mirror of
https://git.uploadfilter24.eu/lerentis/terraform-provider-gitea.git
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84c9110a24
Bumps [github.com/hashicorp/terraform-plugin-sdk/v2](https://github.com/hashicorp/terraform-plugin-sdk) from 2.24.1 to 2.26.0. - [Release notes](https://github.com/hashicorp/terraform-plugin-sdk/releases) - [Changelog](https://github.com/hashicorp/terraform-plugin-sdk/blob/main/CHANGELOG.md) - [Commits](https://github.com/hashicorp/terraform-plugin-sdk/compare/v2.24.1...v2.26.0) --- updated-dependencies: - dependency-name: github.com/hashicorp/terraform-plugin-sdk/v2 dependency-type: direct:production update-type: version-update:semver-minor ... Signed-off-by: dependabot[bot] <support@github.com>
450 lines
15 KiB
Go
450 lines
15 KiB
Go
package function
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import (
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"fmt"
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"github.com/zclconf/go-cty/cty"
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)
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// Function represents a function. This is the main type in this package.
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type Function struct {
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spec *Spec
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}
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// Spec is the specification of a function, used to instantiate
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// a new Function.
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type Spec struct {
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// Description is an optional description for the function specification.
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Description string
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// Params is a description of the positional parameters for the function.
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// The standard checking logic rejects any calls that do not provide
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// arguments conforming to this definition, freeing the function
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// implementer from dealing with such inconsistencies.
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Params []Parameter
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// VarParam is an optional specification of additional "varargs" the
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// function accepts. If this is non-nil then callers may provide an
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// arbitrary number of additional arguments (after those matching with
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// the fixed parameters in Params) that conform to the given specification,
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// which will appear as additional values in the slices of values
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// provided to the type and implementation functions.
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VarParam *Parameter
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// Type is the TypeFunc that decides the return type of the function
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// given its arguments, which may be Unknown. See the documentation
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// of TypeFunc for more information.
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//
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// Use StaticReturnType if the function's return type does not vary
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// depending on its arguments.
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Type TypeFunc
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// RefineResult is an optional callback for describing additional
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// refinements for the result value beyond what can be described using
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// a type constraint.
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//
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// A refinement callback should always return the same builder it was
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// given, typically after modifying it using the methods of
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// [cty.RefinementBuilder].
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//
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// Any refinements described by this callback must hold for the entire
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// range of results from the function. For refinements that only apply
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// to certain results, use direct refinement within [Impl] instead.
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RefineResult func(*cty.RefinementBuilder) *cty.RefinementBuilder
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// Impl is the ImplFunc that implements the function's behavior.
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//
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// Functions are expected to behave as pure functions, and not create
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// any visible side-effects.
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//
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// If a TypeFunc is also provided, the value returned from Impl *must*
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// conform to the type it returns, or a call to the function will panic.
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Impl ImplFunc
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}
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// New creates a new function with the given specification.
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//
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// After passing a Spec to this function, the caller must no longer read from
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// or mutate it.
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func New(spec *Spec) Function {
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f := Function{
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spec: spec,
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}
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return f
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}
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// TypeFunc is a callback type for determining the return type of a function
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// given its arguments.
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//
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// Any of the values passed to this function may be unknown, even if the
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// parameters are not configured to accept unknowns.
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//
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// If any of the given values are *not* unknown, the TypeFunc may use the
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// values for pre-validation and for choosing the return type. For example,
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// a hypothetical JSON-unmarshalling function could return
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// cty.DynamicPseudoType if the given JSON string is unknown, but return
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// a concrete type based on the JSON structure if the JSON string is already
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// known.
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type TypeFunc func(args []cty.Value) (cty.Type, error)
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// ImplFunc is a callback type for the main implementation of a function.
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//
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// "args" are the values for the arguments, and this slice will always be at
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// least as long as the argument definition slice for the function.
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//
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// "retType" is the type returned from the Type callback, included as a
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// convenience to avoid the need to re-compute the return type for generic
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// functions whose return type is a function of the arguments.
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type ImplFunc func(args []cty.Value, retType cty.Type) (cty.Value, error)
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// StaticReturnType returns a TypeFunc that always returns the given type.
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//
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// This is provided as a convenience for defining a function whose return
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// type does not depend on the argument types.
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func StaticReturnType(ty cty.Type) TypeFunc {
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return func([]cty.Value) (cty.Type, error) {
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return ty, nil
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}
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}
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// ReturnType returns the return type of a function given a set of candidate
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// argument types, or returns an error if the given types are unacceptable.
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//
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// If the caller already knows values for at least some of the arguments
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// it can be better to call ReturnTypeForValues, since certain functions may
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// determine their return types from their values and return DynamicVal if
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// the values are unknown.
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func (f Function) ReturnType(argTypes []cty.Type) (cty.Type, error) {
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vals := make([]cty.Value, len(argTypes))
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for i, ty := range argTypes {
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vals[i] = cty.UnknownVal(ty)
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}
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return f.ReturnTypeForValues(vals)
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}
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func (f Function) returnTypeForValues(args []cty.Value) (ty cty.Type, dynTypedArgs bool, err error) {
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var posArgs []cty.Value
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var varArgs []cty.Value
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if f.spec.VarParam == nil {
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if len(args) != len(f.spec.Params) {
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return cty.Type{}, false, fmt.Errorf(
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"wrong number of arguments (%d required; %d given)",
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len(f.spec.Params), len(args),
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)
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}
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posArgs = args
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varArgs = nil
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} else {
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if len(args) < len(f.spec.Params) {
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return cty.Type{}, false, fmt.Errorf(
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"wrong number of arguments (at least %d required; %d given)",
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len(f.spec.Params), len(args),
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)
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}
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posArgs = args[0:len(f.spec.Params)]
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varArgs = args[len(f.spec.Params):]
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}
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for i, spec := range f.spec.Params {
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val := posArgs[i]
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if val.ContainsMarked() && !spec.AllowMarked {
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// During type checking we just unmark values and discard their
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// marks, under the assumption that during actual execution of
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// the function we'll do similarly and then re-apply the marks
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// afterwards. Note that this does mean that a function that
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// inspects values (rather than just types) in its Type
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// implementation can potentially fail to take into account marks,
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// unless it specifically opts in to seeing them.
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unmarked, _ := val.UnmarkDeep()
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newArgs := make([]cty.Value, len(args))
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copy(newArgs, args)
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newArgs[i] = unmarked
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args = newArgs
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}
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if val.IsNull() && !spec.AllowNull {
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return cty.Type{}, false, NewArgErrorf(i, "argument must not be null")
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}
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// AllowUnknown is ignored for type-checking, since we expect to be
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// able to type check with unknown values. We *do* still need to deal
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// with DynamicPseudoType here though, since the Type function might
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// not be ready to deal with that.
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if val.Type() == cty.DynamicPseudoType {
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if !spec.AllowDynamicType {
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return cty.DynamicPseudoType, true, nil
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}
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} else if errs := val.Type().TestConformance(spec.Type); errs != nil {
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// For now we'll just return the first error in the set, since
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// we don't have a good way to return the whole list here.
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// Would be good to do something better at some point...
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return cty.Type{}, false, NewArgError(i, errs[0])
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}
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}
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if varArgs != nil {
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spec := f.spec.VarParam
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for i, val := range varArgs {
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realI := i + len(posArgs)
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if val.ContainsMarked() && !spec.AllowMarked {
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// See the similar block in the loop above for what's going on here.
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unmarked, _ := val.UnmarkDeep()
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newArgs := make([]cty.Value, len(args))
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copy(newArgs, args)
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newArgs[realI] = unmarked
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args = newArgs
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}
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if val.IsNull() && !spec.AllowNull {
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return cty.Type{}, false, NewArgErrorf(realI, "argument must not be null")
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}
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if val.Type() == cty.DynamicPseudoType {
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if !spec.AllowDynamicType {
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return cty.DynamicPseudoType, true, nil
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}
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} else if errs := val.Type().TestConformance(spec.Type); errs != nil {
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// For now we'll just return the first error in the set, since
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// we don't have a good way to return the whole list here.
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// Would be good to do something better at some point...
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return cty.Type{}, false, NewArgError(i, errs[0])
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}
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}
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}
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// Intercept any panics from the function and return them as normal errors,
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// so a calling language runtime doesn't need to deal with panics.
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defer func() {
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if r := recover(); r != nil {
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ty = cty.NilType
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err = errorForPanic(r)
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}
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}()
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ty, err = f.spec.Type(args)
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return ty, false, err
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}
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// ReturnTypeForValues is similar to ReturnType but can be used if the caller
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// already knows the values of some or all of the arguments, in which case
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// the function may be able to determine a more definite result if its
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// return type depends on the argument *values*.
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//
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// For any arguments whose values are not known, pass an Unknown value of
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// the appropriate type.
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func (f Function) ReturnTypeForValues(args []cty.Value) (ty cty.Type, err error) {
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ty, _, err = f.returnTypeForValues(args)
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return ty, err
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}
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// Call actually calls the function with the given arguments, which must
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// conform to the function's parameter specification or an error will be
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// returned.
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func (f Function) Call(args []cty.Value) (val cty.Value, err error) {
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expectedType, dynTypeArgs, err := f.returnTypeForValues(args)
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if err != nil {
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return cty.NilVal, err
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}
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if dynTypeArgs {
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// returnTypeForValues sets this if any argument was inexactly typed
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// and the corresponding parameter did not indicate it could deal with
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// that. In that case we also avoid calling the implementation function
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// because it will also typically not be ready to deal with that case.
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return cty.UnknownVal(expectedType), nil
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}
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if refineResult := f.spec.RefineResult; refineResult != nil {
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// If this function has a refinement callback then we'll refine
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// our result value in the same way regardless of how we return.
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// It's the function author's responsibility to ensure that the
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// refinements they specify are valid for the full range of possible
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// return values from the function. If not, this will panic when
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// detecting an inconsistency.
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defer func() {
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if val != cty.NilVal {
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if val.IsKnown() || val.Type() != cty.DynamicPseudoType {
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val = val.RefineWith(refineResult)
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}
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}
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}()
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}
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// Type checking already dealt with most situations relating to our
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// parameter specification, but we still need to deal with unknown
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// values and marked values.
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posArgs := args[:len(f.spec.Params)]
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varArgs := args[len(f.spec.Params):]
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var resultMarks []cty.ValueMarks
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for i, spec := range f.spec.Params {
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val := posArgs[i]
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if !val.IsKnown() && !spec.AllowUnknown {
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return cty.UnknownVal(expectedType), nil
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}
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if !spec.AllowMarked {
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unwrappedVal, marks := val.UnmarkDeep()
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if len(marks) > 0 {
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// In order to avoid additional overhead on applications that
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// are not using marked values, we copy the given args only
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// if we encounter a marked value we need to unmark. However,
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// as a consequence we end up doing redundant copying if multiple
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// marked values need to be unwrapped. That seems okay because
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// argument lists are generally small.
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newArgs := make([]cty.Value, len(args))
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copy(newArgs, args)
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newArgs[i] = unwrappedVal
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resultMarks = append(resultMarks, marks)
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args = newArgs
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}
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}
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}
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if f.spec.VarParam != nil {
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spec := f.spec.VarParam
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for i, val := range varArgs {
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if !val.IsKnown() && !spec.AllowUnknown {
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return cty.UnknownVal(expectedType), nil
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}
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if !spec.AllowMarked {
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unwrappedVal, marks := val.UnmarkDeep()
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if len(marks) > 0 {
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newArgs := make([]cty.Value, len(args))
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copy(newArgs, args)
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newArgs[len(posArgs)+i] = unwrappedVal
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resultMarks = append(resultMarks, marks)
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args = newArgs
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}
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}
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}
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}
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var retVal cty.Value
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{
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// Intercept any panics from the function and return them as normal errors,
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// so a calling language runtime doesn't need to deal with panics.
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defer func() {
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if r := recover(); r != nil {
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val = cty.NilVal
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err = errorForPanic(r)
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}
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}()
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retVal, err = f.spec.Impl(args, expectedType)
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if err != nil {
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return cty.NilVal, err
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}
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if len(resultMarks) > 0 {
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retVal = retVal.WithMarks(resultMarks...)
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}
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}
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// Returned value must conform to what the Type function expected, to
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// protect callers from having to deal with inconsistencies.
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if errs := retVal.Type().TestConformance(expectedType); errs != nil {
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panic(fmt.Errorf(
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"returned value %#v does not conform to expected return type %#v: %s",
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retVal, expectedType, errs[0],
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))
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}
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return retVal, nil
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}
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// ProxyFunc the type returned by the method Function.Proxy.
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type ProxyFunc func(args ...cty.Value) (cty.Value, error)
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// Proxy returns a function that can be called with cty.Value arguments
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// to run the function. This is provided as a convenience for when using
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// a function directly within Go code.
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func (f Function) Proxy() ProxyFunc {
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return func(args ...cty.Value) (cty.Value, error) {
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return f.Call(args)
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}
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}
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// Params returns information about the function's fixed positional parameters.
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// This does not include information about any variadic arguments accepted;
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// for that, call VarParam.
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func (f Function) Params() []Parameter {
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new := make([]Parameter, len(f.spec.Params))
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copy(new, f.spec.Params)
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return new
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}
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// VarParam returns information about the variadic arguments the function
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// expects, or nil if the function is not variadic.
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func (f Function) VarParam() *Parameter {
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if f.spec.VarParam == nil {
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return nil
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}
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ret := *f.spec.VarParam
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return &ret
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}
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// Description returns a human-readable description of the function.
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func (f Function) Description() string {
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return f.spec.Description
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}
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// WithNewDescriptions returns a new function that has the same signature
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// and implementation as the receiver but has the function description and
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// the parameter descriptions replaced with those given in the arguments.
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//
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// All descriptions may be given as an empty string to specify that there
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// should be no description at all.
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//
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// The paramDescs argument must match the number of parameters
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// the reciever expects, or this function will panic. If the function has a
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// VarParam then that counts as one parameter for the sake of this rule. The
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// given descriptions will be assigned in order starting with the positional
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// arguments in their declared order, followed by the variadic parameter if
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// any.
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//
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// As a special case, WithNewDescriptions will accept a paramDescs which
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// does not cover the reciever's variadic parameter (if any), so that it's
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// possible to add a variadic parameter to a function which didn't previously
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// have one without that being a breaking change for an existing caller using
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// WithNewDescriptions against that function. In this case the base description
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// of the variadic parameter will be preserved.
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func (f Function) WithNewDescriptions(funcDesc string, paramDescs []string) Function {
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retSpec := *f.spec // shallow copy of the reciever
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retSpec.Description = funcDesc
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retSpec.Params = make([]Parameter, len(f.spec.Params))
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copy(retSpec.Params, f.spec.Params) // shallow copy of positional parameters
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if f.spec.VarParam != nil {
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retVarParam := *f.spec.VarParam // shallow copy of variadic parameter
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retSpec.VarParam = &retVarParam
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}
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if retSpec.VarParam != nil {
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if with, without := len(retSpec.Params)+1, len(retSpec.Params); len(paramDescs) != with && len(paramDescs) != without {
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panic(fmt.Sprintf("paramDescs must have length of either %d or %d", with, without))
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}
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} else {
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if want := len(retSpec.Params); len(paramDescs) != want {
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panic(fmt.Sprintf("paramDescs must have length %d", want))
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}
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}
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posParamDescs := paramDescs[:len(retSpec.Params)]
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varParamDescs := paramDescs[len(retSpec.Params):] // guaranteed to be zero or one elements because of the rules above
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for i, desc := range posParamDescs {
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retSpec.Params[i].Description = desc
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}
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for _, desc := range varParamDescs {
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retSpec.VarParam.Description = desc
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}
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return New(&retSpec)
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}
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