--- title: "Using mwcsr package" output: rmarkdown::html_vignette: toc: true vignette: > %\VignetteIndexEntry{Using mwcsr package} %\VignetteEngine{knitr::rmarkdown} %\VignetteEncoding{UTF-8} --- ```{r setup, include=FALSE} knitr::opts_chunk$set(cache = TRUE) ``` `mwcsr` is an R package to solve maximum weight connected subgraph (MWCS) problem and its variants. The package implements and provides an interface to several solvers: both exact and heuristic. ## Installation `mwcsr` can be installed from GitHub repository using `devtools` package: ```{r eval=F} library(devtools) install_github("ctlab/mwcsr") ``` ## Quick start Load `mwcsr`, as well as `igraph` package, which contains functions for graph manipulations. ```{r message=FALSE} library(mwcsr) library(igraph) ``` Let's load an example instance of MWCS problem. The instance is a simple `igraph` object with `weight` vertex attribute. ```{r} data("mwcs_example") print(mwcs_example) summary(V(mwcs_example)$weight) ``` Now let us initialize a heuristic relax-and-cut MWCS solver (Alvarez-Miranda and Sinnl, 2017): ```{r} rcsolver <- rmwcs_solver() ``` Now we can use this solver to solve the example instance: ```{r} m <- solve_mwcsp(rcsolver, mwcs_example) print(m$graph) print(m$weight) ``` ## Supported problem types Supported MWCS variants are: * classic (simple) MWCS, where only vertices are weighted; * generalized MWCS (GMWCS), where both vertices and edges are weighted; * signal generalized MWCS (SGMWCS), where both vertices and edges are marked with weighted "signals", and a weight of a subgraph is calculated as a sum of weights of its unique signals. In `mwcsr`, instances of all of the above problems are represented by an `igraph` object with certain specified attributes. The validity and the type of the instance can be checked using `get_instance_type` function, for example: ```{r} get_instance_type(mwcs_example) ``` ### Simple MWCS Simple maximum weight connected subgraph (MWCS) problem can be defined as follows. Let $G = (V, E)$ be an undirected graph and $\omega : V \rightarrow \mathbb{R}$ is a weight function defined on the vertices. Then MWCS problem consists in finding a connected subgraph $\widetilde{G} = (\widetilde{V}, \widetilde{E})$ with a maximal total sum of vertex weights: $$\Omega(\widetilde{G}) = \sum_{v \in \widetilde{V}} \omega(v) \rightarrow max.$$ An important property of MWCS is that solution can always be represented as a tree. In `mwcsr` an MWCS instance is defined as an `igraph` with `weight` vertex attribute (and without `weight` edge attribute). ```{r} mwcs_example summary(V(mwcs_example)$weight) ``` ### Budget MWCS Budget MWCS is a slight modification of the original problem. While the objective function remains the same, an additional constraint is introduced. In this problem nonnegative values called budget costs are assigned to vertices. The sum of budget costs of the vertices in the solution is then constrained to not exceed a predefined budget. More formally, let $c: V \rightarrow R^+$ be the function of the budget costs. $B \in R^+$ is a budget of the problem. In this terms Budget MWCS is defined as a problem where the following conditions are satisfied: $$ \Omega(\widetilde{G}) = \sum\limits_{v \in \widetilde{V}} \omega(v) \rightarrow max.\\ \text{subject to} \sum\limits_{v \in \widetilde{V}} c(v) \leq B $$ In `mwcsr` a Budget MWCS instance is an `igraph` object with `weight` vertex attribute as in original MWCS problem and additional `budget_cost` vertex attribute. Value of the budget not the part of the instance itself but rather a parameter to be passed to a function that solves an instance. ```{r} budget_mwcs_example <- mwcs_example set.seed(42) V(budget_mwcs_example)$budget_cost <- runif(vcount(budget_mwcs_example)) get_instance_type(budget_mwcs_example) ``` ### Generalized MWCS (GMWCS) Generalized MWCS (GMWCS) is similar to MWCS, but edges are also weighted. More formally, let $G = (V, E)$ be an undirected graph and $\omega : (V \cup E) \rightarrow \mathbb{R}$ is a weight function defined on the vertices and the edges. Then GMWCS problem consists in finding a connected subgraph $\widetilde{G} = (\widetilde{V}, \widetilde{E})$ with a a maximal total sum of vertex and edge weights: $$ \Omega(\widetilde{G}) = \sum_{v \in \widetilde{V}} \omega(v) + \sum_{e \in \widetilde{E}} \omega(e) \rightarrow max. $$ An important consequence of edge weights is that the optimal solution can contain cycles. A GMWCS instance is defined as an `igraph` with `weight` attribute defined for both vertices and edges. ```{r} data(gmwcs_example) gmwcs_example summary(V(gmwcs_example)$weight) summary(E(gmwcs_example)$weight) ``` ### Signal generalized MWCS (SGMWCS) The signal generalized MWCS (SGMWCS) variant continues to generalize MWCS problem and introduces a concept of _signals_. Instead of specifying vertex and edge weights directly, the weights are defined for a set of signals, and vertices and edges are marked with these signals. The difference from GMWCS is that the signals can be repeated in the graph, while the weight of the subgraph is defined as a sum of weights of its unique signals. Formally, let $G = (V, E)$ be an undirected graph, $S$ -- a set of signlas with weights $\omega: S \rightarrow \mathbb{R}$, and $\sigma: (V \cup E) \rightarrow 2^S$ -- markings of the vertices and edges with signals. An SGMWCS problem consists in finding a connected subgraph, with a maximal total sum of its unique signals: $$ \Omega(\widetilde{G}) = \sum_{s \in \sigma(\widetilde{V} \cup \widetilde{E})} \omega(s) \rightarrow max, $$ where $\sigma(\widetilde{V} \cup \widetilde{E}) = \bigcup_{x \in (\widetilde{V} \cup \widetilde{E})} \sigma(x)$. SGMWCS instances can arise when the data, from which the weights are inferred, map to the graph ambigously. For example, when m/z peak from mass-spectrometry data is assigned to multiple isomer metabolites, or when the same enzyme catalyze multiple reactions, and so on. Practically, it is usually assumed that the signals with negative weights are not repeated. An SGMWCS is represented as an `igraph` object, with `signal` attribute defined for both vertices and edges and a `signals` attribute defined for the graph, containing the signal weights. Specification of multiple signals per node or edge is not yet supported. ```{r} data("sgmwcs_example") sgmwcs_example str(V(sgmwcs_example)$signal) str(E(sgmwcs_example)$signal) head(sgmwcs_example$signals) ``` #### Constructing SGMWCS instances Sometimes, construction of SGMWCS instances can be simplified using `normalize_sgmwcs_instance` function. Let consider an example graph obtained from [gatom](https://github.com/ctlab/gatom) package. ```{r} data("gatom_example") print(gatom_example) ``` In this graph, the `signals` graph attributed is absent with weights specified directly as vertex or edge attributes along with `signal` attributes, which is a very practical intermediate representation. However, it is recognized as a GMWCS instance: ```{r} get_instance_type(gatom_example) ``` Let convert this representation into a valid SGMWCS instance using `normalize_sgmwcs_instance` function: ```{r} gatom_instance <- normalize_sgmwcs_instance(gatom_example) get_instance_type(gatom_instance) ``` And let call the same function with explicit arguments: ```{r} gatom_instance <- normalize_sgmwcs_instance(gatom_example, nodes.weight.column = "weight", edges.weight.column = "weight", nodes.group.by = "signal", edges.group.by = "signal", group.only.positive = TRUE) ``` The function does the following: 1. It extracts signal weights from the specified columns. `NULL` can be specified as a value of `nodes.group.by` or `edges.group.by` if there are no corresponding signals in the data, in which case zero signals will be created. 2. It splits input signals with negative weights into multiple unique signals, unless `group.only.positive` is set to `FALSE`. ## Supported solvers Currently, four solvers are supported: * heuristic relax-and-cut solver `rmwcs_solver` for MWCS and Budget MWCS; * heuristic relax-and-cut solver `rnc_solver` for MWCS/GMWCS/SGMWCS; * heuristic simulated annealing solver `annealing_solver` for MWCS/GMWCS/SGMWCS; * exact (if CPLEX library is available) or heuristic (without CPLEX) solver `virgo_solver` for MWCS/GMWCS/SGMWCS. * exact SCIP-Jack (if SCIP is available) solver `scipjack_solver` for MWCS; While selecting a particular solver depends on the particular class of instances, the general recommendations are: * For MWCS use `rmwcs_solver` if small suboptimality can be tolerated. It is very fast and usually is able to find optimal or very close to optimal solution. To find exact solution `virgo_solver` can be used if CPLEX library is available. * For Budget MWCS only `rmwcs_solver` is available. * For GMWCS and SGMWCS `virgo_solver` is the recommended solver if CPLEX library is available. Without CPLEX it is recommended to use `rnc_solver` giving both acceptable primal solution and an upper bound on the objective function. Manual tuning of the `annealing_solver` may give better solutions in some cases. ### Rmwcs solver Relax-and-cut solver is a heuristic solver able to rapidly find high-quality solutions for MWCS problem (Alvarez-Miranda and Sinnl, 2017, https://doi.org/10.1016/j.cor.2017.05.015). The solver does not require any additional libraries. Relax-and-cut solver can be constructed using `rmwcs_solver` function with the default arguments. ```{r} rmwcs <- rmwcs_solver() m <- solve_mwcsp(rmwcs, mwcs_example) print(m$weight) print(m$solved_to_optimality) ``` `rmwcs_solver` supports Budget MWCS instances and its special case where all budget costs are set to one and called MWCS with cardinality constraints. In `mwcsr` such problems are represented as Simple MWCS problems and maximum cardinality is passed to `solve_mwcsp` funciton as argument: ```{r} m <- solve_mwcsp(rmwcs, mwcs_example, max_cardinality = 10) print(vcount(m$graph)) print(m$weight) ``` To solve Budget MWCS passing budget limit is necessary as well: ```{r} m <- solve_mwcsp(rmwcs, budget_mwcs_example, budget = 10) print(sum(V(m$graph)$budget_cost)) print(m$weight) ``` ### Rnc solver Rnc solver is another relax-and-cut solver made for GMWCS/SGMWCS problems inspired by rmwcs solver. The solver does not require any libraries as well. Although with `rnc_solver` it is possible to solve MWCS problems, running `rmwcs_solver` for this type of problems of this type is preferable. No budget and cardinality variants are available. The solver can be constructed using `rnc_solver` function. ```{r} rnc <- rnc_solver() m <- solve_mwcsp(rnc, gmwcs_example) print(m$weight) print(m$solved_to_optimality) ``` And for SGMWCS instance: ```{r} rnc <- rnc_solver() m <- solve_mwcsp(rnc, sgmwcs_example) print(m$weight) ``` ### Simulated annealing solver Another heuristic solver is a simulated annealing based solver. The solver is rather generic, but can produce good enough solutions if parameters are tuned well. As it is heuristic solver with no estimate on upper bound of the objective function the solved to optimality flag is always set to `FALSE`. This solver does support warm start allowing to run series of restarts of annealing solver with different temperature schedules. The use of this solver may be beneficial in some cases, although there are no generic guidelines. ```{r} m <- NULL for (i in 0:15) { asolver <- annealing_solver(schedule = "boltzmann", initial_temperature = 8.0 / (2 ** i), final_temperature = 1 / (2 ** i)) if (i != 0) { m <- solve_mwcsp(asolver, gmwcs_example, warm_start = m) } else { m <- solve_mwcsp(asolver, gmwcs_example) } print(m$weight) } ``` ### Java-based Virgo solver The `mwcsr` package provides interface to exact Java-based Virgo solver (https://github.com/ctlab/virgo-solver) which can be used to solve MWCS, GMWCS and SGMWCS instances. The solver requires Java (11+) to be installed on your machine. There are two modes of execution: 1. Heuristic -- which finds a solution based on minimal spanning tree heuristic and does not require any additional setup; 2. Exact -- which uses CPLEX library to solve the instances to provable optimality. CPLEX can be downloaded from the official web-site: https://www.ibm.com/products/ilog-cplex-optimization-studio. Free licence can be obtained for academic purposes. CPLEX version 12.7.1 or higher is required. Heuristic solver can be constructed, by specifying `cplex_dir=NULL`. As it is a heuristic solver, the solved to optimality flag is always set to `FALSE`. ```{r} mst_solver <- virgo_solver(cplex_dir=NULL) m <- solve_mwcsp(mst_solver, sgmwcs_example) print(m$weight) print(m$solved_to_optimality) ``` Exact solver requires setting `cplex_dir` argument with a path to CPLEX installation. The `cplex_dir` requires, that `cplex.jar` file and CPLEX dynamic library file (depending on the operating system: `libcplex.dll` for Windows, `libcplex.so` for Linux, `libcplex.jnilib` for OS X) can be found there with recursive search. Alternatively, `cplex_jar` argument pointing to `cplex.jar` file and `cplex_bin` argument pointing to the directory with CPLEX dynamic library files can be specified. Additionally, it is convenient to put the path to CPLEX into a `CPLEX_HOME` environment variable, so that it does not have to be changed from one system to another, when run. ```{r, purl = FALSE, error = TRUE} cplex_dir <- Sys.getenv('CPLEX_HOME') exact_solver <- virgo_solver(cplex_dir=cplex_dir) m <- solve_mwcsp(exact_solver, sgmwcs_example) ``` As the CPLEX found the optimal solution, the corresponding flag is set to `TRUE`: ```{r, purl = FALSE, error = TRUE} print(m$weight) print(m$solved_to_optimality) ``` Some additional information like the running time, instance files, solver version is available as in the `stats` field. Refer to Virgo documentation for the description of the values. ```{r, purl = FALSE, error = TRUE} print(m$stats) ``` Computational resources availble for Virgo can be specified with the following parameters: * `memory` -- maximum amount of memory, more specifically Java heap size, specified via `-Xmx` Java option, default: `2G`. * `threads` -- number of threads for simultaneous computation, default: the number of available cores. * `timelimit` -- maximum time in seconds to solve the problem, if the solver is interrupted due to time limit, the best solution found so far is reported and `solved_to_optimality` flag is set to `FALSE`. Another useful parameter is `penalty`. The non-zero penalty make the solver run an additional pass over the solution, with each edge penalized with the specified value. As there can be multiple solutions, having the same weight, especially in case of SGMWCS, this procedure allows to locally minimize the solution size, while preserving the weight. ```{r, purl = FALSE, error = TRUE} psolver <- virgo_solver(cplex_dir=cplex_dir, penalty=0.001) min_m <- solve_mwcsp(psolver, sgmwcs_example) print(min_m$weight) print(min_m$stats) ``` Now the solution, has `min_m$stats$nodes` nodes instead of `m$stats$nodes` for the solution that was found before, while having the same total weight of `min_m$weight`. ### SCIP-jack solver You can also use R interface to SCIP-jack solver. To use it you need to download SCIPOptSuite from the [official web-site](https://scipopt.org/#scipoptsuite) and build `scipstp` application. Beware, that `scipstp` is not provided in the pre-built SCIPOptSuite version, so you have to build it manually from source. Quick build instructions: ```{bash eval=FALSE} # in scipoptsuite source directory cmake -Bbuild -H. cmake --build build --target scipstp # optionally copy scipstp file somewhere to $PATH cp build/applications/scipstp /usr/local/bin/ ``` For complete build and configuration instructions for this solver visit [SCIP](https://www.scipopt.org/doc/html/INSTALL_APPLICATIONS_EXAMPLES.php) website. After installing and ensuring that scipstp application is correctly built, you can access `scipjack_solver` class to solve MWCS instances: ```{r message=FALSE,eval=FALSE} scip <- scipjack_solver(scipstp_bin=Sys.which("scipstp")) sol <- solve_mwcsp(scip, mwcs_example) ``` The optimization parameters are passed using \href{https://www.scipopt.org/doc-6.0.2/html/PARAMETERS.php}{SCIPopt} config file. You can modify bundled file or create a new one to fine-tune the solver. ## Integration with BioNet This part of the tutorial shows how `mwcsr` solvers can be combined with `BioNet` package to find an active module in a protein-protein interaction network. You need `BioNet` and `DLBCL` packages from Bioconductor to be installed in order to run following code examples. ```{r, message=FALSE} BioNetInstalled <- FALSE if (requireNamespace("BioNet") && requireNamespace("DLBCL")) { BioNetInstalled <- TRUE } ``` Let start with generating an example scored network, following BioNet tutorial: ```{r message=FALSE} if (BioNetInstalled) { library("BioNet") library("DLBCL") data(dataLym) data(interactome) pvals <- cbind(t = dataLym$t.pval, s = dataLym$s.pval) rownames(pvals) <- dataLym$label pval <- aggrPvals(pvals, order = 2, plot = FALSE) logFC <- dataLym$diff names(logFC) <- dataLym$label subnet <- subNetwork(dataLym$label, interactome) subnet <- rmSelfLoops(subnet) fb <- fitBumModel(pval, plot = FALSE) scores <- scoreNodes(subnet, fb, fdr = 0.001) } ``` Here we have network object `subnet` of type `graphNEL` and a vector of node scores `scores`: ```{r} if (BioNetInstalled) { subnet str(scores) } ``` BioNet comes with a heuristic MWCS FastHeinz solver, that we can use to find the module following the BioNet tutorial: ```{r} if (BioNetInstalled) { bionet_h <- runFastHeinz(subnet, scores) plotModule(bionet_h, scores=scores, diff.expr=logFC) sum(scores[nodes(bionet_h)]) } ``` We can construct an MWCS instance by converting `graphNEL` object into `igraph` and add node weights: ```{r} if (BioNetInstalled) { bionet_example <- igraph.from.graphNEL(subnet, weight=FALSE) # ignoring edge weights of 1 V(bionet_example)$weight <- scores[V(bionet_example)] get_instance_type(bionet_example) } ``` Now the instance can be solved with the relax-and-cut solver: ```{r} if (BioNetInstalled) { rmwcs <- rmwcs_solver() bionet_m <- solve_mwcsp(rmwcs, bionet_example) plotModule(bionet_m$graph, scores=scores, diff.expr=logFC) } ``` Note that the weight increased, compared to FastHeinz solution: ```{r} if (BioNetInstalled) { print(bionet_m$weight) } ``` Similarly, Virgo can be used to solve the instance to provable optimality, but in this case it produces the same results: ```{r, purl = FALSE, error = TRUE} if (BioNetInstalled) { bionet_m_exact <- solve_mwcsp(exact_solver, bionet_example) print(bionet_m_exact$weight) print(bionet_m_exact$solved_to_optimality) } ```