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@ -199,3 +199,272 @@ In addition to these, user code may have some practical dependencies, such as: |
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Signed 41.6 fixed point provides a fractional increment of 0.015625; |
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Signed 41.6 fixed point provides a fractional increment of 0.015625; |
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for the scheduler, this would mean about 15.6ms resolution, which is not |
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for the scheduler, this would mean about 15.6ms resolution, which is not |
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that great. |
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that great. |
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Efficient check for double-to-fastint conversion |
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================================================ |
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Criteria |
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-------- |
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For an IEEE double to be representable as a fast integer, it must be: |
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* A whole number |
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* In the 48-bit range |
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* Not a negative zero, assuming that the integer zero is taken to represent |
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a positive zero |
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What to optimize for |
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-------------------- |
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This algorithm is needed when Duktape: |
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* Parses a number and checks whether to represent the number as a double or |
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a fastint |
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* Executes internal code with no fastint handling; in this case any fastint |
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inputs are first coerced to doubles and then back to fastints if the result |
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fits |
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* Executes internal code with fastint handling, with one or more of the |
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inputs not matching the fastint "fast path" but the result possibly fitting |
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into a fastint |
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The "fast path" for fastint operations doesn't execute this algorithm because |
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both inputs and outputs are fastints and Duktape detects this in the fast path |
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preconditions. Given this, an aggressive memory-speed tradeoff (e.g. a table |
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for each exponent) doesn't make sense. |
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The speed of this algorithm affects two scenarios: |
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1. Computations where the numbers involved are outside the fastint range. Here |
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it's important to quickly determine that a fastint representation is not |
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possible. |
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2. Computations where the numbers can be represented as fastints (at least some |
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of the time), but one or more operations don't have a fastint "fast path" so |
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that the numbers get upgraded to an IEEE double and then need to be downgraded |
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back to a fastint. |
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Both cases matter, but for typical embedded code the latter case matters more. |
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In other words, the code should be optimized for the case where a fastint fit |
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is possible. |
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Exponent and sign by cases |
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-------------------------- |
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An IEEE double has a sign (1 bit), an exponent (11 bits), and a 52-bit stored |
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mantissa. The mantissa has an implicit (not stored) leading '1' digit, except |
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for denormals, NaNs, and infinities. |
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Going through the possible exponent values: |
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* If exponent is 0: |
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- The number is a fastint only if the sign bit is zero (positive) and the |
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entire mantissa is all zeroes. This corresponds to +0. |
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- If the mantissa is non-zero, the number is a denormal. |
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* If the exponent is in the range [1, 1022] the number is not a fastint |
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because the implicit mantissa bit corresponds to the number 0.5. |
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* If exponent is exactly 1023: |
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- The number is only a fastint if the stored mantissa is all zeroes. |
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This corresponds to +/- 1. |
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* If exponent is exactly 1024: |
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- The number is only a fastint if 51 lowest bits of the mantissa are all |
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zeroes. This corresponds to the numbers +/- 2 and +/- 3. |
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* Generalizing, if the exponent is in the range [1023,1069], the number is |
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a fastint if and only if: |
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- The lowest N bits of the mantissa are zero, where N = 52 - (exp - 1023), |
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with either sign. |
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- N can also be expressed as: N = 1075 - exp. |
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* If exponent is exactly 1070: |
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- The number is only a fastint if the sign bit is set (negative) and the |
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stored mantissa is all zeroes. This corresponds to -2^47. The positive |
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counterpart +2^47 does not fit into the fastint range. |
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* If exponent is [1071,2047] the number is never a fastint: |
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- For exponents [1071,2046] the number is too large to be a fastint. |
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- For exponent 2047 the number is a NaN or infinity depending on the |
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mantissa contents, neither a valid fastint. |
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Pseudocode 1 |
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------------ |
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The algorithm:: |
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is_fastint(sgn, exp, mant): |
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if exp == 0: |
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return sign == 0 and mzero(mant, 52) |
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else if exp < 1023: |
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return false |
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else if exp < 1070: |
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return mzero(mant, 1075 - exp) |
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else if exp == 1070: |
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return sign == 1 and mzero(mant, 52) |
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else: |
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return false |
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The ``mzero`` helper predicate returns true if the mantissa given has its |
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lowest ``n`` bits zero. |
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Non-zero integers in the fastint range will fall into the case where a certain |
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computed number of low mantissa bits must be checked to be zero. As discussed |
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above, the algorithm should be optimized for the "input fits fastint" case. |
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Pseudocode 2 |
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------------ |
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Some rewriting:: |
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is_fastint(sgn, exp, mant): |
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nzero = 1075 - exp |
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if nzero >= 52 and nzero <= 6: // exp 1023 ... exp 1069 |
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// exponents 1023 to 1069: regular handling, common case |
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return mzero(mant, nzero) |
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else if nzero == 1075: |
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// exponent 0: irregular handling, but still common (positive zero) |
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return sign == 0 and mzero(mant, 52) |
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else if nzero == 5: |
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// exponent 1070: irregular handling, rare case |
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return sign == 1 and mzero(mant, 52) |
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else: |
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// exponents [1,1022] and [1071,2047], rare case |
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return false |
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C algorithm with a lookup table |
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------------------------------- |
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The common case ``nzero`` values are between [6, 52] and correspond to |
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mantissa masks. Compute a mask index instead as nzero - 6 = 1069 - exp:: |
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duk_uint64_t mzero_masks[47] = { |
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0x000000000000003fULL, /* exp 1069, nzero 6 */ |
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0x000000000000007fULL, /* exp 1068, nzero 7 */ |
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0x00000000000000ffULL, /* exp 1067, nzero 8 */ |
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0x00000000000001ffULL, /* exp 1066, nzero 9 */ |
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/* ... */ |
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0x0003ffffffffffffULL, /* exp 1025, nzero 50 */ |
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0x0007ffffffffffffULL, /* exp 1024, nzero 51 */ |
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0x000fffffffffffffULL, /* exp 1023, nzero 52 */ |
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}; |
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int is_fastint(duk_int64_t d) { |
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int exp = (d >> 52) & 0x07ff; |
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int idx = 1069 - exp; |
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if (idx >= 0 && idx <= 46) { /* exponents 1069 to 1023 */ |
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return (mzero_masks[idx] & mant) == 0; |
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} else if (idx == 1069) { /* exponent 0 */ |
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return (d >= 0) && ((d & 0x000fffffffffffffULL) == 0); |
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} else if (idx == -1) { /* exponent 1070 */ |
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return (d < 0) && ((d & 0x000fffffffffffffULL) == 0); |
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} else { |
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return 0; |
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} |
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}; |
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The memory cost of the mask table is 8x47 = 376 bytes. This can be halved |
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e.g. by using a table of 32-bit values with separate cases for nzero >= 32 |
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and nzero < 32. |
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Unfortunately the expected case (exponents 1023 to 1069) involves a mask |
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check with a variable mask, so it may be unsuitable for direct inlining in |
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the most important hot spots. |
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C algorithm with a computed mask |
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-------------------------------- |
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Since this algorithm only runs outside the proper fastint "fast path" it |
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may be more sensible to avoid a memory tradeoff and compute the masks:: |
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int is_fastint(duk_int64_t d) { |
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int exp = (d >> 52) & 0x07ff; |
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int shift = exp - 1023; |
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if (shift >= 0 && shift <= 46) { /* exponents 1023 to 1069 */ |
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return ((0x000fffffffffffffULL >> shift) & mant) == 0; |
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} else if (shift == -1023) { /* exponent 0 */ |
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return (d >= 0) && ((d & 0x000fffffffffffffULL) == 0); |
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} else if (shift == 47) { /* exponent 1070 */ |
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return (d < 0) && ((d & 0x000fffffffffffffULL) == 0); |
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} else { |
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return 0; |
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} |
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}; |
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For middle endian machines (ARM) this algorithm first needs swapping |
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of the 32-bit parts. By changing the mask checks to operate on 32-bit |
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parts the algorithm would work on more platforms and would also remove |
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the need for swapping the parts on middle endian platforms. |
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C algorithm with 32-bit operations and a computed mask |
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------------------------------------------------------ |
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:: |
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int is_fastint(duk_uint32_t hi, duk_uint32_t lo) { |
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int exp = (hi >> 20) & 0x07ff; |
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int shift = exp - 1023; |
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if (shift >= 0 && shift <= 46) { /* exponents 1023 to 1069 */ |
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if (shift <= 20) { |
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/* 0x000fffff'ffffffff -> 0x00000000'ffffffff */ |
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return (((0x000fffffUL >> shift) & hi) == 0) && (lo == 0); |
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} else { |
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/* 0x00000000'ffffffff -> 0x00000000'0000003f */ |
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return (((0xffffffffUL >> (shift - 20)) & lo) == 0); |
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} |
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} else if (shift == -1023) { /* exponent 0 */ |
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/* return ((hi & 0x800fffffUL) == 0x00000000UL) && (lo == 0); */ |
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return (hi == 0) && (lo == 0); |
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} else if (shift == 47) { /* exponent 1070 */ |
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return ((hi & 0x800fffffUL) == 0x80000000UL) && (lo == 0); |
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} else { |
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return 0; |
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} |
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}; |
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Future work |
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=========== |
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Skipping the double-to-fastint test sometimes |
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--------------------------------------------- |
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The double-to-fastint can safely err on the side of caution and decide to |
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represent a fastint-compatible number as a double. This opens up the |
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possibility of skipping the double-to-fastint test in some cases which |
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may improve performance and reduce code size. |
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For instance, when ``Math.cos()`` pushes its result on the stack, it's |
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probably quite a safe bet that the number won't fit a fastint, so it could |
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be written as a double directly without a double-to-fastint downgrade |
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check. In case it is a fastint (-1, 0, or 1) it will be represented as a |
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double but will be downgraded to a fastint by the first operation that |
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does execute the downgrade check. To support this, there could be a macro |
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like ``DUK_TVAL_SET_NUMBER_NOFASTINT``. |
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Another option is to run the double-to-fastint check randomly or e.g. only |
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every Nth time it is needed (N could be quite large, e.g. the prime 17). |
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This should be quite OK from a performance point of view. If a number is |
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incorrectly stored as a double and is involved in a lot of operations, |
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chances are it will get downgraded quite quickly, as long as the check |
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interval does not unluckily correlate with the downgrade check frequency. |
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This approach may not be worth it because an optimized fastint downgrade |
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check should have quite reasonable performance, and such an approach would |
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have no effect on the actual fastint fast path (inputs are fastints, |
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outputs are fastints). |
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