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// inventory, path, realpath, root, and parent // // node.root is a reference to the root module in the tree (ie, typically the // cwd project folder) // // node.location is the /-delimited path from the root module to the node. In // the case of link targets that may be outside of the root's package tree, // this can include some number of /../ path segments. The location of the // root module is always '.'. node.location thus never contains drive letters // or absolute paths, and is portable within a given project, suitable for // inclusion in lockfiles and metadata. // // node.path is the path to the place where this node lives on disk. It is // system-specific and absolute. // // node.realpath is the path to where the module actually resides on disk. In // the case of non-link nodes, node.realpath is equivalent to node.path. In // the case of link nodes, it is equivalent to node.target.path. // // Setting node.parent will set the node's root to the parent's root, as well // as updating edgesIn and edgesOut to reload dependency resolutions as needed, // and setting node.path to parent.path/node_modules/name. // // node.inventory is a Map of name to a Set() of all the nodes under a given // root by that name. It's empty for non-root nodes, and changing the root // reference will remove it from the old root's inventory and add it to the new // one. This map is useful for cases like `npm update foo` or `npm ls foo` // where we need to quickly find all instances of a given package name within a // tree. const semver = require('semver') const nameFromFolder = require('@npmcli/name-from-folder') const Edge = require('./edge.js') const Inventory = require('./inventory.js') const OverrideSet = require('./override-set.js') const { normalize } = require('read-package-json-fast') const { getPaths: getBinPaths } = require('bin-links') const npa = require('npm-package-arg') const debug = require('./debug.js') const gatherDepSet = require('./gather-dep-set.js') const treeCheck = require('./tree-check.js') const { walkUp } = require('walk-up-path') const { resolve, relative, dirname, basename } = require('node:path') const util = require('node:util') const _package = Symbol('_package') const _parent = Symbol('_parent') const _target = Symbol.for('_target') const _fsParent = Symbol('_fsParent') const _reloadNamedEdges = Symbol('_reloadNamedEdges') // overridden by Link class const _loadDeps = Symbol.for('Arborist.Node._loadDeps') const _refreshLocation = Symbol.for('_refreshLocation') const _changePath = Symbol.for('_changePath') // used by Link class as well const _delistFromMeta = Symbol.for('_delistFromMeta') const _explain = Symbol('_explain') const _explanation = Symbol('_explanation') const relpath = require('./relpath.js') const consistentResolve = require('./consistent-resolve.js') const printableTree = require('./printable.js') const CaseInsensitiveMap = require('./case-insensitive-map.js') const querySelectorAll = require('./query-selector-all.js') class Node { #global #meta #root #workspaces constructor (options) { // NB: path can be null if it's a link target const { root, path, realpath, parent, error, meta, fsParent, resolved, integrity, // allow setting name explicitly when we haven't set a path yet name, children, fsChildren, installLinks = false, legacyPeerDeps = false, linksIn, isInStore = false, hasShrinkwrap, overrides, loadOverrides = false, extraneous = true, dev = true, optional = true, devOptional = true, peer = true, global = false, dummy = false, sourceReference = null, } = options // this object gives querySelectorAll somewhere to stash context about a node // while processing a query this.queryContext = {} // true if part of a global install this.#global = global this.#workspaces = null this.errors = error ? [error] : [] this.isInStore = isInStore // this will usually be null, except when modeling a // package's dependencies in a virtual root. this.sourceReference = sourceReference // TODO if this came from pacote.manifest we don't have to do this, // we can be told to skip this step const pkg = sourceReference ? sourceReference.package : normalize(options.pkg || {}) this.name = name || nameFromFolder(path || pkg.name || realpath) || pkg.name || null // should be equal if not a link this.path = path ? resolve(path) : null if (!this.name && (!this.path || this.path !== dirname(this.path))) { throw new TypeError('could not detect node name from path or package') } this.realpath = !this.isLink ? this.path : resolve(realpath) this.resolved = resolved || null if (!this.resolved) { // note: this *only* works for non-file: deps, so we avoid even // trying here. // file: deps are tracked in package.json will _resolved set to the // full path to the tarball or link target. However, if the package // is checked into git or moved to another location, that's 100% not // portable at all! The _where and _location don't provide much help, // since _location is just where the module ended up in the tree, // and _where can be different than the actual root if it's a // meta-dep deeper in the dependency graph. // // If we don't have the other oldest indicators of legacy npm, then it's // probably what we're getting from pacote, which IS trustworthy. // // Otherwise, hopefully a shrinkwrap will help us out. const resolved = consistentResolve(pkg._resolved) if (resolved && !(/^file:/.test(resolved) && pkg._where)) { this.resolved = resolved } } this.integrity = integrity || pkg._integrity || null this.hasShrinkwrap = hasShrinkwrap || pkg._hasShrinkwrap || false this.installLinks = installLinks this.legacyPeerDeps = legacyPeerDeps this.children = new CaseInsensitiveMap() this.fsChildren = new Set() this.inventory = new Inventory() this.tops = new Set() this.linksIn = new Set(linksIn || []) // these three are set by an Arborist taking a catalog // after the tree is built. We don't get this along the way, // because they have a tendency to change as new children are // added, especially when they're deduped. Eg, a dev dep may be // a 3-levels-deep dependency of a non-dev dep. If we calc the // flags along the way, then they'll tend to be invalid by the // time we need to look at them. if (!dummy) { this.dev = dev this.optional = optional this.devOptional = devOptional this.peer = peer this.extraneous = extraneous this.dummy = false } else { // true if this is a placeholder for the purpose of serving as a // fsParent to link targets that get their deps resolved outside // the root tree folder. this.dummy = true this.dev = false this.optional = false this.devOptional = false this.peer = false this.extraneous = false } this.edgesIn = new Set() this.edgesOut = new CaseInsensitiveMap() // have to set the internal package ref before assigning the parent, // because this.package is read when adding to inventory this[_package] = pkg && typeof pkg === 'object' ? pkg : {} if (overrides) { this.overrides = overrides } else if (loadOverrides) { const overrides = this[_package].overrides || {} if (Object.keys(overrides).length > 0) { this.overrides = new OverrideSet({ overrides: this[_package].overrides, }) } } // only relevant for the root and top nodes this.meta = meta // Note: this is _slightly_ less efficient for the initial tree // building than it could be, but in exchange, it's a much simpler // algorithm. // If this node has a bunch of children, and those children satisfy // its various deps, then we're going to _first_ create all the // edges, and _then_ assign the children into place, re-resolving // them all in _reloadNamedEdges. // A more efficient, but more complicated, approach would be to // flag this node as being a part of a tree build, so it could // hold off on resolving its deps until its children are in place. // call the parent setter // Must be set prior to calling _loadDeps, because top-ness is relevant // will also assign root if present on the parent this[_parent] = null this.parent = parent || null this[_fsParent] = null this.fsParent = fsParent || null // see parent/root setters below. // root is set to parent's root if we have a parent, otherwise if it's // null, then it's set to the node itself. if (!parent && !fsParent) { this.root = root || null } // mostly a convenience for testing, but also a way to create // trees in a more declarative way than setting parent on each if (children) { for (const c of children) { new Node({ ...c, parent: this }) } } if (fsChildren) { for (const c of fsChildren) { new Node({ ...c, fsParent: this }) } } // now load all the dep edges this[_loadDeps]() } get meta () { return this.#meta } set meta (meta) { this.#meta = meta if (meta) { meta.add(this) } } get global () { if (this.#root === this) { return this.#global } return this.#root.global } // true for packages installed directly in the global node_modules folder get globalTop () { return this.global && this.parent && this.parent.isProjectRoot } get workspaces () { return this.#workspaces } set workspaces (workspaces) { // deletes edges if they already exists if (this.#workspaces) { for (const name of this.#workspaces.keys()) { if (!workspaces.has(name)) { this.edgesOut.get(name).detach() } } } this.#workspaces = workspaces this.#loadWorkspaces() this[_loadDeps]() } get binPaths () { if (!this.parent) { return [] } return getBinPaths({ pkg: this[_package], path: this.path, global: this.global, top: this.globalTop, }) } get hasInstallScript () { const { hasInstallScript, scripts } = this.package const { install, preinstall, postinstall } = scripts || {} return !!(hasInstallScript || install || preinstall || postinstall) } get version () { return this[_package].version || '' } get packageName () { return this[_package].name || null } get pkgid () { const { name = '', version = '' } = this.package // root package will prefer package name over folder name, // and never be called an alias. const { isProjectRoot } = this const myname = isProjectRoot ? name || this.name : this.name const alias = !isProjectRoot && name && myname !== name ? `npm:${name}@` : '' return `${myname}@${alias}${version}` } get overridden () { return !!(this.overrides && this.overrides.value && this.overrides.name === this.name) } get package () { return this[_package] } set package (pkg) { // just detach them all. we could make this _slightly_ more efficient // by only detaching the ones that changed, but we'd still have to walk // them all, and the comparison logic gets a bit tricky. we generally // only do this more than once at the root level, so the resolve() calls // are only one level deep, and there's not much to be saved, anyway. // simpler to just toss them all out. for (const edge of this.edgesOut.values()) { edge.detach() } this[_explanation] = null /* istanbul ignore next - should be impossible */ if (!pkg || typeof pkg !== 'object') { debug(() => { throw new Error('setting Node.package to non-object') }) pkg = {} } this[_package] = pkg this.#loadWorkspaces() this[_loadDeps]() // do a hard reload, since the dependents may now be valid or invalid // as a result of the package change. this.edgesIn.forEach(edge => edge.reload(true)) } // node.explain(nodes seen already, edge we're trying to satisfy // if edge is not specified, it lists every edge into the node. explain (edge = null, seen = []) { if (this[_explanation]) { return this[_explanation] } return this[_explanation] = this[_explain](edge, seen) } [_explain] (edge, seen) { if (this.isProjectRoot && !this.sourceReference) { return { location: this.path, } } const why = { name: this.isProjectRoot || this.isTop ? this.packageName : this.name, version: this.package.version, } if (this.errors.length || !this.packageName || !this.package.version) { why.errors = this.errors.length ? this.errors : [ new Error('invalid package: lacks name and/or version'), ] why.package = this.package } if (this.root.sourceReference) { const { name, version } = this.root.package why.whileInstalling = { name, version, path: this.root.sourceReference.path, } } if (this.sourceReference) { return this.sourceReference.explain(edge, seen) } if (seen.includes(this)) { return why } why.location = this.location why.isWorkspace = this.isWorkspace // make a new list each time. we can revisit, but not loop. seen = seen.concat(this) why.dependents = [] if (edge) { why.dependents.push(edge.explain(seen)) } else { // ignore invalid edges, since those aren't satisfied by this thing, // and are not keeping it held in this spot anyway. const edges = [] for (const edge of this.edgesIn) { if (!edge.valid && !edge.from.isProjectRoot) { continue } edges.push(edge) } for (const edge of edges) { why.dependents.push(edge.explain(seen)) } } if (this.linksIn.size) { why.linksIn = [...this.linksIn].map(link => link[_explain](edge, seen)) } return why } isDescendantOf (node) { for (let p = this; p; p = p.resolveParent) { if (p === node) { return true } } return false } getBundler (path = []) { // made a cycle, definitely not bundled! if (path.includes(this)) { return null } path.push(this) const parent = this[_parent] if (!parent) { return null } const pBundler = parent.getBundler(path) if (pBundler) { return pBundler } const ppkg = parent.package const bd = ppkg && ppkg.bundleDependencies // explicit bundling if (Array.isArray(bd) && bd.includes(this.name)) { return parent } // deps that are deduped up to the bundling level are bundled. // however, if they get their dep met further up than that, // then they are not bundled. Ie, installing a package with // unmet bundled deps will not cause your deps to be bundled. for (const edge of this.edgesIn) { const eBundler = edge.from.getBundler(path) if (!eBundler) { continue } if (eBundler === parent) { return eBundler } } return null } get inBundle () { return !!this.getBundler() } // when reifying, if a package is technically in a bundleDependencies list, // but that list is the root project, we still have to install it. This // getter returns true if it's in a dependency's bundle list, not the root's. get inDepBundle () { const bundler = this.getBundler() return !!bundler && bundler !== this.root } get isWorkspace () { if (this.isProjectRoot) { return false } const { root } = this const { type, to } = root.edgesOut.get(this.packageName) || {} return type === 'workspace' && to && (to.target === this || to === this) } get isRoot () { return this === this.root } get isProjectRoot () { // only treat as project root if it's the actual link that is the root, // or the target of the root link, but NOT if it's another link to the // same root that happens to be somewhere else. return this === this.root || this === this.root.target } get isRegistryDependency () { if (this.edgesIn.size === 0) { return false } for (const edge of this.edgesIn) { if (!npa(edge.spec).registry) { return false } } return true } * ancestry () { for (let anc = this; anc; anc = anc.resolveParent) { yield anc } } set root (root) { // setting to null means this is the new root // should only ever be one step while (root && root.root !== root) { root = root.root } root = root || this // delete from current root inventory this[_delistFromMeta]() // can't set the root (yet) if there's no way to determine location // this allows us to do new Node({...}) and then set the root later. // just make the assignment so we don't lose it, and move on. if (!this.path || !root.realpath || !root.path) { this.#root = root return } // temporarily become a root node this.#root = this // break all linksIn, we're going to re-set them if needed later for (const link of this.linksIn) { link[_target] = null this.linksIn.delete(link) } // temporarily break this link as well, we'll re-set if possible later const { target } = this if (this.isLink) { if (target) { target.linksIn.delete(this) if (target.root === this) { target[_delistFromMeta]() } } this[_target] = null } // if this is part of a cascading root set, then don't do this bit // but if the parent/fsParent is in a different set, we have to break // that reference before proceeding if (this.parent && this.parent.root !== root) { this.parent.children.delete(this.name) this[_parent] = null } if (this.fsParent && this.fsParent.root !== root) { this.fsParent.fsChildren.delete(this) this[_fsParent] = null } if (root === this) { this[_refreshLocation]() } else { // setting to some different node. const loc = relpath(root.realpath, this.path) const current = root.inventory.get(loc) // clobber whatever is there now if (current) { current.root = null } this.#root = root // set this.location and add to inventory this[_refreshLocation]() // try to find our parent/fsParent in the new root inventory for (const p of walkUp(dirname(this.path))) { if (p === this.path) { continue } const ploc = relpath(root.realpath, p) const parent = root.inventory.get(ploc) if (parent) { /* istanbul ignore next - impossible */ if (parent.isLink) { debug(() => { throw Object.assign(new Error('assigning parentage to link'), { path: this.path, parent: parent.path, parentReal: parent.realpath, }) }) continue } const childLoc = `${ploc}${ploc ? '/' : ''}node_modules/${this.name}` const isParent = this.location === childLoc if (isParent) { const oldChild = parent.children.get(this.name) if (oldChild && oldChild !== this) { oldChild.root = null } if (this.parent) { this.parent.children.delete(this.name) this.parent[_reloadNamedEdges](this.name) } parent.children.set(this.name, this) this[_parent] = parent // don't do it for links, because they don't have a target yet // we'll hit them up a bit later on. if (!this.isLink) { parent[_reloadNamedEdges](this.name) } } else { /* istanbul ignore if - should be impossible, since we break * all fsParent/child relationships when moving? */ if (this.fsParent) { this.fsParent.fsChildren.delete(this) } parent.fsChildren.add(this) this[_fsParent] = parent } break } } // if it doesn't have a parent, it's a top node if (!this.parent) { root.tops.add(this) } else { root.tops.delete(this) } // assign parentage for any nodes that need to have this as a parent // this can happen when we have a node at nm/a/nm/b added *before* // the node at nm/a, which might have the root node as a fsParent. // we can't rely on the public setter here, because it calls into // this function to set up these references! // check dirname so that /foo isn't treated as the fsparent of /foo-bar const nmloc = `${this.location}${this.location ? '/' : ''}node_modules/` // only walk top nodes, since anything else already has a parent. for (const child of root.tops) { const isChild = child.location === nmloc + child.name const isFsChild = dirname(child.path).startsWith(this.path) && child !== this && !child.parent && ( !child.fsParent || child.fsParent === this || dirname(this.path).startsWith(child.fsParent.path) ) if (!isChild && !isFsChild) { continue } // set up the internal parentage links if (this.isLink) { child.root = null } else { // can't possibly have a parent, because it's in tops if (child.fsParent) { child.fsParent.fsChildren.delete(child) } child[_fsParent] = null if (isChild) { this.children.set(child.name, child) child[_parent] = this root.tops.delete(child) } else { this.fsChildren.add(child) child[_fsParent] = this } } } // look for any nodes with the same realpath. either they're links // to that realpath, or a thing at that realpath if we're adding a link // (if we're adding a regular node, we already deleted the old one) for (const node of root.inventory.query('realpath', this.realpath)) { if (node === this) { continue } /* istanbul ignore next - should be impossible */ debug(() => { if (node.root !== root) { throw new Error('inventory contains node from other root') } }) if (this.isLink) { const target = node.target this[_target] = target this[_package] = target.package target.linksIn.add(this) // reload edges here, because now we have a target if (this.parent) { this.parent[_reloadNamedEdges](this.name) } break } else { /* istanbul ignore else - should be impossible */ if (node.isLink) { node[_target] = this node[_package] = this.package this.linksIn.add(node) if (node.parent) { node.parent[_reloadNamedEdges](node.name) } } else { debug(() => { throw Object.assign(new Error('duplicate node in root setter'), { path: this.path, realpath: this.realpath, root: root.realpath, }) }) } } } } // reload all edgesIn where the root doesn't match, so we don't have // cross-tree dependency graphs for (const edge of this.edgesIn) { if (edge.from.root !== root) { edge.reload() } } // reload all edgesOut where root doens't match, or is missing, since // it might not be missing in the new tree for (const edge of this.edgesOut.values()) { if (!edge.to || edge.to.root !== root) { edge.reload() } } // now make sure our family comes along for the ride! const family = new Set([ ...this.fsChildren, ...this.children.values(), ...this.inventory.values(), ].filter(n => n !== this)) for (const child of family) { if (child.root !== root) { child[_delistFromMeta]() child[_parent] = null this.children.delete(child.name) child[_fsParent] = null this.fsChildren.delete(child) for (const l of child.linksIn) { l[_target] = null child.linksIn.delete(l) } } } for (const child of family) { if (child.root !== root) { child.root = root } } // if we had a target, and didn't find one in the new root, then bring // it over as well, but only if we're setting the link into a new root, // as we don't want to lose the target any time we remove a link. if (this.isLink && target && !this.target && root !== this) { target.root = root } if (!this.overrides && this.parent && this.parent.overrides) { this.overrides = this.parent.overrides.getNodeRule(this) } // tree should always be valid upon root setter completion. treeCheck(this) if (this !== root) { treeCheck(root) } } get root () { return this.#root || this } #loadWorkspaces () { if (!this.#workspaces) { return } for (const [name, path] of this.#workspaces.entries()) { new Edge({ from: this, name, spec: `file:${path.replace(/#/g, '%23')}`, type: 'workspace' }) } } [_loadDeps] () { // Caveat! Order is relevant! // Packages in optionalDependencies are optional. // Packages in both deps and devDeps are required. // Note the subtle breaking change from v6: it is no longer possible // to have a different spec for a devDep than production dep. // Linked targets that are disconnected from the tree are tops, // but don't have a 'path' field, only a 'realpath', because we // don't know their canonical location. We don't need their devDeps. const pd = this.package.peerDependencies const ad = this.package.acceptDependencies || {} if (pd && typeof pd === 'object' && !this.legacyPeerDeps) { const pm = this.package.peerDependenciesMeta || {} const peerDependencies = {} const peerOptional = {} for (const [name, dep] of Object.entries(pd)) { if (pm[name]?.optional) { peerOptional[name] = dep } else { peerDependencies[name] = dep } } this.#loadDepType(peerDependencies, 'peer', ad) this.#loadDepType(peerOptional, 'peerOptional', ad) } this.#loadDepType(this.package.dependencies, 'prod', ad) this.#loadDepType(this.package.optionalDependencies, 'optional', ad) const { globalTop, isTop, path, sourceReference } = this const { globalTop: srcGlobalTop, isTop: srcTop, path: srcPath, } = sourceReference || {} const thisDev = isTop && !globalTop && path const srcDev = !sourceReference || srcTop && !srcGlobalTop && srcPath if (thisDev && srcDev) { this.#loadDepType(this.package.devDependencies, 'dev', ad) } } #loadDepType (deps, type, ad) { // Because of the order in which _loadDeps runs, we always want to // prioritize a new edge over an existing one for (const [name, spec] of Object.entries(deps || {})) { const current = this.edgesOut.get(name) if (!current || current.type !== 'workspace') { new Edge({ from: this, name, spec, accept: ad[name], type }) } } } get fsParent () { // in debug setter prevents fsParent from being this return this[_fsParent] } set fsParent (fsParent) { if (!fsParent) { if (this[_fsParent]) { this.root = null } return } debug(() => { if (fsParent === this) { throw new Error('setting node to its own fsParent') } if (fsParent.realpath === this.realpath) { throw new Error('setting fsParent to same path') } // the initial set MUST be an actual walk-up from the realpath // subsequent sets will re-root on the new fsParent's path. if (!this[_fsParent] && this.realpath.indexOf(fsParent.realpath) !== 0) { throw Object.assign(new Error('setting fsParent improperly'), { path: this.path, realpath: this.realpath, fsParent: { path: fsParent.path, realpath: fsParent.realpath, }, }) } }) if (fsParent.isLink) { fsParent = fsParent.target } // setting a thing to its own fsParent is not normal, but no-op for safety if (this === fsParent || fsParent.realpath === this.realpath) { return } // nothing to do if (this[_fsParent] === fsParent) { return } const oldFsParent = this[_fsParent] const newPath = !oldFsParent ? this.path : resolve(fsParent.path, relative(oldFsParent.path, this.path)) const nmPath = resolve(fsParent.path, 'node_modules', this.name) // this is actually the parent, set that instead if (newPath === nmPath) { this.parent = fsParent return } const pathChange = newPath !== this.path // remove from old parent/fsParent const oldParent = this.parent const oldName = this.name if (this.parent) { this.parent.children.delete(this.name) this[_parent] = null } if (this.fsParent) { this.fsParent.fsChildren.delete(this) this[_fsParent] = null } // update this.path/realpath for this and all children/fsChildren if (pathChange) { this[_changePath](newPath) } if (oldParent) { oldParent[_reloadNamedEdges](oldName) } // clobbers anything at that path, resets all appropriate references this.root = fsParent.root } // is it safe to replace one node with another? check the edges to // make sure no one will get upset. Note that the node might end up // having its own unmet dependencies, if the new node has new deps. // Note that there are cases where Arborist will opt to insert a node // into the tree even though this function returns false! This is // necessary when a root dependency is added or updated, or when a // root dependency brings peer deps along with it. In that case, we // will go ahead and create the invalid state, and then try to resolve // it with more tree construction, because it's a user request. canReplaceWith (node, ignorePeers) { if (node.name !== this.name) { return false } if (node.packageName !== this.packageName) { return false } // XXX need to check for two root nodes? if (node.overrides !== this.overrides) { return false } ignorePeers = new Set(ignorePeers) // gather up all the deps of this node and that are only depended // upon by deps of this node. those ones don't count, since // they'll be replaced if this node is replaced anyway. const depSet = gatherDepSet([this], e => e.to !== this && e.valid) for (const edge of this.edgesIn) { // when replacing peer sets, we need to be able to replace the entire // peer group, which means we ignore incoming edges from other peers // within the replacement set. if (!this.isTop && edge.from.parent === this.parent && edge.peer && ignorePeers.has(edge.from.name)) { continue } // only care about edges that don't originate from this node if (!depSet.has(edge.from) && !edge.satisfiedBy(node)) { return false } } return true } canReplace (node, ignorePeers) { return node.canReplaceWith(this, ignorePeers) } // return true if it's safe to remove this node, because anything that // is depending on it would be fine with the thing that they would resolve // to if it was removed, or nothing is depending on it in the first place. canDedupe (preferDedupe = false) { // not allowed to mess with shrinkwraps or bundles if (this.inDepBundle || this.inShrinkwrap) { return false } // it's a top level pkg, or a dep of one if (!this.resolveParent || !this.resolveParent.resolveParent) { return false } // no one wants it, remove it if (this.edgesIn.size === 0) { return true } const other = this.resolveParent.resolveParent.resolve(this.name) // nothing else, need this one if (!other) { return false } // if it's the same thing, then always fine to remove if (other.matches(this)) { return true } // if the other thing can't replace this, then skip it if (!other.canReplace(this)) { return false } // if we prefer dedupe, or if the version is greater/equal, take the other if (preferDedupe || semver.gte(other.version, this.version)) { return true } return false } satisfies (requested) { if (requested instanceof Edge) { return this.name === requested.name && requested.satisfiedBy(this) } const parsed = npa(requested) const { name = this.name, rawSpec: spec } = parsed return this.name === name && this.satisfies(new Edge({ from: new Node({ path: this.root.realpath }), type: 'prod', name, spec, })) } matches (node) { // if the nodes are literally the same object, obviously a match. if (node === this) { return true } // if the names don't match, they're different things, even if // the package contents are identical. if (node.name !== this.name) { return false } // if they're links, they match if the targets match if (this.isLink) { return node.isLink && this.target.matches(node.target) } // if they're two project root nodes, they're different if the paths differ if (this.isProjectRoot && node.isProjectRoot) { return this.path === node.path } // if the integrity matches, then they're the same. if (this.integrity && node.integrity) { return this.integrity === node.integrity } // if no integrity, check resolved if (this.resolved && node.resolved) { return this.resolved === node.resolved } // if no resolved, check both package name and version // otherwise, conclude that they are different things return this.packageName && node.packageName && this.packageName === node.packageName && this.version && node.version && this.version === node.version } // replace this node with the supplied argument // Useful when mutating an ideal tree, so we can avoid having to call // the parent/root setters more than necessary. replaceWith (node) { node.replace(this) } replace (node) { this[_delistFromMeta]() // if the name matches, but is not identical, we are intending to clobber // something case-insensitively, so merely setting name and path won't // have the desired effect. just set the path so it'll collide in the // parent's children map, and leave it at that. if (node.parent?.children.get(this.name) === node) { this.path = resolve(node.parent.path, 'node_modules', this.name) } else { this.path = node.path this.name = node.name } if (!this.isLink) { this.realpath = this.path } this[_refreshLocation]() // keep children when a node replaces another if (!this.isLink) { for (const kid of node.children.values()) { kid.parent = this } if (node.isLink && node.target) { node.target.root = null } } if (!node.isRoot) { this.root = node.root } treeCheck(this) } get inShrinkwrap () { return this.parent && (this.parent.hasShrinkwrap || this.parent.inShrinkwrap) } get parent () { // setter prevents _parent from being this return this[_parent] } // This setter keeps everything in order when we move a node from // one point in a logical tree to another. Edges get reloaded, // metadata updated, etc. It's also called when we *replace* a node // with another by the same name (eg, to update or dedupe). // This does a couple of walks out on the node_modules tree, recursing // into child nodes. However, as setting the parent is typically done // with nodes that don't have have many children, and (deduped) package // trees tend to be broad rather than deep, it's not that bad. // The only walk that starts from the parent rather than this node is // limited by edge name. set parent (parent) { // when setting to null, just remove it from the tree entirely if (!parent) { // but only delete it if we actually had a parent in the first place // otherwise it's just setting to null when it's already null if (this[_parent]) { this.root = null } return } if (parent.isLink) { parent = parent.target } // setting a thing to its own parent is not normal, but no-op for safety if (this === parent) { return } const oldParent = this[_parent] // nothing to do if (oldParent === parent) { return } // ok now we know something is actually changing, and parent is not a link const newPath = resolve(parent.path, 'node_modules', this.name) const pathChange = newPath !== this.path // remove from old parent/fsParent if (oldParent) { oldParent.children.delete(this.name) this[_parent] = null } if (this.fsParent) { this.fsParent.fsChildren.delete(this) this[_fsParent] = null } // update this.path/realpath for this and all children/fsChildren if (pathChange) { this[_changePath](newPath) } if (parent.overrides) { this.overrides = parent.overrides.getNodeRule(this) } // clobbers anything at that path, resets all appropriate references this.root = parent.root } // Call this before changing path or updating the _root reference. // Removes the node from its root the metadata and inventory. [_delistFromMeta] () { const root = this.root if (!root.realpath || !this.path) { return } root.inventory.delete(this) root.tops.delete(this) if (root.meta) { root.meta.delete(this.path) } /* istanbul ignore next - should be impossible */ debug(() => { if ([...root.inventory.values()].includes(this)) { throw new Error('failed to delist') } }) } // update this.path/realpath and the paths of all children/fsChildren [_changePath] (newPath) { // have to de-list before changing paths this[_delistFromMeta]() const oldPath = this.path this.path = newPath const namePattern = /(?:^|\/|\\)node_modules[\\/](@[^/\\]+[\\/][^\\/]+|[^\\/]+)$/ const nameChange = newPath.match(namePattern) if (nameChange && this.name !== nameChange[1]) { this.name = nameChange[1].replace(/\\/g, '/') } // if we move a link target, update link realpaths if (!this.isLink) { this.realpath = newPath for (const link of this.linksIn) { link[_delistFromMeta]() link.realpath = newPath link[_refreshLocation]() } } // if we move /x to /y, then a module at /x/a/b becomes /y/a/b for (const child of this.fsChildren) { child[_changePath](resolve(newPath, relative(oldPath, child.path))) } for (const [name, child] of this.children.entries()) { child[_changePath](resolve(newPath, 'node_modules', name)) } this[_refreshLocation]() } // Called whenever the root/parent is changed. // NB: need to remove from former root's meta/inventory and then update // this.path BEFORE calling this method! [_refreshLocation] () { const root = this.root const loc = relpath(root.realpath, this.path) this.location = loc root.inventory.add(this) if (root.meta) { root.meta.add(this) } } assertRootOverrides () { if (!this.isProjectRoot || !this.overrides) { return } for (const edge of this.edgesOut.values()) { // if these differ an override has been applied, those are not allowed // for top level dependencies so throw an error if (edge.spec !== edge.rawSpec && !edge.spec.startsWith('$')) { throw Object.assign(new Error(`Override for ${edge.name}@${edge.rawSpec} conflicts with direct dependency`), { code: 'EOVERRIDE' }) } } } addEdgeOut (edge) { if (this.overrides) { edge.overrides = this.overrides.getEdgeRule(edge) } this.edgesOut.set(edge.name, edge) } addEdgeIn (edge) { if (edge.overrides) { this.overrides = edge.overrides } this.edgesIn.add(edge) // try to get metadata from the yarn.lock file if (this.root.meta) { this.root.meta.addEdge(edge) } } [_reloadNamedEdges] (name, rootLoc = this.location) { const edge = this.edgesOut.get(name) // if we don't have an edge, do nothing, but keep descending const rootLocResolved = edge && edge.to && edge.to.location === `${rootLoc}/node_modules/${edge.name}` const sameResolved = edge && this.resolve(name) === edge.to const recheck = rootLocResolved || !sameResolved if (edge && recheck) { edge.reload(true) } for (const c of this.children.values()) { c[_reloadNamedEdges](name, rootLoc) } for (const c of this.fsChildren) { c[_reloadNamedEdges](name, rootLoc) } } get isLink () { return false } get target () { return this } set target (n) { debug(() => { throw Object.assign(new Error('cannot set target on non-Link Nodes'), { path: this.path, }) }) } get depth () { if (this.isTop) { return 0 } return this.parent.depth + 1 } get isTop () { return !this.parent || this.globalTop } get top () { if (this.isTop) { return this } return this.parent.top } get isFsTop () { return !this.fsParent } get fsTop () { if (this.isFsTop) { return this } return this.fsParent.fsTop } get resolveParent () { return this.parent || this.fsParent } resolve (name) { /* istanbul ignore next - should be impossible, * but I keep doing this mistake in tests */ debug(() => { if (typeof name !== 'string' || !name) { throw new Error('non-string passed to Node.resolve') } }) const mine = this.children.get(name) if (mine) { return mine } const resolveParent = this.resolveParent if (resolveParent) { return resolveParent.resolve(name) } return null } inNodeModules () { const rp = this.realpath const name = this.name const scoped = name.charAt(0) === '@' const d = dirname(rp) const nm = scoped ? dirname(d) : d const dir = dirname(nm) const base = scoped ? `${basename(d)}/${basename(rp)}` : basename(rp) return base === name && basename(nm) === 'node_modules' ? dir : false } // maybe accept both string value or array of strings // seems to be what dom API does querySelectorAll (query, opts) { return querySelectorAll(this, query, opts) } toJSON () { return printableTree(this) } [util.inspect.custom] () { return this.toJSON() } } module.exports = Node