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<!--
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Copyright (c) 2016 OpenPOWER Foundation
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Licensed under the GNU Free Documentation License, Version 1.3;
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with no Invariants Sections, with no Front-Cover Texts,
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and with no Back-Cover Texts (the "License");
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you may not use this file except in compliance with the License.
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You may obtain a copy of the License at
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http://www.gnu.org/licenses/fdl-1.3.txt
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-->
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<chapter xmlns="http://docbook.org/ns/docbook"
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xmlns:xl="http://www.w3.org/1999/xlink" version="5.0"
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xml:lang="en"
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xml:id="dbdoclet.50655244_pgfId-1095944">
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<title>Vector Programming Interfaces</title>
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<para>To ensure portability of applications optimized to exploit the SIMD
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functions of Power ISA processors, the ELF V2 ABI defines a set of
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functions and data types for SIMD programming. ELF V2-compliant compilers
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will provide suitable support for these functions, preferably as built-in
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functions that translate to one or more Power ISA instructions.</para>
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<para>Compilers are encouraged, but not required, to provide built-in
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functions to access individual instructions in the IBM POWER® instruction
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set architecture. In most cases, each such built-in function should provide
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direct access to the underlying instruction.</para>
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<para>However, to ease porting between little-endian (LE) and big-endian
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(BE) POWER systems, and between POWER and other platforms, it is preferable
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that some built-in functions provide the same semantics on both LE and BE
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POWER systems, even if this means that the built-in functions are
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implemented with different instruction sequences for LE and BE. To achieve
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this, vector built-in functions provide a set of functions derived from the
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set of hardware functions provided by the Power vector SIMD instructions.
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Unlike traditional “hardware intrinsic” built-in functions, no fixed
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mapping exists between these built-in functions and the generated hardware
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instruction sequence. Rather, the compiler is free to generate optimized
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instruction sequences that implement the semantics of the program specified
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by the programmer using these built-in functions.</para>
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<para>This is primarily applicable to the vector facility of the POWER ISA,
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also known as Power SIMD, consisting of the VMX (or Altivec) and VSX
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instructions. This set of instructions operates on groups of 2, 4, 8, or 16
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vector elements at a time in 128-bit registers. On a big-endian POWER
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platform, vector elements are loaded from memory into a register so that
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the 0th element occupies the high-order bits of the register, and the
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(N – 1)th element occupies the low-order bits of the register. This is
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referred to as big-endian element order. On a little-endian POWER platform,
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vector elements are loaded from memory such that the 0th element occupies
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the low-order bits of the register, and the (N – 1)th element occupies the
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high-order bits. This is referred to as little-endian element order.</para>
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<section xml:id="dbdoclet.50655244_39970">
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<title>Vector Data Types</title>
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<para>Languages provide support for the data types in
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<xref linkend="dbdoclet.50655240_89351" /> to represent vector data types
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stored in vector registers.</para>
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<para>For the C and C++ programming languages (and related/derived
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languages), these data types may be accessed based on the type names listed
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in
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<xref linkend="dbdoclet.50655240_89351" /> when Power ISA SIMD language
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extensions are enabled using either the vector or __vector keywords.</para>
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<para>For the Fortran language,
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<xref linkend="dbdoclet.50655244_80766" /> gives a correspondence of Fortran
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and C/C++ language types.</para>
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<para>The assignment operator always performs a byte-by-byte data copy for
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vector data types.</para>
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<para>Like other C/C++ language types, vector types may be defined to have
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const or volatile properties. Vector data types can be defined as being in
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static, auto, and register storage.</para>
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<para>Pointers to vector types are defined like pointers of other C/C++
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types. Pointers to objects may be defined to have const and volatile
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properties. While the preferred alignment for vector data types is a
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multiple of 16 bytes, pointers may point to vector objects at an arbitrary
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alignment.</para>
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<para>The preferred way to access vectors at an application-defined address
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is by using vector pointers and the C/C++ dereference operator *. Similar
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to other C /C++ data types, the array reference operator [ ] may be used to
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access vector objects with a vector pointer with the usual definition to
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access the n-th vector element from a vector pointer. The use of vector
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built-in functions such as vec_xl and vec_xst is discouraged except for
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languages where no dereference operators are available.</para>
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<programlisting>vector char vca;
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vector char vcb;
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vector int via;
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int a[4];
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void *vp;
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via = *(vector int *) &a[0];
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vca = (vector char) via;
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vcb = vca;
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vca = *(vector char *)vp;
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*(vector char *)&a[0] = vca;</programlisting>
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<para>Compilers are expected to recognize and optimize multiple operations
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that can be optimized into a single hardware instruction. For example, a
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load and splat hardware instruction might be generated for the following
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sequence:</para>
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<programlisting>double *double_ptr;
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register vector double vd = vec_splats(*double_ptr);</programlisting>
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</section>
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<section xml:id="dbdoclet.50655244_83520">
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<title>Vector Operators</title>
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<para>In addition to the dereference and assignment operators, the Power
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SIMD Vector Programming API provides the usual operators that are valid on
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pointers; these operators are also valid for pointers to vector
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types.</para>
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<para>The traditional C/C++ operators are defined on vector types with “do
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all” semantics for unary and binary +, unary and binary –, binary *, binary
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%, and binary / as well as the unary and binary logical and comparison
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operators.</para>
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<para>For unary operators, the specified operation is performed on the
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corresponding base element of the single operand to derive the result value
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for each vector element of the vector result. The result type of unary
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operations is the type of the single input operand.</para>
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<para>For binary operators, the specified operation is performed on the
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corresponding base elements of both operands to derive the result value for
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each vector element of the vector result. Both operands of the binary
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operators must have the same vector type with the same base element type.
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The result of binary operators is the same type as the type of the input
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operands.</para>
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<para>Further, the array reference operator may be applied to vector data
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types, yielding an l-value corresponding to the specified element in
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accordance with the vector element numbering rules (see
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<xref linkend="dbdoclet.50655244_25365" />). An l-value may either be
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assigned a new value or accessed for reading its value.</para>
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</section>
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<section xml:id="dbdoclet.50655244_25365">
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<title>Vector Layout and Element Numbering</title>
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<para>Vector data types consist of a homogeneous sequence of elements of
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the base data type specified in the vector data type. Individual elements
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of a vector can be addressed by a vector element number. Element numbers
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can be established either by counting from the “left” of a register and
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assigning the left-most element the element number 0, or from the “right”
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of the register and assigning the right-most element the element number
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0.</para>
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<para>In big-endian environments, establishing element counts from the left
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makes the element stored at the lowest memory address the lowest-numbered
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element. Thus, when vectors and arrays of a given base data type are
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overlaid, vector element 0 corresponds to array element 0, vector element 1
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corresponds to array element 1, and so forth.</para>
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<para>In little-endian environments, establishing element counts from the
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right makes the element stored at the lowest memory address the
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lowest-numbered element. Thus, when vectors and arrays of a given base data
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type are overlaid, vector element 0 will correspond to array element 0,
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vector element 1 will correspond to array element 1, and so forth.</para>
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<para>Consequently, the vector numbering schemes can be described as
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big-endian and little-endian vector layouts and vector element numberings.
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(The term “endian” comes from the endian debates presented in
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<citetitle>Gulliver's Travels</citetitle> by Jonathan Swift.)</para>
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<para>For internal consistency, in the ELF V2 ABI, the default vector
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layout and vector element ordering in big-endian environments shall be big
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endian, and the default vector layout and vector element ordering in
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little-endian environments shall be little endian.</para>
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<para>This element numbering shall also be used by the [ ] accessor method
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to vector elements provided as an extension of the C/C++ languages by some
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compilers, as well as for other language extensions or library constructs
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that directly or indirectly refer to elements by their element
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number.</para>
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<para>Application programs may query the vector element ordering in use
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(that is, whether -qaltivec=be or -maltivec=be has been selected) by
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testing the __VEC_ELEMENT_REG_ORDER__ macro. This macro has two possible
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values:</para>
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<informaltable frame="none" rowsep="0" colsep="0">
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<tgroup cols="2">
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<colspec colname="c1" colwidth="40*" />
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<colspec colname="c2" colwidth="60*" />
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<tbody>
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<row>
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<entry>
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<para>__ORDER_LITTLE_ENDIAN__</para>
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</entry>
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<entry>
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<para>Vector elements use little-endian element ordering.</para>
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</entry>
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</row>
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<row>
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<entry>
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<para>__ORDER_BIG_ENDIAN__</para>
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</entry>
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<entry>
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<para>Vector elements use big-endian element ordering.</para>
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</entry>
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</row>
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</tbody>
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</tgroup>
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</informaltable>
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</section>
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<section xml:id="dbdoclet.50655244_90667">
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<title>Vector Built-in Functions</title>
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<para>The Power language environments provide a well-known set of built-in
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functions for the Power SIMD instructions (including both Altivec/VMX and
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VSX). A full description of these built-in functions is beyond the scope of
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this ABI document. Most built-in functions are polymorphic, operating on a
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variety of vector types (vectors of signed characters, vectors of unsigned
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halfwords, and so forth).</para>
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<para>Some of the Power SIMD (VMX/Altivec and/or VSX) hardware instructions
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refer, implicitly or explicitly, to vector element numbers. For example,
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the vspltb instruction has as one of its inputs an index into a vector. The
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element at that index position is to be replicated in every element of the
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output vector. For another example, the vmuleuh instruction operates on the
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even-numbered elements of its input vectors. The hardware instructions
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define these element numbers using big-endian element order, even when the
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machine is running in little-endian mode. Thus, a built-in function that
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maps directly to the underlying hardware instruction, regardless of the
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target endianness, has the potential to confuse programmers on
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little-endian platforms.</para>
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<para>It is more useful to define built-in functions that map to these
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instructions to use natural element order. That is, the explicit or
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implicit element numbers specified by such built-in functions should be
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interpreted using big-endian element order on a big-endian platform, and
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using little-endian element order on a little-endian platform.</para>
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<para>This ABI defines the following built-in functions to use natural
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element order. The Implementation Notes column suggests possible ways to
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implement little-endian (LE) versions of the built-in functions, although
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designers of a compiler are free to use other methods to implement the
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specified semantics as they see fit.</para>
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<para> </para>
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<table frame="all" pgwide="1" xml:id="dbdoclet.50655244_35023">
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<title>Endian-Sensitive Operations</title>
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<tgroup cols="3">
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<colspec colname="c1" colwidth="25*" align="center" />
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<colspec colname="c2" colwidth="30*" align="center" />
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<colspec colname="c3" colwidth="45*" />
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<thead>
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<row>
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<entry>
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<para>
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<emphasis role="bold">Built-In Function</emphasis>
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</para>
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</entry>
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<entry>
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<para>
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<emphasis role="bold">Corresponding POWER
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Instructions</emphasis>
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</para>
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</entry>
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<entry align="center">
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<para>
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<emphasis role="bold">Implementation Notes</emphasis>
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</para>
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</entry>
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</row>
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</thead>
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<tbody>
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<row revisionflag="added">
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<entry>
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<para>vec_bperm</para>
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</entry>
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<entry>
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<para> </para>
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</entry>
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<entry>
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<para>For LE unsigned long long ARGs, swap halves of ARG2 and of
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the result.</para>
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</entry>
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</row>
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<row revisionflag="added">
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<entry>
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<para>vec_cntlz_lsbb</para>
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</entry>
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<entry>
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<para> </para>
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</entry>
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<entry>
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<para>For LE, use vctzlsbb.</para>
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</entry>
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</row>
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<row revisionflag="added">
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<entry>
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<para>vec_cnttz_lsbb</para>
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</entry>
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<entry>
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<para> </para>
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</entry>
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<entry>
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<para>For LE, use vclzlsbb.</para>
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</entry>
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</row>
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<row>
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<entry>
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<para>vec_extract</para>
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</entry>
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<entry>
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<para>None</para>
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</entry>
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<entry>
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<para>vec_extract (v, 3) is equivalent to v[3].</para>
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</entry>
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</row>
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<row revisionflag="added">
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<entry>
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<para>vec_extract_fp32_from_shorth</para>
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</entry>
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<entry>
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<para> </para>
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</entry>
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<entry>
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<para>For LE, extract the left four elements.</para>
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</entry>
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</row>
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<row revisionflag="added">
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<entry>
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<para>vec_extract_fp32_from_shortl</para>
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</entry>
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<entry>
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<para> </para>
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</entry>
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<entry>
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<para>For LE, extract the right four elements.</para>
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</entry>
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</row>
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<row revisionflag="added">
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<entry>
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<para>vec_extract4b</para>
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</entry>
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<entry>
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<para> </para>
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</entry>
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<entry>
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<para>For LE, subtract the byte position from 12, and swap the
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halves of the result.</para>
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</entry>
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</row>
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<row revisionflag="added">
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<entry>
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<para>vec_first_match_index</para>
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</entry>
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<entry>
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<para> </para>
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</entry>
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<entry>
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<para>For LE, use vctz.</para>
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</entry>
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</row>
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<row revisionflag="added">
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<entry>
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|
<para>vec_first_match_index_or_eos</para>
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</entry>
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<entry>
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<para> </para>
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</entry>
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<entry>
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<para>For LE, use vctz.</para>
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</entry>
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</row>
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<row>
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<entry>
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<para>vec_insert</para>
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</entry>
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<entry>
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<para>None</para>
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</entry>
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<entry>
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<para>vec_insert (x, v, 3) returns the vector v with the
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<emphasis>third</emphasis> element modified to contain x.</para>
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</entry>
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</row>
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<row revisionflag="added">
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<entry>
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|
<para>vec_insert4b</para>
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</entry>
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|
<entry>
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|
<para> </para>
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</entry>
|
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|
<entry>
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|
<para>For LE, subtract the byte position from 12, and swap the
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halves of ARG2.</para>
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</entry>
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</row>
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<row>
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<entry>
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<para>vec_mergee</para>
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</entry>
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<entry>
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<para>vmrgew</para>
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</entry>
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<entry>
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|
<para>Swap inputs and use vmrgow for LE. Phased in.<footnote xml:id="pgfId-1105723">
|
|
|
<para>This optional function is being phased in, and it may not
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|
be available on all implementations.</para>
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|
</footnote></para>
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</entry>
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</row>
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<row>
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<entry>
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<para>vec_mergeh</para>
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</entry>
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<entry>
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<para>vmrghb, vmrghh, vmrghw</para>
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</entry>
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<entry>
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<para>Swap inputs and use vmrglb, and so on, for LE.</para>
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</entry>
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</row>
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<row>
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<entry>
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|
<para>vec_mergel</para>
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</entry>
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<entry>
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|
|
<para>vmrglb, vmrglh, vmrglw</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Swap inputs and use vmrghb, and so on, for LE.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_mergeo</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>vmrgow</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Swap inputs and use vmrgew for LE. Phased in.<footnoteref linkend="pgfId-1105723" /> </para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_mule</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>vmuleub, vmulesb, vmuleuh, vmulesh</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Replace with vmuloub, and so on, for LE.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_mulo</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>vmuloub, vmulosb, vmulouh, vmulosh</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Replace with vmuleub, and so on, for LE.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_pack</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>vpkuhum, vpkuwum</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Swap input arguments for LE.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_packpx</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>vpkpx</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Swap input arguments for LE.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_packs</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>vpkuhus, vpkshss, vpkuwus, vpkswss</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Swap input arguments for LE.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_packsu</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>vpkuhus, vpkshus, vpkuwus, vpkswus</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Swap input arguments for LE.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_perm</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>vperm</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>For LE, swap input arguments and complement the selection
|
|
|
vector.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_splat</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>vspltb, vsplth, vspltw</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Subtract the element number from N – 1 for LE.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_sum2s</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>vsum2sws</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>For LE, swap elements 0 and 1, and elements 2 and 3, of the
|
|
|
second input argument; then swap elements 0 and 1, and elements 2
|
|
|
and 3, of the result vector.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_sums</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>vsumsws</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>For LE, use element 3 in little-endian order from the
|
|
|
second input vector, and place the result in element 3 in
|
|
|
little-endian order of the result vector.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_unpackh</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>vupkhsb, vupkhpx, vupkhsh</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Use vupklsb, and so on, for LE.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_unpackl</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>vupklsb, vupklpx, vupklsh</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Use vupkhsb, and so on, for LE.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row revisionflag="added">
|
|
|
<entry>
|
|
|
<para>vec_xl_len_r</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para> </para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>For LE, the bytes are loaded left justified then shifted
|
|
|
right 16 – cnt bytes or rotated left cnt bytes. Let “cnt” be the
|
|
|
number of bytes specified to be loaded by vec_xl_len_r.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row revisionflag="added">
|
|
|
<entry>
|
|
|
<para>vec_xst_len_r</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para> </para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>For LE, the bytes are shifted left 16 – cnt bytes or rotated
|
|
|
right cnt bytes so they are left justified to be stored. Let
|
|
|
“cnt” be the number of bytes specified to be stored by
|
|
|
vec_xst_len_r.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
</tbody>
|
|
|
</tgroup>
|
|
|
</table>
|
|
|
<note>
|
|
|
<para><emphasis role="bold">Reminder</emphasis>: The assignment operator = is the
|
|
|
preferred way to assign values from one vector data type to
|
|
|
another vector data type in accordance with the C and C++
|
|
|
programming languages.</para>
|
|
|
</note>
|
|
|
<para> </para>
|
|
|
<bridgehead>Extended Data Movement Functions</bridgehead>
|
|
|
<para>The built-in functions in
|
|
|
<xref linkend="dbdoclet.50655244_42521" /> map to Altivec/VMX load and
|
|
|
store instructions and provide access to the “auto-aligning” memory
|
|
|
instructions of the Altivec ISA where low-order address bits are
|
|
|
discarded before performing a memory access. These instructions access
|
|
|
load and store data in accordance with the program's current endian mode,
|
|
|
and do not need to be adapted by the compiler to reflect little-endian
|
|
|
operating during code generation:</para>
|
|
|
<para> </para>
|
|
|
<table frame="all" pgwide="1" xml:id="dbdoclet.50655244_42521">
|
|
|
<title>Altivec Memory Access Built-In Functions</title>
|
|
|
<tgroup cols="3">
|
|
|
<colspec colname="c1" colwidth="15*" align="center" />
|
|
|
<colspec colname="c2" colwidth="35*" align="center" />
|
|
|
<colspec colname="c3" colwidth="50*" />
|
|
|
<thead>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>
|
|
|
<emphasis role="bold">Built-in Function</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>
|
|
|
<emphasis role="bold">Corresponding POWER
|
|
|
Instructions</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry align="center">
|
|
|
<para>
|
|
|
<emphasis role="bold">Implementation Notes</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
</thead>
|
|
|
<tbody>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_ld</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>lvx</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Hardware works as a function of endian mode.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_lde</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>lvebx, lvehx, lvewx</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Hardware works as a function of endian mode.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_ldl</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>lvxl</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Hardware works as a function of endian mode.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_st</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>stvx</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Hardware works as a function of endian mode.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_ste</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>stvebx, stvehx, stvewx</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Hardware works as a function of endian mode.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_stl</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>stvxl</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Hardware works as a function of endian mode.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
</tbody>
|
|
|
</tgroup>
|
|
|
</table>
|
|
|
<para>Previous versions of the Altivec built-in functions defined
|
|
|
intrinsics to access the Altivec instructions lvsl and lvsr, which could
|
|
|
be used in conjunction with vec_vperm and Altivec load and store
|
|
|
instructions for unaligned access. The vec_lvsl and vec_lvsr interfaces
|
|
|
are deprecated in accordance with the interfaces specified here. For
|
|
|
compatibility, the built-in pseudo sequences published in previous VMX
|
|
|
documents continue to work with little-endian data layout and the
|
|
|
little-endian vector layout described in this document. However, the use
|
|
|
of these sequences in new code is discouraged and usually results in
|
|
|
worse performance. It is recommended (but not required) that compilers
|
|
|
issue a warning when these functions are used in little-endian
|
|
|
environments. It is recommended that programmers use the assignment
|
|
|
operator = or the vector vec_xl and vec_xst vector built-in functions to
|
|
|
access unaligned data streams.</para>
|
|
|
<para>The set of extended mnemonics in
|
|
|
<xref linkend="dbdoclet.50655244_62451" /> may be provided by some
|
|
|
compilers and are not required by the Power SIMD programming interfaces.
|
|
|
In particular, the assignment operator = will have the same effect of
|
|
|
copying values between vector data types and provides a preferable method
|
|
|
to assign values while giving the compiler more freedom to optimize data
|
|
|
allocation. The only use for these functions is to support some coding
|
|
|
patterns enabling big-endian vector layout code sequences in both
|
|
|
big-endian and little-endian environments. Memory access built-in
|
|
|
functions that specify a vector element format (that is, the w4 and d2
|
|
|
forms) are deprecated. They will be phased out in future versions of this
|
|
|
specification because vec_xl and vec_xst provide overloaded
|
|
|
layout-specific memory access based on the specified vector data
|
|
|
type.</para>
|
|
|
<table frame="all" pgwide="1" xml:id="dbdoclet.50655244_62451">
|
|
|
<title>Optional Built-In Memory Access Functions</title>
|
|
|
<tgroup cols="3">
|
|
|
<colspec colname="c1" colwidth="15*" align="center" />
|
|
|
<colspec colname="c2" colwidth="35*" align="center" />
|
|
|
<colspec colname="c3" colwidth="50*" />
|
|
|
<thead>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>
|
|
|
<emphasis role="bold">Built-in Function</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>
|
|
|
<emphasis role="bold">Corresponding POWER
|
|
|
Instructions</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry align="center">
|
|
|
<para>
|
|
|
<emphasis role="bold">Little-Endian Implementation
|
|
|
Notes</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
</thead>
|
|
|
<tbody>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_xl</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>lxvd2x</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>lxvd2x ; xxpermdi</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_xlw4<footnote xml:id="dbdoclet.50655244_73052"><para>
|
|
|
Deprecated. The use of vector data type
|
|
|
assignment and overloaded vec_xl and vec_xst vector
|
|
|
built-in functions are preferred forms for assigning
|
|
|
vector operations. Similarly, the use of
|
|
|
<literal>__builtin_lxvd2x</literal>, <literal>__builtin_lxvw4x</literal>,
|
|
|
<literal>__builtin_stxvd2x</literal>, <literal>__builtin_stxvw4x</literal>,
|
|
|
available in some compilers, is discouraged.</para></footnote>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>lxvw4x</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>lxvd2x ; xxpermdi</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_xld2<footnoteref linkend="dbdoclet.50655244_73052"/>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>lxvd2x</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>lxvd2x ; xxpermdi</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_xst</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>stxvd2x</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>xxpermdi ; stxvd2x</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_xstw4<footnoteref linkend="dbdoclet.50655244_73052"/>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>stxvw4x</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>xxpermdi ; stxvd2x</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_xstd2<footnoteref linkend="dbdoclet.50655244_73052"/>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>stxvd2x</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>xxpermdi ; stxvd2x</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
</tbody>
|
|
|
</tgroup>
|
|
|
</table>
|
|
|
<para>The two optional built-in vector functions in
|
|
|
<xref linkend="dbdoclet.50655244_66443" /> can be used to load and store
|
|
|
vectors with a big-endian element ordering (that is, bytes from low to
|
|
|
high memory will be loaded from left to right into a vector char
|
|
|
variable), independent of the -qaltivec=be or -maltivec=be setting. For
|
|
|
more information, see
|
|
|
<xref linkend="dbdoclet.50655244_34309" />.</para>
|
|
|
<para> </para>
|
|
|
<table frame="all" pgwide="1" xml:id="dbdoclet.50655244_66443">
|
|
|
<title>Optional Fixed Data Layout Built-In Vector Functions</title>
|
|
|
<tgroup cols="3">
|
|
|
<colspec colname="c1" colwidth="15*" align="center"/>
|
|
|
<colspec colname="c2" colwidth="35*" align="center"/>
|
|
|
<colspec colname="c3" colwidth="50*" />
|
|
|
<thead>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>
|
|
|
<emphasis role="bold">Built-in Function</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>
|
|
|
<emphasis role="bold">Corresponding POWER
|
|
|
Instructions</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry align="center">
|
|
|
<para>
|
|
|
<emphasis role="bold">Little-Endian Implementation
|
|
|
Notes</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
</thead>
|
|
|
<tbody>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_xl_be</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>lxvd2x</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Use lxvd2x for vector long long; vector long, vector
|
|
|
double.</para>
|
|
|
<para>Use lxvd2x followed by reversal of elements within each
|
|
|
doubleword for all other data types.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_xst_be</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>stxvd2x</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Use stxvd2x for vector long long; vector long, vector
|
|
|
double.</para>
|
|
|
<para>Use stxvd2x following a reversal of elements within each
|
|
|
doubleword for all other data types.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
</tbody>
|
|
|
</tgroup>
|
|
|
</table>
|
|
|
<para>In addition to the hardware-specific vector built-in functions,
|
|
|
implementations are expected to provide the interfaces listed in
|
|
|
<xref linkend="dbdoclet.50655244_10651" />.</para>
|
|
|
<para> </para>
|
|
|
<table frame="all" pgwide="1" xml:id="dbdoclet.50655244_10651">
|
|
|
<title>Built-In Interfaces for Inserting and Extracting Elements from a
|
|
|
Vector</title>
|
|
|
<tgroup cols="2">
|
|
|
<colspec colname="c1" colwidth="40*" align="center"/>
|
|
|
<colspec colname="c2" colwidth="60*" />
|
|
|
<thead>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>
|
|
|
<emphasis role="bold">Built-In Function</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry align="center">
|
|
|
<para>
|
|
|
<emphasis role="bold">Implementation Notes</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
</thead>
|
|
|
<tbody>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_extract</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>vec_extract (v, 3) is equivalent to v[3].</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_insert</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>vec_insert (x, v, 3) returns the vector v with the
|
|
|
<emphasis>third</emphasis> element modified to contain x.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
</tbody>
|
|
|
</tgroup>
|
|
|
</table>
|
|
|
<para>Environments may provide the optional built-in vector functions
|
|
|
listed in
|
|
|
<xref linkend="dbdoclet.50655244_10811" /> to adjust for endian behavior
|
|
|
by reversing the order of elements (reve) and bytes within elements
|
|
|
(revb).</para>
|
|
|
<para> </para>
|
|
|
<table frame="all" pgwide="1" xml:id="dbdoclet.50655244_10811">
|
|
|
<title>Optional Built-In Functions</title>
|
|
|
<tgroup cols="2">
|
|
|
<colspec colname="c1" colwidth="20*" />
|
|
|
<colspec colname="c2" colwidth="80*" />
|
|
|
<thead>
|
|
|
<row>
|
|
|
<entry align="center">
|
|
|
<para>
|
|
|
<emphasis role="bold">Name</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry align="center">
|
|
|
<para>
|
|
|
<emphasis role="bold">Description</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
</thead>
|
|
|
<tbody>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_revb</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Reverses the order of bytes within elements.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_reve</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Reverses the order of elements.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
</tbody>
|
|
|
</tgroup>
|
|
|
</table>
|
|
|
<section xml:id="dbdoclet.50655244_34309">
|
|
|
<title>Big-Endian Vector Layout in Little-Endian Environments</title>
|
|
|
<para>Because the vector layout and element numbering cannot be
|
|
|
represented in source code in an endian-neutral manner, code originating
|
|
|
from big-endian platforms may need to be compiled on little-endian
|
|
|
platforms, or vice versa. To simplify such application porting, some
|
|
|
compilers may provide an additional bridge mode to enable a simplified
|
|
|
porting for some applications.</para>
|
|
|
<para>Note that such support only works for homogeneous data being loaded
|
|
|
into vector registers (that is, no unions or structs containing elements
|
|
|
of different sizes) and when those vectors are loaded from and stored to
|
|
|
memory with element-size-specific built-in vector memory functions of
|
|
|
<xref linkend="dbdoclet.50655244_91731" /> and
|
|
|
<xref linkend="dbdoclet.50655244_21918" />. That is because, in this
|
|
|
mode, data within each element must be adjusted for little-endian data
|
|
|
representation while providing a big-endian layout and numbering of
|
|
|
vector elements within a vector.</para>
|
|
|
<note>
|
|
|
<para>Because of the internal contradiction of big-endian
|
|
|
vector layouts and little-endian data, such an environment will have
|
|
|
intrinsic limitations for the type of functionality that may be
|
|
|
offered. However, it may provide a useful bridge in the porting of
|
|
|
code using vector built-ins between environments having different
|
|
|
data layout models.</para>
|
|
|
</note>
|
|
|
<para>Compiler designers may implement additional built-in functions or
|
|
|
other mechanisms that use big-endian element ordering in little-endian
|
|
|
mode. For example, the GCC and IBM XL compilers define the options
|
|
|
-maltivec=be and -qaltivec=be, respectively, to allow programmers to
|
|
|
specify that the built-ins will generate big-endian hardware instructions
|
|
|
directly for the corresponding big-endian sequences in little-endian
|
|
|
mode. To ensure consistent element operation in this mode, the lvx
|
|
|
instructions and related instructions are changed to maintain a
|
|
|
big-endian data layout in registers by adding appropriate permute
|
|
|
sequences as shown in
|
|
|
<xref linkend="dbdoclet.50655244_91731" />. The selected vector element
|
|
|
order is reflected in the __VEC_ELEMENT_REG_ORDER__ macro. See
|
|
|
<xref linkend="dbdoclet.50655243_page131" />.</para>
|
|
|
<table frame="all" pgwide="1" xml:id="dbdoclet.50655244_91731">
|
|
|
<title>Altivec Built-In Vector Memory Access Functions (BE Layout in LE
|
|
|
Mode)</title>
|
|
|
<tgroup cols="3">
|
|
|
<colspec colname="c1" colwidth="15*" align="center"/>
|
|
|
<colspec colname="c2" colwidth="35*" align="center"/>
|
|
|
<colspec colname="c3" colwidth="50*" />
|
|
|
<thead>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>
|
|
|
<emphasis role="bold">Built-In Function</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>
|
|
|
<emphasis role="bold">Corresponding POWER
|
|
|
Instructions</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry align="center">
|
|
|
<para>
|
|
|
<emphasis role="bold">BE Vector Layout in Little-Endian Mode
|
|
|
Implementation Notes</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
</thead>
|
|
|
<tbody>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_ld</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>lvx</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Reverse elements with a vperm after load for LE based on
|
|
|
vector base type.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_lde</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>lvebx, lvehx, lvewx</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Reverse elements with a vperm after load for LE based on
|
|
|
vector base type.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_ldl</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>lvxl</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Reverse elements with a vperm after load for LE based on
|
|
|
vector base type.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_st</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>stvx</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Reverse elements with a vperm before store for LE based
|
|
|
on vector base type.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_ste</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>stvebx, stvehx, stvewx</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Reverse elements with a vperm before store for LE based
|
|
|
on vector base type.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_stl</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>stvxl</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Reverse elements with a vperm before store for LE based
|
|
|
on vector base type.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
</tbody>
|
|
|
</tgroup>
|
|
|
</table>
|
|
|
<para>Access to memory instructions handling potentially unaligned
|
|
|
accesses may be accomplished by using instructions (or instruction
|
|
|
sequences) that perform little-endian load of the underlying vector data
|
|
|
type while maintaining big-endian element ordering. See
|
|
|
<xref linkend="dbdoclet.50655244_21918" />.</para>
|
|
|
<para> </para>
|
|
|
<table frame="all" pgwide="1" xml:id="dbdoclet.50655244_21918">
|
|
|
<title>Optional Built-In Memory Access Functions (BE Layout in LE
|
|
|
Mode)</title>
|
|
|
<tgroup cols="3">
|
|
|
<colspec colname="c1" colwidth="15*" align="center"/>
|
|
|
<colspec colname="c2" colwidth="35*" align="center"/>
|
|
|
<colspec colname="c3" colwidth="50*" />
|
|
|
<thead>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>
|
|
|
<emphasis role="bold">Built-In Function</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>
|
|
|
<emphasis role="bold">Corresponding POWER
|
|
|
Instructions</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry align="center">
|
|
|
<para>
|
|
|
<emphasis role="bold">BE Vector Layout in Little-Endian Mode
|
|
|
Implementation Notes</emphasis>
|
|
|
</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
</thead>
|
|
|
<tbody>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_xl</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>lxvd2x</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Use lxvd2x for vector long long; vector long, vector
|
|
|
double.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_xlw<phrase revisionflag="added">4</phrase><footnote xml:id="dbdoclet.50655244_78719">
|
|
|
<para>Deprecated. The use of vector data type
|
|
|
assignment and overloaded vec_xl and vec_xst vector
|
|
|
built-in functions are preferred forms for assigning
|
|
|
vector operations. Similarly, the use of
|
|
|
<literal>__builtin_lxvd2x</literal>,<literal> __builtin_lxvw4x</literal>,
|
|
|
<literal>__builtin_stxvd2x</literal>, <literal>__builtin_stxvw4x</literal>,
|
|
|
available in some compilers, is discouraged.</para></footnote>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>lxvw4x</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Use lxvw4x for vector int; vector float.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_xld2<footnoteref linkend="dbdoclet.50655244_78719"/>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>lxvd2x</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Use lxvd2x, followed by reversal of elements within each
|
|
|
doubleword, for all other data types.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_xst</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>stxvd2x</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Use stxvd2x for vector long long; vector long, vector
|
|
|
double.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_xstw4<footnoteref linkend="dbdoclet.50655244_78719"/>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>stxvw4x</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Use stxvw4x for vector int; vector float.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
<row>
|
|
|
<entry>
|
|
|
<para>vec_xstd2<footnoteref linkend="dbdoclet.50655244_78719"/>
|
|
|
</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>stxvd2x</para>
|
|
|
</entry>
|
|
|
<entry>
|
|
|
<para>Use stxvd2x, following a reversal of elements within each
|
|
|
doubleword, for all other data types.</para>
|
|
|
</entry>
|
|
|
</row>
|
|
|
</tbody>
|
|
|
</tgroup>
|
|
|
</table>
|
|
|
<note>
|
|
|
<para>The use of -maltivec=be or -qaltivec=be in
|
|
|
little-endian mode disables the transformations described
|
|
|
in
|
|
|
<xref linkend="dbdoclet.50655244_35023" />.</para>
|
|
|
</note>
|
|
|
<para>The operation of the assignment operator is never changed by a
|
|
|
setting such as <literal>-qaltivec=be</literal> or <literal>-maltivec=be</literal>.</para>
|
|
|
</section>
|
|
|
</section>
|
|
|
<section xml:id="dbdoclet.50655244_20743">
|
|
|
<title>Language-Specific Vector Support for Other Languages</title>
|
|
|
<section xml:id="dbdoclet.50655244_37862">
|
|
|
<title>Fortran</title>
|
|
|
<para>
|
|
|
<xref linkend="dbdoclet.50655244_80766" /> shows the correspondence
|
|
|
between the C/C++ types described in this document and their Fortran
|
|
|
equivalents. In Fortran, the Boolean vector data types are represented by
|
|
|
VECTOR(UNSIGNED(n)).</para>
|
|
|
<para>Because the Fortran language does not support pointers, vector
|
|
|
built-in functions that expect pointers to a base type take an array
|
|
|
element reference to indicate the address of a memory location that is
|
|
|
the subject of a memory access built-in function.</para>
|
|
|
<para>Because the Fortran language does not support type casts, the
|
|
|
vec_convert and vec_concat built-in functions shown in
|
|
|
<xref linkend="dbdoclet.50655244_14722" /> are provided to perform
|
|
|
bit-exact type conversions between vector types.</para>
|
|
|
<para> </para>
|
|
|
<table frame="all" pgwide="1" xml:id="dbdoclet.50655244_14722">
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<title>Built-In Vector Conversion Function</title>
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<tgroup cols="2">
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<colspec colname="c1" colwidth="30*" align="center" />
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<colspec colname="c2" colwidth="70*" />
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<thead>
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<row>
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<entry>
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<para>
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<emphasis role="bold">Group</emphasis>
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</para>
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</entry>
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<entry align="center">
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<para>
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<emphasis role="bold">Description</emphasis>
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</para>
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</entry>
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</row>
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</thead>
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<tbody>
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<row revisionflag="added">
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<entry>
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<para>VEC_CONCAT (ARG1, ARG2)<?linebreak?>(Fortran)</para>
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<para></para>
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</entry>
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<entry>
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<para>Purpose:</para>
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<para>Concatenates two elements to form a vector.</para>
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<para>Result value:</para>
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<para>The resulting vector consists of the two scalar elements,
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ARG1 and ARG2, assigned to elements 0 and 1 (using the
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environment’s native endian numbering), respectively.</para>
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<itemizedlist>
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<listitem>
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<para><emphasis role="bold">Note: </emphasis>This function corresponds to the C/C++ vector
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constructor (vector type){a,b}. It is provided only for
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languages without vector constructors.</para>
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</listitem>
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</itemizedlist>
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</entry>
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</row>
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<row revisionflag="added">
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<entry>
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<para></para>
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</entry>
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<entry>
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<para>vector signed long long vec_concat (signed long long,
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signed long long);</para>
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</entry>
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</row>
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<row revisionflag="added">
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<entry>
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<para></para>
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</entry>
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<entry>
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<para>vector unsigned long long vec_concat (unsigned long long,
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unsigned long long);</para>
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</entry>
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</row>
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<row revisionflag="added">
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<entry>
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<para></para>
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</entry>
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<entry>
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<para>vector double vec_concat (double, double);</para>
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</entry>
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</row>
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<row>
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<entry>
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<para>VEC_CONVERT(V, MOLD)</para>
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</entry>
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<entry>
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<para>Purpose:</para>
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<para>Converts a vector to a vector of a given type.</para>
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<para>Class:</para>
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<para>Pure function</para>
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<para>Argument type and attributes:</para>
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<itemizedlist spacing="compact">
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<listitem>
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<para>V Must be an INTENT(IN) vector.</para>
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</listitem>
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<listitem>
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<para>MOLD Must be an INTENT(IN) vector. If it is a
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variable, it need not be defined.</para>
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</listitem>
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</itemizedlist>
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<para>Result type and attributes:</para>
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<para>The result is a vector of the same type as MOLD.</para>
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<para>Result value:</para>
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<para>The result is as if it were on the left-hand side of an
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intrinsic assignment with V on the right-hand side.</para>
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</entry>
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</row>
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</tbody>
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</tgroup>
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</table>
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<para>
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<xref linkend="dbdoclet.50655244_80766" /> gives a correspondence of
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Fortran and C/C++ language types.</para>
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<para> </para>
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<table frame="all" pgwide="1" xml:id="dbdoclet.50655244_80766">
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<title>Fortran Vector Data Types</title>
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<tgroup cols="2">
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<colspec colname="c1" colwidth="50*" />
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<colspec colname="c2" colwidth="50*" />
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<thead>
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<row>
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<entry align="center">
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<para>
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<emphasis role="bold">XL Fortran Vector Type</emphasis>
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</para>
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</entry>
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<entry align="center">
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<para>
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<emphasis role="bold">XL C/C++ Vector Type</emphasis>
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</para>
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</entry>
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</row>
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</thead>
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<tbody>
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<row>
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<entry>
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<para>VECTOR(INTEGER(1))</para>
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</entry>
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<entry>
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<para>vector signed char</para>
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</entry>
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</row>
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<row>
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<entry>
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<para>VECTOR(INTEGER(2))</para>
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</entry>
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<entry>
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<para>vector signed short</para>
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</entry>
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</row>
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<row>
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<entry>
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<para>VECTOR(INTEGER(4))</para>
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</entry>
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<entry>
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<para>vector signed int</para>
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</entry>
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</row>
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<row>
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<entry>
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<para>VECTOR(INTEGER(8))</para>
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</entry>
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<entry>
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<para>vector signed long long, vector signed long</para>
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</entry>
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</row>
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<row>
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<entry>
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<para>VECTOR(INTEGER(16))</para>
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</entry>
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<entry>
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<para>vector signed __int128</para>
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</entry>
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</row>
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<row>
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<entry>
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<para>VECTOR(UNSIGNED(1))</para>
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</entry>
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<entry>
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<para>vector unsigned char</para>
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</entry>
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</row>
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<row>
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<entry>
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<para>VECTOR(UNSIGNED(2))</para>
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</entry>
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<entry>
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<para>vector unsigned short</para>
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</entry>
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</row>
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<row>
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<entry>
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<para>VECTOR(UNSIGNED(4))</para>
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</entry>
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<entry>
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<para>vector unsigned int</para>
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</entry>
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</row>
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<row>
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<entry>
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<para>VECTOR(UNSIGNED(8))</para>
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</entry>
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<entry>
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<para>vector unsigned long long, vector unsigned long</para>
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</entry>
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</row>
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<row>
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<entry>
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<para>VECTOR(UNSIGNED(16))</para>
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</entry>
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<entry>
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<para>vector unsigned __int128</para>
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</entry>
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</row>
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<row>
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<entry>
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<para>VECTOR(REAL(4))</para>
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</entry>
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<entry>
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<para>vector float</para>
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</entry>
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</row>
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<row>
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<entry>
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<para>VECTOR(REAL(8))</para>
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</entry>
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<entry>
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<para>vector double</para>
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</entry>
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</row>
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<row>
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<entry>
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<para>VECTOR(PIXEL)</para>
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</entry>
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<entry>
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<para>vector pixel</para>
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</entry>
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</row>
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</tbody>
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</tgroup>
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</table>
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</section>
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</section>
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<section>
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<title>Library Interfaces</title>
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<section>
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<title>printf and scanf of Vector Data Types</title>
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<para>Support for vector variable input and output
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<emphasis>may</emphasis> be provided as an extension to the following
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POSIX library functions for the new vector conversion format
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strings:</para>
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<itemizedlist spacing="compact">
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<listitem>
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<para>scanf</para>
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</listitem>
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<listitem>
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<para>fscanf</para>
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</listitem>
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<listitem>
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<para>sscanf</para>
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</listitem>
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<listitem>
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<para>wsscanf</para>
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</listitem>
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<listitem>
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<para>printf</para>
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</listitem>
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<listitem>
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<para>fprintf</para>
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</listitem>
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<listitem>
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<para>sprintf</para>
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</listitem>
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<listitem>
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<para>snprintf</para>
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</listitem>
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<listitem>
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<para>wsprintf</para>
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</listitem>
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<listitem>
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<para>vprintf</para>
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</listitem>
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<listitem>
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<para>vfprintf</para>
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</listitem>
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<listitem>
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<para>vsprintf</para>
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</listitem>
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<listitem>
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<para>vwsprintf</para>
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</listitem>
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</itemizedlist>
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<para>(One sample implementation for such an extended specification is
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libvecprintf.)</para>
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<para>The size formatters are as follows:</para>
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<itemizedlist>
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<listitem>
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<para>vl or lv consumes one argument and modifies an existing integer
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conversion, resulting in vector signed int, vector unsigned int, or
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vector bool for output conversions or vector signed int * or vector
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unsigned int * for input conversions. The data is then treated as a
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series of four 4-byte components, with the subsequent conversion
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format applied to each.</para>
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</listitem>
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<listitem>
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<para>vh or hv consumes one argument and modifies an existing short
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integer conversion, resulting in vector signed short or vector
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unsigned short for output conversions or vector signed short * or
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vector unsigned short * for input conversions. The data is treated as
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a series of eight 2-byte components, with the subsequent conversion
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format applied to each.</para>
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</listitem>
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<listitem>
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<para>v consumes one argument and modifies a 1-byte integer, 1-byte
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character, or 4-byte floating-point conversion. If the conversion is
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a floating-point conversion, the result is vector float for output
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conversion or vector float * for input conversion. The data is
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treated as a series of four 4-byte floating-point components with the
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subsequent conversion format applied to each. If the conversion is an
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integer or character conversion, the result is either vector signed
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char, vector unsigned char, or vector bool char for output
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conversion, or vector signed char * or vector unsigned char * for
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input conversions. The data is treated as a series of sixteen 1-byte
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components, with the subsequent conversion format applied to
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each.</para>
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</listitem>
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<listitem>
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<para>vv consumes one argument and modifies an 8-byte floating-point
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conversion. If the conversion is a floating-point conversion, the
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result is vector double for output conversion or vector double * for
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input conversion. The data is treated as a series of two 8-byte
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floating-point components with the subsequent conversion format
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applied to each. Integer and byte conversions are not defined for the
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vv modifier.</para>
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</listitem>
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</itemizedlist>
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<note>
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<para>As new vector types are defined, new format codes should
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be defined to support scanf and printf of those types.</para>
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</note>
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<para>Any conversion format that can be applied to the singular form of a
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vector-data type can be used with a vector form. The %d, %x, %X, %u, %i,
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and %o integer conversions can be applied with the %lv, %vl, %hv, %vh,
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and %v vector-length qualifiers. The %c character conversion can be
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applied with the %v vector length qualifier. The %a, %A, %e, %E, %f, %F,
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%g, and %G float conversions can be applied with the %v vector length
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qualifier.</para>
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<para>For input conversions, an optional separator character can be
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specified excluding white space preceding the separator. If no separator
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is specified, the default separator is a space including white space
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characters preceding the separator, unless the conversion is c. Then, the
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default conversion is null.</para>
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<para>For output conversions, an optional separator character can be
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specified immediately preceding the vector size conversion. If no
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separator is specified, the default separator is a space unless the
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conversion is c. Then, the default separator is null.</para>
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<para> </para>
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</section>
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</section>
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</chapter>
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