ia32-64/x86/vreducesd.html

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		— Perform a Reduction Transformation on a Scalar Float64 Value</title></head><body><header><nav><ul><li><a href='index.html'>Index</a></li><li>December 2023</li></ul></nav></header><h1>VREDUCESD
		— Perform a Reduction Transformation on a Scalar Float64 Value</h1>

<table>
<tr>
<th>Opcode/Instruction</th>
<th>Op / En</th>
<th>64/32 bit Mode Support</th>
<th>CPUID Feature Flag</th>
<th>Description</th></tr>
<tr>
<td>EVEX.LLIG.66.0F3A.W1 57 VREDUCESD xmm1 {k1}{z}, xmm2, xmm3/m64{sae}, imm8/r</td>
<td>A</td>
<td>V/V</td>
<td>AVX512D Q</td>
<td>Perform a reduction transformation on a scalar double precision floating-point value in xmm3/m64 by subtracting a number of fraction bits specified by the imm8 field. Also, upper double precision floating-point value (bits[127:64]) from xmm2 are copied to xmm1[127:64]. Stores the result in xmm1 register.</td></tr></table>
<h2 id="instruction-operand-encoding">Instruction Operand Encoding<a class="anchor" href="#instruction-operand-encoding">
			¶
		</a></h2>
<table>
<tr>
<th>Op/En</th>
<th>Tuple Type</th>
<th>Operand 1</th>
<th>Operand 2</th>
<th>Operand 3</th>
<th>Operand 4</th></tr>
<tr>
<td>A</td>
<td>Tuple1 Scalar</td>
<td>ModRM:reg (w)</td>
<td>EVEX.vvvv (r)</td>
<td>ModRM:r/m (r)</td>
<td>N/A</td></tr></table>
<h3 id="description">Description<a class="anchor" href="#description">
			¶
		</a></h3>
<p>Perform a reduction transformation of the binary encoded double precision floating-point value in the low qword element of the second source operand (the third operand) and store the reduced result in binary floating-point format to the low qword element of the destination operand (the first operand) under the writemask k1. Bits 127:64 of the destination operand are copied from respective qword elements of the first source operand (the second operand).</p>
<p>The reduction transformation subtracts the integer part and the leading M fractional bits from the binary floating-point source value, where M is a unsigned integer specified by imm8[7:4], see <a href='vreducepd.html#fig-5-28'>Figure 5-28</a>. Specifically, the reduction transformation can be expressed as:</p>
<p>dest = src – (ROUND(2<sup>M</sup>*src))*2<sup>-M</sup>;</p>
<p>where “Round()” treats “src”, “2<sup>M</sup>”, and their product as binary floating-point numbers with normalized significand and biased exponents.</p>
<p>The magnitude of the reduced result can be expressed by considering src= 2<sup>p</sup>*man2,</p>
<p>where ‘man2’ is the normalized significand and ‘p’ is the unbiased exponent</p>
<p>Then if RC = RNE: 0&lt;=|Reduced Result|&lt;=2<sup>p-M-1</sup></p>
<p>Then if RC ≠ RNE: 0&lt;=|Reduced Result|&lt;2<sup>p-M</sup></p>
<p>This instruction might end up with a precision exception set. However, in case of SPE set (i.e., Suppress Precision Exception, which is imm8[3]=1), no precision exception is reported.</p>
<p>The operation is write masked.</p>
<p>Handling of special case of input values are listed in <a href='vreducepd.html#tbl-5-29'>Table 5-29</a>.</p>
<h3 id="operation">Operation<a class="anchor" href="#operation">
			¶
		</a></h3>
<pre>ReduceArgumentDP(SRC[63:0], imm8[7:0])
{
    // Check for NaN
    IF (SRC [63:0] = NAN) THEN
        RETURN (Convert SRC[63:0] to QNaN); FI;
    M := imm8[7:4]; // Number of fraction bits of the normalized significand to be subtracted
    RC := imm8[1:0];// Round Control for ROUND() operation
    RC source := imm[2];
    SPE := imm[3];// Suppress Precision Exception
    TMP[63:0] := 2<sup>-M</sup> *{ROUND(2<sup>M</sup>*SRC[63:0], SPE, RC_source, RC)}; // ROUND() treats SRC and 2<sup>M</sup> as standard binary FP values
    TMP[63:0] := SRC[63:0] – TMP[63:0]; // subtraction under the same RC,SPE controls
    RETURN TMP[63:0]; // binary encoded FP with biased exponent and normalized significand
}
</pre>
<h4 id="vreducesd">VREDUCESD<a class="anchor" href="#vreducesd">
			¶
		</a></h4>
<pre>IF k1[0] or *no writemask*
    THEN DEST[63:0] := ReduceArgumentDP(SRC2[63:0], imm8[7:0])
    ELSE
        IF *merging-masking* ; merging-masking
            THEN *DEST[63:0] remains unchanged*
            ELSE ; zeroing-masking
                THEN DEST[63:0] = 0
        FI;
FI;
DEST[127:64] := SRC1[127:64]
DEST[MAXVL-1:128] := 0
</pre>
<h3 id="intel-c-c++-compiler-intrinsic-equivalent">Intel C/C++ Compiler Intrinsic Equivalent<a class="anchor" href="#intel-c-c++-compiler-intrinsic-equivalent">
			¶
		</a></h3>
<pre>VREDUCESD __m128d _mm_mask_reduce_sd( __m128d a, __m128d b, int imm, int sae)
</pre>
<pre>VREDUCESD __m128d _mm_mask_reduce_sd(__m128d s, __mmask16 k, __m128d a, __m128d b, int imm, int sae)
</pre>
<pre>VREDUCESD __m128d _mm_maskz_reduce_sd(__mmask16 k, __m128d a, __m128d b, int imm, int sae)
</pre>
<h3 class="exceptions" id="simd-floating-point-exceptions">SIMD Floating-Point Exceptions<a class="anchor" href="#simd-floating-point-exceptions">
			¶
		</a></h3>
<p>Invalid, Precision.</p>
<p>If SPE is enabled, precision exception is not reported (regardless of MXCSR exception mask).</p>
<h3 class="exceptions" id="other-exceptions">Other Exceptions<a class="anchor" href="#other-exceptions">
			¶
		</a></h3>
<p>See <span class="not-imported">Table 2-47</span>, “Type E3 Class Exception Conditions.”</p><footer><p>
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