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Line 1: ~~The~~ <math>d</math>-dimensional ~~'''[[~~hypercube~~]]'''~~ is a network topology for parallel computers with <math>2^d</math> processing elements. The topology allows for an efficient implementation of some basic communication primitives such as [[~~Broadcasting_~~Broadcasting (networking)\|Broadcast]], All-[[~~Reduce_~~Reduce (~~parallel_pattern~~parallel pattern)\|Reduce]], and [[Prefix sum]].<ref>Grama, A.(2003). Introduction to Parallel Computing. Addison Wesley; Auflage: 2 ed. {{ISBN: \|978-0201648652}}.</ref> The processing elements are numbered ~~from~~ <math>0</math> tothrough <math>2^d - 1</math>. Each processing ~~elements~~element is ~~then~~ adjacent to processing elements whose numbers differ in ~~exactly~~one and only one bit. The algorithms described onin this page utilize this structure efficiently. == Algorithm ~~Outline~~outline == Most of the communication primitives presented in this article share a common template.<ref>Foster, I.(1995). Designing and Building Parallel Programs: Concepts and Tools for Parallel Software Engineering. Addison Wesley; {{ISBN: \|0201575949}}.</ref> Initially, each processing element possesses one message that must reach every other processing element during the course of the algorithm. The following pseudo code sketches the communication steps necessary. Hereby, '''Initialization''', '''Operation''', and '''Output''' are placeholders that depend on the given communication primitive (see next section). '''Input:''' message <math>m</math>. Line 11: <math>y := i \text{ XOR } 2^k</math> '''Send''' <math>s</math> '''to''' <math>y</math> '''~~Recieve~~Receive''' <math>m</math> '''from''' <math>y</math> '''Operation'''<math>(s, m)</math> '''endfor''' '''Output''' Each processing element iterates over its neighbors (the expression <math>i \text{ XOR } 2^k</math> negates the <math>k</math>-th bit in <math>i</math>'s binary representation, therefore obtaining the numbers of its neighbors). ~~During~~In aneach iteration, each processing element exchanges a message with the neighbor and processes the received message afterwards. The processing operation depends on the communication primitive. [[File:Hypergraph Communication Pattern.png\|thumb\|Algorithm outline applied to the <math>3</math>-dimensional hypercube. In the first step (before any communication), each processing element possesses one message (blue). Communication is marked red. After each step, the processing elements store the received message, but other operations are also possible.]] == Communication ~~Primitives~~primitives == === Prefix sum === AtIn the beginning of a [[~~Prefix_sum\|~~prefix sum]] operation, each processing element <math>i</math> owns a message <math>m_i</math>. The goal is to ~~calculate~~compute <math>\bigoplus_{0 \le j \le i} m_j</math>, where <math>\oplus</math> is an associative operation. The following pseudo code describes the algorithm. '''Input''': message <math>m_i</math> of processor <math>i</math>. '''Output''': prefix sum <math>\bigoplus_{0 \le j \le i} m_j</math> of processor <math>i</math>. <math>x := m_i</math> <math>\sigma := m_i</math> Line 41: This results in a factor of <math>\log p</math> for <math>T_\text{start}</math> and a factor of <math>n\log p</math> for <math>T_\text{byte}</math>: <math>T(n,p) = (T_\text{start} + nT_\text{byte})\log p</math>. [[File:Hypergraph Communication Steps for Prefix Sum.png\|thumb\|Example for a prefix sum calculation. Upper number: ~~number~~tentatetive prefix sum (variable <math>~~m_i~~x</math> ~~that each processing element contributes to the prefix sum~~). Lower number: ~~prefix~~ sum ~~(at~~over ~~the~~all ~~end~~elements ofin the ~~computation~~sub cube (variable <math>\sigma</math>).]] === All-~~Gather~~gather / ~~All~~all-~~Reduce~~reduce === '''All-~~Gather~~gather''' operations start with each processing element having a message <math>m_i</math>. The goal of the operation is for each processing element to know the messages of all other processing elements, i.e. <math>x := m_0 \cdot m_1 \dots m_p</math> where <math>\cdot</math> is concatenation. The operation can be implemented following the algorithm template. '''Input''': message <math>x := m_i</math> at processing unit <math>i</math>. '''Output''': all messages <math>m_1 \cdot m_2 \dots m_p</math>. <math>x := m_i</math> Line 58: With each iteration, the transferred message doubles in length. This leads to a runtime of <math>T(n,p) \approx \sum_{j=0}^{d-1}(T_\text{start} + n \cdot 2^jT_\text{byte})= \log(p) T_\text{start} + (p-1)nT_\text{byte}</math>. The same principle can be applied to the '''All-Reduce''' operations, but instead of concatenating the messages, it performs ana reduction operation on the two messages. So it is a '''Reduce''' operation, where all processing units know the result. InCompared ~~Hypercubes~~to a ~~modified~~normal reduce operation followed by a broadcast, ~~'''~~All-~~Gather'''~~Reduce in hypercubes reduces the number of ~~communications compared to Reduce and~~communication ~~Broadcast~~steps. === All-to-~~All~~all === Here every processing element has a unique message for all other processing elements. '''Input:''' message <math>m_{ij}</math> at processing element <math>i</math> to processing element <math>j</math>. '''for''' <math>d > k \geq 0</math> '''do''' '''Receive''' from processing element <math>i \text{ XOR } 2^k</math>: all messages for my <math>k</math>-dimensional sub cube '''Send''' to processing element <math>i \text{ XOR } 2^k</math>: all messages for its <math>k</math>-dimensional sub cube '''endfor''' With each iteration a messages comes closer to its destination by one dimension, if it hasn't arrived yet. SoHence, ~~there~~all ~~only~~messages have reached their target after at most <math>d = \log{p}</math> steps ~~needed~~. In every step, <math>p / 2</math> messages are sent.: Inin the first iteration, half of the messages aren't meant for the own sub cube. In every following step, the sub cube is only half the size as before, but in the previous step exactly the same number of messages arrived from another processing element. This results in a run-time of <math>T(n,p) \approx \log{p} (T_\text{start} + \frac{p}{2}nT_\text{byte})</math>. == ESBT-~~Broadcast~~broadcast == The ESBT-broadcast (Edge-disjoint Spanning Binomial Tree) algorithm<ref>{{cite journal\|last1=Johnsson\|first1=S.L.\|last2=Ho\|first2=C.-T.\|title=Optimum broadcasting and personalized communication in hypercubes\|journal=IEEE Transactions on Computers\|volume=38\|issue=9\|year=1989\|pages=1249–1268\|issn=~~00189340~~0018-9340\|doi=10.1109/12.29465}}</ref> is a pipelined broadcast algorithm with optimal runtime for clusters with hypercube network topology. The algorithm embeds <math>d</math> edge-disjoint binomial trees in the hypercube, such that each neighbor of processing element <math>0</math> is the root of a spanning binomial tree on <math>2^d - 1</math> nodes. To broadcast a message, the source node splits its message into <math>k</math> chunks of equal size and cyclically sends them to the roots of the binomial trees. Upon receiving a chunk, the binomial trees broadcast it. === Runtime === ~~The runtime of this algorithm is as follows.~~ In each step, the source node sends one of its <math>k</math> chunks to a binomial tree. Broadcasting the chunk within the binomial tree takes <math>d</math> steps. Thus, it takes <math>k</math> steps to distribute all chunks and additionally <math>d</math> steps until the last binomial tree broadcast has finished, resulting in <math>k + d</math> steps overall. Therefore, the runtime for a message of length <math>n</math> is <math>T(n, p, k) = \left(\frac{n}{k} T_\text{byte} + T_\text{start} \right) (k + d)</math>. With the optimal chunk size <math>k^* = \sqrt{\frac{nd \cdot T_\text{byte}}{T_\text{start}}}</math>, the optimal runtime of the algorithm is <math>T^(n, p) = n \cdot T_\text{byte} + \log(p) \cdot T_\text{start} + \sqrt{n \log(p) \cdot T_\text{start} \cdot T_\text{byte}}</math>. === Construction of the ~~Binomial~~binomial ~~Trees~~trees === [[File:HypergraphESBT.png\|thumb\|A <math>3</math>-dimensional hypercubes with three ESBT embedded.]] This section describes how to construct the binomial trees systematically. First, construct a single binomial spanning tree von <math>2^d</math> nodes as follows. Number the nodes from <math>0</math> to <math>2^d - 1</math> and consider their binary representation. Then the children of each nodes are obtained by negating single leading zeroes. This results in a single binomial spanning tree. To obtain <math>d</math> edge-disjoint copies of the tree, translate and rotate the nodes: for the <math>k</math>-th copy of the tree, apply a XOR operation with <math>2^k</math> to each node. ~~Afterwards~~Subsequently, right -rotate all nodes by <math>k</math> digits. The resulting binomial trees are edge-disjoint and therefore, fulfill the requirements for the ESBT-broadcasting algorithm. == See also == [[Hypercube internetwork topology]] ==References== {{Reflist}} [[Category:Parallel computing]] ~~== Referenzen ==~~