybeUninit::slice_assume_init_mut(&mut buf[..len]) }) {
            // ...unless we've been requested the fixed precision instead.
            // we also need to check that, if the original buffer was empty,
            // the additional digit can only be added when `k == limit` (edge case).
            k += 1;
            if k > limit && len < buf.len() {
                buf[len] = MaybeUninit::new(c);
                len += 1;
            }
        }
    }

    // SAFETY: we initialized that memory above.
    (unsafe { MaybeUninit::slice_assume_init_ref(&buf[..len]) }, k)
}