Files
larksuite-cli/cmd/root.go

754 lines
28 KiB
Go

// Copyright (c) 2026 Lark Technologies Pte. Ltd.
// SPDX-License-Identifier: MIT
package cmd
import (
"context"
"errors"
"fmt"
"os"
"sort"
"strings"
"github.com/larksuite/cli/errs"
"github.com/larksuite/cli/extension/platform"
internalauth "github.com/larksuite/cli/internal/auth"
"github.com/larksuite/cli/internal/build"
"github.com/larksuite/cli/internal/cmdpolicy"
"github.com/larksuite/cli/internal/cmdutil"
"github.com/larksuite/cli/internal/core"
"github.com/larksuite/cli/internal/deprecation"
"github.com/larksuite/cli/internal/errclass"
"github.com/larksuite/cli/internal/errcompat"
"github.com/larksuite/cli/internal/hook"
"github.com/larksuite/cli/internal/output"
"github.com/larksuite/cli/internal/registry"
"github.com/larksuite/cli/internal/skillscheck"
"github.com/larksuite/cli/internal/suggest"
"github.com/larksuite/cli/internal/update"
"github.com/spf13/cobra"
"github.com/spf13/pflag"
)
const rootLong = `lark-cli — Lark/Feishu CLI tool.
USAGE:
lark-cli <command> [subcommand] [method] [options]
lark-cli api <method> <path> [--params <json>] [--data <json>]
lark-cli schema <service.resource.method>
EXAMPLES:
# View upcoming events
lark-cli calendar +agenda
# List calendar events
lark-cli calendar events instance_view --params '{"calendar_id":"primary","start_time":"1700000000","end_time":"1700086400"}'
# Search users
lark-cli contact +search-user --query "John"
# Generic API call
lark-cli api GET /open-apis/calendar/v4/calendars
AI AGENT SKILLS:
lark-cli pairs with AI agent skills (Claude Code, etc.) that
teach the agent Lark API patterns, best practices, and workflows.
Install all skills:
npx skills add larksuite/cli -g -y
Or pick specific domains:
npx skills add larksuite/cli -s lark-calendar -y
npx skills add larksuite/cli -s lark-im -y
Learn more: https://github.com/larksuite/cli#agent-skills
COMMUNITY:
GitHub: https://github.com/larksuite/cli
Issues: https://github.com/larksuite/cli/issues
Docs: https://open.feishu.cn/document/
More help: lark-cli <command> --help`
// Execute runs the root command and returns the process exit code.
// rawInvocationArgs holds os.Args[1:] captured at Execute() entry. cobra's
// UnknownFlags whitelist (installUnknownSubcommandGuard) swallows unknown flags
// before they reach a group's RunE, so unknownSubcommandRunE re-derives them
// from here. It stays nil in unit tests that invoke a RunE directly with
// explicit args — correct, since those don't exercise the whitelist path.
var rawInvocationArgs []string
func Execute() int {
rawInvocationArgs = os.Args[1:]
inv, err := BootstrapInvocationContext(os.Args[1:])
if err != nil {
fmt.Fprintln(os.Stderr, "Error:", err)
return 1
}
configureFlagCompletions(os.Args)
ctx := context.Background()
f, rootCmd, reg := buildInternal(
ctx, inv,
WithIO(os.Stdin, os.Stdout, os.Stderr),
HideProfile(isSingleAppMode()),
)
// --- Notices (non-blocking) ---
if !isCompletionCommand(os.Args) {
setupNotices()
}
runErr := rootCmd.Execute()
// Fire Shutdown lifecycle hooks regardless of run outcome.
// emitShutdown imposes a 2s total deadline and never propagates handler
// errors (Emit's documented Shutdown contract), so it cannot block exit
// or alter the user-visible exit code.
if reg != nil && !isCompletionCommand(os.Args) {
_ = hook.Emit(ctx, reg, platform.Shutdown, runErr)
}
if runErr != nil {
return handleRootError(f, runErr)
}
return 0
}
// setupNotices wires both the binary update notice and the skills
// staleness notice into output.PendingNotice as a composed function.
// Each provider populates an independent key under _notice; either
// or both may be present in any given envelope.
func setupNotices() {
// Binary update — synchronous cache check + async refresh
if info := update.CheckCached(build.Version); info != nil {
update.SetPending(info)
}
ver := build.Version
go func() {
defer func() {
if r := recover(); r != nil {
fmt.Fprintf(os.Stderr, "update check panic: %v\n", r)
}
}()
update.RefreshCache(ver)
if update.GetPending() == nil {
if info := update.CheckCached(ver); info != nil {
update.SetPending(info)
}
}
}()
// Skills check — synchronous, local-only (no network, no goroutine).
skillscheck.Init(build.Version)
// Composed notice provider — emits keys only when each pending is set.
output.PendingNotice = composePendingNotice
}
// composePendingNotice merges all process-level pending notices (available
// update, skills/binary drift, deprecated-command alias) into the map surfaced
// as the JSON "_notice" envelope field. Returns nil when nothing is pending.
// Extracted from Execute so the composition is unit-testable.
func composePendingNotice() map[string]interface{} {
notice := map[string]interface{}{}
if info := update.GetPending(); info != nil {
notice["update"] = map[string]interface{}{
"current": info.Current,
"latest": info.Latest,
"message": info.Message(),
"command": "lark-cli update",
}
}
if stale := skillscheck.GetPending(); stale != nil {
notice["skills"] = map[string]interface{}{
"current": stale.Current,
"target": stale.Target,
"message": stale.Message(),
"command": "lark-cli update",
}
}
if dep := deprecation.GetPending(); dep != nil {
entry := map[string]interface{}{
"command": dep.Command,
"message": dep.Message(),
"action": "lark-cli update",
}
if dep.Replacement != "" {
entry["replacement"] = dep.Replacement
}
if dep.Skill != "" {
entry["skill"] = dep.Skill
}
notice["deprecated_command"] = entry
}
if len(notice) == 0 {
return nil
}
return notice
}
// isCompletionCommand returns true if args indicate a shell completion request.
// Update notifications and Shutdown lifecycle emits must be suppressed for
// these to avoid corrupting machine-parseable completion output and to avoid
// firing plugin Shutdown handlers on every Tab keystroke.
//
// Cobra dispatches BOTH "__complete" and its alias "__completeNoDesc" through
// the same hidden subcommand (see cobra/completions.go ShellCompRequestCmd /
// ShellCompNoDescRequestCmd). Check both, otherwise bash/zsh completion
// (which often uses NoDesc) silently bypasses the gate.
func isCompletionCommand(args []string) bool {
for _, arg := range args {
if arg == "completion" || arg == "__complete" || arg == "__completeNoDesc" {
return true
}
}
return false
}
// configureFlagCompletions enables cmdutil.RegisterFlagCompletion only when
// the invocation will actually serve a __complete request.
func configureFlagCompletions(args []string) {
cmdutil.SetFlagCompletionsEnabled(isCompletionCommand(args))
}
// handleRootError dispatches a command error to the appropriate handler
// and returns the process exit code.
//
// Dispatch order:
// 1. Legacy shapes (*core.ConfigError, *internalauth.NeedAuthorizationError)
// are promoted via errcompat to their typed errs/ counterparts, with the
// original preserved in the Cause chain.
// 2. Typed errors from errs/ (e.g. *errs.PermissionError, *errs.APIError,
// *errs.SecurityPolicyError, *errs.AuthenticationError): render via the
// typed envelope writer, which lifts extension fields (missing_scopes,
// console_url, challenge_url, ...) to the top level. Routed by
// errs.CategoryOf via ExitCodeOf.
// 3. Legacy *output.ExitError: asExitError adapts it to the legacy
// envelope, written via WriteErrorEnvelope.
// 4. Cobra errors (required flags, unknown commands, etc.): plain text.
func handleRootError(f *cmdutil.Factory, err error) int {
errOut := f.IOStreams.ErrOut
// Promote legacy error shapes into typed errs/ before envelope marshal.
// NeedAuthorizationError check is first because it is the more specific
// shape; *core.ConfigError check follows. errors.As preserves the original
// in the Cause chain, so external errors.As(&core.ConfigError{}) consumers
// (cmd/auth/list.go, cmd/doctor/doctor.go, ...) still match.
//
// Outer-typed short-circuit: if err is already a typed *errs.* error,
// skip PromoteXxxError so the producer's Subtype / Hint / extension
// fields are not overwritten by a coarser promoted shape derived from a
// legacy error buried in its Cause chain. Promotion is only for legacy
// untyped entry points.
if !isOuterTypedError(err) {
var needAuthErr *internalauth.NeedAuthorizationError
if errors.As(err, &needAuthErr) {
err = errcompat.PromoteAuthError(needAuthErr)
} else {
var cfgErr *core.ConfigError
if errors.As(err, &cfgErr) {
err = errcompat.PromoteConfigError(cfgErr)
}
}
}
// When the typed error is a need_user_authorization signal, fold in the
// current command's declared scopes as a Hint so the user/AI sees the
// concrete scope(s) to re-auth with. The hint is computed on the fly from
// local shortcut/service metadata — it never depends on server state.
applyNeedAuthorizationHint(f, err)
// Staged dispatch: capture the typed exit code BEFORE attempting the
// envelope write. WriteTypedErrorEnvelope is best-effort on the wire
// (partial-write still returns true) so the exit code we read here is
// preserved even if stderr is torn — torn stderr must not downgrade
// typed exits 3/4/6/10 to the legacy "Error:" path with exit 1.
// WriteTypedErrorEnvelope still returns false when err carries no
// Problem; in that case we fall through to the legacy bridge below.
typedExit := output.ExitCodeOf(err)
if output.WriteTypedErrorEnvelope(errOut, err, string(f.ResolvedIdentity)) {
return typedExit
}
// Partial-failure (batch / multi-status): the ok:false result envelope is
// already on stdout; set the exit code and write nothing to stderr.
var pfErr *output.PartialFailureError
if errors.As(err, &pfErr) {
return pfErr.Code
}
if exitErr := asExitError(err); exitErr != nil {
if !exitErr.Raw {
// Raw errors (e.g. from `api` command via output.MarkRaw)
// preserve the original API error detail; skip enrichment
// which would clear it.
enrichMissingScopeError(f, exitErr)
enrichPermissionError(f, exitErr)
}
output.WriteErrorEnvelope(errOut, exitErr, string(f.ResolvedIdentity))
return exitErr.Code
}
// A backward-compat alias records its deprecation notice in PreRunE, which
// runs before cobra's required-flag validation — but a missing required flag
// fails before RunE and lands here, where the bare "Error:" line would drop
// the notice. When a deprecation is pending, route through the structured
// envelope so the migration hint still reaches the caller; all other errors
// keep the existing plain output.
if deprecation.GetPending() != nil {
output.WriteErrorEnvelope(errOut, &output.ExitError{
Code: 1,
Detail: &output.ErrDetail{Type: "validation", Message: err.Error()},
}, string(f.ResolvedIdentity))
return 1
}
fmt.Fprintln(errOut, "Error:", err)
return 1
}
// isOuterTypedError returns true if err is a typed *errs.* error AT THE
// TOP OF THE CHAIN (not buried inside Unwrap). Used by handleRootError
// to gate PromoteXxxError so a producer's outer typed envelope is never
// overwritten by a coarser shape derived from its legacy Cause.
func isOuterTypedError(err error) bool {
_, ok := err.(errs.TypedError)
return ok
}
// asExitError converts known structured error types to *output.ExitError.
// Returns nil for unrecognized errors (e.g. cobra flag errors).
//
// Deprecated: legacy *output.ExitError bridge.
func asExitError(err error) *output.ExitError {
var cfgErr *core.ConfigError
if errors.As(err, &cfgErr) {
return output.ErrWithHint(cfgErr.Code, cfgErr.Type, cfgErr.Message, cfgErr.Hint)
}
var exitErr *output.ExitError
if errors.As(err, &exitErr) {
return exitErr
}
return nil
}
// installUnknownSubcommandGuard replaces cobra's silent help fallback on
// group commands (no Run/RunE) with an unknown_subcommand error.
//
// IMPORTANT: every command modified here is also tagged with
// cmdpolicy.AnnotationPureGroup so the user-layer policy engine
// continues to treat the command as a pure parent group. Without the
// tag, the RunE injection here would flip Runnable()=true and a user
// rule like `max_risk: read` would deny every `<group> --help` call
// with reason_code=risk_not_annotated.
func installUnknownSubcommandGuard(cmd *cobra.Command) {
if cmd.HasSubCommands() && cmd.Run == nil && cmd.RunE == nil {
cmd.RunE = unknownSubcommandRunE
// Route an unknown subcommand to unknownSubcommandRunE even when flags
// are also present (e.g. `sheets +cells-find --url ...`). A pure group
// consumes no flags itself, so unknown flags belong to the (missing)
// subcommand; whitelisting them here prevents cobra from erroring on the
// flag first and printing usage instead of our structured suggestion.
cmd.FParseErrWhitelist.UnknownFlags = true
if cmd.Annotations == nil {
cmd.Annotations = map[string]string{}
}
cmd.Annotations[cmdpolicy.AnnotationPureGroup] = "true"
}
for _, c := range cmd.Commands() {
installUnknownSubcommandGuard(c)
}
}
// Deprecated: unknownSubcommandRunE produces a legacy *output.ExitError that
// predates the typed error contract introduced by errs/. New code MUST NOT
// add producers of this shape — unknown-subcommand signals should move to
// a typed *errs.ValidationError (or a dedicated typed error) carrying the
// agent-protocol metadata as typed extension fields. This helper is retained
// only while existing dispatch sites are migrated; it will be removed once
// they have moved to the typed surface.
func unknownSubcommandRunE(cmd *cobra.Command, args []string) error {
if len(args) == 0 {
// A bare group (e.g. `sheets`), or one carrying only group-valid flags
// like the global --profile, legitimately prints help. But a flag that
// belongs to a (missing) subcommand is a user error: the guard's
// FParseErrWhitelist swallows such flags and leaves args empty, so without
// the checks below they would silently fall through to help + exit 0 —
// letting an agent mistake a malformed call (`im --format json`,
// `sheets --badflag`) for success. Recover the swallowed tokens from the
// raw invocation and fail structured instead.
flags := flagTokensInArgs(rawInvocationArgs)
if len(flags) == 0 {
return cmd.Help()
}
if unknown := unknownFlagTokens(cmd, rawInvocationArgs); len(unknown) > 0 {
return &output.ExitError{
Code: output.ExitValidation,
Detail: &output.ErrDetail{
Type: "unknown_flag",
Message: fmt.Sprintf("unknown flag %s before a subcommand for %q", strings.Join(unknown, ", "), cmd.CommandPath()),
Hint: fmt.Sprintf("flags belong to a subcommand; run `%s --help` to list subcommands and their flags", cmd.CommandPath()),
Detail: map[string]any{
// Keep the same detail keys as flagDidYouMean's unknown_flag
// so a consumer keyed on Type can read a stable shape. The
// subcommand isn't resolved here, so suggestions/valid_flags
// have no meaningful universe to draw from — emit empty
// rather than the group's own (misleading) flags. unknown is
// the back-compat singular field; unknown_flags carries the
// full list when more than one flag was supplied.
"unknown": strings.Join(unknown, ", "),
"unknown_flags": unknown,
"command_path": cmd.CommandPath(),
"suggestions": []string{},
"valid_flags": []string{},
},
},
}
}
// The remaining flags are all defined somewhere in the tree. Those valid
// on the group itself or inherited (e.g. the global --profile) do not
// require a subcommand, so a bare group carrying only those still prints
// help. Anything left belongs to a subcommand that was omitted
// (e.g. `im --format json`): distinct from unknown_flag — the flags are
// real, the subcommand is what's missing.
misplaced := subcommandOnlyFlagTokens(cmd, rawInvocationArgs)
if len(misplaced) == 0 {
return cmd.Help()
}
return &output.ExitError{
Code: output.ExitValidation,
Detail: &output.ErrDetail{
Type: "missing_subcommand",
Message: fmt.Sprintf("missing subcommand for %q; flag %s belongs to a subcommand, not the group", cmd.CommandPath(), strings.Join(misplaced, ", ")),
Hint: fmt.Sprintf("run `%s --help` to list subcommands and their flags", cmd.CommandPath()),
Detail: map[string]any{
"command_path": cmd.CommandPath(),
"flags": misplaced,
"suggestions": []string{},
},
},
}
}
unknown := args[0]
available, deprecated := availableSubcommandNames(cmd)
// Rank suggestions across both current and deprecated names so a mistyped
// legacy command (e.g. +raed → +read) still resolves; the alias stays
// runnable and self-flags via the _notice on execution.
suggestions := suggest.Closest(unknown, append(append([]string{}, available...), deprecated...), 6)
msg := fmt.Sprintf("unknown subcommand %q for %q", unknown, cmd.CommandPath())
hint := fmt.Sprintf("run `%s --help` to see available subcommands", cmd.CommandPath())
if len(suggestions) > 0 {
hint = fmt.Sprintf("did you mean one of: %s? (run `%s --help` for the full list)",
strings.Join(suggestions, ", "), cmd.CommandPath())
}
detail := map[string]any{
"unknown": unknown,
"command_path": cmd.CommandPath(),
"suggestions": suggestions,
"available": available,
}
// Only services with backward-compat aliases (currently sheets) carry a
// deprecated bucket; omit the key elsewhere so every other service's
// envelope is unchanged.
if len(deprecated) > 0 {
detail["deprecated"] = deprecated
}
return &output.ExitError{
Code: output.ExitValidation,
Detail: &output.ErrDetail{
Type: "unknown_subcommand",
Message: msg,
Hint: hint,
Detail: detail,
},
}
}
// flagTokensInArgs returns the flag-like tokens (-x, --foo, --foo=bar) in
// rawArgs, stopping at the "--" positional terminator. Whether a flag is
// defined is not considered (see unknownFlagTokens for that). A pure group
// with any flag token but no subcommand is a user error — a pure group
// consumes no flags of its own, so the flag must belong to a subcommand — so
// the caller fails structured instead of falling through to help.
func flagTokensInArgs(rawArgs []string) []string {
var toks []string
for _, a := range rawArgs {
if a == "--" {
break // everything after -- is positional
}
if len(a) < 2 || a[0] != '-' {
continue
}
toks = append(toks, a)
}
return toks
}
// unknownFlagTokens returns the flag tokens in rawArgs that cmd does not define
// (on itself, inherited, or any direct subcommand). installUnknownSubcommandGuard
// whitelists unknown flags on pure groups so a mistyped subcommand still reaches
// the suggestion path; the side effect is that flags before a subcommand are
// swallowed. This recovers the genuinely-unknown ones so the caller can name
// them in a "did you mean" envelope.
func unknownFlagTokens(cmd *cobra.Command, rawArgs []string) []string {
var unknown []string
for _, a := range flagTokensInArgs(rawArgs) {
name := strings.SplitN(strings.TrimLeft(a, "-"), "=", 2)[0]
if name != "" && !flagDefinedInTree(cmd, name) {
unknown = append(unknown, a)
}
}
return unknown
}
// flagKnownOnGroup reports whether name is a flag defined on cmd itself or
// inherited (a global persistent flag like --profile) — i.e. valid on the bare
// group and therefore not requiring a subcommand.
func flagKnownOnGroup(cmd *cobra.Command, name string) bool {
short := len(name) == 1
lookup := func(fs *pflag.FlagSet) bool {
if short {
return fs.ShorthandLookup(name) != nil
}
return fs.Lookup(name) != nil
}
return lookup(cmd.Flags()) || lookup(cmd.InheritedFlags())
}
// subcommandOnlyFlagTokens returns the flag tokens in rawArgs that are valid on
// a subcommand of cmd but not on cmd itself/inherited — flags supplied while
// omitting the subcommand they belong to (`im --format json`). Global flags
// valid on the bare group (e.g. --profile) are excluded so
// `lark-cli --profile p im` still prints help rather than erroring.
func subcommandOnlyFlagTokens(cmd *cobra.Command, rawArgs []string) []string {
var misplaced []string
for _, a := range flagTokensInArgs(rawArgs) {
name := strings.SplitN(strings.TrimLeft(a, "-"), "=", 2)[0]
if name == "" || flagKnownOnGroup(cmd, name) {
continue
}
if flagDefinedInTree(cmd, name) {
misplaced = append(misplaced, a)
}
}
return misplaced
}
// flagDefinedInTree reports whether name is defined on cmd, its inherited
// (persistent) flags, or any direct subcommand. The subcommand case covers a
// user who merely omitted the subcommand — e.g. `sheets --format json`, where
// --format is injected on every leaf shortcut, not on the group — so only a
// genuinely unknown flag like `sheets --badflag` is reported.
func flagDefinedInTree(cmd *cobra.Command, name string) bool {
short := len(name) == 1
known := func(c *cobra.Command, inherited bool) bool {
fs := c.Flags()
if inherited {
fs = c.InheritedFlags()
}
if short {
return fs.ShorthandLookup(name) != nil
}
return fs.Lookup(name) != nil
}
if known(cmd, false) || known(cmd, true) {
return true
}
for _, c := range cmd.Commands() {
if known(c, false) {
return true
}
}
return false
}
// availableSubcommandNames returns the invokable subcommand names of cmd, split
// into current commands and backward-compatibility aliases (those tagged into
// the deprecated cobra group via cmdutil.DeprecatedGroupID). Both slices are
// sorted; hidden commands plus help/completion are omitted.
func availableSubcommandNames(cmd *cobra.Command) (available, deprecated []string) {
for _, c := range cmd.Commands() {
if c.Hidden || !c.IsAvailableCommand() {
continue
}
name := c.Name()
if name == "help" || name == "completion" {
continue
}
if cmdutil.IsDeprecatedCommand(c) {
deprecated = append(deprecated, name)
} else {
available = append(available, name)
}
}
sort.Strings(available)
sort.Strings(deprecated)
return available, deprecated
}
// flagDidYouMean is the root FlagErrorFunc (inherited by all subcommands). It
// converts cobra's flag-parse errors into the structured ErrorEnvelope: an
// unknown flag gets a focused "did you mean" hint plus the full valid-flag list
// in detail (so agents recover even when the typo is semantic, e.g. --query vs
// --find, where edit distance alone finds nothing). Other flag errors stay
// structured but generic.
func flagDidYouMean(c *cobra.Command, ferr error) error {
name, isUnknown := unknownFlagName(ferr)
if !isUnknown {
return &output.ExitError{
Code: output.ExitValidation,
Detail: &output.ErrDetail{
Type: "flag_error",
Message: ferr.Error(),
Hint: fmt.Sprintf("run `%s --help` for valid flags", c.CommandPath()),
},
}
}
valid := visibleFlagNames(c)
suggestions := suggest.Closest(name, valid, 3)
hint := fmt.Sprintf("run `%s --help` to see valid flags", c.CommandPath())
if len(suggestions) > 0 {
for i := range suggestions {
suggestions[i] = "--" + suggestions[i]
}
hint = fmt.Sprintf("did you mean %s? (run `%s --help` for all flags)",
strings.Join(suggestions, ", "), c.CommandPath())
}
return &output.ExitError{
Code: output.ExitValidation,
Detail: &output.ErrDetail{
Type: "unknown_flag",
Message: fmt.Sprintf("unknown flag %q for %q", "--"+name, c.CommandPath()),
Hint: hint,
Detail: map[string]any{
"unknown": "--" + name,
"command_path": c.CommandPath(),
"suggestions": suggestions,
"valid_flags": valid,
},
},
}
}
// unknownFlagName extracts the offending long-flag name from cobra's flag-parse
// error text ("unknown flag: --query" → "query"). Returns ok=false for anything
// else (missing argument, invalid value, unknown shorthand) so the caller keeps
// those structured but generic — hallucinated flags are essentially always long.
//
// CONTRACT: this matches cobra's English wording "unknown flag: --" (go.mod
// pins github.com/spf13/cobra). If cobra rewords this or gains i18n the match
// silently fails and unknown flags degrade to a generic flag_error — re-verify
// this prefix when bumping cobra.
func unknownFlagName(err error) (string, bool) {
const p = "unknown flag: --"
msg := err.Error()
i := strings.Index(msg, p)
if i < 0 {
return "", false
}
rest := msg[i+len(p):]
if j := strings.IndexAny(rest, " \t"); j >= 0 {
rest = rest[:j]
}
return rest, true
}
// visibleFlagNames lists the non-hidden flag names of c (for suggestions and
// the valid_flags detail).
func visibleFlagNames(c *cobra.Command) []string {
var names []string
c.Flags().VisitAll(func(f *pflag.Flag) {
if !f.Hidden {
names = append(names, f.Name)
}
})
sort.Strings(names)
return names
}
// installTipsHelpFunc wraps the default help function to append a TIPS section
// when a command has tips set via cmdutil.SetTips. It also force-shows global
// flags that are normally hidden in single-app mode (currently --profile)
// when rendering the root command's own help, so users discovering the CLI
// still see them at `lark-cli --help`.
func installTipsHelpFunc(root *cobra.Command) {
defaultHelp := root.HelpFunc()
root.SetHelpFunc(func(cmd *cobra.Command, args []string) {
if cmd == root {
if f := root.PersistentFlags().Lookup("profile"); f != nil && f.Hidden {
f.Hidden = false
defer func() { f.Hidden = true }()
}
}
defaultHelp(cmd, args)
out := cmd.OutOrStdout()
if level, ok := cmdutil.GetRisk(cmd); ok {
fmt.Fprintln(out)
fmt.Fprintln(out, "Risk:", level)
}
tips := cmdutil.GetTips(cmd)
if len(tips) == 0 {
return
}
fmt.Fprintln(out)
fmt.Fprintln(out, "Tips:")
for _, tip := range tips {
fmt.Fprintf(out, " • %s\n", tip)
}
})
}
// enrichPermissionError rewrites the legacy *output.ExitError envelope so its
// Message + Hint match the per-subtype canonical text produced by the typed
// dispatcher path (errclass.CanonicalPermissionMessage / errclass.PermissionHint).
// This guarantees a caller observing the wire envelope cannot tell whether
// the error reached the dispatcher via the legacy *ExitError bridge or via
// the typed *errs.PermissionError fast path.
//
// Deprecated: legacy *output.ExitError enrichment; typed PermissionError
// values produced by errclass.BuildAPIError already carry MissingScopes +
// ConsoleURL directly.
func enrichPermissionError(f *cmdutil.Factory, exitErr *output.ExitError) {
if exitErr.Detail == nil {
return
}
// Only the legacy permission-class envelope types route here. "app_status"
// covers 99991662 (app_disabled) / 99991673 (app_unavailable); "permission"
// covers the four scope-class codes (99991672 / 99991676 / 99991679 / 230027).
if exitErr.Detail.Type != "permission" && exitErr.Detail.Type != "app_status" {
return
}
larkCode := exitErr.Detail.Code
meta, ok := errclass.LookupCodeMeta(larkCode)
if !ok || meta.Category != errs.CategoryAuthorization {
return
}
// Extract required scopes from API error detail (shared helper). May be
// empty for app-status codes — canonical message + hint still apply.
missing := registry.ExtractRequiredScopes(exitErr.Detail.Detail)
cfg, err := f.Config()
if err != nil {
return
}
// Reuse the same console URL builder as the typed path so both wire
// envelopes carry identical console_url values for the same input.
consoleURL := errclass.ConsoleURL(string(cfg.Brand), cfg.AppID, missing)
// Clear raw API detail — useful info is now in message/hint/console_url.
exitErr.Detail.Detail = nil
identity := string(f.ResolvedIdentity)
if identity == "" {
identity = "user"
}
exitErr.Detail.Message = errclass.CanonicalPermissionMessage(meta.Subtype, cfg.AppID, missing, exitErr.Detail.Message)
exitErr.Detail.Hint = errclass.PermissionHint(missing, identity, meta.Subtype, consoleURL)
exitErr.Detail.ConsoleURL = consoleURL
}