databricks-cli/libs/dyn/dynvar/ref.go

package dynvar

import (
	"regexp"

	"github.com/databricks/cli/libs/dyn"
)

var re = regexp.MustCompile(`\$\{([a-zA-Z]+([-_]?[a-zA-Z0-9]+)*(\.[a-zA-Z]+([-_]?[a-zA-Z0-9]+)*(\[[0-9]+\])*)*(\[[0-9]+\])*)\}`)

// ref represents a variable reference.
// It is a string [dyn.Value] contained in a larger [dyn.Value].
// Its path within the containing [dyn.Value] is also stored.
type ref struct {
	// Original value.
	value dyn.Value

	// String value in the original [dyn.Value].
	str string

	// Matches of the variable reference in the string.
	matches [][]string
}

// newRef returns a new ref if the given [dyn.Value] contains a string
// with one or more variable references. It returns false if the given
// [dyn.Value] does not contain variable references.
//
// Examples of a valid variable references:
//   - "${a.b}"
//   - "${a.b.c}"
//   - "${a} ${b} ${c}"
func newRef(v dyn.Value) (ref, bool) {
	s, ok := v.AsString()
	if !ok {
		return ref{}, false
	}

	// Check if the string contains any variable references.
	m := re.FindAllStringSubmatch(s, -1)
	if len(m) == 0 {
		return ref{}, false
	}

	return ref{
		value:   v,
		str:     s,
		matches: m,
	}, true
}

// isPure returns true if the variable reference contains a single
// variable reference and nothing more. We need this so we can
// interpolate values of non-string types (i.e. it can be substituted).
func (v ref) isPure() bool {
	// Need single match, equal to the incoming string.
	if len(v.matches) == 0 || len(v.matches[0]) == 0 {
		panic("invalid variable reference; expect at least one match")
	}
	return v.matches[0][0] == v.str
}

func (v ref) references() []string {
	var out []string
	for _, m := range v.matches {
		out = append(out, m[1])
	}
	return out
}

func IsPureVariableReference(s string) bool {
	return len(s) > 0 && re.FindString(s) == s
}
Add `dynvar` package for variable resolution with a `dyn.Value` tree (#1143) ## Changes This is the `dyn` counterpart to the `bundle/config/interpolation` package. It relies on the paths in `${foo.bar}` being valid `dyn.Path` instances. It leverages `dyn.Walk` to get a complete picture of all variable references and uses `dyn.Get` to retrieve values pointed to by variable references. Depends on #1142. ## Tests Unit test coverage. I tried to mirror the tests from `bundle/config/interpolation` and added new ones where applicable (for example to test type retention of referenced values). 2024-01-24 18:49:06 +00:00			`package dynvar`

			`import (`
			`"regexp"`

			`"github.com/databricks/cli/libs/dyn"`
			`)`

Make bundle JSON schema modular with `$defs` (#1700) ## Changes This PR makes sweeping changes to the way we generate and test the bundle JSON schema. The main benefits are: 1. More modular JSON schema. Every definition in the schema now is one level deep and points to references instead of inlining the entire schema for a field. This unblocks PyDABs from taking a dependency on the JSON schema. 2. Generate the JSON schema during CLI code generation. Directly stream it instead of computing it at runtime whenever a user calls `databricks bundle schema`. This is nice because we no longer need to embed a partial OpenAPI spec in the CLI. Down the line, we can add a `Schema()` method to every struct in the Databricks Go SDK and remove the dependency on the OpenAPI spec altogether. It'll become more important once we decouple Go SDK structs and methods from the underlying APIs. 3. Add enum values for Go SDK fields in the JSON schema. Better autocompletion and validation for these fields. As a follow-up, we can add enum values for non-Go SDK enums as well (created internal ticket to track). 4. Use "packageName.structName" as a key to read JSON schemas from the OpenAPI spec for Go SDK structs. Before, we would use an unrolled presentation of the JSON schema (stored in `bundle_descriptions.json`), which was complex to parse and include in the final JSON schema output. This also means loading values from the OpenAPI spec for `target` schema works automatically and no longer needs custom code. 5. Support recursive types (eg: `for_each_task`). With us now using $refs everywhere it's trivial to support. 6. Using complex variables would be invalid according to the schema generated before this PR. Now that bug is fixed. In the future adding more custom rules will be easier as well due to the single level nature of the JSON schema. Since this is a complete change of approach in how we generate the JSON schema, there are a few (very minor) regressions worth calling out. 1. We'll lose a few custom descriptions for non Go SDK structs that were a part of `bundle_descriptions.json`. Support for those can be added in the future as a followup. 2. Since now the final JSON schema is a static artefact, we lose some lead time for the signal that JSON schema integration tests are failing. It's okay though since we have a lot of coverage via the existing unit tests. ## Tests Unit tests. End to end tests are being added in this PR: https://github.com/databricks/cli/pull/1726 Previous unit tests were all deleted because they were bloated. Effort was made to make the new unit tests provide (almost) equivalent coverage. 2024-09-10 13:55:18 +00:00			var re = regexp.MustCompile(`\$\{([a-zA-Z]+([-_]?[a-zA-Z0-9]+)(\.[a-zA-Z]+([-_]?[a-zA-Z0-9]+)(\[[0-9]+\]))(\[[0-9]+\])*)\}`)
Add `dynvar` package for variable resolution with a `dyn.Value` tree (#1143) ## Changes This is the `dyn` counterpart to the `bundle/config/interpolation` package. It relies on the paths in `${foo.bar}` being valid `dyn.Path` instances. It leverages `dyn.Walk` to get a complete picture of all variable references and uses `dyn.Get` to retrieve values pointed to by variable references. Depends on #1142. ## Tests Unit test coverage. I tried to mirror the tests from `bundle/config/interpolation` and added new ones where applicable (for example to test type retention of referenced values). 2024-01-24 18:49:06 +00:00
			`// ref represents a variable reference.`
			`// It is a string [dyn.Value] contained in a larger [dyn.Value].`
			`// Its path within the containing [dyn.Value] is also stored.`
			`type ref struct {`
			`// Original value.`
			`value dyn.Value`

			`// String value in the original [dyn.Value].`
			`str string`

			`// Matches of the variable reference in the string.`
			`matches [][]string`
			`}`

			`// newRef returns a new ref if the given [dyn.Value] contains a string`
			`// with one or more variable references. It returns false if the given`
			`// [dyn.Value] does not contain variable references.`
			`//`
			`// Examples of a valid variable references:`
			`// - "${a.b}"`
			`// - "${a.b.c}"`
			`// - "${a} ${b} ${c}"`
			`func newRef(v dyn.Value) (ref, bool) {`
			`s, ok := v.AsString()`
			`if !ok {`
			`return ref{}, false`
			`}`

			`// Check if the string contains any variable references.`
			`m := re.FindAllStringSubmatch(s, -1)`
			`if len(m) == 0 {`
			`return ref{}, false`
			`}`

			`return ref{`
			`value: v,`
			`str: s,`
			`matches: m,`
			`}, true`
			`}`

			`// isPure returns true if the variable reference contains a single`
			`// variable reference and nothing more. We need this so we can`
			`// interpolate values of non-string types (i.e. it can be substituted).`
			`func (v ref) isPure() bool {`
			`// Need single match, equal to the incoming string.`
			`if len(v.matches) == 0 \|\| len(v.matches[0]) == 0 {`
			`panic("invalid variable reference; expect at least one match")`
			`}`
			`return v.matches[0][0] == v.str`
			`}`

			`func (v ref) references() []string {`
			`var out []string`
			`for _, m := range v.matches {`
			`out = append(out, m[1])`
			`}`
			`return out`
			`}`
Allow use of variables references in primitive non-string fields (#1219) ## Changes This change enables the use of bundle variables for boolean, integer, and floating point fields. ## Tests * Unit tests. * I ran a manual test to confirm parameterizing the number of workers in a cluster definition works. 2024-02-19 10:44:51 +00:00
			`func IsPureVariableReference(s string) bool {`
			`return len(s) > 0 && re.FindString(s) == s`
			`}`