This problem is not caused by conversion from long double to double. It may be due to inaccuracy in the `sin`

routine in the math library.

The `fsin`

instruction is specified to produce a result within 1 ULP (in the long double format) for operands within its range (per Intel 64 and IA-32 Architectures Software Developer's Manual, October 2011, volume 1, 8.3.10), in round-to-nearest mode. On an Intel Core i7, `fsin`

of the questioner’s value, −5.07121364272633190495298549649305641651153564453125 or -0x1.448ec3aaa278dp+2, produces 0xe.fb206c69b0ba402p-4. We can easily see from this hexadecimal that the last 11 bits are 100 0000 0010. Those are the bits that will be rounded when converting from long double. If they are greater than 100 0000 0000, the number will be rounded up. They are greater. Therefore, the result of converting this long double value to double is 0xe.fb206c69b0ba8p-4, which equals 0x1.df640d8d36175p-1 and 0.93631021832247418590355891865328885614871978759765625. Also note that even if the result were one ULP lower, the last 11 bits would still be greater than 100 0000 0000 and would still round up. Therefore this result should not vary on Intel CPUs conforming to the above documentation.

Compare this to computing a double-precision sine directly, using an ideal `sin`

routine that produces correctly rounded results. The sine of the value is approximately 0.93631021832247413051857150785044253634581268961333520518023697738674775240815140702992025520721336793516756640679315765619707343171517531053811196321335899848286682535203710849065933755262347468763562 (computed with Maple 10). The double closest to this is 0x1.df640d8d36175p-1. That is the same value we obtained by converting the `fsin`

result to double.

Therefore, the discrepancy is not caused by conversion of long double to double; converting the long double `fsin`

result to double produces exactly the same result as an ideal double-precision `sin`

routine.

We do not have a specification for the accuracy of the `sin`

routine used by the questioner’s Visual Studio package. In commercial libraries, allowing errors of 1 ULP or several ULP is common. Observe how close the sine is to a point where the double-precision value is rounded: It is .498864 ULP (double-precision ULP) away from a double, so it is .001136 ULP away from the point where rounding changes. Therefore, even a very slight inaccuracy in the `sin`

routine will cause it to return 0x1.df640d8d36174p-1 instead of the closer 0x1.df640d8d36175p-1.

Therefore, I conjecture the source of the discrepancy is a very small inaccuracy in the `sin`

routine.

`fsin`

approach uses the x87 FPU with 80-bit precision, the implementation of`sin`

in MSVC (I'm using 2010) seems to use SSE with its 128-bit xmm* registers. (Also, see this question.) – DCoder Sep 1 '12 at 7:16