// Copyright 2021 The Go Authors. All rights reserved.
// Use of this source code is governed by a BSD-style
// license that can be found in the LICENSE file.
package modload
import (
"cmd/go/internal/cfg"
"cmd/go/internal/gover"
"cmd/go/internal/mvs"
"cmd/internal/par"
"context"
"errors"
"fmt"
"maps"
"os"
"slices"
"golang.org/x/mod/module"
)
// editRequirements returns an edited version of rs such that:
//
// 1. Each module version in mustSelect is selected.
//
// 2. Each module version in tryUpgrade is upgraded toward the indicated
// version as far as can be done without violating (1).
// (Other upgrades are also allowed if they are caused by
// transitive requirements of versions in mustSelect or
// tryUpgrade.)
//
// 3. Each module version in rs.rootModules (or rs.graph, if rs is unpruned)
// is downgraded or upgraded from its original version only to the extent
// needed to satisfy (1) and (2).
//
// Generally, the module versions in mustSelect are due to the module or a
// package within the module matching an explicit command line argument to 'go
// get', and the versions in tryUpgrade are transitive dependencies that are
// either being upgraded by 'go get -u' or being added to satisfy some
// otherwise-missing package import.
//
// If pruning is enabled, the roots of the edited requirements include an
// explicit entry for each module path in tryUpgrade, mustSelect, and the roots
// of rs, unless the selected version for the module path is "none".
func editRequirements(ctx context.Context, rs *Requirements, tryUpgrade, mustSelect []module.Version) (edited *Requirements, changed bool, err error) {
if rs.pruning == workspace {
panic("editRequirements cannot edit workspace requirements")
}
orig := rs
// If we already know what go version we will end up on after the edit, and
// the pruning for that version is different, go ahead and apply it now.
//
// If we are changing from pruned to unpruned, then we MUST check the unpruned
// graph for conflicts from the start. (Checking only for pruned conflicts
// would miss some that would be introduced later.)
//
// If we are changing from unpruned to pruned, then we would like to avoid
// unnecessary downgrades due to conflicts that would be pruned out of the
// final graph anyway.
//
// Note that even if we don't find a go version in mustSelect, it is possible
// that we will switch from unpruned to pruned (but not the other way around!)
// after applying the edits if we find a dependency that requires a high
// enough go version to trigger an upgrade.
rootPruning := orig.pruning
for _, m := range mustSelect {
if m.Path == "go" {
rootPruning = pruningForGoVersion(m.Version)
break
} else if m.Path == "toolchain" && pruningForGoVersion(gover.FromToolchain(m.Version)) == unpruned {
// We don't know exactly what go version we will end up at, but we know
// that it must be a version supported by the requested toolchain, and
// that toolchain does not support pruning.
//
// TODO(bcmills): 'go get' ought to reject explicit toolchain versions
// older than gover.GoStrictVersion. Once that is fixed, is this still
// needed?
rootPruning = unpruned
break
}
}
if rootPruning != rs.pruning {
rs, err = convertPruning(ctx, rs, rootPruning)
if err != nil {
return orig, false, err
}
}
// selectedRoot records the edited version (possibly "none") for each module
// path that would be a root in the edited requirements.
var selectedRoot map[string]string // module path → edited version
if rootPruning == pruned {
selectedRoot = maps.Clone(rs.maxRootVersion)
} else {
// In a module without graph pruning, modules that provide packages imported
// by the main module may either be explicit roots or implicit transitive
// dependencies. To the extent possible, we want to preserve those implicit
// dependencies, so we need to treat everything in the build list as
// potentially relevant — that is, as what would be a “root” in a module
// with graph pruning enabled.
mg, err := rs.Graph(ctx)
if err != nil {
// If we couldn't load the graph, we don't know what its requirements were
// to begin with, so we can't edit those requirements in a coherent way.
return orig, false, err
}
bl := mg.BuildList()[MainModules.Len():]
selectedRoot = make(map[string]string, len(bl))
for _, m := range bl {
selectedRoot[m.Path] = m.Version
}
}
for _, r := range tryUpgrade {
if v, ok := selectedRoot[r.Path]; ok && gover.ModCompare(r.Path, v, r.Version) >= 0 {
continue
}
if cfg.BuildV {
fmt.Fprintf(os.Stderr, "go: trying upgrade to %v\n", r)
}
selectedRoot[r.Path] = r.Version
}
// conflicts is a list of conflicts that we cannot resolve without violating
// some version in mustSelect. It may be incomplete, but we want to report
// as many conflicts as we can so that the user can solve more of them at once.
var conflicts []Conflict
// mustSelectVersion is an index of the versions in mustSelect.
mustSelectVersion := make(map[string]string, len(mustSelect))
for _, r := range mustSelect {
if v, ok := mustSelectVersion[r.Path]; ok && v != r.Version {
prev := module.Version{Path: r.Path, Version: v}
if gover.ModCompare(r.Path, v, r.Version) > 0 {
conflicts = append(conflicts, Conflict{Path: []module.Version{prev}, Constraint: r})
} else {
conflicts = append(conflicts, Conflict{Path: []module.Version{r}, Constraint: prev})
}
continue
}
mustSelectVersion[r.Path] = r.Version
selectedRoot[r.Path] = r.Version
}
// We've indexed all of the data we need and we've computed the initial
// versions of the roots. Now we need to load the actual module graph and
// restore the invariant that every root is the selected version of its path.
//
// For 'go mod tidy' we would do that using expandGraph, which upgrades the
// roots until their requirements are internally consistent and then drops out
// the old roots. However, here we need to do more: we also need to make sure
// the modules in mustSelect don't get upgraded above their intended versions.
// To do that, we repeatedly walk the module graph, identify paths of
// requirements that result in versions that are too high, and downgrade the
// roots that lead to those paths. When no conflicts remain, we're done.
//
// Since we want to report accurate paths to each conflict, we don't drop out
// older-than-selected roots until the process completes. That might mean that
// we do some extra downgrades when they could be skipped, but for the benefit
// of being able to explain the reason for every downgrade that seems
// worthwhile.
//
// Graph pruning adds an extra wrinkle: a given node in the module graph
// may be reached from a root whose dependencies are pruned, and from a root
// whose dependencies are not pruned. It may be the case that the path from
// the unpruned root leads to a conflict, while the path from the pruned root
// prunes out the requirements that would lead to that conflict.
// So we need to track the two kinds of paths independently.
// They join back together at the roots of the graph: if a root r1 with pruned
// requirements depends on a root r2 with unpruned requirements, then
// selecting r1 would cause r2 to become a root and pull in all of its
// unpruned dependencies.
//
// The dqTracker type implements the logic for propagating conflict paths
// through the pruned and unpruned parts of the module graph.
//
// We make a best effort to fix incompatibilities, subject to two properties:
//
// 1. If the user runs 'go get' with a set of mutually-compatible module
// versions, we should accept those versions.
//
// 2. If we end up upgrading or downgrading a module, it should be
// clear why we did so.
//
// We don't try to find an optimal SAT solution,
// especially given the complex interactions with graph pruning.
var (
roots []module.Version // the current versions in selectedRoot, in sorted order
rootsDirty = true // true if roots does not match selectedRoot
)
// rejectedRoot records the set of module versions that have been disqualified
// as roots of the module graph. When downgrading due to a conflict or error,
// we skip any version that has already been rejected.
//
// NOTE(bcmills): I am not sure that the rejectedRoot map is really necessary,
// since we normally only downgrade roots or accept indirect upgrades to
// known-good versions. However, I am having trouble proving that accepting an
// indirect upgrade never introduces a conflict that leads to further
// downgrades. I really want to be able to prove that editRequirements
// terminates, and the easiest way to prove it is to add this map.
//
// Then the proof of termination is this:
// On every iteration where we mark the roots as dirty, we add some new module
// version to the map. The universe of module versions is finite, so we must
// eventually reach a state in which we do not add any version to the map.
// In that state, we either report a conflict or succeed in the edit.
rejectedRoot := map[module.Version]bool{}
for rootsDirty && len(conflicts) == 0 {
roots = roots[:0]
for p, v := range selectedRoot {
if v != "none" {
roots = append(roots, module.Version{Path: p, Version: v})
}
}
gover.ModSort(roots)
// First, we extend the graph so that it includes the selected version
// of every root. The upgraded roots are in addition to the original
// roots, so we will have enough information to trace a path to each
// conflict we discover from one or more of the original roots.
mg, upgradedRoots, err := extendGraph(ctx, rootPruning, roots, selectedRoot)
if err != nil {
var tooNew *gover.TooNewError
if mg == nil || errors.As(err, &tooNew) {
return orig, false, err
}
// We're about to walk the entire extended module graph, so we will find
// any error then — and we will either try to resolve it by downgrading
// something or report it as a conflict with more detail.
}
// extendedRootPruning is an index of the pruning used to load each root in
// the extended module graph.
extendedRootPruning := make(map[module.Version]modPruning, len(roots)+len(upgradedRoots))
findPruning := func(m module.Version) modPruning {
if rootPruning == pruned {
summary, _ := mg.loadCache.Get(m)
if summary != nil && summary.pruning == unpruned {
return unpruned
}
}
return rootPruning
}
for _, m := range roots {
extendedRootPruning[m] = findPruning(m)
}
for m := range upgradedRoots {
extendedRootPruning[m] = findPruning(m)
}
// Now check the resulting extended graph for errors and incompatibilities.
t := dqTracker{extendedRootPruning: extendedRootPruning}
mg.g.WalkBreadthFirst(func(m module.Version) {
if max, ok := mustSelectVersion[m.Path]; ok && gover.ModCompare(m.Path, m.Version, max) > 0 {
// m itself violates mustSelect, so it cannot appear in the module graph
// even if its transitive dependencies would be pruned out.
t.disqualify(m, pruned, dqState{dep: m})
return
}
summary, err := mg.loadCache.Get(m)
if err != nil && err != par.ErrCacheEntryNotFound {
// We can't determine the requirements of m, so we don't know whether
// they would be allowed. This may be a transient error reaching the
// repository, rather than a permanent error with the retrieved version.
//
// TODO(golang.org/issue/31730, golang.org/issue/30134):
// decide what to do based on the actual error.
t.disqualify(m, pruned, dqState{err: err})
return
}
reqs, ok := mg.RequiredBy(m)
if !ok {
// The dependencies of m do not appear in the module graph, so they
// can't be causing any problems this time.
return
}
if summary == nil {
if m.Version != "" {
panic(fmt.Sprintf("internal error: %d reqs present for %v, but summary is nil", len(reqs), m))
}
// m is the main module: we are editing its dependencies, so it cannot
// become disqualified.
return
}
// Before we check for problems due to transitive dependencies, first
// check m's direct requirements. A requirement on a version r that
// violates mustSelect disqualifies m, even if the requirements of r are
// themselves pruned out.
for _, r := range reqs {
if max, ok := mustSelectVersion[r.Path]; ok && gover.ModCompare(r.Path, r.Version, max) > 0 {
t.disqualify(m, pruned, dqState{dep: r})
return
}
}
for _, r := range reqs {
if !t.require(m, r) {
break
}
}
})
// We have now marked all of the versions in the graph that have conflicts,
// with a path to each conflict from one or more roots that introduce it.
// Now we need to identify those roots and change their versions
// (if possible) in order to resolve the conflicts.
rootsDirty = false
for _, m := range roots {
path, err := t.path(m, extendedRootPruning[m])
if len(path) == 0 && err == nil {
continue // Nothing wrong with m; we can keep it.
}
// path leads to a module with a problem: either it violates a constraint,
// or some error prevents us from determining whether it violates a
// constraint. We might end up logging or returning the conflict
// information, so go ahead and fill in the details about it.
conflict := Conflict{
Path: path,
Err: err,
}
if err == nil {
var last module.Version = path[len(path)-1]
mustV, ok := mustSelectVersion[last.Path]
if !ok {
fmt.Fprintf(os.Stderr, "go: %v\n", conflict)
panic("internal error: found a version conflict, but no constraint it violates")
}
conflict.Constraint = module.Version{
Path: last.Path,
Version: mustV,
}
}
if v, ok := mustSelectVersion[m.Path]; ok && v == m.Version {
// m is in mustSelect, but is marked as disqualified due to a transitive
// dependency.
//
// In theory we could try removing module paths that don't appear in
// mustSelect (added by tryUpgrade or already present in rs) in order to
// get graph pruning to take effect, but (a) it is likely that 'go mod
// tidy' would re-add those roots and reintroduce unwanted upgrades,
// causing confusion, and (b) deciding which roots to try to eliminate
// would add a lot of complexity.
//
// Instead, we report the path to the conflict as an error.
// If users want to explicitly prune out nodes from the dependency
// graph, they can always add an explicit 'exclude' directive.
conflicts = append(conflicts, conflict)
continue
}
// If m is not the selected version of its path, we have two options: we
// can either upgrade to the version that actually is selected (dropping m
// itself out of the bottom of the module graph), or we can try
// downgrading it.
//
// If the version we would be upgrading to is ok to use, we will just plan
// to do that and avoid the overhead of trying to find some lower version
// to downgrade to.
//
// However, it is possible that m depends on something that leads to its
// own upgrade, so if the upgrade isn't viable we should go ahead and try
// to downgrade (like with any other root).
if v := mg.Selected(m.Path); v != m.Version {
u := module.Version{Path: m.Path, Version: v}
uPruning, ok := t.extendedRootPruning[m]
if !ok {
fmt.Fprintf(os.Stderr, "go: %v\n", conflict)
panic(fmt.Sprintf("internal error: selected version of root %v is %v, but it was not expanded as a new root", m, u))
}
if !t.check(u, uPruning).isDisqualified() && !rejectedRoot[u] {
// Applying the upgrade from m to u will resolve the conflict,
// so plan to do that if there are no other conflicts to resolve.
continue
}
}
// Figure out what version of m's path was present before we started
// the edit. We want to make sure we consider keeping it as-is,
// even if it wouldn't normally be included. (For example, it might
// be a pseudo-version or pre-release.)
origMG, _ := orig.Graph(ctx)
origV := origMG.Selected(m.Path)
if conflict.Err != nil && origV == m.Version {
// This version of m.Path was already in the module graph before we
// started editing, and the problem with it is that we can't load its
// (transitive) requirements.
//
// If this conflict was just one step in a longer chain of downgrades,
// then we would want to keep going past it until we find a version
// that doesn't have that problem. However, we only want to downgrade
// away from an *existing* requirement if we can confirm that it actually
// conflicts with mustSelect. (For example, we don't want
// 'go get -u ./...' to incidentally downgrade some dependency whose
// go.mod file is unavailable or has a bad checksum.)
conflicts = append(conflicts, conflict)
continue
}
// We need to downgrade m's path to some lower version to try to resolve
// the conflict. Find the next-lowest candidate and apply it.
rejectedRoot[m] = true
prev := m
for {
prev, err = previousVersion(ctx, prev)
if gover.ModCompare(m.Path, m.Version, origV) > 0 && (gover.ModCompare(m.Path, prev.Version, origV) < 0 || err != nil) {
// previousVersion skipped over origV. Insert it into the order.
prev.Version = origV
} else if err != nil {
// We don't know the next downgrade to try. Give up.
return orig, false, err
}
if rejectedRoot[prev] {
// We already rejected prev in a previous round.
// To ensure that this algorithm terminates, don't try it again.
continue
}
pruning := rootPruning
if pruning == pruned {
if summary, err := mg.loadCache.Get(m); err == nil {
pruning = summary.pruning
}
}
if t.check(prev, pruning).isDisqualified() {
// We found a problem with prev this round that would also disqualify
// it as a root. Don't bother trying it next round.
rejectedRoot[prev] = true
continue
}
break
}
selectedRoot[m.Path] = prev.Version
rootsDirty = true
// If this downgrade is potentially interesting, log the reason for it.
if conflict.Err != nil || cfg.BuildV {
var action string
if prev.Version == "none" {
action = fmt.Sprintf("removing %s", m)
} else if prev.Version == origV {
action = fmt.Sprintf("restoring %s", prev)
} else {
action = fmt.Sprintf("trying %s", prev)
}
fmt.Fprintf(os.Stderr, "go: %s\n\t%s\n", conflict.Summary(), action)
}
}
if rootsDirty {
continue
}
// We didn't resolve any issues by downgrading, but we may still need to
// resolve some conflicts by locking in upgrades. Do that now.
//
// We don't do these upgrades until we're done downgrading because the
// downgrade process might reveal or remove conflicts (by changing which
// requirement edges are pruned out).
var upgradedFrom []module.Version // for logging only
for p, v := range selectedRoot {
if _, ok := mustSelectVersion[p]; !ok {
if actual := mg.Selected(p); actual != v {
if cfg.BuildV {
upgradedFrom = append(upgradedFrom, module.Version{Path: p, Version: v})
}
selectedRoot[p] = actual
// Accepting the upgrade to m.Path might cause the selected versions
// of other modules to fall, because they were being increased by
// dependencies of m that are no longer present in the graph.
//
// TODO(bcmills): Can removing m as a root also cause the selected
// versions of other modules to rise? I think not: we're strictly
// removing non-root nodes from the module graph, which can't cause
// any root to decrease (because they're roots), and the dependencies
// of non-roots don't matter because they're either always unpruned or
// always pruned out.
//
// At any rate, it shouldn't cost much to reload the module graph one
// last time and confirm that it is stable.
rootsDirty = true
}
}
}
if rootsDirty {
if cfg.BuildV {
gover.ModSort(upgradedFrom) // Make logging deterministic.
for _, m := range upgradedFrom {
fmt.Fprintf(os.Stderr, "go: accepting indirect upgrade from %v to %s\n", m, selectedRoot[m.Path])
}
}
continue
}
break
}
if len(conflicts) > 0 {
return orig, false, &ConstraintError{Conflicts: conflicts}
}
if rootPruning == unpruned {
// An unpruned go.mod file lists only a subset of the requirements needed
// for building packages. Figure out which requirements need to be explicit.
var rootPaths []string
// The modules in mustSelect are always promoted to be explicit.
for _, m := range mustSelect {
if m.Version != "none" && !MainModules.Contains(m.Path) {
rootPaths = append(rootPaths, m.Path)
}
}
for _, m := range roots {
if v, ok := rs.rootSelected(m.Path); ok && (v == m.Version || rs.direct[m.Path]) {
// m.Path was formerly a root, and either its version hasn't changed or
// we believe that it provides a package directly imported by a package
// or test in the main module. For now we'll assume that it is still
// relevant enough to remain a root. If we actually load all of the
// packages and tests in the main module (which we are not doing here),
// we can revise the explicit roots at that point.
rootPaths = append(rootPaths, m.Path)
}
}
roots, err = mvs.Req(MainModules.mustGetSingleMainModule(), rootPaths, &mvsReqs{roots: roots})
if err != nil {
return nil, false, err
}
}
changed = rootPruning != orig.pruning || !slices.Equal(roots, orig.rootModules)
if !changed {
// Because the roots we just computed are unchanged, the entire graph must
// be the same as it was before. Save the original rs, since we have
// probably already loaded its requirement graph.
return orig, false, nil
}
// A module that is not even in the build list necessarily cannot provide
// any imported packages. Mark as direct only the direct modules that are
// still in the build list. (We assume that any module path that provided a
// direct import before the edit continues to do so after. There are a few
// edge cases where that can change, such as if a package moves into or out of
// a nested module or disappears entirely. If that happens, the user can run
// 'go mod tidy' to clean up the direct/indirect annotations.)
//
// TODO(bcmills): Would it make more sense to leave the direct map as-is
// but allow it to refer to modules that are no longer in the build list?
// That might complicate updateRoots, but it may be cleaner in other ways.
direct := make(map[string]bool, len(rs.direct))
for _, m := range roots {
if rs.direct[m.Path] {
direct[m.Path] = true
}
}
edited = newRequirements(rootPruning, roots, direct)
// If we ended up adding a dependency that upgrades our go version far enough
// to activate pruning, we must convert the edited Requirements in order to
// avoid dropping transitive dependencies from the build list the next time
// someone uses the updated go.mod file.
//
// Note that it isn't possible to go in the other direction (from pruned to
// unpruned) unless the "go" or "toolchain" module is explicitly listed in
// mustSelect, which we already handled at the very beginning of the edit.
// That is because the virtual "go" module only requires a "toolchain",
// and the "toolchain" module never requires anything else, which means that
// those two modules will never be downgraded due to a conflict with any other
// constraint.
if rootPruning == unpruned {
if v, ok := edited.rootSelected("go"); ok && pruningForGoVersion(v) == pruned {
// Since we computed the edit with the unpruned graph, and the pruned
// graph is a strict subset of the unpruned graph, this conversion
// preserves the exact (edited) build list that we already computed.
//
// However, it does that by shoving the whole build list into the roots of
// the graph. 'go get' will check for that sort of transition and log a
// message reminding the user how to clean up this mess we're about to
// make. 😅
edited, err = convertPruning(ctx, edited, pruned)
if err != nil {
return orig, false, err
}
}
}
return edited, true, nil
}
// extendGraph loads the module graph from roots, and iteratively extends it by
// unpruning the selected version of each module path that is a root in rs or in
// the roots slice until the graph reaches a fixed point.
//
// The graph is guaranteed to converge to a fixed point because unpruning a
// module version can only increase (never decrease) the selected versions,
// and the set of versions for each module is finite.
//
// The extended graph is useful for diagnosing version conflicts: for each
// selected module version, it can provide a complete path of requirements from
// some root to that version.
func extendGraph(ctx context.Context, rootPruning modPruning, roots []module.Version, selectedRoot map[string]string) (mg *ModuleGraph, upgradedRoot map[module.Version]bool, err error) {
for {
mg, err = readModGraph(ctx, rootPruning, roots, upgradedRoot)
// We keep on going even if err is non-nil until we reach a steady state.
// (Note that readModGraph returns a non-nil *ModuleGraph even in case of
// errors.) The caller may be able to fix the errors by adjusting versions,
// so we really want to return as complete a result as we can.
if rootPruning == unpruned {
// Everything is already unpruned, so there isn't anything we can do to
// extend it further.
break
}
nPrevRoots := len(upgradedRoot)
for p := range selectedRoot {
// Since p is a root path, when we fix up the module graph to be
// consistent with the selected versions, p will be promoted to a root,
// which will pull in its dependencies. Ensure that its dependencies are
// included in the module graph.
v := mg.g.Selected(p)
if v == "none" {
// Version “none” always has no requirements, so it doesn't need
// an explicit node in the module graph.
continue
}
m := module.Version{Path: p, Version: v}
if _, ok := mg.g.RequiredBy(m); !ok && !upgradedRoot[m] {
// The dependencies of the selected version of p were not loaded.
// Mark it as an upgrade so that we will load its dependencies
// in the next iteration.
//
// Note that we don't remove any of the existing roots, even if they are
// no longer the selected version: with graph pruning in effect this may
// leave some spurious dependencies in the graph, but it at least
// preserves enough of the graph to explain why each upgrade occurred:
// this way, we can report a complete path from the passed-in roots
// to every node in the module graph.
//
// This process is guaranteed to reach a fixed point: since we are only
// adding roots (never removing them), the selected version of each module
// can only increase, never decrease, and the set of module versions in the
// universe is finite.
if upgradedRoot == nil {
upgradedRoot = make(map[module.Version]bool)
}
upgradedRoot[m] = true
}
}
if len(upgradedRoot) == nPrevRoots {
break
}
}
return mg, upgradedRoot, err
}
type perPruning[T any] struct {
pruned T
unpruned T
}
func (pp perPruning[T]) from(p modPruning) T {
if p == unpruned {
return pp.unpruned
}
return pp.pruned
}
// A dqTracker tracks and propagates the reason that each module version
// cannot be included in the module graph.
type dqTracker struct {
// extendedRootPruning is the modPruning given the go.mod file for each root
// in the extended module graph.
extendedRootPruning map[module.Version]modPruning
// dqReason records whether and why each encountered version is
// disqualified in a pruned or unpruned context.
dqReason map[module.Version]perPruning[dqState]
// requiring maps each not-yet-disqualified module version to the versions
// that would cause that module's requirements to be included in a pruned or
// unpruned context. If that version becomes disqualified, the
// disqualification will be propagated to all of the versions in the
// corresponding list.
//
// This map is similar to the module requirement graph, but includes more
// detail about whether a given dependency edge appears in a pruned or
// unpruned context. (Other commands do not need this level of detail.)
requiring map[module.Version][]module.Version
}
// A dqState indicates whether and why a module version is “disqualified” from
// being used in a way that would incorporate its requirements.
//
// The zero dqState indicates that the module version is not known to be
// disqualified, either because it is ok or because we are currently traversing
// a cycle that includes it.
type dqState struct {
err error // if non-nil, disqualified because the requirements of the module could not be read
dep module.Version // disqualified because the module is or requires dep
}
func (dq dqState) isDisqualified() bool {
return dq != dqState{}
}
func (dq dqState) String() string {
if dq.err != nil {
return dq.err.Error()
}
if dq.dep != (module.Version{}) {
return dq.dep.String()
}
return "(no conflict)"
}
// require records that m directly requires r, in case r becomes disqualified.
// (These edges are in the opposite direction from the edges in an mvs.Graph.)
//
// If r is already disqualified, require propagates the disqualification to m
// and returns the reason for the disqualification.
func (t *dqTracker) require(m, r module.Version) (ok bool) {
rdq := t.dqReason[r]
rootPruning, isRoot := t.extendedRootPruning[r]
if isRoot && rdq.from(rootPruning).isDisqualified() {
// When we pull in m's dependencies, we will have an edge from m to r, and r
// is disqualified (it is a root, which causes its problematic dependencies
// to always be included). So we cannot pull in m's dependencies at all:
// m is completely disqualified.
t.disqualify(m, pruned, dqState{dep: r})
return false
}
if dq := rdq.from(unpruned); dq.isDisqualified() {
t.disqualify(m, unpruned, dqState{dep: r})
if _, ok := t.extendedRootPruning[m]; !ok {
// Since m is not a root, its dependencies can't be included in the pruned
// part of the module graph, and will never be disqualified from a pruned
// reason. We've already disqualified everything that matters.
return false
}
}
// Record that m is a dependent of r, so that if r is later disqualified
// m will be disqualified as well.
if t.requiring == nil {
t.requiring = make(map[module.Version][]module.Version)
}
t.requiring[r] = append(t.requiring[r], m)
return true
}
// disqualify records why the dependencies of m cannot be included in the module
// graph if reached from a part of the graph with the given pruning.
//
// Since the pruned graph is a subgraph of the unpruned graph, disqualifying a
// module from a pruned part of the graph also disqualifies it in the unpruned
// parts.
func (t *dqTracker) disqualify(m module.Version, fromPruning modPruning, reason dqState) {
if !reason.isDisqualified() {
panic("internal error: disqualify called with a non-disqualifying dqState")
}
dq := t.dqReason[m]
if dq.from(fromPruning).isDisqualified() {
return // Already disqualified for some other reason; don't overwrite it.
}
rootPruning, isRoot := t.extendedRootPruning[m]
if fromPruning == pruned {
dq.pruned = reason
if !dq.unpruned.isDisqualified() {
// Since the pruned graph of m is a subgraph of the unpruned graph, if it
// is disqualified due to something in the pruned graph, it is certainly
// disqualified in the unpruned graph from the same reason.
dq.unpruned = reason
}
} else {
dq.unpruned = reason
if dq.pruned.isDisqualified() {
panic(fmt.Sprintf("internal error: %v is marked as disqualified when pruned, but not when unpruned", m))
}
if isRoot && rootPruning == unpruned {
// Since m is a root that is always unpruned, any other roots — even
// pruned ones! — that cause it to be selected would also cause the reason
// for is disqualification to be included in the module graph.
dq.pruned = reason
}
}
if t.dqReason == nil {
t.dqReason = make(map[module.Version]perPruning[dqState])
}
t.dqReason[m] = dq
if isRoot && (fromPruning == pruned || rootPruning == unpruned) {
// Either m is disqualified even when its dependencies are pruned,
// or m's go.mod file causes its dependencies to *always* be unpruned.
// Everything that depends on it must be disqualified.
for _, p := range t.requiring[m] {
t.disqualify(p, pruned, dqState{dep: m})
// Note that since the pruned graph is a subset of the unpruned graph,
// disqualifying p in the pruned graph also disqualifies it in the
// unpruned graph.
}
// Everything in t.requiring[m] is now fully disqualified.
// We won't need to use it again.
delete(t.requiring, m)
return
}
// Either m is not a root, or it is a pruned root but only being disqualified
// when reached from the unpruned parts of the module graph.
// Either way, the reason for this disqualification is only visible to the
// unpruned parts of the module graph.
for _, p := range t.requiring[m] {
t.disqualify(p, unpruned, dqState{dep: m})
}
if !isRoot {
// Since m is not a root, its dependencies can't be included in the pruned
// part of the module graph, and will never be disqualified from a pruned
// reason. We've already disqualified everything that matters.
delete(t.requiring, m)
}
}
// check reports whether m is disqualified in the given pruning context.
func (t *dqTracker) check(m module.Version, pruning modPruning) dqState {
return t.dqReason[m].from(pruning)
}
// path returns the path from m to the reason it is disqualified, which may be
// either a module that violates constraints or an error in loading
// requirements.
//
// If m is not disqualified, path returns (nil, nil).
func (t *dqTracker) path(m module.Version, pruning modPruning) (path []module.Version, err error) {
for {
if rootPruning, isRoot := t.extendedRootPruning[m]; isRoot && rootPruning == unpruned {
// Since m is a root, any other module that requires it would cause
// its full unpruned dependencies to be included in the module graph.
// Those dependencies must also be considered as part of the path to the conflict.
pruning = unpruned
}
dq := t.dqReason[m].from(pruning)
if !dq.isDisqualified() {
return path, nil
}
path = append(path, m)
if dq.err != nil || dq.dep == m {
return path, dq.err // m itself is the conflict.
}
m = dq.dep
}
}