The present invention relates generally to computer hardware, and relates more particularly to the configuration of computing systems, for example, servers. Specifically, the present invention provides methods and an apparatus for automatic system parameter configuration for performance improvement.
The overwhelming success of the World Wide Web as a mechanism for facilitating information retrieval and conducting business transactions has led to an increase in the deployment of complex enterprise applications. These applications typically run on web application servers, which manage tasks including concurrency, memory management, database access and the like. The performance of an application server depends heavily on appropriate configuration, which is a difficult and error-prone task due to a large number of configuration parameters (which may number more than one hundred) and complex interactions between these parameters.
Despite the importance of configuration, the setting of parameters is an imprecise practice. For example, developers typically use rules-of-thumb, heuristics, or best practice guidelines provided by software vendors to derive the settings. However, configuration depends largely on the particular application being deployed and its expected workload, as well as the configuration of the systems with which it interacts.
Thus, there is a need in the art for a method and apparatus for automatic system parameter configuration for performance improvement.
In one embodiment, the present invention is a method and apparatus for automatic system parameter configuration for performance improvement. One embodiment of the inventive method involves formulating a black box optimization problem, and solving the optimization problem using an enhanced smart hill climbing method. The smart hill climbing method includes both a global and a more precise local search to identify an optimal solution. In one embodiment, one or both of the global and local searches employs a weighted Latin Hypercube Sampling method in combination with importance sampling techniques to yield improved search results.
So that the manner in which the above recited embodiments of the invention are attained and can be understood in detail, a more particular description of the invention, briefly summarized above, may be obtained by reference to the embodiments thereof which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only typical embodiments of this invention and are therefore not to be considered limiting of its scope, for the invention may admit to other equally effective embodiments.
To facilitate understanding, identical reference numerals have been used, where possible, to designate identical elements that are common to the figures.
In one embodiment, the present invention is a method and apparatus for automatic system parameter configuration for performance improvement. Although the invention will be described within the exemplary context of the configuration of an application server, those skilled in the art will appreciate that the present invention may be deployed to configure the system parameters of any computing system, and not just the parameters of an application server. The method of the present invention provides an efficient, automatic system for determining the optimal values of key system parameters. In turn, the implementation of the optimal parameter settings will improve system performance by minimizing system response time and maximizing system throughput.
wherein x=(x1, . . . , xN), Ii is the parameter range for parameter xi and I=Ii× . . . ×IN, where I is a compact set in IRN.
In one embodiment, the performance function g(x) is unknown or does not have a closed form. Thus, in step 204, the method 200 formulates the black box optimization problem as a problem where the objective function is black-box with limited function evaluation. The challenge is for the method 200 to obtain a global optimal solution.
When I is large, finding {right arrow over (X)} is generally difficult. In addition, function evaluation for each individual parameter setting x requires effort in setting up experiments and data collection, which can be time consuming and expensive. Thus, efficiency, i.e., the generation of a good solution with a minimum number of experiments, is of paramount importance in choosing a search method to solve the problem formulated in step 204.
Thus, in step 206, the method 200 implements a “smart hill climbing” method to solve the optimization problem formulated in step 204. As described in further detail with reference to
Once the method 300 has identified the appropriate starting point, the method 300 proceeds to step 306 and implements a local search starting from the starting point identified in step 304 and applying a gradient-based sampling method to search around the neighborhood of the starting point for a better solution to the optimization problem. Thus, the size of the neighborhood decreases as the local searching step 306 progresses. In one embodiment, the gradient-based sampling method is applied based on the construction of locally fitted quadratic functions, leading to better convergence for the location of optimal solutions. As the method 300 applies the gradient-based sampling method, the method 300 progresses toward step 308, where the method 300 identifies an optimal solution to the optimization problem.
The method 400 then proceeds to step 406 and, for the ith dimension (where i=1, . . . , N), divides the parameter range Ii into K non-overlapping intervals of equal probabilities, e.g., 1/K. The kth sample point will thus be an N-dimensional vector, with the value for the dimension i uniformly drawn from the Pki-th interval of Ii.
The method 600 then proceeds to step 608 and identifies the optimal (e.g., minimal) point on the quadratic curve. The minimal points for all dimensions are combined to form a next candidate for the best solution, e.g., {right arrow over (X)}. In step 610, the method 600 inquires if a better solution than the next candidate point identified in step 608 can be found. If a better solution can be found, the method 600 returns to step 604 and repeats the fitting procedure until no better solution can be found. Alternatively, if the method 600 determines at step 610 that no better solution can be found, the method 600 reduces the size of the sampling neighborhood in step 612. In one embodiment, a predefined shrink factor dictates the amount by which the sampling neighborhood is shrunk.
After reducing the size of the sampling neighborhood, the method 600 inquires in step 614 if the sampling neighborhood has been reduced within a predefined threshold. If the sampling neighborhood has not been reduced to within the predefined threshold, the method 600 returns to step 604 and attempts to further reduce the neighborhood size by repeating steps 604-612. Alternatively, if the method 600 concludes that the neighborhood size has been reduced to within the predefined threshold, the method 600 identifies a “solution” in step 616. The identified “solution” may be a local search starting point, if the method 600 is employed in a global search (e.g., step 304 of
Thus, the improved search method 600 takes into account knowledge learned about the correlation structures during a local searching step, the basic idea being that server performance is often correlated with certain parameters. The correlation corresponds to a linear approximation of the objective function, and can be roughly estimated through the sampled points. From the global search perspective, the correlation information can be combined with LHS to generate skewed random search samples. From the local search perspective, as described above, quadratic approximations may be employed to guide the search procedure to an optimal solution. In this way, the searching procedure takes advantage of sampled points and uses information from the sampled points to further guide the search procedure. In one embodiment, the smart hill climbing method 300 also draws random samples at the beginning and restarting phases. Further local sampling is performed from selected candidate points.
In one embodiment, key functions of the smart hill climbing method 300 include regression fitting of linear and quadratic functions (e.g., step 606 of method 600), finding minimal points of quadratic functions within given intervals (e.g., step 608 of method 600) and weighted LHS. One embodiment of a weighted LHS method incorporates the correlation between the server parameters x and the performance function g(x) to generate intervals for each dimension and to sample points from a given range.
In one embodiment, analysis of the correlation structure assumes that S experiments have been carried out (where S increases as the method 300 proceeds), where xS=(xS1, . . . , xSN) is a vector of parameter setting at experiment s and s=1, . . . , S, and where yss is a corresponding function value of the black box objective function (e.g., as formulated in step 204 of the method 200). For example, yss could be client response time. Thus, for an unknown function g:
ys=g(xs), s=1, . . . , S (EQN. 2)
The correlation structure may be analyzed based on the measurements described above. For example, the correlation between server performance and an individual tunable parameter i may be analyzed by linear regression, where estimates are obtained for ai and bi (i=1, . . . , N) based on the past S measurements, where:
Y=aiXi+bi (EQN. 3)
wherein Y=(yl, . . . , ys) Xi collects all used values for parameter I in the past S experiments and Xi=(xil, . . . xiS), ai=pi std(Y)/std(Xi), and pi is the correlation coefficient between the server performance and the parameter i.
One key feature of the smart hill climbing method 600 described with reference to
In one embodiment, importance sampling is implemented by the method 600 using a truncated exponential density function for generating samples. Since the idea is same in the sampling of all parameters, the truncated exponential density function may be expressed, without the subscript i, as:
ƒ(c, g, x)=ge−acx (EQN. 4)
wherein the sampling range is x ∈[m,M]. For ƒ(c, g, x) to be a density function, the normalizing factor g is:
In one embodiment, the interval [m, M] is divided into K intervals with equal probability 1/K. Letting zj be the jth dividing point:
j/K =∫nz
The solution for zj is thus:
In one embodiment, zj denotes the dividing points for a parameter range, e.g., for use in step 406 of the method 400, or for use in weighted LHS as described in further detail below with reference to
One point ξj is drawn from a given interval [zj, zj+1], which follows a conditional probability ƒ(c, g, x)/h, where h is a scaling constant. Thus, solving for h from the normalizing equation (e.g., EQN. 6):
Therefore, the expression for h is:
A random number, u, is drawn from a uniform distribution in an interval [0, 1]. The point ξj is drawn such that:
After standard algebraic manipulations, the expression for ξj becomes:
Thus,
The method 800 then proceeds to step 806 and, for the ith dimension (where i=1, . . . , N), divides the parameter range Ii into K non-overlapping intervals of equal probabilities, e.g., 1/K. In one embodiment, the dividing points are calculated according to EQN. 7, as described above. The method 800 then proceeds to step 808, and for the kth interval (for the ith dimension), generates a random sample ξki. In one embodiment, ξki is generated using EQN. 11, as described above. The jth sample point will thus be an N-dimensional vector, with the value for the dimension i equal to ξP
The present invention thus provides a reliable and efficient means for configuring computing systems, such as application servers. The present invention takes advantage of global trend and correlation information when generating samples from a global level, which optimizes performance for servers whose performance depends on certain parameters in a rough monotonic fashion on a global level. Moreover, by estimating local gradient properties, these estimated properties can be employed to guide local searching steps. Thus, the inventive method is enabled to quickly find high-quality solutions for server parameter optimization.
Alternatively, the server configuration module 905 can be represented by one or more software applications (or even a combination of software and hardware, e.g., using Application Specific Integrated Circuits (ASIC)), where the software is loaded from a storage medium (e.g., I/O devices 906) and operated by the processor 902 in the memory 904 of the general purpose computing device 900. Thus, in one embodiment, the server configuration module 905 for allocating resources among entities described herein with reference to the preceding Figures can be stored on a computer readable medium or carrier (e.g., RAM, magnetic or optical drive or diskette, and the like).
Thus, the present invention represents a significant advancement in the field of system parameter configuration (e.g., the configuration of application servers). A method including novel smart hill climbing and weighted LHS techniques is provided that exploits knowledge of past experiments in order to enable a system to be optimally configured in a manner that is quicker and more precise than existing configuration methods using uniform sampling techniques.
While foregoing is directed to the preferred embodiment of the present invention, other and further embodiments of the invention may be devised without departing from the basic scope thereof, and the scope thereof is determined by the claims that follow.
Number | Name | Date | Kind |
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20040267679 | Fromherz et al. | Dec 2004 | A1 |
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Number | Date | Country | |
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20050262230 A1 | Nov 2005 | US |